Safety Guidelines
This manual contains notices you have to observe in order to ensure your personal safety, as well as to prevent
damage to property. The notices referring to your personal safety are highlighted in the manual by a safety alert
symbol, notices referring only to property damage have no safety alert symbol. These notices shown below are
graded according to the degree of danger.
DANGER
indicates that death or severe personal injury will result if proper precautions are not taken.
WARNING
indicates that death or severe personal injury may result if proper precautions are not taken.
CAUTION
with a safety alert symbol, indicates that minor personal injury can result if proper precautions are not taken.
CAUTION
without a safety alert symbol, indicates that property damage can result if proper precautions are not taken.
NOTICE
indicates that an unintended result or situation can occur if the corresponding information is not taken into
account.
If more than one degree of danger is present, the warning notice representing the highest degree of danger will
be used. A notice warning of injury to persons with a safety alert symbol may also include a warning relating to
property damage.
Qualified Personnel
The device/system may only be set up and used in conjunction with this documentation. Commissioning and
operation of a device/system may only be performed by qualified personnel. Within the context of the safety notes
in this documentation qualified persons are defined as persons who are authorized to commission, ground and
label devices, systems and circuits in accordance with established safety practices and standards.
Prescribed Usage
Note the following:
WARNING
This device may only be used for the applications described in the catalog or the technical description and only
in connection with devices or components from other manufacturers which have been approved or
recommended by Siemens. Correct, reliable operation of the product requires proper transport, storage,
positioning and assembly as well as careful operation and maintenance.
Trademarks
All names identified by ® are registered trademarks of the Siemens AG. The remaining trademarks in this
publication may be trademarks whose use by third parties for their own purposes could violate the rights of the
owner.
Disclaimer of Liability
We have reviewed the contents of this publication to ensure consistency with the hardware and software
described. Since variance cannot be precluded entirely, we cannot guarantee full consistency. However, the
information in this publication is reviewed regularly and any necessary corrections are included in subsequent
editions.
Siemens AG
Automation and Drives
Postfach 48 48
90327 NÜRNBERG
GERMANY
A5E01602431-02
Ⓟ 04/2008
Copyright © Siemens AG 2008.
Technical data subject to change
SIMATIC RF620T
Operating Instructions, 04/2008, A5E01602431-02 3
Table of contents
1 SIMATIC RF620T Operating Instructions .................................................................................................. 5
1.1 Characteristics ...............................................................................................................................5
1.2 Ordering data .................................................................................................................................6
1.3 Planning the use ............................................................................................................................6
1.3.1 Reading range when mounted on non-metallic carriers ................................................................6
1.3.2 Directional radio pattern of the transponder on non-metallic surfaces ..........................................7
1.3.3 Optimum antenna/transponder positioning with plane mounting of the transponder on
metal ............................................................................................................................................10
1.3.4 Reading range on flat metallic carrier plates ...............................................................................11
1.3.5 Influence of conducting walls on the reading range.....................................................................12
1.3.6 Directional radio pattern of the transponder on metallic surfaces ...............................................14
1.3.7 Reading range when mounted on ESD carrier materials ............................................................15
1.3.8 Communication with multiple transponders .................................................................................16
1.4 Mounting instructions ...................................................................................................................17
1.5 Memory configuration ..................................................................................................................18
1.6 Technical Specifications ..............................................................................................................21
1.6.1 Mechanical data...........................................................................................................................21
1.6.2 Electrical data...............................................................................................................................21
1.6.3 Memory specifications .................................................................................................................22
1.6.4 Environmental conditions.............................................................................................................22
1.6.5 Chemical resistance of the transponder RF620T ........................................................................22
1.7 Certificates and approvals ...........................................................................................................26
1.7.1 Certificates and approvals ...........................................................................................................26
1.8 Dimension drawing ......................................................................................................................27
Table of contents
SIMATIC RF620T
4 Operating Instructions, 04/2008, A5E01602431-02
SIMATIC RF620T
Operating Instructions, 04/2008, A5E01602431-02 5
SIMATIC RF620T Operating Instructions 1
1.1 Characteristics
The SIMATIC RF620T Transponder is passive and maintenance-free, based on the UHF
Class 1 Gen2 technology for storing 96-bit electronic product codes (EPC)
The container tag for industrial applications is rugged and highly resistant to detergents. It is
designed for easy attachment onto plastic, wood, glass, e.g. containers, palettes, and
trolleys
The optimum functionality/range of the RF620T on metal is achieved by means of the
spacer.
Since the plastic is food safe, it is also suitable for use in the food-processing industry.
This container tag is designed for the frequency ranges 868 MHz (Europe) and 915 MHz
(USA) and can be operated in combination with our UHF system RF660.
SIMATIC RF620T Transponder Characteristics
Area of application Transponder for rugged, industrial
requirements such as RF identification in
warehouses and the logistics and transport
area.
Europe USA / Canada Frequency versions
868 MHz 915 MHz
Polarization Linear
Memory EPC 96 bit
Read/write range
• with non-metallic
carriers
• direct on metallic
carriers
• with spacer on metallic
carriers
• typically 0.2 to 6 m
• typically 0.2 to 2 m
• typically 0.2 to 4 m
Mounting • screw, bond
• on metal by means of spacers
① Labeling area You can inscribe the transponder itself using
laser, or adhere a label to position ①.
Possible types of labeling:
• Barcode
• Inscription in plain text
• Data matrix code
Housing color Anthracite
SIMATIC RF620T Operating Instructions
1.2 Ordering data
SIMATIC RF620T
6 Operating Instructions, 04/2008, A5E01602431-02
1.2 Ordering data
Ordering data Order No.
SIMATIC RF620T
• Frequency 865 MHz to 928 MHz,
• UHF Class 1 Gen2 technology (96 bit)
• -25 °C to +80 °C operating temperature
• Dimensions (L x W x H) 127 x 38 x 6 mm
• IP 67 degree of protection
6GT2810-2HC80
Spacer for SIMATIC RF620T
• For attaching to metal surfaces
• Dimensions (L x W x H) 155 x 38 x 12 mm
6GT2898-2AA00
1.3 Planning the use
1.3.1 Reading range when mounted on non-metallic carriers
The transponder is generally designed for mounting on metallic objects which provide the
conditions for the maximum reading ranges
Table 1-1 Reading range on non-metallic carriers
Carrier plate material Reading range
Transponder on wooden carrier
(dry, degree of moisture < 15%)
typ. 6 m
Transponder on plastic carrier typ. 6 m
Transponder on glass typ. 6 m
Transponder on plastic mineral water bottle typ. 1.2 m
100% reading range is achieved when mounted in empty, anechoic rooms.
SIMATIC RF620T Operating Instructions
1.3 Planning the use
SIMATIC RF620T
Operating Instructions, 04/2008, A5E01602431-02 7
1.3.2 Directional radio pattern of the transponder on non-metallic surfaces
Preferably, align the data carrier parallel to the transmitting antenna. If, however, the data
carrier including the metallic carrier plate is tilted, the reading range will be reduced.
Rotation about the polarization axis
3RODUL]DWLRQD[LV
Figure 1-1 Rotation of the transponder about the polarization axis
Generally the range does not change when the transponder without carrier material is
rotated about the polarization axis.
SIMATIC RF620T Operating Instructions
1.3 Planning the use
SIMATIC RF620T
8 Operating Instructions, 04/2008, A5E01602431-02
Rotation orthogonal to the polarization axis
0
10
20
30
40
50
60
70
80
90
100
-180 -160 -140 -120 -100 -80 -60 -40 -20 0 20 40 60 80 100 120 140 160 180
$QJOHGHJUHHV
5DQJH
Figure 1-2 Transponder characteristics when rotated orthogonally to the polarization axis (within the
tag plane)
SIMATIC RF620T Operating Instructions
1.3 Planning the use
SIMATIC RF620T
Operating Instructions, 04/2008, A5E01602431-02 9
If the transponder is positioned orthogonally to the transmitting antenna, it normally cannot
be read. Therefore the data carrier is preferably to be aligned parallel to the transmitting
antenna. The following figure illustrates this situation.
Figure 1-3 Application example for possible orientations of the transponder.
SIMATIC RF620T Operating Instructions
1.3 Planning the use
SIMATIC RF620T
10 Operating Instructions, 04/2008, A5E01602431-02
1.3.3 Optimum antenna/transponder positioning with plane mounting of the transponder
on metal
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Figure 1-4 Example of optimum antenna/transponder positioning
SIMATIC RF620T Operating Instructions
1.3 Planning the use
SIMATIC RF620T
Operating Instructions, 04/2008, A5E01602431-02 11
1.3.4 Reading range on flat metallic carrier plates
The transponder generally has linear polarization. The polarization axis runs as shown in the
diagram below. If the tag is centrically mounted on a flat metal plate, which may either be
almost square or circular, it can be aligned in any direction since the transmitting and
receiving RF660A antennas operate with circular polarization.
3RODUL]DWLRQD[LV
6TXDUH
PHWDOVXSSRUW
&LUFXODUPHWDO
FDUULHUSODWH
r
Figure 1-5 Optimum positioning of the transponder on a (square or circular) metal carrier plate
Table 1-2 Reading range with metallic, plane carriers without spacer
Carrier plate material Reading range Europe Reading range USA
Metal plate at least 300 x 300 mm typ. 2 m typ. 1.5 m
Metal plate 150 x 150 mm typ. 1.5 m typ. 1 m
Table 1-3 Reading range with metallic, plane carriers with spacer
Carrier plate material Reading range Europe Reading range USA
Metal plate at least 300 x 300 mm typ. 4 m typ. 6 m
Metal plate 150 x 150 mm typ. 2 m typ. 4.5 m
The use of spacers on metallic surfaces is therefore recommended.
On rectangular carrier plates, the reading distance depends on the mounting orientation of
the transponder A 90° rotation of the transponder about the axis of symmetry may result in
greater reading distances
SIMATIC RF620T Operating Instructions
1.3 Planning the use
SIMATIC RF620T
12 Operating Instructions, 04/2008, A5E01602431-02
1.3.5 Influence of conducting walls on the reading range
If there are conducting walls or restrictions in the vicinity that could shade the radio field, a
distance of approx. 10 cm is recommended between the transponder and the wall In
principle, walls have least influence if the polarization axis is orthogonal to the conducting
wall. A spacer must be used in any case.
Reading range: One conducting wall
Dependence of the reading distance when positioned orthogonally to the conducting wall
G
&RQGXFWLQJZDOO
3RODUL]DWLRQD[LV
Top view
Distance d 20 mm 50 mm 100 mm
Approx. 100% Approx. 100% Approx. 100% Wall height 20 mm
Approx. 100% Approx. 100% Approx. 100% Wall height 50 mm
Reading range
Approx. 80% Approx. 100% Approx. 100% Wall height 100 mm
Dependence of the reading distance when positioned parallel to the conducting wall
G
&RQGXFWLQJZDOO
3RODUL]DWLRQD[LV
Top view
Distance d 20 mm 50 mm 100 mm
Approx. 70 % Approx. 100% Approx. 100% Wall height 20 mm
Approx. 60 % Approx. 90 % Approx. 100% Wall height 50 mm
Reading range
Approx. 30 % Approx. 70 % Approx. 100% Wall height 100 mm
SIMATIC RF620T Operating Instructions
1.3 Planning the use
SIMATIC RF620T
Operating Instructions, 04/2008, A5E01602431-02 13
Reading range: Two conducting walls
Influence on reading range when positioned against two conducting walls
G
G
&RQGXFWLQJZDOO
&RQGXFWLQJZDOO
3RODUL]DWLRQD[LV
Top view
G
&RQGXFWLQJZDOO
&RQGXFWLQJZDOO
:DOOKHLJKW
Side view
Distance d 20 mm 50 mm 100 mm
Approx. 70 % Approx. 100% Approx. 100% Wall height 20 mm
Approx. 60 % Approx. 90 % Approx. 100% Wall height 50 mm
Reading range
Approx. 30 % Approx. 70 % Approx. 100% Wall height 100 mm
The values specified in the tables above are reference values.
SIMATIC RF620T Operating Instructions
1.3 Planning the use
SIMATIC RF620T
14 Operating Instructions, 04/2008, A5E01602431-02
1.3.6 Directional radio pattern of the transponder on metallic surfaces
Preferably, align the data carrier parallel to the transmitting antenna. If, however, the data
carrier including the metallic carrier plate is tilted, the reading range will be reduced.
Rotation about the polarization axis or orthogonal to the polarization axis
r
r
r
r
0
10
20
30
40
50
60
70
80
90
100
-170
-150
-130
-110
-90
-70
-50
-30
-10
10
30
50
70
90
110
130
150
170
3RODUL]DWLRQD[LV
2UWKRJRQDOD[LV
5HDGLQJUDQJH
$QJOHGHJUHHV
Figure 1-6 Characteristic of the transponder when rotated about the polarization axis or orthogonally
to the polarization axis
SIMATIC RF620T Operating Instructions
1.3 Planning the use
SIMATIC RF620T
Operating Instructions, 04/2008, A5E01602431-02 15
1.3.7 Reading range when mounted on ESD carrier materials
The transponder is generally designed for mounting on non-conductive objects which
provide the conditions for the maximum reading ranges The conductive or dissipative
surface of ESD materials limits the reading range depending on the surface resistance.
Generally, dissipative materials with a surface resistance of 1 x 105 to 1 x 1011 ohm and
conductive materials with 1 x 103 to 1 x 105 ohm are available.
Table 1-4 Limited reading range with ESD materials
Carrier plate material Reading range
Transponder on electrostatic dissipative
materials, dimensions 60 x 40 cm
(surface resistance 2 x 109 ohm)
Approx. 4 m
Transponder on electrostatic conductive
materials, dimensions 60 x 40 cm
(surface resistance 1 x 104 ohm)
Use of spacers
Approx. 1 m
Approx. 2 m
100% reading range is achieved when mounted in empty, anechoic rooms. With multi-tag
capability, limitations may result in the reading range.
0
10
20
30
40
50
60
70
80
90
100
1x10
0
1x10
1
1x10
2
1x10
3
1x10
4
1x10
5
1x10
6
1x10
7
1x10
8
1x10
9
1x10
10
1x10
11
5HDGLQJUDQJH
6XUIDFHUHVLVWDQFHRKP
Figure 1-7 Schematic representation of how the reading range depends on the surface resistance of the ESD material
In the representation above, the two reading points with regard to the dependence of the
reading range in % on the surface resistance are shown At the same time a linear
dependence between the reading points is to be expected, however with measurement
inaccuracies. The darker the hatching, the greater the probability that the reading point is
found in the hatched area.
SIMATIC RF620T Operating Instructions
1.3 Planning the use
SIMATIC RF620T
16 Operating Instructions, 04/2008, A5E01602431-02
1.3.8 Communication with multiple transponders
The RF600 system is multitag-capable. This means that the reader can detect and write to
several transponders almost simultaneously. The minimum distance between the
transponders is ≥ 50 mm.
PP
Figure 1-8 Multitag reading
SIMATIC RF620T Operating Instructions
1.4 Mounting instructions
SIMATIC RF620T
Operating Instructions, 04/2008, A5E01602431-02 17
1.4 Mounting instructions
CAUTION
Level mounting
Please note that both the transponder and the spacer must be mounted on a level surface.
CAUTION
The screw fixing element was tested with the types of screws, spring washers and plain
washers indicated below. Depending on the application area, the user must use similar,
correspondingly certified screws, spring washers and plain washers (e.g. for the food
processing industry).
EJOT screws can be additionally etched and passivated in some areas of the food
processing industry, e.g if they made of stainless steel A2. In other areas without special
requirements, the screws can be, for example, zinc plated and blue passivated.
Note
In case of high mechanical loads (such as shocks or vibration), the transponder must be
fixed onto the spacer by means of screws.
SIMATIC RF620T Operating Instructions
1.5 Memory configuration
SIMATIC RF620T
18 Operating Instructions, 04/2008, A5E01602431-02
Properties Description Graphics
• Transponder • Screw mounting (e.g. 2 x M4
hexagon socket head cap screws
ISO 4762, spring lock and
grommet ISO 7092)
or glued
• Transponder on
spacer
• Clips or screw on the side of the
clip, or 2 screws (e.g. z.B.
EJOT PT ® WN 5411 35x10 VZ
crosshead srew/torx)
Mounting type
• Spacer • Screw mounting (e.g. 2 x M4
hexagon socket head cap screws
ISO 4762, spring lock and
grommet ISO 7092) or glued or
with adhesive tape
Tightening torque (at room temperature) < 1.2 Nm
1.5 Memory configuration
Memory banks
The memory is divided logically into three different memory banks:
Memory bank (decimal) Memory type Description
MemBank 102 TID Is defined by the manufacturer, contains the class identifier of a tag
MemBank 012 EPC Contains the EPC UID, the protocol and the CRC of a tag
MemBank 002 RESERVED Contains the access and kill password
The graphic below illustrates the exact memory utilization: Each box in the right part of the
graphic represents one word (16 bit) in the memory.
SIMATIC RF620T Operating Instructions
1.5 Memory configuration
SIMATIC RF620T
Operating Instructions, 04/2008, A5E01602431-02 19
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Color Access by SIMATIC RF660R / SIMATIC RF610M
Read
Write / read
Reading the memory bit
The EPC ID is automatically read during the sensing cycle of the stationary or mobile reader.
(see "SIMATIC RF660R Parameterization Manual", Section "EPC Class 1 GEN 2 protocol
settings" or "SIMATIC RF610M Instruction Manual").
In addition, the TID, the EPC ID, the protocol command bits, the CRC-16 bits, the access
password and the kill password can be read using the "tagDataRead" XML command. (see
"SIMATIC RF660R Function Manual", Section "Smart reader tag data reading" and Section
"FCC channel ID settings").
SIMATIC RF620T Operating Instructions
1.5 Memory configuration
SIMATIC RF620T
20 Operating Instructions, 04/2008, A5E01602431-02
Reserved memory bank: programming or modifying memory areas
The memory areas of the reserved memory bank can be programmed using the SIMATIC
RF660R reader:
● Using the "tagDataWrite" XML command (see "SIMATIC RF660R Function Manual",
Section "Smart reader tag data writing")
Alternatively, the memory areas of the reserved memory bank can be modified using the
mobile RF610M reader:
● Using the "Write" function in the data editor (see "SIMATIC RF610M Instruction Manual",
Section "Write tag")
EPC memory bank: programming or modifying EPC ID
The EPC ID can be programmed using the SIMATIC RF660R reader:
● Using the "tagProgramID" XML command (see "SIMATIC RF660R Function Manual",
Section "Smart reader tag ID programming")
Alternatively, the EPC ID can be modified using the mobile RF610M reader:
● Using the "Write ID" function (see "SIMATIC RF610M" Instruction Manual, Section "Write
ID"
SIMATIC RF620T Operating Instructions
1.6 Technical Specifications
SIMATIC RF620T
Operating Instructions, 04/2008, A5E01602431-02 21
1.6 Technical Specifications
1.6.1 Mechanical data
Property Description
Dimensions (L x W x H)
• Transponder
• Spacer
• 127 x 38 x 6 mm
• 157 x 39 x 12 mm
Design Plastic enclosure (PP; food safe)
Housing color Anthracite
Weight
• Transponder
• Spacer
• Transponder with spacer
• Approx. 18 g
• Approx. 22 g
• Approx. 40 g
Mounting on metal Preferably with spacer
1.6.2 Electrical data
Description Property
Europe USA / Canada
Air interface According to ISO 18 000/ISO -6
Frequency range 865 … 868 MHz 915 MHz
Necessary2) transmit power 2 W (ERP) 4 W (EIRP)
Read distance
• non-metallic carriers
• on conductive plastic
• on metal using spacers1)
• typ. 6 m
• typ. 1 m
• typ. 4 m
Write distance
• non-metallic carriers
• on conductive plastic
• on metal using spacers1)
• typ. 4 m
• typ. 0.7 m
• typ. 3 m
Polarization type Linear
Minimum distance to transmitting
antenna
Approx. 0.2 m
Energy source Radio field energy via antenna, without battery
Multi-tag capability Yes, minimum distance between data carriers ≥ 50 mm
1) Metallic surface approx. 30 x 30 cm
2) Maximum read/write distances
See also
Reading range when mounted on ESD carrier materials (Page 15)
Reading range on flat metallic carrier plates (Page 11)
Reading range when mounted on non-metallic carriers (Page 6)
SIMATIC RF620T Operating Instructions
1.6 Technical Specifications
SIMATIC RF620T
22 Operating Instructions, 04/2008, A5E01602431-02
1.6.3 Memory specifications
Property Description
Type EPC Class 1 Gen2
Memory organization EPC code 96 bit
Protocol ISO 18000-6C
Data retention time 10 years
Read cycles Unlimited
Write cycles 100 000 min.
1.6.4 Environmental conditions
Property Description
Temperature range during operation -25 °C … +80 °C
Temperature range during storage -40 °C to +70 °C
Shock
Vibration
compliant with EN 60721-3-7 Class 7 M3
100 g,
50 g
Torsion and bending load Not permissible
Degree of protection IP 67
1.6.5 Chemical resistance of the transponder RF620T
The following table provides an overview of the chemical resistance of the data memory
made of polypropylene.
Concentration 20 °C 50 °C
Emissions
alkaline/containing hydrogen fluoride
/carbon dioxide
Low ○○○○ ○○○○
Emissions containing hydrochloric acid ○○○○ ○○○○
Emissions containing sulphuric acid ○○○○ -
Battery acid 38 ○○○○ ○○○○
Aluminum acetate, w. ○○○○ ○○○○
Aluminum chloride 10 ○○○○ ○○○○
Aluminum nitrate, w. ○○○○ ○○○○
Aluminum salts ○○○○ ○○○○
Formic acid 50 ○○○○ -
Aminoacetic acid (glycocoll, glycine) 10 ○○○○ ○○○○
SIMATIC RF620T Operating Instructions
1.6 Technical Specifications
SIMATIC RF620T
Operating Instructions, 04/2008, A5E01602431-02 23
Concentration 20 °C 50 °C
Ammonia gas ○○○○ ○○○○
Ammonia 25 ○○○○ ○○○○
Ammonia, w. conc. ○○○○ ○○○○
10 ○○○○ ○○○○
Arsenic acid, w. ○○○○ ○○○○
Ascorbic acid, w. ○○○○ ○○○○
Petroleum spirit - -
Benzene ○○ -
Prussic acid, w. ○○○○ ○○○○
Sodium hypochlorite solution diluted /
20
○○○○ ○○
50 ○○ ○○
Borax ○○○○ ○○○○
Boric acid, w. 10 ○○○○ ○○○○
Brake fluid ○○○○ ○○○○
Bromine - -
Butane, gas, liquid techn. pure ○○○○ ○○○○
Butyl acetate (acetic acid butyl ester) ○○ -
Calcium chloride, w./ alcoholic ○○○○ ○○○
Calcium chloride, ○○○○ ○○○○
Calcium nitrate, w. ○○○○ ○○○○
50 ○○○○ ○○○○
Chlorine ᅳ ᅳ
Chloroacetic acid ○○○○ ○○○○
Chloric acid 20 ○○○○ -
Chrome baths, tech. ᅳ ᅳ
Chromium salts ○○○○ ○○○○
Chromic acid 10 ○○○○ ○○○○
20 / 50 ○○ ○○
Chromic acid, w ○○○○ ○○
Chromosulphuric acid conc. - -
Citric acid 10 ○○○○ ○○○○
Diesel fuel ○○○○
Diesel oil 100 ○○○○
Diglycole acid 30 ○○○○ ○○○○
Iron salts, w. k. g. ○○○○ ○○○○
Vinegar ○○○○ ○○○○
Acetic acid 5 / 50 ○○○○ ○○○○
Ethanol 50 / 96 ○○○○ ○○○○
Ethyl alcohol 96 / 40 ○○○○ ○○○○
Fluoride ○○○○ ○○○○
SIMATIC RF620T Operating Instructions
1.6 Technical Specifications
SIMATIC RF620T
24 Operating Instructions, 04/2008, A5E01602431-02
Concentration 20 °C 50 °C
Formaldehyde 10 ○○○○ ○○○○
40 ○○○○ ○○○
Formaldehyde solution 30 ○○○○ ○○○○
Glycerin any ○○○○ ○○○○
Glycol ○○○○ ○○○○
Uric acid ○○○○
HD oil, motor oil, without aromatic
compounds
○○○○
Fuel oil ○○○○
Isopropanol techn. pure ○○○○ ○○○○
Potassium hydroxide, w. ○○○○ ○○○○
Potassium hydroxide 10 / 50 ○○○○ ○○○○
Silicic acid any ○○○○ ○○○○
Common salt ○○○○ ○○○○
Carbonic acid saturated ○○○○ ○○○○
Lysol ○○○○ ○○
Magnesium salts, w. k. g. ○○○○ ○○○○
Magnesium salts any ○○○○ ○○○○
Machine oil 100 ○○○○
Sea water ○○○○ ○○○○
Methanol ○○○○ ○○○○
Methyl alcohol, w. 50 ○○○○ ○○○○
Lactic acid, w. ○○○○ ○○○○
Lactic acid 3 / 85 ○○○○ ○○○
80 ○○○○ ○○○○
Engine oil ○○○○
Sodium carbonate, w. (soda) k. g. ○○○○ ○○○○
Sodium carbonate ○○○○ ○○○○
Sodium chloride, w. k. g. ○○○○ ○○○○
Sodium hydroxide, w. ○○○○ ○○○○
Sodium hydroxide solution, w. ○○○○ ○○○○
Sodium hydroxide solution 30 / 45 / 60 ○○○○ ○○○○
Nickel salts, w. k. g. ○○○○ ○○○○
Nickel salts saturated ○○○○ ○○○○
Nitrobenzol ○○○ ○○
Oxalic acid ○○○○ ○○○○
Petroleum techn. pure ○○○○
Phosphoric acid 1-5 / 30 ○○○○ ○○○○
85 ○○○○ ○○○
Phosphoric acid, w 20 ○○○○ ○○○○
Propane liquid ○○○○
Propane gaseous ○○
SIMATIC RF620T Operating Instructions
1.6 Technical Specifications
SIMATIC RF620T
Operating Instructions, 04/2008, A5E01602431-02 25
Concentration 20 °C 50 °C
Mercury pure ○○○○ ○○○○
Crude oil 100 ○○○○ ○○
Ammonium chloride 100 ○○○○ ○○○○
Ammonium chloride, w. ○○○○ ○○○○
Nitric acid - -
50 ○○
1-10 ○○○○ ○○○○
Hydrochloric acid 1-5 / 20 ○○○○ ○○○○
35 ○○○○ ○○○
conc. ○○○○ ○○○○
Sulphur dioxide Low ○○○○ ○○○○
moist ○○○○ ○○
liquid - -
Sulphuric acid 1-6 / 40 / 80 ○○○○ ○○○○
20 ○○○○ ○○○
60 ○○○○ ○○
95 ○○ -
fuming - -
Hydrogen sulphide Low/saturated ○○○○ ○○○○
Detergent High ○○○○ ○○○○
Water ○○○○ ○○○○
Hydrogen techn. pure ○○○○ ○○○○
Plasticizer ○○○○ ○○
Abbreviations
○○○○ Resistant
○○○ Virtually resistant
○○ Limited resistance
○ Less resistant
ᅳ Not resistant
w. Aqueous solution
k. g. Cold saturated
SIMATIC RF620T Operating Instructions
1.7 Certificates and approvals
SIMATIC RF620T
26 Operating Instructions, 04/2008, A5E01602431-02
1.7 Certificates and approvals
1.7.1 Certificates and approvals
Table 1-5 6GT2810-2HC00 - RF620T UHF container tag
Certificate Description
CE Approval to R&TTE
Table 1-6 6GT2810-2HC00 - RF620T UHF container tag
Standards
FCC
Federal Communications
Commission
Passive labels or transponders comply with the valid regulations;
certification is not required
This product is UL-certified for the USA and Canada.
It meets the following safety standard(s):
UL 60950-1 - Information Technology Equipment Safety - Part 1:
General Requirements
CSA C22.2 No. 60950 -1 - Safety of Information Technology
Equipment
UL Report E 205089
SIMATIC RF620T Operating Instructions
1.8 Dimension drawing
SIMATIC RF620T
Operating Instructions, 04/2008, A5E01602431-02 27
1.8 Dimension drawing
Figure 1-9 SIMATIC RF620T UHF container tag
Units of measurement: All dimensions in mm
Tolerances, unless indicated otherwise, are +-0.5 mm.
① Labeling area, see Section Characteristics (Page 5)
SIMATIC RF620T Operating Instructions
1.8 Dimension drawing
SIMATIC RF620T
28 Operating Instructions, 04/2008, A5E01602431-02
