Page 1: User Manual
Video Recorder VRX180 User Manual Issue 3 – 03/03 US1I-6228...
Page 2 Issue 3 – 03/03 US1I-6228...
Page 3 In no event is Honeywell liable to anyone for any indirect, special or consequential damages. The information and specifications in this document are subject to change without notice.
Page 4: About This Document
Contact your local sales office of warranty information. If warranted goods are returned to Honeywell during the period of coverage, Honeywell will repair of replace without charge those items it finds defective. The foregoing is Buyer’s sole remedy and is in lieu of all other warranties, expressed or implied, including those of merchantability and fitness for a particular purpose.
Page 5 Symbol Protective ground terminal. Provided for connection of the protective earth green (green or green/yellow) supply system conductor. Functional ground terminal. Used for non-safety purposes such as noise immunity improvement. WARNING. Risk of electric shock. This symbol warns the user of a potential shock hazard where voltages greater than 30 Vrms, 42.4 Vpeak, or 60 Vdc may be accessible.
Page 6 Video Recorder – User Manual...
Page 7: Table Of Contents
1. INTRODUCTION ... 1 Video Recorder Overview ...1 Specifications ...2 Model Selection Guide ...12 INSTALLATION... 13 Warning...13 Unpacking ...14 Panel mounting the video recorder ...15 Wiring the video recorder ...17 Terminal connections ...19 3. PROGRAMMING AND OPERATING CONCEPTS AND PROCEDURES ... 35 Overview ...35 Quick Start Programming...35 Modes of Operation...35...
Page 8 4. HOW TO PROGRAM FUNCTION BLOCKS AND FEATURES...CONT…………………. Enter Labels ...84 Program Analog Inputs ...87 Program Control Loops ...90 Program Analog Outputs ...101 4.10 Program Discrete Inputs ...104 4.11 Program Discrete Outputs ...105 4.12 Program Calculated Values ...105 4.13 Program Alarms ...143 4.14 Program Totalizers...144 4.15 Program Profiles ...146 4.16 Program Constants ...147...
Page 9 7. ONLINE OPERATION USING MENUS ... 221 Overview ...221 Data Storage ...222 Access Summaries ...228 Data Entry ...232 Setpoint Profiles ...234 Tune Loop ...235 Set Mode...242 Review Programming...242 8. MAINTENANCE ... 243 Overview ...243 Routine Maintenance ...245 Set Mode...245 Calibrate Analog Inputs...245 AO MODULE calibration ...246 Off-line Diagnostics ...247 Database Services ...248...
Page 10 TABLES Table 1-1 Specifications... 2 Table 1-2 Analog Input Accuracy--Linear types ... 7 Table 1-3 Analog Input --Non-linear types... 8 Table 1-4 Standards ... 9 Table 2-1 Universal Analog Input Board Specifications ... 22 Table 3-1 Button Functions... 41 Table 3-2 QWERTY Key Equivalents... 45 Table 3-3 Function Block Types...
Page 11 Table 4-36 Set Up Timer Prompts ... 127 Table 4-37 Mass Flow Prompts ... 128 Table 4-38 Carbon Prompts ... 129 Table 4-39 Relative Humidity Prompts ... 131 Table 4-40 F Sterilization Prompts ... 132 Table 4-41 Advanced Splitter Prompts ... 134 Table 4-42 Standard Splitter Prompts ...
Page 12 Table 5-13 Profiler Starting Procedure ... 202 Table 5-14 Profiler Hold Procedure ... 203 Table 5-15 Profiler Reset Procedure ... 203 Table 5-16 Profiler Advance Procedure... 204 Table 5-17 Profiler Shutdown Procedure... 204 Table 5-18 Event Viewing Procedure ... 205 Table 5-19 Details Viewing Procedure ...
Page 13 Figure 1-1 Video Recorder ... 1 Figure 1-2 Video Recorder Model Number ... 10 Figure 2-1 AI Board Terminal Block Connections ... 22 Figure 2-2 10 ohm Copper Connections ... 22 Figure 2-3 DI Board Terminal Block Connections... 23 Figure 2-4 AO Board Terminal Block Connections ...
Page 14 Figure 4-8 Function Generator Configuration For Valve Characterization... 124 Figure 4-9 Function Generator Configuration For Input Signal Characterization... 124 Figure 4-10 Periodic Timer ... 126 Figure 4-11 Typical Carbon Potential Control Configuration... 130 Figure 4-12 Advanced Splitter (Default Outputs) ... 133 Figure 4-13 Heat/Cool Configuration...
Page 15: Introduction
1.1 Video Recorder Overview The Video Recorder (Figure 1-1) is part of the family of multi-point, multi-function video products. The instrument offers display versatility, flexible data storage, up to 8 control loops, each one can run its own profile, and advanced math functions. This integration of several functions eliminates the need for multiple devices and reduces installation costs.
Page 16: Specifications
Introduction 1.2 Specifications Enclosure Metal case and rugged die cast aluminium door and frame. High impact resistant polycarbonate keypad and glass or polycarbonate window. IP55 rating (NEMA 3) from front panel. Mounting (Panel) 40 mm thickness (max.) (1,57") Dimensions Compact size: 320 mm (12.60") depth 310 mm front face height x 317 mm width (12.21"...
Page 17 Number of Memory can store 96 programs for a single channel programmer, 48 programs for a dual Programs channel programmer, 32 programs for a three channel programmer, and 24 for a four channel programmer. Programs can also be stored to floppy disk. Programmer has ability to start a program at a predetermined time.
Page 18 Introduction Number Input Types Signal source Input Impedance Input Isolation Stray rejection Burnout T/C Break Detection Scan rate A/D Converter Resolution Number Type Isolation from ground Accuracy Temperature Effects D/A Resolution Number Input Voltage Range Peak Voltage AC Frequency Isolation from ground Isolation between inputs ON Voltage Level OFF Voltage Level...
Page 19 Input Impedance Input Current 0.9 mA @ 100 Vac Minimum ON Current 0.3 mA Maximum OFF Current 0.15 mA Base Power Required* 50 mA maximum OFF to ON Response 5 to 30 ms ON to OFF Response 10 to 50 ms Number 6 (dry contact) per module, up to 6 modules per video recorder Isolation from ground...
Page 20 Introduction Time Resolution Module Synchronization Math Calculations Standard Math package includes: 24 Calculated Values along with the following Math functions: Free Form Math, Math Operators (+, -, x, , Absolute Value, Square Root, Std. Deviation), Free Form Logic, Logic Operators (AND, OR, XOR, Inverter, Flip Flop, One- Shot), Inverter algorithms.
Page 21: Table 1-2 Analog Input Accuracy--Linear Types
Table 1-1 Specifications (continued) Accuracy Reference conditions Accuracy Rated limits and Parameters associated drifts Temperature Supply voltage Source resistance Humidity Long-term stability Table 1-2 Analog Input Accuracy--Linear types Millivolts 0 to 10 mV 0 to 1 V -10, +10 mV -1, 0, 1 V 0 to 20 mV 0 to 2 V...
Page 22: Table 1-3 Analog Input --Non-Linear Types
Introduction Type Operating span °F 2190 2500 -450 to 1830 -300 to 2372 3300 3210 3210 W5/W26 (3) 4200 PLAT II (3) -100 to 2500 NI-NIMO 2502 CU10 -100 to PT100 IEC -300 to 1570 Type Operating span °F 18890-0035 1200 to 2600 18890-0073 800 to 1800...
Page 23: Table 1-4 Standards
This product is designed and manufactured to be in conformity with applicable U.S., Canadian, and International (IEC/CENELEC/CE) standards for intended instrument locations. The following Standards and Specifications are met or exceeded. Case Protection IP55 on front door only, when the instrument is panel mounted and the front door securely closed.
Page 24: Figure 1-2 Video Recorder Model Number
Introduction 1.3 Model Selection Guide This table helps you to identify correctly the unit in front of you. Please refer to the product label and verify that you have the right unit. Select the desired key number. The mark to the right shows the selection available. A complete model number has the requested number of digits from each table as follows.
Page 25 Model Selection Guide (cont.) T A B L E II - A D D IT IO N A L IN P U T S A N D O U T P U T S (c o n tin u e d ) N o n e S lo t N 4 U n iv e rs a l A n a lo g In p u ts...
Page 26: Model Selection Guide
5. When selecting Control loops, make sure to select outputs (as necessary in Table II) 6. Provided with each VRX180 are : one pre-initialized disk and one SDI software pack. SDI software should be installed on a PC and used for initialization of new disks.
Page 27: Installation
What’s in this section? The following topics are covered in this section. Topic Warning Unpacking Panel mounting the video recorder Wiring the video recorder Terminal connections NOTICE If this instrument is used in a manner not specified by the manufacturer, the protection provided by the instrument may be impaired.
Page 28: Unpacking
Installation 2.2 Unpacking Examine the shipping container carefully. If there are visible signs of damage, notify the carrier and your local sales office immediately. If there is no visible damage, compare the contents with the packing list. Notify your local sales office if there is equipment shortage.
Page 29: Panel Mounting The Video Recorder
2.3 Panel mounting the video recorder 2.3.1 Recommendations This video recorder is designed to operate under specific conditions. If you need more information, refer to the product specification sheet. 2.3.2 External dimensions and cut-out Prepare panel cut-out as detailed below: 12.48 NOTE: Maximum panel thickness 40 mm (1.55") CAUTION...
Page 30 Installation 2.3.3 Installing the video recorder To install the video recorder, follow the figure below: Step 1: Remove rear cover and wire access holes Step 2: Insert video recorder through the panel cutout Step 3: Attach mounting brackets to the sides of the video recorder Bracket position Step 4: Tighten the mounting screws Mounting brackets...
Page 31: Wiring The Video Recorder
NOTE: When installing the video recorder, the following limits should be respected: Mounting angle limits 2.4 Wiring the video recorder 2.4.1 Recommendations CAUTION • All wiring must be in accordance with local electrical codes and should be carried out by authorized and experienced personnel.
Page 32 Installation • EXAMPLE: Rep. B: Grounding screw Rep. C: Clamp Rep. D: Shielded cable (inputs) Rep. E: External grounding cable • The use of spade terminals on all wiring is recommended. Rep. A: Cable retaining bracket (46210075-501) Video Recorder - User Manual...
Page 33: Terminal Connections
2.5 Terminal connections 2.5.1 Rear cover The rear cover protects the I/O boards terminal connectors. On the rear cover, a drawing reminds the user of the terminals use. AI = Analog input AO = Analog output DI = Digital input DO = Digital output (relay) Note: Terminal blocks can be removed from the board for easier wiring and board replacement.
Page 34 Installation Removing the rear cover grants access to the terminals location: Step A: Turn off power Step B: Loosen screws holding rear cover Step C: Slide rear cover to the left Step D: Remove rear cover Video Recorder - User Manual...
Page 35 2.5.2 Inserting and extracting inputs and outputs board: Steps A and B show how to insert or extract a board from the video recorder. To extract a board: Step A then Step B. To insert a board: Step B then Step A. Step A (1) Press down on terminal block clips (2) Push in or pull out to insert or remove from board...
Page 36: Table 2-1 Universal Analog Input Board Specifications
Installation 2.5.3 Analog input boards A universal Analog Input board accepts a variety of input signals from field devices. Figure 2-1 illustrates the terminal block connections for the various inputs. One AI board can be configured to accept multiple input types. Table 2-1 Universal Analog Input Board Specifications Specification Input Types...
Page 37: Figure 2-3 Di Board Terminal Block Connections
2.5.4 Digital Inputs Boards Three types of Digital Input (DI) boards accept three types of input signals. Logic Input DC Input AC Input Each type is described on the following pages. DI boards. See Section 1 for details on all I/O board specifications. Contact Closure Logic input 24 VDC...
Page 38: Figure 2-4 Ao Board Terminal Block Connections
Installation 4 to 2 0 m A o u tp u t L o a d G r o u n d T e r m in a l 2 4 V NOTE - Channels not used as analog outputs can be used to supply a transmitter with 24 Vdc power Figure 2-4 2.5.6 Digital Outputs...
Page 39: Figure 2-5 Do Board Terminal Block Connections
Installation Figure 2-5 DO Board Terminal Block Connections The Digital Output board with relay outputs contain jumpers to set the de-energized state of the relay contacts. The relays are factory set to Normally Closed (NC) for each output on the relay output board, Figure 2-6 DO Board Relay Contact Setting To change the state of the contacts: See .
Page 40 Installation Normally Open Contacts Figure 2-6 DO Board Relay Contact Setting 2.5.7 Wiring communications This software package has been designed to operate with three kinds of serial communication standards which are: RS232, RS422 and RS485. Refer to the following chapters for the wiring configuration of each of them.
Page 41: Figure 2-7 Rs232 Wiring Configuration
2.5.7.1 RS232 wiring configuration VIDEO RECORDER Figure 2-7 2.5.7.1.1 Switch configuration RS232 wiring configuration RS232 LEFT a wa y from PC boa rd towa rd PC boa rd Video Recorder - User Manual Installation RIG HT...
Page 42 Installation 2.5.7.1.2 Interface connector • With DB9 connector Interface cable connectors pin arrangement and signal functions. VIDEO RECORDER SIDE 14 15 16 17 18 19 20 21 22 23 24 DB25 male connector face view RECORDER Pin n° Note : Check compatibility with your PC as far as no standard for DB9 connector exists yet. VIDEO RECORDER 9 10 11 12...
Page 43 • With DB25 connector Interface cable connectors pin arrangement and signal functions. VIDEO RECORDER SIDE 14 15 16 17 18 19 20 21 22 23 24 25 DB25 male connector face view VIDEO RECORDER Pin n° VIDEO RECORDER 10 11 12 13 25 24 23 22 21 20 19 18 17 16 15 14 Direction Pin n°...
Page 44: Figure 2-8 Rs422 Wiring Configuration
Installation 2.5.7.2 RS422 wiring configuration VIDEO RECORDER 2.5.7.2.1 Switch configuration a wa y from PC boa rd VIDEO RECORDER Figure 2-8 RS422 wiring configuration RS422 RIG HT LEFT towa rd PC boa rd Video Recorder - User Manual VIDEO RECORDER...
Page 45: Figure 2-10 Rs485 Wiring Configuration
Installation 2.5.7.2.2 Interface connector TOP SIDE RXA (-) RXB (+) TXA (-) TXB (+) BOTTOM SIDE Figure 2-9 RS422 Inferface connections 2.5.7.3 RS485 (2 wires) wiring configuration VIDEO RECORDER VIDEO RECORDER VIDEO RECORDER Figure 2-10 RS485 wiring configuration Video Recorder - User Manual...
Page 46: Figure 2-11 Interface Connector
Installation 2.5.7.3.1 Switch configuration away from PC board 2.5.7.3.2 Interface connector RS485 LEFT RIGHT toward PC board TOP SIDE RX/TXA (-) RX/TXB (+) BOTTOM SIDE Figure 2-11 Interface connector Video Recorder - User Manual...
Page 47 2.5.7.4 Connecting the RS422/485 link to a computer The VRX180 video recorder with the RS422/485 Communications option can be connected your computer using one of two arrangements : • Wired to an RS422/485 compatible serial port (if the computer is equipped with such a port).
Page 48 Installation Video Recorder - User Manual...
Page 49: Programming And Operating Concepts And Procedures
3. Programming and Operating Concepts and Procedures 3.1 Overview This section explains the instrument’s programming and operating concepts and procedures. Read and understand this section before attempting to program and operate your instrument. 3.2 Quick Start Programming Use this section to quickly start up your instrument. This section contains the basic concepts you should know for configuring the instrument.
Page 50: Menu Navigation
Programming and Operating Concepts 3.4 Menu Navigation Moving between the Program, Online, and Maintenance modes of the instrument is accomplished through use of the instrument’s Menu, Up Arrow, Down Arrow, and Enter keys located on its front door. Refer to Figure 3-1. 1000.00 PV 405.00 SP 405.00...
Page 51: Figure 3-2 Menu Navigation Guide Through On Line, Program, And Maintenance Mode Main Menus
A more detailed explanation of the function of each button appears in Section 3.5. To develop a feel for navigating between modes, power up the instrument and perform the sequence of steps that follows. Upon powering up the instrument for the very first time, the logo display will initially appear. Press the Menu button several times until the ON LINE, PROGRAM, or MAINTENANCE mode MAIN MENU is displayed.
Page 52: Figure 3-3 On Line Mode Main Menu
Programming and Operating Concepts Once within the mode selected in Step 5, scroll through the mode’s MAIN MENU using the Up Arrow and Down Arrow buttons. Verify each menu choice as indicated in Figure 3-2. Repeat Steps 3 through 6 for the last of the three mode selections possible. Having completed the preceding exercise, changing the instrument’s mode should now be a simple task.
Page 53: Figure 3-4 Program Mode Main Menu
MAIN MENU - PROGRAM SET MODE PROGRAM ANALOG ANALOG LABELS INPUTS OUTPUTS INPUT #1 INPUT #2 ANALOG INPUTS LOOP #1 LOOP #2 CONTROL LOOPS OUTPUT #1 OUTPUT #2 OUTPUT #3 ANALOG OUTPUTS INPUT #1 INPUT #2 DISCRETE INPUTS OUTPUT #1 OUTPUT #2 OUTPUT #3 DISCRETE OUTPUTS...
Page 54: Figure 3-5 Maintenance Mode Main Menu
Programming and Operating Concepts MAIN MENU - MAINTENANCE SET MODE MAINTENANCE CALIBRATE ANALOG CALIBRATE ANALOG INPUTS INPUTS OUTPUT #1 CALIBRATE ANALOG OUTPUTS RAM SIZE OFF-LINE DIAGNOSTICS (KB) DATABASE SERVICES CLEAR ALL MEMORY RESET UNIT PRODUCT INFORMATION MAINS FREQUENCY WARM START TIME DEMO Figure 3-5 MAINTENANCE mode MAIN MENU RESET ANALOG INPUT...
Page 55: Button Functions
3.5 Button functions In all modes, the instrument is operated by using the front panel buttons to view and select items from menus and displays. Table 3-1 describes each panel button and its functions. Symbol Name Menu • • • Up Arrow/ •...
Page 56 Programming and Operating Concepts Symbol Name Down • Arrow/ Next • • • • Left Arrow • • Enter • • • • • • • Display From any display or menu, pressing this button changes the instrument to online mode* and accesses the display programmed as Display #4.
Page 57 Symbol Name Display 1 From any display or menu, pressing this button changes the instrument to online mode* and accesses the display programmed as Display #1. See Table 4-64 on page 154 for more information on Displays. Display 2 From any display or menu, pressing this button changes the instrument to online mode* and accesses the display programmed as Display #2.
Page 58 Programming and Operating Concepts Symbol Name Auto/ • Manual • • ATTENTION The following keys are like Digital Inputs on the keypad of the instrument. They must be configured as part of the instrument’s function blocks in order to be active. •...
Page 59: Text Entry From External Sources
3.6 Text Entry From External Sources QWERTY keyboard To use a keyboard to enter text such as labels, numbers, and equations, connect an AT Qwerty keyboard to the mini DIN connector. See Table 3-2 for key functions. The instrument’s cursor must be on the text to be changed (on the right side of the display) before you type in the new text.
Page 60 Programming and Operating Concepts Table 3-2 QWERTY Key Equivalents (continued) Button ASCII barcode reader To enter text such as labels, numbers, and equations with a barcode reader, connect the barcode reader to the mini DIN connector with an adapter (part No. 104286). The instrument buttons remain functional. See section 3.7 on how to connect a mini DIN connector.
Page 61: Connecting A Keyboard Or A Barcode Reader
Programming and Operating Concepts 3.7 Connecting a keyboard or a barcode reader The mini DIN connector is located on the front door of the instrument. Lift the rubber cap (1) to connect the mini DIN connector (2) Figure 3-6 Connection of a keyboard or a barcode reader Video Recorder –...
Page 62: Installing And Removing A Floppy Disk
Programming and Operating Concepts 3.8 Installing and removing a floppy disk To install or remove a floppy disk from the instrument, open the door as described in the following drawings. NOTE: recording on the disk stops when door is open. Open the door latch Door with key lock Door with latch...
Page 63: Definition Of Function Blocks
3.9 Definition of Function Blocks Definition A function block is a unit of software that performs a set of operations on its input parameters and function block parameters and produces output parameters. These output parameters can be programmed as inputs to other function blocks, whose output parameters can be programmed as inputs to other function blocks, and so on.
Page 64: Table 3-3 Function Block Types
Programming and Operating Concepts Function block Type name Alarm Analog Input Analog Output Calculated Value Constant Discrete Input Discrete Output Loop Setpoint Profiler System Totalizer * Depends on options ordered. Why use function blocks? Function blocks give you configuration flexibility. For instance, the instrument does not have a dedicated relay that is activated during an alarm;...
Page 65: Components Of Function Blocks
3.10 Components of function blocks The three components of a function block are: Input parameter(s) Function block parameter(s) Output parameter(s). Figure 3-7 shows the function block Alarm #1’s components. Func ti on bloc k p aram ete r Fu nc ti on bloc k p aramete r In put param ete r In put paramete r In put paramete r...
Page 66 Programming and Operating Concepts Function block parameter A function block parameter’s data is contained within the block. When you are programming a function block and are not given a choice of PARM, you are programming a function block parameter. Typical choices when programming a function block parameter are NONE, OFF, any numerical value, or a list of options for the parameter, but not PARM.
Page 67: Table 3-4 Function Block Parameter Designators
Table 3-4 Function Block Parameter Designators Function Function Block Block Name Type Analog Input System Parameter Analog Output Discrete Input Discrete Output Control Loop ON/OFF Loop only Programming and Operating Concepts Output Parameter Name code Output Value Reference Junction Temp. Alarm Global Alarm High Alarm Low...
Page 68 Programming and Operating Concepts Table 3-4 Function Block Parameter Designators (continued) Function Function Block Block Name Type Setpoint Profiler Alarm Constant Calculated Value* *CV output codes are available for programming only if the CV has been programmed. For example, you cannot program an input parameter with CV1 OV unless CV1 has been programmed.
Page 69: How To Program Input Parameters
3.11 How to program input parameters A function block has two types of programmable parameters: input parameters and function block parameters. When in a function block’s Program menu, if a menu item has choices OFF, a number, or PARM, then the menu item is an input parameter to that function block. That is, if you choose PARM you can connect the input parameter to another function block’s output code.
Page 70: Figure 3-9 Function Block Connection Format
Programming and Operating Concepts Type of function block Choices: AI - Analog Input AL - Alarm AO - Analog Output CV - Calculated Value CN - Constant DI - Discrete Input DO - Discrete Output LP - Loop (control) SP - Setpoint Profiler SY - System TL - Totalizer Figure 3-9 Function Block Connection Format...
Page 71: Table 3-6 Example Number Selection Procedure Using Front Panel Buttons
Table 3-6 Example Number Selection Procedure Using Front Panel Buttons Step In the Program Control Loops menu, select LOOP #2. Consult the Program Control Loops section of this manual to learn about the menu item you wish to change, namely, SETPOINT #2. Press Down Arrow button to move the cursor to the menu choice SETPOINT #2.
Page 72: How To Program Function Block Parameters
Programming and Operating Concepts ATTENTION Note the difference between programming a discrete parameter with OFF and programming it with a 0. “OFF” means “not connected”; 0 means “off state”. 3.12 How to program function block parameters The second type of programmable parameter is a function block parameter. parameter’s data is contained within a function block and cannot be connected to another function block.
Page 73: Table 3-10 Example Configuration Procedure
Table 3-9 Function Block Configuration Procedure (continued) Step Program the function block’s other items as desired. Other items include decimal point positions, descriptor, tag, and various labels for identifying the function block. Repeat steps 1-4 for all desired function blocks until the instrument is configured. Example configuration Figure 3-10 shows a simplified configuration using typical function block connections.
Page 74: How To Program Common Configurations
Programming and Operating Concepts 3.14 How to program common configurations Being able to diagram a control configuration in terms of function blocks makes it easier to program and configure your instrument for its intended process control application. This function block diagram you create can be used as a “construction blue print”...
Page 75: Figure 3-12 Basic Function Blocks Required For Control Configuration Of Figure 3-11
1. Diagram the function blocks To configure this application using the instrument, your task is to build up a simple current control loop. Note that this control loop must monitor and control the temperature of the furnace zone to a local set point of 500 ºF.
Page 76: Figure 3-13 Labeling Each Function Block's Name And Major Inputs And Outputs
Programming and Operating Concepts 3. Label output parameters The second part in labeling each function block is to denote the blocks’ major input and output parameters. Each of these parameters will correspond to actual menu settings that you program on the instrument.
Page 77: Figure 3-14 Labels For Internal Function Block Parameters
TYPE J THERMOCOUPLE INPUT TYPE = J RANGE LOW = 0 RANGE HIGH = 1000 Figure 3-14 Labels For Internal Function Block Parameters Note that the internal parameters that we have specified in the function block diagram built up so far are based largely on what can be inferred from the elements of the control configuration depicted in Figure 3-11.
Page 78: Figure 3-16 Complete Function Block Diagram Of Figure 3-11
Programming and Operating Concepts 6. Draw the Feedback connection To fully complete the function block diagram, one final and very important interconnection must be drawn. In setting up control loops in this instrument, a feedback path must be specified between the loop function block itself and the hardware element that externalizes the loop’s output to the real world.
Page 79: Figure 3-17 Control Of Wastewater Ph Using A Time Proportioning (Dat) Control Signal
Time Proportioning Relay Driven Pump A second control scheme is to use a relay to produce a time proportioning or Duration Adjusting Type (DAT) control signal. Such an application is depicted in Figure 3-17. CAUSTIC REAGENT Figure 3-17 Control Of Wastewater pH Using A Time Proportioning (DAT) Control This application requires a basic time proportioning control loop to monitor and control the pH of the wastewater to a local set point of 7 pH units.
Page 80: Figure 3-19 Temperature Control Of Water Using Split Output Or Duplex Control
Programming and Operating Concepts From Figure 3-18, the instrument’s AI1 function block will essentially process the 4 to 20 mA transmitter signal to generate a pH measurement. This measurement will be “AI1 OV” which, in turn, will be applied to LP1’s process variable input, “PV.” Before the 4 to 20 mA signal is applied to AI1, it will be converted to a 1 to 5 VDC signal with a 250 Ω...
Page 81: Figure 3-20 Function Block Diagram Of Figure 3-19
In Figure 3-20, the analog input function block AI1 is depicted processing the resistance values produced by the RTD. The resulting water temperature measurements (AI1 OV) are then fed to the process variable input (PV) of the LP1 control loop block. Note how LP1 has been defined as a split output control loop using the notation “TYPE = SPLIT.”...
Page 82: Figure 3-21 Temperature Control Of An Oil Heated Chemical Reaction Chamber
Programming and Operating Concepts Cascade Control An example of a cascade control application is featured in Figure 3-21. Cascade control is typically used when two process values must be simultaneously controlled, with one process value directly influencing the behavior of the other. In this control strategy, each process value is supported by its own dedicated control loop.
Page 83: Figure 3-22 Function Block Diagram Of The Cascade Control Strategy
REACTION AI1 OV VESSEL THERMOCOUPLE TYPE = CAS_P SP1 = 1234.5 AI2 OV THERMOCOUPLE NOTE: 1) SP1 is desired reaction vessel temperature. 2) SP2 is the remote setpoint input of LP2. Figure 3-22 Function Block Diagram Of The Cascade Control Strategy Recall that based on the instrument’s model number, up to eight control loops (LP1 through LP8) are potentially available for use within the instrument.
Page 84: Figure 3-23 Example Set Point Profile
Programming and Operating Concepts Set Point Profile Implementation By definition, set point profiles are essentially user specified plots of process values against time. These plots are characterized by “segments” which are a series of intervals of varying time lengths that divide the plots into several segments.
Page 85: Figure 3-24 Function Block Diagram Of Set Point Profile Control Of Figure 3-16
TYPE J THERMOCOUPLE INPUT TYPE = J RANGE LOW = 0 RANGE HIGH = 1000 Figure 3-24 Function Block Diagram Of Set Point Profile Control Of Figure 3-16 Figure 3-24 basically depicts all the components of the Figure 3-16’s control configuration with a set point profiler function block denoted by SP1.
Page 86: Figure 3-26 Up To 16 Discrete Events May Be Programmed Per Step Of A Set Point Profile
Programming and Operating Concepts Also typical in the execution of a set point profile is the generation of discrete events during each profile step. Discrete events are simply status indicators that are programmed to assume either an ON or OFF state during a step of a profile.
Page 87: Figure 3-27 Tying A Profile Function Block's Discrete Events With Discrete Output Hardware
TYPE J THERMOCOUPLE External INPUT TYPE = J Switches RANGE LOW = 0 RANGE HIGH = 1000 DI1 OS START DI2 OS HOLD RESET + + + DI3 OS Figure 3-27 Tying A Profile Function Block’s Discrete Events With Discrete Output Hardware Refer to your instrument’s model number to verify its complement of discrete input and output hardware.
Page 88: Data Storage
Programming and Operating Concepts 3.15 Data Storage This instrument supports either floppy 1,44 MB or 100 MB ZIP disks. Note that only DOS formatted floppy disks may be used in the instrument’s disk drive and the unit’s front door must be closed for any disk drive operations to take place.
Page 89: Table 3-11 Data Storage File Extensions
Performing Data Storage Configuring the instrument to store the first category, Data Storage (process and diagnostic data) is done through an Online menu entitled DATA STORAGE. All aspects of preparing a DOS formatted disk to accept process and diagnostic data information are managed through this menu’s selections. Process and diagnostic data may be stored on the same disk, but not along with other storage types (i.e., configuration, setpoint programs, or calibration).
Page 90 Programming and Operating Concepts Initializing a ZIP disk To activate the new data storage schedules that have been configured in the SET UP NEW SCHEDULES menu requires you to “initialize” the DOS formatted disk to which process and diagnostic data will be stored. This is done by executing a routine entitled INITIALIZE DISK, also found in the DATA STORAGE menu.
Page 91 The next step to complete is to initialize the disk on the video recorder as you would have done normally, as explained in the «Initializing a zip disk» section, except that this time, it will take just a few seconds. Note: it is recommended to dedicate a ZIP disk to storage of data only and store configurations of products on a separate disk.
Page 92 Programming and Operating Concepts EXAMPLES : Example #1 : 4 Live Trends all having 1 Hour Screens + 1 Data Storage Trend at 5 Seconds + 1 Data Storage Trend at 10 Seconds + 1 Live Screen. The result = ((1/12) * 4) + 1/5 + 1/10 + 1 = 1.6333 (BELOW THE LIMIT) Example #2 : 1 Live Trends with 5 Minute Screen + 1 Data Storage Trend at 0.25 Seconds + 1 Live Screen.
Page 93: How To Program Function Blocks And Features
4. How To Program Function Blocks and Features 4.1 Overview This section describes all the programming procedures to get your instrument up and running, except Profiles which are discussed in Section 5. It describes the entire Program Mode menu and some items from the Online Mode menu.
Page 94: Programming Tips
Programming Function Blocks and Features 4.2 Programming tips See Section 3 for general programming procedures. Before programming a function block’s input parameter with a CV’s (Calculated Value) output parameter, you must program the CV first; otherwise, the CV’s output parameter will not be available for programming.
Page 95: The Program Mode Menu
4.3 The Program mode menu Program mode is an off-line mode for programming (configuring) the instrument. In this mode, all outputs are frozen. Table 4-1 shows the top level of the Program Mode menu with all available options. Your instrument may have a reduced menu if options are not present or if features have been disabled.
Page 96: Frequently Used Programming Prompts
Programming Function Blocks and Features 4.4 Frequently used programming prompts When programming the instrument you will see certain prompts repeatedly in different menus. These are described in Table 4-2, rather than in each menu in which they appear. Table 4-2 Frequently Used Programming Prompts Prompt IN DECIMAL POS X.XXXXX...
Page 97: Set Mode
4.5 Set Mode Select this item to change the operating mode of the instrument to Online, Program or Maintenance. The top of the display will show which mode you have changed to. Program mode Program mode is an off-line mode for programming (configuring) the instrument. In this mode, all outputs are frozen.
Page 98: Enter Labels
Programming Function Blocks and Features 4.6 Enter Labels Overview Labeling lets you use the front panel buttons, a QWERTY keyboard, or barcode reader to assign custom text identifiers to most data and functions to make them easily recognized on displays. Labeling items makes programming and operation easier but is not required.
Page 99: Table 4-3 Labels For Function Blocks
Table 4-3 Labels for Function Blocks Prompt Range/Selections DESCR Enter 16 characters maximum. Enter 7 characters maximum. Default choices: UNITS DEGR ON STATE DOWN START STOP HIGH RESET TRUE FALSE LEFT RIGHT DECRS INCRS LOAD UNLOAD COOL HEAT OFF STATE See ON STATE for default choices.
Page 100: Table 4-4 Other Labels
Programming Function Blocks and Features Prompt UNIT Enter up to 16 characters to specify a label for the instrument. ENGINEERING Enter up to 4 characters to change UNITS available engineering units from the defaults: FILENAMES Enter up to 6 characters to change available filenames from these defaults: FILE PROD...
Page 101: Program Analog Inputs
4.7 Program Analog Inputs To program Analog Inputs, select PROGRAM ANALOG INPUTS on the Main Program Menu. Select an AI to program. Table 4-5 Analog Input Algorithm Selection Prompt INPUT ALGORITHM Standard algorithm prompts Table 4-6 describes all the prompts associated with the standard algorithm. These are the default prompts for analog input programming.
Page 102 Programming Function Blocks and Features Table 4-6 Standard Algorithm Prompts (continued) Prompt TEMPERATURE UNIT Select C for Degrees Celsius, F for Degrees Fahrenheit, K for Kelvin, R for Rankine, or NONE. DIRECT/INDIRECT Select DIRECT for thermocouple, pyrometer, or RTD inputs. Select INDIR (Indirect) for volt or millivolt signal inputs from linear or non-linear transmitters.
Page 103: Table 4-7 Custom Algorithm Prompts
Custom algorithm prompts Table 4-7 describes the custom algorithm prompts. See Table 4-2 for additional prompts. These prompts appear only if CUSTOM INPUT is enabled under FEATURES. See Section 0. Table 4-7 Custom Algorithm Prompts Prompt INPUT SIGNAL RJ ENABLE EMISSIVITY ENABLE ELECTRICAL UNITS SAMPLE HOLD...
Page 104: Program Control Loops
Programming Function Blocks and Features 4.8 Program Control Loops Control Loop Programming Structure Programming a control loop requires configuring at least 3 function blocks: an Analog Input (AI), a loop algorithm and an Analog Output (AO). The term AO is applied to any type of control output; current (CAT), or time proportioning (DAT).
Page 105 Characteristic Split output programming A splitter output type (Standard or Advanced) calculated value is used to send requirements the Split loop output to 2 or 3 different analog output (AO) functions. In this case, program the control loop to receive a feedback from the back calculation output of the splitter calculated value.
Page 106: Table 4-9 Control Loop Type Menu Selections
Programming Function Blocks and Features Table 4-9 Control Loop Type Menu Selections SPLIT IN DECIMAL POS IN DECIMAL POS IN DECIMAL POS OUT DECIMAL OUT DECIMAL OUT DECIMAL PV HIGH LIMIT PV HIGH LIMIT PV HIGH LIMIT PV LOW LIMIT PV LOW LIMIT PV LOW LIMIT CONTROL...
Page 107 Table 4-9 Control Loop Type Menu Selections (continued) SPLIT FEEDFORWARD FEEDFORWARD FEEDFORWARD FEEDFORWARD GAIN GAIN OUTPUT OUTPUT TRACKING TRACKING FORCE REMOTE FORCE REMOTE CHG ACTION CHG ACTION INPUT INPUT DUAL TUNING DUAL TUNING DISCR VS KEY DISCR VS KEY SETPOINT SETPOINT SELECT SELECT...
Page 108: Table 4-10 Loop Prompts
Programming Function Blocks and Features Loop Menu Items Table 4-10 alphabetically describes every loop menu item. See Table 4-2 for additional prompts. Prompt Range/Selections APPROACH HIGH Enter a value 0.1 to 100 or OFF. APPROACH LOW Enter a value 0.1 to 100 or OFF.
Page 109 Table 4-10 Loop Prompts (continued) Prompt Range/Selections ENGINEERING Select letter UNITS FEEDBACK OFF, analog parameter, number FEEDFORWARD OFF, analog parameter, number FEEDFORWARD -10.00 to 10.00 GAIN FORCE REMOTE OFF, discrete parameter, 0, GAIN/PROP BAND PB or GAIN GAIN#1 OR GAIN#2 Enter a value of 0.1 to 200 for Gain, or 0.5 to 1000.0 for Proportional Band.
Page 110 Programming Function Blocks and Features Table 4-10 Loop Prompts (continued) Prompt Range/Selections IN DECIMAL Select decimal position POSITION INTERACTIVE YES, NO LATCHING YES, NO MANUAL OFF OFF, discrete parameter, 0, MANUAL RESET -100 to +100 OUTPUT LOW LIM & OFF or number OUTPUT HIGH LIM OUTPUT TRACKING 0-100%, Analog parameter,...
Page 111 Table 4-10 Loop Prompts (continued) Prompt Range/Selections RATE#1 & 0.02-10.00 minutes RATE#2 RESET#1 & 0.005-99.99 repeats/minute RESET#2 RESET LIMIT OFF or 100 to 200%. RATIO BIAS Programming Function Blocks and Features Modifies the loop output based on the rate of change of the process variable.
Page 112 Programming Function Blocks and Features Table 4-10 Loop Prompts (continued) Prompt Range/Selections RATIO SETPOINT SETPOINT SELECT OFF, discrete parameter, 0, SETPOINT#1 & Set point #1 can be a SETPOINT#2 number only. Set point #2 can be a number, an analog parameter, or OFF.
Page 113 Table 4-10 Loop Prompts (continued) Prompt Range/Selections SP INC SLEW LIMIT & Enter a number SP DEC SLEW LIMIT SP LOW LIMIT & SP OFF or number HIGH LIMIT SP1 TRACKING SP2, NONE SUPPRESS YES, NO OVERSHOOT ATTENTION Regardless of the setting of this SUPPRESS OVERSHOOT selection, overshoot is not suppressed when the process disturbance causes an initial deviation (PV-SP) value between -0.7 and +0.7 engineering units.
Page 114: Figure 4-1 Function Block Configuration Of A Typical Ratio Control Loop
Programming Function Blocks and Features UNITS = FPS INPUT TYPE = LINEAR DIRECT/INDIRECT/SQRT = SQRT RANGE LOW = 0 RANGE HIGH = 40 CIRCUIT LOW = 1 CIRCUIT HIGH = 5 ELECTRICAL UNITS = VOLTS AI2 OV AIR P SIGNAL AI3 OV VARIABLE FUEL P...
Page 115: Program Analog Outputs
4.9 Program Analog Outputs The analog outputs will be accessible if an analog output board is detected upon power up. If the instrument will be used for control, program the loops first. See Program Control Loops in Section 4.8. Select an analog output to program. Analog output type Select the output type from Table 4-11.
Page 116: Table 4-13 Analog Output Prompts
Programming Function Blocks and Features Table 4-13 Analog Output Prompts Prompt Range/Selections INPUT SOURCE Enter OFF, analog parameter, number as the analog output source. INPUT LOW LIMIT If the AO's input source is a PID control loop, specify a high value of 100 and a low value of 0.
Page 117 Table 4-13 Analog Output Prompts (continued) Prompt Range/Selections MIN ON TIME OFF or MIN OFF TIME OFF or number OUTPUT RELAY Select discrete output channel. ATTENTION ON/OFF loop types provide direct output without the use of an analog output. To complete an ON/OFF loop configuration, assign the ON/OFF loop’s output (LPn OS) to a Discrete Output Relay.
Page 118: Program Discrete Inputs
Programming Function Blocks and Features 4.10 Program Discrete Inputs Discrete Input function blocks are controlled by the on/off status of the input hardware. The output of the function block, DIn OS, reflects the status of the associated input hardware. This output DIn OS can be connected to other function blocks’...
Page 119: Program Discrete Outputs
4.11 Program Discrete Outputs Discrete Output function blocks control the relay or open collector output hardware. The Program Discrete Outputs menu item will appear if a Discrete Outputs board is installed. ATTENTION If a discrete output has been assigned to a time proportioning output (DAT), it will not be programmable here. See "OUTPUT RELAY"...
Page 120: Program Calculated Values
Programming Function Blocks and Features 4.12 Program Calculated Values A Calculated Value (CV) is a data point whose value is derived from calculations involving other data points. The CV Output can be analog or discrete. A CV can include other CVs in its calculations. Once a CV is created, it can be used by any function block as many times as desired.
Page 121: Table 4-17 Peak Picking Prompts
Peak Picking This type monitors the input and determines a “peak” value reached during the specified time interval (in minutes). The peak can be chosen to be a maximum, minimum, average, or standard deviation. At the end of the time interval, the output CVn OV steps to the value of the peak and holds this value until the end of the next time interval.
Page 122: Table 4-18 Signal Select Prompts
Programming Function Blocks and Features Signal Select Selects one of 48 inputs based on the action and outputs it as CVn OV. Table 4-18 describes the Signal Select prompts. See Table 4-2 for additional prompts. Table 4-18 Signal Select Prompts Prompt Range/Selections OUTPUT LOW LIMIT...
Page 123: Table 4-19 Compare Prompts
Compare Compare can be used instead of an Alarm’s output to control a relay. It can also provide on/off control with hysteresis. Compares 2 inputs. Call the result of this comparison “Result”. Result is a pulse that goes ON(1) when comparison is true, and OFF(0) when comparison is not true.
Page 124: Figure 4-3 Compare's Greater Than Result, With Hysteresis
Programming Function Blocks and Features Input # 1 > Input # 2 1 Degree Result switches ON Result OFF Time Figure 4-3 Compare’s Greater Than Result, With Hysteresis Operator GT (Greater than) Hysteresis = 2 degrees Input #2 Input #1 Input # 2 - Input #1 Result switches OFF Result ON...
Page 125: Table 4-20 Compare's Condition Type And Condition Time Prompts
Table 4-20 Compare’s Condition Type and Condition Time Prompts Condition type Application NONE Condition type Application DELAY Filters short pulses Delays rising edge of Result for CONDITION TIME If Result is: Then CVn OS is: Condition type Application EXTEND Used for interfacing with slower circuits.
Page 126 Programming Function Blocks and Features Table 4-20 Compare’s Condition Type and Condition Time Prompts (continued) Condition type Application PULSE Used for interfacing with slower circuits. On rising edge of Result, creates pulse length CONDITION TIME and ignores additional rising edges of Result within that CONDITION TIME.
Page 127: Table 4-21 Counter Prompts
Counter Counts the number of OFF(0)-to-ON(1) transitions of the input. This number is output as CVn OV. When this number reaches the Preset value, a discrete output parameter CVn OS goes ON(1) until Reset occurs. Table 4-21 describes the Counter prompts. See Table 4-2 for additional prompts. Prompt Range/Selections RANGE LOW...
Page 128: Table 4-22 Math Prompts
Programming Function Blocks and Features Math Performs math on up to 8 inputs using a single operator. Output is CVn OV. Division by 0 is indicated by CVn OV’s displayed value flashing 0. Table 4-22 describes the Math prompts. See Table 4-2 for additional prompts. Prompt Range/Selections INPUT A - INPUT H...
Page 129: Table 4-23 Free Form Math Prompts
Free Form Math The output CVn OV is the result of a user-specified equation. QWERTY keyboard may be used for easier equation entry. Table 4-23 describes the Free Form Math prompts. See Table 4-2 for additional prompts. Table 4-23 Free Form Math Prompts Prompt Range/Selections OUT LOW LIMIT...
Page 130: Table 4-24 Free Form Math Functions
Programming Function Blocks and Features For this function or value n (constant) Negation (-n) Value of Input A Value of Input B Value of Input C Value of Input D Value of Input E Value of Input F Value of Input G Value of Input H Subtract Multiply...
Page 131: Table 4-25 Logic Prompts
Logic The input or inputs are processed by a logic operator. Call the result of this logic operation “Result”. Result is a pulse that goes ON(1) when the logic is true, and OFF(0) when the logic is not true. Result is then processed according to the specified condition type and condition time.
Page 132: Table 4-26 Logic Operators
Programming Function Blocks and Features For this operator Definition If all programmed inputs are ON, Result is ON. If at least 1 programmed input is ON, Result is ON. Uses Inputs A and B only. If one and only one input is ON, Result is ON.
Page 133: Table 4-27 Free Form Logic Prompts
Free Form Logic Lets you enter up to 64 characters as a custom logic equation (EQ) containing inputs and logical operators. The result of this equation is called “Result”. Result is then processed according to the specified condition type and condition time. The final output is CVn OS. See Figure 4-6. Inputs Figure 4-6 Free Form Logic Signal Flow Table 4-27 describes the Free Form Logic prompts.
Page 134: Table 4-28 (A Or B) And C
Programming Function Blocks and Features Order of evaluation Parentheses () OR, XOR Example equation using operators and inputs (A+B)*C computes the result of (A OR B) AND C. Example equation using iteration The equation A+B*O computes the result of: (Input A OR Input B from current machine cycle) AND (Input A OR Input B from previous machine cycle). Table 4-29 shows some possible results of this equation.
Page 135: Table 4-31 Bcd Prompts
Converts up to 8 discrete inputs’ binary coded decimal into an unsigned integer and output the integer as CVn OV. For example, 00000100 = 4. On the instrument, when the enable is triggered, the set point program specified by the value of CVn OV is copied from internal storage to the Profile function block(s) where the profile(s) can be programmed or executed.
Page 136: Table 4-32 How Profiles Are Saved In Memory
Programming Function Blocks and Features Table 4-32 How Profiles Are Saved In Memory 1-programmer 2-programmer instrument instrument 1 Profile per Program 2 Profiles per Program This …contains This Program… this Profile Program… 3-programmer instrument 3 Profiles per Program …contains This …contains these Program…...
Page 137: Table 4-33 Function Generator Prompts
Function Generator This CV type can be used to characterize a valve (Figure 4-8) or an input signal (Figure 4-9). You enter a custom curve of up to 19 segments (20 X,Y coordinates). The input is compared with the X values and its corresponding Y value becomes the output CVn OV.
Page 138: Figure 4-8 Function Generator Configuration For Valve Characterization
Programming Function Blocks and Features Figure 4-8 Function Generator Configuration For Valve Characterization Figure 4-9 Function Generator Configuration For Input Signal Characterization FUNCTION GENERATOR INPUT FUNCTION GENERATOR INPUT Video Recorder – User Manual ANOTHER FUNCTION BLOCK...
Page 139: Table 4-34 Interval Timer Prompts
Interval Timer This timer counts down from the preset value in minutes. This time remaining is CVn OV. The timer has a single discrete output CVn OS which is ON(1) while the timer is actively counting or while RESET is ON(1), and OFF(0) while the timer has timed out to zero. When RESET/RUN switches ON(1) the timer resets to the preset value;...
Page 140: Figure 4-10 Periodic Timer
Programming Function Blocks and Features Periodic Timer Generates a discrete output pulse CVn OS which is ON(1) for 1 machine cycle (250ms, 500ms, 1 sec) at specified Start time and repeated at a specified Period thereafter. Use this to activate a discrete parameter at a particular time and at regular intervals.
Page 141: Table 4-35 Periodic Timer Prompts
Table 4-35 Periodic Timer Prompts Prompt Range/Selections SET UP TIMER See Table 4-36 for prompts Prompt Range/Selections PHASE NONE, DAILY, WEEKLY, MONTHLY PERIOD HOURS 0-23 PERIOD MINUTES 0-59 PERIOD SECONDS 0-59 RESET OFF, discrete parameter, 0, 1 START DAY MONDAY, TUESDAY…SUNDAY 1-31 START HOURS...
Page 142: Table 4-37 Mass Flow Prompts
Programming Function Blocks and Features Mass Flow By compensating for variations in fluid temperature and pressure, Mass Flow is used to obtain a more precise fluid flow measurement from an orifice plate developing a differential pressure. The output CVn OV is mass flow and is calculated from the following formula for U.S. Units Of Measurement: MF = FACTOR 1 x SQRT [DP INPUT x (PRESSURE INPUT+14.7) / (TEMPERATURE INPUT + 459)] where FACTOR 1 is calculated by user...
Page 143: Table 4-38 Carbon Prompts
Carbon Potential The Carbon Potential Control Function Block provides for weight percent (wt%) control of carbon in carburizing, hardening, and atmosphere generating applications. Table 4-38 Carbon Prompts Prompt Range/Selections PROBE TYPE NONE, AACP, SUPER SYS, MARATHON, FCC CARBON PROBE IN NUMBER, PARM, OFF PROBE TEMP INPUT NUMBER, PARM, OFF...
Page 144: Figure 4-11 Typical Carbon Potential Control Configuration
Programming Function Blocks and Features Probe Output LINEAR CARBON XXXXX.X POTENTIAL CONTROL 1250.0 INDIRECT 0.0 mV 1250.0 mV Probe Temp. TYPE K (typ.) XXXXX.X 2800.0 DIRECT F/SAFE DOWN LINEAR (Config as req’d by CO analyzer) CONSTANT Burn Off CONSTANT Furnace Temperature TYPE K (typ.) XXXXX.X -450.0...
Page 145: Table 4-39 Relative Humidity Prompts
Relative Humidity Outputs CVn OV relative humidity as a function of dry-bulb temperature, wet-bulb temperature, and atmospheric pressure. Table 4-39 describes the Relative Humidity prompts. See Table 4-2 for additional prompts. Table 4-39 Prompt Range/Selections RANGE LOW OFF or number RANGE HIGH DRY BULB TEMP OFF, analog parameter,...
Page 146: Table 4-40 F Sterilization Prompts
Programming Function Blocks and Features Sterilization The output CVn OV is a “kill time”, F sterilization process. F represents the number of minutes after which the microorganism population is decreased by one decimal or log unit. The F = ∑ [dt x (10 (T-T ref )/Z where: dt = time between F...
Page 147: Figure 4-12 Advanced Splitter (Default Outputs)
Advanced Splitter Output (ADV SPLITTER) This function can be used for heat/cool applications. It splits an input into 3 independently scaled outputs: CVn_A1, CVn_A2 and CVn_A3 (Figure 4-12). For each output, when the input is between IN LO LIM and IN HI LIM, the output is scaled between the OUT LO LIM and OUT HI LIM. Each output holds its OUT LO LIM value when the input <...
Page 148: Table 4-41 Advanced Splitter Prompts
Programming Function Blocks and Features Table 4-41 Advanced Splitter Prompts Prompt Range/Selections RANGE LOW OFF or number RANGE HIGH INPUT OFF, analog parameter, number FEEDBACK #1 OFF, AOn BC, LPn BC FEEDBACK #2 FEEDBACK #3 OUT#1 IN LO LIM OFF or number OUT#1 IN HI LIM OUT#1 OUT LO LIM OFF or number...
Page 149: Table 4-42 Standard Splitter Prompts
Standard Splitter Output (STD SPLITTER) This function can be used for heat/cool applications. It is a deadband-based splitter that divides a Split loop’s output (-100% to +100%) into two outputs CVn A1 and CVn A2, both of which are zero when the loop output is zero (Figure 4-14).
Page 150: Table 4-43 Scaling Prompts
Programming Function Blocks and Features Scaling The output CVn OV is a linear scaling of the input using the specified limits. Table 4-43 describes the Scaling prompts. See Table 4-2 for additional prompts. Table 4-43 Scaling Prompts Prompt Range/Selections IN LOW LIMIT OFF or number IN HIGH LIMIT RANGE LOW...
Page 151: Table 4-44 Signal Clamp Prompts
Signal Clamp If input is between Low Select and High Select, the output CVn OV equals the input. If the input exceeds these two limits, the output equals the preset value. Table 4-44 describes the Signal Clamp prompts. See Table 4-2 for additional prompts. Table 4-44 Signal Clamp Prompts Prompt Range/Selections...
Page 152: Table 4-45 1 Point Block Average Prompts
Programming Function Blocks and Features 1 Point Block Average (1 Pt Block Avg) Outputs a block mean average CVn OV of the input over the specified Average Period. A new sample of the input will be taken on every instrument scan cycle. The block average is only updated at the end of the Average Period.
Page 153: Table 4-46 Rolling Average Prompts
Rolling Average Outputs a rolling mean average CVn OV of the input over the specified Average Period. As new input samples are collected, old samples are discarded. The function will calculate a new average at equally spaced sample intervals. averaging period Sample interval = # of samples sum of samples...
Page 154: Table 4-47 Multiple Average Prompts
Programming Function Blocks and Features Multiple Input Average (Multiple Avg) The output CVn A1 is the instantaneous average of the assigned input points. The average is calculated every scan cycle. Table 4-47 describes the Multiple Average prompts. See Table 4-2 for additional prompts. Table 4-47 Multiple Average Prompts Prompt Range/Selections...
Page 155: Table 4-48 Cems Block Average Prompts
CEMS Block Average Outputs a block mean average CVn OV over the specified Average Period. The average is calculated from input samples taken at equally spaced Sample Periods. All samples are discarded at the end of the Average Period and the Average Period begins again. Samples are ignored when Calibrate Hold is ON(1).
Page 156: Table 4-49 Cems Rolling Average Prompts
Programming Function Blocks and Features Table 4-49 CEMS Rolling Average Prompts Prompt Range/Selections RANGE LOW OFF or number RANGE HIGH INPUT OFF, analog parameter, number RESET OFF, discrete parameter, 0, 1 TIME UNITS Seconds, minutes, hours, or days. AVERAGE PERIOD OFF or number FRAME PERIOD OFF or number...
Page 157: Program Alarms
4.13 Program Alarms You can program an alarm to be triggered by any extreme input value. To program alarms, select “PROGRAM ALARMS” on the Main Program Menu. Select an alarm to program. REFERENCE When an alarm occurs, it produces an output pulse which can be configured to trigger a discrete output (such as a relay).
Page 158: Program Totalizers
Programming Function Blocks and Features 4.14 Program Totalizers The optional totalizer integrates an analog value over time. With the input being viewed as a flow rate, the function outputs a running total TLn OV over time. ATTENTION Totalizers which exceed the value 999,999 may only be displayed on the dedicated “Totalizer Display”. If the value is programmed on other displays or stored to disk, when it exceeds the programmed limits the value may be truncated and the value will flash.
Page 159: Table 4-51 Totalizer Prompts
Prompt Range/Selections INPUT SOURCE OFF, analog parameter, number. OUTPUT LOW LIMIT OFF or number OUTPUT HIGH LIMIT ACTION DOWN DEMAND CONTIN TIME UNITS SEC, MIN, HOUR, DAY ON DEMAND INPUT OFF, discrete parameter, 0, PRESET OFF, analog parameter, number ZERO CUTOFF OFF or number RESETTABLE YES, NO...
Page 160: Program Profiles
Programming Function Blocks and Features 4.15 Program Profiles Profile programming is explained in Section 5. Video Recorder – User Manual...
Page 161: Program Constants
4.16 Program Constants Constants can be programmed here and their values edited Online. Select a constant to program. Table 4-52 describes the Constant prompts. See Table 4-2 for additional prompts. Table 4-52 Constant Prompts Prompt Range/Selections VALUE OFF, analog parameter, number INPUT LOW LIMIT OFF or number INPUT HIGH LIMIT...
Page 162: Figure 4-16 Example Of Constant Destination
Programming Function Blocks and Features Destination defined To program Loops and Analog Outputs, you select the Program Control Loops or Program Analog Outputs from the Program Mode Menu, then program each menu item. Some of these menu items, such as proportional band or slew limits, are function block parameters; that is, they can be programmed with numerical values only.
Page 163: Copy Block
4.17 Copy Block Use Copy Block to copy the setup of any function block to another channel of the same function block. For example, if you have programmed AI1 and want AI2 to have the same settings, use Copy Block. If desired, you can make program changes to AI2 after the copy is complete.
Page 164: Program Displays
Programming Function Blocks and Features 4.18 Program Displays You can configure up to 10 primary displays using one or more display formats shown in Figure and assign them to appear in specified order when the Display button is pressed. S P1 200.00 1500.0 0 -200.00...
Page 165 TE MP 2 TE MP3 TE MP 4 TE MP1 10 00.00 50 0.00 25 0.00 500.00 2261.50 DEGF 0.00 0.00 0.00 0.00 A TEMP 1 HIGH 51 0.00 28 2.00 12 4.00 27 3.00 D EGF DEGF DEGF DEGF 6 Point Vertical Bar Graph 4 Point Vertical Bar Graph (V_4 _B AR)
Page 166: Table 4-54 Display Setup Procedure
Programming Function Blocks and Features Display Setup Procedure Table 4-54 describes the display setup procedure. Step Select Program Displays from the Program mode menu. For each display format desired (trend, bar graph, panel display, unit data), specify points to be displayed.
Page 167: Table 4-56 Paper Chart Speed Equivalents To Time Base Selections
Table 4-56 Paper Chart Speed Equivalents to Time Base Selections Instrument Time/Screen 5 minutes 15 minutes 30 minutes 1 hour 2 hours 4 hours 8 hours 24 hours 7 days 31 days Set Up Trend 2 - 3 - 4 See Table 4-55 for prompts.
Page 168: Table 4-57 1 Trend Group Live Buffer Size
Programming Function Blocks and Features Live Trend Buffer Size Table 4-57 1 trend group live buffer size Number of Number of points in the pages in the 5 min trend buffer 52,9 35,2 26,4 21,1 17,6 15,1 13,2 11,7 10,6 Table 4-58 2 trend group live buffer size Number of Number of...
Page 169: Table 4-59 4 Trend Group Live Buffer Size
Table 4-59 4 trend group live buffer size Number of Number of points in the pages in the 5 min trend buffer 13,2 Programming Function Blocks and Features 4 Trend Groups Display length 15 min 30 min 1 hr 2 hrs 39,6 79,3 158,6...
Page 170: Table 4-60 Set Up Bar Graph 1 Prompts
Programming Function Blocks and Features Set Up Bar Graph 1 Table 4-60 describes the prompts for setting up Bar Graph 1. Table 4-60 Set Up Bar Graph 1 Prompts Prompt Range/Selections POINT #1 – OFF, analog parameter, POINT #12 numbers Set Up Bar Graph 2 - 3 - 4 See Table 4-60 for prompts.
Page 171: Table 4-64 Assign Displays To Keys Prompts
Assign Displays to Keys Your instrument has 4 display keys. You can assign a total of 10 displays to these keys. Pressing the Display 1 key ( ) accesses the format you assign to Display 1. Display 2 key ( 2 and Display 3 key ( Table 4-64 describes the prompts for assigning displays to keys.
Page 172 Programming Function Blocks and Features Table 4-64 Assign Displays To Keys Prompts (continued) Prompt Range/Selections DISPLAY 1 FORMAT DISPLAY 2 DISPLAY 10 TREND BARGRAPH ROTATION RATE LOOP PROFILE Select one of the following display formats. The corresponding format will be shown when the Display keys are pressed.
Page 173: Enable Features
4.19 Enable Features Features can be restored to or removed from menus and displays simply by turning them On (ENABLE) or Off (DISABLE) here. Disabled functions and their data are not destroyed or erased—they just cannot be viewed on the display. For example, a programmed constant retains its value and continues to function in calculations whether it is disabled or enabled.
Page 174: Program Security
Programming Function Blocks and Features 4.20 Program Security Security lets you protect certain menu items and functions from unwanted or accidental access. Access to a secured item requires entry of a 3-digit master or operator code. Select “PROGRAM SECURITY” to display the Security menu (if security is active, you will be prompted to enter the master code before continuing).
Page 175: Serial Communications
Serial Communications is an optional feature that lets the instrument exchange data with a host device (a PC running Honeywell or other compatible software) on an RS422/485 data link. Using Modbus RTU protocol, this link can be used to transfer configurations and data. Set up the link as follows.
Page 176: Set Clock
Programming Function Blocks and Features 4.22 Set Clock To assure data, alarms, and events are properly time stamped, the clock must be properly set. The clock uses military time. Select "CLOCK" from the main Program menu. Enter the date and time with the following prompts. Table 4-68 describes the Set Clock prompts.
Page 177: Load/Store Configuration
4.23 Load/Store Configuration Instrument configurations can be stored to and loaded from floppy disk. The front door must be closed. Configurations have filename extension .LNC. Table 4-69 describes the Load/Store Config prompts. Table 4-69 Load/Store Config Files Prompts Prompt Range/Selections FILE01 STORE CONFIG TO DISK...
Page 178: Scan Rate
Programming Function Blocks and Features 4.24 Scan Rate Scan rate is the time required to measure inputs, execute function blocks (AI, Loops, AO, DI, DO, CV, etc.) and update outputs. It is also known as the machine cycle, scan cycle, and update rate. The Scan Rate prompt lets you set the scan rate of the instrument to a value slower than the maximum rate allowed by the hardware.
Page 179: Select Language
Programming Function Blocks and Features 4.25 Select Language SELECT LANGUAGE on the Main Program Menu changes the instrument’s language to: English Spanish German French Italian Video Recorder – User Manual...
Page 180: Data Storage
Programming Function Blocks and Features 4.26 Data Storage Overview Data Storage lets you store trends, unit data, alarms, events, and diagnostics in separate files on a floppy disk for later analysis and review (replay). Data can be reviewed onscreen or on a PC with SDA data analysis software or the TrendManager Pro V5 software suite.
Page 181 Set Up New Schedules This item contains setup menus for all data sets. Select it to specify what data to store and how to store it. If a type of data storage is not scheduled, no disk file will be created for it. ATTENTION If you make any changes to any item under SET UP NEW SCHEDULES, you must initialize using new schedules to activate those changes.
Page 182: Table 4-72 Prompts For Storage Setup Of Trends, Alarms, Events, Diagnostics
Programming Function Blocks and Features Table 4-72 Prompts For Storage Setup Of Trends, Alarms, Events, Diagnostics Prompt Range/Selections POINT #1 - Analog or discrete parameter POINT #12 STORAGE MODE CONTIN, BATCH, or NONE COPY DISPLAY SETUP LOW RATE Seconds: .5, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 20, 30, 40, 50 Minutes: 1, 2, 3, 4, 5, 10, 15, 20, 30, 40, 50...
Page 183: Table 4-73 Stored Events
Trend Data 2, 3 & 4 Trend Data 2, Trend Data 3 and Trend Data 4 use the same prompts as in Table 4-72. Alarms Alarm data storage consists of a complete log of alarms, including time of occurrence, time of clearing, value of the alarm parameter, the alarm sense (high, low, etc.) and the batch identification number, if present.
Page 184: Table 4-74 Unit Data Prompts
Programming Function Blocks and Features Diagnostics Data storage for Diagnostics is a complete log of all diagnostic messages. It includes the diagnostic code or identifier message and its time and date of occurrence. Setup is done with the following parameters: STORAGE MODE, ROLLOVER, DIAG SAMPLES, EXTERNAL ENABLE, SELECT FILENAME.
Page 185 Table 4-74 Unit Data Prompts (continued) Prompt Range/Selections SELECT FILENAME FILE PROD UNIT CONFIG KILN CALIB FURNCE DEMIN BATCH LINE ZONE START HOUR 0-23 START MINUTE 0-59 START MONTH JAN-DEC START DAY 1-31 START YEAR 1994-2038 INTERVAL DAYS 0-31 INTERVAL HOURS 0-24 INTERVAL MINS 0-59...
Page 186: Table 4-75 Disk Capacity Prompts
Programming Function Blocks and Features Disk capacity Choose DISK CAPACITY under SET UP NEW SCHEDULES menu to allocate trend storage. See Table 4-75. Table 4-75 Disk capacity Prompts Prompt Range/Selections DISK CAPACITY TREND#1 LO RATE Seconds: .25, .5, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 20, 30, 40, 50 Minutes: 1, 2, 3, 4, 5, 10, 20, 30, 40, 50...
Page 187: Table 4-76 Disk Storage Capacity Of Ls120 Or Zip Disk
Table 4-76 Disk Storage Capacity of 100MB ZIP disk (The values shown below are for each Trend file) 1 sec. 5 sec. 13.5 days months days months 29.8 days days 24.4 days days 18.9 days days 16.2 days days Programming Function Blocks and Features 24000000 bytes per file.
Page 188: Table 4-77 Disk Storage Capacity For The 1.44 Mbyte Floppy Disk
Programming Function Blocks and Features Batch Control Specify a discrete parameter as the START/STOP switch for all data types whose storage mode is set to “BATCH”. ATTENTION If no BATCH CONTROL parameter is defined here, batch storage is started/stopped instead through the menu item BATCH STATE.
Page 189: Setpoint Profiler
What’s in this section? Section 5 explains the functions, configuration, and operation of the Setpoint Profiler. Terminology is defined and all prompts are explained. Section Overview of the Setpoint Profiler Components of a profile Parameters that control a profile’s execution How to set up a profiler How to load and run a profiler 5.1 Overview of the Setpoint Profiler...
Page 190: Figure 5-1 Setpoint Profiler Schematic
Setpoint Profiler Guaranteed soak configurable per segment. Discrete outputs to indicate profile state, including Ready, Run, Hold, In Progress, and At End. Up to 16 Discrete outputs (Events) programmable per segment. Four user-selectable methods for ramping. Automatic recycling of the profile. Up to four levels of looping within profile.
Page 191: Figure 5-2 Single And Multi-Phase Profiles
Two types of profiles A single phase profile is the simpler of the two profile types. It does not contain startup and shutdown segments. It runs from Segment 1 to the last segment. A multiphase profile divides the profile into three phases: the startup phase, the batch phase, and the shutdown phase.
Page 192: Components Of A Profile
Setpoint Profiler 5.2 Components of a profile Two PVs available Each profile can monitor up to 2 process variables. The second PV is for monitoring a second variable related to your process. The value of each PV is compared with the value of the profile. If the difference between either PV and the profile value exceeds specified amounts, the profiler will Hold (soak), if enabled to do so.
Page 193: Figure 5-4 Time Ramp Type
To properly terminate a Val/Dur profile you must program the segment beyond the last segment with the following: The value you want the program to “end” with. Looking at Figure 5-3, the last segment is a soak, thus the Value of segment #6 should be set to the same value used in segment #5. Any other value will cause segment #5 to be a “ramp”...
Page 194: Figure 5-5 Rate Ramp Type
Setpoint Profiler Rate Ramp Type Each ramp segment’s TIME specifies the rate at which the profiler output will reach the next soak segment, where the rate is specified by the prompts TIME/TIME UNITS. The ramp segment’s VALUE prompt is not used. Ramp segments Time = rate at which next soak Value will be reached, in PV units/Time Units.
Page 195: Figure 5-6 External Ramp Type
Ramp segments Time = amount profile will change toward next soak Value when the Ramp Increment discrete switches on. Value = not used with ramp segment. Segment #3 Value Segment #1 Value Segment #1 Time ATTENTION External ramp type’s TIME prompt is in engineering units of the PV, not in time units (seconds, minutes, or hours).
Page 196: Figure 5-7 Guaranteed Soak And Hysteresis
Setpoint Profiler Soak segment All soak segments have a beginning VALUE and a TIME during which that value is maintained. This is true regardless of the ramp type used. Guaranteed Soak Guaranteed soak will Hold the profile value if either PV to the profile (typically a Control Loop’s PV) deviates specified amounts above or below the profiler output.
Page 197: Table 5-1 Example Of Segment Events
Segment Events Each segment contains 16 programmable discrete event outputs whose ON/OFF states- specified by you -can be used to trigger other discrete functions. The segment’s event states are activated at the beginning of the segment and are maintained unless changed by the next segment in the profile. See Table 5-1 .
Page 198: Figure 5-9 Example Of A Segment Loop
Setpoint Profiler Segment Loops You can program up to four segment loops within a profile. A segment loop is one or more consecutive segments which must repeat a selected number of times before proceeding to the next segment outside of the loop. Segment loops are specified by the parameters REPEAT COUNT, FROM SEGMENT #, and TO SEGMENT #.
Page 199: Parameters That Control A Profile's Execution
5.3 Parameters that control a profile’s execution Coordinating operation of multiple profilers In a multi-profiler instrument the profiles in a program can be totally unrelated to each other, that is, you can give them different times and settings. If you want the profilers to be coordinated, you must configure each profiler that way.
Page 200: Figure 5-10 Hot Start
Setpoint Profiler Table 5-2 Parameters That Control Profiler Execution (continued) Parameter name Definition HOLD Holds a profiler at its current position. Profiler’s Elapsed Time continues but Segment Time stops until Profiler is started again. Hold is activated by online operator menu or by a discrete input.
Page 201: Figure 5-11 Fast Forward
Parameter name Definition FAST FAST FORWARD is a way to test for proper FORWARD functioning of the profiler’s events and outputs, without having to wait for the profiler to execute at its normal speed. When FAST FORWARD is ON, the profiler will run at a speed determined by the TIME MULTIPLIER parameter.
Page 202: Figure 5-12 Shutdown
Setpoint Profiler Parameter name Definition SHUTDOWN When Shutdown is activated by a discrete input or by the operator menu, the profiler jumps from the batch phase to the shutdown phase of a multiphase profile. The shutdown phase begins at the segment defined by the parameter BATCH LAST SEGMENT+1.
Page 203: How To Set Up A Profiler
Parameter name Definition GUARANTEED See Guaranteed Soak on page 182. SOAK HOLD LEVEL/EDGE EDIT Grants access to the profile’s segments edition page, see table 5-5. 5.4 How to set up a profiler Up to 4 profilers can be programmed, depending on the options on your instrument. There are two menus for programming a profiler: PROGRAM PROFILERS in the Program menu, and SETPOINT PROFILES in the Online menu.
Page 204: Table 5-3 Program Profiler Prompts
Setpoint Profiler Prompt DISPLAY LO LIM OFF or number DISPLAY HI LIM OFF or number PV #1 OFF, analog parameter, number PV #2 OFF, analog parameter, number START Discrete parameter, 1, 0, or OFF RESET/RUN Discrete parameter, 1, 0, or OFF HOLD Discrete parameter, 1, 0, or OFF ADVANCE...
Page 205: Table 5-4 Setpoint Profiles Prompts
Setpoint Profiles Menu (in Online mode) This menu lets you define profile ramp and soak segments and associated parameters, and store and load programs to and from floppy disk or memory. See Figure 5-13 for allowable and non-allowable storage. To access the Setpoint Profiles menu: Press the Menu button until a main menu is displayed.
Page 206: Figure 5-13 Allowable And Non-Allowable Program Storage
Setpoint Profiler Table 5-4 Setpoint Profiles Prompts (continued) Prompt LOAD PROGRAM Files with .LNS extension. FROM DISK LOAD PROGRAM PROGRAM NUMBER FROM MEMORY Figure 5-13 Allowable and Non-Allowable Program Storage Range/Selections Select a program to load into the Setpoint Profiler function block. Press Enter to load. Existing profiles in the instrument will be replaced by the profiles in the program being loaded.
Page 207: Table 5-5 Edit Profile Prompts
Prompt Range/Selections RAMP TYPE VAL/DUR, TIME, RATE, EXTERNAL TIME UNITS SECS, MINS, HOURS EDIT SEGMENTS GUAR SOAK LO LIM OFF or number GUAR SOAK HI LIM OFF or number HYSTERESIS OFF or number BATCH FIRST 0-63 SEGMENT BATCH LAST 0-63 SEGMENT Table 5-5 Edit Profile Prompts See 4 types of ramp segments on page 178.
Page 208 Setpoint Profiler Table 5-5 Edit Profile Prompts (continued) Prompt AUTO CYCLE OFF, ON AUTO CYCLE COUNT 0-254 EDIT PROFILE LOOPS LOOP #1-4 FROM SEGMENT # 1-63 TO SEGMENT # 1-63 REPEAT COUNT 1-999 JUMP FROM 0-63 SEGMENT JUMP TO SEGMENT 0-63 Range/Selections Select ON to have the profile (or batch phase if...
Page 209 Setpoint Profiler Table 5-5 Edit Profile Prompts (continued) Prompt Range/Selections Definition TIME MULTIPLIER Number Time Multiplier determines the speed at which the profiler will run when in Fast Forward mode. It is used for testing the profiler’s execution. See Fast Forward. When FAST FORWARD is ON(1), the profiler will run at a speed determined by the TIME MULTIPLIER parameter.
Page 210: Table 5-6 Edit Segments Prompts
Setpoint Profiler Editing Segments Use the following prompts to map out each segment’s value, time, and events. Up to 63 segments are programmable per profile. Prompt NEXT SEGMENT PREVIOUS SEGMENT VALUE OFF or number AUX VALUE OFF or number TIME OFF or Positive number GUAR SOAK #1 ON or OFF...
Page 211: How To Load And Run A Profiler
5.5 How to load and run a profiler Overview From the Setpoint Profile Trend’s menu you can: load a profiler from memory load a profiler from storage media start a profiler hold a profiler reset a profiler advance a profiler shut down a profiler view profiler events view profiler details (profiler elapsed time, segment time remaining, profiler length in seconds, PV...
Page 212: Table 5-7 How Profiles Are Stored In Memory
Setpoint Profiler ATTENTION The following procedures assume the instrument has been programmed to display the Setpoint Profiler as a trend. To program displays, see section 4.18 Program Displays. How to load programs from memory using Online menu Programs stored in memory are identified by number (1-48) depending on instrument model number. Each program stored in memory contains one to four profiles, depending on your instrument.
Page 213: Table 5-8 Procedure To Load A Program From Memory Using Online Menu
Table 5-8 Procedure To Load A Program From Memory Using Online Menu Step Action Press the Display button to change to online mode. Press the Menu button to display the online menu. Press Decrement button to highlight Setpoint Profiles. Press Enter. Press Decrement button to highlight Load Program From Memory.
Page 214: Table 5-10 How Profiles Are Stored On Disk
Setpoint Profiler How programs are stored on a disk Programs are saved to disk as a file name, number, and .LNS extension. Unlike memory storage, you can specify which profiles you want stored as a program. Disk capacity depends on the number of profiles in the program.
Page 215: Table 5-12 Procedure To Load A Program From Disk
How to load a program from disk Table 5-12 Procedure To Load A Program From Disk Step Press the Display button to change to online mode. Press the Menu button to display the online menu. Press Decrement button to highlight Setpoint Profiles.
Page 216: Table 5-13 Profiler Starting Procedure
Setpoint Profiler How to start a profiler A profiler can be started from the Ready, Hold or End state. Step Press Display button until the Setpoint Trend is displayed. Press Tab button to display the profile menu. Cursor is on Start. Press Enter. ATTENTION A profile can also be started by pressing the F1 button, but only if that profile’s START parameter was configured as SY1 F1.
Page 217: Table 5-14 Profiler Hold Procedure
How to hold a profiler Step Perform steps 1 and 2 from Start procedure (Table 5-13). Press Decrement button to move cursor to Hold. Press Enter. ATTENTION A profile can also be put on HOLD by pressing the F2 button, but only if that profile’s HOLD parameter was configured as SY1 F2.
Page 218: Table 5-16 Profiler Advance Procedure
Setpoint Profiler How to advance a profiler to the next segment Step Place profiler in Hold. Press Decrement button to move cursor to Advance. Press Enter. To resume running the profiler, select Start. How to shut down a profiler Step Place profiler in Hold by performing Profiler holding procedure (Table 5-14).
Page 219: Table 5-18 Event Viewing Procedure
How to view event status Step Perform steps 1 and 2 from Start procedure (Table 5-13). Press Decrement button to move cursor to Events. Press Enter. How to view profiler details Step Perform steps 1 and 2 from Start procedure (Table 5-13).
Page 220: Table 5-20 Summary Viewing Procedure
Setpoint Profiler How to view profiler summary display Step Perform steps 1 and 2 from Start procedure (Table 5-13). Press Decrement button to move cursor to Summary. Press Enter. Press the Tab button to move the cursor to the TREND of the desired profiler, then press Enter.
Page 221: Table 5-21 Segment Editing Procedure
How to edit a profile’s segments Profile may be in Run, Ready, End, or Hold to edit segments. CAUTION For value duration ramp type, it is recommended you do not edit the currently running segment or the next segment. Doing so may prematurely terminate the segment, that is, the profiler may jump to the next segment.
Page 222 Setpoint Profiler Video Recorder – User Manual...
Page 223: Online Operations Using Primary Displays
6. Online Operations Using Primary Displays 6.1 Overview Online operation using primary displays consists of using the buttons to view and interact with the displays that were assigned to the Display button. Pressing the Display button changes to online mode and accesses the displays assigned to this key.
Page 224: Interacting With Primary Displays
Online Operations Using Primary Displays 6.2 Interacting With Primary Displays Interacting with Setpoint Trend Display When a Setpoint Trend display is shown (Figure 6-1), press the Tab key to display options for controlling the profilers execution. See Section 5.5 for details. PROFIL01 0.00 0:00:00...
Page 225: Table 6-2 Point/Detail Menu Prompts
Interacting with Live or Replay Trends With a live vertical or horizontal trend on the display, press Tab key to access the Point/Detail menu. When replaying (stored) trends this menu is always displayed. From this menu you can press the Tab key again to advance the scoreboard at the top of the display to the next point in the trend.
Page 226 Online Operations Using Primary Displays Table 6-2 Point/Detail Menu Prompts (continued) Prompt FIND Lets you display the trend from a certain time. A list of times will appear on the display, as shown. FIRST is the oldest time available in the trend. LAST is the most recent time available.
Page 227: Figure 6-3 Vertical Trend At 2X Zoom
TEMP7 1941.5 1500.0 12:15 11:45 11:15 A ALARM 1 HIGH Figure 6-3 Vertical Trend at 2X Zoom Video Recorder – User Manual Online Operations Using Primary Displays DEGF 2500.0 Zoom cursor Amount of magnification...
Page 228: Table 6-3 Stop Panel_4 Display Rotation Procedure
Online Operations Using Primary Displays Interacting with Panel_4 Display To stop the rotation of the panel display on a precise point series, follow the procedure in Table 6-3. 14 JAN 99 PRESSURE Table 6-3 Stop Panel_4 Display Rotation Procedure Step Action Press Tab key Press Tab key...
Page 229: Figure 6-5 Loop Displays
Interacting with Loop Displays AUTO A D DISK FULL 1000.00 0.00 PV 405.00 SP 405.00 A SP1 Loop 2 Bar Summary L P3 1000.0 1500.00 1200.00 0.00 0.00 PV 405.00 623.00 1054.00 622.00 SP 405.00 1040.00 15.0 10.0 M S1 A S1 M S2 Loop 4 Bar Summary...
Page 230: Table 6-5 Interacting With Loop Displays
Online Operations Using Primary Displays To perform this action Move the cursor box to another area of the display Toggle the loop between Auto and Manual modes Lower or raise the loop output (displayed as %). Increase or decrease Setpoint value Access the loop tuning parameters Table 6-5 Interacting With Loop Displays...
Page 231: Display Messages And Symbols
6.3 Display Messages and Symbols Overview Messages and symbols will appear in different areas of the display to inform the operator of a variety of conditions. The area across the bottom of the display (Figure 6-6) is reserved for messages that require the operator to take action.
Page 232: Table 6-6 Messages And Symbols At Bottom Of Display
Online Operations Using Primary Displays Description of Messages and Symbols Table 6-6 Messages and Symbols at Bottom of Display Message/Symbol A A A A followed by text description of alarm D D D D followed by text description of diagnostic Data Storage Messages UPDATING DISK CHECKING DISK...
Page 233: Table 6-7 Messages And Symbols Elsewhere On Display
Table 6-6 Messages and Symbols at Bottom of Display (continued) Message/Symbol Color GENERAL ERROR Yellow Yellow White White Table 6-7 Messages and Symbols Elsewhere on Display Message/Symbol Color REVIEW or REPLAY White White Flashing between ****** Same as and value data point Flashing between value Same as...
Page 234 Online Operations Using Primary Displays Video Recorder – User Manual...
Page 235: Online Operation Using Menus
7. Online Operation Using Menus 7.1 Overview Online operation involves interacting with displays and with menus. This section describes how to interact with the online menus. The Online Menu is accessed by pressing the Display button, then the Menu button. Or, you can choose SET MODE from any menu to change the mode.
Page 236: Data Storage
Online Operation Using Menus 7.2 Data Storage Overview Data Storage lets you store trend data, unit data, alarms, events, and diagnostics for later review onscreen or on a PC with SDA software or the TrendManager Pro V5 software suite. Setup and configuration of Data Storage is described in Section 4.26;...
Page 237: Table 7-3 Disk Status
How data is stored To provide continuity of storage when the disk is removed, the data storage feature buffers data internally for a period of time based on the storage rate and amount of storage data. Since storage files and Setpoint program files may not be stored on the same disk, you can swap the storage disk with a configuration disk for up to the buffered data time period while loading Setpoint programs without losing storage data.
Page 238 Online Operation Using Menus Initialization errors If an initialization error occurs, one of the following messages may appear. Error message BEZEL OPEN WRITE-PROTECTED DISK ERRORS DISK IS MISSING Checking current storage setup To see what is being stored and when, select DATA STORAGE SETUP, then select REVIEW CURRENT SCHEDULES.
Page 239: Table 7-4 Storage Start/Stop Controls
Starting and stopping storage Data Storage can be started and stopped three ways. At the highest level, the ENABLE STORAGE menu item enables or disables all data storage. At the next highest level, EXTERNAL ENABLE enables or disables storage for each file type (Trends #1-3, Alarms, Events, Diagnostics, Unit Data). At the lowest level, storage for each file type is started and stopped with one of two controls: a menu item BATCH STATE or a discrete parameter BATCH CONTROL.
Page 240: Table 7-5 Data Storage Replay Procedure
Online Operation Using Menus Checking Data Storage Status The Data Storage Status display is accessed from the Online data storage online menu. It is also accessed by pressing any display button, if the button has this display assigned to it. See Figure 7-1. T im e rem ain ing for e ach tre nd (da ys, h ou rs, m inu te s)
Page 241 ATTENTION If you are replaying data from a “non-current disk,” keep in mind that the instrument will continue acquiring data and holding it temporarily in its active memory (RAM) until you insert a proper disk for storage. If you spend too much time replaying data, the instrument could run out of active memory space. If this occurs, a storage full warning message will be displayed.
Page 242: Access Summaries
Online Operation Using Menus 7.3 Access Summaries Summaries are available for all points, alarms and diagnostics in the instrument. Display alarm summary Alarms are set up as part of the instrument configuration procedure (Section 4.13). Up to 12 alarms can be configured.
Page 243: Table 7-6 Alarm Acknowledgment Procedure
What happens during an alarm A flashing red alarm indicator appears on the bottom of all screens. (The alarm must be acknowledged to stop the flashing.) On displays where the alarm point appears, the value is red and a red indicator appears. The alarm is entered into the active alarm summary which can be viewed at any time.
Page 244: Table 7-7 Diagnostic Acknowledgment Procedure
Online Operation Using Menus What happens during a diagnostic • A flashing blue diagnostic indicator will appear on the bottom of the screen. • The diagnostic message will be entered into the diagnostic summary which can be viewed at any time.
Page 245: Table 7-8 Delete All Diagnostics Procedure
Step Select ACCESS SUMMARIES from the Main On-Line Menu. Select DELETE ALL DIAGNOSTICS and press Enter to delete all diagnostics from the summary. Press Menu or Display buttons to exit the menu. Product Information Select this item to display the logo screen, which includes the product identification, software version number, part number of the PROM, and serial number.
Page 246: Data Entry
Online Operation Using Menus 7.4 Data Entry Data Entry lets you enter or revise data online. Choices available depend on installed options and enabled features (see “Enable Features” in Section 4.19). Edit Alarm Setpoints Select this item to display a list of alarms and their setpoints. If the setpoint is a numeric value, it can be changed on this display using the Up Arrow, Down Arrow and Left Arrow buttons.
Page 247 Online Operation Using Menus Select this item to display a list of all resettable Totalizers and their current values. If the Totalizer is non-resettable it will not appear. You may use this display to reset one Totalizer, or all at once. Note that some or all Totalizers may be configured to be non-resettable.
Page 248: Setpoint Profiles
Online Operation Using Menus 7.5 Setpoint Profiles For instructions on this menu, see Section 5.4 How to set up a profiler, Tables 5-4 and 5-5. For instructions on common operator tasks with the Setpoint Profiler, see Section 5.5. Video Recorder – User Manual...
Page 249: Tune Loop
7.6 Tune Loop This option lets you tune (change) various loop parameters online. These tunable parameters depend on the loop type in use and are described in Section 4.8, Program Control Loops. Also, the following menu choices are available. Prompt Range/Selections LOOP TYPE STD, ADV, SPLIT, ON OFF,...
Page 250 Online Operation Using Menus Table 7-9 Tune Loop Prompts (continued) Prompt Range/Selections RESET #1 0.005-99.99 repeats/minute RATE #1 0.02-10.00 minutes PROP. BAND #2 RESET #2 RATE #2 MANUAL RESET -100 to +100 SUPPRESS YES, NO OVERSHOOT PRETUNE SET TIMEBASE 5 MIN, 15 MIN, 30 MIN, 1 HR, 2 HR, 4 HR Determines the period of time for a repeat of the proportional gain output.
Page 251: Figure 7-2 Control Loop Tuning Display
Table 7-9 Tune Loop Prompts (continued) Prompt Range/Selections DISPLAY TUNING TREND Select this to display the actual tuning trend with PV and setpoint (Figure 7-2). Data collection for this trend display will continue as long as the display shows either the trend or the Loop Tuning Menu.
Page 252: Table 7-10 Stages Of Pretune
Online Operation Using Menus Pretune Loop Pretune calculates optimum values for a loop's Proportional Band/Gain, Reset and Rate by analyzing the reaction of the loop to a "step change" in setpoint or output. After these new tuning values have been calculated you have the option of applying (installing) or not applying them to a preselected tune set of the loop.
Page 253: Table 7-12 Pretune Identifying & Calculating Prompts
Table 7-11 Pretune STOPPED Prompts (continued) Prompt Range/Selections OUTPUT SIZE -100 to +100 SP STEP SIZE -100 to +100 START Before Starting Pretune Before starting Pretune, configure/adjust the loop as follows: Auto/Manual: Either mode is acceptable. Changing the loop mode after starting pretune will abort the pretune, causing an error message to appear.
Page 254: Table 7-13 Pretune Complete Prompts
Online Operation Using Menus Table 7-12 Pretune IDENTIFYING & CALCULATING Prompts Prompt SETPOINT RUN TIME ABORT Pretune COMPLETE menu Table 7-13 describes the Pretune COMPLETE prompts. Prompt STATUS PB/GAIN RESET RATE INSTALL ABORT (continued) Definition Current working set point value of the loop being tuned. This is a read-only prompt.
Page 255: Table 7-14 Pretune Abort Messages
Pretune Abort messages One of the following messages is displayed when an unusual event has aborted the pretune. “PTA” means “Pretune Abort.” Message PTA-WARM START PTA-WENT OFFLINE PTA-LOOP STATUS PTA-AM SEL CHNGE PTA-SP SEL CHNGE PTA-OUT MOVED PTA-SP MOVED PTA-LOOP OS PTA-LOOP NOT CFG PTA-BAD STEP SIZ PTA-ONOFF LOOP...
Page 256: Set Mode
Online Operation Using Menus 7.7 Set Mode Select this item to change the operating mode of the instrument to Program or Maintenance. These operating modes are discussed in Sections 4, 5, and 8. 7.8 Review Programming This item is visible only if enabled under Enable Features in the Program mode. Select this item to see how the instrument is configured.
Page 257: Maintenance
8.1 Overview This section includes information on maintenance through the Maintenance Mode menu using some off- line utility programs and diagnostics procedures. To avoid voiding the warranty, contact your service provider before attempting any service or repair of this instrument. Maintenance Mode is an off-line mode for maintaining proper operation of the instrument and setting defaults.
Page 258 Maintenance What’s in this section The following topics are explained in this section. Topic Routine Maintenance Set Mode Calibrate Analog Inputs AO Module Calibration Off-line Diagnostics Database Services Reset Unit Product Information Mains Frequency Warm Start Time Demo Video Recorder – User Manual Page...
Page 259: Routine Maintenance
8.2 Routine Maintenance CAUTION Calibrate the instrument routinely to ensure conformity to specifications. Calibration is to be performed by qualified service personnel only. Clean the front panel with a damp cloth. If needed, use a detergent containing no abrasives. Always clean the front panel with the bezel closed.
Page 260: Ao Module Calibration
Maintenance Additional calibration selections allow you to perform other calibration procedures: CALIBRATE REFERENCE JUNCTIONS – for calibrating the two Cold Junction (CJ) references on AI module. COPY ANALOG INPUT CALIBRATION – for copying calibration values from one AI module channel to another.
Page 261: Off-Line Diagnostics
WARNING Disconnect power to all terminals before connecting or disconnecting calibration leads. Hazardous voltage is present on the mains terminals and may be present on other terminals. More than one switch may be required to de-energize the unit before servicing. Failure to comply with these instructions could result in death or serious injury.
Page 262: Database Services
Maintenance 8.7 Database Services The following table describes the prompts. Prompt CLEAR ALL MEMORY FULL UPGRADE INCREMENTAL UPGRADE SOFTWARE UPGRADE 8.8 Reset Unit Select this item to reboot the unit after making changes to Mains Frequency. This function clears all RAM buffers (storage and display) and accumulated values of some function blocks (Calculated Value timers, totalizers, and control loop integral) are reset to initial values.This function does not clear memory.
Page 263: Warm Start Time
8.11 Warm Start Time The instrument will start up in one of three modes based on the length of time power is off. First Time Start First time start occurs when the unit is being powered up for the first time or when the memory clear services maintenance routing is executed.
Page 264: Demo
Maintenance 8.12 Demo This item is intended primarily for sales demonstrations. It causes the instrument to display a series of simulated values. NOTICE Never turn the demo on in an instrument that has already been configured to support its true application without first saving the instrument’s configuration to floppy disk.
Page 265: Diagnostic And Error Messages
9. Diagnostic and error messages 9.1 Diagnostic Messages The instrument executes diagnostic routines during instrument start-up and during maintenance procedures such as calibration. It also monitors online operation for both process faults and instrument errors. Error messages Table 9-1shows messages that may appear on the instrument displays if a diagnostic condition is detected, along with the action you should take.
Page 266: Table 9-2 Internal Error Messages
Diagnostic and error messages Internal error messages In addition to diagnostic messages, error messages are presented to indicate an internal fault. To correct the problem, Table 9-2 lists suggested actions you should take, in the order you should take them. To acknowledge or clear the error message, see Section 7.2 Access Summaries. Error message NONV RAM ERROR PROCESSOR EXCEPTION...
Page 267 Error message 1. Check for noise. SLOT CARD FAILURE 2. Check AI card connection. 3. Replace AI card. 1. Check for bad floppy disk. STORAGE FAILURE 2. Run disk diagnostic on the disk drive. 3. Check seating of floppy cables. 4.
Page 268: Loop Error Indicators
Diagnostic and error messages 9.2 Loop Error Indicators When a loop's PV, SP2, or other parameter fails, the loop switches to its default/failsafe condition, indicated by certain display symbols flashing. To return the loop to its desired condition, correct the failure.
Page 269: Error Messages
9.3 Error Messages Overview Sometimes errors occur while you are programming or loading a configuration into your instrument. In most cases the instrument displays a descriptive error message. For example, if you try to program a function block incorrectly, the instrument tells you the problem. Table 9-4 lists these error messages along with a description of each one and what action to take.
Page 270 Diagnostic and error messages Error Incorrect Input The Advanced Splitter CV was programmed with coordinates input limits for Output#2 (A2) only, or for Output#1 & #3 (A1 & A3) only, or for Output#3 (A3) only. Incorrect Number of The function was not programmed with the minimum number of parameters.
Page 271 Error Low Limit Outside of AI circuit low limit is < voltage limit of -500 mV. Circuit Low limit Outside of For thermocouple or RTD, Range Low limit is < the Table low limit for that type. Low Output Limit less A current output (CAT) low limit is less than zero.
Page 272 Diagnostic and error messages Error Trend Has Too Many Data Storage cannot store more than 3 points at 1/4 Points For Rate Selected second scan rate. Type Does Not Exist A function block type was loaded that does not exist. For example, you loaded a Profile but the unit does not have the Profile option.
Page 273: Parts
Kit Description Power supply HMI board CPU board Interconnection board Relay output board with terminals DC digital output board with terminals AC digital output board with terminals Analog output board with terminals Contact closure input board with terminals Universal analog input board with terminals DC digital input board with terminals AC digital input board with terminals Keyboard card...
Page 274 Parts Kit Description Backlight Cable of LCD screen Door switch Kit Description Terminal block (for low voltage inputs) Terminal block (for alarm relays, ac/dc I/Os) Battery Panel mounting kit Internal 100MB ZIP disk drive Kit of 4 resistors 250 ohms Fuse MISCELLANEOUS CONSUMABLES...
Page 275 Portable case - 46190112-501 Spare case galvanised - 46190104-501 Spare painted case - 46190104-503 Door complete with LCD, glass and latch - 46193090-501 Door complete with LCD, glass and lock - 46193090-502 Door complete with LCD, plastic window and latch - 46193090-503 Door complete with LCD, plastic window and lock - 46193090-504 CPU board - 46193304-501 Power supply -...
Page 276 Parts Backlight 46193065-501 Backlight igniter 46193060-501 LCD screen 46193062-501 cable of LCD screen 46193261-501 Keyboard card 46193310-501 I n te r c o n n e c tio n b o a r d 4 6 1 9 0 3 2 6 - 5 0 2 H M I b o a r d 4 6 1 9 3 3 0 1 - 5 0 1 D o o r s w it c h 4 6 1 9 3 1 1 2 - 5 0 1 I n t e r n a l 1 0 0 M B Z IP d r iv e 4 6 1 9 3 1 1 0 - 5 0 1...
Page 277: Appendix A
A.1 Security Bypass Procedure Overview Your instrument has a security bypass code which allows you to enter secured areas of the product.. Use this bypass code if you have forgotten or lost the master and/or operator security code. Bypass procedure Step When you are prompted for the master or operator security code, use the Increment and Decrement buttons to select the bypass code 783.
Page 278 Appendix A Video Recorder – User Manual...
Page 279: Safety
SIKKERHESKRAV For at undgå elektrisk stød med mulighed for personskade, skal alle sikkerhedsbestemmelser i denne manual følges nøje. Dette symbol advarer brugeren om en potentiel berøringsfare, såfremt der kan være adgang til den livsfarlige netspænding. Beskyttende jordterminal. Terminalen er forberedt for og skal forbindes til beskyttelses- jordledning i henhold til stærkstrømsberkendtgørelsen (DK).
Page 280 Safety VEILIGHEIDSVEREISTEN Ter vermindering van het gevaar van elektrische schokken die lichamelijk letsel kunnen veroorzaken, dient u alle veiligheidsaanwijzingen in dit dokument te volgen. Dit symbool waarschuwt de gebruiker voor een potentieel schokgevaar wanneer toegang bestaat tot onderdelen die onder gevaarlijke spanning staan. Beschermende aarde-aansluiting.
Page 281 TURVALLISUUSMÄÄRÄYKSET Noudata tämän ohjeen kaikkia turvaohjeita välttääksesi sähkötapaturman vaaraa. Tämä merkki varoittaa käyttäjää sähköiskun vaarasta paikassa, missä voi koskettaa vaarallisia jännitteitä. Suojamaaliitin. Kytke maadoitsjohdin tähän liittimeen. Jos laitetta käytetään olosuhteissa, joihin sitä ei ole suunniteltu, käyttöturvallisuus voi heikentyä. Älä vaihda mitään komponettia tai osaa, jota valmistaja ei ole määritellyt käyttäjän vaihdettavaksi. Asennus ja johdotus on tehtävä...
Page 282 Safety CONSIGNES DE SECURITE Pour réduire tout risque de décharge électrique qui pourrait provoquer une lésion corporelle, respectez toutes les consignes de sécurité de cette documentation. Ce symbole avertit l'utilisateur d'un risque électrique potentiel lorsqu'il peut avoir accès à des éléments sous tension. Borne de mise à...
Page 283 SICHERHEITSHINWEISE Befolgen Sie alle Sicherheitshinweise in diesen Unterlagen, um das Risiko eines Stromschlags zu verringern, der zu Körperverletzung führen kann. Dieses Symbol warnt den Benutzer vor eventueller Berührungsgefahr, wo lebensgefährliche Spannungen zugänglich sein können. Schützende Erdung. Für den Anschluß der schützenden Erdung der Versorgungssystemleitung.
Page 284 Safety ΑΠΑΙΤΗΣΕΙΣ ΑΣΦΑΛΕΙΑΣ Για την αποφυγή του κινδύνου ηλεκτροπληξίας που θα µπορούσε να προκαλέσει προσωπικό τραυµατισµό, ακολουθείστε όλες τις υποδείξεις ασφαλείας αυτών των οδηγιών. Το σύµβολο αυτό προειδοποιεί το χρήστη για πιθανό ηλεκτρικό κίνδυνο σε περίπτωση επαφής µε επικίνδυνα µέρη της συσκευής. Προστατευτικό...
Page 285 NORME DI SICUREZZA Per ridurre i rischi di scariche elettriche che potrebbero causare alle persone, seguire tutte le precauzioni circa la sicurezza indicate in questa documentazione. Questo simbolo avverte del pericolo di scossa elettrica nelle aree in cui sono accessibili conduttori sotto tensione.
Page 286 Safety SIKKERHETSKRAV Følg alle retningslinjene i dette dokumentet, slik at du reduserer risikoen for elektrisk støt og mulige personskader. Dette symbolet advarer brukeren om tilgjengelige terminaler med farlige spenninger og en potensiell fare for elektrisk støt. Jordingsterminal. kabelen for jording av systemet skal tilknyttes til denne terminalen.
Page 287 INSTRUÇÕES DE SEGURANÇA Para reduzir o risco de choque eléctrico que pode causar danos corporais, seguir todas as normas de segurança contidas nesta documentação. Este símbolo avisa o utilizador sobre um eventual perigo de choque quando são acessíveis voltagens sob tensão perigosas. Terminal de protecção de terra.
Page 288 Safety NORMAS DE SEGURIDAD Para reducir el riesgo de choque eléctrico el cual podría causar lesiones personales, seguir todas las indicaciones de este documento. Este símbolo previene al usuario de un riesgo potencial de descarga cuando se puede acceder a corrientes de tensión peligrosas. Terminal de tierra de protección.
Page 289 SÄKERHETSFÖRESKRIFTER För att reducera riskerna av elektriska chocker som kan orsaka personskador, följ alla säkerhetsföreskrifter i denna dokumentation. Denna symbol varnar användaren för risk för elchock vid tillfällig åtkomst av spänningsförande del. Anslutning av skyddsjord. Avsedd för anslutning av elsysternets skyddsjordsledare. Om utrustningen används på...
Page 290 Safety Video Recorder – User Manual...
Page 291: Index
Action State ... 104, 105 Advancing profile ... 204 Alarm acknowledging... 229 edit setpoints ... 232 history ... 229 summary... 228 what happens during ... 229 Alarm History ... 229 Analog Input Adjust ... 232 Analog inputs program ... 87 Analog outputs program ...
Page 292 Index Edit Alarm Setpoints ... 232 Edit Constants ... 232 Editing profile segments ... 207 Electrical Units... 89 Enable storage ... 166 Error messages, diagnostics ... 251 Error Messages ... 255 Events middle of ramp segment ... 183 Exponential notation how to display...
Page 293 Panel display interacting with... 214 Parts ... 259 Pretune Abort messages... 241 COMPLETE menu... 240 STOPPED menu ... 238 Pretune Loop ... 238 Primary display, example ... 217 Process Variable ... 90 Product Information ... 231 Product Information ... 248 Profile advance...
Page 294: Sales And Service
For application assistance, current specifications, pricing, or name of the nearest Authorized Distributor, contact one of the offices below. ARGENTINA CANADA Honeywell S.A.I.C. Honeywell Limited Belgrano 1156 The Honeywell Centre Buenos Aires 300 Yorkland Blvd. Argentina Toronto, Ontario Tel. : 54 1 383 9290 M2j 1s1...

Honeywell VRX180 User Manual

1 Introduction

2 Installation

3 Programming and Operating Concepts and Procedures

4 How to Program Function Blocks and Features

5 Setpoint Profiler

6 Online Operations Using Primary Displays

7 Online Operation Using Menus

8 Maintenance

Quick Links

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Summary of Contents for Honeywell VRX180