Power Meter Front End Design: The Delta Connection Atmel's AT73C500 + AT73C501-based meter chipset measures power and energy in three-phase systems or, alternatively, the chipset can be set to operate in a mode where it measures three separate, single-phase connections. In normal modes of operation, the chipset measures Y-connected threephase, four-wire environments, but there is no dedicated operating mode for Delta-connected three-phase, three-wire systems. This application note describes how to implement the chipset in threephase, three-wire environments. * The Main Current (I1, I2 and I3) is defined as the current that flows through the phase conductor. Depending on the type of connection, this current is not necessarily the same that flows through the load. Three-Phase Basics The Star Connection To understand the measurement method, it is important to outline some of the following basic concepts. A typical three-phase, four-wire service with a grounded neutral is illustrated in Figure 1. The system shown is commonly referred to as a YN-configuration, with the subscript denoting there is a neutral wire present. The wiring method is sometimes also referred to as Star connection. Terminology Voltages (and currents) in a three-phase system are referred to as either phase voltages (currents) or main voltages (currents), depending on the point of reference. * A Phase Voltage(1) (UP1, UP2 and UP3) is always referenced to the neutral wire. In systems where there is no physical neutral wire, the phase voltages are referenced to a virtual neutral. Note: 1. Also called neutral voltage. This should not be confused with the ground neutral that is at zero potential. * The Main Voltage (U1, U2 and U3) is defined as the voltage between two of the phase conductors. * A Phase Current (IP1, IP2 and IP3) is the current flowing through the load impedance. Depending on the type of connection, this current is not necessarily directly measurable from the meter connection points, but must be derived from the vector sum of other currents. Power Meter Front End Design: The Delta Connection Application Note In Figure 1, the circuit on the left illustrates the power generator and the circuit on the right the load. In this type of connection, the energy meter would interface to measure the phase voltages (U P1 , U P2 and U P3 ) and phase currents (IP1, IP2 and IP3). In a balanced (all loads are equal) Star connection, the neutral line carries no current and the main current is equal to the phase current. The main voltage is related to the phase voltage as follows: U = 3 x UP Rev. 1680A-07/00 1 Figure 1. Three-phase, Four-wire, YN-connection I1 L1 IP1 U1 UP1 N U2 UP2 L2 Z1 I2 Z2 IP3 U3 Z3 I3 L3 UP3 IP2 IN The Delta Connection The number of wires may be reduced from four to three, if the load is wired in Delta-configuration. It is noted that the generator does not necessarily have to be wired in Deltaconfiguration, it can also be Star-connected. An example of both the generator and the load-connected in Delta-configuration is illustrated in Figure 2. (measured between phase conductors). When recalculating main voltages to phase voltages, the voltages are referenced to a virtual neutral wire. The connection in Figure 2 contains no neutral wire and the inherent voltage marking therefore refers to main voltages I = 3 x IP It is noted, that in a balanced Delta connection, the relationship between phase current and main current is: Figure 2. Three-phase, Three-wire, Delta Connection I1 L1 Z 31 U1 UP1 I2 L2 L3 U2 UP2 IP3 Z 23 IP2 U3 I3 UP3 IN VIRTUAL GROUND POTENTIAL 2 Meter Front End Design Z 12 IP1 Meter Front End Design Front End Connections The schematic diagram on page 7 shows a method for connecting the A/D converter to three-wire service. The example Delta connection is rated for a 230/400V system, but may easily be adapted to any other rating. The Voltage Front End front end should allow for a 15% voltage overhead, as specified in IEC standards (see Table 1). To achieve the ratings in Table 1, we start by defining resistors R4 = R5 = R6 = 1 kohm, and get: U x 2 - 1 x R4 380kohm R1 = R2 = R3 = PFS u IN The two transformers (Tr1 and Tr2) together with the resistor network R1 through R6 convert the main voltages to phase voltages. The conversion factor (the number of primary windings per number of secondary windings) of the transformers is 1:1. Using a standard valued resistor of 390 kohm, the maximum voltage for this configuration will be approximately 275V (i.e., about 390V peak amplitude). The voltage maximum should later be fine-tuned to 270V during factory calibration. Resistors R1, R2 and R3 must be scaled to match the voltage of the system in order for the ADC inputs not to exceed the maximum peak rating of 1 volt. ADC voltage maximum should be reached at maximum main voltage of the system front end. It may be assumed that the main voltage is equal for all three phases and, therefore, that the maximum input voltage to the converter, uIN, can be calculated from any one of the following: The above calculations may be repeated to adapt the design for any voltage system, but the maximum voltage of the meter front end must be considered when reading data or pulses from the meter. It should be noted that the default bit resolution of data registers and the meter constant of pulse outputs are based on a 270V maximum voltage. u IN = R4 R5 R6 x UPFS x 2 = x UPFS x 2 = x UPFS x 2 R1 + R4 R2 + R5 R3 + R6 We assume a system where the phase voltage is 230V and, consequently, the main voltage 400V. The analog It should also be noted that the DSP now measures phase voltages of a Delta-connected load. For example, the meter software of the ATEK5003 (The Evaluation Kit for the AT73C500 chipset) displays RMS voltage values with respect to the phase voltage and not the main voltage.. Table 1. Voltage Ratings at Various Circuit Nodes Path Voltage Node Symbol Nominal Maximum Unit Phase1 Phase2 Phase3 U1 U2 U3 400 460 VRMS Tr1/3 - GND Tr1/4 - GND Tr2/4 - GND UP1 UP2 UP3 230 270 VRMS C1 C2 C3 VI1 VI2 VI3 0.602 0.707 VRMS Tr3/Primary Tr4/Primary Tr5/Primary I1 I2 I3 - 80 ARMS C4 C5 C6 CI1 CI2 CI3 - 0.707 VRMS Current 3 The Current Front End Current transformers Tr3, Tr4 and Tr5 are used for sensing the phase current, which goes through the primary winding. The transformers should have a conversion factor, M, such that, at maximum rated phase current, the secondary current, which goes through the shunt resistors (R7, R8 and R9) does not produce more than 1-volt peak amplitude at the ADC input. The higher the conversion factor of the transformer, the lower the value of the shunt resistor and vice versa. It should be noted that for high resistive values, the signal distortion in the current transformer is low, but the thermal noise in the resistor is high. On the other hand, for low resistive values, the thermal noise is lower, but the power dissipation of the resistor is higher. In addition, the current transformer may distort the signal if the load on the secondary winding is too high. As a compromise, the example wiring uses current transformers with a conversion factor of 2500 and shunt resistors of 22 ohms. The full-scale current rating is 80A, at which the RMS voltage at the ADC input is: UIN = R 7 x I I I1 80A = R 8 x 2 = R 9 x 3 = 22 x = 0.704V M M 2500 M The peak amplitude at the ADC input is then: u IN = 2 x UIN = 0.9956V It should be noted that the current measured by the chipset is the main current. In a Start Connection, this is of no importance, since the phase and main currents are equal, but in the Delta-configuration this must be accounted for. Measurement Method The DSP uses the same calculation methods, regardless of type of connection, since there is no special mode setting for connecting the device to a Delta load. The differences in measurement method, as compared to the default Star connection are due to the wiring of the front end and the conditioning of signal amplitudes. Using the front end connections illustrated in the schematic on page 7, the DSP will measure phase voltages and main currents for each phase. The measurement results, available via the data registers, do not necessarily give straightforward indications on the condition of the phase loads in a Delta connection. For example, the RMS values of phase voltages and main currents cannot be used to derive the power consumption of one phase load, since the Delta-wired load is connected between two phase nodes, as shown in Figure 3. The DSP will give measurement results as if the load was connected in Star. Measurement results must therefore be related to the equivalent Star connection as shown in Figure 4. Please note that the load impedances of the equivalent connection are not the same as those for the actual Delta connection. For example, the active power readings for phase one indicates how much power has been consumed in the equivalent load of Z1 and not how much power has been consumed in any of the true loads of the Delta connection. Figure 3. The Delta-connected Load I1 U1 UP1 IP3 Z 31 Z 12 I2 IP2 U2 UP2 U3 I3 UP3 VIRTUAL GROUND POTENTIAL 4 Meter Front End Design IP1 Z 23 Meter Front End Design Figure 4. Equivalent, Unbalanced Star Connection without Neutral Wire I1 = IP1 UP1 Z1 U1 I2 = IP2 Z2 U2 UP2 U3 Z3 I3 = IP3 UP3 VIRTUAL GROUND POTENTIAL Summary In Delta-configuration, data registers should be interpreted as shown in Table 2. Table 2. Delta-configuration Variable Register P1 0 P2 1 P3 2 Q1 3 Q2 4 Q3 5 S1 6 S2 7 S3 8 Measure Note Active Power Power consumed in equivalent phase load Reactive Power Power consumed in equivalent phase load Apparent Power Power consumed in equivalent phase load Power Factor Between main current and phase voltage PF1 9 PF2 10 PF3 11 WPE 12 Active Power Exported WPI 13 Active Power Imported WQI 14 Reactive Power, Ind. Load WQC 15 Reactive Power, Cap. Load TIME 16 Time Since Reset Not affected FREQ 17 Line Frequency Not affected RMS Voltage Phase voltage RMS Current Main current Total power in all loads Total powerin all loads U1 19 U2 20 U3 21 I1 22 I2 23 I3 24 5 Typically, it is of no importance if the individual phase powers reported are relative to a Star or Delta connection, as long as the overall power readings are correct. Regardless if the chipset is wired to a default Star load or the Delta load, as illustrated in the schematic on page 7, the overall power readings are always obtained by summing the individual phase registers. When wired to a Delta load, it must be noted that individual phase power information is correct only in the special case 6 Meter Front End Design when both the generator and the load are balanced. If the load or supply is unbalanced (even if the generator is balanced, impedances in the transmission lines may result in unbalanced voltages), then only the sum of the individual phase power readings will be valid for the Delta connection. Individual phase powers cannot be evaluated for an unbalanced Delta load. Meter Front End Design Figure 5. Front End Connection Schematic 7 Atmel Headquarters Atmel Operations Corporate Headquarters Atmel Colorado Springs 2325 Orchard Parkway San Jose, CA 95131 TEL (408) 441-0311 FAX (408) 487-2600 Europe 1150 E. Cheyenne Mtn. Blvd. Colorado Springs, CO 80906 TEL (719) 576-3300 FAX (719) 540-1759 Atmel Rousset Atmel U.K., Ltd. Coliseum Business Centre Riverside Way Camberley, Surrey GU15 3YL England TEL (44) 1276-686-677 FAX (44) 1276-686-697 Zone Industrielle 13106 Rousset Cedex France TEL (33) 4-4253-6000 FAX (33) 4-4253-6001 Asia Atmel Asia, Ltd. Room 1219 Chinachem Golden Plaza 77 Mody Road Tsimhatsui East Kowloon Hong Kong TEL (852) 2721-9778 FAX (852) 2722-1369 Japan Atmel Japan K.K. 9F, Tonetsu Shinkawa Bldg. 1-24-8 Shinkawa Chuo-ku, Tokyo 104-0033 Japan TEL (81) 3-3523-3551 FAX (81) 3-3523-7581 Fax-on-Demand North America: 1-(800) 292-8635 International: 1-(408) 441-0732 e-mail literature@atmel.com Web Site http://www.atmel.com BBS 1-(408) 436-4309 (c) Atmel Corporation 2000. Atmel Corporation makes no warranty for the use of its products, other than those expressly contained in the Company's standard warranty which is detailed in Atmel's Terms and Conditions located on the Company's web site. The Company assumes no responsibility for any errors which may appear in this document, reserves the right to change devices or specifications detailed herein at any time without notice, and does not make any commitment to update the information contained herein. No licenses to patents or other intellectual property of Atmel are granted by the Company in connection with the sale of Atmel products, expressly or by implication. Atmel's products are not authorized for use as critical components in life suppor t devices or systems. Marks bearing (R) and/or TM are registered trademarks and trademarks of Atmel Corporation. Terms and product names in this document may be trademarks of others. Printed on recycled paper. 1680A-07/00/xM