Product Description Quick Start Guide Revision: Firmware version: 1.10 Firmware upgrades: Specifications Operating Modes: Slaves Supported: Configuration: IC200BEM103-MA None Master only, Slave only, Combined Master/Slave Up to 40 slave devices may be configured for the Master mode Configured as a Generic Communication Module with contiguous %I, %Q, %AI, and %AQ references. Status Data: Slave presence bit per each slave device, 64 bits total. DeviceNet Features: Slave only - Group 2 Only Server or UCMM Capable (COMMREQ selectable) DeviceNet network address: DeviceNet network data rate: Indicators (3): Master or Master/Slave - UCMM Capable 0 to 63. COMMREQ selectable. 125K, 250K, 500K baud. COMMREQ selectable. OK LED to indicate the status of the NCM after powerup. Mod LED to indicate the status of the NCM module. Net LED to indicate communication status on the DeviceNet network. Power Consumption: Backplane: 140mA at 5V, 10mA at 3.3V DeviceNet: 125mA maximum The DeviceNet Network Control Module is a DeviceNet master/slave module that provides an interface to a DeviceNet network. One or more NCMs may be installed at any location in the PLC. 1. Install the Communications Carrier on the DIN Rail by simply clicking it into place. Note: Connecting carriers must be installed on the same section of 35mm x 7.5mm DIN rail. The DIN rail must have a conductive (unpainted) finish for proper grounding. 2. Install the Module on the Communications Carrier. The latch on the module must be in the unlocked position. Align the connectors and the latch post and press the NCM down until the two tabs on the bottom of the NCM click into place. Turn the latch to the locked position to secure the NCM to the top of the carrier. 3. Connect the communications bus to the connector on the front of the Network Control Module. (Refer to the heading Bus Installation Guidelines for detailed bus installation instructions.) 4. Remove the connector cover on the right-hand side of the Communications Carrier. Do not discard this cover; you will need to install it on the last carrier. It protects the connector pins from damage and ESD during handling and use. Connector Cover PLC CPU power supply Optional booster power supply DeviceNet Network Control Module 5. Install additional modules by mounting modules on their carriers and sliding them along the DIN rail to fully engage the connectors in the sides of the carriers. Preinstallation Check Carefully inspect all shipping containers for damage. If any equipment is damaged, notify the delivery service immediately. Save the damaged shipping container for inspection by the delivery service. After unpacking the equipment, record all serial numbers. Save the shipping containers and packing material in case it is necessary to transport or ship any part of the system. 6. Power up the System, and Observe the Module LEDs. The LEDs indicate the presence of power and show the operating mode and status of the NCM. OK MOD NET 1
OK MOD NET OFF when the NCM has not yet started its powerup sequence. Blinking green indicates the NCM is performing its powerup sequence and has not yet finished successfully. Green indicates the NCM has successfully completed powerup diagnostics. Amber when the NCM has either failed powerup diagnostics or has not yet received a valid from the CPU. Blinking amber means the NCM has failed powerup diagnostics. The number of blinks indicates the fault type. OFF when the NCM is not powered. blinks green if the NCM is missing, incomplete, or incorrect. The NCM may be in Standby state. green when the NCM is operating normally. blinks red if there is a recoverable fault. red if there is an unrecoverable fault. The NCM may need replacing. OFF when the NCM is not online or not powered. blinks red and green if the NCM detects a Network Access error and is in the Communications Faulted state. blinks green if the NCM is online but has no connections in the established state. It has no established connections to other nodes. green when the NCM is online and has connections in the established state. blinks red if one or more I/O Connections are in the Timed-Out state. red if an error renders the NCM incapable of communicating on the network. Bus Installation Guidelines The network cable required for DeviceNet operation is specified in the following table. A 5-conductor cable is necessary. One wire is a drain, two wires are for carrying power on the network, and the remaining two wires are to carry the data transmission. On a DeviceNet fieldbus, every device must, at least, power its network transceivers from the network power source. Some devices draw all of their power from the network supply. DeviceNet specifies two types of network cable, Thick and Thin cable. Thick cable provides for longer distances and more power. Generally, Thick cable is used for the Trunk cable. Thin cable is used for shorter distances and is generally used for drop cables or where cable flexibility is necessary. DeviceNet Cable Specifications Thick Cable General Specifications Thin Cable General Specifications Network Topology Redundancy Network Power for Node devices Allowed Nodes (Bridging excluded) Data Packet Size Duplicate Address Detection Error Detection / Correction Two shielded pairs - Common axis with drain wire in center Overall braid shield - 65% coverage; 36 AWG or 0.12mm tinned Cu braid minimum (individually tinned) Drain wire- #18 Copper minimum; 19 strands minimum (individually tinned) Outside diameter - 0.410 inches (min) to 0.490 inches (max.) roundness radius delta to be within 15% of 0.5 O.D. Two shielded pairs - Common axis with drain wire in center Overall braid shield - 65% coverage; 36 AWG or 0.12mm tinned Cu braid minimum (individually tinned) Drain wire - #22 Copper; 19 strands minimum (individually tinned) Outside diameter - 0.240 inches (min.) to 0.280 inches (max.) roundness radius delta to be within 20% of 0.5 O.D. Bus with limited branching (trunkline/dropline) Not Supported Nominal 24 volt DC ±4% 64 nodes 0-8 bytes with allowance for message fragmentation Addresses verified at power-up CRC - retransmission of message if validity not acknowledged by recipient Installation in Hazardous Locations This equipment is suitable for use in CLASS I, DIVISION 2, GROUPS A, B, C, D or non-hazardous locations only. WARNING - EXPLOSION HAZARD - substitution of components may impair suitability for CLASS I, DIVISION 2; WARNING - EXPLOSION HAZARD - when in hazardous locations, turn off power before replacing or wiring modules; and WARNING - EXPLOSION HAZARD - Do not connect or disconnect equipment unless power has been switched off or the area is known to be non-hazardous. 2
Bus Length The maximum length of the bus is limited by the cable type, transfer rate, and the number and accumulated length of drop lines. Individual branch lengths may not exceed 6 meters and are limited to one network node per drop. However, the node may be a node offering multiple ports. With Thin cable, the maximum bus length, regardless of data rate, is 100m. With Thick cable used as the trunk line, the maximum bus length is as shown in the following table. Data Rate 500Kbps 250Kbps 125Kbps Bus length and drop length restrictions 100m bus length and branches totaling < 39m 250m bus length and branches totaling < 78m 500m bus length and branches totaling < 156m Bus Connectors and Termination DeviceNet uses several forms of connectors. The NCM provides the 5- pin standard Phoenix open-style pluggable connector. The pin-to-signalto-wire color assignments are shown in the following table: Pin Signal Wire Color 1 V- Black 2 CAN_L Blue 3 Shield Bare 4 CAN_H White 5 V+ Red Connector orientation on the NCM is shown in figure below: 1 - V- 2 - CAN_L 3 Shield 4 - CAN_H 5 - V+ Termination of a DeviceNet network is passive and includes one resistor at each end of the network. A terminating resistor is placed across the data communication signals at pin 2 (CAN_L) and pin 4 (CAN_H). Correct terminating resistor is a 121 ohm 1% ¼ watt resistor. Bus Power Supply and Grounding DeviceNet requires a power supply of 24VDC (±4%) at a 16A maximum. However, with the use of Thick cable, a maximum of 8A is permitted on a single network segment. This is possible if the power supply is placed at the center point of two network segments, thus supplying 8A to each segment. With the use of thin cable, a maximum of 3A is permitted. As with most Fieldbus networks, grounding of the network and its devices is very important. In DeviceNet, it is required that all cable shields be tied to ground at each device connection. This is done by tying the bare wire of the cable to pin 3 (Shield) of the connector. In addition, the DeviceNet network power supply must be grounded, but only at one point. The V- signal must be connected to Protective Earth Ground at the power supply only. If multiple power supplies are used, only one power supply must have V- connected to Earth Ground. Configuration Guidelines The DeviceNet Network Control Module must be configured in two steps. The first step uses the software to include the module in the PLC. The second step uses the programming software to send a COMMREQ containing the network addressing and data lengths to the NCM. PLC Configuration for the DeviceNet NCM The NCM is configured as part of the overall PLC system. The software is used to specify the following module characteristics: A location. The NCM can be placed in any module location in the system. In the selected location, insert a Communication Carrier. On that Carrier, insert a Generic Communications Module. Settings: Select the Reference Address and Length for an I/O area in each of the 4 reference types: I, AI, Q, and AQ. The length for each must exactly match the total amount of data of that type for all the slave devices controlled by the NCM, including the 64 bits of Communications Status Data provided by the NCM itself. For example, the %I length must equal the total amount of all discrete input data contained in the NCM s input data area, described later in this chapter. And the %AI length must equal the total amount of all analog input data contained in the NCM's input data area. Conversely, the %Q and %AQ lengths must equal the total amount of all discrete and analog output data, respectively. Enter the Module ID: FFFF9808. Wiring: can be used to enter tags for the different data points. Programming Guidelines The second part of configuring an NCM is to send a single COMMREQ from the application program to the NCM. No communications can occur until a valid COMMREQ is received by the NCM. The format of this COMMREQ is shown below. The COMMREQ defines whether the NCM is used as a DeviceNet Master, a DevceNet Slave, or as both simultaneously. It specifies the network address and data rate of the NCM. It also specifies the network address of each device, the I/O mode, and the lengths of each slave s data. The sum of the I/O data for each slave device (including the NCM itself, if the NCM is a Slave) and the 64 bits of Communications Status Data must exactly equal the length for each reference type entered using the software. Configuring the NCM as a DeviceNet Master Only When configuring the NCM as a Master, the COMMREQ must specify: Network address of the Master Network data rate of the Master For each subordinate slave: its network address its I/O mode the amount of I/O data of each type: I, AI, Q, AQ Configuring the NCM as a DeviceNet Slave Only When configuring the NCM as a Slave, the COMMREQ must specify: Network address Network data rate Network mode Amount of I/O data of each type: I, AI, Q, AQ 3
Configuring the NCM as a Master and Slave Combined When configuring the NCM as both a DeviceNet Master and Slave, the COMMREQ must provide all of the information for both a Master and Slave. Note that in this combined scenario, the network mode of the slave is ignored as the Master requires the slave to be UCMM-capable. Network address of the Master/Slave. Network data rate of the Master/Slave. For the NCM as a Slave the amount of I/O data of each reference type: I, AI, Q, AQ For each subordinate slave: the network address the I/O mode the amount of I/O data of each type: I, AI, Q, AQ COMMREQ Command Block Word # Contents 1 Length of the data block in words. (Shown below, number of slaves = length): 0 slave = 8, 1 slave =11, 2 slaves = 14, 3 slaves =17,, n slaves = 8 + n * 3. 2 Always 0 3 Status Pointer Memory (8 = R, 10 = AI, 12 = AQ) 4 Status Pointer Offset (0 based) 5-6 Always 0 The slave devices can be entered in the COMMREQ in any order. The NCM checks that the lengths for the four data areas sent in the PLC file match the sum of the lengths sent in the COMMREQ. For convenience, the units of length in the of a Generic Communication Module match the units of length defined in the COMMREQ. Any bit length field must be entered as a multiple of 8 bits, such as 8, 16, 24, etc. COMMREQ Data Block Word # Byte # Contents 1 1-2 COMMREQ Command Number = 1000H 2 3 Master Address (0 63) 4 Master Baud Rate (0 = 125k, 1 = 250k, 2 = 500k) 3 5 If NCM is Slave, Length of its I data (in bits, 0 if none) 6 If NCM is Slave, Length of its AI data (in words, 0 if none) 4 7 If NCM is Slave, Length of its Q data (in bits, 0 if none) 8 If NCM is Slave, Length of its AQ data (in words, 0 if none) 5 9-10 Reserved for Master Scan Rate, 0 = Scan as fast as possible 6 11-12 NCM Slave communication mode (0 = UCMM-capable, 1 = Group 2 Only) This field is only applicable when the NCM is configured as a Slave only. This field is also ignored when the NCM is configured as a Master device. In the Master case, the NCM Slave communication mode is fixed as UCMM-capable. 7-8 13-16 Reserved 9 17 First Slave s Address (0 63) 18 First Slave s I/O mode (1 = Poll, 2 = Strobe, 4 = COS w/ack, 0xC = COS w/o Ack) Word # Byte # Contents 10 19 First Slave s I data length (in bits, 0 if none) 20 First Slave s AI data length (in words, 0 if none) 11 21 First Slave s Q data length (in bits, 0 if none) 22 First Slave s AQ data length (in words, 0 if none) 12-14 23-28 Second Slave s : : : : : 126-128 251 256 Fortieth Slave s COMMREQ Return Codes The following table lists the possible return codes returned by the COMMREQ upon completion. The return code is written to the Status Pointer location specified by Words 3 and 4 of the COMMREQ Command Block. Return Description Code (Hex) 1 Successful Status - Network operation can proceed 2 NCM has already received a COMMREQ 3 NCM has not been configured via PLC 4 NCM is using the default, i.e. includes 64 bits %I only 5 COMMREQ does not include sufficient data (length must be 8 when configured as a Slave Only) 6 Slave information is incomplete (length must be 11,14,17, etc when configured as a Master) 7 COMMREQ Command number is invalid (must be 0x1000) 8 Reserved fields (Words 7-8) are not 0 as required 9 Total Discrete Input length does not match the module A Total Discrete Output length does not match the module B Total Analog Input length does not match the module C Total Analog Output length does not match the module D NCM network address is invalid (must be 0-63) E NCM network data rate is invalid (must be 0,1,2) F Slave network address is invalid (must be 0-63) 10 Reserved 11 Slave I/O type is invalid (must be 1,2,4, or 0xC) 12 Multiple I/O types are specified for a slave (must be 1,2,4,or 0xC) 13 When configured as a Strobe device, the output data length must be 0 14 When configured as a Strobe device, input data length must 1-8 bytes 15 Duplicate for a slave device. There are two or more entries with the same Slave network address. 16 Master or Slave Discrete Input Length must be divisible by 8 (8,16,24, etc) 17 Master or Slave Discrete Output Length must be divisible by 8 (8,16,24, etc) 18 Unknown Configuration error 19 Headend stopped - aborted 4
COMMREQ Example The following example illustrates the COMMREQ function block of the PLC logic and the COMMREQ Command Block, Data Block, and Return Code. IN SYSID TASK COMMREQ Parameters The IN parameter specifies the location of the Command and Data Block. The SYSID parameter specifies the physical slot location of the NCM. In the following example, the NCM is in slot 1 next to the PLC CPU. The TASK parameter specifies the NCM application task to which the COMMREQ is directed. The TASK must always be 0. %R00001 1 0 COMM REQ IN SYSID TASK The following example configures the NCM to communicate with 5 slave devices with Slave Addresses 1 through 5. The Master will use address 0 and operate the network at 500Kbits/sec. The Master will not act as a slave device in this. Address Device Description Network I/O Requirements 1 2 input points 2 output points 2 4 input points 4 output points 3 4 input points 4 output points, 2 analog inputs 2 analog outputs 4 2 input points 2 output points 5 1 input point 1 output point FT 2 bytes Input (1 byte of data +1 byte of status) 2 bytes Input (1 byte of data + 1 byte of status) 2 bytes Input (1 byte of data + 1 byte of status) 2 words Input 2 words Output 1 byte Input 1 byte Input The COMMREQ Command Block is placed at %R00001 through %R00006 and the Data Block follows immediately from %R00007 through %R00029. When specifying the input and output lengths for the slave devices, specify the number of bits for discrete data and the number of words for analog data. Hence, 1 byte of input data is specified as 8 bits. And 1 word of output data is specified as 1 word. COMMREQ Area Command Block Data Block Ref Table Value Description %R1 23 Length of Data Block (23 words, %R7-%R29) %R2 0 Not used (must be 0) %R3 8 Reference Table (8=%R) %R4 99 Reference Table Offset %R100 %R5 0 Not used (must be 0) %R6 0 Not used (must be 0) %R7 0x1000 COMMREQ Command %R8 0x200 Master Address = 0 Baud Rate = 500K %R9 0 NCM is not a slave %R10 0 NCM is not a slave %R11 0 Reserved (must be 0) %R12 0 NCM is not a slave %R13 0 Reserved (must be 0) %R14 0 Reserved (must be 0) %R15 0x101 Slave Address 1 %R16 0x10 (16) 16 bits (2 bytes) input %R17 0x08 8 bits (1 byte) output %R18 0x102 Slave Address 2 %R19 0x10 (16) 16 bits (2 bytes) input %R20 0x08 8 bits (1 byte) output %R21 0x103 Slave Address 3 %R22 0x210 2 words input 16 bits (2 bytes) input %R23 0x208 2 words output 8 bits (1 byte) output %R24 0x104 Slave Address 4 %R25 0x08 8 bits (1 byte) input %R26 0x08 8 bits (1 byte) output %R27 0x105 Slave Address 5 %R28 0x08 8 bits (1 byte) output %R29 0x08 8 bits (1 byte) input 5
Finally, when specifying the Generic Communication Module for the NCM, it is necessary to add up the I/O requirements of each of the slave devices. Also add the 64 bytes of status for the NCM. Generic Communication Module Reference and Lengths %I 128 (64 for the NCM status + 16 + 16 + 16 + 8 + 8) %Q 40 (8 + 8 + 8 + 8 + 8) %AI 2 %AQ 2 Communications Status Data Format The first 8 bytes (64 bits) of the NCM input data contain the communications status of each of the 64 node addresses. By looking at this data first, the application program in the PLC can determine the validity of each device s input data. MSB 7 6 Byte 0 5 4 3 Byte 1 2 1 Byte 2 LSB 0 Byte 0 - Node addresses 0-7 Byte 1 - Node addresses 8-15 Byte 2 - Node addresses 16-23 Byte 3 - Node addresses 24-31 Byte 4 - Node addresses 32-39 Byte 5 - Node addresses 40-47 Byte 6 - Node addresses 48-55 Byte 7 - Node addresses 56-63 Byte 3 Byte 4 Byte 5 MSB 55 54 Byte 6 53 52 51 Byte 7 50 49 LSB 48 Product Revision History Rev Date Description IC200BEM103-MA Oct 2016 EU RoHS compliant module per directive 2011/65/EU dated 8-June- 2011. No changes to features, performance or compatibility. IC200BEM103-LA Feb 2012 Label change. No changes to IC200BEM103-KA Mar 2011 features, performance or compatibility. IC200BEM103-JA Mar 2010 IC200BEM103-HA Oct 2008 Changed manufacturing location. No changes to features, performance or compatibility. Updated Power Supply OK signal circuitry. IC200BEM103-GA Apr 2005 Improvement to latching mechanism IC200BEM103-EA Apr 2004 Changed to V0 plastic for module housing. IC200BEM103-DA Jan 2004 Improved noise immunity. IC200BEM103-CA Jan 2004 IC200BEM103-BA Nov 2002 ATEX approval for Group 2 Category 3 applications. Improved reporting of Open Input error at higher temperatures. Added parallel RC connection for ODVA compliance. IC200BEM103-AA Aug 1999 Initial product release Each bit represents the status of the device corresponding to that node address. For example, bit 0 in byte 0 represents the status of the device with node address 0. Bit 1 in byte 0 represents the status of the device with node address 1, and so on. When the NCM is configured as a Slave device, the corresponding bit for the NCM address represents the status of the Slave device. When the NCM is configured as a Master only, the corresponding bit is 0. Bit Value Description 0 The device is NOT successfully exchanging I/O data on the DeviceNet network 1 The device is successfully exchanging I/O data on the DeviceNet network Operating Notes/Restrictions 1. The DNCM is limited to communicating with up to 40 slave devices. 2. Because a quick RUN-STOP-RUN transition of the CPU headend may cause the NCM to become confused during, it is suggested that the Configuration COMMREQ to the NCM be delayed at least 4 seconds after first scan. 1999-2016 General Electric Company. All Rights Reserved. * Indicates a trademark of General Electric Company and/or its subsidiaries. All other trademarks are the property of their respective owners. 6