DeltaV SIS with Electronic Marshalling Hardware Reference Guide.pdf

March 26, 2018 | Author: Quayo Deejay | Category: Electrical Connector, Relay, Ethernet, Fuse (Electrical), Thermocouple


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D800057X012April 2013 DeltaV SIS™ CHARMs Smart Logic Solver Hardware Reference Printed in the Republic of Singapore. © Emerson Process Management 1996 - 2013. All rights reserved. For Emerson Process Management trademarks and service marks, go to Emerson Process Management Trademarks and Service Marks. All other marks are property of their respective owners. The contents of this publication are presented for informational purposes only, and while every effort has been made to ensure their accuracy, they are not to be construed as warranties or guarantees, expressed or implied, regarding the products or services described herein or their use or applicability. All sales are governed by our terms and conditions, which are available on request. We reserve the right to modify or improve the design or specification of such products at any time without notice. See the CE statement in the Preface to this manual. Emerson Process Management Distribution Ltd. Process Systems and Solutions Meridian East Meridian Business Park Leicester, LE19 1uX, UK Emerson a.s. European System and Assembly Pieštanská 1202/44 Nové Mesto nad Váhom 91528 Slovakia Fisher-Rosemount Systems, Inc. – an Emerson Process Management company 1100 W. Louis Henna Blvd. Round Rock, TX 78681 Contents Contents Preface ............................................................................................................................ iii Chapter 1 CHARMs Smart Logic Solver hardware specifications ........................................................ 1 CHARMs Smart Logic Solver (CSLS) SIS hardware overview ......................................................................... 1 CHARMs Smart Logic Solver ........................................................................................................................2 CHARMs Smart Logic Solver Power Module .................................................................................................4 SZ Controller ...............................................................................................................................................6 CHARMs Smart Logic Solver Carrier ............................................................................................................ 8 Safety Network Ports ................................................................................................................................ 10 Reset Safety Network Ports ........................................................................................................... 11 SZ Controller Carrier ................................................................................................................................. 12 Ethernet Isolation Ports ............................................................................................................................ 14 CHARM Baseplate ..................................................................................................................................... 16 I.S. CHARM Baseplate ............................................................................................................................... 19 Address Plug .............................................................................................................................................22 LS CHARM Column Terminator ................................................................................................................. 23 LS CHARM Column Extenders and cable ....................................................................................................23 Chapter 2 Logic Solver CHARMs Terminal Block specifications .........................................................27 CHARM Terminal Block ............................................................................................................................. 27 CHARM Fused Injected Power Terminal Block ........................................................................................... 29 CHARM Thermocouple / mV Terminal Block ............................................................................................. 30 I.S. CHARM Terminal Block ........................................................................................................................31 I.S. CHARM Thermocouple mV Terminal Block ..........................................................................................32 DVC Terminal Block .................................................................................................................................. 33 LS CHARM Address Terminal .....................................................................................................................34 Redundant Terminal Block ........................................................................................................................35 Redundant DTA Injected Power Relay Terminal Block ............................................................................... 37 Redundant DTA Relay Terminal Block ....................................................................................................... 39 Redundant ETA Relay Terminal Block ........................................................................................................ 40 Redundant DVC Terminal Block ................................................................................................................ 42 Chapter 3 Logic Solver CHARMs specifications ................................................................................ 45 LS input CHARMs specifications ................................................................................................................ 45 LS AI 0-10 VDC isolated CHARM .................................................................................................... 45 LS AI 4-20 mA HART CHARM ......................................................................................................... 47 LS DI 24 VDC isolated CHARM ....................................................................................................... 48 LS DI 120 VAC isolated CHARM ..................................................................................................... 50 LS DI 230 VAC isolated CHARM ..................................................................................................... 52 LS DI 24 VDC low-side (dry contact) CHARM ..................................................................................53 LS DI NAMUR CHARM ....................................................................................................................55 LS RTD / Resistance input CHARM ................................................................................................. 57 LS Thermocouple / mV input CHARM ............................................................................................ 59 LS Intrinsically Safe input CHARMs specifications ...................................................................................... 61 LS AI 4-20 mA HART (Intrinsically Safe) CHARM ............................................................................. 61 LS DI NAMUR (Intrinsically Safe) CHARM ....................................................................................... 63 i ............... 70 LS DVC HART DTA CHARMs .......................................................................................................................................................................90 Chapter 5 Networks in a CHARMs Smart Logic Solver SIS system ...........................................................................................77 LS 24 VDC Power CHARM ................................................................................................................90 Ethernet Isolation Port LEDs ......... 105 Index ................................................... 83 Analog LS CHARMs LED ................................ 103 Chapter 7 Product type numbers for CHARMs Smart Logic Solver SIS hardware ....Contents LS RTD / Resistance input (Intrinsically Safe) CHARM ................................................107 ii .........................................................................................................103 Temperature and humidity specifications for CSLS SIS hardware ..........87 Safety Network Port LEDs .........96 Twisted pair and fiber-optic star network with DeltaV safety switches ................................... vibration....... 80 Chapter 4 LED descriptions for CHARMs Smart Logic Solver hardware ................................68 LS Output CHARMs specifications ...................................................................................................................................................................................................................................................................................................................................................................................................................... and shock specifications for CSLS SIS hardware ........................................................... 93 Communication in a CHARMs Smart Logic Solver SIS system ...............................................105 Product type numbers for CHARMs Smart Logic Solver SIS hardware ........................................................................................................... 93 DeltaV LSN20 Safety Switches .................................................................................. 88 SZ controller LEDs .......................................65 LS Thermocouple / mV input (Intrinsically Safe) CHARM ..................................................................................................... 94 DeltaV SRM100 Safety Switch ............................................................................................................ 70 LS DO 24 VDC CHARMs ...............................................................................................................................................................................................................................99 Twisted pair network with DeltaV safety switches and firewalls .............................................................. 103 Contaminants..................................................................... 97 Twisted pair network with DeltaV safety switches ..............................................83 Discrete LS CHARMs LEDs .............................................................................................................................................. 101 Chapter 6 Environmental specifications for CHARMs Smart Logic Solver hardware ................ 85 CHARMs Smart Logic Solver LEDs ....................... All installation and maintenance procedures described in this document must be performed by qualified personnel and all equipment must be used only for the purposes described. Note All electrical installations must conform to applicable federal. • The Quick Start Guide for DeltaV Power. Warnings are used to describe a critical procedure that must be followed to prevent a safety risk or equipment damage. Conventions used in this manual Notes are used to help you to understand important information. Assumptions It is assumed that you have read the Quick Start Guide for DeltaV Power. Related documentation • The DeltaV SIS™ CHARMs Smart Logic Solver Hardware Installation manual contains information about installing CHARMs Smart Logic Solver (CSLS) SIS hardware. and local codes and regulations. wiring diagrams. specifications. and Surge Suppression manual contains instructions for properly preparing your site for electrical power and grounding. Failure to follow the procedures may compromise compliance. and Surge Suppression is available from your Emerson Process Management representative or sales office. and Surge Suppression and have followed the instructions for properly preparing your site for electrical power and grounding before installing your DeltaV system. Grounding. The Quick Start Guide for DeltaV Power. the protection provided by the equipment may be impaired. and other reference information for DeltaV CHARMs Smart Logic Solver (CSLS) SIS hardware. these products must be installed and maintained according to the procedures described in this document. state. To maintain compliance. It is also assumed that all installation procedures described in this document are performed by qualified personnel and that the equipment is used only for the purposes described. Grounding. CE statement This manual describes installation and maintenance procedures for products that have been tested to be in compliance with appropriate CE directives.About this manual Preface About this manual This manual contains installation notes. Grounding. If the equipment is used in a manner not specified. dimensions. iii . iv .About this manual Cautions are used to describe a procedure that must be followed to prevent equipment malfunction. The CSLS Carrier provides 24 VDC Solver Carriers input to the CSLS and to the Power Modules. Each bank of 12 LS CHARMs is held by a CHARM Baseplate.S. Redundant CSLS can support up to 96 LS Solvers (CSLS) CHARMs.CHARMs Smart Logic Solver hardware specifications 1 CHARMs Smart Logic Solver hardware specifications Topics covered in this chapter: • • CHARMs Smart Logic Solver (CSLS) SIS hardware overview CHARMs Smart Logic Solver specifications • • • • • • • • • • • CHARMs Smart Logic Solver Power Module specifications SZ Controller specifications CHARMs Smart Logic Solver Carrier specifications Safety Network Ports specifications SZ Controller Carrier specifications Ethernet Isolation Ports specifications CHARM Baseplate specifications I. SZ Controllers isolate CSLS from the rest of the system. The maximum number of LS CHARMs (96) are organized in eight banks of 12 CHARMs. CSLS mount on CHARMs Smart Logic Solver Carriers and connect to the Local Safety Network through connectors on the carriers. The CSLS Carrier houses primary 1 . CHARMs CSLS Carriers are DIN rail-mounted carriers that hold simplex or Smart Logic redundant CSLS and Power Modules. SZ Controllers SZ Controllers mount on the SZ Controller Carrier and connect to the Area Control Network and the Local Safety Network through ports on the carrier. The Power Modules provide 6.3 VDC to the LS CHARMs. A Modbus/TCP port on the carrier enables an SZ controller to support standalone SIS installations. SZ controllers receive redundant 24 VDC input through the carrier. CHARM Baseplate specifications Address Plug LS CHARM Column Terminator specifications LS CHARM Column Extenders and cable CHARMs Smart Logic Solver (CSLS) SIS hardware overview CSLS SIS hardware consists of: CHARMs CSLS process LS CHARM signals and run the SIS modules that contain Smart Logic the safety system logic. Ethernet connection through the CSLS Carrier 2 Redundant 10/100BASE-TX ports.S. . thermocouple input. power output. • A physical keylock switch on the CHARMs Smart Logic Solver Carrier along with an unlock software function restricts how and when the CSLS can be unlocked for downloads and upgrades. and voltage LS CHARMs as well as LS Intrinsically Safe analog input and discrete input CHARMs.CHARMs Smart Logic Solver hardware specifications and secondary Safety Network Ports for connections to the Local Safety Network and a keylock switch that restricts how and when the CSLS can be unlocked for downloads and upgrades. The baseplates connect to the CSLS Carrier and to other baseplates through connectors on the baseplates. Each baseplate holds up to 12 terminal blocks that hold LS CHARMs. 575 mA maximum for redundant. CHARM power requirements are additional. • The CSLS connects to the Local Safety Network through redundant Ethernet ports on the CHARMs Smart Logic Solver Carrier. LS DVC HART simplex and redundant DTA. discrete output (including LS DO redundant DTA and LS DO redundant ETA CHARMs). and an Address Plug that determines the address of the baseplate and the CHARMs installed on the baseplate. The DeltaV system supports analog input. SZ Controller Carriers Baseplates SZ Controller Carriers are DIN rail-mounted carriers that hold simplex or redundant SZ Controllers. • The CSLS receives 24 VDC input power from the CHARMs Smart Logic Solver Carrier. discrete input. Baseplates hold LS Intrinsically Safe CHARMs. Logic Solver LS CHARMs are single I/O channels that plug into the LS CHARM Terminal (LS) CHARMs Blocks on the CHARM Baseplate. Specifications Table 1-1: CHARMs Smart Logic Solver specifications Item Specification Input power requirement through the CSLS Carrier 24 VDC ±10% at 325 mA maximum for simplex. The SZ Controller Carrier houses primary and secondary Ethernet Isolation Ports for connections to the DeltaV Area Control Network and to the Local Safety Network. CHARMs Smart Logic Solver specifications Installation notes • Redundant CHARMs Smart Logic Solvers (CSLS) install on the CHARMs Smart Logic Solver Carrier. CHARM Baseplates hold Logic Solver CHARMs (LS CHARMs) and I. 38 in.0 cm (6. Mounting One or two slots on the CSLS Carrier.5 cm (1. Includes: • 13 W for redundant CSLSs (7 W for simplex CSLS) • 3 W for redundant Power Modules • 1 W per Safety Network Port Isolation None. The CSLS is referenced to the incoming 24 VDC return. Front and side view and dimensions Figure 1-1: CHARMs Smart Logic Solver Side View Front View 16.7 cm (5.) 3.) 3 .) 13.38 in.30 in.CHARMs Smart Logic Solver hardware specifications Table 1-1: CHARMs Smart Logic Solver specifications (continued) Item Specification Heat dissipation 18 W maximum for a redundant CSLS node. ) 13.79 in.) Related information CHARMs Smart Logic Solver Carrier specifications CHARMs Smart Logic Solver Power Module specifications Installation notes 4 • The Power Module installs on the CHARMs Smart Logic Solver (CSLS) Carrier. • Two Power Modules can be installed on the CSLS Carrier to provide redundant +6.51 in. .) Power Modules 16.7 cm (5.3 VDC power.9 cm (9. • The Power Module receives +24 VDC from the carrier and generates +6.5 cm (6.3 VDC CHARM power for the CHARMs.CHARMs Smart Logic Solver hardware specifications Figure 1-2: CHARMs Smart Logic Solvers on the carrier Side view Front view CHARMs Smart Logic Solvers 24.39 in. Images Figure 1-3: Power Module Side View Front View 9.5 cm (0.43 in. All outputs are referenced to the incoming 24 VDC return.98 in.CHARMs Smart Logic Solver hardware specifications Specifications Table 1-2: Power Module specifications Item Specification Input power requirement through the CSLS Carrier +24 VDC ±10% at 1.) 11.3 cm (4.5 A maximum simplex and redundant Power to CHARMs bus +6.3V ± 3% at 4 A maximum Heat dissipation 3 W simplex and redundant Isolation None.8 cm (3.) 2.) 5 .87 in. Mounting Adjacent to each CSLS on the CSLS Carrier. ) Related information CHARMs Smart Logic Solver specifications CHARMs Smart Logic Solver Carrier specifications SZ Controller specifications Installation notes 6 • Redundant SZ Controllers install on the SZ Controller Carrier.39 in. • A Modbus/TCP port on the SZ Controller Carrier enables the SZ Controller to support standalone SIS installations.51 in.7 cm (5. .) Power Modules 16.9 cm (9.) 13.5 cm (6. • SZ Controllers receive redundant 24 VDC input power through the SZ Controller Carrier. • SZ Controllers connect to the Area Control Network and to the Local Safety Network through the Ethernet Isolation Ports (primary and secondary) on the SZ Controller Carrier.CHARMs Smart Logic Solver hardware specifications Figure 1-4: Power Modules on the CSLS Carrier Side view Front view CHARMs Smart Logic Solvers 24.79 in. 7 cm (5.) 13.38 in. The SZ controller is referenced to the incoming 24 VDC return.) 3.) 7 .30 in. Mounting One or two slots on the SZ Controller Carrier.5 cm (1.CHARMs Smart Logic Solver hardware specifications Specifications Table 1-3: SZ Controller specifications Item Specification Input power requirement through the SZ Controller Carrier +24 VDC ±10% at 325 mA maximum for simplex. Heat dissipation 7 W simplex.0 cm (6. Ethernet connections through the SZ Controller Carrier Redundant 10/100BASE-TX ports.38 in. 575 mA maximum for redundant. 13 W redundant Isolation None. Images Figure 1-5: SZ Controller Side View Front View 16. To remove a SNP. The SNPs are removable.) 16. • A physical keylock switch on the CHARMs Smart Logic Solver Carrier along with an unlock software function restricts how and when the CSLS can be unlocked for downloads and upgrades.CHARMs Smart Logic Solver hardware specifications Figure 1-6: SZ Controllers on the carrier Side view Front view SZ Controllers 22.) 13.39 in.9 cm (9. • Redundant CHARMs Smart Logic Solvers (CSLS) and redundant Power Modules plug into the slots on the CHARMs Smart Logic Solver Carrier.) Related information SZ Controller Carrier specifications CHARMs Smart Logic Solver Carrier specifications Installation notes 8 • The CHARMs Smart Logic Solver Carrier installs on vertical T-type DIN rails. The CSLS and the Power Modules receive 24 VDC input power through the carrier. depress the button next to the SNP and push it out of the carrier.7 cm (5.3 VDC power for the CHARMs.51 in.02 in. Each port has a port activity LED.5 cm (6. . The Power Modules generate 6. • The CHARMs Smart Logic Solver Carrier houses a primary and secondary Safety Network Port (SNP) for connections to the Local Safety Network. 80 in.) 13.9 cm (9. Input power (redundant) +24 VDC ±10% at 12. Images Figure 1-7: CHARMs Smart Logic Solver Carrier dimensions Side view Front view 24.) 9 .7 cm (5.CHARMs Smart Logic Solver hardware specifications Specifications Table 1-4: CHARMs Smart Logic Solver Carrier specifications Item Specification Capacity One or two redundant CSLS and one or two redundant Power Modules.39 in.3V DC at 4 A maximum Redundant Ethernet connections (primary and secondary) Copper twisted pair: 10/100BASE-TX with RJ45 connectors.6 cm (3. full duplex operation.5 A maximum Output power to SIS CHARMs Baseplates +24 VDC ±10% at 10 A maximum +6.) Connector 8.39 in. • The SNPs are removable.CHARMs Smart Logic Solver hardware specifications Figure 1-8: Front view of the CHARMs Smart Logic Solver Carrier Push to remove port Push to remove port 24 VDC input Primary Safety Network Port Secondary Safety Network Port CHARMs Smart Logic Solver (CSLS) slot CHARMs Smart Logic Solver (CSLS) slot Power module slot.3 VDC to CHARMs Power module slot. Provides 6. depress the button next to the SNP and push it out of the carrier. Provides 6.3 VDC to CHARMs Keylock Switch Front view Related information CHARMs Smart Logic Solver specifications CHARMs Smart Logic Solver Power Module specifications Safety Network Ports specifications Safety Network Port LEDs Safety Network Ports specifications Installation notes 10 • The CHARMs Smart Logic Solver Carrier houses a primary and secondary Safety Network Port (SNP) for connections to the Local Safety Network. . To remove a SNP. full duplex operation.9 cm (0. Unplug the primary and secondary Safety Network Ports from the carrier .41 in. This can be done while the CSLS carrier is under power.28 in.33 cm (3.74 in.) Connector 6.1 cm (2.) 1. Input power provided by the controller +5 VDC at 200 mA maximum Heat dissipation 1W Image Figure 1-9: Safety Network Port Side View Front View Safety Network port LED 8.) Related information CHARMs Smart Logic Solver Carrier specifications Safety Network Port LEDs Reset Safety Network Ports 1.CHARMs Smart Logic Solver hardware specifications Specifications Table 1-5: Safety Network Port specifications Item Specification Redundant Ethernet connections (primary and secondary) Copper twisted pair: 10/100BASE-TX with RJ45 connectors. 11 . 5. Remove both CSLSs from the carrier and install them in the opposite slots: move the CSLS in the right slot to the left slot and the CSLS in the left slot to the right slot. Specifications Table 1-6: SZ Controller Carrier specifications 12 Item Specification Capacity One or two redundant SZ Controllers. full duplex operation. a Safety Network port for connections to the Local Safety Network. • The SZ Controller Carrier houses a primary and secondary Ethernet Isolation Port (EIP). If these connectors are used. 6. wait a minute. Input power (redundant) +24 VDC ±10% at 1 A maximum Battery power for SZ Controllers +5. and port activity LEDs. The active and standby LEDs on the CSLSs should be off. • Screw terminal connections on the carrier allow an external power source to be connected to backup the real-time-clock on the SZ Controllers for power outages greater than 100 hours. the power source must meet the requirements in the following table. • The SZ Controller Carrier provides redundant 24 VDC power for the SZ Controller. The EIPs are removable. 3. 4. and reconnect power. The secondary Area Control Network port also functions as a Modbus/TCP port. Wait one to two minutes for the CSLSs to boot up.CHARMs Smart Logic Solver hardware specifications 2. • Redundant SZ Controllers plug into the slots on the SZ Controller Carrier. SZ Controller Carrier specifications Installation notes • The SZ Controller Carrier installs on vertical T-type DIN rails. Wait one to two minutes for the CSLSs to boot up. Remove power from the CSLS carrier.6 VDC at 30 uA typical Redundant Ethernet connections (primary and secondary) Copper twisted pair: 10/100BASE-TX with RJ45 connectors.0 to +12. Plug the primary and secondary Safety Network Ports back into their original locations. . depress the button next to the EIP and push it out of the carrier. Each EIP consists of an Area Control Network port for connections to the DeltaV Area Control Network. To remove an EIP. ) 6.5 cm (2.9 cm (9.7 cm (5.58 in.01 in.) 13.CHARMs Smart Logic Solver hardware specifications Images Figure 1-10: SZ Controller Carrier dimensions Side view Front view 22.39 in.) 13 . CHARMs Smart Logic Solver hardware specifications Figure 1-11: Front view of the SZ Controller Carrier Primary Area Control Network Port Push to remove port Push to remove port 24 VDC input Secondary Area Control Network Port and Modbus/TCP Port Primary Ethernet Isolation Port Secondary Ethernet Isolation Port Primary Safety Network Port Secondary Safety Network Port Redundant SZ Controller Slots Front view Battery backup Keylock Switch (Reserved for future use) Related information SZ Controller specifications Ethernet Isolation Ports specifications Ethernet Isolation Port LEDs Ethernet Isolation Ports specifications Installation notes • 14 The SZ Controller Carrier houses a primary and secondary Ethernet Isolation Port (EIP). . The secondary Area Control Network port also functions as a Modbus/TCP port. Each EIP consists of an Area Control Network port for connections to the DeltaV Area Control Network and a Safety Network port for connections to the Local Safety Network. 9 cm (0.) Related information SZ Controller Carrier specifications Ethernet Isolation Port LEDs 15 . Input power provided by the CHARMs Smart Logic Solver (CSLS) +5 VDC at 200 mA maximum Heat dissipation 1W Image Figure 1-12: Ethernet Isolation Port Side View Front View Area Control Network port LED Safety Network port 8. To remove an EIP.74 in.) LED Connector 6.1 cm (2.33 cm (3.) 1.28 in. depress the button next to the EIP and push it out of the carrier. Specifications Table 1-7: Ethernet Isolation Port specifications Item Specification Redundant Ethernet connections (primary and secondary) Copper twisted pair: 10/100BASE-TX with RJ45 connectors. full duplex operation.41 in.CHARMs Smart Logic Solver hardware specifications • The EIPs are removable. CHARMs Smart Logic Solver hardware specifications CHARM Baseplate specifications Installation notes • The CHARM Baseplates hold LS CHARMs and install directly onto a vertical T-type DIN rail. CHARM Baseplates connect to the CHARMs Smart Logic Solver Carrier and to other CHARM Baseplates through connectors on the baseplates. • Each CHARM Baseplate holds one Address plug and up to 12 CHARM terminal blocks holding LS CHARMs. • Connect the CHARM Baseplate with Address Plug 1 to the CHARMs Smart Logic Solver Carrier as shown in Figure 1-14. • Install CHARM Baseplates in sequential order under the CHARMs Smart Logic Solver Carrier based on the Address Plug installed on the baseplate. Connect the baseplates together to form the power and communications bus for LS CHARMs. • Up to eight CHARM Baseplates can be installed under one CHARMs Smart Logic Solver Carrier. • Any mix of LS CHARM terminal blocks can be installed on a CHARM Baseplate; however, if CHARM Fused Injected Power Terminal Blocks are installed on a CHARM Baseplate they must all be of the same voltage. Specifications Table 1-8: CHARM Baseplate specifications 16 Item Specification Total CHARM Bus power +6.3 VDC at ±3% at 4 A maximum Total +24 VDC power +24 VDC ± 10% at 10 A maximum Total bussed power 250 VAC maximum at 10 A maximum Bussed power per CHARM slot 250 VAC maximum at 2 A maximum Capacity • 12 CHARMs (maximum) installed in CHARM terminal blocks. • One address plug (1-8) installed in a CHARM address terminal. CHARMs Smart Logic Solver hardware specifications Images Figure 1-13: CHARM Baseplate Side view Front view Connector Address plug 19.5 cm (7.68 in.) L S CHARM terminal blocks Connector 4.7 cm (1.86 in.) Baseplate only 8.3 cm (3.29 in.) 12.5 cm (4.91 in.) Baseplate and terminal blocks 17 CHARMs Smart Logic Solver hardware specifications Figure 1-14: Connected CHARM Baseplates CSLS Carrier CHARM Baseplate 1 Address Plug 1 1 CHARM Baseplate 2 Address Plug 2 NOTE: Up to 8 baseplates can be installed under each CSLS pair. 18 2 S. CHARM Baseplate specifications Item Specification Total +24 VDC power • +24 VDC ± 10% at 7. CHARM Baseplates install directly onto a vertical T-type DIN rail. Specifications Table 1-9: I.S. • Install I.4 A maximum Capacity • 12 LS I.S.S.10% at 8. 19 . CHARM address terminal.S. CHARM Baseplates in sequential order under the CSLS carrier based on the Address Plug installed on the baseplate.S. CHARM Baseplate specifications Installation notes • The I.S. • A Separation Wall must be installed on every I. CHARM Baseplate with Address Plug 1 to the CSLS carrier as shown in Figure 1-16. • Each I. • One address plug (1-8) installed in an I. CHARM Baseplate. CHARMs. CHARM terminal blocks holding LS I. CHARM Baseplates through connectors on the baseplates.S.S. CHARM Baseplate holds one Address plug and up to 12 I.S. I.S. CHARM Baseplates can be installed under one CSLS carrier.6 A maximum • +24 VDC .S.CHARMs Smart Logic Solver hardware specifications I.S. CHARM Baseplates connect to the CSLS carrier and to other I. • Up to eight I. CHARM terminal blocks. • Connect the I. CHARMs (maximum) installed in I.S.S. ) .91 in.CHARM Baseplate Side view Front view Connector Address plug 19.) I.CHARMs Smart Logic Solver hardware specifications Images Figure 1-15: I.7 cm (1.) 20 Baseplate and terminal blocks 12.5 cm (7.S.68 in.5 cm (4.29 in.S. CHARM terminal blocks Connector 4.3 cm (3.86 in.) Baseplate only 8. S.S. CHARM Baseplates CSLS Carrier I. CHARM Baseplate 2 2 Separation Wall Address Plug 2 Connector NOTE: Up to 8 baseplates can be installed under each CSLS pair.CHARMs Smart Logic Solver hardware specifications Figure 1-16: Connected I. CHARM Baseplate 1 1 Separation Wall Address Plug 1 Connector I. DIN Rail 21 .S. Address Plug 3 on the third baseplate.2 cm (0.89 in.79cm (1.CHARMs Smart Logic Solver hardware specifications Address Plug Installation notes • The Address Plug (1-8) installs in the LS CHARM Address Terminal in the dedicated slot on the CHARM Baseplate.) 4. Address Plug 2 on the second baseplate.8 cm (1.88 in.48 in.3 VDC ±3% at 2 mA maximum Views and dimensions Figure 1-17: Address Plug Front view 1.) Side view 4. and so on.) Related information LS CHARM Address Terminal specifications 22 Bottom view . Specifications Table 1-10: Address Plug specifications Item Specification Input power +6. • Install Address Plug 1 on the first baseplate. 91 in.) Front view Connector 4.CHARMs Smart Logic Solver hardware specifications LS CHARM Column Terminator specifications Installation notes The LS CHARM Column Terminator terminates the redundant bus and provides terminals for connecting the baseplates to shield ground.5 cm (1. Specifications Table 1-11: LS CHARM Column Terminator specifications Item Specifications Number of connections 2 (shield drain wire) Front and side views and dimensions Figure 1-18: LS CHARM Column Terminator Side view 3. For example.86 in. • The top column extender can be connected to baseplates only. Refer to the second image in this topic.) 12. • Three cable lengths are available for use with the extenders: 23 . if the CSLS carrier only is installed on a DIN rail and the baseplates are installed on another DIN rail. • To connect the cables between the extenders.) LS CHARM Column Extenders and cable Installation notes • The LS CHARM Column Extenders are used to extend the power and communications busses when CHARM Baseplates in a 96 CHARM system are installed on multiple DIN rails. the bottom column extender would be connected to the CSLS carrier and either another bottom extender or top extender could be connected to a baseplate on the other DIN rail.39 in. Install it after the last CHARM Baseplate on the DIN rail. • The bottom column extender can be connected to a CHARMs Smart Logic Solver (CSLS) Carrier or to a baseplate depending upon the physical location of the carrier and the baseplate.5 cm (4. connect primary to primary and secondary to secondary.7 cm (1. 64 feet).CHARMs Smart Logic Solver hardware specifications • - 0.) Front view A B 12.72 cm 1.48 cm 4.) .0 meters (3.28 feet) - 2.64 feet) - 1.91 (in.91 (in.12 (in.) Carrier connector 2.5 meters (1.0 meters (6.56 feet) A maximum of four extender pairs can be used and only one extender pair can exceed 0.) Removal screw Carrier connector Removal screw 3.) 24 Top view 4.5 meters (1.85 (in.48 cm 4.87 cm 1.3 VDC ± 3% at 4 A maximum Total +24 VDC power +24 VDC ± 10% at 10 A maximum Dimensions and connectors Figure 1-19: LS CHARM Column Extenders Bottom CHARM Extender Top CHARM Extender 4.38 (in. Specifications Table 1-12: LS CHARM Column Extenders Item Specification Total CHARM Bus power +6.85 (in.51 cm 1.72 cm 1.) A B 12. CHARMs Smart Logic Solver hardware specifications Example installations using LS CHARM Column Extenders Example 1 CSLS Carrier Example 2 Example 3 Address Plug 1 Top CHARM Column Extender CHARM Baseplate 1 Address Plug 1 Address Plug 2 CHARM Baseplate 2 Bottom CHARM Column Extenders CSLS Carrier Bottom CHARM Column Extender CSLS Carrier CHARM Baseplate 1 Address Plug 2 Address Plug 1 Address Plug 3 CHARM Baseplate 1 CHARM Baseplate 3 Address Plug 2 Address Plug 4 CHARM Baseplate 2 CHARM Baseplate 4 CHARM Baseplate 2 1 Bottom CHARM Column Extenders 25 . CHARMs Smart Logic Solver hardware specifications 26 . CHARM Thermocouple / mV Terminal Block specifications DVC Terminal Block specifications LS CHARM Address Terminal specifications Redundant Terminal Block specifications Redundant DTA Injected Power Relay Terminal Block specifications Redundant DTA Relay Terminal Block specifications Redundant ETA Relay Terminal Block specifications Redundant DVC Terminal Block specifications CHARM Terminal Block specifications Installation notes • The CHARM Terminal Blocks are preinstalled on the CHARM Baseplate.S. remove the CHARM Terminal Block from the CHARM Baseplate. When the posts are in the neutral position. You will hear a click when the posts are completely pushed in. • The CHARM Terminal Block's keying mechanism sets itself to match the inserted LS CHARM. flip the terminal block 180°.Logic Solver CHARMs Terminal Block specifications 2 Logic Solver CHARMs Terminal Block specifications Topics covered in this chapter: • • CHARM Terminal Block specifications CHARM Fused Injected Power Terminal Block specifications • • • • • • • • • • CHARM Thermocouple / mV Terminal Block specifications I. • The following LS CHARMs can use the CHARM Terminal Block: - LS AI 0-10 VDC Isolated - LS AI 4-20 mA HART - LS DI 24 VDC Isolated - LS DI 120 VAC Isolated - LS DI 230 VAC Isolated - LS DI 24 VDC Low-Side 27 .S. and use your fingers to push the two keying posts completely in and return the posts to the neutral position. Each terminal block holds a single Logic Solver (LS) CHARM and provides the keying and field wiring for the LS CHARM. CHARM Terminal Block specifications I. • To reset the keying mechanism. the terminal block can receive a different LS CHARM type. 03 in.) 10.2 cm (4.3 cm (2.) Related information LS AI 4-20 mA HART CHARM specifications LS DI 24 VDC low-side (dry contact) CHARM specifications LS DI 24 VDC isolated CHARM specifications LS DI 120 VAC isolated CHARM specifications LS DI 230 VAC isolated CHARM specifications LS RTD / Resistance input CHARM specifications LS AI 0-10 VDC isolated CHARM specifications 28 Bottom view Terminal 2 Terminal 1 Terminal 4 Terminal 3 .09 in.) 3 4 Side view 5.48 in.Logic Solver CHARMs Terminal Block specifications - LS DI NAMUR - LS RTD / Resistance Input - LS DO 24 VDC DTA - LS DO 24 VDC ETA Specifications Table 2-1: CHARM Terminal Block specifications Item Specification Number of connections 4 Power rating 250 VAC maximum at 2 A maximum Front and side views and dimensions Figure 2-1: CHARM Terminal Block Front view 1 2 1.2 cm (0. the terminal block can receive a different CHARM type. • The fuse cannot be replaced when the terminal block is under power.Logic Solver CHARMs Terminal Block specifications LS DO 24 VDC CHARMs specifications LS DI NAMUR CHARM specifications CHARM Fused Injected Power Terminal Block specifications Installation notes • The CHARM Fused Injected Power Terminal Block installs on the CHARM Baseplate and holds a single Logic Solver (LS) CHARM. You will hear a click when the posts are completely pushed in. • The following LS CHARMs can use the CHARM Fused Injected Power Terminal Block: - LS DI 24 VDC Isolated CHARM - LS DI 120 VAC Isolated CHARM - LS DI 230 VAC Isolated CHARM - LS 24 VDC Power CHARM Specifications Table 2-2: CHARM Fused Injected Power Terminal Block specifications Item Specification Number of connections 2 Power rating 250 VAC maximum at 1 A maximum 29 . It provides the keying and field wiring for the LS CHARM and bussed power connections to implement high-side outputs and dry contact inputs for isolated Discrete CHARMs. flip the terminal block 180°. remove the CHARM Fused Injected Power Terminal Block from the CHARM Baseplate. • To reset the keying mechanism. When the posts are in the neutral position. • The terminal block's fuse protects the field wiring from short circuits. • The CHARM Fused Injected Power Terminal Block's keying mechanism sets itself to match the inserted CHARM. and use your fingers to push the two keying posts completely in and return the posts to the neutral position. Bussed power is wired to the CHARM Address Terminal. Logic Solver CHARMs Terminal Block specifications Front and side views and dimensions Figure 2-2: CHARM Fused Injected Power Terminal Block Front view 1.2 cm (0.48 in.) 2 4 Fuse Bottom view Side view Terminal 2 5.3 cm (2.09 in.) Terminal 4 10.2 cm (4.03 in.) Related information LS DI 24 VDC isolated CHARM specifications LS DI 120 VAC isolated CHARM specifications LS DI 230 VAC isolated CHARM specifications LS 24 VDC Power CHARM specifications CHARM Thermocouple / mV Terminal Block specifications Installation notes • The CHARM Thermocouple / mV Terminal Block installs on the CHARM Baseplate and holds a single LS CHARM. It provides the field wiring for the LS CHARM. • The CHARM Thermocouple / mV Terminal Block's keying is fixed to allow only the LS Thermocouple / mV input CHARM. Specifications Table 2-3: CHARM Thermocouple / mV Terminal Block specifications 30 Item Specification Number of connections 2 Logic Solver CHARMs Terminal Block specifications Table 2-3: CHARM Thermocouple / mV Terminal Block specifications (continued) Item Specification Power rating 5 VDC maximum at 25 mA maximum Front and side views and dimensions Figure 2-3: CHARM Thermocouple / mV Terminal Block Front view 1.2 cm (0.40 in.) Side view Bottom view Terminal 2 Terminal 1 5.3 cm (2.09 in.) 10.2 cm (4.03 in.) I.S. CHARM Terminal Block specifications Installation notes • The I.S. CHARM Terminal Blocks are preinstalled on the I.S. CHARM Baseplate. Each terminal block holds a single I.S. CHARM and provides the keying and field wiring for the I.S. CHARM. • The I.S. CHARM Terminal Block's keying mechanism sets itself to match the inserted I.S. CHARM. • To reset the keying mechanism, remove the I.S. CHARM Terminal Block from the I.S. CHARM Baseplate, flip the terminal block 180°, and use your fingers to push the two keying posts completely in and return the posts to the neutral position. You will hear a click when the posts are completely pushed in. When the posts are in the neutral position, the terminal block can receive a different I.S. CHARM type. • All I.S. CHARM types including the Logic Solver I.S. CHARMs can use the I.S. CHARM Terminal Block. 31 Logic Solver CHARMs Terminal Block specifications Specifications Table 2-4: I.S. CHARM Terminal Block specifications Item Specification Number of connections 4 Power rating 28 VDC maximum at 45 mA Front and side views and dimensions Figure 2-4: I.S. CHARM Terminal Block Front view 1 2 1.2 cm (0.48 in.) 3 4 Side view 5.3 cm (2.09 in.) Bottom view Terminal 2 Terminal 1 Terminal 4 Terminal 3 10.2 cm (4.03 in.) Related information LS AI 4-20 mA HART (Intrinsically Safe) CHARM specifications LS DI NAMUR (Intrinsically Safe) CHARM specifications I.S. CHARM Thermocouple / mV Terminal Block specifications Installation notes • 32 The I.S. CHARM Thermocouple / mV Terminal Blocks holds a single I.S. Thermocouple / mV input CHARM and provides the keying and field wiring for the I.S. CHARM. S. CHARM Thermocouple / mV Terminal Block specifications Item Specification Number of connections 2 Power rating 45 mA maximum at 28 VDC Front and side views and dimensions Figure 2-5: I.S.Logic Solver CHARMs Terminal Block specifications • The terminal block's keying mechanism is fixed to allow only an I. CHARM Thermocouple / mV Terminal Block Front view 1.3 cm (2.) DVC Terminal Block specifications Installation notes • The DVC Terminal Block holds a single LS DVC HART DTA CHARM and provides the keying and field wiring connections for the CHARM.40 in.2 cm (4. Specifications Table 2-5: I. Thermocouple / mV input CHARM.2 cm (0.) 4 Side view 5.) Bottom view Terminal 4 Terminal 3 10. 33 .09 in.S.03 in. • The terminal block's keying mechanism is fixed to allow only a LS DVC HART DTA CHARM. ) Side view Bottom view Terminal 1 5.) Terminal 2 10.48 in.03 in.3 cm (2. .) Related information LS DVC HART DTA CHARMs specifications LS CHARM Address Terminal specifications Installation notes 34 • The LS CHARM Address Terminal is preinstalled in the dedicated slot on the CHARM Baseplate and holds one Address Plug (1-8).2 cm (0.09 in.2 cm (4. • The LS CHARM Address Terminal's keying mechanism sets itself to match the inserted Address Plug (1-8).Logic Solver CHARMs Terminal Block specifications Specifications Table 2-6: DVC Terminal Block specifications Item Specification Number of connections 2 Power rating 30 VDC maximum at 30 mA maximum Front and side views and dimensions Figure 2-6: DVC Terminal Block Front view 1. 09 in.Logic Solver CHARMs Terminal Block specifications • To reset the keying mechanism.2 cm (0.03 in. and reset the keying mechanism. Specifications Table 2-7: LS CHARM Address Terminal specifications Item Specification Number of connections 2 sets of 2 connections Power rating 250 VAC maximum at 10 A maximum Front and side views and dimensions Figure 2-7: LS CHARM Address Terminal Front view 1.) Side view 5.2 cm (4.48 in.) Redundant Terminal Block specifications Installation notes • Each Redundant Terminal Block holds two LS DO 24 VDC (Redundant ETA) or LS DO 24 VDC (Redundant DTA) CHARMs. It provides the keying and field wiring connections for the CHARMs. remove the Address Terminal. • Four screw terminals on the LS CHARM Address Terminal provide field power to isolated LS CHARMs installed in CHARM Fused Injected Power Terminal Blocks.) Bottom view Terminal - Terminal + 10.3 cm (2. remove the Address Plug (1-8) from the CHARM Baseplate. 35 . ) Side view Bottom view Terminal 1 5.) Related information LS DO 24 VDC CHARMs specifications 36 .5 cm (0.98 in. Specifications Table 2-8: Redundant Terminal Block specifications Item Specifications Number of connections 2 Power rating 250 VAC maximum at 2 A maximum Front and side views and dimensions Figure 2-8: Redundant Terminal Block Front view 2.) Terminal 2 10.09 in.3 cm (2. • Install the terminal block in an odd and even numbered slot on the baseplate.2 cm (4.03 in.Logic Solver CHARMs Terminal Block specifications • Both CHARMs installed in the terminal block must be of the same type: either two LS DO 24 VDC (Redundant DTA) CHARMs or two LS DO 24 VDC (Redundant ETA) CHARMs • The Redundant Terminal Block's keying mechanism sets itself to match the inserted CHARMs. slots 1 and 2 or slots 3 and 4). The lower slot number must be odd and the even slot number must be the next higher number (for example. slots 1 and 2 or slots 3 and 4). place probes between the positive (+) address terminal and the test point. • The Redundant DTA Relay Injected Power Terminal Block has a built-in relay. • The Redundant DTA Relay Injected Power Terminal Block has a replaceable fuse that protects the field wiring from short circuits. Specifications Table 2-9: Redundant DTA Injected Power Relay Terminal Block specifications Item Specification Number of connections 2 Power rating 250 VAC maximum at 1 A maximum Number of test points 1 37 .Logic Solver CHARMs Terminal Block specifications Redundant DTA Injected Power Relay Terminal Block specifications Installation notes • Each Redundant DTA Injected Power Relay Terminal Block holds two LS DO 24 VDC (Redundant DTA) CHARMs. place probes between screw terminal 1 and the test point. • The test point is used to verify each contact individually. • Install the terminal block in an odd and even numbered slot on the baseplate. It provides the keying and field wiring connections for the CHARMs and bussed power connections to implement high-side outputs. To verify one relay. • The Redundant DTA Injected Power Relay Terminal Block's keying is fixed to allow only LS DO 24 VDC (Redundant DTA) CHARMs. The fuse cannot be replaced when the terminal block is under power in a hazardous environment. The lower slot number must be odd and the even slot number must be the next higher number (for example. • This terminal block is used by a LS DO 24 VDC (Redundant DTA) CHARM when driving a final element that requires more than 500 mA and the baseplate's injected power bus rather than system power is required to power the field circuit. Bussed power is wired to the CHARM Address Terminal. To verify the other relay. 09 in.5 cm (0.3 cm (2.98 in.03 in.) Terminal 2 10.2 cm (4. Baseplate Terminal 1 Injected Power – + T 2 Related information LS DO 24 VDC CHARMs specifications LS CHARM Address Terminal specifications 38 .) The following image shows the relay circuit.) Test point Side view Bottom view Terminal 1 5.Logic Solver CHARMs Terminal Block specifications Front and side views and dimensions Figure 2-9: Redundant DTA Injected Power Relay Terminal Block Front view 2. The fuse cannot be replaced when the terminal block is under power in a hazardous environment. place probes between screw terminal 2 and the test point. It provides the keying and field wiring connections for the CHARMs. The lower slot number must be odd and the even slot number must be the next higher number (for example. Specifications Table 2-10: Redundant DTA Relay Terminal Block specifications Item Specification Number of connections 2 Power rating 250 VAC maximum at 1 A maximum Number of test points 1 39 . • The Redundant DTA Relay Terminal Block's keying is fixed to allow only LS DO 24 VDC (Redundant DTA) CHARMs. • The Redundant DTA Relay Terminal Block has a replaceable fuse that protects the field wiring from short circuits. • This terminal block is used by a LS DO 24 VDC (Redundant DTA) CHARM when driving a final element that requires more than 500 mA. • Install the terminal block in an odd and even numbered slot on the baseplate. • The Redundant DTA Relay Terminal Block has a built-in relay. • Both CHARMs installed in the terminal block must be of the same type. slots 1 and 2 or slots 3 and 4). To verify the other relay.Logic Solver CHARMs Terminal Block specifications Redundant DTA Relay Terminal Block specifications Installation notes • Each Redundant DTA Relay Terminal Block holds two LS DO 24 VDC (Redundant DTA) CHARMs. • The test point is used to verify each contact individually. place probes between screw terminal 1 and the test point. To verify one relay. The fuse cannot be replaced when the terminal block is under power in a hazardous environment.98 in.5 cm (0.) 2 T Terminal 2 1 10.09 in.) Test point Side view Bottom view Terminal 1 5. • The Redundant ETA Relay Terminal Block has a built-in relay. • The Redundant ETA Relay Terminal Block has a replaceable fuse that protects the field wiring from short circuits.03 in.Logic Solver CHARMs Terminal Block specifications Front and side views and dimensions Figure 2-10: Redundant DTA Relay Terminal Block Front view 2.) Related information LS DO 24 VDC CHARMs specifications Redundant ETA Relay Terminal Block specifications Installation notes 40 • Each Redundant ETA Relay Terminal Block holds two LS DO 24 VDC (Redundant ETA) CHARMs. .2 cm (4. • The Redundant ETA Relay Terminal Block's keying is fixed to allow only LS DO 24 VDC (Redundant ETA) CHARMs. It provides the keying and field wiring connections for the CHARMs.3 cm (2. 09 in.03 in. slots 1 and 2 or slots 3 and 4).) Side view Bottom view Terminal 1 5.Logic Solver CHARMs Terminal Block specifications • Install the terminal block in an odd and even numbered slot on the baseplate.) 2 Terminal 2 1 10.3 cm (2.5 cm (0.2 cm (4.98 in. Specifications Table 2-11: Redundant ETA Relay Terminal Block specifications Item Specification Number of connections 2 Power rating 250 VAC maximum at 1 A maximum Front and side views and dimensions Figure 2-11: Redundant ETA Relay Terminal Block Front view 2. The lower slot number must be odd and the even slot number must be the next higher number (for example.) Related information LS DO 24 VDC CHARMs specifications 41 . 03 in.3 cm (2.) Terminal 2 10.Logic Solver CHARMs Terminal Block specifications Redundant DVC Terminal Block specifications Installation notes • Each Redundant DVC Terminal Block holds two LS DVC HART (Redundant DTA) CHARMs.5 cm (0. The lower slot number must be odd and the even slot number must be the next higher number (for example. Specifications Table 2-12: Redundant DVC Terminal Block specifications Item Specifications Number of connections 2 Power rating 30 VDC maximum at 60 mA maximum Front and side views and dimensions Figure 2-12: Redundant DVC Terminal Block Front view 2. It provides the keying and field wiring connections for the CHARMs.2 cm (4. • Install the terminal block in an odd and even numbered slot on the baseplate.09 in.) Side view Bottom view Terminal 1 5.98 in. • The Redundant DVC Terminal Block's keying is fixed to allow only LS DVC HART (Redundant DTA) CHARMs.) 42 . slots 1 and 2 or slots 3 and 4). Logic Solver CHARMs Terminal Block specifications Related information LS DVC HART DTA CHARMs specifications 43 . Logic Solver CHARMs Terminal Block specifications 44 . If an open loop condition exists. Input impedance 10 MΩ Repeatability 0. Specifications Table 3-1: LS AI 0-10 VDC isolated CHARM specifications Item Specification Sensor types Voltage devices: • • • • • • 0 to 5 V 0 to 10 V 1 to 5 V -1 to +1 V -5 to +5 V -10 to +10 V Note Open loop conditions are not detected for voltage LS CHARMs. the Status parameter in DeltaV Diagnostics reports a value of Sensor Out of Range. Accuracy over full temperature range Refer to the following table. • Installing a 250 Ω resistor across terminals 3 and 4 converts a 4-20 mA field signal to a 1-5 VDC input signal.Logic Solver CHARMs specifications 3 Logic Solver CHARMs specifications Topics covered in this chapter: • • • LS input CHARMs specifications LS Intrinsically Safe input CHARMs specifications LS Output CHARMs specifications LS input CHARMs specifications LS AI 0-10 VDC isolated CHARM specifications Installation notes • The LS AI 0-10 VDC isolated CHARM requires a CHARM Terminal Block.05% of span Resolution Refer to the following table (24 bit A/D converter used) Calibration None required 45 . 00008 V 0 to 10 V ±0.00015 V -10 to + 10 V ±0.0002 V/°C 0.00003 V -5 to +5 V ±0.00006 V -1 to +1 V ±0.Logic Solver CHARMs specifications Table 3-1: LS AI 0-10 VDC isolated CHARM specifications (continued) Item Specification Common mode rejection 90 dB at 50/60 Hz Isolation Input channel galvanically isolated and factory tested to 1000 VDC Input power requirements Total power requirement: 22 mA maximum • Input power from CSLS Power Modules: +6.3 VDC ±3% at 32 mA maximum • 24 VDC input power: +24 VDC ± 10% at 10 mA maximum CHARM heat dissipation 0.010 V ±0.00030 V Wiring diagram Figure 3-1: LS AI 0-10 VDC isolated CHARM wiring diagram CHARM CHARM Baseplate CHARM Terminal Block 2 Shield 46 3 + A/D Conversion Isolation 1 4 – Voltage Source .0005 V/°C 0.005 V ±0.0005 V/°C 0.005 V ±0.005 V ±0.001 V/°C 0.001 V/°C 0.40 W Table 3-2: Isolated input voltage sensor type specifications Sensor type 25° reference accuracy Temperature drift Nominal resolution 0 to 5 V ±0.0025 V ±0.00015 V 1 to 5 V ±0.010 V ±0.0005 V/°C 0. 0 V minimum at 20 mA with 24 VDC input power.25% of span (-40-70° C) Repeatability 0. Accuracy over temperature range • 0.3 VDC ±3% at 32 mA maximum • +24 VDC input power: +24 VDC ±10% at 25 mA maximum CHARM heat dissipation 0. • This CHARM supports 2 and 4-wire devices.33 W HART scan time 500 ms HART Communications • HART pass-through request/response • HART variable report • Field device status report 47 . Specifications Table 3-3: LS AI 4-20 mA HART CHARM specifications Item Specification Channel type and functionality Analog input: • 4-20 mA • 0-20 mA • 4-20 mA with HART Nominal signal range (span) • 4-20 mA • 0-20 mA optional Full signal range 0-24 mA Input impedance 250 Ω ±1% 2-wire transmitter power 15.05% of span Resolution 16-bit Calibration None required Input power requirements Total power requirement: +24 VDC ±10% at 36 mA maximum for 2-wire configurations and 12 mA maximum for 4-wire configurations: • Input power from CSLS Power Modules: +6.1% of span (0 to 60° C) • 0.Logic Solver CHARMs specifications Related information CHARM Terminal Block specifications LS AI 4-20 mA HART CHARM specifications Installation notes • The LS AI 4-20 mA HART CHARM requires the CHARM Terminal Block. the input channel can be used as a dry contact input channel. . • When a CHARM Fused Injected Power Terminal Block is used.Logic Solver CHARMs specifications Wiring diagrams Figure 3-2: LS AI 4-20 mA HART CHARM wiring diagram for 2-wire applications CHARM Baseplate CHARM +24V CHARM Terminal Block 1 Current Limiting Circuitry + 2 A/D Conversion and HART Interface 3 4 – T 2-wire analog and/or HART transmitter 250 Ω Shield Figure 3-3: LS AI 4-20 mA HART CHARM wiring diagram for 4-wire applications CHARM Baseplate CHARM +24V CHARM Terminal Block 1 Current Limiting Circuitry + 2 A/D Conversion and HART Interface 3 4 – T 4-wire analog and/or HART self-powered transmitter 250 Ω Shield Related information CHARM Terminal Block specifications LS DI 24 VDC isolated CHARM specifications Installation notes 48 • When a CHARM Terminal Block is used. the input channel can be used as a conventional isolated input channel. Logic Solver CHARMs specifications Specifications Table 3-4: LS DI 24 VDC isolated CHARM specifications Item Specification Channel type Discrete input: isolated VDC Detection level for ON >10 VDC Detection level for OFF < 5 VDC Wetting current 6 mA at +24 VDC Output impedance 4 kΩ (approximate) Channel isolation Input is optically isolated and factory tested to 1000 VDC. Input power requirements Total power requirement: +24 VDC ±10% at 12 mA maximum : • Input power from CSLS Power Modules: +6.32 W Wiring diagrams Figure 3-4: LS DI 24 VDC isolated CHARM wiring diagram CHARM Baseplate CHARM CHARM Terminal Block 1 3 2 KΩ Isolation and Control Circuitry + – Field Devices 2 KΩ 2 4 49 24 VDC Power Supply .3 VDC ±3% at 32 mA maximum • +24 VDC input power: none CHARM heat dissipation 0. the input channel can be used as a dry contact input channel. Specifications Table 3-5: LS DI 120 VAC isolated CHARM specifications 50 Item Specification Channel type Discrete input: isolated 120 VAC Detection level for On >84 VAC Detection level for Off <34 VAC Wetting current 2 mA at 120 VAC Output impedance 60 kΩ (approximate) Channel isolation Input channel is optically isolated from the system at 250 VAC . • When a CHARM Fused Injected Power Terminal Block is used. • Although CHARMs can be installed in any location.Logic Solver CHARMs specifications Figure 3-5: LS DI 24 VDC isolated CHARM wiring diagram for dry contact configuration with CHARM Fused Injected Power Terminal Block CHARM Baseplate CHARM + – Charm Fused Injected Power Terminal Block 2 KΩ Isolation and Control Circuitry 2A 2 KΩ 2 + 4 – Related information CHARM Terminal Block specifications CHARM Fused Injected Power Terminal Block specifications LS DI 120 VAC isolated CHARM specifications Installation notes • When a CHARM Terminal Block is used. To ensure a safe working environment. it is recommended that you wire AC signals to a different enclosure from DC signals. it is good engineering practice to separate low voltage DC signals from high voltage AC signals. the input channel can be used as a conventional isolated input channel. Logic Solver CHARMs specifications Table 3-5: LS DI 120 VAC isolated CHARM specifications (continued) Item Specification Frequency 50 / 60 Hz Maximum input voltage 130 VAC Input power requirements Total power requirement: +24 VDC ±10% at 12 mA maximum : • Input power from CSLS Power Modules: +6.41 W Wiring diagrams Figure 3-6: LS DI 120 VAC isolated CHARM wiring diagram CHARM Baseplate CHARM CHARM Terminal Block 1 3 30 KΩ L Isolation and Control Circuitry Field Devices 2 4 N 30 KΩ Figure 3-7: LS DI 120 VAC isolated CHARM wiring diagram for dry contact configuration with CHARM Fused Injected Power Terminal Block CHARM Baseplate CHARM L + N – Charm Fused Injected Power Terminal Block 30 KΩ 2A Isolation and Control Circuitry L 2 4 N 30 KΩ 51 120 VAC Power Supply .3 VDC ±3% at 32 mA maximum • +24 VDC input power: none CHARM heat dissipation 0. • When a CHARM Fused Injected Power Terminal Block is used. To ensure a safe working environment. the input channel can be used as a dry contact input channel. Frequency 50 / 60 Hz Maximum input voltage 250 VAC Input power requirements Total power requirement: +24 VDC ±10% at 12 mA maximum : • Input power from CSLS Power Modules: +6. the input channel can be used as a conventional isolated input channel. it is recommended that you wire AC signals to a different enclosure from DC signals.40 W . it is good engineering practice to separate low voltage DC signals from high voltage AC signals. Specifications Table 3-6: LS DI 230 VAC isolated CHARM specifications 52 Item Specification Channel type Discrete input: isolated 230 VAC Detection level for On >168 VAC Detection level for Off <68 VAC Wetting current 1 mA at 230 VAC Input impedance 240 kΩ (approximate) Channel isolation Input channel is optically isolated from the system at 250 VAC. • Although CHARMs can be installed in any location.Logic Solver CHARMs specifications Related information CHARM Terminal Block specifications CHARM Fused Injected Power Terminal Block specifications LS DI 230 VAC isolated CHARM specifications Installation notes • When a CHARM Terminal Block is used.3 VDC ±3% at 32 mA maximum • +24 VDC input power: none CHARM heat dissipation 0. 53 230 VAC Power Supply . • Debounce filters can be configured for this CHARM in DeltaV Explorer.Logic Solver CHARMs specifications Wiring diagrams Figure 3-8: LS DI 230 VAC isolated CHARM wiring diagram CHARM Baseplate CHARM CHARM Terminal Block 1 3 120 KΩ L Isolation and Control Circuitry Field Devices 2 4 N 120 KΩ Figure 3-9: LS DI 230 VAC isolated CHARM wiring diagram for dry contact configuration with CHARM Fused Injected Power Terminal Block CHARM Baseplate CHARM L + N – Charm Fused Injected Power Terminal Block 120 KΩ 2A Isolation and Control Circuitry L 2 4 N 120 KΩ Related information CHARM Terminal Block specifications CHARM Fused Injected Power Terminal Block specifications LS DI 24 VDC low-side (dry contact) CHARM specifications Installation notes • The LS DI 24 VDC low-side (dry contact) CHARM requires a CHARM Terminal Block. Figure 3-10: External line fault resistors + 2.3 kΩ (>2.Logic Solver CHARMs specifications • This CHARM can sense relay/switch contact closure and supports line fault detection for detecting open or short circuits in field wiring when external line fault resistors are used.2 kΩ (<1. To use line fault detection you must: - Enable line fault detection in the configuration.25 mA at 24 VDC) Detection level for Off >8.(minus) signal 54 Detection level for On <5.4 KΩ 12 KΩ Specifications Table 3-7: LS DI 24 VDC low-side (dry contact) CHARM specifications Item Specification Channel type Discrete input: +24 VDC dry contact On/Off detection on the .75 mA at 24 VDC) Channel impedance 4.5 VDC (±5%).4 kΩ resistor in series for short circuit detection.3 VDC ±3% at 32 mA maximum • +24 VDC input power: +24 VDC ±10% at 10 mA maximum CHARM heat dissipation 0. - Connect the dry contact to a 12 kΩ resistor in parallel for open circuit detection and a 2.5 mA nominal Open line fault detection levels • Guaranteed short circuit: < 100 Ω • Guaranteed good status: 400 Ω to 40 kΩ • Guaranteed open circuit: 75 kΩ Input power requirements Total power requirement: +24 VDC ±10% at 22 mA maximum : • Input power from CSLS Power Modules: +6.33 W .8 kΩ Wetting voltage 22. current limited to 12. 4 kΩ resistor in series for short circuit detection.Logic Solver CHARMs specifications Wiring diagram Figure 3-11: LS DI 24 VDC low-side (dry contact) CHARM wiring diagram CHARM Baseplate CHARM +24 VDC 1 Current Limiting Circuitry Channel Sensing Circuitry CHARM Terminal Block 3 + 2 4 Field device – + 4. - Connect the dry contact to a 12 kΩ resistor in parallel for open circuit detection and a 2. 55 . • The LS DI NAMUR CHARM can sense relay/switch contact closure and supports NAMUR sensors with NAMUR-specified line fault detection levels. To use line fault detection you must: - Enable line fault detection in the configuration. • Debounce filters can be configured for this CHARM in DeltaV Explorer.8 kΩ 2.4 KΩ 1 12 KΩ 2 – Field device Option 1 Related information CHARM Terminal Block specifications LS DI NAMUR CHARM specifications Installation notes • The LS DI NAMUR CHARM requires a CHARM Terminal Block. • LS DI NAMUR CHARM supports line fault detection for detecting open or short circuits in field wiring when external line fault resistors are used. Logic Solver CHARMs specifications Figure 3-12: External line fault detection resistors + 2.2 mA >9 kΩ Channel impedance 1.51 W .4 KΩ 12 KΩ Specifications Table 3-8: LS DI NAMUR CHARM specifications Item Specification Channel type Discrete input: 12 VDC.5 kΩ Wetting voltage 12 VDC (±5%) Optional line fault detection levels • Guaranteed short circuit: <100 Ω • Guaranteed good status: 400 Ω to 40 kΩ • Guaranteed open circuit: > 75 kΩ NAMUR sensor compatible Input power requirements Total power requirement: +24 VDC ±10% at 28 mA maximum : • Input power from CSLS Power Modules: +6. dry contact.3 VDC ±3% at 32 mA maximum • +24 VDC input power: +24 VDC ±10% at 16 mA maximum CHARM heat dissipation 0. supports NAMUR sensors On/Off detection on the + signal 56 Detection level for On >2.1 mA <4 kΩ Detection level for Off <1. Refer to Table 3-10 Accuracy over full temperature range Depends upon the sensor type. • This CHARM can be configured for 2.4 KΩ 1 12 KΩ 2 – Field device Option 2 Related information CHARM Terminal Block specifications LS RTD / Resistance input CHARM specifications Installation notes • The LS RTD / Resistance input CHARM requires a CHARM Terminal Block. or 4-wire Full scale signal range Selectable based on sensor. 3.5 KΩ 1 1 Field device 2 3 – Option 1 + Namur Sensor 2 4 – + 2. or 4-wire applications.Logic Solver CHARMs specifications Wiring diagram Figure 3-13: LS DI NAMUR CHARM wiring diagram + CHARM Baseplate CHARM Channel Sensing Circuitry CHARM Terminal Block 12 V 1. Refer to the temperature drift specification in Table 3-10 Repeatability 0. Specifications Table 3-9: LS RTD Input CHARM specifications Item Specification Channel type RTD input Sensor types Refer to Table 3-10 Sensor configuration 2.05% of span Resolution Depends upon the sensor type. 3. Refer to the resolution specification in Table 3-10 Calibration None required 57 . 25° C ±0.01° C Resistance RTD input 0 to 2.30 W Table 3-10: LS RTD sensor type specifications Sensor type Operating range 25° reference accura.02° C/°C ~0.25° C ±0.Temperature drift cy Resolution Pt100 -200 to 850° C ±0.02° C Pt1000 -200 to 260° C ±0.01° C/°C ~0.02° C/°C ~0.01° C Ni200 -80 to 260 °C ±0.02° C Pt500 -200 to 850° C ±0.01° C/°C ~0.25° C ±0.5 mA in 2 and 4-wire configurations • 0.01° C Ni500 -80 to 260 °C ±0.02° C/°C ~0.3 VDC ±3% at 32 mA maximum • +24 VDC input power: ±10% at 10 mA maximum CHARM heat dissipation 0.02° C/°C ~0.000 Ω ±0.15° C ±0.01° C/°C ~0.25° C ±0.01° C Ni100 -80 to 260 °C ±0.01° C Ni1000 -80 to 140 °C ±0.01° C Ni120 -80 to 260 °C ±0.01° C/°C ~0.25 mA in 3-wire configurations DC50/60 Hz common mode rejection 90 dB typical Channel isolation RTD sensor input is galvanically isolated and factory tested to 1000 VDC.01° C/°C ~0.25 Ω ±0.20° C ±0.02° C Pt200 -200 to 850° C ±0.20° C ±0.20° C ±0.25° C ±0.02° C/°C ~0.Logic Solver CHARMs specifications Table 3-9: LS RTD Input CHARM specifications (continued) Item Specification Sensor excitation current • 0. Open sensor detection Yes Input power requirements Total power requirement: +24 VDC ±10% at 22 mA maximum : • Input power from CSLS Power Modules: +6.031 Ω 58 .20° C ±0.03 Ω/°C ~0.01° C Cu10 -200 to 260 °C ±0. 59 . • Color coding for thermocouple wires varies from country to country. The sensor is provided with the CHARM. • A sensor connected to two of the wiring terminals provides Cold Junction Compensation. Refer to your local standards for the appropriate color code.Logic Solver CHARMs specifications Wiring diagrams Figure 3-14: LS RTD / Resistance CHARM wiring diagram CHARM CHARM Baseplate CHARM Terminal Block Excitation Current and A/D Conversion Isolation 1 4-Wire 3 + 2 4 – 3-Wire + Shield 1 2 – 4 2-Wire + 1 2 – Related information CHARM Terminal Block specifications LS Thermocouple / mV input CHARM specifications Installation notes • The LS Thermocouple / mV input CHARM requires the CHARM Thermocouple / mV Terminal Block. Refer to Table 3-12 Repeatability 0. and ±100 mV. R. total error is made up of the 25°C reference accuracy value. J.3 VDC ±3% at 32 mA maximum • +24 VDC input power: ±10% at 10 mA maximum CHARM heat dissipation 0. Refer to Table 3-12 Accuracy over full scale temperature range Depends upon Thermocouple sensor type.06°C/°C 0. plus the CJC accuracy value. Refer to Table 3-12 Calibration None required Cold Junction Compensation (CJC) accuracy ±1. plus the sensor accuracy value. Uses 24-bit A/D converter. uncharacterized mV: Low level voltage source (±20 mV.6° C ±0.8° C ±0.0° C Cold Junction Compensation range -40° C to 85° C Open sensor detection Yes DC/50/60Hz common mode rejection 90 dB typical Channel isolation TC sensor input is galvanically isolated and factory tested to 1000 VDC. S. Table 3-12: LS Thermocouple sensor type specifications Sensor types 25°C reference accuracy Temperature drift Nominal resolution Full scale Operating range B ±0.018°C -270° to 1000°C -200° to 1000°C J ±0.03°C/°C 0.024°C 0° to 1820°C 250° to 1820°C E ±0. T. ±50 mV.04°C/°C 0. Full scale signal range Depends upon Thermocouple sensor type. K.30 W Note In the 25°C reference accuracy column in the following table.05% of span Resolution Depends upon Thermocouple sensor type. N.Logic Solver CHARMs specifications Specifications Table 3-11: LS Thermocouple / mV Input CHARM specifications Item Specification Channel type Thermocouple input Sensor types Thermocouple: B.4° C ±0.022°C -210° to 1200°C -210° to 1200°C 60 . Input power requirements Total power requirement: +24 VDC ±10% at 22 mA maximum : • Input power from CSLS Power Modules: +6. E. 028°C -50° to 1768°C -50° to 1768°C T ±0.028°C -50° to 1768°C -50° to 1768°C S ±0.8° C ±0.S. • The LS AI 4-20 mA HART (I.02°C/°C 0.020 mV .025 mV .001 mV/ °C .0015 mV ±50 mV ±50 mV ±20 mV ±0.S.03°C/°C 0.) CHARM supports 2 and 4-wire devices.05°C/°C 0.5° C ±0.4° C ±0. 61 .002 mV/ °C .) CHARM requires the I.8° C ±0.0005 mV/ °C .01°C -270° to 400°C -200° to 400°C ±100 mV ±0.025°C -270° to 1372°C -200° to 1372°C N ±0.010 mV .S.Logic Solver CHARMs specifications Table 3-12: LS Thermocouple sensor type specifications (continued) Sensor types 25°C reference accuracy Temperature drift Nominal resolution Full scale Operating range K ±0.6° C ±0.05°C/°C 0.0006 mV/ °C ±20 mV ±20 mV Wiring diagram Figure 3-15: LS Thermocouple / mV input CHARM wiring diagram CHARM CHARM Baseplate CHARM Thermocouple/mV terminal block + 2 Internal RTD A/D Conversion and CJC Measurement Isolation 1 _ Shield LS Intrinsically Safe input CHARMs specifications LS AI 4-20 mA HART (Intrinsically Safe) CHARM specifications Installation notes • The LS AI 4-20 mA HART (I. CHARM Terminal Block.0031 mV ±100 mV ±100 mV ±50 mV ±0.024°C -270° to 1300°C -200° to 1300°C R ±0.04°C/°C 0. 0 VDC minimum at 20 mA • Current limit: 25 mA (typical) Accuracy over temperature range • 0.Logic Solver CHARMs specifications Specifications Table 3-13: LS AI 4-20 mA HART (I.3 VDC ±3% at 0 mA maximum • +24 VDC input power: +24 VDC ±10% at 60 mA maximum CHARM heat dissipation (includes terminal block) 0. voltage peak value 375 V.86 W HART scan time 500 ms HART Communications • HART pass-through request/response • HART variable report • Field device status report .S.) CHARM specifications 62 Item Specification Channel type and functionality Intrinsically safe analog input: • 4-20 mA with HART • 0-20 mA Nominal signal range (span) • 4-20 mA • 0-20 mA (optional) Full signal range 0-22 mA 2-wire transmitter power • 16. Input power requirements • Input power from CSLS Power Modules: +6.1% of span (0 to 60° C) • .05% of span Resolution 16-bit Calibration None required Channel isolation Galvanically isolated according to EN 60079-11.25% of span (-40°C to 70°C) Repeatability 0. • The LS DI NAMUR (I. Power and Communications I. Power Isolation I.S.S.S.S.S.S.) CHARM for 2-wire applications CHARM Non-I. Power Isolation I. CHARM Terminal Block 1 Zone 0/1 Current Limiting Circuitry + 2 CHARM Data Processing and Communications 3 4 T – 2-wire analog and/or HART transmitter A/D Conversion and HART Interface Opto-Isolated Data Link Shield Figure 3-17: LS AI 4-20 mA HART (I.S.S.S.S.S.S.) CHARM can sense relay/switch contact closure and supports NAMUR sensors with NAMUR-specified line fault detection levels. Isolated Field Circuit Isolated +24V +24V I. CHARM Terminal Block 1 Zone 0/1 Current Limiting Circuitry – 2 CHARM Data Processing and Communications 3 4 + T 4-wire analog and/or HART self-powered transmitter A/D Conversion and HART Interface Opto-Isolated Data Link Shield Related information I. CHARM Baseplate I.Logic Solver CHARMs specifications Wiring diagrams Figure 3-16: LS AI 4-20 mA HART (I.S.) CHARM requires an I. Power and Communications I.S. CHARM Baseplate I. CHARM Terminal Block. 63 . Isolated Field Circuit Isolated +24V +24V I.S. CHARM Terminal Block specifications LS DI NAMUR (Intrinsically Safe) CHARM specifications Installation notes • The LS DI NAMUR (I.S.) CHARM for 4-wire applications CHARM Non-I. - Connect the dry contact to a 18 kΩ resistor in parallel for open circuit detection and a .2 mA Channel impedance 1 kΩ ±10% Wetting voltage 8 VDC ± 1 V Optional line fault detection levels • Guaranteed short circuit: <100 Ω • Guaranteed good status: 360 Ω to 20 kΩ • Guaranteed open circuit: >75 kΩ NAMUR sensor compatible Calibration None required Channel Isolation Galvanically isolated according to EN 60079-11. Figure 3-18: External line fault detection resistors + . voltage peak value 375 V.1 mA Detection level for Off <1.) CHARM specifications Item Specification Channel type Intrinsically safe discrete input: 8 VDC.) CHARM supports line fault detection for detecting open or short circuits in field wiring when external line fault resistors are used.36 KΩ 18 KΩ - Specifications Table 3-14: LS DI NAMUR (I.57 W . dry contact. Input power requirements • Input power from CSLS Power Modules: +6.S. To use line fault detection you must: - Enable line fault detection in the configuration.S. supports NAMUR sensors On/Off detection on the + signal 64 Detection level for On >2.36 kΩ resistor in series for short circuit detection.3 VDC ±3% at 0 mA maximum • +24 VDC input power: +24 VDC ±10% at 28 mA maximum CHARM heat dissipation (includes terminal block) 0.Logic Solver CHARMs specifications • The LS DI NAMUR (I. Isolated Field Circuit I.S. Refer to the temperature drift specification in RTD Sensor type specifications 65 . Power Isolation Zone 0/1 + Field Power and Channel Sensing Circuit CHARM Data Processing and Communications Option 1 2 4 NAMUR Sensor – Or Dry Contact + Opto-Isolated Data Link Shield 3 . or 4-wire applications.) CHARM wiring diagram + 3 CHARM Non-I. CHARM Terminal Block Field device 4 – 1 3 Isolated +24V +24V I.S. Power and Communications I. Refer to RTD Sensor type specifications Accuracy over full temperature range Depends upon the sensor type.Logic Solver CHARMs specifications Wiring diagram Figure 3-19: LS DI NAMUR (I. CHARM Terminal Block specifications LS RTD / Resistance input (Intrinsically Safe) CHARM specifications Installation notes • The LS RTD / Resistance input (I.S.S.S. or 4-wire Full scale signal range Selectable based on sensor. CHARM Terminal Block.S. Specifications Table 3-15: LS RTD /Resistance input (I. CHARM Baseplate I.) CHARM requires the I.S.S.36 KΩ 18 KΩ 4 – Field device Option 2 Related information I. • This CHARM can be configured for 2. 3.) CHARM specifications Item Specification Channel type RTD input Sensor types Refer to RTD Sensor type specifications Sensor configuration 2.S. 3.S. 014°C/°C 0.02°C/°C 0.24°C 0. RTD sensor type specifications Sensor type Operating range 25° reference accuracy Temperature drift Resolution 4-wire 3-wire 2-wire 4-wire 3-wire 2-wire Pt100 -200 to 850°C 0.006°C/°C 0.11°C 0.01°C Ni1000 -80 to 150 °C 0.41°C 0.04°C/°C 0.25 mA in 3-wire configurations DC50/60 Hz common mode rejection 90 dB typical Channel isolation Galvanically isolated according to EN 60079-11.01°C Ni120 -80 to 260 °C 0.42°C/ °C(2) 0.003°C/°C 0.014°C/°C 0. voltage peak value 375 VDC.03°C/°C 0.47°C 0.08°C 0.10°C 0.07°C/°C 0.60 W Note The accuracy and temperature drift values in the following table apply for a lead resistance of 0 Ω.34°C 0.74°C 0.10°C/°C 0.003°C/°C 0.20°C 0.003°C/°C 0.06°C 0.34°C 1.62°C 0.60°C 0.01°C Ni500 -80 to 260 °C 0.58°C 0.5 mA in 2 and 4-wire configurations • 0.00°C 0.00°C( 5.03°C/°C ~0.12°C 0.02°C/°C ~0.15°C 0.01°C/°C 0.85°C 0.01°C/°C ~0.01°C Ni100 -80 to 260 °C 0.02°C Pt200 -200 to 850°C 0. Refer to the resolution specification in RTD Sensor type specifications Calibration None required Sensor excitation current • 0. Uses 24-bit A/D converter.91°C 1.19°C 0.03°C/°C ~0. Table 3-16: LS I.01°C 0.40°C 1.02°C/°C ~0.70°C 8.05°C/°C ~0.01°C Ni200 -80 to 260 °C 0.19°C 0.015°C/°C 0.05°C/°C 0.18°C 0.42°C 0.003°C/°C 0.14°C 0.01°C/°C 0.S.33°C 0.01°C/°C ~0.05% of span Resolution Depends upon the sensor type.S.01°C Cu10 -200 to 260°C 1) (1) 3-wire mode for Cu10 is disabled through the firmware (2) 3-wire mode for Cu10 is disabled through the firmware 66 .02°C/°C 0.) CHARM specifications (continued) Item Specification Repeatability 0.Logic Solver CHARMs specifications Table 3-15: LS RTD /Resistance input (I.003°C/°C 0.3 VDC ±3% at 32 mA maximum • +24 VDC input power: ±10% at 23 mA maximum CHARM heat dissipation 0.02°C Pt500 -200 to 850°C 0. Open sensor detection Yes Input power requirements Total power requirement: +24 VDC ±10% at 23 mA maximum : • Input power from CIOC: +6.02°C/°C ~0.01°C/°C ~0.29°C/°C ~0.020°C/°C 0.50°C 1.47°C 0.02°C Pt1000 -200 to 260°C 0. S.Logic Solver CHARMs specifications Table 3-16: LS I. Power Isolation I.70 Ω 0. Refer to Recommended I/O Practices in DeltaV Books online for usage information.S.S.031 Ω Wiring diagrams Figure 3-20: LS RTD / Resistance input (I. RTD sensor type specifications (continued) Sensor type Resistance/user defined (0-2 kΩ)(3) Operating range 25° reference accuracy 0-100% Temperature drift 4-wire 3-wire 2-wire 4-wire 3-wire 0. CHARM Terminal Block 4-Wire 3 – 2 4 + Opto-isolated Data Link 3-Wire Shield 3 1 2 – + 2-Wire 1 2 – + Related information I.08 Ω/°C Resolution 2-wire 0. 67 .50 Ω 1. CHARM Terminal Block specifications (3) (The Callendar-Van Dusen linearization equation can be used with user defined Pt RTDs.020 Ω/°C 0. Power and Communications 1 Excitation Current and A/D Conversion I.48 Ω 0.S.03 Ω/°C ~0.) CHARM wiring diagram CHARM Baseplate CHARM Isolated +24V +24V CHARM Data Processing and Communications Non-I.S.S. Refer to Thermocouple sensor type specifications Accuracy over full scale temperature range Depends upon Thermocouple sensor type.05% of span Resolution Depends upon Thermocouple sensor type. uncharacterized mV: Low level voltage source (±20 mV. T. Refer to your local standards for the appropriate color code. Uses 24-bit A/D converter.03°C /°C Open sensor detection Yes Channel isolation Galvanically isolated according to EN 60079-11. K. N. ±50 mV. • Cold Junction Compensation for the CHARM is built into the terminal block.) CHARM requires the I. Thermocouple input Sensor types Thermocouple: B. Specifications Table 3-17: LS Thermocouple Input (I. and ±100 mV). R.S.S.7°C Cold Junction Compensation range -40° C to 85°C Temperature drift 0. S. voltage peak value 375 VDC. Input power requirements Total power requirement: +24 VDC ±10% at 23 mA maximum : • Input power from CIOC: +6. • Color coding for thermocouple wires varies from country to country.) CHARM specifications Item Specification Channel type I. Refer to Thermocouple sensor type specifications Repeatability 0. J.Logic Solver CHARMs specifications LS Thermocouple / mV input (Intrinsically Safe) CHARM specifications Installation notes • The LS Thermocouple / mV input (I.60 W .3 VDC ±3% at 32 mA maximum • +24 VDC input power: ±10% at 23 mA maximum CHARM heat dissipation 0. E. S. CHARM Thermocouple / mV Terminal Block. Refer to Thermocouple sensor type specifications Calibration None required Cold Junction Compensation (CJC) accuracy ±0.S. 68 Full scale signal range Depends upon Thermocouple sensor type. Logic Solver CHARMs specifications Note In the 25°C reference accuracy column in the following table.05°C/°C E ±0. Power Isolation Internal RTD +24V I.S.03°C/°C ~0.8 µV/°C ~0.05°C/°C ~0. CHARM Baseplate Isolated +24V CHARM Data Processing and Communications 4 + Opto-Isolated Data Link Non-I.10°C ±0.03°C/°C ~0.S.S.90°C ±0.70°C ±0.0015 mV -50 to 50 mV -50 to 50 mV ±20 mV 20 µV ±0. plus the sensor accuracy value. Power and Communications _ 3 A/D Conversion and CJC Measurement I.S.022°C -210° to 1200°C -200° to 1200°C K ±1.024°C 0° to 1820°C 250° to 400°C ±1.5 µV/°C ~0.7 µV/°C ~0.02°C/°C ±100 mV 50 µV ±2. plus the CJC accuracy value.07°C/°C ~0.05°C/°C ~0.0031 mV -100 to 100 mV -100 to 100 mV ±50 mV 40 µV ±1.S.07°C/°C ~0.028°C -50° to 1768°C -50° to 1767°C S ±1.025°C -270° to 1372°C -200° to 1370°C N ±1.50°C ±0. total error is made up of the 25°C reference accuracy value. CHARM Thermocouple / mV Terminal Block specifications 69 .70°C ±0.0006 mV -20 to 20 mV -20 to 20 mV 400° to 1820°C -200° to 400°C Wiring diagram Figure 3-21: LS Thermocouple / mV input (I.20°C ±0.60°C ±0.S.70°C ±0. CHARM Thermocouple/mV terminal block Shield Related information I.06°C/°C ~0.S.Thermocouple sensor type specifications Sensor types 25°C reference accuracy Temperature drift Nominal resolution Full scale Operating range B ±2.018°C -270° to 1000°C -200° to 1000°C J ±0. Table 3-18: I.01°C -270° to 400°C -250° to -200°C ±0.70°C ±0.04°C/°C ~0.70°C ±0.028°C -50° to 1768°C -50° to 1767°C T ±1.) CHARM wiring diagram CHARM I.024°C -270° to 1300°C -200° to 1300°C R ±1. - For applications that drive a final element that requires more than 500 mA. This CHARM is suitable for use in SIL 3 de-energize to trip (DTA) applications. • This CHARM is suitable for use in SIL 3 de-energize to trip (DTA) applications. The Redundant DTA Injected Power Relay Terminal Block has a built-in relay that can handle up to 3 A and the redundancy allows for higher safety coverage to shut down the process. the LS DO 24 VDC (Redundant DTA) CHARM. • The LS DO 24 VDC (Redundant ETA) CHARM requires the Redundant Terminal Block or the Redundant ETA Relay Terminal Block. The Redundant DTA Relay Terminal Block has a built-in relay that can handle up to 2 A and the redundancy allows for higher safety coverage to shut down the process. and also requires the use of the baseplate's injected power bus rather than system power use the Redundant DTA Injected Power Relay Terminal Block. Specifications Table 3-19: LS DO 24 VDC CHARMs specifications 70 Item Specification Channel type Discrete output: 24 VDC high-side . Line monitoring is enabled in the configuration. This CHARM is suitable for use in SIL 2 energize to trip (ETA) applications. This CHARM is suitable for use in SIL 2 energize to trip (ETA) applications. the LS DO 24 VDC ETA CHARM. Note Line fault detection is not compatible with significant capacitive loading (cable + load > 30 nF) and must be disabled under these conditions. Installation notes • The LS DO 24 VDC DTA CHARM requires the CHARM Terminal Block. • The LS DO 24 VDC (Redundant DTA) CHARM can use the following terminal blocks: - The Redundant Terminal Block - For applications that drive a final element that requires more than 500 mA use the Redundant DTA Relay Terminal Block. • The LS DO CHARMs have short circuit protection and support line monitoring for sensing field wiring faults such as open and short circuits.Logic Solver CHARMs specifications LS Output CHARMs specifications LS DO 24 VDC CHARMs specifications The DeltaV system supports the LS DO 24 VDC DTA CHARM. • The LS DO 24 VDC ETA CHARM requires the CHARM Terminal Block. and the LS DO 24 VDC (Redundant ETA) CHARM. 5 kΩ load • Guaranteed open circuit: >20 kΩ load Line fault test timing 200 µsec Input power requirements Total power requirement per CHARM: +24 VDC ±10% at 36 mA maximum plus output load current : • Input power from CSLS Power Modules: +6.3 W 71 . 1. Off-state leakage current 5 mA maximum Line fault detection levels • Guaranteed short circuit: 10 Ω • Guaranteed good status: 56 Ω to 3. channel protection Output inrush current and short circuit protection: limited to 580 mA (typical) for simplex.3 VDC ± 3% at 60 mA average • 24 VDC input power: +24 VDC ±10% at 36 mA maximum Total power requirement for redundant pair driving relay terminal: +24 VDC ±10% at 148 mA maximum: • Input power from CSLS Power Modules:+6.Logic Solver CHARMs specifications Table 3-19: LS DO 24 VDC CHARMs specifications (continued) Item Specification On-state output rating 24 VDC at 500 mA continuous per channel Channel power is derived from +24 VDC (±10%) power supplied to the CHARMs Smart Logic Solver Carrier.3 VDC ± 3% at 60 mA maximum CHARM heat dissipation 1.16 A for redundant when both CHARMs are operational. On-state current limiting. Logic Solver CHARMs specifications Wiring diagrams Figure 3-22: LS DO 24 VDC DTA Simplex CHARM wiring diagram CHARM CHARM Baseplate CHARM Terminal Block +24 VDC 1 Current Limiting Circuitry + 2 – S Solenoid Channel Readback Circuitry Figure 3-23: LS DO 24 VDC ETA Simplex CHARM wiring diagram CHARM CHARM Baseplate CHARM Terminal Block +24 VDC Current Limiting Circuitry 1 + 2 Channel Readback Circuitry 72 – S Solenoid . Logic Solver CHARMs specifications Figure 3-24: LS DO 24 VDC (Redundant DTA) CHARM wiring diagram CHARM CHARM Baseplate Redundant Terminal Block +24 VDC 1 Current Limiting Circuitry + 2 S – Solenoid Channel Readback Circuitry CHARM CHARM Baseplate +24 VDC Current Limiting Circuitry Channel Readback Circuitry 73 . Logic Solver CHARMs specifications Figure 3-25: LS DO 24 VDC (Redundant ETA) CHARM wiring diagram CHARM CHARM Baseplate Redundant Terminal Block +24 VDC 1 Current Limiting Circuitry + 2 Channel Readback Circuitry CHARM +24 VDC Current Limiting Circuitry Channel Readback Circuitry 74 CHARM Baseplate – S Solenoid . Logic Solver CHARMs specifications Figure 3-26: LS DO 24 VDC (Redundant DTA) CHARM wiring diagram with Redundant DTA Relay Terminal block CHARM CHARM Baseplate Redundant DTA Relay Terminal Block +24 VDC 1 Current Limiting Circuitry + Source – Test Point Channel Readback Circuitry – S + CHARM CHARM Baseplate Solenoid 2 +24 VDC Current Limiting Circuitry Channel Readback Circuitry 75 . Logic Solver CHARMs specifications Figure 3-27: LS DO 24 VDC (Redundant DTA) CHARM wiring diagram with Redundant DTA Injected Power Relay Terminal Block CHARM +24 VDC CHARM Baseplate L+ Redundant DTA Injected Power Relay Terminal Block N Current Limiting Circuitry 2A Channel Readback Circuitry CHARM 1 +24 VDC Current Limiting Circuitry – 2 Channel Readback Circuitry 76 + S Solenoid . and the LS DVC HART (Redundant DTA) CHARM. 77 .Logic Solver CHARMs specifications Figure 3-28: LS DO 24 VDC (Redundant ETA) CHARM wiring diagram with Redundant ETA Relay Terminal block CHARM CHARM Baseplate Redundant ETA Relay Terminal Block +24 VDC 1 Current Limiting Circuitry + Source – – Channel Readback Circuitry CHARM 2 S + Solenoid CHARM Baseplate +24 VDC Current Limiting Circuitry Channel Readback Circuitry Related information CHARM Terminal Block specifications Redundant Terminal Block specifications Redundant DTA Relay Terminal Block specifications Redundant ETA Relay Terminal Block specifications Redundant DTA Injected Power Relay Terminal Block specifications LS DVC HART DTA CHARMs specifications The DeltaV system supports the LS DVC HART DTA CHARM. Redundancy allows for higher safety coverage to shutdown the process. This CHARM is suitable for use in SIL 3 de-energize to trip (DTA) applications. • The LS DVC HART (Redundant DTA) CHARM requires the Redundant DVC Terminal Block.03 W HART scan time 500 ms HART communications • HART pass-through request/response • HART variable report • Field device status report .Logic Solver CHARMs specifications Installation notes • The LS DVC HART DTA CHARM requires the DVC Terminal Block. This CHARM is suitable for use in SIL 3 de-energize to trip (DTA) applications.3 VDC ± 3% at 96 mA maximum • 24 VDC input power: +24 VDC ±10% at 34 mA maximum Total power requirement (redundant pair): +24 VDC ±10% at 108 mA maximum: • Input power from CSLS Power Modules:+6.3 VDC ± 3% at 190 mA maximum • 24 VDC input power: +24 VDC ±10% at 46 mA maximum 78 CHARM heat dissipation 1. Specifications Table 3-20: LS DVC HART DTA CHARMs specifications Item Specification Channel type Analog output: 4-20 mA with HART Nominal signal range • 4-20 mA • 0-20 mA optional Full signal range 0-24 mA Accuracy over temperature range • 0 to 60°C: 2% of span • -40° to 70°C: 5% of span Resolution 12 bits Calibration None required Compliance voltage • Voltage to load: 15 V minimum at 20 mA and 24 VDC • Load resistance: 250 Ω minimum to 600 Ω maximum Input power requirements Total power requirement (simplex): +24 VDC ±10% at 64 mA maximum: • Input power from CSLS Power Modules:+6. Logic Solver CHARMs specifications Wiring diagrams Figure 3-29: LS DVC HART DTA (simplex) CHARM wiring diagram CHARM CHARM Baseplate DVC Terminal Block 1 Current Limiting Circuitry + DVC HART Interface 2 – Digital Valve Controller Current Sinking Output Shield Figure 3-30: LS DVC HART (Redundant DTA) CHARM wiring diagram CHARM CHARM Baseplate Redundant DVC Terminal Block 1 Current Limiting Circuitry + DVC HART Interface 2 – Digital Valve Controller Current Sinking Output CHARM Current Limiting Circuitry HART Interface Current Sinking Output Shield 79 . • The LS 24 VDC Power CHARM requires no configuration. • You must inject the 24 VDC power at the Address Terminal on the baseplate on which the CHARM is installed.Logic Solver CHARMs specifications Related information DVC Terminal Block specifications Redundant DVC Terminal Block specifications LS 24 VDC Power CHARM specifications Installation notes • The LS 24 VDC Power CHARM provides 24 VDC power to a single.01 A maximum: • 10 mA status readback • 1 A maximum to load CHARM heat dissipation 80 0.32 W .3 VDC ±3% at 32 mA maximum • +24 VDC input power: none Injected power requirement: +24 VDC ±10% at 1. Input power requirements +24 VDC ±10% at 12 mA maximum: • Input power from CSLS Power Modules: +6. three or four wire field device and monitors the power status. Output power has no isolation from the injection point. The CHARM must be removed from the terminal block to disconnect power from the field devices. • The LS 24 VDC Power CHARM requires a CHARM Fused Injected Power Terminal Block. • Installing the CHARM on the terminal block connects the power that was injected at the Address Terminal to the screw terminals on the terminal block. Specifications Table 3-21: LS 24 VDC Power CHARM specifications Item Specification Channel type 24 VDC power output Status readback level for power Good > 10 VDC Status readback level for power Bad < 5 VDC Channel isolation Status readback circuitry is optically isolated and factory tested to 1000 VDC. Logic Solver CHARMs specifications Wiring diagram Figure 3-31: LS 24 VDC Power CHARM wiring diagram CHARM Baseplate CHARM +V -V Charm Fused Injected Power Terminal Block 2 KΩ 2A Isolation 2 KΩ 2 4 + – Output Power Related information CHARM Fused Injected Power Terminal Block specifications 81 . Logic Solver CHARMs specifications 82 . ) Table 4-1: Analog LS CHARMs LED LED color and pattern Description and corrective action Green (continuous) The channel and LS CHARM status is good and the LS CHARM is configured.S.S. 83 .S.) • LS AI 0-10 VDC isolated • LS RTD / Resistance input • LS RTD / Resistance input (I.LED descriptions for CHARMs Smart Logic Solver hardware 4 LED descriptions for CHARMs Smart Logic Solver hardware Topics covered in this chapter: • • Analog LS CHARMs LED Discrete LS CHARMs LEDs • • • • CHARMs Smart Logic Solver LEDs Safety Network Port LEDs SZ controller LEDs Ethernet Isolation Port LEDs Analog LS CHARMs LED This table describes the meaning of the colors and patterns associated with the single LED on the following analog input LS CHARMs: • LS AI 4-20 mA HART • LS AI 4-20 mA HART (I.) • LS Thermocouple / mV input • LS Thermocouple / mV input (I. • If this pattern is seen on all LS CHARMs. ensure that the correct address plug is installed. a configuration error such as a configuration mismatch. • If this pattern is seen on all LS CHARMs. • Hardware error in the LS CHARM. Red (flashing ten times per second) Duplicate address. the LS CHARM has not been configured. Green (flashing ten times per second) A user has issued an identify LS CHARM command from the DeltaV Diagnostics application. • If this pattern is seen on a group of 12 LS CHARMs. Red (continuous) No communications on the bus or no address. • If this pattern is seen on a group of 12 LS CHARMs. has occurred. ensure that the correct address plug is installed. ensure that the CSLS is functioning correctly. Green and red alternating two times per second The CHARM is being upgraded or is in upgrade mode.LED descriptions for CHARMs Smart Logic Solver hardware Table 4-1: Analog LS CHARMs LED (continued) 84 LED color and pattern Description and corrective action Green (flashing once per second) The channel and LS CHARM status is good but the LS CHARM is not configured. configure the LS CHARM in DeltaV Explorer. If DeltaV Diagnostics displays BAD status for this LS CHARM. Ensure that the ranges are correct. Check the wiring and field power. • Field value is out of the configured range or the sensor is out of range. Check all baseplates for a duplicate address plug. In this case. • If this pattern is seen on an individual LS CHARM. • If this pattern is seen on an individual LS input CHARM. . replace the LS CHARM. replace the CHARM. Green then red flashing three or four times per second A CHARM fault (such as a bad address or a faulty CHARM bus) exists that does not affect the channel status. Red (flashing twice per second) • Channel fault (open or short circuit) detected or field power missing. This is not a fault and no action is required. ensure that the CSLS is functioning correctly. If DeltaV Diagnostics displays GOOD status for the LS CHARM. Check DeltaV Diagnostics for a hardware error. replace the LS CHARM. • If the LEDs on all the LS CHARMs on a baseplate are not showing a color.S. • If all LS CHARMs' LEDs are not showing a color.LED descriptions for CHARMs Smart Logic Solver hardware Table 4-1: Analog LS CHARMs LED (continued) LED color and pattern Description and corrective action No colors The CHARM is unpowered or not functioning. Discrete LS CHARMs LEDs This table describes the meaning of the colors and patterns associated with the two LEDs on the following discrete LS CHARMs: • LS 24 VDC Power • LS DI 24 VDC isolated • LS DI 120 VAC isolated • LS DI 230 VAC isolated • LS DI 24 VDC low-side (dry contact) • LS DI NAMUR • LS DI NAMUR (I. • If the LED on one LS CHARM is not showing a color. 85 .) • LS DO 24 VDC • LS DVC HART DTA (simplex and redundant) Table 4-2: Discrete LS CHARMs LEDs LED color and pattern Description and corrective action Green (continuous) The channel and LS CHARM status is good and the CHARM is configured. check the power connections. check the connection to the baseplate. Check DeltaV Diagnostics for a hardware error. has occurred. If DeltaV Diagnostics displays GOOD status for the LS CHARM. If DeltaV Diagnostics displays BAD status for this LS CHARM. ensure that the CSLS is functioning correctly.LED descriptions for CHARMs Smart Logic Solver hardware Table 4-2: Discrete LS CHARMs LEDs (continued) 86 LED color and pattern Description and corrective action Green (flashing once per second) The channel and LS CHARM status is good but the LS CHARM is not configured. the LS CHARM has not been configured. Check all baseplates for a duplicate address plug. replace the CHARM. replace the LS CHARM. Green then red flashing three or four times per second A CHARM fault (such as a bad address or a faulty CHARM bus) exists that does not affect the channel status. • If this pattern is seen on all LS CHARMs. • If this pattern is seen on an individual LS CHARM. check that the CHARMs Smart Logic Solver (CSLS) is commissioned and that the LS CHARM is being driven by logic. This could also indicate a hardware error in the LS CHARM. ensure that the correct address plug is installed. • If this pattern is seen on all LS CHARMs. Green and red alternating two times per second The CHARM is being upgraded or is in upgrade mode. This is not a fault and no action is required. ensure that the correct address plug is installed. Red (continuous) No communications on the bus or no address. Red (flashing ten times per second) Duplicate address. . • If this pattern is seen on an individual LS output CHARM. Green (flashing ten times per second) A user has issued an identify LS CHARM command from the DeltaV Diagnostics application. Red (flashing twice per second) Channel fault (open or short circuit) detected or field power missing. configure the LS CHARM in DeltaV Explorer. • If this pattern is seen on a group of 12 LS CHARMs. ensure that the CSLS is functioning correctly. • If this pattern is seen on an individual LS input CHARM. In this case. a configuration error such as a configuration mismatch. • If this pattern is seen on a group of 12 LS CHARMs. Check the wiring and field power. Power on and all other LEDS flashing quickly The CSLS is identifying. Power on and Error flashing slowly with Active and Standby off The CSLS is unassigned. Active. For outputs. Power on with Error. No corrective action is required. • If all LS CHARMs' LEDs are not showing a color. Check the power connections. If the CSLS is not shown as assigned to a placeholder for its SZ controller under the Local Safety Network in DeltaV Explorer. Power and Error on solid with Active and Standby off The CSLS went through a reset or an error has occurred. check the connection to the baseplate.The actual input value or the intended output value is Off. Yellow continuous also indicates that the LS DVC CHARM is driving a 20 mA signal. Commission the redundant CSLS. • Off . the Safety Network Ports must be reset. Yellow This is the channel status indication: • Yellow (continuous) . replace the LS CHARM. Contact technical support. Assign the CSLS to a placeholder. check the power connections. Power on and Standby off with Error and Active flashing slowly The active CSLS is assigned but decommissioned. and Standby off The CSLS is powering up. • If the LEDs on all the LS CHARMs on a baseplate are not showing a color. CHARMs Smart Logic Solver LEDs The CSLS's Power. Table 4-3: CHARMs Smart Logic Solver LEDs LED color and pattern Description and corrective action All LEDs off System power is not supplied to the CSLS. • If the LED on one LS CHARM is not showing a color. Active and Standby LEDs are green and the Error LED is red. yellow continuous indicates the last written output value not the actual readback value.The actual input value or the intended output value is ON. 87 . No corrective action is required.LED descriptions for CHARMs Smart Logic Solver hardware Table 4-2: Discrete LS CHARMs LEDs (continued) LED color and pattern Description and corrective action No colors The CHARM is unpowered or not functioning. Power and Error on with Active and Standby flashing quickly Persistent fatal error. Each port has a port activity LED. No corrective action is required. and downloaded. the Safety Network Ports must be reset. Power on with Active on and Error and Standby off The active CSLS is assigned. The Active LED on the active CSLS should be flashing slowly. Power on with Active flashing slowly and Standby and Error off The redundant (active) CSLS is commissioned but not downloaded. and downloaded. If this is not the case. Contact technical support. Power on with Standby on and Error and Active off The standby CSLS is assigned. there is an error with the standby CSLS going configured and technical support should be contacted. 88 . Download the CSLS. Power on with Error off and Active and Standby flashing alternately. Power on with Standby flashing slowly and Active and Error off The redundant (standby) CSLS is commissioned but not downloaded. The CSLS is being upgraded. Related information Reset Safety Network Ports Safety Network Port LEDs The CSLS carrier house a primary and secondary Safety Network Port (SNP) for connections to the Local Safety Network. commissioned.LED descriptions for CHARMs Smart Logic Solver hardware Table 4-3: CHARMs Smart Logic Solver LEDs (continued) LED color and pattern Description and corrective action Power on and Active off with Error and Standby flashing slowly The standby CSLS is assigned but decommissioned. commissioned. Download the CSLS. If the CSLS is not shown as assigned to a placeholder for its SZ controller under the Local Safety Network in DeltaV Explorer. Commission the redundant CSLS. 89 . but no Ethernet traffic is occurring. Also ensure that the SZ controller is powered and connected to the DeltaV Control Network and the Local Safety Network. verify that the Safety Network Port is properly seated in the CSLS and the CSLS is properly seated in the carrier. If this pattern persists after the CSLS is powered. Off The Safety Network Port is not physically connected. This pattern verifies the wiring and connections and can occur for a short time at power up. This is the normal operating condition.LED descriptions for CHARMs Smart Logic Solver hardware LED Table 4-4: Safety Network port LED LED color and pattern Description and corrective action Flashing green The link is established and active Ethernet traffic is being transmitted and received. neither CSLS is present. Solid green The link is established. Verify that at least one CSLS is installed and powered. or both CSLSs are unpowered. Check to see if the connection to the Ethernet switch is correct and that the switch is on. Commission the controller. Controller went through a reset due to an unrecoverable software error. Contact technical support. Contact technical support. Contact technical support. Controller is decommissioned. Download the controller configuration. Contact technical support. Red (flashing) The controller is decommissioned. Green (flashing) Controller is not configured. Commission the controller. 90 . Internal fault. Off for simplex controllers Ethernet Isolation Port LEDs The SZ controller carrier house a primary and secondary Ethernet Isolation Port (EIP). Error-Off Active-On (green) Red (continuous) Internal fault. Download the controller configuration. Check the power connections. Red-On for one second followed by all LEDs on for five seconds. Internal fault. Each EIP consists of a Control Network port for connections to the DeltaV Area Control Network and a Safety Network port for connections to the Local Safety Network. Off Controller is a standby. Standby-On (green) for redundant controllers Green (flashing) Controller is not configured. Ensure that the Standby LED is On.LED descriptions for CHARMs Smart Logic Solver hardware SZ controller LEDs Table 4-5: SZ controller LEDs LED correct operating condition Fault indication Possible causes and corrective action Power-On (green) Off System power is not supplied to the controller due to a possible line power problem. 91 . This typically occurs during initial installation when network connections are not yet complete. If the LED remains Off after ensuring the items in the preceding list. but may not be connected to a controller or ProfessionalPlus workstation. Solid green The link is established. Verify that the: • Network cable is properly connected • EIP is properly seated in the carrier • SZ controller is properly installed in the carrier • SZ controller is properly powered For redundant controllers. This is the normal operating condition.LED descriptions for CHARMs Smart Logic Solver hardware Control Network port LED Safety Network port LED Table 4-6: Control network port LEDs on the Ethernet Isolation Port LED color and pattern Description and corrective action Flashing green The link is established and active Ethernet traffic is being transmitted and received. This indicates that the EIP is connected to a network switch. verify that the ACN LEDs are flashing. but no Ethernet traffic is occurring. replace the EIP. Off The EIP is not communicating on the network. neither SZ controller is present.LED descriptions for CHARMs Smart Logic Solver hardware Table 4-7: Safety Network port LED on the Ethernet Isolation Port 92 LED color and pattern Description and corrective action Flashing green The link is established and active Ethernet traffic is being transmitted and received. but no Ethernet traffic is occurring. This is the normal operating condition. or both SZ controllers are unpowered. Check to see if the Ethernet network has a CSLS powered and connected on the Safely Network Port. Also occurs for a short time at power up. Solid green The link is established. Ensure that the connection back to the Ethernet switch is correct and that the switch is powered. Off The Safety Network Port is not physically connected. . This verifies the physical wire and connection integrity. Verify that at least one SZ controller is installed and powered. Verify both the Safety Network Port and SZ controller are fully seated. Local Safety Network The Local Safety Network is a Ethernet network that enables communication between CSLSs and a single SZ Controller. The following figure shows an example CSLS SIS network. Refer to the DeltaV™ S-series and CHARMs Hardware Installation manual for information on setting up the Area Control Network.Networks in a CHARMs Smart Logic Solver SIS system 5 Networks in a CHARMs Smart Logic Solver SIS system Topics covered in this chapter: • • Communication in a CHARMs Smart Logic Solver SIS system DeltaV LSN20 Safety Switches • • • • DeltaV SRM100 Safety Switch Twisted pair and fiber-optic star network with DeltaV safety switches Twisted pair network with DeltaV safety switches Twisted pair network with DeltaV safety switches and firewalls Communication in a CHARMs Smart Logic Solver SIS system In a CSLS SIS system. Important The Local Safety Network must be treated as a dedicated standalone Local Area Network (LAN) and must not be connected to any other network including other DeltaV Local Safety Networks. A redundant SZ Controller with its redundant CSLSs and LS CHARMs connect to the Local Safety Network and to a DeltaV Area Control Network with redundant CIOCs and standard CHARMs. communication occurs over the DeltaV Area Control Network and a Local Safety Network. SZ Controllers connect to the Area Control Network (as well as to the Local Safety Network) and isolate the CHARMs Smart Logic Solvers (CSLS) from the rest of the DeltaV system. Only DeltaV Safety Switches (LSN20 and SRM100) and DeltaV SIS nodes are supported on the Local Safety Network. 93 . All CSLSs under one SZ Controller share the same Local Safety Network. parameter changes. DeltaV Area Control Network The DeltaV Area Control Network is an Ethernet network that enables communication between the nodes in a DeltaV network. SZ Controllers provide the DeltaV interface to multiple CSLSs on the same Local Safety Network. and module data over the Local Safety Network to the CSLSs. The CSLSs communicate secure parameter and input data to other CSLSs over the Local Safety Network. The SZ Controller communicates configuration. . Up to 6 more baseplates for a total of 96 CHARMs per CIOC. Up to 6 more baseplates for a total of 96 CHARMs per CSLS. Redundant CSLS Baseplate for 12 CHARMs.Networks in a CHARMs Smart Logic Solver SIS system Pro/Op/App Stations ProPlus RM100 Primary RM100 Secondary Primary Secondary DeltaV Area Control Network DeltaV Controller Firewall MD30 Primary DeltaV Controller Firewall MD30 Secondary Redundant SZ Controllers LSN20 Primary Redundant CIOCs LSN20 Secondary Local Safety Network Baseplate for 12 CHARMs. DeltaV LSN20 Safety Switches Installation notes • 94 The LSN20 Safety Switches are used exclusively on the Local Safety Network (LSN). Networks in a CHARMs Smart Logic Solver SIS system Important Only DeltaV Safety Switches (LSN20 and SRM100) and DeltaV SIS nodes are supported on the Local Safety Network. twisted pair uplink. 10/100mb/s RJ45 twisted pair ports Port layout Network Switch FP20 FAULT +24V(P1) 0V 0V Power/relay connectors LEDs +24V(P2) P FAULT RUN LOCK USB port 24 V USB V. full duplex 7 8 Network Switch FP20 LS Fiber uplink port FAULT +24V(P1) 0V 0V +24V(P2) DA P FAULT RUN LOCK Power/relay connectors LEDs 1 USB port 24 V USB V. 100mb/s single mode fiber uplink ports (SC connectors). Two ports on each switch are fiber uplink. • DeltaV LSN20 Safety Switches have eight ports.24 1 2 3 4 8 twisted pair ports 5 6 Ground screw • LSN20-6TX2MM • LSN20-6TX2MM-ES (1) • 6. 10/100mb/s RJ45 twisted pair ports • 2. Port information Table 5-1: Port information for the DeltaV LSN20 Safety Switches Model Number and types of ports • LSN20-6TX2TX • LSN20-6TX2TX-ES(1) 8. or a combination of fiber and twisted pair uplink ports. 95 . 100mb/s multimode fiber uplink ports (SC connectors). 10/100mb/s RJ45 twisted pair ports • 2.24 LS DA 1 2 Fiber uplink port 2 3 4 Ground screw • LSN20-6TX2SM • LSN20-6TX2SM-ES(1) • 6. The remaining 6 ports are 10/100mb/s twisted pair. full duplex 5 6 Network Switch FP20 LS Fiber uplink port Twisted pair ports FAULT +24V(P1) 0V 0V +24V(P2) DA P FAULT RUN LOCK Power/relay connectors LEDs 1 USB port 24 V USB V.24 LS DA 1 2 Fiber uplink port Ground screw 2 3 4 Twisted pair ports 5 6 (1) The ES version of the switches have an extended temperature range and conformal coating. 1 2. gigabit Ethernet combo Switch ports • 8. • The SRM100 Safety Switch consists of a base switch and sockets for two media modules that plug into the switch and provide an additional 8 or 16 ports.6 2. 96 Image Signal contact USB Port v.1 2.8 V. • The SRM100 Safety Switch supports redundant input power.7 2. fast Ethernet ports • 2.3 2. Important Only DeltaV Safety Switches (LSN20 and SRM100) and DeltaV SIS nodes are supported on the Local Safety Network.24 Network Switch RM100 FAULT USB Sockets for media modules Ethernet ports RM100 Base Module 1. • The SRM100 Safety Switch can be mounted on a 19 inch rack or on a wall.5 2.Networks in a CHARMs Smart Logic Solver SIS system DeltaV SRM100 Safety Switch Installation notes • The SRM100 Safety Switch is used exclusively on the Local Safety Network (LSN). The standard power supply alone supplies power to the SRM100 Safety Switch.2 2. The redundant power supply automatically becomes active if the standard supply fails.4 2. If the switch is mounted on a 19 inch rack.2 SFP ports Twisted pair ports .24 RUN LOCK P 1. be sure to install sliding mounting rails to properly hold the switch. 100/1000mb/s SFP-based ports • 2 sockets for media modules for an additional 8 or 16 ports. Port information Table 5-2: Port information for the DeltaV SRM100 Safety Switch Model Number and types of ports SRM100 Safety • 2. Networks in a CHARMs Smart Logic Solver SIS system Twisted pair and fiber-optic star network with DeltaV safety switches Figure 5-1: Example safety network Control Room Building 1 DeltaV Operator and Application Stations and ProPlus 1 1 Cat 5e Sc Tp Cat 5e Sc Tp Cat 5e Sc Tp Cat 5e Sc Tp Cat 5e Sc Tp Cat 5e Sc Tp Cat 5e Sc Tp Rack Room Building 1 Cat 5e Sc Tp Control Network (ACN) Switches Non-Safety Network RM100 100 Mbps or 1000 Mbps Fiber Optic SFP Modules RM100 4 100 Mbps or 1000 Mbps Fiber Optic SFP Modules 6 4 Safety System Switches Building 1 Upper port to primary Control Network switches Upper port to secondary Control Network switches Lower port to secondary Safety Network switches Lower port to secondary Safety Network Switches 2 SRM100 5 SRM100 SZ Controller 7 100 Mbps Fiber Optic SFP Modules 100 Mbps Fiber Optic SFP Modules 7 4 Building 2 Building 4 3 RM100 LSN20 LSN20 Control Network (ACN) Switches Non-Safety Network 100 Mbps or 1000 Mbps Fiber Optic SFP Modules 6 RM100 CHARMs I/O Safety Network Switches 9 Building 3 1 100 Mbps or 1000 Mbps Fiber Optic SFP Modules 8 3 RM100 LSN20 100 Mbps or 1000 Mbps Fiber Optic SFP Modules LSN20 Control Network (ACN) Switches Non-Safety 6 Network RM100 CHARMs I/O 9 NOTE: Separate fiber optic cable runs must be used for the Safety Network and Control Network. Safety Network Switches 8 1 100 Mbps or 1000 Mbps Fiber Optic SFP Modules Local Safety Network 97 . metal-enclosed RJ45 connector on one end and an isolated. and to gain additional distance that goes beyond the 100 meters (328 ft) maximum allowed for screened twisted pair cabling (ScTP). The switches are plug and play. The metal connector end of this cable assembly must be placed on the switch and not on the PC.Networks in a CHARMs Smart Logic Solver SIS system Callout 1 2 3 4 5 6 7 8 9 98 Description 100 meter (maximum) straight-through or crossover cable. plastic-enclosed RJ45 connector on the other end. Build this cable assembly with a shielded. For network diagnostics for these switches. metal-enclosed RJ45 connector on both ends. The SRM100 Safety Switch cannot be managed through the Smart Switch Command Center. Both single mode and multimode fiber optic cable is supported used in conjunction with the DeltaV Smart Switches The SZ Controller completely isolates communications between the DeltaV Control Network and the Local Safety Network. for ground isolation between buildings. The shield on the CSLS RJ45 connector connects only to a Faraday cage in the CSLS. The RM100 Smart Switches are managed through the DeltaV console using Smart Switch Command Center. The shield on the SZ controller's RJ45 connector connects only to a Faraday cage in the controller. The switches are plug and play. metal-enclosed RJ45 connector on both ends. the RJ45 connectors are floating and the single point of ground is made at the switch to which the CSLS is connected. Fiber-optic cable must be used for outdoor building to building communications for immunity to electromagnetic interference caused by near lightning strikes. Do not use external cabling to connect these two independent systems together. Build this cable assembly with a shielded. not to the controller's DC ground. not to the CSLS DC ground. Therefore. Connect the switch's ground screw to a suitable ground for the cable shields. To prevent ground loops. For network diagnostics for these switches. The LSN safety switches cannot be managed through the Smart Switch Command Center. you must attach an optional serial cable to the serial port of the safety switch and use an application such as Hyper-terminal to access the switch information. No configuration of the safety switch is possible though the serial port. . build this cable assembly with a shielded. Therefore. 100 m (maximum) straight-through or crossover cable. 100 m (maximum) straight-through or crossover cable. No configuration of the safety switch is possible though the serial port. you must attach an optional serial cable to the serial port of the safety switch and use an application such as Hyper-terminal to access the switch information. the RJ45 connectors are floating and the single point of ground is made at the switch to which the controller is connected. Networks in a CHARMs Smart Logic Solver SIS system Twisted pair network with DeltaV safety switches Figure 5-2: Example safety network Control Network (ACN) DeltaV Operator and Application Stations and ProPlus 1 1 10/100 TP 10/100 TP 10/100 TP 10/100 TP 10/100 TP 10/100 TP 10/100 TP 10/100 TP 3 Control Network (ACN) Switches Non-Safety Network RM100 RM100 5 Upper port to primary Control Network switches Upper port to secondary Control Network switches Safety Network Lower port to secondary Safety Network switches 2 Lower port to secondary Safety Network Switches 2 6 6 4 LSN20 Safety Switch 7 3 LSN20 Safety Switch SZ Controller 3 8 CSLS CHARMS I/O 1 2 3 8 99 . Networks in a CHARMs Smart Logic Solver SIS system Callout 1 2 3 4 5 6 7 8 100 Description 100 meter (maximum) straight-through or crossover cable. Therefore. The metal connector end of this cable assembly must be placed on the switch and not on the PC. The shield on the CSLS RJ45 connector connects only to a Faraday cage in the CSLS. Therefore. 100 m (maximum) straight-through or crossover cable. plastic-enclosed RJ45 connector on the other end. metal-enclosed RJ45 connector on one end and an isolated. Build this cable assembly with a shielded. To prevent ground loops. not to the CSLS DC ground. metal-enclosed RJ45 connector on both ends. Build this cable assembly with a shielded. Up to 16 CHARMs Smart Logic Solvers (CSLS) can be connected within the Safety System architecture. The LSN20 safety switches cannot be managed through the Smart Switch Command Center. the RJ45 connectors are floating and the single point of ground is made at the switch to which the controller is connected. The RM100 Smart Switches are managed through the DeltaV console using Smart Switch Command Center. Attach the ground screw of the switch to a suitable ground for the cable shields. External cabling should never be used to connect these two independent systems together. the LSN20 switches. are used but an SRM100 rack mounted safety switch with optional twisted pair port modules could be used so that the maximum of 16 CSLS can be attached. build this cable assembly with a shielded. For network diagnostics for these switches. 100 m (maximum) straight-through or crossover cable. The SZ Controller completely isolates communications between the DeltaV Control Network and the Safety Network. you must attach an optional serial cable to the serial port of the safety switch and use an application such as Hyper-terminal to access the switch information. . The shield on the SZ controller's RJ45 connector connects only to a Faraday cage in the controller. metal-enclosed RJ45 connector on both ends. No configuration of the safety switch is possible though the serial port. which have a low port count. not to the controller's DC ground. the RJ45 connectors are floating and the single point of ground is made at the switch to which the CSLS is connected. The switches are plug and play. In this example. Networks in a CHARMs Smart Logic Solver SIS system Twisted pair network with DeltaV safety switches and firewalls Figure 5-3: Example safety network with firewalls Control Network (ACN) DeltaV Operator and Application Stations and ProPlus 1 1 10/100 TP 10/100 TP 10/100 TP 10/100 TP 10/100 TP 10/100 TP 10/100 TP 10/100 TP 3 Control Network (ACN) Switches Non-Safety Network RM100 RM100 5 10 11 11 Primary 10 Secondary Upper port firewall to upper port SZ Controller Upper port firewall to upper port SZ Controller 8 8 DeltaV Controller Firewall Lower port to primary Safety System Switches DeltaV Controller Firewall Lower port to secondary Safety System Switches 4 SZ Controller Safety Network 2 2 6 LSN20 Safety Switch 6 LSN20 Safety Switch 3 3 7 9 CSLS CHARMS I/O 101 . plastic-enclosed RJ45 connector on the other end. are used but an SRM100 rack mounted safety switch with optional twisted pair port modules could be used so that the maximum of 16 CSLS can be attached. The shield on the CSLS RJ45 connector connects only to a Faraday cage in the CSLS. Build this cable assembly with a shielded. The SZ Controller completely isolates communications between the DeltaV Control Network and the Safety Network. not to the controller's DC ground. 100 m (maximum) straight-through or crossover cable. The metal connector end of this cable assembly must be placed on the switch and not on the PC. For network diagnostics for these switches. metal-enclosed RJ45 connector on one end and an isolated. metal-enclosed RJ45 connector on both ends. 100 meter (maximum) straight-through or crossover cable. 7 Attach the ground screw of the switch to a suitable ground for the cable shields. not to the CSLS DC ground. metal-enclosed RJ45 connector on both ends. The shield on the SZ controller's RJ45 connector connects only to a Faraday cage in the controller. which have a low port count. External cabling should never be used to connect these two independent systems together. Build this cable assembly with a shielded. No configuration of the safety switch is possible though the serial port. To prevent ground loops. Therefore. The switches are plug and play. metal-enclosed RJ45 connector on one end and an isolated. The LSN20 safety switches cannot be managed through the Smart Switch Command Center. the LSN20 switches. 100 m (maximum) straight-through or crossover cable. the RJ45 connectors are floating and the single point of ground is made at the switch to which the CSLS is connected. Therefore. 8 Attach the ground screw of the firewall to a suitable ground for the cable shields. In this example. . plastic-enclosed RJ45 connector on the other end. build this cable assembly with a shielded. the RJ45 connectors are floating and the single point of ground is made at the switch to which the controller is connected. you must attach an optional serial cable to the serial port of the safety switch and use an application such as Hyper-terminal to access the switch information.Networks in a CHARMs Smart Logic Solver SIS system Callout 1 2 3 4 5 6 100 meter (maximum) straight-through or crossover cable. To prevent ground loops. build this cable assembly with a shielded. The metal connector end of this cable assembly must be placed on the switch and not on the PC. The RM100 Smart Switches are managed through the DeltaV console using Smart Switch Command Center. 9 10 102 Description Up to 16 CHARMs Smart Logic Solvers (CSLS) can be connected within the Safety System architecture. vibration.2 to 150 Hz • Shock: 10g 1/2 sine wave for 11 ms • IP 20 rating 103 .04-1985 Airborne Contaminants Class G3 • Vibration: 1mm Peak-to-Peak from 2 to 13. and shock specifications for CSLS SIS hardware • Airborne contaminants: ISA-S71. vibration.2 Hz. and shock specifications for CSLS SIS hardware Temperature and humidity specifications for CSLS SIS hardware Operating temperature range Storage temperature range Relative humidity CSLS -40°C to 70°C (-40°F to 158°F) -40°C to 85°C (-40°F to 185°F) 5 to 95% non-condensing CSLS carrier -40°C to 70°C (-40°F to 158°F) -40°C to 85°C (-40°F to 185°F) 5 to 95% non-condensing CSLS Power Module -40°C to 70°C (-40°F to 158°F) -40°C to 85°C (-40°F to 185°F) 5 to 95% non-condensing LS CHARMs -40°C to 70°C (-40°F to 158°F) -40°C to 85°C (-40°F to 185°F) 5 to 95% non-condensing Ethernet Isolation Ports -40°C to 70°C (-40°F to 158°F) -40°C to 85°C (-40°F to 185°F) 5 to 95% non-condensing Safety Network Ports -40°C to 70°C (-40°F to 158°F) -40°C to 85°C (-40°F to 185°F) 5 to 95% non-condensing SZ Controller -40°C to 70°C (-40°F to 158°F) -40°C to 85°C (-40°F to 185°F) 5 to 95% non-condensing SZ Controller carrier -40°C to 70°C (-40°F to 158°F) -40°C to 85°C (-40°F to 185°F) 5 to 95% non-condensing Device Contaminants.Environmental specifications for CHARMs Smart Logic Solver hardware 6 Environmental specifications for CHARMs Smart Logic Solver hardware Topics covered in this chapter: • • Temperature and humidity specifications for CSLS SIS hardware Contaminants. 0.7g from 13. Environmental specifications for CHARMs Smart Logic Solver hardware 104 . S.) CHARM KL3302X1-BA1 LS DO 24 VDC DTA CHARM KL3302X1-BB1 LS DO 24 VDC (Redundant DTA) CHARM KL3302X1-BC1 LS DO 24 VDC ETA CHARM KL3302X1-BD1 LS DO 24 VDC (Redundant ETA) CHARM KL3322X1-BA1 LS DVC HART DTA CHARM KL3322X1-BB1 LS DVC HART (Redundant DTA) CHARM KL4001X1-BA1 SZ Controller Carrier 105 . S.) CHARM KL3106X1-LS1 LS RTD / Resistance input (I.) CHARM KL3103X1-LS1 LS DI NAMUR (I.Product type numbers for CHARMs Smart Logic Solver SIS hardware 7 Product type numbers for CHARMs Smart Logic Solver SIS hardware Product type numbers for CHARMs Smart Logic Solver SIS hardware Table 7-1: CHARMs Smart Logic Solver SIS hardware products cross referenced to product type numbers Product type number Product name KL1501X1-BA1 CHARMs Smart Logic Solver Power Module KL1603X1-BA1 Safety Network Port (copper) KL1604X1-BA1 Ethernet Isolation Port (copper) KL2001X1-BA1 CHARMs Smart Logic Solver KL2001X1-BB1 SZ Controller KL3001X1-LS1 LS DI NAMUR CHARM KL3003X1-LS1 LS DI 24 VDC low-side (dry contact) CHARM KL3005X1-LS1 LS DI 24 VDC isolated CHARM KL3007X1-LS1 LS 24 VDC Power CHARM KL3011X1-LS1 LS DI 120 VAC isolated CHARM KL3012X1-LS1 LS DI 230 VAC isolated CHARM KL3021X1-LS1 LS AI 4-20 mA HART CHARM KL3023X1-LS1 LS AI 0-10 VDC isolated CHARM KL3031X1-LS1 LS RTD / Resistance input CHARM KL3032X1-LS1 LS Thermocouple / mV input CHARM KL3101X1-LS1 LS AI 4-20 mA HART (I.S.S.) CHARM KL3105X1-LS1 LS Thermocouple / mV input (I. Product type numbers for CHARMs Smart Logic Solver SIS hardware Table 7-1: CHARMs Smart Logic Solver SIS hardware products cross referenced to product type numbers (continued) 106 Product type number Product name KL4103X1-BA1 CHARMs Smart Logic Solver Carrier KL4505X1-BA1 Redundant Terminal Block KL4505X1-CA1 Redundant DVC Terminal Block KL4505X1-DA1 Redundant ETA Relay Terminal Block KL4505X1-EA1 Redundant DTA Relay Terminal Block KL4505X1-FA1 Redundant DVC Terminal Block KL4505X1-GA1 Redundant DTA Injected Power Relay Terminal Block . See CHARMs Smart Logic Solver Carrier D DeltaV Area Control Network 93 DeltaV Local Safety Network example twisted pair network with RM100 and FP20 switches 97 Discrete LS input and oupt CHARMs LEDs 85 DVC terminal block 33. 31 CHARMs Smart Logic Solver Carrier specifications 8. 53 LS DI 24 VDC isolated CHARM 48. 48 LS DI 120 VAC isolated CHARM 50. 48 wiring diagram 47. CHARM terminal block 31. 17 CHARM Fused Injected Power terminal block 29. 72 LS DO 24 VDC (Redundant ETA) CHARM 70. 17 specifications 16. 46 specifications 45. 81 specifications 80. 48 specifications 47.S. 72 LS DO 24 VDC ETA CHARM 70. 46 LS AI 4-20 mA HART (I. 51 LS DI 230 VAC isolated CHARM 52. 72 LS DO 24 VDC DTA CHARM 70. 17 LS 24 VDC Power CHARM 80. 81 wiring diagram 80. 30 CHARM terminal block 27.S. 48 LS CHARM address terminal 34.S. 28 CHARM Thermocouple / mV terminal block 30.S. 5 CHARMs Smart Logic Solvers LEDs 87 specifications 2. CHARM Thermocouple / mV terminal block 32. 69 LS Thermocouple / mV input CHARM 59–61 Address Plug 22 Analog LS input and output CHARMs LEDs 83 C CHARM Baseplates installation notes 16. 33 installation notes CHARM Baseplates 16. 81 LS AI 0-10 VDC isolated CHARM 45. 49 LS DI 24 VDC low-side (dry contact) CHARM 53–55 LS DI NAMUR (I. 9 CHARMs Smart Logic Solver Power Module 4. See CHARMs Smart Logic Solvers CSLS Carrier.) CHARM 61–63 L LEDs Analog LS input and output CHARMs 83 CHARMs Smart Logic Solvers 87 Discrete LS input and output CHARMs 85 Ethernet Isolation port 90 Safety Network Port 88 SZ controllers 90 Local Safety Network 93 LS 24 VDC Power CHARM installation notes 80. 81 LS AI 0-10 VDC isolated CHARM installation notes 45. 67 LS Thermocouple / mV input (Intrinsically Safe) CHARM 68. 46 LS AI 4-20 mA HART (I.) CHARM 63–65 LS DI NAMUR CHARM 55–57 LS DO 24 VDC (Redundant DTA) CHARM 70. 32 I.Index Index A LS AI 4-20 mA HART CHARM 47. 59 LS RTD / Resistance input (Intrinsically Safe) CHARM 65.) CHARM installation notes 61–63 specifications 61–63 wiring diagram 61–63 LS AI 4-20 mA HART CHARM installation notes 47. 3 Column extenders top and bottom 23–25 CSLS. 46 wiring diagram 45. 34 E Ethernet Isolation port LEDs 90 I I. 35 107 .S. 72 LS DVC HART (Redundant DTA) CHARM 77–79 LS DVC HART DTA CHARM 77–79 LS RTD / Resistance CHARM 57. 49 wiring diagram 48. 49 LS DI 24 VDC low-side (dry contact) 53–55 LS DI NAMUR 55–57 LS DI NAMUR (Intrinsically Safe) 63–65 LS DO 24 VDC (Redundant DTA) 70. 53 LS DI 24 VDC isolated CHARM installation notes 48. 72 specifications 70. 49 LS DI 24 VDC low-side (dry contact) CHARM installation notes 53–55 specifications 53–55 wiring diagram 53–55 LS DI NAMUR (I. 69 specifications 68. 53 LS DI 24 VDC isolated 48.) CHARM installation notes 63–65 specifications 63–65 wiring diagram 63–65 LS DI NAMUR CHARM installation notes 55–57 specifications 55–57 wiring diagram 55–57 LS DO 24 VDC (Redundant DTA) installation notes 70. 72 LS DVC HART (Redundant DTA) installation notes 77–79 specifications 77–79 wiring diagram 77–79 LS DVC HART DTA installation notes 77–79 specifications 77–79 wiring diagram 77–79 LS RTD / Resistance CHARM installation notes 57. 72 specifications 70. 46 LS AI 4-20 mA HART 47. 72 wiring diagram 70. 38 Redundant DTA Relay terminal block 39. 67 specifications 65. 72 wiring diagram 70. 67 LS Thermocouple / mV input (Intrinsically Safe) CHARM installation notes 68. 72 108 LS DO 24 VDC (Redundant ETA) installation notes 70.S. 95 P Power Module specifications 4. 36 . 72 LS DO 24 VDC ETA installation notes 70. 59 LS RTD / Resistance input (Intrinsically Safe) CHARM installation notes 65. 72 wiring diagram 70. 72 specifications 70. 81 LS AI 0-10 VDC isolated 45. 67 LS Thermocouple / mV input 59–61 LS Thermocouple / mV input (Intrinsically Safe 68. 49 specifications 48. 67 wiring diagram 65. 40 Redundant DVC terminal block 42 Redundant ETA Relay terminal block 40. 53 wiring diagram 52. 72 wiring diagram 70. 72 LS DO 24 VDC (Redundant ETA) 70. 72 LS DO 24 VDC DTA 70. 59 specifications 57. 59 LS RTD / Resistance input (Intrinsically Safe) 65. 48 LS AI 4-20 mA HART (Intrinsically Safe) 61–63 LS DI 120 VAC isolated 50. 53 specifications 52. 51 wiring diagram 50. 5 product type numbers for CSLS SIS hardware 105 R Redundant DTA Injected Power Relay terminal block 37. 51 LS DI 230 VAC isolated 52. 69 LS Thermocouple / mV input CHARM installation notes 59–61 specifications 59–61 wiring diagram 59–61 LSN20 Safety Switches 94. 69 wiring diagram 68.Index LS CHARM Column Extenders top and bottom 23–25 LS CHARMs LS DVC HART (Redundant DTA) 77–79 LS DVC HART DTA 77–79 LS 24 VDC Power 80. 72 LS DO 24 VDC DTA installation notes 70. 69 LS DI 120 VAC isolated CHARM installation notes 50. 51 specifications 50. 72 LS RTD / Resistance 57. 41 Redundant terminal block 35. 51 LS DI 230 VAC isolated CHARM installation notes 52. 72 LS DO 24 VDC ETA 70. 59 wiring diagram 57. 72 specifications 70. 81 LS AI 0-10 VDC isolated CHARM 45. 69 LS Thermocouple / mV input CHARM 59–61 SZ Controller 6. 49 LS DI 24 VDC low-side (dry contact) CHARM 53–55 LS DI NAMUR (I. 38 Redundant DTA Relay 39. 36 Top and bottom LS CHARM Column Extenders 23–25 W wiring diagrams LS 24 VDC Power CHARM 80.Index S T Safety Network Port LEDs 88 Safety Network Ports reset Safety Network Ports 11 resetting 11 SIS Controller. 40 Redundant DVC 42 Redundant ETA Relay 40. 41 Redundant terminal block Relay 35. 3 LS 24 VDC Power CHARM 80. 32 I. 72 LS DVC HART (Redundant DTA) CHARM 77–79 LS DVC HART DTA CHARM 77–79 LS RTD / Resistance CHARM 57. 72 LS DO 24 VDC (Redundant ETA) CHARM 70.) CHARM 63–65 LS DI NAMUR CHARM 55–57 LS DO 24 VDC (Redundant DTA)CHARM 70. 7 terminal blocks CHARM Fused Injected Power 29.S. 34 I.S. 51 LS DI 230 VAC isolated CHARM 52. 53 LS DI 24 VDC isolated CHARM 48. 72 LS DO 24 VDC ETA CHARM 70.S. 9 CHARMs Smart Logic Solver Power Module 4. 53 LS DI 24 VDC isolated CHARM 48. CHARM Thermocouple / mV terminal block 32. CHARM terminal block 31. 33 Redundant DTA Injected Power Relay 37. 72 LS DO 24 VDC (Redundant ETA) CHARM 70. 81 LS AI 0-10 VDC isolated CHARM 45. 5 CHARMs Smart Logic Solvers 2. 72 LS DO 24 VDC ETA CHARM 70. 46 LS AI 4-20 mA HART (I. 67 LS Thermocouple / mV input (Intrinsically Safe) CHARM 68. 67 LS Thermocouple / mV input (Intrinsically Safe) CHARM 68.) CHARM 61–63 LS AI 4-20 mA HART CHARM 47. 49 LS DI 24 VDC low-side (dry contact) CHARM 53–55 LS DI NAMUR (I. 7 SZ Controller Carrier 12. 59 LS RTD / Resistance input (Intrinsically Safe) CHARM 65. 28 CHARM Thermocouple / mV terminal block 30.S.S. 59 LS RTD / Resistance input (Intrinsically Safe) CHARM 65. 48 LS DI 120 VAC isolated CHARM 50. 13 SZ Controller specifications 6.S. 72 LS DO 24 VDC DTA CHARM 70. 69 LS Thermocouple / mV input CHARM 59–61 109 . 13 SRM100 Safety Switch 96 SZ controller LEDs 90 SZ Controller Carrier specifications 12. 30 CHARM terminal block 27. 51 LS DI 230 VAC isolated CHARM 52.) CHARM 61–63 LS AI 4-20 mA HART CHARM 47. 72 LS DVC HART (Redundant DTA) CHARM) 77–79 LS DVC HART DTA CHARM 77–79 LS RTD / Resistance CHARM 57. 46 LS AI 4-20 mA HART (I. 17 CHARMs Smart Logic Solver Carrier 8. See SZ Controller specifications CHARM Baseplates 16. 31 DVC 33. 48 LS DI 120 VAC isolated CHARM 50. 72 LS DO 24 VDC DTA CHARM 70.) CHARM 63–65 LS DI NAMUR CHARM 55–57 LS DO 24 VDC (Redundant DTA)CHARM 70.
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