'04 -10 12 SANYO Electric Co., Ltd. Electronic Device Company About this catalog The contents of this catalog are current as of September 2004, but product names and specifications are subject to change for improvement or discontinuation without notice. When ordering products, please be sure to request a delivery specifications form and read it carefully. Do not use the OS-CON for life-threatening applications (space equipment, aerial equipment, nuclear equipment, life-threatening medical equipment, vehicle control equipment, etc.). However, since there may be cases where conductive polymer aluminum solid electrolytic capacitors (SVP, SVQP, SVPD, SEP and SEQP) are adaptable with our special levels, be sure to consult with us, and exchange delivery specifications with us before use. The performance, characteristics, and features of the products described in this catalog are based on the products working alone under prescribed conditions. Data listed here is not intended as a guarantee of performance when working as part of any other product or device. In order to detect problems and situations that cannot be predicted beforehand by evaluation of supplied data, please always perform necessary performance evaluations with these devices as part of the product that they will be used in. When using the products listed in this catalog, please always be sure to try to prevent any possible accidents or injury by designing products in a careful and safe manner. If you have any questions concerning the use of these products, please contact any of our sales representatives. For any products listed in this catalog that may constitute restricted trade goods under overseas exchange or service trade laws, permission to deliver according to law may be required before importing. Unauthorized duplication of this catalog in part or in whole is forbidden. Please understand that we cannot be held responsible for any damages to the industrial properties of any third party that arise from the use or application of the products listed in this catalog, with the exception of those items directly related to method of construction. Introduction of Aluminum solid capacitors with Conductive polymer Guaranteed at 125C 85Cx 85% guaranteed and rated 35V max. P2829 P2627 SMD standard product Guaranteed at 125C P3031 Large capacitance and low ESR Low profile Large capacitance and low ESR P2425 Low ESR and large ripple current P2223 P2021 P1819 P3435 P3233 Guaranteed at 125C High voltage resistant Standard radial lead type Guaranteed at 105C for 3,000h Aluminum solid capacitors with Organic semiconductive electrolyte P3637 5 mm height (max.) P4243 Large capacitance and miniaturization P3637 Low ESL and low ESR P4445 Low profile P3839 Large capacitance and low ESR P4647 Long life span P4041 Standard product P4849 Miniaturization For information on integration of OS-CON models and discontinued series, please see page 86 1 Aluminum solid capacitors with Conductive polymer Aluminum solid capacitors with Organic semiconductive electrolyte Contents Item 1. Operating Precautions Description Cautions for circuit design Cautions for installation Others Page 4 to 10 2. Measures to Protect the 11 Environment 3. Series system diagram 4. Specifications for each series Serise system diagram, Sketch of Case Size Size list,ESRMatrix Conductive polymer type, Specifications for each series(Environmental product) SVPD series : Vertical SMD, Guaranteed at 125C, Rated 35V max. SVPC series : Vertical SMD, Large capacitance and low ESR SVPB series : Vertical SMD, Low profile SVPA series : Vertical SMD, Low ESR SVQP series : Vertical SMD, Guaranteed at 125C SVP series : Vertical SMD SEPC series : Radial lead type, Large capacitance and Low ESR SEQP series : Radial lead type, Guaranteed at 125C and high voltage resistant SEP series : Radial Lead type, Guaranteed at 105C for 3,000h Organic semiconductor type, Specifications for each series SF series : 5mm height (max.) SPA series : Low ESL and low ESR SP series : Large capacitance, Low ESR and Suitable for audio SC series : Standard product SA series : Large capacitance and miniaturization SL series : Low profile SH series : Long life span SS series : Miniaturization 2 5. Specifications for the radial lead type Explanation of part number Specification of Lead process Specification of taping product Minimum packaging quantity 6. Specifications for the SMD type Explanation of part number Taping Specifications Minimum packaging quantity Recommended Reflow conditions 12, 13 14 to 17 18, 20, 22, 24, 26, 28, 30, 32, 19 21 23 25 27 29 31 33 34, 35 36, 36, 38, 40, 42, 44, 46, 48, 37 37 39 41 43 45 47 49 50 50 51 51 52 52, 53 53 54 Contents Item Description Page 7. Construction and Characteristics Structure and Manufacturing method of OS-CON Electric characteristics of OS-CON 55, 56 57 to 60 8. Reliability Reliability test Presumption of life span 61 to 63 63, 64 9. Features Summary of OS-CON features 65 0. Precautions when using OS-CON in circuits Explanation of the rush current suppression methods. Examples of rush current suppression methods. Sudden discharge current suppression. Precautions when connecting an OS-CON and an aluminum electrolytic capacitor in parallel. 66 67 68 69 -. Application Ripple removal capability of OS-CON Evaluation of ripple current removal capability in comparison with other capacitors when the ambient temperature of a switching power supply is set at 25C, -20C and 70C. High-speed back-up capability When current is consumed with large variation of load at high-speed, capability of back-up capacitor is compared with other electrolytic capacitors. 76, 77 Application in lowpass filter circuit Necessity of OS-CON in low-pass filter circuit, and comparison with aluminum electrolytic capacitors. 78, 79 Application of Switching power supply to smoothing capacitor Mechanism and treatment method of abnormal voltage oscillation of switching power supply. Influence of output ripples on images Comparative demonstration using OS-CON and aluminum electrolytic capacitor showing noise from switching power supply of CCD camera. 85 =. Information and wish Integration of models and discontinued production information. 86 . Questionnaire Sheet contained required information for the selection of a Capacitor with switching power supply. 87 70 to 75 80 to 84 The data listed here is only representative of OS-CON, and does NOT show any guaranteed value. Change in product specifications, dimensions, etc. may occur without prior notice. Be sure that when placing order, please ask for specifications of each series in delivery, and read them well before use. 3 Instractionsfor use 1. Operating Precautions OS-CON is uniquely structured solid aluminum electrolytic capacitor. Please note the following points in order to take full advantages of the OS-CONs performance and to ensure the most stable quality possible. Circuit designing Crucial precautions [Important] 1. Polarity OS-CON is a solid aluminum electrolytic capacitor with positive and negative electrodes. Do not reverse the polarity when using. If it is used with the polarities reversed, increased leakage current or a decreased life span may result. 2. Prohibited circuits The OS-CON leakage current may become greater even if the soldering conditions adhere to the specification requirements. The high temperature no-load test, high temperature and high humidity no-load test, rapidly changing temperature test, etc may cause leakage current to become larger. Therefore, do not use the OS-CON in the following circuits because trouble or failure may occur. (a) High impedance voltage retention circuits (b) Coupling circuits (c) Time constant circuits In addition to the leakage current fluctuation, capacitance may also fluctuate depending on operational temperature and humidity. The fluctuation of the capacitance may cause problem if it is used as a time constant capacitor, which is extremely sensitive to the fluctuation of the capacitance. Do not use it as a time constant capacitor. Do not use the OS-CON in circuits except those above if changes in the leakage current affects circuit operations. If you plan to use 2 or more OS-CONs in a series connection, please contact us before use. 3. Compliance with rated performance OS-CON must be used under rated performance prescribed in the specification. Operational and installation condition must be carefully examined. (a) Over-voltage exceeding the rated voltage should not be applied even for an instance since it may cause a short circuit. (b) Operating temperature (ambient of OS-CON ) must be within the category temperature range of specification. (c) Do not apply current that exceeds the rated ripple current. When excessive ripple current is applied, the OS-CON may result in shorter life due to the internal heat increase. 4. Applied voltage (a) OS-CON can be applied with 100% of rated voltage except for 25V product. In case of 25 V product, if the operating temperature is above 85 deg.C, derating voltage shown in the following figure must be applied. If the temperature is below 85 deg.C, derating is not necessary. In any event, over voltage exceeding the rated voltage must not be applied even for a moment. * Concerning SVPD series 25V products, there are no problems using them at 100% of the rated voltage. (b) Sum of the DC voltage value and the ripple voltage peak values must not exceed the rated voltage. (c) When DC voltage is low, negative ripple voltage peak value must not become a reverse voltage that exceeds 10 % of the rated voltage. (d) Use the OS-CON within 20 % of the rated voltage for applications which may cause the reverse voltage during the transient phenomena when the power is turned off or the source is switched. 4 Instractionsfor use 1. Operating Precautions 5. Sudden charge and discharge Sudden charge and discharge may result in short circuits and the large Leakage current. Therefore, protection circuits are recommended to design in when the following conditions are available. (a) The rush current is over 10 A. (b) The rush current is over 10 times of allowable ripple current of OS-CON. A protection resistor (1 k) must be inserted to the circuit during the charge and discharge when measuring the leakage current. 6. Failure and life-span The OS-CON failure rate in use is based on the failure rate level in the specification requirements (Upper category temperature and category voltage adhere to JIS C 5003. The confidence level is 60% and the failure rate is 0.5 %/1000h.) and this ratio is low, however, failures may occur. It is possible to cause a failure circuit even if OS-CONs have a lowest failure rate. As the above reason, please insert a protection circuit to prevent unlikely event by accident. Meanwhile, please design your circuit using OS-CON which cause no damage to social or person directly, or use after checking that it causes no problem even if it fails. The failure modes mainly have two types (a) and (b) as follows. (a) Contingency failure The contingency failure mainly has short circuit. The phenomenon of after short is on following. (1) Phenomenon of after short circuit mode (a) Resin sealing type (SC, SA, SL, SH, SS, SP, SPA, and SF series) In the event a short circuit causes the current to become relatively small (less than approximately 3A for 10 and less than approximately 1A for 6.3), the OS-CON itself will generate a little heat, but its appearance will not be affected even when electricity is supplied continuously. However, if the short circuit current value exceeds the mentioned values above, the temperature inside the OS-CON will increase. When the temperature exceeds approximately 220C, the impregnated organic semiconductor melts and liquefies, the internal pressure is raised, and the liquefied organic semiconductor and odorous gas are released from the space between the sealant and the aluminum case and lead terminals. In this case, keep your face and hands away from the area. (b) Rubber sealing type (SEP, SEQP, SEPC, SVP, SVQP, SVPA, SVPB, SVPC, and SVPD series) In the event a short circuit causes the current to become relatively small (less than approximately 1A for 10, less than approximately 0.5A for 8 and less than approximately 0.2A for 6.3), the OS-CON itself will generate a little heat, but its appearance will not be affected even when electricity is supplied continuously. However, if the short circuit current value exceeds the mentioned values above, the temperature inside the OS-CON will increase, the internal pressure is raised, rubber sealing is turned over, and odorous gas is released. In this case, keep your face and hands away from the area. (2) If a short circuit occurs and odorous gas is released, either turn off the main power of the equipment or unplug the power cord from the outlet. (3) If a short circuit occurs, it may take from a few seconds to a few minutes before the organic semiconductor liquefies and an odorous gas produces, depending on the conditions. It is recommended to set up a power protection circuit to function during this time. (4) If the gas comes in contact with eyes, rinse immediately. If the gas is inhaled, gargle immediately. (5) Do not lick the OS-CONs electrolyte. If the electrolyte comes in contact with skin, wash it off with soap immediately. (6) The electrolyte, electrolytic paper, resin, sleeve, sealing rubber, and plastic spacer used in the OS-CON are all combustible. When the current is extraordinarily large after a short circuit, in the worst case, the shortedout section in the lead terminal or inside the capacitor may ignite the resin and/or rubber. Pay attention to the capacitor mounting method, mounting position, pattern design, etc. (b) Performance characteristic and failure (life-span) The OS-CONs characteristics can possibly change (Capacitance reduction and ESR increase) within the specified range in specifications when it is used in the condition of Rated voltage, Electric and mechanical performance. When life span exceeded the specified guarantee time of Endurance and Damp heat, electric characteristic might change and cause electrolyte insulation. This is called Open circuit mode. 5 (1) Please confirm the following item when select and design OS-CON. Electric performance Capacitance Capacitance Delivery Mounting SMD type: Reflow soldering Radial lead type: Flow soldering ESR Leakage current In use Capacitance ESR Leakage current Others Ripple current Confirmation Item Capacitance tolerance of rated capacitance. Change rate in Capacitance to initial value after mounting. Note: This item also applied to SMD type-reflow mounting of SANYO Recommended reflow condition. Heat stress to OS-CON will be influenced by the different of reflow equipment, board material, size, and numbers of mounting. Please check your reflow condition whether it is within the above SANYO Recommendable Reflow Condition or not and confirm OS-CON's electric characteristic change before and after reflow. The specification after mounting. Leakage current less than or equal to the value of specification after voltage treatment. Leakage current may increase and exceed the specification value after mounting. In such a case, Leakage current will decrease and return back to specification after applying voltage. (1) Change rate in Capacitance before and after Endurance test (2) Change rate in Capacitance before and after Damp heat test (1) The specification after Endurance test. (2) The specification after Damp heat test. (1) Leakage current is less than or equal to specification after Endurance test. (2) Leakage current may increase and exceed the specification value after Damp heat test. In such case, Leakage current will decrease and return back to specification after applying voltage. It is necessary to apply a frequency coefficient according to an usable frequency which is beside 100kHz to 500kHz. Cautions 1. Leakage current Heat pressure from soldering and mechanical stress from transportation may cause the leakage current to become large. In such a case, leakage current will gradually decrease by applying voltage less than or equal to the rated voltage at a temperature within the upper category temperature. In close conditions to the upper category temperature, the nearer the applied voltage is to the rated voltage, the faster the leakage current recovery speed is. (Refer to below.) OS-CON leakage current restoration characteristics 10F/16V (16V DC applied) 1000 OS-CON leakage current restoration characteristics 33F/10V (Ambient temperature : 65C) (Measured voltage : 10V) 1000 100 Leakage current (A) Leakage current (A) Instractionsfor use 1. Operating Precautions 100 10 1 0.1 1 10 (Hrs.) 100 1000 5V applied 10 8V applied 1 *A sample that had stress intentionally applied to make the leakage current larger was used to make leakage current recovery easy to understand. 10V applied 0.1 1 10 (Hrs.) 100 1000 2. Capacitor insulation (a) Insulation in the marking sleeve and the laminate resin is not guaranteed. Be aware that the space between the case and the negative electrode terminal is not insulated and has some resistance. (b) Be sure to completely separate the case, negative lead terminal, positive lead terminal and PC board patterns with each other. 3. Operating environmental restrictions Do not use the OS-CON in the following environments. (a) Places where water, salt water or oil can directly fall on it, and places where condensation may form. (b) Places filled with noxious gas (hydrogen sulfide, sulfurous acid, nitrous acid, chlorine, ammonia, etc.). (c) Places susceptible to ozone, ultraviolet rays and radiation. 6 4. PCB (PC board) design (a) Avoid locating heat-generating components around the OS-CON and on the underside of the PC board (underneath the OS-CON). (b) Follow the recommendations given in the specifications for land patterns for SMD type PC board when designing circuits. (c) The pitch and diameter of PCB holes to which radial lead type of OS-CON is mounted should be designed to conform to the dimensional tolerance stipulated in the specifications. 5. Parallel connection A large amount of ripple current may be applied to the OS-CON when it is used in parallel with another capacitor. Carefully select the type of capacitor. 6. Others Design circuits after checking the following items. (a) Electric characteristics are affected by temperature and frequency fluctuations. Design circuits after checking the following items. (b) When mounting an OS-CON on a double-sided PC board, extra PC board holes and the through holes for connecting the front and back of the PCB must not exist underneath the OS-CON. Mounting precautions 1. Considerations when soldering The soldering conditions are to be within the range prescribed in specifications. If the specifications are not followed, there is a possibility of the cosmetic defection, the intensive increase of leakage current, and the capacitance reduction. 2. Things to be noted before mounting (a) Do not reuse OS-CONs that have been assembled in a set and energized. Excluding OS-CONs that have been removed for measuring electrical characteristics during a periodic inspection, OS-CONs cannot be reused. (b) Leakage current may increase when OS-CONs are stored for long periods of time. In this case, we recommend that you apply the rated voltage for 1 hour at 60C - 70C with a resistor load of 1 k. 3. Mounting-1 (a) Mount after checking the capacitance and the rated voltage. (b) Mount after checking the polarity. (c) Do not drop the OS-CON on the floor. Do not use OS-CONs that have been dropped. (d) Do not deform the OS-CON. 4. Mounting-2 (a) Mount after checking that SMD types of the OS-CONs terminal pitch and the PCB land pattern. (b) Mount after checking that radial lead types of the OS-CONs terminal pitch and diameter of PCB holes. When an automatic inserter is used to clinch the OS-CONs lead terminals, make sure it is not set too strong. (c) Be careful to the shock force that can be produced by absorbers, product checkers, and centers on automatic inserters and installers. (d) Do not apply excessive external force to the lead terminal and the OS-CON itself. 7 Instractionsfor use 1. Operating Precautions Instractionsfor use 1. Operating Precautions 5. Soldering with a soldering iron (a) Set the soldering conditions (temperature, time) so that they fall within the stipulated range in the specifications. (b) When the lead terminal for radial lead type must be processed because the lead pitch and the PCB holes in spacing do not match, process it before soldering so that no stress is applied to the OS-CON itself. (c) Do not subject the OS-CON itself to excessive stress when soldering. (d) When a soldering iron is used to repair an OS-CON that has already been soldered once and needs to be removed, remove it after the solder has been completely melted so that no stress is applied to the OS-CONs lead terminal. (e) Do not let the tip of the soldering iron touch the OS-CON itself. ( f ) The leakage current value after soldering may increase a little (from a few A to several hundred A) depending on the soldering conditions (preheating and solder temperature and time, PCB material and thickness, etc.). The leakage current can be reduced through self-repair by applying voltage. 6. Flow soldering (a) Do not use flow soldering for SMD type. (b) Do not solder the OS-CON by submerging it in melted solder. Use the PCB to protect the OS-CON and only solder the opposite side that the OS-CON is mounted on. (c) Set the soldering conditions (soldering temperature, terminal immersion time) so that they fall within the stipulated range in the specifications. The leakage current value after soldering may increase (from a few A to a few mA) depending on the soldering conditions (preheating and solder temperature and time, PCB material and thickness, etc.). However, the leakage current can be reduced by applying voltage to set into operating condition. In regards to flow soldering, be sure to solder within the following conditions. Temperature Duration Flow number Preheating 120C or less (ambient temperature) 120 sec. or less 1 time Soldering conditions 260 + 5C or less 10 + 1 sec. or less 2 times or less *1 *1 When soldering 2 times, immersion time should be 10 + 1 sec. or less. (d) Take care that flux does not adhere to anywhere expect the lead terminal. (e) When soldering, take care that other components do not fall over and touch the OS-CON. ( f ) Flow soldering under extremely abnormal conditions may reduce the capacitance of products after soldering. 7. Reflow soldering (a) Reflow soldering is unapplicable to Radial lead type. (b) Set the soldering conditions (soldering temperature, terminal submersion time) so that they fall within the stipulated range in the specifications. The leakage current value after soldering may increase a little (from a few A to several mA) depending on the soldering conditions (preheating and solder temperature and time, PCB material and thickness, etc.). The leakage current can be reduced through self-repair by applying voltage. (c) Please contact SANYO for setting VPS soldering conditions (d) In the case of reflow soldering, capacitive static electricity may decrease after soldering even when the soldering conditions are within the required values. 8. Handling after soldering (a) Do not tilt, bend or twist the OS-CON after it has been soldered on the PCB. (b) Do not move the PCB with catching OS-CON itself by hand after soldering. (c) Do not dump the OS-CON with objects after it has been soldered to the PCB. When stacking PCBs, make sure that the OS-CON does not touch other PCBs or components. (d) Do not subject the OS-CON to excessive stress after it has been soldered to PCB. 8 Instractionsfor use 1. Operating Precautions 9. Washing the PCB Check the following items before washing the PCB with these detergents: high quality alcohol-based cleaning fluid such as Pine-ST-100S, Clean thru 750H, 750L, 710M, 750K, or Techno Care FRW 14 through 17; or detergents including substitute freon as AK-225AES and IPA. (a) Use immersion or ultrasonic waves to clean for a total of less than five minutes. (SVP,SVQP,SVPA,SVPB, SVPC,SVPD,SEP,SEQP and SEPC series are less than two minutes.) (b) The temperature of the cleaning fluid should be less than 60 C. (c) Watch the contamination of the detergent (conductivity, pH, specific gravity, water content, etc.). (d) After cleaning, do not store the OS-CON in a location subject to gases from the cleaning fluid or in an airtight container. Dry the PCB and OS-CON with hot air (less than the maximum operating temperature). Please do not heat (heat run, dry, etc.) soon after cleaning. (e) Please contact SANYO for details about detergents and cleaning methods, and about detergents other than those listed above. 10. Fixatives and coatings (a) Select the appropriate covering and sealant materials for OS-CONs. In particular, make sure the fixative, coating and thinner do not contain acetone. (b) Before applying a fixative or coating, completely remove any flux residue and foreign matter from the area where the board and OS-CON will be jointed together. (c) Allow any detergent to dry before applying the fixative or coating. (d) Please contact SANYO for fixative and coating heat curing conditions. 11. Precautions with completed board (a) Do not touch the lead terminals of OS-CON directly. (b) Do not use electric conductors to cause short circuits between the OS-CONs lead terminals. Do not subject the OS-CON to conductive solutions such as acids and alkaline water solutions. (c) Check the installation environment of the board the OS-CON is installed in. (d) Age the board at conditions that fall below the capacitors ratings. (e) It is recommended that the board be used at room temperature and in ordinary humidity. Storage and Disposal 1. Storage conditions (a) Do not store the OS-CON at high temperatures and high humidity. Store it in a location that is not subject to direct sunlight and that has temperatures less than 5C to 35C and a relative humidity less than 75 % generally. (b) To keep good solderability, store the OS-CONs in its plastic bag under shipping condition. SMD types (SVP, SVQP, SVPA, SVPB, SVPC and SVPD series) are sealed up in specifically designed aluminum laminate bags to prevent deterioration in characteristic and solderability before and after reflows resulting from moisture absorption. (c) To keep good solderability, store radial lead types packed in bags for not more than one year (after delivery), and radial lead types with taping and SMD types for not more than six months (after delivery) before opening.(Refer to the table on the next page.) (d) Open the bags just before mounting, and use up all products once opened. In case of leftovers, put radial lead types packed in bags, SMD types and unpackaged ones back into the storage bags (specifically designed aluminum laminate bags for SMD types), and seal up the opening with tape etc. Put radial lead types with taping in plastic bags as they are put into storage boxes and seal up the opening with tape etc. In case of storage after opening, please follow the storage term as stated in the table below. (e) Do not store the OS-CON in damp conditions such as with water, salt spray, or oil spray, and high humidity. ( f ) Do not store the OS-CON in places filled with noxious gas (hydrogen sulfide, sulfurous acid, nitrous acid, chlorine, ammonia, etc.). 9 Instractionsfor use 1. Operating Precautions (g) Do not store the OS-CON in places susceptible to ozone, ultraviolet rays and radiation. Before unseal After unseal Within 6 months after delivery Within 30 days from opening (Unopened condition) (Packaged condition with carrier tape) Radial lead type Within 1 year after delivery Within 7 days from opening bag packing product (Unopened condition) (1 week) Radial lead type Within 6 months after delivery Within 7 days from opening taping product (Unopened condition) (1 week) SMD type The moisture absorption level of the SMD type is shown below. Floor Life LEVEL 2a Time Condition 4Week 30/60%RH Storage Condition Packed with carrier tape (Required standard : IPC/JEDEC J-STD-020B) 2. Disposal OS-CON comprises solid organic compounds, various metals, resin, rubber, etc. Treat it as industrial waste when disposing of it. In case of disposing a large amount of OS-CON, SANYO can dispose on behalf. Note: In case of some problems concerning industrial possessive rights of third party by using this product, we don't take responsibility except for what to be directly conceded with structure processes OS-CON. Please design with safety measures taking into consideration any social damage, such as personal or fire accident when using this product. 10 TM 2. Measures to Protect the Environment RoHS Directive Restriction of the use of certain hazardous substances in electrical and electronic equipment * EU environmental regulation * RoHS aims to improve the regulations for hazardous substances in electrical and electronic equipment, and to minimize the hazardous effects on environment and to people's health from the production process up to and including the disposal process. * RoHS prohibits the use of 6 substances including cadmium, lead, hexavalent chromium, mercury, polybrominated biphenyls (PBBs), and polybrominated diphenyl ethers (PBDEs). OS-CON Measures for the RoHS Directive Measures status *1 Conductive polymer Already in conformation OS-CON Organic semiconductor OS-CON Sleeve material is being changed from PVC to PET (Complete removal of lead and phtalic esters) *1 Contact us about the detailed status because a few specific special products do not meet the RoHS Directive yet. Also, contact us concerning the status of sleeve material change. 11 Measuresto Protectthe Environment We are working on complete removal of environmental hazardous substances from the OS-CON, in order to conform to EU RoHS Directive (refer to below) coming into effect from July 2006 and to green procurement introduced in many companies. 3. SERIES SYSTEM DIAGRAM Aluminum solid capacitors with Conductive polymer Environmental productLead-free reflow product SVPB Series P2223 Low profile Low profile SVPA Series Large Cap. P2425 Low ESR and large ripple current SVPC Series P2021 Large capacitance and low ESR Seriessystem diagram Low ESR SVQP Series P2627 SVP Series High Temp. P2829 Guaranteed at 125 standard High Voltage SMD SVPD Series P1819 High voltage resistant and guaranteed at 125C Aluminum solid capacitors with Conductive polymer Environmental productLead-free flow product SEQP Series P3233 Guaranteed at 125 High voltage resistant Radial SEP Series High Temp. SEPC Series Low ESR P3435 Guaranteed for 3,000h P3031 Large capacitance and low ESR Aluminum solid capacitors with Organic semiconductive electrolyte SH Series P4647 Long life. Long life span P4243 Large capacitance and miniaturization Long life. Large Cap. SC Series P4041 SP Series Low ESR P3839 Standard Large capacitance and low ESR Low profile Low profile SS Series SL Series SF Series P4849 P4445 P3637 Miniaturization Low profile 5mm height (max.) Low profile 12 Radial SA Series Low ESL SPA Series P3637 Low ESL and low ESR 3. SERIES SYSTEM DIAGRAM * Sketch of Case Size (unit : mm) SMD type with conductive polymer electrolyte 10.0 8.0 B6 C5 C55 E7 12.7 10.3 8.3 10.3 8.3 10.3 8.3 C6 12.0 8.0 7.0 10.3 8.3 6.6 6.6 6.6 5.3 A5 6.0 5.5 5.0 6.0 5.5 4.3 6.6 F8 E12 F12 (Size code) Radial lead type with conductive polymer electrolyte C6 8.0 E7 8.0 E9 F8 13.0 8.0 E12 10.0 13.0 9.0 8.0 10.0 12.0 8.0 7.0 6.0 6.3 E13 F13 (Size code) Radial lead type with Organic semiconductive electrolyte 8.0 10.0 10.0 A B C D 12.5 E F F0 A' B' C' E' F' 8.0 10.0 E1 G H (Size code) 10.0 10.0 8.0 5.0 10.0 6.0 8.0 6.0 6.3 6.0 5.0 6.0 6.0 4.0 16.0 26.0 23.0 21.0 11.5 10.8 6.3 11.5 6.3 7.8 5.0 7.8 7.8 4.0 9E 9F (Size code) Profile of case size are all expressed in maximum values. 13 Seriessystem diagram 6.6 5.3 4.3 8.0 6.3 6.3 6.3 6.6 5.0 4.0 10.0 3. SERIES SYSTEM DIAGRAM Size List V 2 F 4 2.5 6.3 10 1 1.5 2.2 3.3 SVP(A5), SC(A),SL(A'),SH(A) 4.7 Seriessystem diagram SC(A),SL(A'),SH(A) 6.8 SVP(A5) 8.2 SVP(A5),SC(B), SL(B'),SH(B),SS(A') 10 15 SC(B),SL(B'),SH(B), SS(A') SVP(A5) SVP(A5) SC(C),SL(C'),SS(B') SC(C),SS(B') SVP(B6),SL(C') SVPA(B6),SVP(B6), SA(C),SH(C) SVP(C6), SC(D),SL(C') 18 22 27 33 SVP(A5) 39 SVP(B6) 47 SVPD(C6),SEQP(C6),SVP(C6), SVPB(C5),SVQP(C6),SEP(C6), SP(C') 56 SVPA(B6),SVP(B6), SS(C') 68 SVPA(B6) 82 SVPB(C5), SEP(C6), SP(C') 100 SVPA(C6),SVPC(B6), SEQP(C6),SVP(C6,E7), SVQP(C6),SEP(C6), SP(C),SL(E'),SS(D) 150 SVP(C6) 220 330 SVPA(E7) 390 SVPC(C6) SVPC(B6), SVP(C6), SVQP(C6),SL(E') SP(E'),SL(F'),SS(D) SEQP(E7),SVQP(E7), SEP(E7),SF(E1),SP(E'), SA(E),SL(F'),SH(E) SEPC(E9) 560 SVPC(E7), SVP(E12), SEP(E12) SEPC(E9,E13), SVPA(F8),SVPC(E12) 680 820 SP(F) 1200 SP(F) 1500 SVPC(E12),SVP(F12), SEP(F13) SEQP(F7),SVP(E7),SVPC(C6) SVQP(E7),SEP(E7) SVPA(E7), SVP(E7,F8), SVQP(E7),SP(D), SS(E) SP(F') SVQP(E7),SEP(E7), SF(E1),SP(E'),SL(F') SVPC(C6),SEQP(E7), SVP(E7),SEP(E7),SP(F') SEP(F8),SS(F) 470 SEPC(E9,E12,E13), SVPC(E7),SEQP(E12), SVP(E12),SEP(E12), SPA(9E),SP(E) SEPC(E13),SVPA(F8), SVPC(E7),SEQP(F8), SVP(F8),SEP(F8) SEPC(F13),SPA(9F),SP(F) SVPA(E7), SVPC(C6), SVP(E7,F8), SVQP(E7), SP(F',D),SS(E) SEQP(F8),SVP(F8), SEP(F8),SA(F),SH(F) SVPC(E7),SP(E) SVPA(F8),SEQP(E12), SVP(F8,E12), SEPC(E9,E13),SEP(E12) SEPC(F13),SP(F) SVPC(E12),SEQP(F13), SVP(F12),SEP(F13) SP(F0) SEPC(F13) SP(G) SA(H) SP(F0) SEPC(F13),SVPC(F12) SA(F),SH(F) SEQP(F8),SVP(F8),SVPC(E7) SEP(F8),SP(E) SVPA(F8),SEQP(E12), SVP(F8,E12), SEP(E12),SS(F) SP(F) SEQP(F13), SVP(F12),SEP(F13) SP(F) SVPC(E12),SEQP(F13), SVP(F12),SEP(F13) ...Conductive polymer type...Organic semiconductor type 14 SP(C) SVPA(E7),SP(D) 270 1800 2200 2700 SVPB(C5),SEQP(C6) SVP(C6),SVQP(C6),SEP(C6) SVPA(C6), SVPC(B6) 180 1000 SVPA(C6),SVPC(B6) SA(D),SL(E'),SH(D) SVPA(C6),SVP(C6),SP(C) SVPB(C5) 120 SP(C') 3. SERIES SYSTEM DIAGRAM Size List 16 20 25 30 32 35 V F SC(A) SC(B) SC(B) 1 1.5 2.2 SS(A') SC(B),SL(B'),SH(B) SC(C) 3.3 SS(B') SC(C),SL(C'),SH(C) SC(D) 4.7 SC(B),SL(B'),SH(B), SS(A') SS(B') SVP(C6),SEP(C6), SP(C'),SC(C), SL(C'),SH(C) SC(D) SL(C'),SS(B') SVP(B6),SS(C') SVP(B6), SC(C),SL(C'),SS(B') SVPB(C5),SA(C), SH(C),SS(C') SC(A),SL(A'),SH(A) SVP(A5), SC(A),SL(A'),SH(A) SC(B),SL(B'),SH(B), SS(A') 6.8 SEQP(E7) SVPD(E7) SVP(B6),SC(D) SVPB(C5),SP(C'),SC(D), SA(C),SH(C),SS(C') SVPA(C6),SEQP(C6),SVP(C6), SVQP(C6),SEP(C6),SVPC(B6) SVPB(C55),SEQP(C6), SVP(C6),SVQP(C6), SEP(C6),SP(C'),SA(C), SH(C),SS(C') SVP(C6) SVP(E7),SEP(E7), SP(C),SA(D),SH(D) SVPD(C6),SVP(E7), SEP(E7),SP(C), SC(C),SH(C) SC(E) SEQP(F8) SP(D) SEQP(E12) SC(F) 8.2 10 SC(D),SL(E'),SH(D) SVPD(E7), SVP(F8),SEP(F8), SC(E),SL(F') 15 SVPD(F8) 18 SVPD(E12) 22 27 SVP(E12),SEP(E12), SP(E),SC(F) 33 SVPD(F8) 39 SP(C),SA(D),SL(E'), SH(D) SEQP(E7),SVP(E7), SVQP(E7),SEP(E7), SP(E'),SA(E),SH(E),SS(D) SVPD(E12),SC(F) 47 SVP(E7) SVP(F8),SEP(F8) SVP(F12),SEP(F13), SP(F) 56 SVPC(C6),SP(E'),SL(F'), SS(D) SEQP(F8),SVP(F8), SEP(F8),SP(F',D), SA(E),SH(E) SVPD(E7),SVPA(E7),SEQP(E7), SVP(E7),SVQP(E7),SEP(E7) SVP(F8), SP(F',D),SA(E),SH(E) Seriessystem diagram SS(A') SC(A),SL(A'),SH(A) SC(A),SL(A'),SH(A) SC(B),SL(B'),SH(B) 68 SVPD(F12) 82 SVP(E12), SEQP(E12), SEP(F8,E12), SA(F),SH(F),SS(E) 100 SVPC(E7) SP(E) 120 SEQP(F8),SVP(F8),SEP(F8), SA(F),SH(F) SEQP(F13),SVP(F12), SEP(F13),SS(F) 150 SVPA(F8), SEQP(E12), SVP(F8,E12), SEP(E12),SP(E) SP(F) 180 220 SEPC(E12),SP(F) SEQP(F13),SVP(F12), SEP(F13) 270 330 390 SEPC(E13),SA(G) 470 560 680 820 SA(H) 1000 1200 1500 1800 2200 2700 ...Conductive polymer type...Organic semiconductor type 15 3. SERIES SYSTEM DIAGRAM ESR Matrix V m 7 8 9 10 11 Seriessystem diagram 12 13 14 SEPC(E9,E13,F13) SP(F0) SVPC(E12) SP(G) SPA(9F) SVPC(E12,F12),SEQP(F13), SVP(F12),SEP(F13),SPA(9E), SP(F) SEQP(E12),SVP(E12), SEP(E12), SP(E) SEPC(F13) SEPC(E9,E13) SEPC(F13) SVPC(E12),SEQP(F13),SVP(F12), SEP(F13), SP(F) SVPC(C6),SEQP(E12),SVP(E12), 15 16 SEP(E12),SA(H) SP(E) 17 SVP(C6) 18 19 20 SEQP(F13),SVP(E12),SEP(F13) SP(F) SEQP(E12),SVP(E12), SEP(E12), SP(E) SVPA(F8) SVPA(C6,E7), SVPC(E7) 21 22 23 SVP(C6) 24 SVPC(B6) 25 SVPC(C6) SVPA(F8),SP(D) SVPC(C6) SVPA(C6,E7), SVPC(E7) SVPC(B6) SP(F') SVPA(F8),SP(D) SVPA(C6,E7), SVPC(E7) SVPC(E7) SVPA(F8) 27 SEQP(F8),SVP(F8), SEP(F8),SS(F) SVPC(C6) SVPC(B6),SEQP(F8),SVP(F8), SEP(F8),SA(F),SH(F) SVPC(C6) 28 SP(E') SP(F') SEQP(F8),SVP(F8),SEP(F8), SP(D),SS(F) SVPC(C6),SA(F),SH(F) SP(F') 29 30 10V 6.3V 4V 2V/2.5V SEPC(E9,E13) SEPC(E9),SP(F0) SVPC(E12) SVPC(E12),SEPC(F13) SP(F) SVP(F12), SEP(F13), SP(F) SVP(E12), SEP(E12) SVPA(B6), SVPC(B6) SVPA(B6), SVPC(B6),SF(E1) 32 34 SEQP(E7),SVP(E7),SVQP(E7) SEP(E7),SP(C) 35 SVPA(B6), SVPC(B6),SP(E'), SA(E),SH(E),SS(E) SF(E1) SVPA(C6,E7),SVPC(B6) SVP(F8),SS(E) SP(E') SEQP(E7),SVP(E7),SVQP(E7), SEP(E7),SP(C) SEQP(E7),SVP(E7),SVQP(E7), SEP(E7) SVPB(C5),SVP(C6),SVQP(C6), SP(C') SVPB(C5),SP(C),SS(D) SVP(C6),SVQP(C6), SEP(C6) SVPD(C6),SEQP(C6),SVP(C6), SVQP(C6),SEP(C6),SP(C') 36 SVPB(C5),SEQP(C6),SVP(C6), 40 SVPB(C5) SVQP(C6),SEP(C6),SP(C'), SS(D) 45 48 SVP(C6), SA(D),SH(D) 50 55 SL(F') 60 SVP(B6),SL(E') 65 70 SVP(B6),SS(C') SA(C),SL(F'),SH(C) SC(D),SL(F') SL(E') SL(E') SVP(B6), SC(C),SL(C') SVP(B6),SC(C) 75 80 90 100 110 120 SC(B),SL(B'),SH(B) 150 SS(B') 180 200 220 240 250 260 280 300 350 400 450 SL(C') SVP(A5) ...Conductive polymer type...Organic semiconductor type 16 SVP(A5) SC(B),SL(B'),SH(B), SS(B') SVP(A5) SVP(A5) SVP(A5) SC(A),SH(A) SC(A),SH(A) SL(A'),SS(A') SS(A') SL(A') 3. SERIES SYSTEM DIAGRAM ESR Matrix 16V 25V 20V 30V 32V 35V SEPC(F13) SEPC(E12) V m 7 8 9 10 11 Seriessystem diagram 12 13 14 SA(H) 15 SEQP(F13),SVP(F12),SEP(F13) 16 17 18 19 SP(F) SEQP(E12),SVP(E12), SEP(E12), SP(E),SA(G) SEQP(F13),SVP(F12), SEP(F13),SP(F) 20 21 22 23 SVPA(C6) SEQP(E12), SVP(E12),SEP(E12), SP(E) SP(D) 24 SP(F) 25 SVPC(E7) 27 SVPD(F12), SVP(F12),SEP(F13) SA(F),SH(F) SVPA(F8) SVPA(E7),SEQP(F8),SVP(F8), SEP(F8),SA(E),SVPC(C6), SH(E) SP(F') SP(E') 28 29 SP(D),SA(F),SH(F), SS(E,F), SVPD(E12),SVP(E12), SEP(E12),SP(E) 30 32 34 SVPA(C6),SVPC(B6),SVP(F8) SP(F') SVPB(C55), SEP(F8) SP(E'),SA(E),SH(E) SC(F) SVPD(E7),SEQP(E7),SVP(E7), SVQP(E7),SVPB(C5),SEP(E7) SEQP(F8),SVP(F8), SEP(F8),SA(E),SH(E) SP(D),SC(E) 40 SVP(E7),SP(C) SVPB(C5),SEQP(E7),SVP(E7), SVQP(E7),SEP(E7),SP(C) SVPD(F8) 45 SVPD(E7) 48 35 36 SEQP(C6),SVP(C6),SVQP(C6), SEP(C6),SP(C'), SS(D) SP(C') SVP(F8),SEP(F8) SA(D),SH(D) SEQP(C6),SVP(C6),SVQP(C6), SEP(C6),SS(D) SP(C) SVP(E7),SEP(E7), SP(C') SVPD(C6) SVPD(F8) SA(C,D),SH(C,D) SC(D),SL(F'),SH(D) SVPD(E7) SA(C),SH(C) SS(C') SL(E') SVP(C6),SEP(C6) SC(C),SH(C) SC(C),SL(C'),SH(C) SL(F') SC(D),SA(C),SL(E'), SH(C) SVP(B6),SC(C) SL(C'),SS(C') SVP(B6) SEQP(E12) SL(B') SVP(A5) SC(A),SH(A) SL(A'),SS(A') 60 65 SC(F) SEQP(F8) SEQP(E7) 70 75 80 90 100 110 120 150 SC(B),SH(B),SS(B') SC(B),SL(B'),SH(B), 50 55 SC(E) SC(D) SVP(B6) SVPD(E12) SS(B') SS(B') SS(A') SC(B),SH(B) SC(C) SL(B') SC(B) SC(A),SH(A) SC(A),SH(A) SL(A') SL(A') SC(B) SC(A) 180 200 220 240 250 260 280 300 350 400 450 ...Conductive polymer type...Organic semiconductor type 17 4. SPECIFICATIONS FOR EACH SERIES Conductive polymer type SVPD Series Guaranteed at 125C, 85Cx85% guaranteed,Rated 35V, Rated 35V max. Marking : Polarity( ), Rated voltage, (Purple) SVPD Rated capacitance, Lot.No. Specifications Items Category temperature range Tolerance on rated capacitance Tangent of loss angle Leakage current 1 ESR Characteristics of impedance ratio at high temp. and low temp. Characteristics -55C to +125C M : 20% 120Hz Less than or equal to the value of Table1 120Hz Less than or equal to the value of Table1 After 2 minutes Less than or equal to the value of Table1 Z / Z 20C 0.75 to 1.25 Based the value at -55C 0.75 to 1.25 Z / Z 20C 100KHz+20C +125C Within 20% C/C 2 times or less than an initial standard 125C, 2,000h, Rated tan Endurance 2 times or less than an initial standard voltage applied ESR Leakage current Below an initial standard Within 20% C/C 85C, 85 to 90% RH, 2 times or less than an initial standard tan Damp heat (Steady state) 1,000h, 2 times or less than an initial standard ESR Rated voltage applied Leakage current Below an initial standard Within 10% C/C Resistance to 1.3 times or less than an initial standard tan 2 (VPS) (230C X 75s) soldering heat 1.3 times or less than an initial standard ESR Leakage current Below an initial standard (after voltage processing) Conditions 1 In case of some problems for measured values, measure after applying rated voltage for 120 minutes at 125C . 2 Refer to Page 54 for reflow soldering conditions. Dimensions 0.2max. (unit : mm) W L C6 E7 F8 E12 F12 P C H Size Code D+0.5max. D Specificationsfor eachseries The SVQP series guaranteed 125Chighvoltageresistancewasimproved toaratedmaximumof35V.This product is very reliable, guaranteeing 85C x 85% performance. Suitable for use in smoothing circuits of vehiclemounted equipment, industrial equipment, etc. This product can support lead free-reflow.(2). R Size List RV : Rated voltage (SV) : Surge (125C) RV 10.0 16.0 25.0 35.0 SV11.5 18.4 29.0 40.0 F 8.2 10 18 22 39 47 56 82 E7 C6 E7 F8 E12 F8 E12 C6 E7 F12 For the minimum packing quantity, please refer to page 53. 18 6.3 8.0 10.0 8.0 10.0 L +0.1 -0.4 5.9 6.9 7.9 11.9 12.6 W0.2 H0.2 C0.2 R P0.2 6.6 8.3 10.3 8.3 10.3 6.6 8.3 10.3 8.3 10.3 7.3 9.0 11.0 9.0 11.0 0.5 to 0.8 0.5 to 0.8 0.5 to 0.8 0.8 to 1.1 0.8 to 1.1 2.1 3.2 4.6 3.2 4.6 4. SPECIFICATIONS FOR EACH SERIES Table1 SVPD Series Characteristics List Size Code Part Number 1 Rated Voltage (V) ESR Rated Capacitance 100kHz to 300kHz (F) (m) (max.) Rated ripple current Allowable ripple current 100kHz (mArms) 105Tx125 3 Tx105 Tangent of loss angle (max.) Leakage current (A) (max.)2 25SVPD10M 25 10 65 474 1500 0.10 50 10SVPD56M 10 56 45 538 1700 0.12 112 35SVPD8R2M 35 70 400 1300 0.10 57 25SVPD22M 25 22 48 580 1835 0.10 110 16SVPD82M 16 82 40 670 2120 0.12 262 35SVPD18M 35 18 60 550 1800 0.10 126 25SVPD39M 25 39 45 664 2100 0.10 195 35SVPD22M 35 22 50 700 2300 0.12 154 25SVPD47M 25 47 30 943 2980 0.12 235 25SVPD82M 25 82 28 1202 3800 0.12 410 E7 8.2 Specificationsfor eachseries C6 F8 E12 F12 1 2 3 Capacitance tolerance : M 20% After 2 minutes Tx : Ambient temperature Recommended land pattern dimension of PWB c (unit : mm) a b Size Code C6 E7 F8 E12 F12 a 2.1 2.8 4.3 2.8 4.3 b 9.1 11.1 13.1 11.1 13.1 c 1.6 1.9 1.9 1.9 1.9 Frequency coefficient for ripple current Frequency Coefficient 120Hz f 1kHz 0.05 1kHz f 10kHz 0.3 10kHz f 100kHz 0.7 100kHz f 500kHz 1 19 4. SPECIFICATIONS FOR EACH SERIES Conductive polymer type SVPC Series Large capacitance, low ESR Marking : Polarity( ), Rated voltage (Purple) PC(B6, C6), SVPC(E7, E12), Rated capacitance, Lot.No. Specifications Conditions Items Category temperature range Tolerance on rated capacitance Tangent of loss angle Leakage current 1 ESR Characteristics of impedance ratio at high temp. and low temp. Characteristics -55C to +105C M: -20% 120Hz Less than or equal to the value of Table5 120Hz Less than or equal to the value of Table5 After 2 minutes Less than or equal to the value of Table5 Z / Z 20C -55C 0.75 to 1.25 Based the value at +105C 0.75 to 1.25 Z / Z 20C 100KHz+20C C/C Within -20% tan 1.5 times or less than an initial standard 105C, 2,000h, Rated Endurance ESR 1.5 times or less than an initial standard voltage applied Leakage current Below an initial standard C/C Within -20% 60C, 90 to 95%RH, tan 1.5 times or less than an initial standard Damp heat (Steady state) 1,000h, ESR 1.5 times or less than an initial standard No-applied voltage Leakage current Below an initial standard (after voltage processing) Within -10% (-15% for 2.5V) C/C 1.3 times or less than an initial standard Resistance to tan 2 (VPS) (230C X 75s) 1.3 times or less than an initial standard soldering heat ESR Leakage current Below an initial standard (after voltage processing) 1 In case of some problems for measured values, measure after applying rated voltage for 120 minutes at 105C . 2 Refer to Page 54 for reflow soldering conditions. (unit : mm) Dimensions +0.1 Size Code D+0.5max. L W0.2 H0.2 C0.2 -0.4 0.2max. L B6 C6 E7 E12 F12 P C H W D Specificationsfor eachseries The SVPC series capacitor has larger capacitance than SVPA series. Adopt this series to reduce the size of equipment and circuits. This product can support lead free-reflow. (2). R Size List RV : Rated voltage (SV) : Surge (room temperature) RV SV F 39 68 100 120 150 180 220 270 330 390 560 680 820 1200 1500 2700 2.5 3.3 4 5.2 6.3 8.2 10.0 16.0 11.5 18.4 B6 B6 C6 B6 C6 E7 B6 B6 C6 E7 C6 C6 E7 E7,E12 E7 E12 E12 F12 E12 E12 E12 For the minimum packing quantity, please refer to page 53. 20 5.0 6.3 8.0 8.0 10.0 5.9 5.9 6.9 11.9 12.6 5.3 6.6 8.3 8.3 10.3 5.3 6.6 8.3 8.3 10.3 6.0 7.3 9.0 9.0 11.0 R P0.2 0.5 to 0.8 0.5 to 0.8 0.5 to 0.8 0.8 to 1.1 0.8 to 1.1 1.4 2.1 3.2 3.2 4.6 4. SPECIFICATIONS FOR EACH SERIES Table5 SVPC Series Characteristics List Size Code 100kHz 300kHz 3 Rated ripple current 100kHz (mArms) at 105C 16SVPC39M 16 39 35 30 1820 0.12 300 10SVPC68M 10 68 30 26 1970 0.12 300 Rated Voltage (V) Part Number 1 Rated Capacitance (F) ESR (m) (max.) Tangent of loss angle (max.) Leakage current (A) (max.)2 6.3 100 30 26 1970 0.12 300 6SVPC100MY 6.3 100 25 21 2150 0.12 300 4SVPC150M 4 150 30 26 1970 0.12 300 4SVPC150MY 4 150 23 20 2240 0.12 300 2R5SVPC180M 2.5 180 30 26 1970 0.12 300 2R5SVPC180MY 2.5 180 24 20 2200 0.12 300 Specificationsfor eachseries 6SVPC100M B6 C6 E7 E12 F12 1 2 3 16SVPC68M 16 68 30 26 2200 0.12 300 10SVPC120M 10 120 27 23 2320 0.12 300 6SVPC220M 6.3 220 27 23 2320 0.12 300 6SVPC220MV 6.3 220 15 13 3110 0.12 300 4SVPC330M 4 330 27 23 2320 0.12 300 4SVPC330MY 4 330 21 18 2630 0.12 300 2R5SVPC390M 2.5 390 25 22 2410 0.12 300 16SVPC120M 16 120 27 23 2900 0.12 500 10SVPC270M 10 270 22 19 3220 0.12 500 6SVPC390M 6.3 390 22 19 3220 0.12 491 4SVPC560M 4 560 22 19 3220 0.12 500 2R5SVPC680M 2.5 680 20 17 3370 0.12 500 6SVPC820M 6.3 820 12 10 4700 0.15 1033 4SVPC560MX 4 560 9 8 5380 0.15 500 4SVPC1200M 4 1200 12 10 4700 0.15 960 4SVPC1500M 4 1500 12 10 4700 0.15 1200 2R5SVPC820M 2.5 820 9 8 5380 0.15 500 2R5SVPC1500M 2.5 1500 10 9 5150 0.15 750 2R5SVPC2700M 2.5 2700 12 10 5080 0.15 1350 Capacitance tolerance : M 20% After 2 minutes The ESR value in 300kHz is a reference one. c Recommended land pattern dimension of PWB Size a b Code B6 C6 E7 E12 F12 (unit:mm) a 1.4 2.1 2.8 2.8 4.3 b 7.4 9.1 11.1 11.1 13.1 c 1.6 1.6 1.9 1.9 1.9 Frequency coefficient for ripple current Frequency Coefficient 120Hz f 1kHz 0.05 1kHz f 10kHz 0.3 10kHz f 100kHz 0.7 100kHz f 500kHz 1 21 4. SPECIFICATIONS FOR EACH SERIES Conductive polymer type SVPB Series Low profile Marking : Polarity( ), Rated voltage, (Purple) PB Rated capacitance, Lot.No. Specifications Items Category temperature range Tolerance on rated capacitance Tangent of loss angle Leakage current 1 ESR Characteristics of impedance ratio at high temp. and low temp. Conditions 120Hz 120Hz After 2 minutes Based the value at 100KHz+20C Endurance 105C, 1,000h, Rated voltage applied Damp heat (Steady state) 60C, 90 to 95% RH, 500h, No-applied voltage Resistance to soldering heat (VPS) (215C X 90s) 2 Characteristics -55C to +105C M :20% Less than or equal to the value of Table2 Less than or equal to the value of Table2 Less than or equal to the value of Table2 Z / Z 20C 0.75 to 1.25 -55C 0.75 to 1.25 Z / Z 20C +105C Within 20% (30% for C5 size) C/C 1.5 times or less than an initial standard tan 1.5 times or less than an initial standard ESR Leakage current Below an initial standard Within 20% C/C 1.5 times or less than an initial standard tan 1.5 times or less than an initial standard ESR Leakage current Below an initial standard (after voltage processing) Within 10% (20% for C5 size) C/C 1.3 times or less than an initial standard tan 1.3 times or less than an initial standard ESR Leakage current Below an initial standard (after voltage processing) 1 In case of some problems for measured values, measure after applying rated voltage for 120 minutes at 105C . 2 Refer to Page 54 for reflow soldering conditions. Dimensions 0.2max. (unit : mm) W L R Size List RV 2.5 SV 3.3 F 15 22 33 56 82 100 120 C5 C55 P C H Size Code D+0.5max. L D Specificationsfor eachseries This is a low profile series based on the SVPA series. Suitable for miniaturizing devices and circuits. This product can support lead free-reflow (2). 6.3 6.3 W0.2 H0.2 C0.2 6.6 6.6 6.6 6.6 7.3 7.3 4.9 5.4 RV : Rated voltage 4.0 6.3 5.2 8.2 (SV) : Surge (room temperature) 10.0 16.0 20.0 11.5 18.4 23.0 C5 C55 C5 C5 C5 C5 C5 For the minimum packing quantity, please refer to page 53. 22 +0.1 -0.4 R P0.2 0.5 to 0.8 0.5 to 0.8 2.1 2.1 4. SPECIFICATIONS FOR EACH SERIES Table2 SVPB Series Characteristics List Size Code Rated Voltage (V) Part Number 1 Rated Rated ESR Capacitance 100kHz to 300kHz ripple current 100kHz (mArms) (F) (m) (max.) at 105C Tangent of loss angle (max.) Leakage current (A) (max.)2 20 15 45 2000 0.12 120 16SVPB33M 16 33 40 1670 0.12 211 10SVPB56M 10 56 40 1670 0.12 224 82 40 1670 0.12 207 Specificationsfor eachseries 20SVPB15M C5 C55 1 2 6SVPB82M 6.3 4SVPB100M 4 100 40 1670 0.12 160 2R5SVPB120M 2.5 120 40 1670 0.12 120 22 35 2000 0.12 88 20SVPB22M 20 Capacitance tolerance : M 20% After 2 minutes The C5 size is also available upon request as a radial lead type. Please contact us if this type is required. Maximum height for radial lead types is 4.5 mm. The C55 size is also available upon request as 4V and 6.3V products. Recommended land pattern dimension of PWB c (unit : mm) a Size Code C5 C55 a 2.1 2.1 b 9.1 9.1 c 1.6 1.6 b Frequency coefficient for ripple current Frequency Coefficient 120Hz f 1kHz 0.05 1kHz f 10kHz 0.3 10kHz f 100kHz 0.7 100kHz f 500kHz 1 23 4. SPECIFICATIONS FOR EACH SERIES Conductive polymer type SVPA Low ESR, Large ripple current Series Marking : Polarity( ), Rated voltage (Purple) PA(B6, C6), SVPA(E7, F8), Rated capacitance, Lot.No. Specifications Items Category temperature range Tolerance on rated capacitance Tangent of loss angle Leakage current 1 ESR Characteristics of impedance ratio at high temp. and low temp. Characteristics -55C to +105C M : 20% 120Hz Less than or equal to the value of Table4 120Hz Less than or equal to the value of Table4 After 2 minutes Less than or equal to the value of Table4 Z / Z 20C 0.75 to 1.25 -55C Based the value at 0.75 to 1.25 Z / Z 20C +105C 100KHz+20C Within 20% C/C 1.5 times or less than an initial standard 105C, 2,000h, Rated tan Endurance 1.5 times or less than an initial standard voltage applied ESR Leakage current Below an initial standard Within 20% C/C 60C, 90 to 95%RH, 1.5 times or less than an initial standard tan Damp heat (Steady state) 1,000h, 1.5 times or less than an initial standard ESR No-applied voltage Leakage current Below an initial standard (after voltage processing) Within 10% C/C Resistance to 1.3 times or less than an initial standard tan 2 (VPS) (230C X 75s) soldering heat 1.3 times or less than an initial standard ESR Leakage current Below an initial standard (after voltage processing) Conditions 1 In case of some problems for measured values, measure after applying rated voltage for 120 minutes at 105C . 2 Refer to Page 54 for reflow soldering conditions. (unit : mm) Dimensions Size Code D+0.5max. L 0.2max. L Size List RV SV F 39 47 68 82 120 150 180 220 270 330 470 680 820 R RV : Rated voltage 2.5 4 3.3 5.2 B6 B6 C6 C6 B6 C6 E7 F8 P C H W D Specificationsfor eachseries This is a low ESR series based on the SVP series. Suitable for miniaturizing devices and circuits. This product can support lead free-reflow(2). (SV) : Surge (room temperature) 6.3 10 16 8.2 11.5 18.4 C6 B6 C6 E7 C6 E7 F8 E7 E7 F8 E7 F8 F8 F8 For the minimum packing quantity, please refer to page 53. 24 5.0 6.3 8.0 10.0 +0.1 W0.2 -0.4 H0.2 C0.2 R P0.2 5.3 6.6 8.3 10.3 5.3 6.6 8.3 10.3 6.0 7.3 9.0 11.0 0.5 to 0.8 0.5 to 0.8 0.5 to 0.8 0.5 to 0.8 1.4 2.1 3.2 4.6 5.9 5.9 6.9 7.9 4. SPECIFICATIONS FOR EACH SERIES Table4 SVPA Series Characteristics List Size Code B6 Rated Capacitance (F) 300kHz 3 Rated ripple current 100kHz (mArms) at 105C Tangent of loss angle (max.) Leakage current (A) (max.)2 100kHz 6SVPA47MAA 6.3 47 30 26 1970 0.12 300 4SVPA68MAA 4 68 30 26 1970 0.12 300 2R5SVPA82MAA 2.5 82 30 26 1970 0.12 300 ESR (m) (max.) 16SVPA39MAA 16 39 35 31 2040 0.12 300 16SVPA39MAAY 16 39 24 20 2460 0.12 300 10SVPA68MAA 10 68 30 26 2200 0.12 300 Specificationsfor eachseries Rated Voltage (V) Part Number 1 C6 E7 F8 1 2 3 6SVPA120MAA 6.3 120 22 19 2570 0.12 300 4SVPA150MAA 4 150 22 19 2570 0.12 300 2R5SVPA180MAA 2.5 180 20 18 2690 0.12 300 16SVPA82MAA 16 82 30 25 2760 0.12 262 10SVPA150MAA 10 150 30 25 2760 0.12 500 6SVPA220MAA 6.3 220 22 19 3220 0.12 500 4SVPA270MAA 4 270 22 19 3220 0.12 500 2R5SVPA330MAA 2.5 330 20 18 3370 0.12 500 16SVPA180M 16 180 29 28 3430 0.12 576 10SVPA330M 10 330 24 23 3770 0.12 660 6SVPA470M 6.3 470 20 19 4130 0.12 592 4SVPA680M 4 680 20 19 4130 0.12 544 2R5SVPA820M 2.5 820 19 18 4240 0.12 500 Capacitance tolerance : M 20% After 2 minutes The ESR value at 300kHz is a reference one. Recommended land pattern dimension of PWB c (unit : mm) a b Size Code B6 C6 E7 F8 a 1.4 2.1 2.8 4.3 b 7.4 9.1 11.1 13.1 c 1.6 1.6 1.9 1.9 Frequency coefficient for ripple current Frequency Coefficient 120Hz f 1kHz 0.05 1kHz f 10kHz 0.3 10kHz f 100kHz 0.7 100kHz f 500kHz 1 25 4. SPECIFICATIONS FOR EACH SERIES Conductive polymer type SVQP Series Guaranteed at 125C Marking : Polarity( ), Rated voltage (Purple) QP, Rated capacitance, Lot.No. Specifications Conditions Items Category temperature range Tolerance on rated capacitance Tangent of loss angle Leakage current 1 ESR Characteristics of impedance ratio at high temp. and low temp. Characteristics -55C to +125C M : 20% 120Hz Less than or equal to the value of Table8 120Hz Less than or equal to the value of Table8 After 2 minutes Less than or equal to the value of Table8 Z / Z 20C 0.75 to 1.25 -55C Based the value at 0.75 to 1.25 Z / Z 20C +125C 100KHz+20C Within 20% C/C 2 times or less than an initial standard tan 125C, 1,000h, Rated Endurance 2 times or less than an initial standard ESR voltage applied Leakage current Below an initial standard Within 20% C/C 60C, 90 to 95%RH, 1.5 times or less than an initial standard tan Damp heat (Steady state) 1,000h, 1.5 times or less than an initial standard ESR No-applied voltage Leakage current Below an initial standard (after voltage processing) C/C Within 10% Resistance to tan 1.3 times or less than an initial standard 2 (VPS) (230C X 75s) soldering heat ESR 1.3 times or less than an initial standard Leakage current Below an initial standard (after voltage processing) 1 In case of some problems for measured values, measure after applying rated voltage for 120 minutes at 125C . 2 Refer to Page 54 for reflow soldering conditions. Dimensions (unit : mm) 0.2max. W L Size List C6 E7 P C H +0.1 Size Code D+0.5max. L W0.2 -0.4 D Specificationsfor eachseries This series has advanced characteristics in resistance to heat compared with the SVP series. The SVQP series is best suited for devices that require enhanced reliability. Following advantages of the improved heatproof characteristics, the SVQP series does not need derating on maximum ripple current. However, the series guarantees allowable ripple current differently in the temperature from 105C to 125C and in the temperature range lower than 105C. This product can support lead free-reflow.(2). R 6.3 8.0 RV : Rated voltage (SV) : Surge (room temperature) 4 6.3 10 16 20 5.2 8.2 11.5 18.4 23 C6 RV SV F 22 39 C6 47 E7 56 C6 82 C6 100 C6 E7 E7 120 150 C6 E7 220 E7 E7 E7 For the minimum packing quantity, please refer to page 53. 26 5.9 6.9 6.6 8.3 H0.2 C0.2 R P0.2 6.6 8.3 7.3 9.0 0.5 to 0.8 0.5 to 0.8 2.1 3.2 4. SPECIFICATIONS FOR EACH SERIES Table8 SVQP Series Characteristics List Size Code Rated Voltage (V) Part Number 1 Rated ESR Capacitance 100kHz to 300kHz (m) (max.) (F) Rated ripple current Allowable ripple current 100kHz (mArms) 3 105Tx125 Tx105 Tangent of loss angle (max.) Leakage current (A) (max.)2 20 22 60 459 1450 0.10 220 16SVQP39M 16 39 50 512 1620 0.10 312 10SVQP56M 10 56 45 538 1700 0.12 280 Specificationsfor eachseries 20SVQP22M C6 E7 1 2 3 6SVQP82M 6.3 82 45 538 1700 0.12 258 6SVQP100M 6.3 100 40 572 1810 0.12 315 4SVQP150M 4 150 40 572 1810 0.12 300 20SVQP47M 20 47 45 598 1890 0.12 470 16SVQP82M 16 82 40 670 2120 0.12 656 10SVQP120M 10 120 35 810 2560 0.12 600 10SVQP150M 10 150 35 810 2560 0.12 750 6SVQP150M 6.3 150 35 810 2560 0.12 472 6SVQP220M 6.3 220 35 810 2560 0.12 693 4SVQP220M 4 220 35 810 2560 0.12 440 Capacitance tolerance : M 20% After 2 minutes Tx : Ambient temperature (unit : mm) Size Code C6 E7 a 2.1 2.8 b 9.1 11.1 c 1.6 1.9 c Recommended land pattern dimension of PWB a b Frequency coefficient for ripple current Frequency Coefficient 120Hz f 1kHz 0.05 1kHz f 10kHz 0.3 10kHz f 100kHz 0.7 100kHz f 500kHz 1 27 4. SPECIFICATIONS FOR EACH SERIES Conductive polymer type SVP Series Standard SMD type Marking : Polarity( ), Rated voltage, Lot.No. (Purple) SVP(Upper E7), Rated capacitance. Specifications Conditions Items Category temperature range Tolerance on rated capacitance Tangent of loss angle Leakage current 1 ESR Characteristics of impedance ratio at high temp. and low temp. Characteristics -55C to +105C M: 20% 120Hz Less than or equal to the value of Table7 120Hz After 2 minutes Less than or equal to the value of Table7 Less than or equal to the value of Table7 Based the value at Z / Z 20C 0.75 to 1.25 -55C 100KHz+20C 0.75 to 1.25 Z / Z 20C +105C C/C Within 20% 105C, 2,000h, Rated tan 1.5 times or less than an initial standard Endurance voltage applied ESR 1.5 times or less than an initial standard (25V20V applied) Leakage current Below an initial standard C/C Within 20% 60C, 90 to 95%RH, tan 1.5 times or less than an initial standard Damp heat (Steady state) 1,000h, ESR 1.5 times or less than an initial standard No-applied voltage Leakage current Below an initial standard (after voltage processing) Within 10% C/C Resistance to 1.3 times or less than an initial standard tan 2 (VPS) (230C X 75s) soldering heat 1.3 times or less than an initial standard ESR Leakage current Below an initial standard (after voltage processing) 1 In case of some problems for measured values, measure after applying rated voltage for 2.5 to 20V products or 20V for 25V products for 120 minutes at 105C . (unit : mm) 2 Refer to Page 54 for reflow soldering conditions. Dimensions Size Code D+0.5max. L 0.2max. A5 B6 C6 E7 F8 L E12 R F12 Size List RV : Rated voltage (SV) : Surge (room temperature) RV 2.5 4 6.3 10 16 20 25 SV F 3.35.28.211.5 18.4 23.0 25.0 A5 A5 A5 A5 A5 A5 A5 B6 B6 B6 B6 C6 C6 C6 C6 C6 C6,E7 E12 E7 E7,F8 E12 F8 4.3 5.3 6.6 8.3 10.3 8.3 10.3 C6 C6 E7 E12 a F12 b E7 E7 F8 E12 F8 F8,E12 F12 F8 F12 F12 F12 F12 For the minimum packing quantity, please refer to page 53. 28 C0.2 R P0.2 5.0 6.0 7.3 9.0 11.0 9.0 11.0 0.5 to 0.8 0.5 to 0.8 0.5 to 0.8 0.5 to 0.8 0.5 to 0.8 0.8 to 1.1 0.8 to 1.1 1.0 1.4 2.1 3.2 4.6 3.2 4.6 Recommended land pattern dimension of PWB C6 E7 E7,F8 F8 F8 F8,E12 F8,E12 F12 4.3 5.3 6.6 8.3 10.3 8.3 10.3 B6 E7 F8 F8 B6 E7 5.4 5.9 5.9 6.9 7.9 11.9 12.6 C6 B6 C6 4.0 5.0 6.3 8.0 10.0 8.0 10.0 +0.1 W0.2 H0.2 -0.4 c 3.3 4.7 6.8 10 15 22 27 33 39 47 56 68 82 100 120 150 180 220 270 330 470 560 680 820 1200 1500 P C H W D Specificationsfor eachseries Standard SMD type product Use for surface mounted type switching power supplies. The rated ripple current value is assured at 105C, so that it is not necessary to apply a temperature correction coefficient such as that defined for other series. This product can support lead free-reflow. (2). (unit:mm) Size Code A5 B6 C6 E7 F8 E12 F12 a 1.0 1.4 2.1 2.8 4.3 2.8 4.3 b 6.2 7.4 9.1 11.1 13.1 11.1 13.1 c 1.6 1.6 1.6 1.9 1.9 1.9 1.9 4. SPECIFICATIONS FOR EACH SERIES Table7 SVP Series Characteristics List Size Code B6 C6 E7 F8 E12 F12 1 2 16SVP3R3M 10SVP4R7M 10SVP6R8M 10SVP10M 10SVP15M 6SVP22M 4SVP33M 20SVP10M 16SVP15M 16SVP22M 10SVP33M 6SVP47M 4SVP39M 4SVP68M 25SVP6R8M 20SVP22M 20SVP27M 16SVP39M 10SVP47M 10SVP56M 6SVP82M 6SVP100M 6SVP120MV 4SVP150MX 2R5SVP220M 25SVP10M 20SVP33M 20SVP47M 16SVP56M 16SVP82M 10SVP120M 10SVP150MX 6SVP220MX 4SVP150M 4SVP330M 25SVP22M 20SVP56M 20SVP68M 16SVP100M 16SVP150M 16SVP180MX 10SVP150M 10SVP270M 10SVP330MX 6SVP220M 6SVP330M 6SVP470MX 4SVP680M 25SVP33M 20SVP100M 16SVP180M 10SVP330M 6SVP470M 4SVP560M 2R5SVP680M 25SVP56M 20SVP150M 16SVP330M 10SVP560M 6SVP820M 4SVP1200M 2R5SVP1500M Rated Voltage (V) 16 10 10 10 10 6.3 4 20 16 16 10 6.3 4 4 25 20 20 16 10 10 6.3 6.3 6.3 4 2.5 25 20 20 16 16 10 10 6.3 4 4 25 20 20 16 16 16 10 10 10 6.3 6.3 6.3 4 25 20 16 10 6.3 4 2.5 25 20 16 10 6.3 4 2.5 Rated Capacitance (F) Rated ESR 100kHz to 300kHz ripple current (m) (max.) (mArms) 3.3 4.7 6.8 10 15 22 33 10 15 22 33 47 39 68 6.8 22 27 39 47 56 82 100 120 150 220 10 33 47 56 82 120 150 220 150 330 22 56 68 100 150 180 150 270 330 220 330 470 680 33 100 180 330 470 560 680 56 150 330 560 820 1200 1500 260 240 240 220 200 200 200 120 120 90 70 70 70 60 80 60 60 50 50 45 45 40 17 40 23 60 45 45 45 40 35 35 35 35 35 50 40 40 35 30 30 30 25 25 25 25 25 25 30 24 20 17 15 13 13 28 20 16 13 12 12 12 660 670 670 700 740 740 740 1020 1020 1060 1100 1100 1100 1400 1200 1450 1450 1620 1620 1700 1700 1810 2780 1810 2390 1500 1890 1890 1890 2120 2560 2560 2560 2560 2560 2000 2400 2400 2670 3020 3020 3020 3700 3700 3700 3700 3700 3700 2980 3320 3640 3950 4210 4520 4520 3800 4320 4720 5230 5440 5440 5440 Tangent of loss angle (max.) 0.07 0.08 0.09 0.10 0.10 0.12 0.15 0.10 0.10 0.10 0.12 0.12 0.12 0.12 0.10 0.10 0.10 0.10 0.12 0.12 0.12 0.12 0.12 0.12 0.12 0.10 0.12 0.12 0.12 0.12 0.12 0.12 0.12 0.12 0.12 0.10 0.12 0.12 0.12 0.12 0.12 0.12 0.12 0.12 0.12 0.12 0.12 0.12 0.12 0.15 0.15 0.15 0.15 0.15 0.15 0.12 0.15 0.15 0.15 0.15 0.18 0.18 Leakage current (A) (max.)2 26.4 23.5 34.0 50.0 75.0 69.3 66.0 100 120 176 165 148 78 136 85 88 108 125 94 112 103 126 151 120 110 125 132 188 179 262 240 300 277 120 264 275 224 272 320 480 576 300 540 660 277 416 592 544 413 400 576 660 592 448 340 700 600 792 840 775 960 750 Specificationsfor eachseries A5 Part Number 1 Capacitance tolerance : M 20% After 2 minutes Frequency coefficient for ripple current Frequency Coefficient 120Hz f 1kHz 0.05 1kHz f 10kHz 0.3 10kHz f 100kHz 0.7 100kHz f 500kHz 1 29 4. SPECIFICATIONS FOR EACH SERIES Conductive polymer type SEPC Series Large capacitance, low ESR Marking (Purple) Specifications Items Category temperature range Tolerance on rated capacitance Tangent of loss angle Leakage current 1 ESR Characteristics of impedance ratio at high temp. and low temp. Conditions 120Hz 120Hz After 2 minutes Based the value at 100KHz+20C 105C, 2,000h, Rated voltage applied Endurance 60C, 90% RH, 1,000h, No-applied voltage Damp heat (Steady state) Resistance to soldering heat Flow method (2605C X 10s) : Polarity( ), Rated voltage, Rated Capacitance SANYO, OS-CON, Lot.No. SEPC. Characteristics -55C to +105C M : 20% Less than or equal to the value of Table3 Less than or equal to the value of Table3 Less than or equal to the value of Table3 Z / Z 20C 0.75 to 1.25 -55C 0.75 to 1.25 Z / Z 20C +105C C/C Within 20% tan 1.5 times or less than an initial standard ESR 1.5 times or less than an initial standard Leakage current Below an initial standard C/C Within 20% tan 1.5 times or less than an initial standard ESR 1.5 times or less than an initial standard Leakage current Below an initial standard (after voltage processing) C/C Within 5% tan Below an initial standard ESR Below an initial standard Leakage current Below an initial standard (after voltage processing) 1 In case of some problems for measured values, measure after applying rated voltage for 120 minutes at 105C . Dimensions E12.E13.F13 Size E9 Size d d L F F 15min. D D Specificationsfor eachseries This is an even lower ESR series based on our SEP series. Suitable for use with motherboards, servers, VGA, etc. Lead free-flow is supported. 15min. 4min. L 19min. 4min. 19min. E9 size flat rubber is used. Size List RV SV F 270 470 560 680 820 1500 2700 2.5 3.3 RV : Rated voltage (SV) : Surge (room temperature) 4.0 6.3 16.0 5.2 8.2 18.4 E9 E13 E9 E9 E13 E9 E13 E13 F13 E12 F13 F13 F13 F13 For the minimum packing quantity, please refer to page 51. 30 (unit : mm) Size Code D+0.5max. Lmax. F d0.05 E9 E12 E13 F13 8.0 8.0 8.0 10.0 9.0 12.0 13.0 13.0 3.50.5 3.50.5 3.50.5 5.00.5 0.6 0.6 0.6 0.6 4. SPECIFICATIONS FOR EACH SERIES Table3 SEPC Series Characteristics List Size Code Rated Voltage (V) Rated Capacitance (F) ESR 100kHz to 300kHz (m) (max.) Rated ripple current 100kHz (mArms) at 105C Tangent of loss angle (max.) 6SEPC470MX 6.3 470 8 5700 0.10 592 4SEPC560MX 4 560 7 6100 0.10 500 2SEPC560MX 2.5 560 8 4700 0.10 280 2SEPC820MX 2.5 820 7 6100 0.10 500 270 11 5000 0.10 864 Part Number 1 Leakage current (A) (max.)2 E12 16SEPC270M 16 6SEPC470M 6.3 470 8 5700 0.10 592 4SEPC560M 4 560 7 6100 0.10 500 4SEPC680M 4 680 7 6100 0.10 544 2R5SEPC820M 2.5 820 7 6100 0.10 500 470 10 6100 0.10 1504 Specificationsfor eachseries E9 E13 16SEPC470M F13 1 2 16 6SEPC680M 6.3 680 7 6640 0.10 857 6SEPC1500M 6.3 1500 10 5560 0.10 1890 4SEPC820M 4 820 7 6640 0.10 656 2SEPC2700M 2.5 2700 10 5560 0.10 1350 Capacitance tolerance : M 20% After 2 minutes Frequency coefficient for ripple current Frequency Coefficient 120Hz f 1kHz 0.05 1kHz f 10kHz 0.3 10kHz f 100kHz 0.7 100kHz f 500kHz 1 31 4. SPECIFICATIONS FOR EACH SERIES Conductive polymer type SEQP 125C guaranteed, 32V product Series Marking : Polarity( ), Rated voltage (Purple) SEQP, Rated capacitance, Lot.No. Specifications Items Category temperature range Tolerance on rated capacitance Tangent of loss angle Leakage current 1 ESR Characteristics of impedance ratio at high temp. and low temp. Conditions 120Hz 120Hz After 2 minutes Based the value at 100KHz+20C Endurance 125C, 1,000h, Rated voltage applied Damp heat (Steady state) 60C, 90 to 95% RH, 1,000h, No-applied voltage Resistance to soldering heat Flow method (2605C X 10s) Characteristics -55C to +125C M : 20% Less than or equal to the value of Table6 Less than or equal to the value of Table6 Less than or equal to the value of Table6 Z / Z 20C 0.75 to 1.25 -55C 0.75 to 1.25 Z / Z 20C +125C Within 20% C/C 2 times or less than an initial standard tan 2 times or less than an initial standard ESR Leakage current Below an initial standard Within 20% C/C 1.5 times or less than an initial standard tan 1.5 times or less than an initial standard ESR Leakage current Below an initial standard (after voltage processing) Within 5% C/C Below an initial standard tan Below an initial standard ESR Leakage current Below an initial standard (after voltage processing) 1 In case of some problems for measured values, measure after applying rated voltage for 120 minutes at 125C . Dimensions (unit : mm) d Size Code D+0.5max. Lmax. F d0.05 C6 E7 F8 E12 F13 6.3 8.0 10.0 8.0 10.0 6.0 7.0 8.0 12.0 13.0 2.50.5 3.50.5 5.00.5 3.50.5 5.00.5 0.45 0.45 0.50 0.60 0.60 F D Specificationsfor eachseries This series has advanced characteristics in resistance to heat compared with the SEP series, and adds a rated voltage of 32V. Suitable for use in increasing device reliability, 32V products may be used on 16 to 24V line industrial devices. Lead free-flow is supported. 15min. L 19min. Size List RV (SV) F 6.8 15 18 22 39 47 56 68 82 100 120 150 180 270 330 470 560 680 820 1200 4min. RV : Rated voltage 4.0 (5.2) 6.3 (8.4) 10 (11.5) (SV) : Surge (room temperature) 16 (18.4) 20 (23) E7 F8 E12 C6 C6 E7 C6 F8 E7 C6 E12 E7 C6 E7 E7 F8 E12 F8 E12 F8 E12 F13 F13 F13 E12 F8 F13 F13 For the minimum packing quantity, please refer to page 51. 32 32 (37) 4. SPECIFICATIONS FOR EACH SERIES Table6 SEQP Series Characteristics List Size Code Rated Voltage (V) Rated ripple current Allowable ripple current Tangent of Rated ESR Capacitance 100kHz to 300kHz loss angle 100kHz (mArms) 3 (F) (m) (max.) (max.) 105CTx125C Tx105C Leakage current (A) (max.)2 20SEQP22M 20 22 60 458 1450 0.10 220 16SEQP39M 16 39 50 512 1620 0.10 312 10SEQP56M 10 56 45 537 1700 0.12 280 82 45 537 1700 0.12 258 150 40 572 1810 0.12 300 100 440 1400 0.10 44 6SEQP82M 6.3 4SEQP150M 4 32SEQP6R8M 32 20SEQP47M 20 47 45 598 1890 0.12 470 16SEQP82M 16 82 40 670 2120 0.12 656 10SEQP120M 10 120 35 810 2560 0.12 600 6.8 Specificationsfor eachseries C6 Part Number 1 E7 6SEQP150M 6.3 150 35 810 2560 0.12 472 4SEQP330M 4 330 35 810 2560 0.12 660 32SEQP15M 32 15 80 560 1800 0.10 96 20SEQP68M 20 68 40 759 2400 0.12 272 16SEQP150M 16 150 30 955 3020 0.12 480 10SEQP270M 10 270 25 1170 3700 0.12 540 F8 E12 F13 1 2 3 6SEQP330M 6.3 330 25 1170 3700 0.12 416 4SEQP680M 4 680 25 1170 3700 0.12 544 32SEQP18M 32 18 50 790 2500 0.12 115 20SEQP100M 20 100 24 1050 3320 0.15 400 16SEQP180M 16 180 20 1151 3640 0.15 576 10SEQP330M 10 330 17 1250 3950 0.15 660 6SEQP470M 6.3 470 15 1332 4210 0.15 592 4SEQP560M 4 560 13 1430 4520 0.15 448 20SEQP150M 20 150 20 1367 4320 0.15 600 16SEQP330M 16 330 16 1493 4720 0.15 792 10SEQP560M 10 560 13 1655 5230 0.15 840 820 12 1721 5440 0.15 775 1200 12 1721 5440 0.18 960 6SEQP820M 6.3 4SEQP1200M 4 Capacitance tolerance : M 20% After 2 minutes Tx : Ambient temperature Frequency coefficient for ripple current Frequency Coefficient 120Hz f 1kHz 0.05 1kHz f 10kHz 0.3 10kHz f 100kHz 0.7 100kHz f 500kHz 1 33 4. SPECIFICATIONS FOR EACH SERIES Conductive polymer type SEP Series Standard radial lead type, Guaranteed at 105C for 3,000h Specifications Conditions Items Category temperature range Tolerance on rated capacitance Tangent of loss angle Leakage current 1 ESR Characteristics of impedance ratio at high temp. and low temp. 120Hz 120Hz After 2 minutes Based the value at 100KHz+20C 105C, 3,000h, Rated voltage applied (2.5V2,000h), (25V20V applied) Endurance 60C, 90 to 95%RH, 1,000h, No-applied voltage Damp heat (Steady state) Resistance to soldering heat Flow method (2605C X 10s) Marking : Polarity( ), Rated voltage, Rated capacitance (Purple) Lot.No., SEP Characteristics -55C to +105C M :20% Less than or equal to the value of Table9 Less than or equal to the value of Table9 Less than or equal to the value of Table9 Z / Z 20C 0.75 to 1.25 -55C 0.75 to 1.25 Z / Z 20C +105C C/C Within 20% tan 1.5 times or less than an initial standard ESR 1.5 times or less than an initial standard Leakage current Below an initial standard C/C Within 20% tan 1.5 times or less than an initial standard ESR 1.5 times or less than an initial standard Leakage current Below an initial standard (after voltage processing) C/C Within 5% tan Below an initial standard ESR Below an initial standard Leakage current Below an initial standard (after voltage processing) 1 In case of some problems for measured values, measure after applying rated voltage for 2.5 to 20V products or temperature derating voltage for 25V products for 120 minutes at 105C . Dimensions (unit : mm) d Size Code D+0.5max. F D Specificationsfor eachseries This is a radial lead type using conductive polymer based on the SVP series. Because of its improved heat-proof characteristics, the rated ripple current values are guaranteed at 105C. Furthermore, there is no need to apply a temperature-compensating coefficient. Lead free-flow is supported. 15min. L 4min. 19min. Size List RV SV F 6.8 10 22 33 39 47 56 68 82 100 120 150 180 220 270 330 470 560 680 820 1200 1500 2.5 3.3 4 5.2 Lmax. F d0.05 C6 6.3 6.0 0.45 E7 8.0 7.0 2.50.5 3.50.5 F8 10.0 8.0 5.00.5 0.50 E12 8.0 12.0 3.50.5 0.60 F13 10.0 13.0 5.00.5 0.60 RV : Rated voltage (SV) : Surge (room temperature) 6.3 10 16 20 25 8.2 11.5 18.4 23.0 25.0 C6 E7 C6 E7 F8 E12 C6 E7 F8 F8 C6 C6 E7 C6 F8,E12 E7 C6 E7 F8 E12 E7 E12 E7 F8 E12 F8 F8 E12 F8 E12 F13 F13 F13 F13 F13 For the minimum packing quantity, please refer to page 51. 34 F13 F13 0.45 4. SPECIFICATIONS FOR EACH SERIES Table9 SEP Series Characteristics List Size Code E7 F8 E12 Rated Voltage (V) 1 2 ESR 100kHz to 300kHz (m) (max.) Rated ripple current 100kHz (mArms) at 105C Tangent of loss angle (max.) Leakage current (A) (max.)2 25SEP6R8M 25 80 1200 0.10 170 20SEP22M 20 22 60 1450 0.10 220 16SEP39M 16 39 50 1620 0.10 312 10SEP56M 10 56 45 1700 0.12 280 82 45 1700 0.12 258 6.8 6SEP82M 6.3 4SEP100M 4 100 40 1810 0.12 200 4SEP150M 4 150 40 1810 0.12 300 25SEP10M 25 10 60 1500 0.10 250 20SEP33M 20 33 45 1890 0.12 330 20SEP47M 20 47 45 1890 0.12 470 16SEP82M 16 82 40 2120 0.12 656 10SEP120M 10 120 35 2560 0.12 600 6SEP150M 6.3 150 35 2560 0.12 472 4SEP220M 4 220 35 2560 0.12 440 4SEP330M 4 330 35 2560 0.12 660 25SEP22M 25 22 50 2000 0.10 275 20SEP56M 20 56 40 2400 0.12 224 20SEP68M 20 68 40 2400 0.12 272 20SEP100MX 20 100 35 2570 0.12 400 16SEP150M 16 150 30 3020 0.12 480 10SEP270M 10 270 25 3700 0.12 540 6SEP330M 6.3 330 25 3700 0.12 416 4SEP470M 4 470 25 3700 0.12 376 4SEP680M 4 680 25 3700 0.12 544 25SEP33M 25 33 30 2980 0.12 413 20SEP100M 20 100 24 3320 0.15 400 16SEP180M 16 180 20 3640 0.15 576 10SEP330M 10 330 17 3950 0.15 660 6.3 470 15 4210 0.15 592 4SEP560M 4 560 13 4520 0.15 448 2R5SEP680M 2.5 680 13 4520 0.15 340 6SEP470M F13 Rated Capacitance (F) 25SEP56M 25 56 28 3800 0.12 700 20SEP150M 20 150 20 4320 0.15 600 16SEP330M 16 330 16 4720 0.15 792 10SEP560M 10 560 13 5230 0.15 840 6SEP820M 6.3 820 12 5440 0.15 775 4SEP1200M 4 1200 12 5440 0.18 960 2R5SEP1500M 2.5 1500 12 5440 0.18 750 Specificationsfor eachseries C6 Part Number 1 Capacitance tolerance : M 20% After 2 minutes Frequency coefficient for ripple current Frequency Coefficient 120Hz f 1kHz 0.05 1kHz f 10kHz 0.3 10kHz f 100kHz 0.7 100kHz f 500kHz 1 35 4. SPECIFICATIONS FOR EACH SERIES SF Radial lead type. 5mm height (max.) Series Radial lead type. Series Low ESL and low ESR The SF series is low-profile, having a maximum height of 5mm. Use this series for smooth power supply of notebook PCs. The SPA series is a lower ESL and ESR based on the SP series. Use this series for motherboards, etc. Specifications Items Category temperature range Tolerance on rated capacitance Tangent of loss angle Leakage current 1 ESR Characteristics of impedance ratio at high temp. and low temp. Endurance Damp heat (Steady state) Resistance to soldering heat Common to SF series and SPA series Sleeve color : Purple Marking : Polarity( ), Rated voltage, Rated Capacitance (White) SANYO, OS-CON, Lot.No. Upper category temp.(105C) Conditions Characteristics -55C to +105C 120Hz M : 20% 120Hz Less than or equal to the value of SF : Table10, SPA : Table11 After 2 minutes Less than or equal to the value of SF : Table10, SPA : Table11 Less than or equal to the value of SF : Table10, SPA : Table11 Z / Z 20C Based the value at 0.75 to 1.25 -55C Z / Z 20C 100KHz+20C 0.75 to 1.25 +105C Within 20% C/C 105C, 2,000h, Rated 1.5 times or less than an initial standard tan voltage applied Below an initial standard Leakage current Within 20% for SF (10% for SPA) C/C 60C, 90 to 95%RH, 2 times or less than an initial standard tan No-applied voltage SF : 500h SPA : 1,000h Leakage current Below an initial standard Within 5% C/C Flow method 1.5 times or less than an initial standard tan (2605C X 10s) Leakage current Below an initial standard (after voltage processing) 1 In case of some problems for measured values, measure after applying rated voltage for 30 minutes at 105C . Size List Dimensions RV : Rated voltage (SV) : Surge (room temperature) SF series (unit : mm) Standards of terminal lead position Sleeve d F B' 15min. 8.0 4min. F 5.0 3.50.5 0.6 C RV (SV) F 150 220 F 4.0 (5.2) 6.3 (8.2) E1 E1 For the minimum packing quantity, please refer to page 51. A' 19min. d0.05 SF series A K D B L Size Code D+0.5max. Lmax. E1 G Mark ; ideal terminal lead position C; the middle point of A-A' SPA series d Size Code D+0.5max. Lmax. F B A 15min. 19min. 4min. C K F B' L A' G Mark ; ideal terminal lead position C; the middle point of A-A' 36 (unit : mm) Standards of terminal lead position Sleeve D Specificationsfor eachseries SPA F d0.05 9E 8.0 9F 10.0 10.0 5.00.5 0.6 10.0 3.50.5 0.6 SPA series F RV (SV) 560 820 4.0 (5.2) 9E 9F For the minimum packing quantity, please refer to page 51. 4. SPECIFICATIONS FOR EACH SERIES Table10 SF Series Characteristics List Size Code Rated Voltage (V) Rated Capacitance (F) 6SF150M 6.3 150 4SF220M 4 220 Part Number 1 Allowable ripple current (mArms)3 Tangent of loss angle (max.) Leakage current (A) (max.)2 32 2420 0.07 189 30 2510 0.07 176 Rated Capacitance (F) ESR 100kHz to 300kHz (m) (max.) Allowable ripple current (mArms)3 2 Tangent of loss angle (max.) Leakage current (A) (max.)2 ESR 100kHz to 300kHz (m) (max.) E1 Specificationsfor eachseries Capacitance tolerance : M 20% After 2 minutes 100kHz, +45C 1 2 3 Table11 SPA Series Characteristics List Size Code Part Number 1 Rated Voltage (V) 9E 4SPA560M 4 560 12 4080 0.08 224 9F 4SPA820M 4 820 11 5040 0.08 328 Capacitance tolerance : M 20% After 2 minutes 100kHz, +45C 1 2 3 ApproximateESLvalues (unit : nH) Size Code Model at 10MHz at 40MHz 9E 4SPA560M 2.6 2.4 E 4SP560M 4 3.8 9F 4SPA820M 3.6 3.4 4SP820M 5.3 5.1 F Approx.36%down Approx.33%down measuring positionroof of lead terminal All above values are not gurranteed, and there are some cases that the values differ in the measuring way. Please contact SANYO for detail. Temperature coefficient for allowable ripple current Ambient Temp. Coefficient Tx45C 1 45CTx65C 0.85 65CTx85C 0.7 85CTx95C 0.4 95CTx105C 0.25 Frequency coefficient for allowable ripple current Frequency Coefficient 120Hz f 1kHz 0.05 1kHz f 10kHz 0.2 10kHz f 100kHz 0.5 100kHz f 500kHz 1 37 4. SPECIFICATIONS FOR EACH SERIES SP Large Capacitance, Low ESR Optimum for Audio etc. Series Specificationsfor eachseries The characteristics of SP series are large capacitance (about 2 times of previous value) and low ESR (about half of previous value). It is optimum to use around MPU of computer equipment. Also, suitable for audio because OFC is used as the lead wires. Sleeve color : Purple Marking : Polarity( ), Rated voltage, Rated Capacitance (White) SANYO, OS-CON, Lot.No., Series name Upper category temp.(105C) Specifications Items Category temperature range Tolerance on rated capacitance Tangent of loss angle Leakage current 2 ESR Characteristics of impedance ratio at high temp. and low temp. Characteristics -55C to +105C 120Hz M : 20% 120Hz Less than or equal to the value of Table12 After 2 minutes Less than or equal to the value of Table12 Less than or equal to the value of Table12 Based the value at Z / Z 20C 0.75 to 1.25 -55C 100KHz+20C Z / Z 20C 0.75 to 1.25 +105C Within 20% C/C 105C, 1,000 to 2,000h 1.5 times or less than an initial standard tan Rated voltage Endurance 3 applied (25V20V applied) 1 Leakage current Below an initial standard Within 20% C/C 60C, 90 to 95%RH 2 times or less than an initial standard tan 1,000h, Damp heat (Steady state) No-applied voltage Below an initial standard Leakage current Within 5% C/C Flow method Resistance to 1.5 times or less than an initial standard tan (2605C X 10s) soldering heat Leakage current Below an initial standard (after voltage processing) 1 2 3 Conditions Please reduce 0.25V per 1C from over 85C for 25V products. In case of some problems for measured values, measure after applying rated voltage for 2 to 20V products or temperature derating voltage for 25V products for 30 minutes at 105C . C', E', F', C, D size : 1,000h. E, F, F0, G size : 2,000h. (2V, 25V, 4SP1000M, 2R5SP1200M : 1,000h) (unit : mm) Dimensions Size Code D0.5max. Lmax. C' 6.0 6.3 6.0 8.0 E' 6.0 10.0 F' C 7.8 6.3 10.8 6.3 D E 11.5 8.0 F 11.5 10.0 21.0 10.0 F0 G 23.0 12.5 Standards of terminal lead position Sleeve F A B' 15min. L 4min. K F D B C A' 19min. G Mark ; ideal terminal lead position C; the middle point of A-A' Size List F RV (SV) 6.8 10 18 22 33 47 56 68 82 100 120 150 180 220 270 330 390 470 560 680 820 1000 1200 1500 1800 2200 F d0.05 Gmax. 0.5 0.60 2.50.5 0.8 0.60 3.50.5 0.8 0.60 5.00.5 0.5 0.60 2.50.5 0.5 0.60 2.50.5 0.8 0.60 3.50.5 0.8 0.60 5.00.5 0.8 0.80 5.00.5 0.8 0.80 5.01.0 RV : Rated voltage (SV) : Surge (room temperature) 2 (2.6) 2.5 (3.3) 4 (5.2) 6.3 (8.2) 10 (11.5) 16 (18.4) 20 (23.0) C' C C' C E' E' F',D C' C' C E' C' C E' D F' C E' E E F F',D F F F F F F',D E E F F0 F0 G For the minimum packing quantity, please refer to page 51. 38 E F D F' E 25 (25.0) C' C D F Kmax. 0.5 0.8 0.8 0.5 0.5 0.8 0.8 0.8 0.8 4. SPECIFICATIONS FOR EACH SERIES Table12 SP Series Characteristics List Size Code E' F' C Rated Voltage (V) 25SP6R8M 25 20SP22M 20 16SP33M 16 10SP56M 10 Rated Capacitance (F) Allowable ESR 100kHz to 300kHz ripple current (m) (max.) (mArms) 3 6.8 Tangent of loss angle (max.) Leakage current (A) (max.)2 60 1510 0.06 17.00 22 50 1580 0.06 44.00 33 50 1580 0.06 52.80 56 45 1710 0.06 56.00 68 40 1850 0.06 42.84 6SP68M 6.3 4SP100M 4 100 40 1850 0.06 40.00 20SP47M 20 47 36 2210 0.07 94.00 16SP68M 16 68 34 2280 0.07 108.80 10SP100M 10 100 32 2350 0.07 100.00 94.50 6SP150M 6.3 150 30 2420 0.07 4SP220M 4 220 28 2510 0.07 88.00 20SP68M 20 68 34 2800 0.07 136.00 16SP100M 16 100 32 2890 0.07 160.00 10SP180M 10 180 29 2990 0.07 180.00 6SP220M 6.3 220 28 3100 0.07 138.60 4SP330M 4 330 24 3230 0.07 132.00 25SP10M 25 10 55 1560 0.07 25.00 20SP33M 20 33 45 1710 0.07 66.00 16SP47M 16 47 45 1710 0.07 75.20 10SP82M 10 82 40 1850 0.07 82.00 6SP120M 6.3 120 35 1930 0.07 75.60 4SP150M 4 150 35 1930 0.07 60.00 25SPS18M 25 18 40 2230 0.08 45.00 20SPS68M 20 68 30 2580 0.08 136.00 D 16SPS100M 16 100 25 2820 0.08 160.00 10SPS150M 10 150 25 2820 0.08 150.00 E 6SPS220M 6.3 220 20 3160 0.08 138.60 4SPS270M 4 270 20 3160 0.08 108.00 25SP33M 25 33 30 2780 0.08 82.50 20SP120M 20 120 24 3110 0.08 240.00 16SP180M 16 180 20 3410 0.08 288.00 10SP270M 10 270 18 3600 0.08 270.00 6.3 390 16 3810 0.08 245.70 4SP560M 4 560 14 4080 0.08 224.00 25SP56M 25 56 25 3260 0.08 140.00 20SP180M 20 180 20 4280 0.08 360.00 16SP270M 16 270 18 4400 0.08 432.00 10SP470M 10 470 15 4510 0.08 470.00 680 13 4840 0.08 428.40 6SP390M F F0 G 6SP680M 6.3 4SP820M 4 820 12 5040 0.08 328.00 4SP1000M 4 1000 12 5040 0.08 400.00 2R5SP1200M 2.5 1200 12 5040 0.08 450.00 2SP1000M 2 1000 11 5260 0.08 400.00 4SP1500M 4 1500 8 6500 0.10 600.00 2SP1800M 2 1800 8 6500 0.10 720.00 4SP2200M 4 2200 9 7100 0.12 880.00 1 Tolerance on rated capacitance : M 20% 2 After 2 minutes 3 100kHz, +45C 4 D size is SPS series. Temperature coefficient for allowable ripple current Ambient Temp. Tx45C 45CTx65C 65CTx85C 85CTx95C 0.85 0.7 0.4 Coefficient 1 Frequency coefficient for allowable ripple current Frequency 120Hz f 1kHz 1kHz f 10kHz Coefficient 0.05 0.2 10kHz f 100kHz 0.5 Specificationsfor eachseries C' Part Number 1 95CTx105C 0.25 100kHz f 500kHz 1 39 4. SPECIFICATIONS FOR EACH SERIES SC Series Standard Products Sleeve color : Purple Marking : Polarity( ), Rated voltage, Rated Capacitance (White) SANYO, OS-CON, Lot.No. Upper category temp.(105C) Specifications Items Category temperature range Tolerance on rated capacitance Tangent of loss angle Leakage current 2 ESR Characteristics of impedance ratio at high temp. and low temp. Conditions Characteristics -55C to +105C 120Hz M : 20% 120Hz Less than or equal to the value of Table13 After 2 minutes Less than or equal to the value of Table13 Less than or equal to the value of Table13 Based the value at Z / Z 20C 0.75 to 1.25 -55C 100KHz+20C Z / Z 20C 0.75 to 1.25 +105C Within 20% C/C 105C, 2,000h, Rated 1.5 times or less than an initial standard tan voltage applied (25V20V applied) 1 Leakage current Below an initial standard Within 10% C/C 60C, 90 to 95%RH, 1.5 times or less than an initial standard tan 1,000h, No-applied voltage Below an initial standard Leakage current Within 5% C/C Flow method Below an initial standard tan (2605C X 10s) Leakage current Below an initial standard (after voltage processing) Endurance Damp heat (Steady state) Resistance to soldering heat 1 Please reduce 0.25V per 1C from over 85C for 25V products. 2 In case of some problems for measured values, measure after applying rated voltage for 6.3 to 16 and 30V products or temperature derating voltage for 25V products for 30 minutes at 105C. Dimensions (unit : mm) Standards of terminal lead position Sleeve d F Size Code D0.5max. Lmax. F d0.05 Gmax. Kmax. A 4.0 7.8 2.00.5 0.45 0.5 0.5 B 5.0 7.8 2.00.5 0.45 0.5 0.5 C 6.3 7.8 2.50.5 0.45 0.5 0.5 D E 6.3 10.8 2.50.5 0.60 0.5 0.5 8.0 11.5 3.50.5 0.60 0.8 0.8 F 10.0 11.5 5.00.5 0.60 0.8 0.8 B A B' 15min. L 4min. C K F D Specificationsfor eachseries Suitable for noise limiters and switching power supplies that make a point of high frequency characteristics. Also, make use of it when needed long life span and high reliability. A' 19min. G Mark ; ideal terminal lead position C; the middle point of A-A' Size List RV (SV) F 1.0 1.5 2.2 3.3 4.7 6.8 10 15 22 33 47 RV : Rated voltage (SV) : Surge (room temperature) 6.3 (7.2) 10 (11.5) A A 16 (18.4) A A B B B B C C D C D D 25 (25.0) 30 (34.5) A A B B C C C D E F F A B B C D D E F For the minimum packing quantity, please refer to page 51. 40 4. SPECIFICATIONS FOR EACH SERIES Table13 SC Series Characteristics List Size Code B C E F 1 2 3 Rated Capacitance (F) ESR 100kHz to 300kHz (m) (max.) Allowable ripple current (mArms) 3 Tangent of loss angle (max.) Leakage current (A) (max.)2 30SC1M 30 1.0 350 430 0.03 1.00 25SC1M 25 1.0 350 430 0.03 0.50 25SC1R5M 25 1.5 300 435 0.03 0.50 16SC2R2M 16 2.2 280 450 0.04 0.50 16SC3R3M 16 3.3 280 500 0.04 0.53 10SC4R7M 10 4.7 280 540 0.05 0.50 6SC6R8M 6.3 6.8 250 560 0.05 0.50 30SC1R5M 30 1.5 300 435 0.03 1.00 30SC2R2M 30 2.2 250 695 0.03 1.32 25SC2R2M 25 2.2 200 695 0.03 0.55 25SC3R3M 25 3.3 200 700 0.03 0.83 16SC4R7M 16 4.7 180 720 0.04 0.75 16SC6R8M 16 6.8 150 745 0.04 1.09 10SC10M 10 10 150 780 0.05 1.00 6SC15M 6.3 15 120 815 0.05 0.95 30SC3R3M 30 3.3 200 820 0.03 1.98 25SC4R7M 25 4.7 100 1130 0.03 1.18 25SC6R8M 25 6.8 100 1140 0.03 1.70 25SC10M 25 10 90 1150 0.03 2.50 16SC15M 16 15 90 1230 0.04 2.40 10SC22M 10 22 70 1270 0.05 2.20 33 70 1320 0.05 2.08 4.7 120 1300 0.04 2.82 6.8 6SC33M D Rated Voltage (V) 6.3 30SC4R7M 30 30SC6R8M 30 120 1340 0.04 4.08 25SC15M 25 15 70 1650 0.04 3.75 16SC22M 16 22 70 1800 0.05 3.52 16SC33M 16 33 70 1900 0.06 5.28 10SC47M 10 47 60 2020 0.06 4.70 30SC10M 30 10 110 1380 0.06 6.00 25SC22M 25 22 40 2330 0.06 5.50 30SC22M 30 22 80 1830 0.06 13.20 25SC33M 25 33 35 2900 0.06 8.25 25SC47M 25 47 35 2980 0.06 11.75 Specificationsfor eachseries A Part Number 1 Tolerance on rated capacitance : M 20%, Product "K" (Tolerance on rated capacitance : 10%) is optionally available. After 2 minutes 100kHz, +45C Temperature coefficient for allowable ripple current Ambient Temp. Coefficient Tx45C 1 45CTx65C 0.85 65CTx85C 0.7 85CTx95C 0.4 95CTx105C 0.25 Frequency coefficient for allowable ripple current Frequency Coefficient 120Hz f 1kHz 0.05 1kHz f 10kHz 0.2 10kHz f 100kHz 0.5 100kHz f 500kHz 1 41 4. SPECIFICATIONS FOR EACH SERIES SA Large capacitance and miniaturized products Series Sleeve color : Purple Marking : Polarity( ), Rated voltage, Rated Capacitance (White) SANYO, OS-CON, Lot.No. Upper category temp.(105C) Specifications Items Category temperature range Tolerance on rated capacitance Tangent of loss angle Leakage current 1 ESR Characteristics of impedance ratio at high temp. and low temp. Endurance Damp heat (Steady state) Resistance to soldering heat Conditions Characteristics -55C to +105C 120Hz M : 20% 120Hz Less than or equal to the value of Table14 Less than or equal to the value of Table14 After 2 minutes Less than or equal to the value of Table14 Z / Z 20C Based the value at 0.75 to 1.25 -55C Z / Z 20C 100KHz+20C 0.75 to 1.25 +105C Within 20% C/C 105C, 2,000h, Rated 1.5 times or less than an initial standard tan voltage applied Below an initial standard Leakage current Within 10% C/C 60C, 90 to 95%RH, 1.5 times or less than an initial standard tan 1,000h, No-applied voltage Below an initial standard Leakage current Within 5% C/C Flow method Below an initial standard tan (2605C X 10s) Leakage current Below an initial standard (after voltage processing) 1 In case of some problems for measured values, measure after applying rated voltage for 30 minutes at 105C. Dimensions (unit : mm) Standards of terminal lead position Sleeve d Size Code D0.5max. Lmax. F F d0.05 Gmax. Kmax. C 6.3 7.8 2.50.5 0.45 0.5 0.5 D 6.3 10.8 2.50.5 0.60 0.5 0.5 E 8.0 11.5 3.50.5 0.60 0.8 0.8 A' F 10.0 11.5 5.00.5 0.60 0.8 0.8 G G 12.5 23.0 5.01.0 0.80 0.8 0.8 H 16.0 26.0 7.51.0 0.80 0.8 0.8 B A B' 15min. L 4min. 19min. C K F D Specificationsfor eachseries SA series is miniaturized SC series with large capacitance. Suitable for high frequency switching power supplies, etc. Mark ; ideal terminal lead position C; the middle point of A-A' Size List RV (SV) F 15 22 33 47 68 100 150 220 330 470 1000 2200 6.3 (7.2) C E RV : Rated voltage (SV) : Surge (room temperature) 10 16 20 (11.5) (18.4) (23.0) C C C D D E D E E F F F F G H H For the minimum packing quantity, please refer to page 51. 42 4. SPECIFICATIONS FOR EACH SERIES Table14 SA Series Characteristics List Size Code Part Number 1 Rated Voltage (V) Rated Capacitance (F) ESR 100kHz to 300kHz (m) (max.) Allowable ripple current (mArms) 3 Tangent of loss angle (max.) Leakage current (A) (max.)2 20SA15M 20 15 90 1200 0.06 6.00 20SA22M 20 22 70 1300 0.06 8.80 16SA33M 16 33 70 1370 0.06 10.56 C 60 1430 0.07 5.92 20 33 70 1710 0.06 13.20 16SA47M 16 47 60 1830 0.06 15.04 10SA68M 10 68 50 2000 0.07 13.60 20SA47M 20 47 40 2450 0.06 18.80 20SA68M 20 68 36 2600 0.06 27.20 16SA100M 16 100 30 2740 0.06 32.00 150 30 2780 0.07 18.90 6.3 D E 6.3 6SA150M 20SA100M 20 100 30 3210 0.06 40.00 16SA150M 16 150 28 3260 0.06 48.00 10SA220M 10 220 27 3370 0.07 44.00 330 25 3500 0.07 41.58 Specificationsfor eachseries 47 20SA33M 6SA47M F 6.3 6SA330M G 16SA470M 16 470 20 6080 0.08 300.80 16SA1000M 16 1000 15 9750 0.09 640.00 2200 15 9750 0.13 554.40 H 6.3 6SA2200M 1 2 3 Tolerance on rated capacitance : M 20%, Product "K" (Tolerance on rated capacitance : 10%) is optionally available. However, the exception regarding G and H size. After 2 minutes 100kHz, +45C Temperature coefficient for allowable ripple current Ambient Temp. Coefficient Tx45C 1 45CTx65C 0.85 65CTx85C 0.7 85CTx95C 0.4 95CTx105C 0.25 Frequency coefficient for allowable ripple current Frequency Coefficient 120Hz f 1kHz 0.05 1kHz f 10kHz 0.2 10kHz f 100kHz 0.5 100kHz f 500kHz 1 43 4. SPECIFICATIONS FOR EACH SERIES SL Series Low-profile products. Sleeve color : Purple Marking : Polarity( ), Rated voltage, Rated Capacitance (White) SANYO, OS-CON, Lot.No. Upper category temp.(105C) Specifications Items Category temperature range Tolerance on rated capacitance Tangent of loss angle Leakage current 2 ESR Characteristics of impedance ratio at high temp. and low temp. Endurance Damp heat (Steady state) Resistance to soldering heat Conditions Characteristics -55C to +105C 120Hz M : 20% 120Hz Less than or equal to the value of Table15 After 2 minutes Less than or equal to the value of Table15 Less than or equal to the value of Table15 Based the value at Z / Z 20C 0.75 to 1.25 -55C 100KHz+20C Z / Z 20C 0.75 to 1.25 +105C Within 20% C/C 105C, 2,000h, Rated 1.5 times or less than an initial standard tan voltage applied (E', F' size ; 1,000h) (25V20V applied) 1 Leakage current Below an initial standard Within 20% C/C 60C, 90 to 95%RH 2 times or less than an initial standard tan 1,000h, No-applied voltage Below an initial standard Leakage current Within 5% C/C Flow method 1.5 times or less than an initial standard tan (2605C X 10s) Leakage current Below an initial standard (after voltage processing) 1 Please reduce 0.25V per 1C from over 85C for 25V products. 2 In case of some problems for measured values, measure after applying rated voltage for 4 to 16V products or temperature derating voltage for 25V products for 30 minutes at 105C. Dimensions (unit : mm) Standards of terminal lead position Sleeve d F B A B' 15min. L 4min. C K F D Specificationsfor eachseries The SL series is low profile with a category upper limit temperature of 105C. Use the SL series for compact and slim designs, such as VTRs, video cameras, car stereos, etc. A' 19min. G Size Code D0.5max. Lmax. F RV (SV) 6.3 (7.2) 10 (11.5) 1.0 1.5 2.2 3.3 4.7 6.8 A' 10 15 B' 22 33 47 68 100 E' 150 F' E' 220 F' For the minimum packing quantity, please 44 A' B' C' C' C' E' F' Gmax. Kmax. 4.0 6.0 1.50.5 0.45 0.5 0.5 B' 5.0 6.0 2.00.5 0.45 0.5 0.5 C' 6.3 6.0 2.50.5 0.45 0.5 0.5 E' 8.0 6.0 3.50.5 0.50 0.8 0.8 F' 10.0 6.0 5.00.5 0.50 0.8 0.8 RV : Rated voltage (SV) : Surge (room temperature) 4 (4.6) d0.05 A' Mark ; ideal terminal lead position C; the middle point of A-A' Size List F 16 (18.4) A' A' B' B' C' C' E' F' refer to page 51. 25 (25.0) A' A' B' B' C' C' E' F' 4. SPECIFICATIONS FOR EACH SERIES Table15 SL Series Characteristics List Size Code Rated Voltage (V) Rated Capacitance (F) ESR 100kHz to 300kHz (m) (max.) 25SL1 25 1 450 430 0.05 0.50 25SL1R5 25 1.5 400 435 0.05 0.75 16SL22 16 2.2 400 450 0.05 0.70 16SL33 16 3.3 400 500 0.06 1.06 10SL47 10 4.7 400 540 0.06 0.94 6.8 350 560 0.06 0.86 Part Number 1 Allowable ripple current (mArms) 3 Tangent of loss angle (max.) Leakage current (A) (max.)2 Specificationsfor eachseries A' 6.3 6SL68 25SL22 25 2.2 250 695 0.05 1.10 25SL33 25 3.3 250 700 0.05 1.65 16SL47 16 4.7 250 720 0.05 1.50 16SL68 16 6.8 180 745 0.05 2.18 10SL10 10 10 150 780 0.05 2.00 15 120 815 0.06 1.89 B' 6.3 6SL15 C' E' F' 1 2 3 25SL47 25 4.7 100 1130 0.06 2.35 25SL68 25 6.8 100 1140 0.06 3.40 16SL10 16 10 100 1150 0.06 3.20 16SL15 16 15 100 1230 0.06 4.80 10SL22 10 22 80 1270 0.06 4.40 10SL33 10 33 80 1350 0.06 6.60 10SL47 10 47 70 1430 0.06 9.40 25SL15M 25 15 75 1400 0.07 7.50 16SL47M 16 47 70 1550 0.07 15.04 10SL68M 10 68 65 1600 0.07 13.60 6SL100M 6.3 100 65 1600 0.07 12.60 4SL150M 4 150 60 2000 0.07 12.00 25SL22M 25 22 70 1600 0.07 11.00 16SL68M 16 68 65 1850 0.07 21.76 10SL100M 10 100 60 2100 0.07 20.00 6SL150M 6.3 150 60 2100 0.07 18.90 4SL220M 4 220 55 2400 0.07 17.60 Tolerance on rated capacitance : M 20%, Product "K" (Tolerance on rated capacitance : 10%) is optionally available except for E' and F' size. After 2 minutes 100kHz, +45C Temperature coefficient for allowable ripple current Ambient Temp. Coefficient Tx45C 1 45CTx65C 0.85 65CTx85C 0.7 85CTx95C 0.4 95CTx105C 0.25 Frequency coefficient for allowable ripple current Frequency Coefficient 120Hz f 1kHz 0.05 1kHz f 10kHz 0.2 10kHz f 100kHz 0.5 100kHz f 500kHz 1 45 4. SPECIFICATIONS FOR EACH SERIES SH Series Long Life (105C X 5,000h) Sleeve color : Purple Marking : Polarity( ), Rated voltage, Rated Capacitance (White) SANYO, OS-CON, Lot.No., Series name Upper category temp.(105C) Specifications Items Category temperature range Tolerance on rated capacitance Tangent of loss angle Leakage current 2 ESR Characteristics of impedance ratio at high temp. and low temp. Endurance Damp heat (Steady state) Resistance to soldering heat Conditions Characteristics -55C to +105C 120Hz M : 20% 120Hz Less than or equal to the value of Table16 After 2 minutes Less than or equal to the value of Table16 Less than or equal to the value of Table16 Based the value at Z / Z 20C 0.75 to 1.25 -55C 100KHz+20C Z / Z 20C 0.75 to 1.25 +105C Within 30% C/C 105C, 5,000h, Rated 1.5 times or less than an initial standard tan voltage applied (25V20V applied) 1 Leakage current 5 times or less than an initial standard Within 10% C/C 60C, 90 to 95%RH 1.5 times or less than an initial standard tan 1,000h, No-applied voltage Below an initial standard Leakage current Within 5% C/C Flow method Below an initial standard tan (2605C X 10s) Leakage current Below an initial standard (after voltage processing) 1 Please reduce 0.25V per 1C from over 85C for 25V products. 2 In case of some problems for measured values, measure after applying rated voltage for 6.3 to 20V products or temperature derating voltage for 25V products for 30 minutes at 105C . Dimensions (unit : mm) Standards of terminal lead position Sleeve d F B A B' 15min. L 4min. C K F D Specificationsfor eachseries SH series has a long life (guaranteed at 105C for 5,000h) with keeping high frequency characteristics. Suitable for industrial equipment which needed high reliability. A' 19min. G Mark ; ideal terminal lead position C; the middle point of A-A' Size List F RV (SV) 1.0 1.5 2.2 3.3 4.7 6.8 10 15 22 33 47 68 100 150 220 330 For the minimum 46 6.3 (7.2) 10 (11.5) A A Size Code D0.5max. Lmax. D E E F Kmax. 4.0 7.8 2.00.5 0.45 0.5 0.5 5.0 7.8 2.00.5 0.45 0.5 0.5 C 6.3 7.8 2.50.5 0.45 0.5 0.5 D E 6.3 10.8 2.50.5 0.60 0.5 0.5 8.0 11.5 3.50.5 0.60 0.8 0.8 F 10.0 11.5 5.00.5 0.60 0.8 0.8 A A B B C D Gmax. B B C d0.05 A RV : Rated voltage (SV) : Surge (room temperature) 16 20 25 (18.4) (23.0) (25.0) B F C C D E E F F F packing quantity, please refer to page 51. A A B B C C C D 4. SPECIFICATIONS FOR EACH SERIES Table16 SH Series Characteristics List Size Code 1 Rated Voltage (V) C D E F 1 2 3 ESR 100kHz to 300kHz (m) (max.) Allowable ripple current (mArms)3 Tangent of loss angle (max.) Leakage current (A) (max.)2 25SH1M 25 1.0 350 430 0.03 0.50 25SH1R5M 25 1.5 300 435 0.03 0.75 16SH2R2M 16 2.2 280 450 0.04 0.70 16SH3R3M 16 3.3 280 500 0.04 1.06 10SH4R7M 10 4.7 280 540 0.05 0.94 6.8 250 560 0.05 0.86 6.3 6SH6R8M B Rated Capacitance (F) 25SH2R2M 25 2.2 200 695 0.03 1.10 25SH3R3M 25 3.3 200 700 0.03 1.65 16SH4R7M 16 4.7 180 720 0.04 1.50 16SH6R8M 16 6.8 150 745 0.04 2.18 10SH10M 10 10 150 780 0.05 2.00 6SH15M 6.3 15 120 815 0.05 1.89 25SH4R7M 25 4.7 100 1130 0.03 2.35 25SH6R8M 25 6.8 100 1140 0.03 3.40 25SH10M 25 10 90 1150 0.03 5.00 20SH15M 20 15 90 1200 0.05 6.00 20SH22M 20 22 70 1300 0.05 8.80 16SH33M 16 33 70 1370 0.06 10.56 6SH47M 6.3 47 60 1430 0.07 5.92 25SH15M 25 15 70 1650 0.04 7.50 20SH33M 20 33 70 1710 0.06 13.20 16SH47M 16 47 60 1830 0.06 15.04 10SH68M 10 68 50 2000 0.07 13.60 20SH47M 20 47 40 2450 0.06 18.80 20SH68M 20 68 36 2600 0.06 27.20 16SH100M 16 100 30 2740 0.06 32.00 6SH150M 6.3 150 30 2780 0.07 18.90 20SH100M 20 100 30 3210 0.06 40.00 16SH150M 16 150 28 3260 0.06 48.00 10SH220M 10 220 27 3370 0.07 44.00 6SH330M 6.3 330 25 3500 0.07 41.58 Specificationsfor eachseries A Part Number Tolerance on rated capacitance : M 20%, Product "K" (Tolerance on rated capacitance : 10%) is optionally available. After 2 minutes 100kHz, +45C Temperature coefficient for allowable ripple current Ambient Temp. Coefficient Tx45C 1 45CTx65C 0.85 65CTx85C 0.7 85CTx95C 0.4 95CTx105C 0.25 Frequency coefficient for allowable ripple current Frequency Coefficient 120Hz f 1kHz 0.05 1kHz f 10kHz 0.2 10kHz f 100kHz 0.5 100kHz f 500kHz 1 47 4. SPECIFICATIONS FOR EACH SERIES SS Miniaturized Products of SC, SA and SL series Series Sleeve color : Purple Marking : Polarity( ), Rated voltage, Rated Capacitance (White) SANYO, OS-CON, Lot.No., Series name Upper category temp.(105C) Specifications Items Category temperature range Tolerance on rated capacitance Tangent of loss angle Leakage current 1 ESR Characteristics of impedance ratio at high temp. and low temp. Endurance Damp heat (Steady state) Conditions 120Hz 120Hz After 2 minutes Based the value at 100KHz+20C 105C, 1,000h, Rated voltage applied (E, F size : 2,000h) 60C, 90 to 95%RH 1,000h, No-applied voltage Flow method (2605C X 10s) Resistance to soldering heat Characteristics -55C to +105C M : 20% Less than or equal to the value of Table17 Less than or equal to the value of Table17 Less than or equal to the value of Table17 Z / Z 20C 0.75 to 1.25 -55C Z / Z 20C 0.75 to 1.25 +105C Within 20% C/C 1.5 times or less than an initial standard tan Below an initial standard Leakage current Within 20% C/C 2 times or less than an initial standard tan Below an initial standard Leakage current Within 5% C/C 1.5 times or less than an initial standard tan Leakage current Below an initial standard (after voltage processing) 1 In case of some problems for measured values, measure after applying rated voltage for 30 minutes at 105C . Dimensions (unit : mm) Standards of terminal lead position Sleeve d F B A B' 15min. L 4min. C K F D Specificationsfor eachseries SS series is a miniaturized version of SC, SA and SL series. Suitable for switching power supplies, etc. to make more compact. A' 19min. G Mark ; ideal terminal lead position C; the middle point of A-A' RV SV 4 (4.6) 6.3 (7.2) 10 (11.5) 2.2 3.3 4.7 6.8 10 15 A' 22 33 B' 47 68 C' 100 150 D 220 E 330 470 F For the minimum packing quantity, please 48 F d0.05 Gmax. Kmax. A' 4.0 6.0 1.50.5 0.45 0.5 0.5 B' 5.0 6.0 2.00.5 0.45 0.5 0.5 C' 6.3 6.0 2.50.5 0.45 0.5 0.5 D E 6.3 10.8 2.50.5 0.60 0.5 0.5 8.0 11.5 3.50.5 0.60 0.8 0.8 F 10.0 11.5 5.00.5 0.60 0.8 0.8 RV : Rated voltage (SV) : Surge (room temperature) Size List F Size Code D0.5max. Lmax. A' 16 (18.4) A' A' B' B' B' 20 (23.0) A' A' B' B' C' C' C' C' D D D E F refer to page 51. E F 4. SPECIFICATIONS FOR EACH SERIES Table17 SS Series Characteristics List Size Code Part Number 1 Rated Voltage (V) Rated Capacitance (F) ESR 100kHz to 300kHz (m) (max.) Allowable ripple current (mArms) 3 Tangent of loss angle (max.) Leakage current (A) (max.)2 20 2.2 400 450 0.05 2.20 20SS3R3M 20 3.3 400 500 0.06 3.30 16SS4R7M 16 4.7 400 540 0.06 3.76 16SS6R8M 16 6.8 400 540 0.06 5.44 10SS10M 10 10 350 560 0.06 5.00 15 350 560 0.06 4.73 Specificationsfor eachseries 20SS2R2M A' 6.3 6SS15M B' 20SS4R7M 20 4.7 250 720 0.05 4.70 20SS6R8M 20 6.8 180 745 0.05 6.80 16SS10M 16 10 150 780 0.05 8.00 16SS15M 16 15 150 780 0.05 12.00 10SS22M 10 22 150 780 0.05 11.00 33 150 780 0.05 10.40 6.3 6SS33M C' 20SS10M 20 10 100 1150 0.06 10.00 20SS15M 20 15 100 1230 0.06 15.00 20SS22M 20 22 100 1230 0.06 22.00 16SS33M 16 33 100 1230 0.06 26.40 4SS68M 4 68 70 1430 0.06 13.60 20SS47M 20 47 60 1830 0.06 47.00 16SS68M 16 68 50 2000 0.07 54.40 10SS100M 10 100 40 2100 0.07 50.00 4SS150M 4 150 40 2100 0.08 30.00 20SS100M 20 100 30 2740 0.07 100.00 10SS150M 10 150 30 2780 0.07 75.00 220 30 3000 0.07 69.30 D E 6.3 6SS220M F 1 2 3 20SS150M 20 150 30 3200 0.07 150.00 10SS330M 10 330 25 3500 0.07 165.00 4SS470M 4 470 25 3500 0.07 94.00 Tolerance on rated capacitance : M 20% After 2 minutes 100kHz, +45C Temperature coefficient for allowable ripple current Ambient Temp. Coefficient Tx45C 1 45CTx65C 0.85 65CTx85C 0.7 85CTx95C 0.4 95CTx105C 0.25 Frequency coefficient for allowable ripple current Frequency Coefficient 120Hz f 1kHz 0.05 1kHz f 10kHz 0.2 10kHz f 100kHz 0.5 100kHz f 500kHz 1 49 5. SPECIFICATIONS FOR THE RADIAL LEAD TYPE 1. Explanation of Part Number (Radial Lead Type) Series name Rated voltage SC SA SL SH SP SS SEP SEQP SEPC SF SPA Series Series Series Series Series Series Series Series Series Series Series Example Rated Cap.(F) Code 1 1 2R2 2.2 4R7 4.7 10 10 22 22 100 100 220 220 1000 1000 2700 2700 Taping or forming of terminal code Capacitance tolerance Cap. tolerance Code 20% Taping or lead terminal wire process code M None suffix for regular Iength lead type products *1 Code 2 is used for 2.5V products of E9 and F13 size in SEPC series. 2. Radial lead terminal process 1) Applications * SP, SPA, and SF series are not applicable to the process. * SEP, SEQP, and SEPC series are not applicable to the forming cut. * The other series are applied to the all of the process. Refer to 2) and 3). * The following table is a standard specification. Please contact us concerning other specifications. Organic semiconductor Series Conductive polymer SP SPA SF SEP SEQP SEPC Size C',C,D,E',E C',C,D,E',E,F',F 9E 9F E1 E12 F13 E9,E12 E13 F13 Bag-packed products (lead terminal cutting) Not processed Straight cut Forming cut x x x x x x x x x x x +C, +C1, +C2, +C3 x +C, +C1, +C2, +C3 x +C, +C1, +C2, +C3 x +C, +C1, +C2, +C3 x +C, +C1, +C2, +C3 Taping +TS +T +T, +TS +T +T, +TS +TSS +T +TSS +TS +T 2) Specifications for lead terminal cutting Applicable Case size (Size code) Straight cut 50 Dimensions (unit : mm) +CA +CC +CD L0.5 A' B' C', D E' +F +F1 +F2 2.5max. L0.5 4 A 5 B, B' 6.3C, C', C6, D 8 E, E', E7, E12, E13 10F, F', F8, F13 +C +C1 +C2 +C3 4 A, 5 B, 6.3C, 8 E, CA CC CD L 5.5 4.0 2.5 51 Lead space : 2.5mm 4 A, A' 5 B, B' forming cut Lead space : 5mm forming cut Lead terminal cutting code 2.51 Process names F L F1 Specificationsforthe radialleadtype Rated volt. Code 2 2.0 2R5 1 2.5 4 4.0 6 6.3 10 10 16 16 20 20 25 25 30 30 32 32 Rated Capacitance L0.5 Size Code A F 2.0 C L F1 F2 5.5 4.5 3.0 C1 C2 C3 5.5 4.0 2.5 3.5 B, B' C,C',C6,D E, E', E7, E12, E13 F, F', F8, F13 2.0 2.5 3.5 5.0 5. SPECIFICATIONS FOR THE RADIAL LEAD TYPE 3) Specifications for Taping a) F=5.0mm Taping code +T (Size Code A,B,C,D,E,A',B',C',E') h H W2 W1 L CarrierTape Hold-downTape D0 F P1 W W0 H0 P0 R P P0 R W P2 W2 W1 L F P1 (Size Code F,F',F8,F13,9F) h W0 P H P2 D0 Hold-downTape CarrierTape t (Size Code C,C',D,E,E',E1,E13,9E) P2 P P h h P0 R P0 R D0 W W1 L F W W1 W0 P1 W0 W2 H L F P1 W2 H a P2 Hold-downTape CarrierTape D0 t CarrierTape Hold-downTape c) F=2.5 or 3.5mm Taping code +TSS (Size Code C6,E7,E9,E12) P h P0 R CarrierTape D0 t Taping Code Code Tolerance 4 +T 5 +T 6.3 +T 8 +T 10 +T 4 +TS 5 +TS 6.3 +TS 8 +TS 6.3 +TSS 8 +TSS F 0.8 0.2 5.0 5.0 5.0 5.0 5.0 2.5 2.5 2.5 3.5 2.5 3.5 P 1.0 12.7 12.7 12.7 12.7 12.7 12.7 12.7 12.7 12.7 12.7 12.7 W F W1 L P1 W0 W2 H P2 P0 0.2 12.7 12.7 12.7 12.7 12.7 12.7 12.7 12.7 12.7 12.7 12.7 P1 0.5 3.85 3.85 3.85 3.85 3.85 5.10 5.10 5.10 4.60 5.10 4.60 Hold-downTape (unit : mm) P2 h W W0 1.0 1.0 0.5 min. 6.35 0 18.0 9.5 6.35 0 18.0 9.5 6.35 0 18.0 9.5 6.35 0 18.0 9.5 6.35 0 18.0 9.5 6.35 0 18.0 9.5 6.35 0 18.0 9.5 6.35 0 18.0 9.5 6.35 0 18.0 9.5 6.35 0 18.0 9.5 6.35 0 18.0 9.5 W1 W2 H H0 D0 t L a 0.5 max. 0.75 0.5 0.2 0.2 max. max. max. 9.0 2.5 18.5 16.0 4.0 0.7 0 11.0 9.0 2.5 18.5 16.0 4.0 0.7 0 11.0 9.0 2.5 18.5 16.0 4.0 0.7 0 11.0 9.0 2.5 20.0 16.0 4.0 0.7 0 11.0 9.0 2.5 18.5 4.0 0.7 0 11.0 9.0 2.5 17.5 4.0 0.7 0 11.0 1.5 9.0 2.5 17.5 4.0 0.7 0 11.0 1.5 9.0 2.5 17.5 4.0 0.7 0 11.0 9.0 2.5 17.5 4.0 0.7 0 11.0 9.0 2.5 17.5 4.0 0.7 0 11.0 9.0 2.5 17.5 4.0 0.7 0 11.0 - 3. Minimum Packing Quantity Packing quantities standard * Processed type discrete lead terminals Size Code Case Size pcs./Bag 4 500 A,A' 5 500 B,B' 6.3 500 C,C',C6,D 200 E,E',E7,E9,E12,E13,E1,9E 8 10 200 F,F',F8,F13,9F 10 100 F0 12.5 50 G 16 25 H Zig-zag pack taping type Size Code Case Size Quantity (pcs.) 4 2,000 A,A' 5 2,000 B,B' 6.3 1,500 C,C',C6,D 8 1,000 E,E',E7,E9,E12,E13,E1,9E 10 500 F,F',F8,F13,9F Ordering information 10(Fo), 12.5 and 16 are packing type only. 51 Specificationsforthe radialleadtype b) F=2.5 or 3.5mm Taping code +TS (Size Code A,A',B,B') 6. SPECIFICATIONS FOR THE SMD TYPE 1. Explanation of Part Number (SMD Type) Series name Rated voltage Rated capacitance Capacitance tolerance Example SVP SVQP SVPA SVPB SVPC SVPD Specificationsfor theSMDtype Rated volt. Code 2.5 2R5 4.0 4 6.3 6 10 10 16 16 20 20 25 25 35 35 Rated Cap.(F) 3.3 4.7 10 22 100 220 470 1500 Series Series Series Series Series Series Cap. tolerance Code Code 3R3 4R7 10 22 100 220 470 1500 20% 2. Specifications for Taping (SMD Type) 1) Carrier tape SVP, SVQP, SVPA, SVPB, SVPC, SVPD series t 4.00.1 2.00.1 B W F E 1.5 0.1 0 T P A Mounting parts Direction of unreeling Dimension Size code 4.7 B W F E 4.7 12.0 5.6 16.0 6.9 16.0 6.9 16.0 6.9 16.0 0.3 0.1 P 5.5 1.75 7.5 1.75 0.1 0.1 7.5 1.75 12.0 7.5 1.75 12.0 7.5 1.75 12.0 8.0 A5 0.2 B6 0.2 C5 0.2 C55 0.2 C6 0.2 E7 0.2 0.2 8.6 24.0 11.5 1.75 12.0 10.7 10.7 24.0 11.5 1.75 16.0 F8 E12 F12 52 A (unit : mm) 5.6 6.9 6.9 6.9 8.6 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.3 0.3 0.3 0.3 0.3 0.3 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 8.0 0.1 0.1 0.1 0.1 0.1 t 0.4 0.1 0.4 0.1 0.4 0.1 0.4 0.1 0.4 0.1 0.4 0.1 0.4 T 5.8 0.2 6.2 0.2 5.3 0.2 6.2 0.2 6.2 0.2 7.2 0.2 8.2 0.1 0.2 12.3 8.6 8.6 24.0 11.5 1.75 16.0 0.5 0.2 0.2 0.3 0.1 0.1 0.1 0.1 0.2 10.7 10.7 24.0 11.5 1.75 16.0 0.4 13.0 0.2 0.2 0.3 0.1 0.1 0.1 0.1 0.2 M 6. SPECIFICATIONS FOR THE SMD TYPE 2) Reel 3) Polarity Direction of unreeling Direction of unreeling 20.5 210.8 R1.0 Series 3802.0 W1 W2 Size Code (unit : mm) W1 W2 SVP A5 13.00.5 17.51.0 SVQP SVPA B6, C5, C55, C6 17.00.5 21.51.0 SVPB SVPC SVPD E7, F8, E12, F12 25.00.5 29.51.0 3. Minimum Packing Quantity SVP, SVQP, SVPA, SVPB, SVPC, SVPD series Size Code A5 B6 C5 C55 C6 E7 F8 E12 F12 pcs./Reel (380) 2,000 1,500 1,300 1,000 1,000 1,000 500 400 400 53 Specificationsfor theSMDtype * SVP Series * SVQP Series * SVPA Series * SVPB Series * SVPC Series * SVPD Series 801.0 130.2 6. SPECIFICATIONS FOR THE SMD TYPE 4. Recommended Reflow Condition of SMD Type OS-CON has different characteristics against soldering heat from conventional aluminum electrolytic capacitors or tantalum capacitors because of its unique materials and structure. Please note the following points on soldering of OS-CON SVP, SVQP, SVPA, SVPB, SVPC and SVPD series to draw out the best performance. Recommended reflow profile Specificationsfor theSMDtype Surface of extemal case/terminal[C] 300 Peak temperature 250 Duration at 230C or higher Duration at 220C or higher Duration at 200C or higher 200 150 Preheating 150C to 180C 100 50 0 0 30 60 90 120 150 180 210 240 (Seconds) Series Item Peak temperature (MAX.) Preheat SVP, SVQP, SVPA, SVPC, SVPD Series 250C 150C to 180C 260C 90 30 sec. SVPB Series 240C 150C to 180C 250C 90 30 sec. 200C over time (MAX.) 60 sec. 60 sec. 50 sec. 60 sec. 220C over time (MAX.) 50 sec. 50 sec. 40 sec. 50 sec. 230C over time (MAX.) 40 sec. 40 sec. 30 sec. 40 sec. Reflow number twice or less twice or less Only 1 time Note1. All temperatures are measured on the topside of the Al-can and terminal surface. Only 1 time Note2. Concerning SVPB series, if 260C peak Reflow condition is necessary, please consult with us. Attention : Reflow soldering may reduce the capacitance of products before or after soldering even if soldering conditions stipulated in Recommended Reflow Condition are met. Though the actual reflow conditions are subject to change depending on the kind of reflow soldering method, please be aware that the peak temperature at the top of AI-case and electrode terminals should not exceed peak temperature. Particular notice should be given to the time that OS-CON is heated at 200C or higher during reflow. Be aware that soldering considerably deviating from these conditions will cause problems such as a 50% reduction in capacitance, and a considerable increase in leakage current. The leakage current value may increase (from a few A to a few mA) even within the above conditions. When the OS-CON is used in a DC circuit, the leakage current will decrease gradually through selfrecovery after voltage is applied. If your reflow profile (reflow temperature, number of reflows, etc.) deviates from the above conditions for mounting the SVP, SVQP, SVPA, SVPB, SVPC and SVPD series, please consult with SANYO. 54 7. CONSTRUCTION AND CHARACTERISTICS 1. Development of OS-CON OS-CON is an electrolytic capacitor. Up to now, an electrolytic solution and manganese dioxide have been used as the electrolyte in electrolytic capacitors. In development of a new highly efficient electrolytic capacitor which has a high conductivity (organic semiconductor) when compared to earlier electrolytes, we have successfully designed the electrolytic capacitor OS-CON, featuring low impedance, using an organic semiconductor for the electrolyte. Features of Organic Semiconductive Electrolyte High conductivity (low resistance value) compared to other electrolytes. High conductivity is stability against temperature. Type of capacitor Type of electrolyte Non-solid electrolytic capacitor Electrolyte solution 3 Solid electrolytic capacitor Manganese dioxide 30 Organic semiconductor (TCNQ complex salt) 300 Constructionand Characteristics OS-CON Conductivity (mS/cm) 3,000 Conductive polymer The comparisons of conductivity is general. 2. Construction and Manufacturing Method of OS-CON 2-1. Construction of OS-CON AL foil OS-CON has almost the same construction as an aluminum electrolytic capacitor, and the element consists of rolled aluminum foils. The difference between OS-CON and the aluminum electrolytic capacitor is that organic semiconductive electrolyte is impregnated in behalf of electrolyte solution. Also, SVP, SVQP, SVPA, SVPB, SVPC, SVPD, SEP, SEQP, and SEPC series are sealed using rubber sealing, and others are sealed using resin sealing. AL foil Adhesive tape Separator sheet Winding Element Rubber sealing Resin sealing Resin Rubber Plastic spacer Resin Organic semiconductor Conductive polymer Rubber Element Element Separator sheet Separator sheet Aluminum case Al2O3 Aluminum case AL foil AL foil Al2O3 AL foil AL foil 55 7. CONSTRUCTION AND CHARACTERISTICS 2-2. OS-CON Manufacturing Method Type :Organic semiconductor ( TCNQ complex salt ) Aluminum etching foil Forming Foil slitter Lead wire Separator Sheet Winding Synthesis of TCNQ complex salt Forming and carbonization Stuff TCNQ complex salt in a case Constructionand Characteristics immersion Epoxy resin Resin sealing Sleeve Sleeve covering Aging and inspection SP series and others Type : Conductive polymer Aluminum etching foil Aluminum etching foil Forming Forming Foil slitter Lead wire Foil slitter Separator Sheet Separator Sheet Winding Winding Forming and carbonization Forming and carbonization Conductive polymer Conductive polymer Immersion and polymerization Immersion and polymerization Rubber * Case Rubber * Case Rubber sealing (curl) Rubber sealing (curl) Aging and Inspection Aging and Inspection Plastic Spacer Forming and Marking SVP, SVQP, SVPA, SVPB, SVPC and SVPD series 56 Lead wire Marking SEP, SEQP and SEPC series 7. CONSTRUCTION AND CHARACTERISTICS 1. OS-CON Electrical Characteristics 1-1. Frequency Characteristics Fig.A (at 25C) 100 A : OS-CON 56F/16V (8X6.9L:347I) B : AI-E (Low Impedance) 47F/16V (6.3X7L:218I) C : Ta-cap 47F/16V (6.3X11L:311I) D : AI-E (Low Impedance) 1000F/16V (16X25L:5024I) Impedance () 10 1 B Constructionand Characteristics C 0.1 D A 0.01 1K 10K 100K Frequency (Hz) 1M 10M 20M Fig.B (at 25C) 100 Impedance () ESR () 10 OS-CON Impedance A35SVPD8R2M B16SVPA82MAA C4SEPC560MX D2SEPC2700M ESR 1 A D A B 0.1 B C C 0.01 0.001 D 1K 10K 100K FrequencyHz 1M 10M 20M The OS-CON is an electrolytic capacitor, however, it has excellent frequency characteristics. Using a high conductive organic semiconductor as the electrolyte, and the thin electrolyte layer brought by the adoption of winding element, improves ESR (Equivalent Series Resistance) greatly, and provides the excellent frequency characteristics. Fig.A shows the impedance frequency characteristics of OS-CON, compared to other types of capacitors. The OS-CON shows a nearly ideal curve. When compared at 100kHz, OS-CON 56F, and low impedance aluminum electrolytic capacitor 1,000F, nearly have the same feature. If the frequency gets higher, the capacitance ratio between OS-CON and aluminum electrolytic capacitor gets higher. Fig.B shows the impedance and ESR frequency characteristics of OS-CON. The resonance point of the OS-CON is at 100kHz to 10MHz. The ESR becomes about 5m or less at 100kHz (560F products)- an extremely small value. 57 7. CONSTRUCTION AND CHARACTERISTICS 1-2 Characteristics at high temperature and low temperature Temperature Characteristics 100 Equivalent Series Resistance at 100kHz 10F OS=OS-CON Purple 10 Al AI=AL-E. CapBlue =TantalumCap. Green CR(X5P) =Cera Cap.Red Ta ESR () 1 Ta (X5P Type) CR(X5U) =Cera Cap.Pink 0.1 (X5U Type) OS 0.01 CR(X5P) 0.001 -55 -20 0 20 Temperature (C) 85 105 Temperature Characteristics 20 Capacitance Change at 120kHz 10 OS 10F Al Ta 0 Capacitance Change (%) Constructionand Characteristics CR(X5U) CR(X5P) -10 -20 CR(X5U) -30 -40 -50 -55 -20 0 20 Temperature (C) 58 85 105 Characteristics at high temperature and low temperature of the OS-CON is that it features little change in temperature for the ESR. Since ESR is dominant at high range of impedance (near resonance point), the ESR value greatly affects noise clearing capacity. What ESR changes a little against temperature means that noise clearing ability changes a little against temperature as well. The OS-CON is suitable for outdoor apparatus. 7. CONSTRUCTION AND CHARACTERISTICS 1-3 Bias Characteristics 1) Capacitance Bias Voltage Characteristics OS.1 =OS-CON(10SVP10M) Purple Light Purple CR(X5P) =Cera Cap. Red 10F OS.1 0 OS.2 =OS-CON(25SVPD10M) (X5P Type ; 10V-10F) OS.2 CR(X5U) =Cera Cap. Pink (X5U Type ; 50V-10F) -10 When voltage is applied to ceramic capacitors, they show a bias characteristics where static capacitance is reduced. Our OS-CON product, however, will show no reduction in capacitance for applied voltage within its rating (Note: our 25V product utilized temperature derated voltage). CR(X5U) CR(X5P) -20 -30 0 10 20 30 35 Bias Voltage (V) 2) Impedance, ESR OS-CON (25SVPD10M) 0V bias 0V bias 100 100 10 10 ESRImpedance() ESRImpedance() Multi-layer Ceramic capacitor (25V, 4.7F) Z 1 0.1 1 0.1 Z ESR ESR 0.01 0.01 0.001 10 100 1000 10000 0.001 10 100 Frequency(kHz) Multi-layer Ceramic capacitor (25V, 4.7F) OS-CON (25SVPD10M) 20V bias 20V bias 100 10000 1000 10000 100 10 ESRImpedance() ESRImpedance() 1000 Frequency(kHz) Z 1 0.1 ESR 0.01 0.001 10 10 1 0.1 Z ESR 0.01 100 Frequency(kHz) 1000 10000 0.001 10 100 Frequency(kHz) As bias is applied to multi-layer ceramic capacitor, ESR value changes considerably between 300kHz to 1MHz. Also, it brings change of Impedance value. There is not change of ESR value in OS-CONs even if applies bias. 59 Constructionand Characteristics Capacitance Change (%) Capacitance Change at 120Hz 7. CONSTRUCTION AND CHARACTERISTICS 1-4 Allowable Ripple Current Alowable Ripple Current 4 (100kHz45C) Alowable Ripple Current 4 3.74 3.5 3.74 3.5 3.37 3 3 2.67 2.5 2 1.80 1.83 1.39 1.37 1.15 1.10 1 0.84 0.74 0.5 Constructionand Characteristics 0.45 0.45 33F 16V 47F 16V 0.45 Ripple Current (Arms) Ripple Current (Arms) 2.67 2.67 1.5 (100kHz85C) 2.5 2.36 2 1.5 1.39 1.28 1.15 1.10 1 0.96 0.84 0.74 0.5 0.48 1.87 1.80 0.45 0.45 33F 16V 47F 16V 0.45 0.48 0 0 100F 10V 220F 10V When selecting smoothing capacitors for power supply, the allowable ripple current of the capacitor is one of the standard selections. The allowable value of ripple current is decided by the generated heat of the capacitor, this heating is due to the ESR. Since a large ESR capacitor generates larger heat value, it can not make the flow of ripple current greater. Compared to other electorolytic capacitors, ESR of OS-CON is so small that it can allow far more ripple currents. 100F 10V OS-CON (SVP series) 220F 10V Light Purple OS-CON (SA series) AI-E. Cap. (Low Impedance) Ta.Cap. (Low ESR) Purple Blue Green SVP, SA series is almost same as the regulation. 1-5. ESL Characteristics OS-CON is aluminum solid capacitor of high performance with large rated capacitance and low ESR. Recently in circuit technologies, the constituent of ESL is picked up in the domain of the high frequency with that of electronic equipment. ESL Approximate ESL values of SEP series unitnH Size Code C6 E7 F8 E12 F13 60 at 10 MHz at 40 MHz 2.6 4.0 5.4 4.0 6.0 2.4 3.8 5.2 3.8 5.8 Measuring positionroof of lead terminal All following values are not gurranteed, and there are some cases that the values differ in the measuring way. Please contact SANYO for detail. 8. RELIABILITY 1. Organic semiconductor (TCNQ complex salt) type OS-CON (16SH33M) 20 10 0 -10 -20 0.1 5000 10000 0 5000 10000 0 5000 10000 0 5000 10000 0.06 0.04 0.02 0 100 80 60 40 20 0 100 The left fig. shows a tendency of each characteristics of OS-CON (Organic semiconductor type) in endurance test. The tendency of capacitance change shows the same as aluminum electrolytic capacitor. However, aluminum electric capacitor has yield point (time) for dry-up of electrolytic solution, but OS-CON doesn't. The capacitance of OS-CON decreases gradually, which is semi-permanent. These changes are little difference if applied voltage or not, except for leakage current. 10 1 0.1 20 10 0 -10 -20 0.1 0 5000 10000 0 5000 10000 0 5000 10000 0 5000 10000 0.08 0.06 0.04 0.02 0 Leakage current ESRm at 100kHz A at 16V30s tanat 120Hz Capacitance change% 1-2 Damp heat (60C90% RH, without load) 100 The left fig. shows a tendency of each characteristics of OS-CON (Organic semiconductor type) in damp heat test. Compared with endurance, it seems that the characteristics is a little change. It is necessary to note using OS-CONs when it is damp heat environment, such as outdoors. 80 60 40 20 0 100 10 1 0.1 61 Reliability 0 0.08 ESRm at 100kHz Leakage current A at 16V30s tanat 120Hz Capacitance change% 1-1 Endurance (105C, applied 16V) 8. RELIABILITY 2. Conductive polymer type OS-CON (16SVP39M) 20 10 0 -10 -20 0.1 5000 10000 0 5000 10000 0 5000 10000 0 5000 10000 0.06 0.04 0.02 0 100 Reliability 0 0.08 ESRm at 100kHz Leakage current A at 16V30s tanat 120Hz Capacitance change% 2-1 Endurance (105C, 16V applied) 80 60 The figure on the left-hand side shows the tendencies of each characteristic of the conductive polymer type OS-CON in an endurance test. Little change in characteristics can be seen after 10,000 hours because of adoption of conductive polymer that excels in thermal stability. Also, the change in characteristic is very little compared with Organic semiconductor type OS-CON. 40 20 0 100 10 1 0.1 20 10 0 -10 -20 0.1 5000 10000 0 5000 10000 0 5000 10000 0 5000 10000 0.06 0.04 0.02 0 100 80 60 40 20 0 100 62 0 0.08 ESRm at 100kHz Leakage current A at 16V30s tanat 120Hz Capacitance change% 2-2 High temperature and High humidity test (60C90% RH, without load) 10 1 0.1 The figure on the left-hand side shows the tendencies of each characteristic of the conductive polymer type OS-CON in a hightemperature and high-humidity test. As is the case with the endurance test, little change in characteristics can be seen after 10,000 hours in a high-temperature and highhumidity environment because of the excellent thermal stability of conductive polymer. Also, the change in characteristics is very little compared with Organic semiconductor type OS-CON. 8. RELIABILITY 3. Temperature Acceleration Test (Endurance) Capacitance Change at 120Hz 22F/10V Capacitance Change (%) 70C -1 85C 105C -10 145C 135C 125C 10 100 Time (h) 1000 Estimation of life time OS-CON 105C 95C 85C 75C 2,000h 6,324h 20,000h 63,245h Aluminum electrolytic capacitor 105C 2,000h 95C 4,000h 85C 8,000h 75C 16,000h Guarantee temperature of OS-CON is 105C, except for SEQP, SVQP and SVPD series. 4. Reliability Presumption of life As described on P61, 62, an item for endurance, capacitance of OS-CON is getting smaller as times go by. This means wear-failure of OS-CON is open mode for capacitance-decrease, which is a main failure factor of OS-CON. The lifetime is different by each operating temperature and self-heating by ripple current. The Presumptive lifetime of OS-CON is about 10 times 20C reduction. The following formula outline could make it possible to estimate the presumptive lifetime of OS-CON at ambient temperature Tx (C). The result of the following page estimation is not guaranteed but presumptive values based on actual measurement. Then, the estimated life-span is limited up to 15years. 63 Reliability 155C The decrease in capacitance brings lifetime failure of OS-CONs, its main reason depends on temperature. The left fig. shows the speed of decreasing at each temperature. This graph indicates that temperature coefficient of OS-CON lifetime is 10 times by 20C reduction. Compared with this, aluminum capacitor's is 2 times by 10C reduction. The followings are converted value at 85C and 75C by using 105C X 2000h. These values are not guaranteed but presumptive values. It means that the life time of OS-CON is longer than other 105C X 2000h guaranteed products. 8.RELIABILITY Organic Semiconductive electrolyte type (SC, SA, SL, SH, SS, SP, SF and SPA series) Lx=LoX10 To-(Tx+Tx) 20 Lx : Life expectance (h) in actual use (temperature Tx) Lo : Guaranteed (h) at maximum temperature in use To : Maximum operating temperature Tx : Temperature in actual use (ambient temperature of OS-CON) (C) Tx : Self-heating temperature by Ripple current (C) Tx=(Ix/Io)2 X T IxIo Io : Allowable ripple current at 45C or less (Arms) Ix : Actual flow of ripple current (Arms) Note : The value of Ix should be below the value of Io with the coefficient Ambient Temp. (C) Coefficient 45 45Tx65 65Tx85 85Tx95 95Tx105 1.0 0.85 0.7 0.4 0.25 Reliability Self-heating value T by maximum allowable ripple current (45C or less) varies according to case size. Refer to the rough values in the chart below : Case size A, A' B, B' C, C' D E, E', E1, 9E F, F', F0, G, H, 9F 8 10 15 16 18 20 T (C) Conductive polymer electrolyte type (SVP, SVQP, SVPA, SVPB, SVPC, SVPD, SEP, SEQP and SEPC series) Lx=LoX10 To-Tx 20 Lx : Life expectance (h) in actual use (temperature Tx) Lo : Guaranteed (h) at maximum temperature in use To : Maximum operating temperature Tx : Temperature in actual use (ambient temperature of OS-CON) (C) The following is the presumptive lifetime at over 105C, which is concerned with the heat-proof characteristic of seal-rubber. Temperature Presumptive lifetime in actual use Tx105C SVPB Presumptive lifetime (Lx) SVP, SVPA, SVPC, SEP(2.5RV),SEPC SEP(425RV) SVQP, SEQP 1,000h 2,000h 5,000h 5,000h 105CTx115(C) 3,160h 3,160h 115CTx125(C) 1,000h 2,000h 3,000h SVPD There is no need to apply a temperature-compensating coefficient for the ripple current in the SVP, SVQP, SVPA, SVPB, SVPC, SVPD, SEP SEQP and SEPC series, which use conductive polymer electrolyte. The self-heating temperature under application of the rated ripple current is approx. 20C in the SVP, SVPA, SVPB, SVPC, SEP and SEPC series (10C in A5 and B6 sizes of SVP, SVPA and SVPC series), and approx. 2C in the SVQP, SEQP and SVPD series, but the estimated life expectancy can be calculated without consideration of self-heating under application of the ripple current because of the excellent heat-proof characteristics of conductive polymer. 5. Factors of Short Circuit Mode 1. Applying voltage over the rated voltage. 2. Applying reverse voltage over the specification. 3. Excessive mechanical stress. 4. Applying rush current by sudden charge or discharge over the specification. For details, please refer to "Operating Precautions" on page 4 to 10. 64 9. Features of OS-CON Summary of features for OS-CON 1 OS-CON is a low ESR capacitor. A frequency characteristics of impedance shows an ideal curve. Ideal to use as de-coupling capacitor for removing such noise as ripple, spike, digital, static, audio, etc. Able to flow large ripple current. Ideal for miniaturization, as a smoothing capacitor of switching power supply. Features Able to discharge rapidly. Ideal for use as back-up capacitor in a circuit where large current is consumed at high-speed. 2 ESR of OS-CON is not dependent on temperature. The OS-CON is useable for low temperature specification equipment. (0Corless) 3 OS-CON has a long life. You can expect to use OS-CON for 50,000h at 85C. (SVQP,SVPD,SEQP and SH series) Ideal for industrial devices that shall be used for a long period. 65 0. Precautions when using OS-CONs in circuits Explanation of the rush current suppression methods When the OS-CON is used in the following circuit, an excessive rush current may flow because the ESR is extremely small. Therefore, consideration must be given to and measures be taken in design, and production facilities, etc. Maintain the rush current at 10A or less. If as long as 10 times of the allowable ripple current of the OS-CON exceeds 10A, reconfigure so that the ripple current does not exceed 10 times. 1. DC-DC converter input circuits a. DC-DC converter circuits are usually a PCB block shape and use a low ESR capacitor in the input section for high performance and miniaturization. b. Consideration must be given to the rush current that flows from the equipment when the DC-DC converter is adjusted and inspected. There is the possibility that an extremely large amount of rush current will flow through the OS-CON during voltage adjustment or inspection of the DC-DC converter's circuit block when the power impedance supplied from the equipment being adjusted or inspected is exceedingly low and the current suppression function of the current limiter and such is provided. (Refer to the example in Figure 1.) Rush current suppression measures must be taken for DC-DC converter adjustment and inspection equipment. (Refer to page 67.) Precautionswhenusing OS-CONincircuits 2. Circuits driven by chargeable batteries a. Circuit power lines equipped with batteries or rechargeable batteries use capacitors such as the OS-CON with very low ESR to increase performance and facilitate miniaturization. There is the possibility of an extremely large amount of rush current flowing through the low ESR capacitors arranged along the power line when the power is turned on for circuits driven by nickel cadmium chargeable batteries etc. that have a very low internal resistance. (Refer to the example in Figure 1.) A protection circuit like that is shown below is usually used to suppress rush current of charging battery. Inductance coil Direction of current flow Diode for absorbing counter electromotive force The main points to be aware of are listed here. Normally, an inductance coil with a magnetic core is used, however, inductance sometimes drops depending on the frequency, so it must be checked. The peak current value of the diode when absorbing counter electromotive force. 3. No protection resistance rush current When there is no protection resistor Z as shown in Figure 1 and the power supply has Re nearly= 0, the OS-CON's rush current is as follows. Rush current (A) = Z (Protection circuit) Supplied DC voltage (E) ESR+Re+Z () Example : For 25SC10M ESR=90m, or less and Supplied DC voltage=20V, 20V = 222A or more less than 0.09 66 Fig. 1 Capacitor Power supply internal resistance Re Power supply voltage E ESR Capacitance Load resistance 0. Precautions when using OS-CONs in circuits Examples of rush current suppression methods 1)Resistormethod 2)Resistorandrelaymethod Relay contact R Resistor for current suppression Capacitor Power supply ESR internal resistance Re Power supply voltage E Capacitance Rush current is as shown below. Rush current (A) = Capacitor R Power supply E (V) Re+ESR+R () 3)ResistorandMOS-FETmethod ESR Relay coil Capacitance The rush current is exactly the same as in the resistor method, however, there is almost no voltage drop caused by the current suppression resistor from the time the relay contact goes ON. Note: After the capacitor has finished recharging, it may take some time or setting of voltage to turn the relay ON. Precautionswhenusing OS-CONincircuits Rush current is usually determined mainly by R as Re and ESR are low. Although the current is simply and clearly suppressed with this method, resistor R for suppressing current causes the voltage to drop. internal resistance Re Power supply voltage E 4)Powerthermistor Power thermistor R Capacitor Capacitor Re Power supply voltage E ESR MOS-FET Capacitance Rush current is exactly the same as in the resistor method, however, there is almost no voltage drop caused by R after rushing, the same as the resistor and relay method. Note: As with the resistor and relay method, after the capacitor has finished recharging, it may take some time or setting of voltage to turn the MOS-FET ON. Re Power supply voltage E ESR Capacitance Taking an example of a common power thermistor, the value is 8 at 25C, but becomes 0.62 at 130C. When the power thermistor is connected as shown in the above diagram, rush current is suppressed due to the large resistor value at the moment the switch is turned on. After this, the output loss (voltage drop) is reduced. However, the power thermistor has a heat constant, meaning that the large resistor value in the initial state cannot be regained the moment the switch is turned off. As a result, the ability to suppress current is lost when the switch is turned off and on quickly. 67 0. Precautions when using OS-CONs in circuits Sudden discharge current suppression OS-CON has an exceedingly low ESR. When the load impedance during discharge is extremely low, there is the chance that it allows a large amount of discharge current to flow for an instant. Please note the following points when using the OS-CON in sudden discharge operations. The discharge equivalent circuit is as shown to the left. The formula for estimating discharge current is given below. Protection resistor Z1 Capacitor ESR Z2 Load circuit Discharge current (A) = Charging voltage (V) ESR+Z1+Z2 () Capacitance Example:For25SC10M Precautionswhenusing OS-CONincircuits ESR=90m orless Chargingvoltage=20Visset,then Z1,Z2=0 Discharge current (A) = Charging voltage 20V ESR 0.09 or less = 222A or more As shown in the above example, there is the chance an extremely large amount of discharge current will flow when electric charge is discharged with 0 loading. When the OS-CON is to be used in sudden discharge operations, configure the circuit so that the peak discharge current becomes 10A or less, using the above mentioned rough estimate expression as a guide. However, if 10 times the allowable ripple current of the OS-CON exceeds 10A, reconfigure so that 10 times the allowable ripple current is not exceeded. 68 0. Precautions when using OS-CONs in circuits Precautions when connecting an OS-CON and an aluminum electrolytic capacitor in parallel Aluminum electrolytic capacitors and OS-CONs are often connected in parallel to improve circuit density and cost performance of ripple absorbing capacitors. Please give full consideration to the following. Fig.1 lr lr1 Ir Total ripple current lr2 ESRCapacitor's equivalent series resistance C1 C2 ESR1 ESR2 Cz1 Cz2 Cz Impedance of the capacitor's capacitive components Fig.2 lr=1000mArms lr1 lr2 OS-CON100F AI-E1000F ESR1 ESR2 30m 80m Formula for calculating the ripple current value Since impedance becomes exceedingly low when the capacity is more than 10F. And frequencies higher than 100kHz, each Cz in Figure 1 can be omitted changing the actual ripple current value to that shown in Figure 2. As shown here, although the OS-CON has 1/10th of the capacity of that of the ESR2 Ir1=Ir X ESR1 + ESR2 =1000mAX mated capacitor, it allows 73% of the ripple current to flow. 80m 30m+80m 727mArms As explained here, when OS-CON and an aluminum electrolytic capacitor are to be used in parallel connection, select the appropriate type of OS-CON that has an extra margin of capacity since a large amount of ripple current flows through it. 69 Precautionswhenusing OS-CONincircuits Ripple current flowing through each parallelly connected capacitor can be found by using the values symbolized in the reference equivalent circuit in Figure 1. The equivalent circuit in Figure 1 can be simplified as shown in Figure 2 when it is to be used for frequencies between 100kHz and a few MHz. (Assuming the capacitor's capacitance is more than 10F.) -. Application RippleremovalcapabilityofOS-CON While there is a tendency to downsize switching power supplies capacitors still remain one of the parts occupying large areas of circuit boards. The working temperature is an important consideration when selecting a capacitor, since it generally results in widely varying capacitor characteristics. The following experiment shows the superior ripple removal capability of the OS-CON at high frequencies in wide range of working temperatures. Experiment A general chopper switching power supply was used to test the OS-CON against two alternatives. SANYO OS-CON, low-impedance aluminum electrolytic capacitor, and low-ESR tantalum capacitors were each connected as the capacitor in the output side smoothing circuit at working temperatures of -20C, 25C and 70C to compare the output residual ripple voltage. L VOUT = 3.3V, IOUT = 3A + VIN = 5V SW IC Osilloscope RL C 200kHz Specimen Application Initially SANYO OS-CON 100uF/6.3V (6SVP100M 6.3mmxL6.0mm) was used as the output side smoothing capacitor (C) in the above test circuit, the residual ripple voltage was measured at ambient temperature of -20C, 25C, 70C. Low-impedance aluminum electrolytic capacitors and low-ESR tantalum capacitors were selected for measurement at each temperature -20C, 25C, 70C so that the residual ripple voltage became equal to that achieved when the OS-CON 100uF/6.3V was used. Finally, the residual ripple voltage was measured at each temperature (-20C to 70C) with an equal number of side smoothing capacitors to the 25C conditions, and the rates of change in the ESR of the smoothing capacitors were calculated from the amounts of change. Result Table1 On-board area ratios of capacitors at each temperature (when the residual ripple voltage is on the same level) Ambient temperature OS-CON Aluminum Electrolytic capacitor Tantalum capacitor 25C 1 7.15 1.46 - 20C 1 16.7 1.46 70C 1 4.77 1.46 Table2 Rates of change in ESR on the basis of 25C Ambient temperature 25C - 20C 70C Rate of change in ESR= OS-CON Aluminum Electrolytic capacitor Tantalum capacitor 1 1 1 1.14 3.03 1.27 0.952 0.587 0.85 Residual ripple voltage at ambient temperature X Oscillation frequency at ambient temperature Residual ripple voltage at 25C X Oscillation frequency at 25C From the above results, it can be seen that SANYO OS-CON excels in temperature characteristics. 70 -. Application Table-1 Ambient temperature 25C Capacitor type OS-CON Aluminum Electrolytic capacitor Tantalum capacitor capacitance/voltage 100F/6.3V 680F/6.3V 100F/10V Quantity 1pc 3pcs 2pcs Residual ripple voltage 22.8mV 23.8mV 24.8mV Size2 mm 6.6 X 6.6 10.5 X 10.5 7.5 X 4.5 On-board area ratio 1 7.15 1.46 200kHz Oscillation frequency Fig Fig2 Fig1 Fig3 Table-2 Ambient temperature - 20C OS-CON Aluminum Electrolytic capacitor Tantalum capacitor capacitance/voltage 100F/6.3V 680F/6.3V 100F/10V Quantity1 1pc 7pcs (3pcs) 2pcs Residual ripple voltage 20.8mV 24.4mV (57.6mV) 25.2mV Size2 mm 6.6 X 6.6 10.5 X 10.5 7.5 X 4.5 On-board area ratio 1 16.7 1.46 250kHz Oscillation frequency Fig Application Capacitor type Fig4 Fig5 Fig6 Fig7 Table-3 Ambient temperature 70C Capacitor type OS-CON Aluminum Electrolytic capacitor Tantalum capacitor capacitance/voltage 100F/6.3V 680F/6.3V 100F/10V Quantity1 1pc 2pcs (3pcs) 2pcs Residual ripple voltage 25.6mV 24.0mV (16.4mV) 24.8mV Size2 mm 6.6 X 6.6 10.5 X 10.5 7.5 X 4.5 On-board area ratio 1 4.77 1.46 170kHz Oscillation frequency Fig Fig8 Fig9 Fig10 Fig11 1Figures in brackets () are conditions at 25C. 2For items other than Ta, rather than the element diameter, the base plate dimensions were taken as the maximum dimensions. 71 -. Application Comparison at 25C OS-CON 100F/6.3V Fig125C (1pc) CH120mV AC 1:1 (2us/div) 22.8mV 200kHz Low-impedance aluminum electrolytic capacitor 680F/6.3V Fig225C(3pc) CH1 = 20mV AC 1:1 (2us/div) Application 23.8mV 200kHz Low-ESR Tantalum capacitor 220F/10V Fig 325C (2pc) CH1 = 20mV AC 1:1 (2us/div) 24.8mV 200kHz 73 -. Application Comparison at -20C OS-CON 100F/6.3V Fig 4 -20C (1pc) (2us/div) CH1 = 20mV AC 1:1 23.8mV 200kHz Low-impedance aluminum electrolytic capacitor 680F/6.3V Fig 5 -20C (7pc) Fig 6 CH1 = 20mV AC 1:1 (2us/div) -20C (3pc) CH1 = 20mV AC 1:1 (2us/div) Application 57.6mV 24.4mV 250kHz 250kHz Low-ESR Tantalum capacitor 220F/10V Fig 7 -20C (2pc) CH1 = 20mV AC 1:1 (2us/div) 25.2mV 250kHz 74 -. Application Comparison at 70C Fig 8 OS-CON 100F/6.3V 70C (1pc) CH1 = 20mV AC 1:1 (2us/div) 25.6mV 170kHz Low-impedance aluminum electrolytic capacitor 680F/6.3V Fig970C(2pc) Fig1070C(3pc) CH1 = 20mV AC 1:1 (2us/div) CH1 = 20mV AC 1:1 (2us/div) Application 24.0mV 16.4mV 170kHz 170kHz Low-ESR Tantalum capacitor 220F/10V Fig 11 70C (2pc) CH1 = 20mV AC 1:1 (2us/div) 24.8mV 170kHz 75 -. Application OS-CON high speed back-up performance (Back-up capacitor for variable load) IC, especially MPU that are lately used in electronic devices operate at very high processing speed. PCB's are able to be more densely populated by reduction of operating voltage and getting narrow pattern space. Involved in changing to lower voltage, current load is increasing with a development of new MPU. A sudden change of current load with larger variable load at high speed causes the voltage variation of supply line, and it makes MPU work wrong. Let us evaluate the excellent back-up performance of OS-CON compared to that of other electrolytic capacitors. Capacitors with low ESR and large capacitance are necessary for high-speed load fluctuations. The OS-CON can provide the largest capacitance among low ESR capacitors, and in this regard, the OS-CON is a suitable back-up capacitor. 1. Test condition Load condition Test circuit Item Application 1 Backup waveform SW Load current Power supply 2 V Oscilloscope Load width 5s Cycle 12.5s Rising time 20ns Current load 2A Voltage 4V Power supply Sample Condition impedance 1 Switching wave form Whole wave form CH32V AC 10 : 1 Rising wave form CH32V AC 10 : 1 5us/div 2V/div 5s/div 2V/div 20ns/div V : AC Volt tolerance (V) The value of capacitance for back-up will be: C= 76 I Xt V -I X ESR 20ns/div C : Capacitance (F) ESR : ESR () t : reaction time (second) I : load current change (A) -. Application 2.Result 2-1ComparisonbetweenOS-CONandothercapacitorswithsamecapacitance Compared with same capacitance, OS-CON's voltage drop of supply line is 104mV, but lowimpedance Aluminum electrolytic capacitor indicates 548mV (5.3times of OS-CON), and low ESR Tantalum electrolytic capacitor indicates 212mV (2times of OS-CON). OS-CON Low Z Aluminum capacitor 10V100F,ESR:425m 10SP100M,ESR:21m CH2200mV AC 1 : 1 V=104mV 5us/div 200mV/div 5s/div CH2200mV AC 1 : 1 V=548mV Low ESR Tantalum capacitor 10V100F,ESR:85m 5us/div 200mV/div 5s/div CH2200mV AC 1 : 1 V=212mV 5us/div 200mV/div 5s/div 2-2 A : Examination of same level variable load To obtain similar level of voltage drop to 10SP100M, Low Z Aluminum electrolytic capacitor needs 1,500F or more. Low ESR Tantalum electrolytic capacitor needs 220F X 2pcs or more. CH2200mV AC 1 : 1 V=104mV Low ESR Tantalum capacitor Low Z Aluminum capacitor 10V1,500F 10SP100M 5us/div 200mV/div 5s/div CH2200mV AC 1 : 1 V=128mV 10V220Fx2 5us/div 200mV/div 5s/div CH2200mV AC 1 : 1 V=116mV 5us/div 200mV/div 5s/div B : In case of lower temperature (-20C) Compared them under the lower temperature, OS-CON is able to keep stable, while the low Z aluminum capacitor has 3.2 times larger drop of the voltage and the low ESR tantalum capacitor has 1.2 times larger drop of the voltage. OS-CON Low Z Aluminum capacitor 10SP100M 10V1,500F CH2200mV AC 1 : 1 V=104mV 5us/div 200mV/div 5s/div CH2200mV AC 1 : 1 V=404mV Low ESR Tantalum capacitor 10V220F X 2 5us/div 200mV/div 5s/div CH2200mV AC 1 : 1 V=144mV 5us/div 200mV/div 5s/div 77 Application OS-CON -. Application Application to low-pass filter circuits As a means of removing noise from power supply lines, a low-pass filter such as shown below may be used. In recent years, switching power supplies have been referred to as power sources, which are compact and highly efficient, but must be large noise sources in not a few cases. Also, digital circuits are various types of noise sources, and in most of the devices with mixed noise-sensitive analog circuits, entry of high-frequency noise into the analog circuits is prevented by connecting these low-pass filters to the power supply lines of the analog circuits. Fig.1 LC Filter Fig.2 RC Filter Then, the ESR of capacitors in use affects the damping factor of filters, and an ideal damping effect can be expected with decrease in the ESR. This is because the capacitor's capacitance and ESR make a zero, which is a first order phase lead network, grow, so that the damping factor effect is cancelled by +20dB/dec at frequencies higher than zero. In other words, the damping factor effect is lost from 40dB/dec to -20dB/dec in the LC filter, and from -20dB/dec to 0 in the RC filter. 0dB fc fz Frequency Application Attenuation Actual damping factor When the ESR is low fc fz When the ESR is low Ideal damping factor Ideal damping factor (a) LC Filter Frequency Actual damping factor Attenuation 0dB (b) RC Filter Fig.3 Actual damping factor Therefore, there are not a few cases where this zero phenomenon affects such problems that the noisecutting effect cannot be produced in spite of an increase in the capacitance of the capacitor in use. Due to its small ESR, the OS-CON is most effective with this low-pass filter. Next, comparisons of actual damping factor effects are made with an aluminum electrolytic capacitor. The capacitors used for comparisons are as follows: * OS-CON 16V/33uF, ESR=37m (16SA33M) ESR is an actual measurement. * Aluminum electrolytic capacitor 10V/33uF, ESR=1410m 78 -. Application q LC Filter (L=10uH) 1) OS-CON 2) Aluminum electrolytic capacitor Frequency characteristics Frequency characteristics Gain [dB] Gain [dB] 80 80 60 60 40 40 20 20 0 0 -20 -20 -40 -40 -60 -60 -80 10 100 1k 10k 100k Frequency [Hz] 1M -80 10 100 1k 10k 100k 1M Frequency [Hz] w RC Filter (R=5.6) 1) OS-CON 2) Aluminum electrolytic capacitor Frequency characteristics Frequency characteristics Gain [dB] Gain [dB] 80 60 60 40 40 20 20 0 0 -20 -20 -40 -40 -60 -60 -80 10 100 1k 10k 100k Frequency [Hz] 1M -80 10 Application 80 100 1k 10k 100k 1M Frequency [Hz] In any of these instances, it can be seen that the OS-CON shows an damping effect in higher frequency regions. These measurements were made only at room temperature. It is, however, needless to say that the difference will be more obvious at low temperatures (especially 0C or less). This is because the ESR of the aluminum electrolytic capacitor increases extremely at low temperatures, while the ESR of the OS-CON hardly changes at low temperatures, which does not affect the damping effect of the filter. 79 -. Application Application of switching power supply for smoothing capacitor It is said that to restrain output ripple current, the output smoothing capacitor of the switching power supply is suitable to use the smaller ESR capacitor. However when the low ESR capacitor is used, the phenomenon sometimes occurs that is called the abnomal oscillation of output voltage. The occurrence degree of the abnormal oscillation of output voltage changes even if it depends on the topology such as the control system, and Boost and Buck style. We explain the mechanism and the treatment method of output voltage oscillation with the example of the Buck style switching regulator under the voltage control mode. 1. Abnormal oscillation of output voltage The switching power supply usually has the negative feed-back circuit to stabilize output voltage. The outline control block is shown in Figure 1. The difference between output voltage and standard voltage Vref are amplified with the error amplifier and convert to the digital signal with the PWM comparator and flip on and flip off switch Q1. Input voltage Vin becomes a square wave form by Q1, and you obtain DC output voltage Vout by make it smooth Q1 L with coil L and capacitor Cout. Therefore, L and Vout also Cout assumed that they form the second low Vin pass filters. Zi Cin The frequency characteristic of the output LC filter is expressed with the Bode diagram like Figure 2. On the other hand, the phase is delayed 180 degrees originally, because the error amplifier is a negative feedback circuit. Therefore, the phase delay of the output LC filter and the error amplifier occur at the same time, and when 360 degrees delay occur, the output voltage oscillates. D Cout Zc Error Amp. PWM Comparator Vref OSC Control block of switching power supply is delayed 180 degrees. But more than some of Gain becomes -40dB/dec to -20dB/dec. delay 180 degrees. This is because the first 180 90 80 Gain Phase 70 50 Cut-off frequency 140 100 80 30 Zero frequency 60 20 40 10 20 0 0 -10 -20 -20 -40 -30 -60 -40 -80 Large -50 -100 -60 -120 ESR -70 -80 -140 -160 Small -90 1 10 100 1000 10000 100000 Frequency [Hz] Fig.2 Frequency characteristic of LC filter -180 1000000 Phase [deg] 40 80 160 120 60 Gain [dB] Application Let's think about an ideal LC filter. The damping rate of the LC filter is -40dB/dec and the cut-off 1 frequency becomes 2 LC , and become Gain Fig.1 and Phase like the dotted line of Figure 2. With an ideal filter the output voltage oscillates because it frequency that is called zero frequency, damping rate Furthemore the Phase returns to delay 90 degrees from -. Application order Phase lead network is formed by the capacitance value and ESR of Cout. Because, after the 1 zero frequency 2 Cout ESR , the Gain damping rate goes on the Phase of +20 dB, +90 degrees. However, when the small ESR capacitor is used, it works as a LC filter up to high frequency band, and the Phase delay to nearly 180 degrees and it becomes easy to oscillate. 30 degrees to 40 degrees or more of Phase margin is thought as a necessity to inhibit the oscillation of output voltage with a general negative feed-back circuit. The Phase margin is numerical value how much the minimum value of the Phase is distant from-180 degrees. The smaller the Phase margin gets, the higher the possibility to oscillate by the characteristic dispersion and temperature change of the component will be. 2. Inhibition method of oscillation By doing Phase compensation with the feed-back circuit of the error amplifier the oscillation of output voltage can be inhibited. There are various kinds in Phase compensation. It is most effective to use the Phase compensation circuit like the following in the switch power supply of the voltage control mode. Zc Gain Phase Gain [dB] 80 180 160 70 140 60 120 50 100 40 80 30 60 20 40 10 20 0 0 -10 -20 -20 -40 -30 -60 -40 -80 -50 -100 -60 -120 -70 -140 -80 -160 -90 1 10 100 1000 10000 100000 1000000 Phase [deg] 90 -180 100000000 Frequency [Hz] Fig.4 Frequency characteristic of Phase Compensation Network 81 Application Figure 3 shows that and Zi form first order Phase lead network and and form first order Phase lag network. By adjusting these values, it dose the Phase compensation by which from Vout PWM Phase will occur and improve Comparator Phase delay of the whole negative Error Amp. feed-back circuit by the frequency Vref characteristic of output LC filter at the frequency band which the Phase indicates the lowest. Figure Fig.3 Phase compensation network of Voltage Control Mode 4 is the example. As the Phase of the output LC filter of Figure 2 becomes a lowest point at around 10kHz, it has about 30 degrees of Phase lead around that frequency. Because of this, it can secure the Phase margin of 30 degrees even if the Phase delay of LC filter becomes 180 degree nearly, the oscillation of output voltage can be inhibited. Related in detail, please inquire it to us. -. Application 3. Concrete examples of prevention oscillation Now, concrete examples of design are introduced. Fig. 5 shows an example of the design of a step-down DC-DC converter using a ROHM-made power supply control IC. Q1 10uH Vin Zi Vout C in D C out Zc + Vref Error amplifier [Specification] + - DV PWM comparator Triangular wave generator 200kHz * Input voltage (Vin) : 5V * Output voltage (Vout) : 3.3V * Output current (Iout) BA9721 : 3.2A * Output ripple voltage (Vripple) : 20mVp-p Fig.5 A concrete example of design Application The ESR of the output capacitor necessary to make an output ripple voltage of 20mVp-p can be obtained as follows: ESR < Vripple / ((Vin-Vout) / L*Vout / Vin / fosc) = 35.7m Consequently, the following capacitors have been selected. 1) OS-CON 6SVP100M1-parallel6.3xL6mm ESR = 32m ESR is an actual measurement. 2) Aluminum electrolytic capacitor 6V/680uF 3-parallel 10xL8mmESR = 128m/p. Total ESR = 43m Photograph 1 (a) and (b) show measuring circuits using the above capacitors. Following, it will be verified just how much we can downsize by using the OS-CON compared with aluminum electrolytic capacitors if the most favorable phase compensating circuit is provided. (a) OS-CON (b) Aluminum electrolytic capacitor Photo 1 Evaluated circuit boards 82 -. Application 4. Examples of design with aluminum electrolytic capacitors When the aluminum electrolytic capacitors are used, the frequency characteristics of the output LC filter are as shown in Fig.6, and there is a sufficient phase margin to such an extent that there is no need to make phase compensation. Therefore, the phase compensating circuit in Fig.7 is sufficient. 20 40 10 20 0 0 Gain Phase -20 Rc -20 -40 -30 -60 -40 -80 -50 -100 -60 -120 -70 -140 -80 -160 -90 10 100 1000 Phase [deg] Gain [dB] -10 -180 100000 10000 Zi Zc Cc Rin : 22k Rc : 100k Cc : 1000pF Rin + Vout PWM To PWM comparator Error amplifier Vref Fig.7 Phase compensating circuit with the AL-E Frequency [Hz] Fig.6 Frequency characteristics of the LC filter with the AL-E With the phase compensation network in Fig.7 (properly speaking, phase compensation is not made), the total frequency characteristics are as shown in Fig.8, and it can be said that there is a sufficient phase margin. The output ripple voltage waveform is shown in Fig.9. Frequency characteristic Gain [dB] CH2 = 5mV AC 1:1 Phase [deg] 180 50 150 40 120 30 90 20 60 10 30 0 0 -10 -30 -20 -60 -30 -90 -40 -120 -50 -150 -60 -180 1k 10k 22m Vp-p Fig.9 Output ripple voltage waveform with the AL-E CH4 = 100mV AC 10:1 (20us/div) 100k Frequency [Hz] Fig8 Total frequency characteristics with the AL-E 5. Examples of design with the OS-CON When the aluminum electrolytic capacitors used in power supply circuits are replaced with the OS-CON without changing the phase compensation network, the output voltage oscillates. (Fig.10) As a reason, we can say that the phase margin is lost because the phase compensation network is not changed despite the fact that the frequency Fig.10 Oscillating output voltage waveform characteristics of the output LC filter change as shown in Fig.6, where the aluminum electrolytic capacitors are used, to Fig.11, where they are replaced with the low ESR OS-CON. 83 Application 60 100 (2us/div) -. Application When the LC filter has little phase margin as shown in Fig.11, appropriate phase compensation can be made by using such a phase compensation network as shown in Fig.12. 20 40 Gain Phase 10 -10 -20 -20 -40 -30 -60 -40 -80 -50 -100 -60 -120 -70 -140 -80 -160 -90 Zc Cc1 0 10 100 1000 -180 100000 10000 Frequency [Hz] Zi Rin2 Cin Phase [deg] Gain [dB] 0 20 Rc Cc2 Rin1 Vout + Rin1 : 3.3k Cin : 150pF Rc : 22k Cc1 : 68pF Cc2 : 1000pF PWM To PWM comparator Error amplifier Vref Fig.12 Phase compensating circuit with the OS-CON Fig.11 Frequency characteristics of the LC filter with the OS-CON This is to cancel the deepened phase lag by forming phase leads at Zi and Zc in Fig.12. Because of this, the total frequency characteristics are as shown in Fig.13; the phase margin is sufficient; and the output ripple voltage waveform (Fig.14) is almost the same as is the case with the aluminum electrolytic capacitors. Gain [dB] Frequency characteristic Phase [deg] Application 60 180 50 150 40 120 30 90 20 60 10 30 0 0 -10 -30 -20 -60 -30 -90 -40 -120 -50 -150 -60 -180 100 1k 10k 100k CH2 = 5mV AC 1:1 19m Vp-p Fig.14 Output ripple voltage waveform with the OS-CON Frequency [Hz] Fig.13 Total frequency characteristics with the OS-CON 84 (2us/div) -. Application Influence of output ripples from switching power supply on actual images As shown on page 70 through to page 75, an OS-CON, aluminum electrolytic capacitor, and a tantalum capacitor were connected as the output capacitor of a switching power supply to compare the remaining output ripples. The result showed that the OS-CON provided an excellent filter effect, superior to those of other capacitors. This section discusses the influence of such remaining ripples on images. You may understand how digital noise affects analog signals. Influence camera on images by a digital An OS-CON with rating of 10V / 47F X 2p. (SL series, size: 6.3 X L5.0) and a low impedance aluminum electrolytic capacitor with rating of 10V / 330F (size: 6.3 X L11.0) were connected as the smoothing capacitor on the output side of the DC-DC converter in a digital camera to compare their influence on actual images when the temperature was changed between 25C, 0C and -20C . OS-CON 10V / 47F X 2p. (SL series ; size : 6.3 X L5.0) Parts mounting circuit OS-CON is used AI-E is used Low impedance Aluminum electrolytic capacitor 10V / 330F X 2p. (size : 6.3 X L11.0) Photo 2 at 25C Photo 3 at 0C Photo 4 at 0C Photo 5 at -20C Photo 6 at -20C Application Photo l at 25C As shown above, images were quite normal down to -20C when the OS-CON was used, while images started to become white, like misting, around 0C as a whole, and images hardly appeared at all at -20C as shown in Photo 6 when the low impedance aluminum electrolytic capacitor was used. 85 =. Information and wish Since the following models of the SC, SA, SL, SH and SVP series have been integrated into models with a higher voltage rating, please consider these higher voltage rating models for new adoption or model changes. Series Size Code SC A SA SL SH SVP Applicable model Alternative model 16SC1M 25SC1M 16SC1R5M 25SC1R5M B 6SC10M 10SC10M C 16SC10M 25SC10M 6SC22M 10SC22M D 6SC47M 10SC47M C 10SA33M 16SA33M E 10SA100M 16SA100M B' 6SL10M 10SL10M C' 6SL22M 10SL22M 6SL33M 10SL33M 6SL47M 10SL47M 16SH1M 25SH1M 16SH1R5M 25SH1R5M C 16SH10M 25SH10M A5 6SVP15M 10SVP15M 4SVP22M 6SVP22M 10SVP22M 16SVP22M 6SVP33M 10SVP33M 6SVP56M 10SVP56M 4SVP82M 6SVP82M 10SVP82M 16SVP82M 6SVP120M 10SVP120M 6SVP150M 10SVP150MX 4SVP220M 6SVP220MX 4SVP470M 6SVP470MX A B6 C6 E7 Information andwish F8 Production of the SG and SV series has been discontinued. Therefore, customers using these series at present are kindly requested to substitute the SP series for the SG series, and the SVP series for the SV series. Production of the SM and SN series is scheduled to be discontinued upon receipt of customer approval. Please use the SVP series for new board designs. 86 . Capacitors Selection Sheet Company Dept. Name TEL E-mail FAX Application Power Supply / Filter / By-pass Capacitor / Coupling Circuits / Others ( Equipment PC / PC Peripheral Unit / Audio / Communication / Automobile / Other ( Radial mm Mount type Height limit ) ) SMD Indispensable item Item Switching Frequency Input Voltage Output Voltage Output Current Ripple Voltage Ambient Temperature Primary Inductance Inductance Winding ratio Symbol fosc Vin Vout Iout Vripple Ta L1 L n1 : n2 Value Unit kHz V V A mVp-p C H H : Iout I 0A Vout Vripple Vdrop Option I Vdrop Current Change Voltage Drop Control IC 0V A mV Please enclose the use circuit in a circle. BUCK Vin > Vout Iout L + FORWARD + L Vout Vin fosc n1 L1 + n2 Iout + Vout Vin + Vin fosc Iout L HearingSheet BOOST Vin < Vout + fosc Vout FLYBACK Iout BUCK-BOOST 0 > Vout Iout n2 + Vout Vin + Vin n1 L1 + L fosc + Vout fosc 87 Memo Application to OS-CON Portable Navigation System TM AdoptedmodelxQuantity 851 20SVP22Mx2 6SVP82Mx4 (Front) OS-CON is used for the DC-DC converter part. (Back) SANYO Electric Co., Ltd. Electronic Device Company Sales division(Japan) 1-1 SANYO-cho, Daito, Osaka, 574-8534 Phone:(072)870-6375/6377 FAX: (072)870-6456 http://www.secc.co.jp SANYO Component Europe GmbH Stahlgruberring 81829 Munich Germany Phone:49-(0)89-460095-284 FAX:49-(0)89-460095-275 Taiwan Branch(Taiwan) 4 Fl., No.146, Sungjiang Rd., Taipei, Taiwan104, R.O.C. Phone:886-2-2536-1855 FAX: 886-2-2536-6168 Korea office 7th Floor, Han-Wha Building 110, Sogong-Dong, Chung-ku, Seoul, Korea Phone:02-777-5860 FAX: 02-777-6053 SANYO Electronic Device (U.S.A.) Corporation San Diego Headquarter 2055 SANYO Ave., San Diego, CA. 92154, U.S.A. Phone:1-619-661-4134 FAX: 1-619-661-1055 http://www.sanyodevice.com San Jose sales office 1230 Oakmead Parkway, Ste. #314, Sunnyvale, CA 94085, U.S.A. Phone:1-408-749-9714 FAX: 1-408-749-0212 Boston sales office 100 Cummings Center, Ste. #218C, Beverly, MA 01915, U.S.A. Phone:1-978-922-6573 FAX: 1-978-922-7428 Dallas sales office 2007 North Collins Blvd., Ste. 407, Richardson, TX 75080, U.S.A. Phone:1-972-238-7450 FAX: 1-972-238-7321 Forrest City sales Representative P.O.Box 2604-Forrest City, AR 72336, U.S.A. Phone:1-870-494-3793 FAX: 1-870-633-6720 SANYO Electronic Components (Singapore) Pte., Ltd. 70 Anson Road #19-01 To 08, Apex Tower Singapore/079905/Singapore Phone:65-6223-0225 FAX: 65-6223-0986 SANYO Electronic Components (HK) Limited Suite 3601-06, 36/F, Tower 6, The Gateway, Harbour City, 9 Canton Road, T.S.T., Kowloon, Hong Kong. Phone:852-2301-0529 FAX: 852-2301-2255 Modifyingthesubjectsandspecificationsinthiscataloguewithoutanynotice.