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74-2699

CONTENTS

Table of Contents

Introduction

...........................................................................................................................

Description of Devices .......................................................................................

4

Control Application .............................................................................................

5

Control Provided.................................................................................................

5

Products Covered...............................................................................................

6

Organization of Manual ......................................................................................

6

Applicable Literature ..........................................................................................

6

Product Names ..................................................................................................

6

Agency Listings ..................................................................................................

7

Abbreviations and Definitions.............................................................................

7

Construction .......................................................................................................

9

Controllers .....................................................................................................

9

Performance Specifications ...................................................................... 12

Wall Modules................................................................................................. 15

Configurations .................................................................................................... 16

Mixed-Output-Type Control ........................................................................... 17
Occupancy Sensor ........................................................................................ 17
Window Open/Closed Digital Input................................................................ 17
Wall Module Options ..................................................................................... 17
Dirty Filter Monitor ......................................................................................... 17
Indoor Air Quality (IAQ) Override................................................................... 17

Application Steps

...........................................................................................................................

Overview ............................................................................................................ 18
Step 1. Plan The System.................................................................................... 18
Step 2. Determine Other Bus Devices Required................................................ 19
Step 3. Lay Out Communications and Power Wiring ......................................... 19

E-Bus Layout ................................................................................................. 19
Power Wiring ................................................................................................. 21

Power Budget Calculation Example:......................................................... 21
Line Loss: ................................................................................................. 22

Step 4. Prepare Wiring Diagrams ...................................................................... 24

General Considerations................................................................................. 24
W7761A Devices........................................................................................... 24
E-Bus Termination Module ............................................................................ 30

Step 5. Order Equipment.................................................................................... 33
Step 6. Configure Devices.................................................................................. 36
Step 7. Troubleshooting ..................................................................................... 36

Troubleshooting Excel 10 Controllers and Wall Modules .............................. 36
Temperature Sensor and Setpoint Potentiometer Resistance Ranges......... 36
Alarms ........................................................................................................... 36
Broadcasting the Service Message ............................................................... 37
W7761A Controller Status LEDs ................................................................... 37
T7780 DDWM Bypass Pushbutton................................................................ 38

List of Figures

...........................................................................................................................

2

Fig. 1. Typical system overview. ........................................................................

4

Fig. 2. Typical W7761A control application. .......................................................

5

Fig. 3. Excel 10 W7761A Remote I/O Device. ................................................... 10
Fig. 4. W7761A construction. ............................................................................. 11

Excel 10 W7761A Remote Input/Output

Device

Summary of Contents for W7761A

Page 1: ...17 Application Steps Overview 18 Step 1 Plan The System 18 Step 2 Determine Other Bus Devices Required 19 Step 3 Lay Out Communications and Power Wiring 19 E Bus Layout 19 Power Wiring 21 Power Budget Calculation Example 21 Line Loss 22 Step 4 Prepare Wiring Diagrams 24 General Considerations 24 W7761A Devices 24 E Bus Termination Module 30 Step 5 Order Equipment 33 Step 6 Configure Devices 36 Ste...

Page 2: ... Listings 7 Table 2 List Of Available Points 12 Table 3 Application Steps 18 Table 4 E Bus Configuration Rules And Device Node Numbers 19 Table 5 VA Ratings For Transformer Sizing 22 Table 6 Field Wiring Reference Table 24 Table 7 W7761A I O Description 25 Table 8 Excel 10 W7761A Device Ordering Information 33 Table 9 Excel 10 Alarms 37 Table 10 LED States 38 Appendices Appendix A Using E Vision f...

Page 3: ...C BUS COMMUNICATION NETWORK EXCEL 500 EXCEL BUILDING SUPERVISOR C BUS TO E BUS INTERFACE DEVICE EXCEL 10 W7751F PANEL PLENUM MOUNT VERSION VARIABLE AIR VOLUME CONTROLLER FTT E BUS COMMUNICATIONS NETWORK FTT E BUS COMMUNICATIONS NETWORK Q7751A FTT E BUS ROUTER EXCEL 10 T7770 WALL MODULE EXCEL 10 W7753A UNIT VENTILATOR CONTROLLER EXCEL 10 T7780 DIGITAL DISPLAY WALL MODULE M12884 EXCEL 10 W7750B CVAH...

Page 4: ... inputs and outputs but no control software All control that would be associated with the inputs and outputs in the W7761A would be accomplished though the Excel Zone Manager and would not be suitable for VAV control temperature control or any control function that would require less than a 30 second update rate Products Covered This System Engineering Guide describes how to apply the W7761A Excel...

Page 5: ...e setpoint and E Bus network connection for use with all Excel 5000 controllers except W7751A C E G T7770C Wall Module with temperature sensor current feature that can be used with the RIO Device setpoint Bypass button and LED and E Bus network connection for use with all Excel 5000 controllers except W7751A C E G T7770D Wall Module with temperature sensor current feature that can be used with the...

Page 6: ...mplies with requirements in FCC Part 15 rules for a Class B Computing Device Q7750A Excel 10 Zone Manager UL Tested and listed under UL916 file number S4804 QVAX PAZY CSA Listing pending FCC Complies with requirements in FCC Part 15 rules for a Class A Computing Device Operation in a residential area can cause interference to radio or TV reception and require the operator to take steps necessary t...

Page 7: ...ce between the C Bus and the E Bus The Excel 10 Zone Manager also has the functionality of an Excel 100 Controller but has no physical I O points NOTE The Q7750A Zone Manager can be referred to as E Link in the internal software CARE FCU Fan Coil Unit Firmware Software stored in a nonvolatile memory medium such as an EPROM Floating Control Refers to Series 60 Modulating Control of a valve or dampe...

Page 8: ...e UV W7761 The model number of the Excel 10 RIO Device also see RIO Wall Module The Excel 10 Space Temperature Sensor and other optional controller inputs are contained in the T7770 or T7780 Wall Modules See Application Step 5 Order Equipment for details on the various models of Wall Modules XBS Excel Building Supervisor a PC based tool for monitoring and changing parameters in C Bus devices Const...

Page 9: ...3 22 21 20 19 18 17 16 E G N D G N D 22 VD C OUT EBU S EBU S JAC K DI 4 W7761A C O M NOT U S E D NOT U S E D GND GND DI 3 DI 2 D I 1 VAC 24 VAC 24 OU T 1 OU T 2 OUT 3 O UT 4 OU T 5 OU T 6 O UT 7 O UT 8 AI 1 O H M AI 2 O H M AI 3 O H M G N D AI 4 O H M G N D AI 5 V m A AI 6 V m A Fig 3 Excel 10 W7761A Remote I O Device ...

Page 10: ... 24 23 22 21 20 19 18 17 16 C O M OU T 1 OU T 2 O U T 3 O U T 4 O U T 5 O U T 6 OU T 7 O U T 8 5 3 16 132 5 5 8 143 3 1 16 77 2 1 8 54 6 152 M 6856 NOT USED NOT USED E G N D AI 1 O H M G N D AI 2 O H M AI 3 O H M G N D AI 4 O H M G N D AI 5 V m A AI 6 V m A VA C 24 VA C 24 D I 1 G N D G N D D I 2 D I 3 D I 4 Fig 4 W7761A construction in in mm ...

Page 11: ...60 Hz The W7761A power consumption is 6 VA maximum at 50 or 60 Hz The W7761A is a NEC Class 2 rated device This listing imposes limits on the amount of power the product can consume or directly control to a total of 100 VA U S only The individual Triac outputs incorporate an internal common connection with the input power transformer The Triacs provide a switched path from the hot side R of the tr...

Page 12: ...312 ft 400m In the event that the total wire length is exceeded then a Q7740A 2 Way Repeater or a Q7740B 4 Way Repeater can be used to allow the number of devices to be spread out as well as increasing the length of wire over which they communicate The maximum number of repeaters per segment is one on either side of the router A Q7751A E Bus Router can also be used to effectively double the maximu...

Page 13: ... to 10V C7600C1008 4 to 20mA Outdoor Air Enthalpy Type Current Supported Sensors C7400A1004 4 to 20mA Return Air Enthalpy Type Current Supported Sensors C7400A1004 4 to 20mA Air Filter Differential Pressure Type Voltage Supported Sensors Third party 2 to 10V 0 to 5 inw 0 to 1 25 kPa differential pressure sensors Space CO2 Sensor Type Voltage Supported Sensors Third party 0 to 10V 0 to 2000 ppm CO2...

Page 14: ...xcel 10 W7761A RIO Device See Fig 6 STANDARD UTILITY CONDUIT BOX 2 X 4 MOUNTING HOLES KNOCKOUTS FOR EUROPEAN APPLICATIONS 3 5 32 80 2 3 8 60 29 32 23 5 1 16 128 2 3 8 60 T7770A1006 M15119 STANDARD UTILITY CONDUIT BOX 2 X 4 MOUNTING HOLES KNOCKOUTS FOR EUROPEAN APPLICATIONS 3 5 32 80 2 3 8 60 1 1 4 32 5 1 16 128 2 3 8 60 T7770C 70 65 60 55 85 80 75 DIP Switch S4 Settings 1 3 5 on 2 4 off 2 4 on 1 3...

Page 15: ...uld be accomplished though the Excel Zone Manager and would not be suitable for VAV control temperature control or any control function that would require less than a 30 second update rate It would be suitable to control miscellaneous exhaust or ventilation fans lighting zones that are spread out through a building which need to be linked to a start stop time program through the Zone Manager or to...

Page 16: ...4 Prepare Wiring Diagrams for details or a set of contacts wired in series for monitoring multiple windows to verify that the window s are closed This window s sensor can then be bound to other Excel 10 controllers on the E Bus or Excel 5000 controllers on the C Bus through the Excel 10 Zone Manager The algorithm in the other Excel 10 controllers expects a contact closure to indicate the window is...

Page 17: ...low a CARE E Vision operator terminal to have access to the E Bus The application engineer needs to determine how many wall modules or other input sensors are required This information is required during installation to ensure that the proper number and type of wires are pulled to the wall modules and the building operators are informed about where they can plug in to the E Bus network with a port...

Page 18: ...des Only T7780 Wall Modules are E Bus nodes Maximum number of Excel 10s and T7780s in segment number two 60 nodes Only T7780 Wall Modules are E Bus nodes Total 125 nodes Refer to the E Bus Wiring Guidelines form 74 2865 for complete description of network topology rules and the maximum wire length limitations If longer runs are required a Q7740A 2 way or Q7740B 4 way repeater can be added to exten...

Page 19: ...ed These cables contain two twisted pairs one for the run down to the wall module and one for the run back up to the controller for ease of installation 0 9 9 9 9 5 2 5 2 5 2 89 9 9 9 9 9 9 4 77 21 0 1 5 72 86 6 86 86 86 83 72 727 12 6 7 7 7 7 7 25 23 5 725 7 50 1 6 5 7 7 50 1 7 21 02 8 6 7 1 6 2 86 6 1 7 V 7 12 86 66 86 2 211 7 216 89 Fig 9 Bus wiring layout for doubly terminated daisy chain E Bu...

Page 20: ...in the same conduit as the E Bus cable Do not use different wire types or gauges on the same E Bus segment The step change in line impedance characteristics causes unpredictable reflections on the bus When using different types is unavoidable use a Q7751A Router at the junction In noisy high EMI environments avoid wire runs parallel to noisy power cables or lines containing lighting dimmer switche...

Page 21: ... resistance in wire ohms per ft x current in wire amperes From specification data 18 AWG twisted pair wire has 6 52 ohms per 1000 feet Loss 200 ft x 2 round trip x 6 52 1000 ohms per ft x 37 VA 24V 4 02 volts This means that four volts are going to be lost between the transformer and the device therefore to assure the device receives at least 20 volts the transformer must output more than 24 volts...

Page 22: ...transformer meets the NEMA standard DC20 1986 the transformer voltage regulating ability can be considered reliable Compliance with the NEMA standard is voluntary The following Honeywell transformers meet this NEMA standard Transformer Type VA Rating AT20A 20 AT40A 40 AT72D 40 AT87A 50 AK3310 Assembly 100 27 26 25 24 23 22 21 20 19 18 17 16 15 14 0 50 100 150 OF LOAD SECONDARY VOLTAGE 200 M993 Fig...

Page 23: ...ld wiring must conform to local codes and ordinances To maintain NEC Class 2 and UL ratings the installation must use transformers of 100 VA or less capacity For multiple controllers operating from a single transformer the same side of the transformer secondary must be connected to the same input terminal in each device and the ground terminals 1 on the W7761A must be connected to a verified earth...

Page 24: ...d conductor nonshielded or Echelon approved shielded cable Level IV 140 F 60 C rating Honeywell AK3791 one twisted pair AK3792 two twisted pairs Refer to E Bus Wiring Guidelines for maximum length E Bus Non Plenum 22 AWG 0 34 mm2 Twisted pair solid conductor nonshielded or Echelon approved shielded cable Level IV 140 F 60 C rating Honeywell AK3781 one twisted pair AK3782 two twisted pairs Refer to...

Page 25: ...7 Digital Output 7 OUT 6 18 Digital Output 6 OUT 5 19 Digital Output 5 OUT 4 20 Digital Output 4 OUT 3 21 Digital Output 3 OUT 2 22 Digital Output 2 OUT 1 23 Digital Output 1 24Vac H 25 Power for the device COM N 24 Return for power to device E Bus 15 Echelon communications screw terminals E Bus 14 Echelon communications screw terminals DI 4 31 Digital Input 4 DGND 30 Digital Ground DI 3 29 Digita...

Page 26: ...IRE TO ASSURE PROPER ELECTRICAL CONTACT WIRES MUST BE TWISTED TOGETHER BEFORE INSERTION INTO THE TERMINAL BLOCK E BUS E GND GND GND GND NOT USED NOT USED AI 1 OHM AI 2 OHM 9 10 11 12 14 J3 15 31 30 29 28 27 26 25 24 23 22 21 20 24 VAC COM E BUS JACK 22 VDC OUT 19 18 17 16 AI 3 OHM AI 4 OHM AI 6 V mA OUT 7 OUT 6 OUT 5 OUT 4 OUT 8 OUT 1 OUT 3 OUT 2 AI 5 V mA 13 DI 2 DI 4 DI 1 DI 3 M15276 GND GND TRI...

Page 27: ... 2 AI 5 V mA DI 2 DI 4 DI 1 DI 3 AI 4 OHM AI 6 V mA AI 2 OHM AI 1 OHM NOT USED COM 24 VAC 24 VA C EARTH GROUND WIRE LENGTH SHOULD BE HELD TO A MINIMUM USE THE HEAVIEST GAUGE WIR E AVAILABLE UP TO 14 AWG 2 O MM2 WITH A MINIMUM OF 18 AWG 1 O MM2 F OR EAR TH GROUND WIRE TO ASSURE PROPER ELECTRICAL CONTACT WIRES MUST BE TWISTED TOGETHER BEFORE INSERTION INTO THE TERMINAL BLOCK 1 2 24 VAC 2 S C7600C S ...

Page 28: ...TOGETHER BEFORE INSERTION INTO THE TERMINAL BLOCK E BUS E GND GND GND GND NOT USED NOT USED AI 1 OHM AI 2 OHM 9 10 11 12 14 J3 15 31 30 29 28 27 26 25 24 23 22 21 20 24 VAC COM E BUS JACK 22 VDC OUT 19 18 17 16 AI 3 OHM AI 4 OHM AI 6 V mA OUT 7 OUT 6 OUT 5 OUT 4 OUT 8 OUT 1 OUT 3 OUT 2 AI 5 V mA 13 DI 2 DI 4 DI 1 DI 3 M15277 GND GND TRIAC EQUIVALENT CIRCUIT 24 VAC OCCUPANCY SENSOR CONTACT CLOSED O...

Page 29: ... INTO THE TERMINAL BLOCK E BUS E GND GND GND GND NOT USED NOT USED AI 1 OHM AI 2 OHM 9 10 11 12 14 J3 15 31 30 29 28 27 26 25 24 23 22 21 20 24 VAC COM E BUS JACK 22 VDC OUT 19 18 17 16 AI 3 OHM AI 4 OHM AI 6 V mA OUT 7 OUT 6 OUT 5 OUT 4 OUT 8 OUT 1 OUT 3 OUT 2 AI 5 V mA 13 DI 2 DI 4 DI 1 DI 3 M15279 GND GND TRIAC EQUIVALENT CIRCUIT 24 VAC 24 H 24 N PWM H 24 VAC PWM OUTPUT FROM CNTRL ML7984B T6 T5...

Page 30: ...IRE AVAILABLE UP TO 14 AWG 2 O MM2 WITH A MINIMUM OF 18 AWG 1 O MM2 FOR EARTH GROUND WIRE REVERSE WIRES INCREASE DECREASE TO REVERSE ACTION DIRECT REVERSE MAKE SURE ALL TRANSFORMER POWER WIRING IS AS SHOWN REVERSING TERMINATIONS WILL RESULT IN EQUIPMENT MALFUNCTION OPTIONAL 24 VAC WIRING TO NEXT CONTROLLER USE 1 4 IN 6 MM PNEUMATIC TUBING MINIMUM BRANCH LINE MUST BE 6 FT 1 8M OR LONGER PNEUMATIC V...

Page 31: ... PART NO 209541B TERMINATION MODULE W7753A 1415 1415 W7753A 1415 W7753A BROWN BROWN ORANGE ORANGE Fig 21 Typical E Bus termination module wiring diagrams place a wire nut on each remaining wire that is not connected to a controller or device See Fig 22 for E Bus termination wiring options ...

Page 32: ...0 1 6 1 7 7 86 5 7 50 1 7 21 02 8 6 3 6 2 7 1 7 7 16 7 25 00 2 4 86 5287 5 86 86 1 7 3 57 12 7 50 1 7 21 02 8 3 57 12 7 50 1 7 21 02 8 3 57 12 7 50 1 7 21 02 8 2 2 2 2 6 7 6 21 6 81 5 4 5 2 5 86 60 7 2 7 72 029 7 6 7 6 6 1 520 326 7 21 2 12 7 50 1 7 21 326 7 21 6 1 7 50 1 7 326 7 21 28 7 50 1 7 6 0 176 21 4 5 3 7 5 127 4 5 3 7 5 6 2 1 4 5 3 6 7 2 6 7 6 QDEOLQJ QWHUQDO 7HUPLQDWLRQ 1HWZRUN XVLQJ MXP...

Page 33: ...work Jack No Logo Relative Setpoint Sensor current feature that can be used with the RIO Device T7770B1038 Sensor with Setpoint and Network Jack No Logo Degrees C Absolute Sensor current feature that can be used with the RIO Device T7770C1002 Sensor with Setpoint Bypass LED and Network Jack Honeywell Logo Degrees F Absolute Sensor current feature that can be used with the RIO Device T7770C1044 Sen...

Page 34: ...ule 1 megabit baud rate 209541B Termination Module One or two required per E Bus segment 205979 Operator Terminal Cable for E Bus Serial interface to wall module or controller Accessories EL7680A1008 Wall Mounted Wide View Infrared Occupancy Sensor EL7628A1007 Ceiling Mounted Infrared Occupancy Sensor EL7611A1003 EL7612A1001 Ultrasonic Occupancy Sensors EL7630A1003 EL7621A1002 EL7621A1010 Power Su...

Page 35: ...Direct Coupled Actuator 66 lb in Series 60 ML6474A1008 Direct Coupled Actuator 132 lb in torque Series 60 ML6185A1000 Direct Coupled Actuator 50 lb in spring return Series 60 V5812A Two way terminal unit water valve 0 19 0 29 0 47 0 74 1 2 and 1 9 Cv 1 2 in npt 13 mm or 2 9 and 4 9 Cv 3 4 in npt 19 mm Use with M6410 Valve Actuator Close off rating for 0 19 to 1 9 Cv is 65 psi for 2 9 and 4 9 Cv is...

Page 36: ...t and Test manual for each product See the Applicable Literature section for form numbers Temperature Sensor and Setpoint Potentiometer Resistance Ranges The T7770 Wall Module or the C7770A Air Temperature Sensor has the following specified calibration points which are plotted in Fig 23 Temperature F Resistance Value ohms 99 11 520 85 16 301 70 24 039 55 36 280 45 48 000 TEMPERATURE DEGREES oF 30 ...

Page 37: ... below SENSOR_FAILURE 3 One or more sensors have failed NOTE The node can be reset by switching the node to MANUAL and then to the normal operating mode Also the Excel 10 variables AlarmLogX where X is 1 through 5 that store the last five alarms to occur in the device are available These points can be viewed through XBS or E Vision Broadcasting the Service Message The Service Message allows a devi...

Page 38: ...ROUN D D11 24 VAC COM OUT 1 OUT 2 OUT 3 OUT 4 OUT 5 OUT 6 OUT 7 OUT 8 STATUS LED W7750 Fig 25 LED location on W7761A T7780 DDWM Bypass Pushbutton See Fig 26 for the T7780 DDWM bypass pushbutton location occupied or unoccupied The T7780 DDWM has two methods for generating its neuron ID shorting two pads or winking 1 Pressing the bypass pushbutton whenever a Carat on the bottom of the LCD display is...

Page 39: ... user guide form 74 2588 When calibrating voltage current sensors on the W7761A the offset amount entered by the user is in volts regardless of the inputs actual engineering units See Appendix E for information on how to derive the proper voltage value to enter as an offset during calibration CUSTOM MAPPING The RIO default CARE plant contains all available points that are supported on the RIO devi...

Page 40: ...0 controllers on the E Bus select the Network menu item and Refer Excel 10 Points Select the RIO device name as the Source Excel 10 and then scroll down the list of Excel 10 Points until you reach CurrentAI and select it Select an Excel 10 controller from the Destination Excel 10 list For example if the user had selected a CVAHU controller from the Destination Excel 10 list the user would select f...

Page 41: ...d a software point pseudo analog that can be mapped to the actual hardware output through the Custom Mapping function of E Vision The following procedure will instruct the user on adding the pseudo analog and using the Custom Mapping function so that the Digital Output can be used in the Zone Manager control strategy or switching logic or be used with Excel 5000 controllers on the C Bus 1 With CAR...

Page 42: ...t and the CPU address set by the XI581 Emulation function Applications XI581 Emulation menu Select the Utilities File Transfer menu items and select Download The Download dialog box will be displayed Check the All selection and click the Controller button When the Select Controller Subsystem dialog box is displayed make sure that the correct CPU address or name is highlighted and select the OK but...

Page 43: ...propriate digital outputs Pulse Width Modulating PWM Control The Excel 10 W7761A device can drive a PWM type actuator to control a modulating actuator The W7761A device contains no control software so these outputs would have to be bound to either the Zone Manager or other Excel 10 controllers PWM control positions the actuator based on the length in seconds of the pulse from the digital output Th...

Page 44: ...tion Mappable The point can be converted into a C Bus point used by C Bus devices A mappable point has a one to one relationship with a C Bus User Address Direct Access The point is accessible through the Subsystem Points mechanism in XBS E Vision Monitor These points are viewable within the E Vision Controller Monitoring on line screen PAR refers to control parameters that are set in the Applicat...

Page 45: ...ncirioIoSelect ResistiveIn1 See AI1RType Eng Units States column for selections Unused_Res_AI AI3RType ncirioIoSelect ResistiveIn2 See AI1RType Eng Units States column for selections Unused_Res_AI AI4RType ncirioIoSelect ResistiveIn3 See AI1RType Eng Units States column for selections Unused_Res_AI AI5VType ncirioIoSelect VoltageIn0 RA_Hum_C7600C OA_Hum_C7600C Filter_Diff_Pres RA_Hum_C7600B OA_Hum...

Page 46: ...physical analog input sensor channel according to the enumerated list shown in the Eng Units States column X X AI2RType Refer to the description for AI1RType X X AI3RType Refer to the description for AI1RType X X AI4RType Refer to the description for AI1RType X X AI5VType specifies which logical voltage or current sensor is assigned to which physical analog input sensor channel according to the en...

Page 47: ...DestOut3Cmd nviRemoteCmd 2 percent 163 to 163 0 DestOut4Cmd nviRemoteCmd 3 percent 163 to 163 0 DestOut5Cmd nviRemoteCmd 4 percent 163 to 163 0 DestOut6Cmd nviRemoteCmd 5 percent 163 to 163 0 DestOut7Cmd nviRemoteCmd 6 percent 163 to 163 0 DestOut8Cmd nviRemoteCmd 7 percent 163 to 163 0 DI1Sel1Type ncirioIoSelect DigitalIn0S1 Active_Short Active_Open Unused_DigInput 0 1 255 Unused_DigInput DI2Sel1...

Page 48: ...ioIoSelect is discribed below RIO is receiving a command to DestOut4Cmd This can be mapped as one of the three output types Discrete Modulate Float_Open or Float_Close by DO3Type If the user selects an enumerated value of Discrete2 for DO3Type this value would be stored in DO2 Then the DestOut4Cmd will command DO2 X X X M DestOut2Cmd Refer to the description for DestOut1Cmd X X X M DestOut3Cmd Ref...

Page 49: ...2Type Eng Units States column for selections Maintained DI3Sel2Type ncirioIoSelect DigitalIn2S2 See DI1Sel2Type Eng Units States column for selections Maintained DI4Sel2Type ncirioIoSelect DigitalIn3S2 See DI1Sel2Type Eng Units States column for selections Maintained DO1Type ncirioIoSelect DigitalOut0 Discrete1 Discrete2 Discrete3 Discrete4 Discrete5 Discrete6 Discrete7 Discrete8 Modulate1 Modulat...

Page 50: ...el1Type X X DI1Sel2Type specifies the sensor type and function connected to DigitalIn0S2 through DigitalIn3S2 The valid enumerated list of logical digital states for DI1Sel2Type is listed in the Eng Units States column X X DI2Sel2Type Refer to the description for DI1Sel2Type X X DI3Sel2Type Refer to the description for DI1Sel2Type X X DI4Sel2Type Refer to the description for DI1Sel2Type X X DO1Typ...

Page 51: ... ncirioIoSelect DigitalOut4 Refer to the Eng Units States column for DO1Type for selections available Unused_DigOutput DO6Type ncirioIoSelect DigitalOut5 Refer to the Eng Units States column for DO1Type for selections available Unused_DigOutput DO7Type ncirioIoSelect DigitalOut6 Refer to the Eng Units States column for DO1Type for selections available Unused_DigOutput DO8Type ncirioIoSelect Digita...

Page 52: ...z is 1 the power supply frequency is Fifty Hz and when FiftySixtyHz is 0 the power supply frequency is Sixty Hz X X X M SrcCO2Level is an output network variable corresponding to the voltage or current input channel AI5 or AI6 if the selection for a CO2 sensor was made via ncirioIoSelect X X X M SrcCurrentAI is an output network variable corresponding to the voltage or current input channel AI5 or...

Page 53: ...n ST_NUL SrcDigIn4Sts nvoRemoteDigIn 3 DI4Value 0 to 255 0 nvoRemoteDigIn 3 DI4State Refer to the DI1State enumerated list shown in the Eng Units States column ST_NUL SrcHumidAI5 nvoRemoteHum 0 percent 163 to 163 0 SrcHumidAI6 nvoRemoteHum 1 percent 163 to 163 0 SrcPressAI5 nvoRemotePres 0 inw 131 5 to 131 5 kPa 32 768 to 32 767 0 SrcPressAI6 nvoRemotePres 1 inw 131 5 to 131 5 kPa 32 768 to 32 767...

Page 54: ...k variable corresponding to the voltage or current input channel AI5 if the selection for a pressure sensor was made via ncirioIoSelect for AI5 X X X M SrcPressAI6 is an output network variable corresponding to the voltage or current input channel AI6 if the selection for a pressure sensor was made via ncirioIoSelect for AI6 X X X M SrcTempAI1 is an output network variable corresponding to the ana...

Page 55: ... OUTPUT DEVICE 55 74 2699 Table C2 Control Parameters Left Engineering Units English Metric or Digital State or Value of User Address NvName Field Name States plus Range State Default nviInUse InUseNumber 0 to 65534 0xFFFF ...

Page 56: ... value meaning no other management nodes are already logged on and that a management node may log on to the node Then the management node writes a number 1 through 65534 to nviInUse and periodically writes the same value to indicate that the management node is still logged on If there are no writes made to nviInUse for approximately 60 seconds then the Excel 10 resets nviInUse to zero to automatic...

Page 57: ... nvoAlarmLog type0 Refer to the AlarmType enumerated list shown in the Eng Units States column NO_ALARM AlarmTypeLog1 nvoAlarmLog type1 Refer to the AlarmType enumerated list shown in the Eng Units States column NO_ALARM AlarmTypeLog2 nvoAlarmLog type2 Refer to the AlarmType enumerated list shown in the Eng Units States column NO_ALARM AlarmTypeLog3 nvoAlarmLog type3 Refer to the AlarmType enumera...

Page 58: ... and not being acknowledged the last alarm report entered into the AlarmTypeLog is the one that was not acknowledged See nvoAlarm and for related subjects type n specifies the alarm that was issued via nvoAlarm See nvoAlarm for the alarm types used in AlarmTypeLog The newest alarm is reported in type 0 and the oldest is reported in type 4 When a new entry is made to the log the oldest entry is los...

Page 59: ... 0 1 FALSE Errorbyte4 nvoError error_bit 0 Byte Offset 0 Bit Offset 3 ResSensor4Error AI4 FALSE TRUE 0 1 FALSE BugFixVer nroPgmVer BugVer 3 nroPgmVer NodeType RIO1 MajorVer nroPgmVer MajorVer 2 MinorVer nroPgmVer MinorVer 1 nroPgmVer NodeType 6 nvoStatus CommFailure FALSE TRUE 0 1 FALSE nvoStatus disabled FALSE TRUE 0 1 FALSE nvoStatus ElectricalFault FALSE TRUE 0 1 FALSE nvoStatus FailSelfTest FA...

Page 60: ...s read by a network management node to identify the node type The contents of nroPgmVer contain compatible model type information and is fixed at the time when the node software is compiled CommFailure This field is not supported and is set to 0 FALSE disabled disabled reports 1 if nvoIO mode is set to DISABLED_MODE or FACTORY_TEST mode Otherwise disabled is set to 0 ElectricalFault This field is ...

Page 61: ...ockedOut FALSE TRUE 0 1 FALSE nvoStatus ManualControl FALSE TRUE 0 1 FALSE nvoStatus MechanicalFault FALSE TRUE 0 1 FALSE nvoStatus ObjectId 0 TO 65535 0 nvoStatus OpenCircuit FALSE TRUE 0 1 FALSE nvoStatus OutOfLlimits FALSE TRUE 0 1 FALSE nvoStatus OutOfService FALSE TRUE 0 1 FALSE nvoStatus OverRange FALSE TRUE 0 1 FALSE nvoStatus SelfTestInProgress FALSE TRUE 0 1 FALSE nvoStatus UnableToMeasur...

Page 62: ... not supported and is set to 0 FALSE MechanicalFault This field is not supported and is set to 0 FALSE ObjectId is set to the current value of nviRequest object_id OpenCircuit This field is not supported and is set to 0 FALSE OutOfLlimits This field is not supported and is set to 0 FALSE OutOfService This field is not supported and is set to 0 FALSE OverRange This field is not supported and is set...

Page 63: ...me DeviceName ASCII Blanks nciApplVer Time1Jan70 seconds 0 nciApplVer VersionNumber 0 to 255 0 AILowLimit nciEUConvrtRes LowerLimitS7 degrees F 40 to 240 degrees C 40 to 116 0 AIOutputRHigh nciEUConvrtRes OutputResHighS7 degrees F 40 to 240 degrees C 40 to 116 0 AIOutputRLow nciEUConvrtRes OutputResLowS7 degrees F 40 to 240 degrees C 40 to 116 0 AIResHigh nciEUConvrtRes ResHigh Ohms 10 to 150000 0...

Page 64: ...you would enter the equivalent temperature of 45 0 degrees F 7 2 degrees C for the AIOutputRHigh value X M X AIOutputRLow This is the equivalent temperature degrees F degrees C value for the resistance entered for AIResLow Using the resistance example for AIResLow of 11 520 ohms you would enter the equivalent temperature of 99 0 degrees F 37 2 degrees C for the AIOutputRLow value X M X AIResHigh T...

Page 65: ...ltahum percent 0 to 163 0 DeltaP nciDelta deltapres inw 0 to 32 kPa 0 to 7 97 0 DeltaT1 nciDelta deltatemp 0 degrees F 0 to 256 degrees C 0 to 124 0 DeltaT2 nciDelta deltatemp 1 degrees F 0 to 256 degrees C 0 to 124 0 DeltaT3 nciDelta deltatemp 2 degrees F 0 to 256 degrees C 0 to 124 0 DeltaT4 nciDelta deltatemp 3 degrees F 0 to 256 degrees C 0 to 124 0 DeltaV nciDelta deltaVolt 0 to 10 5 volts 0 ...

Page 66: ... of nciRioSendT regardless of delta change X M P X DeltaCO2 Refer to the description for DeltaC X M P X DeltaH Refer to the description for DeltaC X M P X DeltaP Refer to the description for DeltaC X M P X DeltaT1 Refer to the description for DeltaC X M P X DeltaT2 Refer to the description for DeltaC X M P X DeltaT3 Refer to the description for DeltaC X M P X DeltaT4 Refer to the description for D...

Page 67: ... DO2PWMPeriod nciPWMConfig1 DO1 si_period_pwm seconds 0 0 to 3000 25 6 DO2PWMZero nciPWMConfig1 DO1 si_pnct_time seconds 0 0 to 3000 0 1 DO2PWMFull nciPWMConfig1 DO1 si_delta_time seconds 0 0 to 3000 25 5 DO3PWMPeriod nciPWMConfig1 DO2 si_period_pwm seconds 0 0 to 3000 25 6 DO3PWMZero nciPWMConfig1 DO2 si_pnct_time seconds 0 0 to 3000 0 1 DO3PWMFull nciPWMConfig1 DO2 si_delta_time seconds 0 0 to 3...

Page 68: ...position of the actuator output The actuator requires this signal pulse width sent once every period so that it knows that it is still connected to the controller and where the zero position starts The variable width delta_time portion is incremented in proportion to the signal percentage There are 255 increments available for example 0 1 second Thus the pulse width will be the minimum width perce...

Page 69: ...25 6 DO8PWMZero nciPWMConfig2 DO7 si_pnct_time seconds 0 0 to 3000 0 1 DO8PWMFull nciPWMConfig2 DO7 si_delta_time seconds 0 0 to 3000 25 5 Table C4 Configuration Parameters Right Continued Share SH Map MA Direct Access DA E Vision EV Calibrate C Monitor M Parameter P Schematic S Hardware Configuration HW Manual Point MN Test TS SH MA DA EV HW MN TS Comments X M X DO6PWMPeriod Refer to the descript...

Page 70: ...an application restart occurs If the mode was MANUAL and DestManMode is set to MODE_ENABLE the node then goes through application restart MODE_DISABLED sets the node into the DISABLED mode The alarm NODE_DISABLED is initiated and the physical outputs are turned off The physical inputs network variable inputs and network variable outputs are still functioning when the node is in the DISABLED mode M...

Page 71: ... D 1 to determine the number of Excel 10s that can be connected to the Zone Manager NOTE More than 60 Excel 10s requires a Router 4 Repeat for each Q7750A Excel 10 Zone Manager in a project 20 60 120 600 700 800 900 600 700 800 900 920 765 610 585 740 895 NUMBER OF C BUS POINTS EXCEL 10 MAPPED POINTS PLUS ZONE MANAGER POINTS OR LESS ADD ROUTER NUMBER OF EXCEL 10s C A NUMBER OF C BUS POINTS EXCEL 1...

Page 72: ...12 2 3159 08 20 6 7 3207 68 30 1 1 3256 28 40 4 4 3304 88 50 10 3353 48 60 15 6 3402 08 70 21 1 3450 68 80 26 7 3499 28 90 32 2 3547 88 100 37 8 3596 48 110 43 4 3645 08 120 49 3693 68 3050 3000 2950 2900 3100 3150 3200 3250 3300 3350 3400 3450 3500 3550 3600 3650 3700 3750 50 40 30 20 10 0 10 20 30 40 60 70 80 90 100 110 120 10 4 4 1 1 6 7 12 2 17 8 23 3 28 9 34 5 40 15 6 21 1 26 7 32 2 37 8 43 4...

Page 73: ... 1650 1600 1550 1500 1700 1750 1800 1850 1900 1950 2000 55 50 45 40 35 30 60 65 70 75 80 85 90 95 100 105 110 115120 OHMS F SENSOR RESISTANCE VERSUS TEMPERATURE M11960 23 9 21 1 18 3 15 6 12 8 10 7 2 4 4 1 7 1 1 26 7 29 4 32 2 35 40 6 46 1 37 8 43 3 48 9 C Fig E 2 Graph of Sensor Resistance versus Temperature Sensor Type T7770A B C D sensor current feature that can be used with the RIO Device and ...

Page 74: ...0K 40K 30K 20K 10K oC M5874A Fig E 3 Graph of Sensor Resistance versus Temperature Voltage Current Sensors Sensor Type C7600B1000 Decorative Wall Mount and C7600C1018 2 to 10V Sensor Use Humidity Table E 4 lists the points for Sensor Voltage versus Humidity Fig E 4 shows the graph of these points Table E 4 Sensor Voltage Versus Humidity Humidity Percentage Sensor Voltage 10 2 67 15 3 08 20 3 48 25...

Page 75: ...HUMIDITY PERCENTAGE M11610 Fig E 4 Graph of Sensor Voltage versus Humidity Sensor Type C7600C1008 4 to 20 mA Sensor Use Humidity Table E 5 lists the points for Sensor Current versus Humidity Fig E 5 shows the graph of these points Table E 5 Sensor Current Versus Humidity Humidity Percentage Sensor Current 10 5 6 15 6 4 20 7 2 25 8 0 30 8 8 35 9 6 40 10 4 45 11 2 50 12 0 55 12 8 60 13 6 65 14 4 70 ...

Page 76: ...Use Enthalpy Table E 6 lists the points for Sensor Current versus Enthalpy volts Fig E 6 shows the graph of these points Table E 6 Sensor Current Versus Enthalpy Volts Enthalpy volts Sensor Current mA 4 1 5 1 25 6 1 49 7 1 74 8 1 99 9 2 24 10 2 49 11 2 74 12 2 99 13 3 24 14 3 49 15 3 74 16 3 98 17 4 23 18 4 48 19 4 73 20 4 98 1 00 1 25 1 50 1 75 2 00 2 25 2 50 2 75 3 00 3 25 3 50 3 75 4 00 4 25 4 ...

Page 77: ...0 50 10 55 13 55 13 60 16 60 16 65 18 65 18 70 21 70 21 75 24 75 24 80 27 80 27 85 29 90 32 95 35 100 38 APPROXIMATE DRY BULB TEMPERATURE F C A A B B C C D D M11160 R E L A T I V E H U M I D I T Y 1 1 HIGH LIMIT CURVE FOR W6210D W7210D Fig E 7 Partial psychometric chart for a C7400A Solid State Enthalpy Sensor See Fig E 8 for a C7400A Solid State Enthalpy Sensor output current versus relative humi...

Page 78: ...4 00 900 4 50 1000 5 00 1100 5 50 1200 6 00 1300 6 50 1400 7 00 1500 7 50 1600 8 00 1700 8 50 1800 9 00 1900 9 50 2000 10 00 0 1 2 3 4 5 6 7 8 9 10 100 300 500 700 900 1100 1300 1500 1700 1900 200 400 600 800 1000 1200 1400 1600 1800 2000 VOLTS PPM SENSOR VOLTAGE VERSUS CO2 CONCENTRATION M11611 Fig E 9 Graph of Sensor Voltage versus CO2 concentration Sensor Type Third party 2 to 20V Sensor Use Mon...

Page 79: ...500 700 900 200 400 600 800 1000 A D VOLTS VOLTS SENSOR VOLTAGE VERSUS INPUT VOLTAGE TO A D M11612 Fig E 10 Graph of Sensor Voltage versus input Voltage to A D Sensor Type Third party Sensor Use Sensor Voltage Vdc Pressure Inw kPa 2 to 10V 0 to 5 inw 0 to 1 25 kPa Table E 11 lists the points for Sensor Voltage Vdc versus Pressure Inw Fig E 11 shows the graph of these points Table E 11 Sensor Volta...

Page 80: ...J D 6 98 Printed in U S A on recycled paper containing at least 10 post consumer paper fibers www honeywell com 3 00 0 75 6 80 3 50 0 87 7 60 4 00 1 00 8 40 4 50 1 12 9 20 5 00 1 25 10 00 2 00 3 00 4 00 5 00 6 00 7 00 8 00 9 00 10 00 0 0 50 1 00 1 50 2 00 2 50 3 00 3 50 4 00 4 50 5 00 VOLTS VDC SENSOR VOLTAGE VERSUS PRESSURE M11963 Inw 0 0 13 0 25 0 37 0 5 0 62 0 75 0 87 1 0 1 12 1 25 kPa Fig E 11...

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