Page 1 V680-series ID Flag Sensors Userʼs Manual ID Flag Sensors V680-HAM91 V680-HAM81 Antennas V680-HS51 V680-HS52 V680-HS61 V680-HS63 V680-HS65 RF Tags V680-D1KP52MT V680-D1KP52M-BT01/D1KP52M-BT11 V680-D1KP53M V680-D1KP54T V680-D1KP66T/-D1KP66MT V680-D1KP66T-SP V680-D1KP58HTN V680-D2KF52M V680-D2KF52M-BT01/D2KF52M-BT11 V680-D8KF67/-D8KF67M V680-D8KF68/-D32KF68 V680S-D2KF67/-D2KF67M V680S-D2KF68/-D2KF68M V680S-D8KF67/-D8KF67M V680S-D8KF68/-D8KF68M Man. No.: Z279-E1-09...
Page 2 Introduction Thank you for purchasing a V680/V680S-series ID System. This manual describes the functions, performance, and application methods needed for optimum use of the V680-series RFID System. Please observe the following items when using the ID System. • Allow the ID System to be installed and operated only by qualified specialist with a sufficient knowledge of electrical systems.
Page 3 Introduc- READ AND UNDERSTAND THIS DOCUMENT tion Product Overview Section 1 Names and Functions of Components Section 2 Functions Section 3 Installation, Connections, and Wiring Section 4 Control I/O Interface Section 5 Troubleshooting Section 6 Appendices Section 7 RFID System F S F S T V680-1KP52MT-BT01/-D1KP52M-BT11 RF Tag T T V680-1KP66T/-D1KP66MT RF Tag T T T ...
Page 4 Please read and understand this document before using the products. Please consult your OMRON representative if you have any questions or comments. WARRANTY OMRON’s exclusive warranty is that the products are free from defects in materials and workmanship for a period of one year (or other period if specified) from date of sale by OMRON.
Page 5: Safety Precautions
Introduction Safety Precautions Alert Symbols for Safe Use The following symbols are used in this manual to indicate precautions that must be observed to ensure safe use of V680-HAM91, V680-HAM81, V680-series Antennas, and V680/V680S-series RF Tags. The precautions provided here contain important safety information. Be sure to observe these precautions. The following signal words are used in this manual.
Page 6: Precautions For Safe Use
9. Turn OFF the Controller power supply before mounting or removing an Antenna. 10. If an error is detected in any Product, immediately stop operation and turn OFF the power supply. Consult with an OMRON representative. 11. Dispose of the Products as industrial waste.
Page 7: Precautions For Correct Use
Introduction Precautions for Correct Use Always observe the following precautions to prevent operation failures, malfunctions, and adverse effects on performance and equipment. 1. Installation and Storage Environment Do not use or store the Product in the following locations. •Locations subject to corrosive gases, dust, dirt, metal powder, or salt. •Locations where the specified ambient temperature and ambient humidity range is exceeded.
Page 8 Introduction •Provide the mounting distances between plural RF tags to prevent them from malfunctions due to mutual interference. •If the central axis of an antenna and RF tag shifts, a communications range will fall. •Do not touch the product immediately after usage at high temperatures. Doing so may occasionally result in burning.
Page 9: Meanings Of Symbols
Introduction Meanings of Symbols Indicates particularly important points related to a function, including precautions and application advice. Indicates page numbers containing relevant information. Indicates reference to helpful information and explanations for difficult terminology. RFID System User's Manual...
Page 10 Introduction MEMO RFID System User's Manual...
Page 11: Table Of Contents
Introduction Table of Contents Introduction Safety Precautions Precautions for Safe Use Precautions for Correct Use Meanings of Symbols Table of Contents Section 1 Product Overview Features System Configuration Section 2 Names and Functions of Components ID Flag Sensor Antennas RF Tags Section 3 Functions Communications Mode Optional Functions...
Page 12 Introduction Section 5 Control I/O Interface I/O Interface Control I/O Control Flow Timing Charts Sample Programming Section 6 Troubleshooting Handling Errors Errors and Countermeasures Maintenance and Inspection Section 7 Appendices Product Specifications Characteristics Reference Data: Antenna and RF Tags Installation RF Tag Memory Capacities and Memory Types RF Tag Memory Map Chemical Resistance of the Antennas and RF Tags...
Page 13: Section 1 Product Overview
Section 1 Product Overview Features System Configuration RFID System User’s Manual...
Page 14: Features
Section 1 Product Overview Features The V680-series ID System uses electromagnetic induction in the 13.56-MHz bandwidth, which conforms to the international standards in ISO/IEC 18000-3 (ISO/IEC 15693). A V680-series ID System enables reading and writing RF Tag data without contact by connecting a V680-HAM91/V680-HAM81 ID Flag Sensor to a V680-series Antenna.
Page 15: System Configuration
Terminal block wiring Interface Cable V680-A60 2 m 10 m Connector connection ID Flag Sensor V680-HAM81 V680-HAM91 Connector connection Antenna V680-HS51 V680-HS52-R V680-HS63-R V680-HS65-R V680-HS61 V680-HS52-W V680-HS63-W V680-HS65-W Wireless Communications RF Tags V680-D1KP58HTN V680-D1KP52M-BT01 V680-D1KP53M V680-D1KP54T V680-D8KF68 V680-D1KP52MT V680-D1KP66T V680-D32KF68...
Page 16 Section 1 Product Overview MEMO RFID System User's Manual...
Page 17: Section 2 Names And Functions Of Components
Section 2 Names and Functions of Components ID Flag Sensor Antennas RF Tags RFID System User's Manual...
Page 18: Id Flag Sensor
Names and Functions of Components ID Flag Sensor Interface Connector : CN1 Connect to 24VDC power, INHIBIT/TRIG Input and Outputs. Recommended Power Supply : S8VS-03024(OMRON) Note. Please use the Interface Cable(Optional). Interface Connector : CN2 Connect to Inputs. Note. Please use the optional Interface Cable(Optional).
Page 19 Section 2 Names and Functions of Components Status Indicator LED The ID Flag Sensor status is displayed. Status Definition Lit green Normal Not lit No power supply or Fatal error. The communication status with the RF Tags is displayed. Status Definition Lit yellow Communicating with RF Tag , Measuring Noise level.
Page 20 CN1 connects to 24 VDC, INHIBIT/TRIG input and all other Outputs. Triangle mark I/O connector : CN1 ID Flag Sensor connectors viewed from mating side MIL-compliant Connector (MIL-C-83503) (Applicable Connector: OMRON XG4A-2639-A) Wire colors Name Description (See Note1.) FG line FG ground terminal Not used.
Page 21 I/O Connector CN2 CN2 connects to Input signals except for INHIBIT/TRIG. Triangle mark I/O connector : CN2 ID Flag Sensor connectors viewed from mating side MIL-compliant Connector (MIL-C-83503) (Applicable Connector: OMRON XG4A-2639-A) Wire colors Pin No.. Name Description (See Note.)
Page 22 Section 2 Names and Functions of Components Mode Setting Switches Access Mode Setting Switch Use this switch to set the communications mode for communications with RF Tags. Refer to the following figure for a set position of the Setting Switch. Cutting edge Example) When it sets "...
Page 23 Section 2 Names and Functions of Components Read Mode Setting Switch Use this switch to set the mode for reading data. Refer to the following figure for a set position of the Setting Switch. Cutting edge Example) When it sets " 1" . Name Description DATA READ1...
Page 24 Section 2 Names and Functions of Components Access Address Setting Switches Use these switches to set the memory address for reading data. Item Description Setting Specify the memory address of the RF Tag in 4-digit hexadecimal. method Example to specify an RF Tag memory address of 01A3 hex: “0“...
Page 25: Antennas
Names and Functions of Components Antennas ■V680-HS51 (2) Communications sufrace (3) Ferrite core (4) Connector ■V680-HS52 (2) Communications sufrace (3) Ferrite core (1) Operation indicator (4) Connector ■V680-HS63 (2) Communications sufrace (3) Ferrite core (4) Connector (1) Operation indicator ■V680-HS65 (2) Communications sufrace (1) Operation (3) Ferrite core indicator (4) Connector ■V680-HS61 (3) Ferrite core (2) Communications sufrace (4) Connector Name Description Operation indicator Lights w hen a signal is transmitted. Communication surface Mounted facing the RF Tags. Ferrite core Connector Connects to the ID Flag Sensor. RFID System User's Manual...
Page 26: Rf Tags
Section 2 Names and Functions of Components RF Tags V680-D1KP52MT/-D2KF52M V680-D1KP52M-BT01/-D2KF52M-BT01 V680-D1KP52M-BT11/-D2KF52M-BT11 V680-D1KP53M V680-D1KP54T V680-D1KP66T/D1KP66MT V680-D1KP66T-SP V680-D1KP58HTN The ID Flag Sensor communications with the RF Tags through the Antenna to read and write data in the internal memory of the RF Tags. The printed side is the communications surface.
Page 27 Section 2 Names and Functions of Components V680-D8KF67/-D8KF67M V680-D8KF68/-D32KF68 V680S-D2KF67/-D2KF67M V680S-D2KF68/-D2KF68M V680S-D8KF67/-D8KF67M V680S-D8KF68/-D8KF68M The ID Flag Sensor communications with the RF Tags through the Antenna to read and write data in the internal memory of the RF Tags. The printed side is the communications surface. Mount the RF Tags with the communications surfaces facing the Antenna.
Page 28 Section 2 Names and Functions of Components MEMO RFID System User's Manual...
Page 29: Section 3 Functions
Section 3 Functions Communications Mode Optional Functions Wire-saving Mode Parity Check Address Shift Noise Measurement Write Protection RFID System User's Manual...
Page 30: Communications Mode
Section 3 Functions Communications Mode The ID Flag Sensor operates after reading the setting of the mode setting switches when the power supply is turned ON. Set the mode for communications with the RF Tags or set the Noise Measurement Mode on the access mode setting switch.
Page 31: Auto Mode
Section 3 Functions Auto Mode In Auto Mode, the ID Flag Sensor automatically begins communications with a RF Tag on a workpiece or pallet when it enters the interrogation zone of the Antenna, and then the ID Flag Sensor outputs the result to the PLC.
Page 32: Optional Functions
Section 3 Functions Optional Functions The following optional functions can be enabled by using the mode setting switches (access mode setting, output mode setting, read mode setting, or write mode setting) and specifying the control signal. Function Description Output time operation Specified by setting the output mode.
Page 33 Section 3 Functions Verification The verification function compares the data (16 bits) that is input to the external data input lines (ID0 to ID15) with the actually data (16 bits) read from the RF Tag, and outputs the result to indicate whether the data matches or not.
Page 34: Wire-Saving Mode
Section 3 Functions Wire-saving Mode The Wire-saving Mode enables detecting read data signals and normal/error completion signals using only 16 data outputs (OD0 to OD15). Using this mode enables controlling reading 16-bit data using only one 16-point Input Unit for a PLC or a wire-saving device. System Configuration Example: Combination and Usage of I/O Lines in Each Mode •...
Page 35: Parity Check
Section 3 Functions Parity Check This function detects vertical parity in the data output on the data output lines (OD0 to OD15) and outputs the parity status. If the number of bits that are ON in the data output lines is even, then the parity output is OFF. If the number of bits that are ON in the data output lines is odd, then the parity output is ON.
Page 36: Address Shift
Section 3 Functions Address Shift The address set on the access address setting switches can be offset by the value specified by external data inputs ADR0 to ADR2 to change the access address. The address shift enables reading or writing to up to 16 access address (up to 128 bits) of RF Tag memory.
Page 37: Noise Measurement
Section 3 Functions Noise Measurement You can check whether noise that affects communications with RF Tags exists in the area where the Antenna and ID Flag Sensor are installed. In Trigger Mode 1 or Auto Mode 1, noise measurement is performed by turning ON the NOISE_IN external input.
Page 38: Write Protection
Section 3 Functions Write Protection The write protection function protects important data stored in the memory of a RF Tag, such as the product model or type, from being overwritten inadvertently. Enable the write protection function after writing important data as described in this section. Setting Write Protection For the write protection function to be effective, it must be enabled in both the ID Flag Sensor settings and the RF Tag settings.
Page 39 Section 3 Functions Example of Write Protection Start Address Is Lower Than the End Address The memory area between the start address and end address will be write-protected. 0000 hex Address Upper digits Lower digits (hex) 0015 hex Write-protected 0000 0120 hex 0001 0002...
Page 40: Disabling Write Protection
Turn ON pin 6 (NOISE_IN/WRITE PROTECT) of the I/O connector on the ID Flag Sensor. Caution When Using Write Protection: The write protection function is an OMRON ID Flag Sensor function. It cannot be used with RFID reader/writer manufactured by other companies.
Page 41: Section 4 Installation, Connections, And Wiring
Section 4 Installation, Connections, and Wiring ID Flag Sensor Installing Antennas Installing RF Tags RFID System User's Manual...
Page 42: Id Flag Sensor
Section 4 Installation, Connections, and Wiring ID Flag Sensor Installation To ensure full functionality of the ID Flag Sensor, follow the instructions provided in this section for installation. Installation Site Do not install the ID Flag Sensor in the following locations. •...
Page 43 Leave space between Units of at least 10 mm. 10 mm min. 10 mm min. End Plate End Plate Spacer Spacer Use at least 2 OMRON DIN Track Spacers. (Each Spacer is 5 mm wide Spacer PFP-S RFID System User's Manual...
Page 44: Connection And Wiring
Section 4 Installation, Connections, and Wiring Connection and Wiring Interface Cable INPUT/OUTPUT controls • When using a solid-state output with the maximum switching current rating over 1A , there is a possibility of causing External Input Errors due to the delay of rise /fall time of output signal. Consider this when selecting the solid-state output.
Page 45: Mounting Procedure
Section 4 Installation, Connections, and Wiring Connecting and Disconnecting the ID Flag Sensor Mounting Procedure Line up the direction of the triangle mark on the connectors of the ID Flag Sensor and the interface cable, and then press in the connector of the interface cable. The lock will engage when the interface cable is pressed into the connector on the ID Flag Sensor.
Page 46 Section 4 Installation, Connections, and Wiring Antenna Connector Mounting the Antenna Hold the connector part of the Antenna and insert it into the Antenna port while matching the key on the ID Flag Sensor with the groove on the connector. Antenna connector Turn the connector clockwise to lock it in place.
Page 47: Installing Antennas
Section 4 Installation, Connections, and Wiring Installing Antennas V680-HS51 Install the Antenna using the nuts and toothed washer that are provided on both sides of the mounting material, as shown in the diagram below. Metallic material Mounting Hole Dimensions Antenna +0.5 dia.
Page 48 Section 4 Installation, Connections, and Wiring V680-HS61 Installation from the Front Two, 3.5 dia. Coil center +0.2 30.5 Securely tighten screws to a torque of 0.98 N ・ m. V680-HS63 ■Installation from the Front Two, M4 Coil center 28 0.2 ■Installation from the Back Insert the nuts that come with the Antenna into sections A. Two, 4.5 dia. Coil center 28 0.2 For details on installing Antennas, refer to Antenna Mounting Precautions . p.157 Securely tighten screws to a torque of 1.2 N･m. RFID System User's Manual...
Page 49 Section 4 Installation, Connections, and Wiring V680-HS65 Use M4 screws and spring washers (in four places) for Four, M4 Antenna installation. 90±0.2 90±0.2 Securely tighten screws to a torque of 0.7 to 1.2 N⋅m. Mounting Bracket Dimensions (Provided Only with the V680-HS65) Note: When installing the Antenna, mount it on the 100±0.2 Four, C1...
Page 50: Installing Rf Tags
Section 4 Installation, Connections, and Wiring Installing RF Tags V680-D1KP52MT RF Tag Installation Direction Mount the RF Tags as shown in the diagram on the right. The R0.2 max. epoxy adhesives listed in the following table are recommended for the given temperature ranges. +0.1 dia.
Page 51 Section 4 Installation, Connections, and Wiring V680-D1KP53M RF Tag Installation Direction Mount the RF Tags as shown in the diagram on the right. The V680D1KP53M epoxy adhesives listed in the following table are R0.5 max. recommended for the given temperature ranges. Ambient operating Product name Manufacturer...
Page 52 1. Insert the coin-shaped RF Tag into the Attachment. The coin-shaped RF Tag has no directionality, so it can be faced in any direction. OMRON Do not repeatedly insert and remove the RF Tag from the Attachment. Doing so an loosen the fit of the RF Tag and break the Attachment clasps.
Page 53 Section 4 Installation, Connections, and Wiring V680-D1KP66T Mounting on Non-metallic Material Mount the RF Tag using M3 pan-head screws from the Mounting Hole Dimensions marked side. Two, M3 Tightening torque: 0.3 to 0.5 N⋅m M3 pan-head screw 25±0.2 Marked side 25±0.2 Mounting on Metallic Material Communications range will decrease if there is metal...
Page 54 Section 4 Installation, Connections, and Wiring V680-D1KP66MT Mount the RF Tag to metal using M3 pan-head screws Mounting Hole Dimensions from the marked side. Tighten the screws to a torque Two, M3 of 0.3 to 0.5 N⋅m.. M3 pan-head screw 25±0.2 Marked side 25±0.2...
Page 55 Section 4 Installation, Connections, and Wiring V680-D1KP58HTN RF Tag Installation Direction The RF Tags have a limited life span. Therefore, install them in locations in which they can be easily replaced. Use the following procedure to mount the V680-A80 Attachment when required. 1.
Page 56 Section 4 Installation, Connections, and Wiring V680-D2KF52M RF Tag Installation Direction R0.2 max. Mount the RF Tag as shown in the diagram on the right. The epoxy adhesives listed in the following table are recommended for the given temperature ranges. +0.1 dia.
Page 57 Section 4 Installation, Connections, and Wiring V680-D8KF67/-D8KF67M RF Tag Installation Direction Secure the RF Tag with M3 screws. Tighten the Mounting Hole Dimensions screws to a torque of 0.6 N⋅m Two, M3 M3 screw 32±0.2 Marked side 32±0.2 When installing RF Tags, refer to RF Tag Mounting Precautions. p.161 Refer to Effect of Surrounding Metals (Reference) for information on the effect of metal on the back of the V680- D8KF67M.
Page 58 Section 4 Installation, Connections, and Wiring V680S-D2KF67/-D2KF67M RF Tag Installation Direction Secure the RF Tag with M3 screws. Tighten the Mounting Hole Dimensions screws to a torque of 0.6 N⋅m Two, M M3 screw 32±0.2 Marked side 32±0.2 When installing RF Tags, refer to RF Tag Mounting Precautions.
Page 59 Section 4 Installation, Connections, and Wiring V680S-D8KF67/-D8KF67M RF Tag Installation Direction Secure the RF Tag with M3 screws. Tighten the Mounting Hole Dimensions screws to a torque of 0.6 N⋅m Two, M M3 screw 32±0.2 Marked side 32±0.2 When installing RF Tags, refer to RF Tag Mounting Precautions. p.161 Refer to Effect of Surrounding Metals (Reference) for information on the effect of metal on the back of the V680S- D8KF67M.
Page 60 Section 4 Installation, Connections, and Wiring MEMO RFID System User's Manual...
Page 61: Section 5 Control I/O Interface
Section 5 Control I/O Interface I/O Interface Control I/O Control Flow Timing Charts Sample Programming RFID System User's Manual...
Page 62: I/O Interface Control
Section 5 Control I/O Interface I/O Interface Control The V680-series ID Flag Sensor can be connected to a PLC, I/O Terminal, B7A-series Link Terminal, DeviceNet device, or other host device. This section describes operations for connecting to and communicating with these devices. Overview of Communications Modes Use the access mode setting switch to set the communications mode for RF Tag communications.
Page 63: I/O Control Flow
Section 5 Control I/O Interface I/O Control Flow The operation outline for ID Flag Sensor at Trigger Mode 1 and Auto Mode 1 are shown in this page. For detail timing of ID Flag Sensor , refer to the timing charts in this section. Control the ID Flag Sensor according to the timing charts.
Page 64: Timing Charts
Section 5 Control I/O Interface Timing Charts Trigger Mode 1: Read Mode setting switch settings In communications range RF Tag position INHIBIT/TRIG Communications Read- Read- with RF Tag R/W input Address shift input 0 hex Address shift data (ADR0 to 2: 3 bits) Access Address : 0010 hex 3 ms NORMAL/STRB...
Page 65 Section 5 Control I/O Interface Trigger Mode1 : Read with Wire-saving Mode Mode setting switch settings In communications range RF Tag position INHIBIT/TRIG Communications Read- Read- with RF Tag R/W input Address shift input 0 hex Address shift data (ADR0 to 2: 3 bits) Access Address : 0010 hex 3 ms NORMAL/STRB...
Page 66 Section 5 Control I/O Interface Trigger Mode1: VERIFY Mode setting switch settings In communications range In communications range RF Tag position INHIBIT/TRIG Communications Verify- Verify- with RF Tag Data intput Reference Data (ID0 to ID15: 16 bits) R/W input Access Address : 0010 hex Address shift input Address shift data 0 hex...
Page 67 Section 5 Control I/O Interface Trigger Mode1: Write Mode setting switch settings RF Tag position In communications range In communications range INHIBIT/TRIG Communications Write Writing with RF Tag failed Data intput Write data (ID0 to ID15: 16 bits) R/W input Access Address : 0010 hex Address shift input 0 hex...
Page 68 Section 5 Control I/O Interface Auto Mode1: Read In communications range In communi- Mode setting switch settings RF Tag position cations range INHIBIT/TRIG Communications Read- Reading with RF Tag incomplete R/W input Address shift input 0 hex Address shift data (ADR0 to 2: 3 bits) Access Address : 0010 hex OFF delay time...
Page 69 Section 5 Control I/O Interface Auto Mode1: VERIFY In communi- In communi- Mode setting switch settings RF Tag position cations range cations range INHIBIT/TRIG Verify- Verify- Communications with RF Tag Data intput 0000 Reference data1 Reference data2 (ID0 to ID15: 16 bits) R/W input Access Address : 0010 hex Output Mode : 10 ms OFF delay...
Page 70 Section 5 Control I/O Interface Auto Mode1: Write Mode setting switch settings In communi- In communi- RF Tag position cations range cations range INHIBIT/TRIG Communications Writing Writing with RF Tag Data intput 0000 Write data (OD0 to OD15: 16 bits) R/W input Access Address : 0010 hex Output Mode : 10 ms OFF delay...
Page 71 Section 5 Control I/O Interface Trigger Mode1 :Noise Measurement Mode setting switch settings INHIBIT/TRIG Measuring Measuring noise level noise level NOISE_IN/WRITE PROTECT input R/W input 3 ms NORMAL/STRB NOISE_OUT output Parity value PARITY output Data output 0000 hex Noise level data 0000 hex (OD0 to OD15: 16 bits) Data Display LED...
Page 72 Section 5 Control I/O Interface Auto Mode1 (Noise Measurement) Mode setting switch settings INHIBIT/TRIG Measuring Measuring noise level Measuring noise level noise level NOISE_IN/WRITE PROTECT input R/W input 3 ms Approx. 10 ms 3 ms Approx. 10 ms NORMAL/STRB NOISE_OUT output Parity Parity...
Page 73: Sample Programming
Section 5 Control I/O Interface Sample Programming Reading Flags This sample program shows a programming example for using an external switch with a Sensor or other device to read RF Tag data and turn ON the outputs for bits allocated to various devices. Mode setting switch settings 00.10 When the external SW turns ON,...
Page 74 Section 5 Control I/O Interface Detecting Disconnection This sample program shows a programming example for detecting disconnection of data output lines (16 lines) by using the parity output. Mode setting switch settings 00.10 When the external SW turns ON, DIFU INHIBIT/TRIG input turns ON, and the ID Flag 100.01 Sensor starts communications.
Page 75 Section 5 Control I/O Interface Auto Mode with Wire-saving Mode This sample program shows a programming example for reading the RF Tag in Auto Mode with Wire-saving mode. The ID Flag Sensor read the RF Tag data in Auto Mode with Wire-saving mode , store the read data in the DM0000, and outputs normal completion contact(100.05).
Page 76 Section 5 Control I/O Interface MEMO RFID System User's Manual...
Page 77: Section 6 Troubleshooting
Section 6 Troubleshooting Handling Errors Errors and Countermeasures Maintenance and Inspection RFID System User's Manual...
Page 78: Handling Errors
Section 6 Troubleshooting Handling Errors Check the error status by looking at the 16bits Data Display LED and the Error output(ERR)/Data Output(OD0 to OD15), and then take suitable actions. Hardware Errors Data Output Error Corrective action Lit red No output Hardware error If the error continues after resetting the power, replace the ID Flag Sensor.
Page 79: Errors And Countermeasures
Section 6 Troubleshooting Errors and Countermeasures The four main causes of problems that may occur in the ID Flag Sensor are as follows: • Noise interference· · · · · · · · · · · · · Take adequate countermeasures against noise. •...
Page 80: Maintenance And Inspection
Section 6 Troubleshooting Maintenance and Inspection The ID Flag Sensor must be inspected on a daily or regular basis so that the functions can be used in good condition. The ID Flag Sensor consists of semiconductors that last almost indefinitely. The following malfunctions may, however, result due to the operating environment and conditions.
Page 81: Section 7 Appendices
Section 7 Appendices Product Specifications Characteristics Reference Data: Antenna and RF Tags Installation RF Tag Memory Capacities and Memory Types RF Tag Memory Map Chemical Resistance of the Antennas and RF Tags V600-Compatible Mode Degree of Protection RFID System User's Manual...
Page 82: Product Specifications
Section 7 Appendices Product Specifications ID Flag Sensor General Specifications V680-HAM91/-HAM81 Item Model V680-HAM91/V680-HAM81 24 VDC +10%/-15%, Ripple (p-p): 10% max. Supply voltage Power consumption 3.5 W max. (supply voltage: 24 VDC, current consumption: 0.15A Max., not included I/O Interface current.) Ambient operating -10 to 55°C (with no icing)
Page 83: I/O Circuit Diagram
Section 7 Appendices I/O Specifications Item V680-HAM91 V680-HAM81 Input Transistor output or contact output Short-circuit current: 3 mA (typical) (Input terminal and 0-V short-circuit) OFF voltage: 15 to 30 VDC ON voltage: 0 to 5 VDC Input impedance: 8.2 kΩ Applied voltage: 30 VDC max.
Page 84 Section 7 Appendices Dimensions V680-HAM91/-HAM81 74.8 (Unit : mm) 71.8 65.75 61.75 4-switch 38.5 4-switch 18.95 30.25 21-Status Indicator 41.55 52.85 Connector 108.26 Connector (5.5) Interface cable V680-A60 2M/5M/10M (Unit : mm) Connector : XG5M-2632-N 14.4 35±5 20±5 20±5 20±5 20±5 Vinyl-insulated round cord 9 mm dia, 23-conductor cable (7/0.2 mm dia.
Page 85: General Specifications
ABS, brass, and epoxy resin filling Weight Approx. 55 g Cable length Standard length of 2 m Note.1 The Connector is not waterproof. Oil resistance has been tested using a specific oil as defined in the OMRON test method. Dimensions (Unit: mm) Two toothed washers...
Page 86 500 m/s , 3 times each in 6 directions (Total: 18 times) Dimensions M22 × 65 mm Material ABS resin, brass, and epoxy resin ﬁller Weight Approx. 850 g (with 12.5-m cable) Cable length Standard lengths of 2 and 12.5 m Note 1. The degree of protection for the Connector is IP67/IP65. Oil resistance has been tested using a speciﬁc oil as deﬁned in the OMRON test method. The ID Flag Sensor is not wa terproof. Do not use it in an environment where mist is present. 2. The Connector is not waterproof. Oil resistance has been tested using a speciﬁc oil as deﬁned in the OMRON test method. The ID Flag Sensor is not waterproof. Do not use it in an environment where mist is present. ■V680-HS61 ・ General Specifications Item Model V680-HS61 Ambient operating -10 to 60 ° C (with no icing) temperature Ambient storage -25 to 75 ° C (with no icing) temperature Ambient operating ...
Page 87 Antenna M22 × 1 Connector (39.5) 35 dia. Operation indicator 47.6 Insulation cover Coaxial cable, 5.3 dia., 22.5 dia. standard length: 2 m Case material Brass Communications surface ABS resin Mounting Hole Dimensions n i l r r ( V680-HS61 (Unit: mm) Ferrite core Connector Insulation cover Coaxial cable, 2.9 dia., standard length: 2 m Case material ABS resin Filling resin Epoxy resin Cable PVC (black) RFID System User's Manual...
Page 88 Note 1. The degree of protection for the Connector is IP67/IP65. Oil resistance has been tested using a specific oil as defined in the OMRON test method. The ID Flag Sensor is not waterproof. Do not use it in an environment where mist is present.
Page 89 Section 7 Appendices Dimensions V680-HS63-W (Unit: mm) Antenna Ferrite core Connector Insulation cover Coaxial cable, 5.5 dia., Operation indicator standard length: 2 m Note: Mounting Hole Dimensions Two, M4 or 4.5-dia. holes Coil center Case material ABS resin Filling resin Epoxy resin Cable PVC (gray)
Page 90 Note 1. The degree of protection for the Connector is IP67/IP65. Oil resistance has been tested using a specific oil as defined in the OMRON test method. The ID Flag Sensor is not waterproof. Do not use it in an environment where mist is present.
Page 91 Section 7 Appendices Dimensions V680-HS65-W (Unit: mm) 90±0.2 Four, 4.5 dia. (Mounting holes) Ferrite core Connector Operation indicator Bushing Insulation cover Coaxial cable, 5.5 dia., standard length: 2 m Case material ABS resin Filling resin Epoxy resin Cable PVC (gray) V680-HS65-R (Unit: mm) 90±0.2...
Page 92 Note 1. After string data at high temperatures, rewrite the data even if changes are not required, high temperatures are those exceeding 125°C up to 180°C. 2. Oil resistance has been tested using a specific oil as defined in the OMRON test method. RFID System...
Page 93 Section 7 Appendices Dimensions R0.2 dia. −0.1 −0.1 (Unit: mm) Case material PPS resin Filling resin Epoxy resin When embedding the V680-D1KP52MT into a metal surface, use the V680-HS51, V680-HS52 Antenna. Transmission will not be possible if the V680-HS63 Antenna is used. The side with the markings is the communications surface.
Page 94 Note 1. After string data at high temperatures, rewrite the data even if changes are not required, high temperatures are those exceeding 125°C up to 180°C. 2. Oil resistance has been tested using a specific oil as defined in the OMRON test method. Dimensions...
Page 95 Note 1. After string data at high temperatures, rewrite the data even if changes are not required, high temperatures are those exceeding 125°C up to 180°C. 2. Oil resistance has been tested using a specific oil as defined in the OMRON test method. Dimensions...
Page 96 Note 1. After string data at high temperatures, rewrite the data even if changes are not required, high temperatures are those exceeding 125°C up to 180°C. 2. Oil resistance has been tested using a specific oil as defined in the OMRON test method. Dimensions C0.5...
Page 97 Section 7 Appendices V680-D1KP54T • General Specifications Item Model V680-D1KP54T Memory capacity 1,000 bytes (user area) Memory type EEPROM Data Retention 10 years after writing (85°C or less), 0.5 years after writing (85°C to 125°C) Total data retention at high temperatures exceeding 125°C is 10 hours (See note.) Write Endurance 100,000 times per block (25°C) Ambient operating...
Page 98 Section 7 Appendices V700-A80 Attachment (Unit : mm) ± Material PPS resin • RF Tag Heat Resistivity • Storing RF Tags under high temperatures or heat cycle will adversely affect the performance of the internal parts and the service life of the RF Tags. •...
Page 99 Note 1. After string data at high temperatures, rewrite the data even if changes are not required, high temperatures are those exceeding 125°C up to 180°C. 2. Oil resistance has been tested using a specific oil as defined in the OMRON test method. The V680-D1KP66MT is designed to be mounted directly to metal. The V680-D1KP66T and V680- D1KP66MT markings are shown in the following diagrams.
Page 100 Section 7 Appendices Dimensions V680-D1KP66T/-D1KP66MT Mouting Hole Dimensions (Unit: mm) Four, R4 Four, R8 25±0.2 Two, M3 25±0.2 25±0.2 Two, 3.5 dia. Two, 6 dia. 25±0.2 35±0.1 Case material PPS resin V600-A86 Attachment (Unit: mm) Four, R5.5 Two, 4 dia. 25±0.2 Two, M3 25±0.2...
Page 101 Section 7 Appendices V680-D1KP66T-SP General Specifications Item Specifications Memory capacity 1,000 bytes Memory type EEPROM Data Retention 10 years after writing (85°C or less), 0.5 years after writing (85 to 110°C) Write Endurance 100,000 times per block (25°C) When communicating: −25 to 70°C (with no icing) Ambient operating When not communicating: −40 to 110°C (with no icing) temperature...
Page 102 , 3 times each in X, Y, and Z directions (Total: 18 times) Materials Coating: PPS resin Weight Approx. 70 g Note. Oil resistance has been tested using a specific oil as defined in the OMRON test method. • Dimensions V680-D1KP58HTN 10±0.2 (Unit: mm) 1.25...
Page 103 Section 7 Appendices Use at high temperatures (V680-D1KP58HTN) Data retention •Data stored in memory in the RF Tag may be lost due to the characteristics of EEPROM, if the accumu- lated usage time of the RF Tag at a high temperature over 125°C exceeds 10 hours after writing data to the RF Tag.
Page 104 Storing RF Tags under high temperatures or heat cycle will adversely affect the performance of the internal parts and the service life of the RF Tags. Correct operation has been confirmed through the OMRON in-house evaluation for RF Tags under the following high-temperature conditions.
Page 105 Approx. 0.5 g Metal countermeasures Note 1. The number of accesses is the total number of reads and writes. 2. Oil resistance has been tested using a specific oil as defined in the OMRON test method. Dimensions (Unit: mm) R0.2 dia.
Page 106 Approx. 25 g Metal countermeasures Note 1. The number of accesses is the total number of reads and writes. 2. Oil resistance has been tested using a specific oil as defined in the OMRON test method. Dimensions (Unit: mm) Bolt RF Tag 8.4 dia.
Page 107 Approx. 10 g Metal countermeasures Note 1. The number of accesses is the total number of reads and writes. 2. Oil resistance has been tested using a specific oil as defined in the OMRON test method. Dimensions (Unit: mm) Bolt RF Tag 6 dia.
Page 108 Note 1. The number of accesses is the total number of reads and writes. 2. Oil resistance has been tested using a specific oil as defined in the OMRON test method. The V680-D8KF67M is designed to be mounted directly to metal. The V680-D8KF67 and V680- D2KF67M markings are shown in the following diagrams.
Page 109 Section 7 Appendices Dimensions (Unit: mm) 13.2 Two, 3.5-dia. Mounting Hole Dimensions mounting holes Two, M3 13.2 40±0.1 −0.5 32±0.2 Mounting reference surface 32±0.2 40±0.1 −0.5 Case material PBT resin Filling resin Epoxy resin RFID System User's Manual...
Page 110 Approx. 50 g Metal countermeasures None Note 1. The number of accesses is the total number of reads and writes. 2. Oil resistance has been tested using a specific oil as defined in the OMRON test method. RFID System User's Manual...
Page 111 Section 7 Appendices General Specifications V680-D8KF68/-D32KF68 Two, 4.5-dia. (Unit: mm) mounting holes Mounting Hole Dimensions 44±0.2 Two, M4 44±0.2 Case material PBT resin Filling resin Epoxy resin The side with the markings is the communications surface. Mount the RF Tag with this side facing the Antenna. V680-A81 Attachment Two, 4.5-dia.
Page 112 Note 1. The number of accesses is the total number of reads and writes. 2. Oil resistance has been tested using a specific oil as defined in the OMRON test method. The V680S-D2KF67M/-D8KF67M is designed to be mounted directly to metal. The V680S-D2KF67/- D2KF67M/-D8KF67 and V680S-D8KF67M markings are shown in the following diagrams.
Page 113 Section 7 Appendices Dimensions (Unit: mm) Two, 3.5-dia. mounting holes Mounting Hole Dimensions 2-M3 32±0.2 32±0.2 Case material PPS resin RFID System User's Manual...
Page 114 Note 1. The number of accesses is the total number of reads and writes. 2. Oil resistance has been tested using a specific oil as defined in the OMRON test method. The V680S-D2KF68M/-D8KF68M is designed to be mounted directly to metal. The V680S-D2KF68/- D2KF68M/-D8KF68 and V680S-D8KF68M markings are shown in the following diagrams.
Page 115 Section 7 Appendices General Specifications (Unit: mm) Two, 4.5-dia. mounting holes Mounting Hole Dimensions 2-M4 76±0.2 76±0.2 Case material PPS resin RFID System User's Manual...
Page 116: Characteristics
V680-D1KP52MT Write 0.5 to 8.5 mm (Axis oﬀset: ±2） V680-HS52 Read 0.5 to 4.5 mm (Axis oﬀset: ±2） V680-D1KP52MT embedded in metal (steel) Write 0.5 to 4.0 mm (Axis oﬀset: ±2） Read 0.5 to 12.0 mm (Axis oﬀset: ±2） V680-HS63 V680-D1KP52MT Write 0.5 to 9.5 mm (Axis oﬀset: ±2） Read 0.5 to 4.0 mm (Axis oﬀset: ±2） V680-D1KP52MT V680-HS61 embedded in metal (steel) Write 0.5 to 3.0 mm (Axis oﬀset: ±2） When embedding the V680-D1KP52MT into a metal surface, use the V680-HS51/-HS52 Antenna. Transmission will not be possible if the V680-HS63 Antenna is used. ■ Measurement Conditions V680-D1KP52MT Metallic material V680-HS51 V680-HS51 Non-metallic material Metallic material V680-D1KP52MT Metallic material (Examples: Resin, plastic, wood, etc.) V680-D1KP52MT Metallic...
Page 117 Section 7 Appendices V680-D1KP52M-BT01/-D1KP52M-BT11 Antenna RF Tag Communications range 0.5 to 2.5 mm (Axis offset: ±2) Read V680-HS51 V680-D1KP52M-BT01/-D1KP52M-BT11 0.5 to 2.0 mm (Axis offset: ±2) Write 0.5 to 3.0 mm (Axis offset: ±2) Read V680-HS52 V680-D1KP52M-BT01/-D1KP52M-BT11 0.5 to 2.5 mm (Axis offset: ±2) Write Measurement Conditions V680-D1KP52M-BT01...
Page 118 Section 7 Appendices V680-D1KP53M Antenna RF Tag Communications range 0.5 to 6.5 mm (Axis offset: ±2) Read V680-D1KP53M 0.5 to 6.0 mm (Axis offset: ±2) Write V680-HS51 0.5 to 3.5 mm (Axis offset: ±2) Read V680-D1KP53M embedded in metal (steel) 0.5 to 3.0 mm (Axis offset: ±2) Write 0.5 to 9.0 mm (Axis offset: ±2)
Page 119 Section 7 Appendices V680-D1KP54T Antenna RF Tag Communications distance Read 0 to 17.0 mm (Axis offset: ±2 mm) V680-HS52 V680-D1KP54T Write 0 to 15.0 mm (Axis offset: ±2 mm) Read 0 to 24.0 mm (Axis offset: ±10 mm) V680-HS63 V680-D1KP54T Write 0 to 20.0 mm (Axis offset: ±10 mm) Read 0 to 33.0 mm (Axis offset: ±10 mm) V680-HS65...
Page 120 Section 7 Appendices V680-D1KP66T Antenna RF Tag Communications range 1.0 to 17.0 mm (Axis offset: ±2) Read V680-HS52 V680-D1KP66T 1.0 to 17.0 mm (Axis offset: ±2) Write 5.0 to 30.0 mm (Axis offset: ±10) Read V680-HS63 V680-D1KP66T 5.0 to 25.0 mm (Axis offset: ±10) Write 5.0 to 47.0 mm (Axis offset: ±10) Read...
Page 121 Section 7 Appendices V680-D1KP66MT Antenna RF Tag Communications range 1.0 to 16.0 mm (Axis offset: ±2) Read V680-D1KP66MT V680-HS52 embedded in metal (steel) 1.0 to 14.0 mm (Axis offset: ±2) Write 5.0 to 25.0 mm (Axis offset: ±10) Read V680-D1KP66MT V680-HS63 embedded in metal (steel) 5.0 to 20.0 mm Axis offset: ±10)
Page 122 Section 7 Appendices V680-D1KP66T-SP Antenna RF Tag Communications range 1.0 to 15.0 mm (Axis offset: ±2) Read V680-HS52 V680-D1KP66T-SP 1.0 to 15.0 mm (Axis offset: ±2) Write 5.0 to 25.0 mm (Axis offset: ±10) Read V680-HS63 V680-D1KP66T-SP 5.0 to 20.0 mm (Axis offset: ±10) Write 5.0 to 42.0 mm (Axis offset: ±10) Read...
Page 123 Section 7 Appendices V680-D1KP58HTN Antenna RF Tag Communications range 0.0 to 55.0 mm (Axis offset: ±10) Read V680-HS65 V680-D1KP58HTN 0.0 to 50.0 mm (Axis offset: ±10) Write Measurement Conditions V680-HS65 V680-D1KP58HTN Communica- tions range Metal Non-metallic material RFID System User's Manual...
Page 124 Section 7 Appendices V680-D2KF52M Antenna RF Tag Communications range 0.5 to 5.5 mm (Axis offset: ±2) Read V680-D2KF52M 0.5 to 5.5 mm (Axis offset: ±2) Write V680-HS51 0.5 to 3.5 mm (Axis offset: ±2) Read V680-D2KF52M embedded in metal (steel) 0.5 to 3.5 mm (Axis offset: ±2) Write 0.5 to 8.0 mm (Axis offset: ±2)
Page 125 Section 7 Appendices V680-D2KF52M-BT01/-D2KF52M-BT11 Antenna RF Tag Communications range 0.5 to 2.5 mm (Axis offset: ±2) Read V680-HS51 V680-D2KF52M-BT01/-D2KF52M-BT11 0.5 to 2.5 mm (Axis offset: ±2) Write 0.5 to 2.0 mm (Axis offset: ±2) Read V680-HS52 V680-D2KF52M-BT01/-D2KF52M-BT11 0.5 to 2.5 mm (Axis offset: ±2) Write Measurement Conditions V680-D2KF52M-BT01...
Page 126 Section 7 Appendices V680-D8KF67 Antenna RF Tag Communications range 0 to 17.0 mm (Axis offset: ±2) Read V680-HS52 V680-D8KF67 0 to 17.0 mm (Axis offset: ±2) Write 0 to 30.0 mm (Axis offset: ±10) Read V680-HS63 V680-D8KF67 0 to 30.0 mm (Axis offset: ±10) Write 0 to 42.0 mm (Axis offset: ±10) Read...
Page 127 Section 7 Appendices V680-D8KF67M Antenna RF Tag Communications range 0 to 16.0 mm (Axis offset: ±2) Read V680-D8KF67M V680-HS52 with metal on back (steel) 0 to 16.0 mm (Axis offset: ±2) Write 0 to 25.0 mm (Axis offset: ±10) Read V680-D8KF67M V680-HS63 with metal on back (steel)
Page 128 Section 7 Appendices V680-D8KF68/-D32KF68 Antenna RF Tag Communications range 5.0 to 45.0 mm (Axis offset: ±10) Read V680-D8KF68 5.0 to 45.0 mm (Axis offset: ±10) Write 5.0 to 35.0 mm (Axis offset: ±10) Read V680-D8KF68 (with V680-A81 Attachment, V680-A81) with metal on back (steel) 5.0 to 35.0 mm (Axis offset: ±10) Write V680-HS63...
Page 129 Section 7 Appendices V680S-D2KF67 Antenna RF Tag Communications range 1.0 to 17.0 mm (Axis offset: ±2) Read V680-HS52 V680S-D2KF67 1.0 to 17.0 mm (Axis offset: ±2) Write 7.0 to 30.0 mm (Axis offset: ±10) Read V680-HS63 V680S-D2KF67 7.0 to 30.0 mm (Axis offset: ±10) Write 5.0 to 42.0 mm (Axis offset: ±10) Read...
Page 130 Section 7 Appendices V680S-D2KF67M Antenna RF Tag Communications range 1.0 to 16.0 mm (Axis offset: ±2) Read V680S-D2KF67M V680-HS52 with metal on back (steel) 1.0 to 16.0 mm (Axis offset: ±2) Write 6.0 to 25.0 mm (Axis offset: ±10) Read V680S-D2KF67M V680-HS63 with metal on back (steel)
Page 131 Section 7 Appendices V680S-D2KF68 Antenna RF Tag Communications range 5.0 to 45.0 mm (Axis offset: ±10) Read V680-HS63 V680S-D2KF68 5.0 to 45.0 mm (Axis offset: ±10) Write 5.0 to 75.0 mm (Axis offset: ±10) Read V680-HS65 V680S-D2KF68 5.0 to 75.0 mm (Axis offset: ±10) Write Measurement Conditions V680-HS65...
Page 132 Section 7 Appendices V680S-D2KF68M Antenna RF Tag Communications range 5.0 to 35.0 mm (Axis offset: ±10) Read V680-HS63 V680S-D2KF68M 5.0 to 35.0 mm (Axis offset: ±10) Write 5.0 to 55.0 mm (Axis offset: ±10) Read V680-HS65 V680S-D2KF68M 5.0 to 55.0 mm (Axis offset: ±10) Write Measurement Conditions V680-HS65...
Page 133 Section 7 Appendices V680S-D8KF67 Antenna RF Tag Communications range 1.0 to 17.0 mm (Axis offset: ±2) Read V680-HS52 V680S-D8KF67 1.0 to 17.0 mm (Axis offset: ±2) Write 7.0 to 30.0 mm (Axis offset: ±10) Read V680-HS63 V680S-D8KF67 7.0 to 30.0 mm (Axis offset: ±10) Write 5.0 to 42.0 mm (Axis offset: ±10) Read...
Page 134 Section 7 Appendices V680S-D8KF67M Antenna RF Tag Communications range 1.0 to 16.0 mm (Axis offset: ±2) Read V680S-D8KF67M V680-HS52 with metal on back (steel) 1.0 to 16.0 mm (Axis offset: ±2) Write 6.0 to 25.0 mm (Axis offset: ±10) Read V680S-D8KF67M V680-HS63 with metal on back (steel)
Page 135 Section 7 Appendices V680S-D8KF68 Antenna RF Tag Communications range 5.0 to 45.0 mm (Axis offset: ±10) Read V680-HS63 V680S-D8KF68 5.0 to 45.0 mm (Axis offset: ±10) Write 5.0 to 75.0 mm (Axis offset: ±10) Read V680-HS65 V680S-D8KF68 5.0 to 75.0 mm (Axis offset: ±10) Write Measurement Conditions V680-HS65...
Page 136 Section 7 Appendices V680S-D8KF68M Antenna RF Tag Communications range 5.0 to 35.0 mm (Axis offset: ±10) Read V680-HS63 V680S-D8KF68M 5.0 to 35.0 mm (Axis offset: ±10) Write 5.0 to 55.0 mm (Axis offset: ±10) Read V680-HS65 V680S-D8KF68M 5.0 to 55.0 mm (Axis offset: ±10) Write Measurement Conditions V680-HS65...
Page 137 Section 7 Appendices Interrogation Zone V680-D1KP52MT The interrogation zone given here are for reference only. For information on communications ranges, refer to Communications Range Specifications in this section. The interrogation zone depends on the type of RF Tags used, the ambient temperature, surrounding metals, and noise. Be sure to check carefully when installing the system. p.114 V680-HS51 Embedded in Metal and V680-D1KP52MT V680-HS51 Embedded in Metal and V680-D1KP52MT...
Page 138 Section 7 Appendices V680-D1KP52M-BT01/-D1KP52M-BT11 The interrogation zone given here are for reference only. For information on communications ranges, refer to Communications Range Specifications in this section. The interrogation zone depends on the type of RF Tags used, the ambient temperature, surrounding metals, and noise. Be sure to check carefully when installing the system. p.115 V680-HS51 Embedded in Metal V680-HS52 Embedded in Non-Metal...
Page 139 Section 7 Appendices V680-D1KP53M The interrogation zone given here are for reference only. For information on communications ranges, refer to Communications Range Specifications in this section. The interrogation zone depends on the type of RF Tags used, the ambient temperature, surrounding metals, and noise. Be sure to check carefully when installing the system. p.116 V680-HS51 Embedded in Metal and V680-D1KP53M V680-HS51 Embedded in Metal and V680-D1KP53M...
Page 140 Section 7 Appendices V680-D1KP54T The interrogation zone given here are for reference only. For information on communications ranges, refer to Communications Range Specifications in this section. The interrogation zone depends on the type of RF Tags used, the ambient temperature, surrounding metals, and noise. Be sure to check carefully when installing the system. p.116 V680-HS52 Embedded in Non-Metal and V680-D1KP54T V680-HS63 with Non-Metal on Back Surface and V680-D1KP54T...
Page 141 Section 7 Appendices V680-D1KP66T The interrogation zone given here are for reference only. For information on communications ranges, refer to Communications Range Specifications in this section. The interrogation zone depends on the type of RF Tags used, the ambient temperature, surrounding metals, and noise. Be sure to check carefully when installing the system. p.118 V680-HS52 Embedded in Non-Metal and V680-D1KP66T V680-HS63 with Non-Metal on Back Surface and V680-D1KP66T...
Page 142 Section 7 Appendices V680-D1KP66MT The interrogation zone given here are for reference only. For information on communications ranges, refer to Communications Range Specifications in this section. The interrogation zone depends on the type of RF Tags used, the ambient temperature, surrounding metals, and noise. Be sure to check carefully when installing the system. p.119 V680-HS52 Embedded in Non-Metal and V680-D1KP66MT V680-HS63 with Non-Metal on Back Surface and V680-D1KP66MT...
Page 143 Section 7 Appendices V680-D1KP66T-SP The interrogation zone given here are for reference only. For information on communications ranges, refer to Communications Range Specifications in this section. The interrogation zone depends on the type of RF Tags used, the ambient temperature, surrounding metals, and noise. Be sure to check carefully when installing the system. p.120 V680-HS52 Embedded in Non-Metal and V680-D1KP66T-SP V680-HS63 with Non-Metal on Back Surface and V680-D1KP66T-SP...
Page 144 Section 7 Appendices V680-D1KP58HTN The interrogation zone given here are for reference only. For information on communications ranges, refer to Communications Range Specifications in this section. The interrogation zone depends on the type of RF Tags used, the ambient temperature, surrounding metals, and noise. Be sure to check carefully when installing the system. p.121 V680-HS65(with Metal on Back Surface) and V680-D1KP58HTN Read...
Page 145 Section 7 Appendices V680-D2KF52M The interrogation zone given here are for reference only. For information on communications ranges, refer to Communications Range Specifications in this section. The interrogation zone depends on the type of RF Tags used, the ambient temperature, surrounding metals, and noise. Be sure to check carefully when installing the system. p.122 V680-HS51 Embedded in Metal and V680-D2KF52M V680-HS51 Embedded in Metal and V680-D2KF52M...
Page 146 Section 7 Appendices V680-D2KF52M-BT01/-D2KF52M-BT11 The interrogation zone given here are for reference only. For information on communications ranges, refer to Communications Range Specifications in this section. The interrogation zone depends on the type of RF Tags used, the ambient temperature, surrounding metals, and noise. Be sure to check carefully when installing the system. p.123 V680-HS51 Embedded in Metal V680-HS52 Embedded in Non-Metal...
Page 147 Section 7 Appendices V680-D8KF67 The interrogation zone given here are for reference only. For information on communications ranges, refer to Communications Range Specifications in this section. The interrogation zone depends on the type of RF Tags used, the ambient temperature, surrounding metals, and noise. Be sure to check carefully when installing the system. p.124 V680-HS52 Embedded in Non-Metal and V680-D8KF67 V680-HS63 with Non-Metal on Back Surface and V680-D8KF67...
Page 148 Section 7 Appendices V680-D8KF67M The interrogation zone given here are for reference only. For information on communications ranges, refer to Communications Range Specifications in this section. The interrogation zone depends on the type of RF Tags used, the ambient temperature, surrounding metals, and noise. Be sure to check carefully when installing the system. p.125 V680-HS52 Embedded in Non-Metal and V680-D8KF67M V680-HS63 with Non-Metal on Back Surface and V680-D8KF67M...
Page 149 Section 7 Appendices V680-D8KF68/-D32KF68 The interrogation zone given here are for reference only. For information on communications ranges, refer to Communications Range Specifications in this section. The interrogation zone depends on the type of RF Tags used, the ambient temperature, surrounding metals, and noise. Be sure to check carefully when installing the system. p.126 V680-HS63 with Metal on Back Surface V680-HS63 with Metal on Back Surface...
Page 150 Section 7 Appendices V680S-D2KF67 The interrogation zone given here are for reference only. For information on communications ranges, refer to Communications Range Specifications in this section. The interrogation zone depends on the type of RF Tags used, the ambient temperature, surrounding metals, and noise. Be sure to check carefully when installing the system. p.127 V680-HS52 Embedded in Non-Metal and V680S-D2KF67 V680-HS63 with Non-Metal on Back Surface and V680S-D2KF67...
Page 151 Section 7 Appendices V680S-D2KF67M The interrogation zone given here are for reference only. For information on communications ranges, refer to Communications Range Specifications in this section. The interrogation zone depends on the type of RF Tags used, the ambient temperature, surrounding metals, and noise. Be sure to check carefully when installing the system. p.128 V680-HS52 Embedded in Non-Metal and V680S-D2KF67M V680-HS63 with Non-Metal on Back Surface and V680S-D2KF67...
Page 152 Section 7 Appendices V680S-D2KF68 The interrogation zone given here are for reference only. For information on communications ranges, refer to Communications Range Specifications in this section. The interrogation zone depends on the type of RF Tags used, the ambient temperature, surrounding metals, and noise. Be sure to check carefully when installing the system. p.129 V680-HS63 with Metal on Back Surface V680-HS63 with Metal on Back Surface...
Page 153 Section 7 Appendices V680S-D2KF68M The interrogation zone given here are for reference only. For information on communications ranges, refer to Communications Range Specifications in this section. The interrogation zone depends on the type of RF Tags used, the ambient temperature, surrounding metals, and noise. Be sure to check carefully when installing the system. p.130 V680-HS63 with Metal on Back Surface V680-HS63 with Metal on Back Surface...
Page 154 Section 7 Appendices V680S-D8KF67 The interrogation zone given here are for reference only. For information on communications ranges, refer to Communications Range Specifications in this section. The interrogation zone depends on the type of RF Tags used, the ambient temperature, surrounding metals, and noise. Be sure to check carefully when installing the system. p.131 V680-HS52 Embedded in Non-Metal and V680S-D8KF67 V680-HS63 with Non-Metal on Back Surface and V680S-D8KF67...
Page 155 Section 7 Appendices V680S-D8KF67M The interrogation zone given here are for reference only. For information on communications ranges, refer to Communications Range Specifications in this section. The interrogation zone depends on the type of RF Tags used, the ambient temperature, surrounding metals, and noise. Be sure to check carefully when installing the system. p.132 V680-HS52 Embedded in Non-Metal and V680S-D8KF67M V680-HS63 with Non-Metal on Back Surface and V680S-D8KF67...
Page 156 Section 7 Appendices V680S-D8KF68 The interrogation zone given here are for reference only. For information on communications ranges, refer to Communications Range Specifications in this section. The interrogation zone depends on the type of RF Tags used, the ambient temperature, surrounding metals, and noise. Be sure to check carefully when installing the system. p.133 V680-HS63 with Metal on Back Surface V680-HS63 with Metal on Back Surface...
Page 157 Section 7 Appendices V680S-D8KF68M The interrogation zone given here are for reference only. For information on communications ranges, refer to Communications Range Specifications in this section. The interrogation zone depends on the type of RF Tags used, the ambient temperature, surrounding metals, and noise. Be sure to check carefully when installing the system. p.134 V680-HS63 with Metal on Back Surface V680-HS63 with Metal on Back Surface...
Page 158: Calculation Example
Section 7 Appendices Communications Time (Reference) Communication time is defined as a time between the ID Flag Sensor starts the communication operation(at the time when the RF Tag comes in the communication area) and outputs the NORMAL/ STRB output signal. Communications Time (Reference) Operation Read Write...
Page 159: Reference Data: Antenna And Rf Tags Installation
Section 7 Appendices Reference Data: Antenna and RF Tags Installation Antenna Mounting Precautions V680-HS51 Effect of Surrounding Metals on the Antenna (Reference) When embedding the Antenna in metal, be sure the metal does not extend beyond the tip of the Antenna.
Page 160 Antenna range reduced by approx. 50%. 60 mm min. 15 mm min. Do not bend the cable into a curve tighter If the metal around the Antenna reaches the coil surface, the than 22 mm in radi u s. communications range will be reduced by approx. 50% compared with mo unting to a non-metallic s urface. ・ Mutual Interference beween Antennas (Reference) To prevent malfunctioning due to mutual interference when using more than one Antenna, leave suﬃcient space between them as shown in the following diagrams. ・Installing the Antennas Facing Each Other ・Installing the Antennas in Parallel 100 mm min. 120 mm min. ■ V680-HS61 ・Eﬀect of Surrounding Metals on the Antenna (Reference) In addition to surface mounting, it is also possible to embed the V680-HS61 in a metallic material to protect it from being struck bu other objects. To prevent malfunctioning, allow a space of at least 60 mm between the Antenna and the sides of the merallic material. If the space is less than 60 mm, the read/ write distance will be greatly diminished. In addition, the height of metallic material must not exceed that of the Antenna. Do not bend the cable into a curve tighter than 18 mm in radius. The communications range will be reduced signiﬁcantly if the Antenna is installed closer than 60 mm to metal surfaces. ・Mutual Interference beween Antennas (Reference) To prevent malfunctioning due to mutual interference when using more than one Antenna, leave suﬃcient space between them as shown in the following diagrams. ・Installing the Antennas Facing Each Other ・Installing the Antennas in Parallel RFID System User's Manual...
Page 161 Section 7 Appendices V680-HS63 Effect of Surrounding Metals on the Antenna (Reference) In addition to surface mounting, it is also possible to embed the V680-HS63 in a metallic material to protect it from being struck by other objects. To prevent malfunctioning, allow a space of at least 30 mm between the Antenna and the sides of the metallic material.
Page 162 Section 7 Appendices V680-HS65 Effect of Surrounding Metals on the Antenna (Reference) In addition to surface mounting, it is also possible to embed the V680-HS65 in a metallic material to protect it from being struck by other objects. To prevent malfunctioning, allow a space of at least 100 mm between the Antenna and the sides of the metallic material.
Page 163 Section 7 Appendices RF Tag Mounting Precautions V680-D1KP52MT Differences in Surrounding Metals (Reference) Communications ranges are affected by the type of metal in back of or surrounding the RF Tag, as shown in the following table. Steel Brass Aluminum V680-D1KP52M 100% 85% to 90% 80% to 85%...
Page 164 Section 7 Appendices Influence of RF Tag Angle (Reference) Install Antennas and RF Tags as parallel to each other as possible. Communications are possible even when an Antenna and an RF Tag are mounted at an angle, but the communications range will be shortened. The relation between the angle and the communications range is shown below.
Page 165 Section 7 Appendices V680-D1KP52M-BT01/-D1KP52M-BT11 Mutual Interference with RF Tags (Reference) To prevent malfunctioning due to mutual interference when using more than one RF Tag, leave sufficient space between them as shown in the following diagram. 25mm min. 25mm min. Influence of RF Tag Angle (Reference) Install Antennas and RF Tags as parallel to each other as possible.
Page 166 Section 7 Appendices V680-D1KP53M Differences in Surrounding Metals (Reference) Communications ranges are affected by the type of metal in back of or surrounding the RF Tag, as shown in the following table. Steel Brass Aluminum V680-D1KP53M 100% 90% to 95% 90% to 95% 90% to 95% Note: The value for steel around or behind the RF Tag is set to 100%.
Page 167 Section 7 Appendices Influence of RF Tag Angle (Reference) Install Antennas and RF Tags as parallel to each other as possible. Communications are possible even when an Antenna and an RF Tag are mounted at an angle, but the communications range will be shortened. The relation between the angle and the communications range is shown below.
Page 168 Section 7 Appendices V680-D1KP54T Effect of Metal behind RF Tags(Reference) The V680-D1KP54T communications distance is reduced if there is any metal material behind the RF Tag. If the RF Tag is to be mounted to metal, then use a insert a non-metal spacer (such as plastic or resin). The relationship between the distance from the RF Tag to the metal surface and the communications distance is shown below.
Page 169 Section 7 Appendices Mutual Interference with RF Tags (Reference) To prevent malfunctioning due to mutual interference when using more than one RF Tag, leave suffi- cient space between them as shown in the following diagram. 80mm min. 80mm min. Influence of RF Tag Angle (Reference) Install Antennas and RF Tags as parallel to each other as possible.
Page 170 Section 7 Appendices V680-D1KP66T Effect of Metal on Back of RF Tags (Reference) The V680-D1KP66T communications range is reduced if there is any metal on the back of the RF Tag. If the RF Tag is to be mounted to metallic material, then either use a V600-A86 Attachment (sold separately) or insert a non-metal spacer (such as plastic or resin).
Page 171 Section 7 Appendices Mutual Interference with RF Tags (Reference) To prevent malfunctioning due to mutual interference when using more than one RF Tag, leave sufficient space between them as shown in the following diagram. 100 mm min. 100 mm min. Influence of RF Tag Angle (Reference) Install Antennas and RF Tags as parallel to each other as possible.
Page 172 Section 7 Appendices V680-D1KP66MT Effect of Surrounding Metals (Reference) The V680-D1KP66MT can be surface-mounted or it can be embedded in metal. If it is embedded in metal, the height of the metal casing must not exceed that of the RF Tag. RF Tag RF Tag Embedded...
Page 173 Section 7 Appendices Influence of RF Tag Angle (Reference) Install Antennas and RF Tags as parallel to each other as possible. Communications are possible even when an Antenna and an RF Tag are mounted at an angle, but the communications range will be shortened. The relation between the angle and the communications range is shown below.
Page 174 Section 7 Appendices V680-D1KP66T-SP Effect of Metal on Back of RF Tags (Reference) The V680-D1KP66T-SP communications range is reduced if there is any metallic material on the back of the RF Tag. If the RF Tag is mounted on metallic material, insert a non-metal spacer (such as plastic or resin).
Page 175 Section 7 Appendices Mutual Interference with RF Tags (Reference) To prevent malfunctioning due to mutual interference when using more than one RF Tag, leave sufficient space between them as shown in the following diagram. 100mm min. 100mm min. 100mm min. 100mm min.
Page 176 Section 7 Appendices Influence of RF Tag Angle (Reference) Install Antennas and RF Tags as parallel to each other as possible. Communications are possible even when an Antenna and an RF Tag are mounted at an angle, but the communications range will be shortened. The relation between the angle and the communications range is shown below.
Page 177 Section 7 Appendices V680-D1KP58HTN Influence of Metal Behind RF Tag (Reference) Take the influence of metal behind RF Tags into consideration when mounting them. The communications range is adversely affected if there is any metal material around the RF Tag. The degree of influence depends on the type, size, and shape of the material around the RF Tag.
Page 178 Section 7 Appendices Influence of RF Tag Angle (Reference) The maximum communications range can be obtained when the Antenna and RF Tag are installed in parallel. When the RF Tag is installed on an angle, the communications range is reduced. Consider the effect of the RF Tag angle when installing the RF Tag.
Page 179 Section 7 Appendices V680-D2KF52M Differences in Surrounding Metals Communications ranges are affected by the type of metal in back of or surrounding the RF Tag, as shown in the following table. Steel Brass Aluminum V680-D2KF52M 100% 80% to 85% 80% to 85% 75% to 80% Note: The value for steel around or behind the RF Tag is set to 100%.
Page 180 Section 7 Appendices Influence of RF Tag Angle (Reference) Install Antennas and RF Tags as parallel to each other as possible. Communications are possible even when an Antenna and an RF Tag are mounted at an angle, but the communications range will be shortened. The relation between the angle and the communications range is shown below.
Page 181 Section 7 Appendices V680-D2KF52M-BT01/-D2KF52M-BT11 Mutual Interference with RF Tags (Reference) To prevent malfunctioning due to mutual interference when using more than one RF Tag, leave sufficient space between them as shown in the following diagram. 25mm min. 25mm min. Influence of RF Tag Angle (Reference) Install Antennas and RF Tags as parallel to each other as possible.
Page 182 Section 7 Appendices V680-D8KF67 Effect of Metal on Back of RF Tags (Reference) The V680-D8KF67 communications range is reduced if there is any metallic material on the back of the RF Tag. V680-HS52 and V680-D8KF67 V680-HS63 and V680-D8KF67 (mm) (mm) Distance to metal (x) Distance to metal (x) RF Tag...
Page 183 Section 7 Appendices Mutual Interference with RF Tags (Reference) To prevent malfunctioning due to mutual interference when using more than one RF Tag, leave sufficient space between them as shown in the following diagram. 200 mm min. 200 mm min. Influence of RF Tag Angle (Reference) Install Antennas and RF Tags as parallel to each other as possible.
Page 184 Section 7 Appendices V680-D8KF67M Effect of Surrounding Metals (Reference) The V680-D8KF67M can be surface-mounted or it can be embedded in metal. If it is embedded in metal, the height of the metal casing must not exceed that of the RF Tag. RF Tag RF Tag Embedded...
Page 185 Section 7 Appendices Influence of RF Tag Angle (Reference) Install Antennas and RF Tags as parallel to each other as possible. Communications are possible even when an Antenna and an RF Tag are mounted at an angle, but the communications range will be shortened. The relation between the angle and the communications range is shown below.
Page 186 Section 7 Appendices V680-D8KF67/-D32KF68 Effect of Surrounding Metals (Reference) • Special Attachment (V680-A81) Installation Direction M4 screw Spring washer The communications distance will be reduced if there is metal on Flat washer the back of an RF Tag. When mounting on a metal surface, use the V680-A81 special Attachment (sold separately) or insert a non-metallic spacer (e.g., plastic, resin, etc.).
Page 187 Section 7 Appendices Mutual Interference with RF Tags (Reference) To prevent malfunctioning due to mutual interference when using more than one RF Tag, leave sufficient space between them as shown in the following diagram. When V680-HS63 Is Used 120 mm min. 120 mm min.
Page 188 Section 7 Appendices Influence of RF Tag Angle (Reference) Install Antennas and RF Tags as parallel to each other as possible. Communications are possible even when an Antenna and an RF Tag are mounted at an angle, but the communications range will be shortened. The relation between the angle and the communications range is shown below.
Page 189 Section 7 Appendices V680S-D2KF67 Effect of Metal on Back of RF Tags (Reference) The V680S-D2KF67 communications range is reduced if there is any metallic material on the back of the RF Tag. V680-HS52 and V680S-D2KF67 V680-HS63 and V680S-D2KF67 (mm) (mm) Distance to metal (x) Distance to metal (x) RF Tag...
Page 190 Section 7 Appendices Mutual Interference with RF Tags (Reference) To prevent malfunctioning due to mutual interference when using more than one RF Tag, leave sufficient space between them as shown in the following diagram. 100 mm min. 100 mm min. Influence of RF Tag Angle (Reference) Install Antennas and RF Tags as parallel to each other as possible.
Page 191 Section 7 Appendices V680S-D2KF67M Effect of Surrounding Metals (Reference) The V680S-D2KF67M can be surface-mounted or it can be embedded in metal. If it is embedded in metal, the height of the metal casing must not exceed that of the RF Tag. RF Tag RF Tag Embedded...
Page 192 Section 7 Appendices Influence of RF Tag Angle (Reference) Install Antennas and RF Tags as parallel to each other as possible. Communications are possible even when an Antenna and an RF Tag are mounted at an angle, but the communications range will be shortened. The relation between the angle and the communications range is shown below.
Page 193 Section 7 Appendices V680S-D2KF68 Effect of Metal on Back of RF Tags (Reference) The V680S-D2KF68 communications range is reduced if there is any metallic material on the back of the RF Tag. V680-HS63 and V680S-D2KF68 V680-HS65 and V680S-D2KF68 (mm) (mm) Distance to metal (x) Distance to metal (x) RF Tag...
Page 194 Section 7 Appendices Mutual Interference with RF Tags (Reference) To prevent malfunctioning due to mutual interference when using more than one RF Tag, leave sufficient space between them as shown in the following diagram. When V680-HS63 Is Used 130 mm min. 130 mm min.
Page 195 Section 7 Appendices Influence of RF Tag Angle (Reference) Install Antennas and RF Tags as close to parallel to each other as possible. Communications are possible even when an Antenna and an RF Tag are mounted at an angle, but the communications range will be shortened.
Page 196 Section 7 Appendices V680S-D2KF68M Effect of Surrounding Metals (Reference) The V680S-D2KF68M can be surface-mounted or it can be embedded in metal. If it is embedded in metal, the height of the metal casing must not exceed that of the RF Tag. RF Tag RF Tag Embedded...
Page 197 Section 7 Appendices Mutual Interference with RF Tags (Reference) To prevent malfunctioning due to mutual interference when using more than one RF Tag, leave sufficient space between them as shown in the following diagram. When V680-HS63 Is Used 110 mm min. 110 mm min.
Page 198 Section 7 Appendices Influence of RF Tag Angle (Reference) Install Antennas and RF Tags as close to parallel to each other as possible. Communications are possible even when an Antenna and an RF Tag are mounted at an angle, but the communications range will be shortened.
Page 199 Section 7 Appendices V680S-D8KF67 Effect of Metal on Back of RF Tags (Reference) The V680S-D8KF67 communications range is reduced if there is any metallic material on the back of the RF Tag. V680-HS52 and V680S-D8KF67 V680-HS63 and V680S-D8KF67 (mm) (mm) Distance to metal (x) Distance to metal (x) RF Tag...
Page 200 Section 7 Appendices Mutual Interference with RF Tags (Reference) To prevent malfunctioning due to mutual interference when using more than one RF Tag, leave sufficient space between them as shown in the following diagram. 100 mm min. 100 mm min. Influence of RF Tag Angle (Reference) Install Antennas and RF Tags as parallel to each other as possible.
Page 201 Section 7 Appendices V680S-D8KF67M Effect of Surrounding Metals (Reference) The V680S-D8KF67M can be surface-mounted or it can be embedded in metal. If it is embedded in metal, the height of the metal casing must not exceed that of the RF Tag. RF Tag RF Tag Embedded...
Page 202 Section 7 Appendices Influence of RF Tag Angle (Reference) Install Antennas and RF Tags as parallel to each other as possible. Communications are possible even when an Antenna and an RF Tag are mounted at an angle, but the communications range will be shortened. The relation between the angle and the communications range is shown below.
Page 203 Section 7 Appendices V680S-D8KF68 Effect of Metal on Back of RF Tags (Reference) The V680S-D8KF68 communications range is reduced if there is any metallic material on the back of the RF Tag. V680-HS63 and V680S-D8KF68 V680-HS65 and V680S-D8KF68 (mm) (mm) Distance to metal (x) Distance to metal (x) RF Tag...
Page 204 Section 7 Appendices Mutual Interference with RF Tags (Reference) To prevent malfunctioning due to mutual interference when using more than one RF Tag, leave sufficient space between them as shown in the following diagram. When V680-HS63 Is Used 130 mm min. 130 mm min.
Page 205 Section 7 Appendices Influence of RF Tag Angle (Reference) Install Antennas and RF Tags as close to parallel to each other as possible. Communications are possible even when an Antenna and an RF Tag are mounted at an angle, but the communications range will be shortened.
Page 206 Section 7 Appendices V680S-D8KF68M Effect of Surrounding Metals (Reference) The V680S-D8KF68M can be surface-mounted or it can be embedded in metal. If it is embedded in metal, the height of the metal casing must not exceed that of the RF Tag. RF Tag RF Tag Embedded...
Page 207 Section 7 Appendices Mutual Interference with RF Tags (Reference) To prevent malfunctioning due to mutual interference when using more than one RF Tag, leave sufficient space between them as shown in the following diagram. When V680-HS63 Is Used 110 mm min. 110 mm min.
Page 208 Section 7 Appendices Influence of RF Tag Angle (Reference) Install Antennas and RF Tags as close to parallel to each other as possible. Communications are possible even when an Antenna and an RF Tag are mounted at an angle, but the communications range will be shortened.
Page 209: Rf Tag Memory Capacities And Memory Types
Section 7 Appendices RF Tag Memory Capacities and Memory Types Memory capacity Model Memory type Life expectancy (user memory) V680-D1KP52MT V680-D1KP52M-BT01 V680-D1KP52M-BT11 V680-D1KP53M Write endurance: 100,000 times per block (25°C) V680-D1KP54T 1,000 bytes EEPROM V680-D1KP66T Data retention: 10 years after writing (85°C or less) V680-D1KP66MT V680-D1KP66T-SP V680-D1KP58HTN...
Page 210: Rf Tag Memory Map
Section 7 Appendices RF Tag Memory Map V680-D1KP@@ Address (hex) Data 0000 0001 0002 0003 EEPROM is used as memory in the RF Tags. User area The memory capacity available to the user is 1,000bytes, including 0000 hex to 0003 hex the Write 03E6 Protection Setting Area).
Page 211 Section 7 Appendices V680S-D8KF@@ Address (hex) Data 0000 0001 0002 0003 FRAM is used as memory in the RF Tags. User area The memory capacity available to the user is 8,192bytes, including 0000 hex to 0003 hex the Write 1FFE Protection Setting Area).
Page 212: Chemical Resistance Of The Antennas And Rf Tags
Section 7 Appendices Chemical Resistance of the Antennas and RF Tags Chemical Resistance of the Antennas ■Applicable Models V680-HS51 V680-HS52-W/ V680-HS63-W/R V680-HS65-W/R V680-HS61 ABS resin is used for case material and epoxy resin for ﬁlling material. Refer to the following lists and do not use chemicals that aﬀect ABS and epoxy resin. ・ Chemicals That Cause Defo rmations, Cracks, Etc. ABS resin Epoxy resin Trichlene, acetone, xylene, to luene, gasoline, creosol, Aqua regia, chromic acid, sulfuric acid (90% RT), nitric acid methylene chloride, phenol, cyclohexane, aqua regia, chromic (60% RT), ammonia solution, acetone, methylene chloride, ...
Page 213 Section 7 Appendices Chemical Resistance of RF Tags Applicable Models V680-D1KP52MT V680-D1KP52M-BT01/-BT11 V680-D1KP53M V680-D2KF52M V680-D2KF52M-BT01/-BT11 PPS resin is used for case material and epoxy resin for filling material. Refer to the following lists and do not use chemicals that affect PPS and epoxy resin. RF Tags cannot be used in applications with explosion-proof specifications.
Page 214 Section 7 Appendices Applicable Models V680-D1KP54T V680-D1KP66T/MT V680-D1KP58HTN V680S-D2KF67/-D2KF67M/-D2KF68/-D2KF68M V680S-D8KF67/-D8KF67M/-D8KF68/-D8KF68M PPS resin is used for case material. Refer to the following lists and do not use chemicals that affect PPS resin. At room At room tem- tem- Chemical 90°C Chemical 90°C pera- pera-...
Page 215: Applicable Model
Section 7 Appendices Applicable Model V680-D1KP66T-SP PFA is used for the V680-D1KP66T-SP RF Tag coating. Refer to the following materials and check the characteristics before using them. Chemical Resistance of PFA Fluororesin (Reference Material) PFA: Tetrafluorethylene-Perfluoroalkylvinyletheir copolymer PFA fluororesin is non-reactive to most chemicals. It reacts to alkaline metals in the melted state, F2 (fluorine) under high temperature and high pressure, and some halogen derivatives.
Page 216 Section 7 Appendices Organic Chemicals Residual characteristic (%) Test temperature Chemical Weight gain (%) (°C) Tensile strength Stretch Water-acetic acid Acetic anhydride Trichloroacetic acid Isooctane Naphtha Mineral oil Toluene o-Creosol Nitrobenzene Benzyl alcohol Aniline n-Butylamine Ethylenediamine Tetrahydrofuran Benzaldehyde Cyclohexane Methyl ethyl ketone Acetophenone Dimethylphtalate n-Butyl acetate...
Page 217 Section 7 Appendices Applicable Models V680-D2KF67/67M V680-D8KF68/D32KF68 V680-D8KF67/67M Chemicals that affect RF Tags are shown below. Polybutylene terephthalate (PBT) resin is used for case material and epoxy resin for filling material. Refer to the following lists and do not use chemicals that affect PBT and epoxy resins. RF Tags cannot be used in applications with explosion-proof specifications.
Page 218: V600-Compatible Mode
Section 7 Appendices V600-Compatible Mode The V680-series ID Flag Sensor supports all functions of the previous V600 series, so that the customer using V600 series can apply the existing programming assets. This section describes the functions of the V600-compatible Mode. Correspondence table for V600-Compatible Mode setting switch Model of correspondence...
Page 219 Section 7 Appendices Mode Function Table Some of the functions cannot be used in the V600-compatible mode. Refer to followings table which shows supported functions for each mode. Mode Setting V600-Compatible Mode AUTO MODE1 AUTO MODE2 AUTO MODE3 TRIGGER MODE1 Function TRIGGER MODE2 TRIGGER MODE3...
Page 220 Section 7 Appendices Timing Charts : Mode2 Trigger Mode 2: Read In communications range Mode setting switch settings In communications RF Tag position range 10 ms min. INHIBIT/TRIG Communications Read- Read- Read- with RF Tag R/W input Data output Previous data output Data output Data output (OD0 to OD15: 16 bits)
Page 221 Section 7 Appendices Trigger Mode 2: VERIFY Mode setting switch settings In communications range In communications range RF Tag position 10 msec min. INHIBIT/TRIG Communications Verify- Verify- Verify- with RF Tag R/W input Data intput Reference Reference data 1 Reference data 2 Reference data 3 (ID0 to ID15: 16 bits) data 0...
Page 222 Section 7 Appendices Trigger Mode 2: Write In communications range In communications range Mode setting switch settings RF Tag position 10 ms min. INHIBIT/TRIG Communications Writing Writing Writing with RF Tag R/W input Data intput Write data2 Write data1 (ID0 to ID15: 16 bits) Access Address : 0010 hex t ms t ms...
Page 223 Section 7 Appendices Auto Mode 2: Read Mode setting switch settings RF Tag position In communications range In communications range INHIBIT/TRIG Communications Read- Reading with RF Tag R/W input 3 ms t ms 3 ms t ms NORMAL/STRB Access Address : 0010 hex Output Time : 50 ms ERR output Previous data...
Page 224 Section 7 Appendices Auto Mode 2: VERIFY Mode setting switch settings In communications range In communications range RF Tag position INHIBIT/TRIG Communications Verify- Verify- with RF Tag R/W input Data intput Reference data 1 Reference data 2 (ID0 to ID15: 16 bits) Access Address : 0010 hex 3 ms t ms 3 ms t ms...
Page 225 Section 7 Appendices Auto Mode 2: Write In communications range In communications range Mode setting switch settings RF Tag position INHIBIT/TRIG Communications Write Writing with RF Tag failed 0000 hex Write data R/W input Data intput (ID0 to ID15: 16 bits) Access Address : 0010 hex 3 ms t ms...
Page 226 Section 7 Appendices Timing Charts : Mode3 Trigger Mode 3: Read Mode setting switch settings RF Tag position In communications range INHIBIT/TRIG Communications Reading Reading with RF Tag OFF delay time NORMAL/STRB OFF delay time ERR output Access Address : 0010 hex Output Mode : 10 ms OFF delay PARTY output Parity value...
Page 227 Section 7 Appendices Trigger Mode 3: Read with Wire-saving mode Mode setting switch settings RF Tag position In communications range INHIBIT/TRIG Communications Reading Reading with RF Tag OFF delay time NORMAL/STRB OFF delay time ERR output Access Address : 0010 hex Output Mode : 10 ms OFF delay PARTY output Parity value...
Page 228 Section 7 Appendices Auto Mode 3: Read Mode setting switch settings In communications range In communications range RF Tag position INHIBIT/TRIG Communications Reading Reading imcomplete with RF Tag OFF delay time NORMAL/STRB ERR output Access Address : 0010 hex Output Mode : 10 ms OFF delay Parity PARTY output Value...
Page 229 Section 7 Appendices Write Protect function for V600-compatible Mode The write protection for V600-compatible modes (Trigger Mode2 : SYNC2, Auto Mode 2 : AUTO2) operates with the same method as the V600 (the previous model). The V600 write protection function has two setting methods depending on the type of RF Tag. Use the following procedure to make the settings for each write protection method.
Page 230 Section 7 Appendices V680-D@KF6@ /V680S -D2KF6@ Setting Write Protection Write protection is set in the 4 bytes of RF Tag addresses 0002 to 0005 hex. The setting for the most significant bit of address 0002 hex enables or disables write protection for the RF Tag. •...
Page 231 Section 7 Appendices Write Protection Setting Example Start Address Lower Than the End Address The memory area between the start address and end address will be write-protected. 0000 Address Upper digits Lower digits 0015 Write- protected 0002 hex Area 0120 0003 hex 0004 hex 0005 hex...
Page 232 Section 7 Appendices Start Address Higher Than End Address The memory area between the start address and the last RF Tag address, as well as the area between 0006 hex and the end address will be write-protected. Address Upper digits Lower digits 0002 hex 0003 hex...
Page 233: Degree Of Protection
Section 7 Appendices Degree of Protection Ingress protection degrees (IP-@@) are determined by the following tests. Be sure to check the sealing capability under the actual operating environment and conditions before actual use. IEC (International Electrotechnical Commission) IEC 60529:2001 (A) First Digit: Degree of Protection from Solid Materials Degree Protection No protection...
Page 234 Oil-proof Protects against penetration of oil drops or oil spray approaching from any direction. Note. Oil resistance has been tested using a specific oil as defined in the OMRON test method. (JIS C 0920:2003, Appendix 1) RFID System User's Manual...
Page 235 Section 7 Appendices MEMO RFID System User's Manual...
Page 236: Revision History
March 2008 Original production Added items for V680-D1KP53M, V680-D8KF67/-D 8KF67M RF Tags, overseas regulations and January 2009 standards, and made other minor corrections. May 2009 The material of V680-D2KF67/-D2KF67M is changed. Added items for V680-D1KP52M-BT01/-D1KP52M-BT11/-D2KF52M-BT01/-D2KF52M-BT11 RF Tags. January 2012 Deleted the related information on the overseas regulations and standards. Made other minor corrections. November 2012 Added item for V680-D1KP58HTN RF Tag, and made other minor corrections. February 2013 Minor changed. Added items for V680S-D2KF67/-D2KF67M/-D2KF68/-D2KF68M RF Tags. February 2014 Deleted items for V680-D2KF67 RF Tags. and made other minor corrections. April 2014 The dimensions of V680S-D2K F67/-D2KF67M/-D2KF68/-D2KF68M is changed. Added items for V680S-D8KF67/-D8KF67M/-D8KF68/-D8KF68M RF Tags. October 2014 and made other minor corrections. May 2018 Added items for V680-D1KP54T RF Tags, and made other minor corrections. November 2018 Made other minor corrections. Jun 2023 Added Items for V680-HS61. RFID System User's Manual...
Page 238 The Netherlands IL 60173-5302 U.S.A. Tel: (31)2356-81-300/Fax: (31)2356-81-388 Tel: (1) 847-843-7900/Fax: (1) 847-843-7787 © OMRON Corporation 2008-2018 All Rights Reserved. OMRON (CHINA) CO., LTD. OMRON ASIA PACIFIC PTE. LTD. In the interest of product improvement, Room 2211, Bank of China Tower, No.

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