Stange SE-707 Operating Manual
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Stange SE-707 Operating Manual

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Program Controller SE-707
Operating Manual
Program Controller
SE-707
Documentation: October 2018
© 2018 by STANGE Elektronik GmbH
1
Subject to technical modifications

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Summary of Contents for Stange SE-707

  • Page 1 Program Controller SE-707 Operating Manual Program Controller SE-707 Documentation: October 2018 © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 2: Table Of Contents

    6.3 M ..........................27 OUNTING DISMOUNTING THE CARD 6.4 C ............................28 ONNECTING THE POWER SUPPLY 6.5 P ......................29 ACKAGING THE CABLE WITH SHIELD CONNECTION 6.6 C RJ45 ........................30 ONNECTING THE PROGRAMMING INTERFACE © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 3 8.2.6 Load programs to the operating mode ........................ 63 8.2.7 Sort programs ..............................63 8.2.8 Store and load program list ..........................64 8.2.9 Loops ................................. 65 8.3 C ................................66 ONFIGURATION 8.3.1 Standard Settings ............................... 67 © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 4 8.3.9.1 Device information ............................... 173 8.3.9.2 Software information..............................173 8.3.9.3 Licence information ..............................174 8.3.9.4 Device health................................174 8.3.9.5 Digital In-/Outputs ................................ 174 8.3.9.6 Save diagnosis data............................... 174 INDEX ....................................175 © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 5: General

    This symbol marks references, whose non-observance can result in damages, malfunctioning and/or loss of the device. Note This symbol emphasizes hints and information, which are to be considered for an efficient and trouble free operation of the device. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 6: Eu-Conformity

    The device does not fall into the range of application of the low-voltage directive EEC 73/23/EEC (electrical equipment for the use within certain voltage limits (low-voltage directive); changed by 93/68/EEC) (This declaration follows closely to EN 45 014) © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 7: Liability And Warranty

    Note ! The content-wise specifications, texts, designs, pictures and other representations are copyrighted and are subject to further industrial property rights. Each abusive utilization is liable to prosecution. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 8: Safety

    • Wires and devices have a correct shielding. • Wiring and line run must be executed correctly. • The electric equipment is grounded and has a uniform reference potential. • Special applications need specific EMC measures. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 9: Grounding Of Inactive Metal Parts

    • maintenance and inspection intervals are to be kept. • device, operating equipment and waste products resulting with the manufacturing are disposed environmentally compatible and in agreement with legal regulations. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 10: Operating Personal

    A soft, dry cloth is adequate and provides good service for cleaning the front panel. 2.11 Repairs Repairs at SE-707 may only be made by STANGE Elektronik GmbH. In this case please contact the technical support of STANGE Elektronik GmbH.

  • Page 11: Manufacturer-Address

    E-mail: 2.14 Disposal STANGE units can be recycled. Send back the device delivered free to STANE Elektronik GmbH for disposal. Or contact a certified electronic waste disposal centre for environmentally acceptable recycling and disposal of your old devices. Particularly to be considered is: •...

  • Page 12: Transport, Packing And Storage

    For the transport of the device is to be used excluding the original packaging. 3.3 Storage Keep packages up to the assembly locked and considering of the environmental conditions for storage. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 13: Technical Data

    Complete after approx. 48 hours operation System time Real-time clock (RTC) Date/Time Accuracy 50 ppm (max. 131 seconds deviation per month) Time levelling Manual or over network time server Memory card SD card Data logger © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 14 9-pole SubminD connector, electrically isolated Processor core Freescale™ i.MX 6 ARM Random access memory 1 GB DRAM Memory for mains failure safe data 1 MB SRAM, battery backed (PLC retain memory) © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 15: Software Specifications

    - Online language switching with Unicode language support (Russian, Chinese etc.) (depending on stage of extension Control system SE-707 are designed for STANGE ECS control system connection "Open" control system interface In the system the PLC program has priority over the visualization.

  • Page 16: Function Basic Data

    100 characters 100 characters Limit values Tolerances Formula Formula term Constants Analogue variables Number of Modbus data words Variables string length 32 characters 32 characters Analogue value multiplexer BCD/BIN decoder © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 17 Plant picture Screensaver C-level formula 2, option 1, option Humidity calculation formula Fieldbus interface „netJACK“, Profinet IO DEVICE Yes, option Yes, option Fieldbus interface „netJACK“, Profibus-DP Slave Yes, option Yes, option © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 18: Installation Of The Industrial Control

    AC power wiring and high-energy, rapidly-switched DC wiring. 5.2 General mounting instructions All SE-707 devices are mounted from the front, i.e. in a control panel. They are fastened from the rear with the supplied fixing frame and 2 securing nuts.

  • Page 19: Installation Dimension

    The device requires a mounting cut-out of B x H: 354 x 238 mm +/-0,5mm The thickness of the front panel may not exceed 7 mm. For better sealing: Use mounting frame rearwards. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 20: Installation Depth

    Program Controller SE-707 5.4 Installation depth Installation depth SE-707: The Installation depth for the SE-707: 99.2 mm. Length of the mounting clips: 65 mm behind the mounting plate © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 21: Front Panel Installation

    Minimum distance for side by side mounted devices: 25 mm Control panel or cabinet Nipple Note The mounting frame is only required if the function of the sealing is needed. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 22: Start-Up

    Always take safety into consideration as you design the grounding and wiring of your SE-707 system. Electronic control devices, such as the SE-707, can fail and can cause unexpected operation of the equipment that is being controlled or monitored. For this reason, you should implement safeguards that are independent of the SE-707 to protect against possible personal injury or equipment damage.

  • Page 23: Overview Of The Connections

    6.2 Overview of the connections Element 24 V DC power supply (+24V/PE/GND) Alarm connector (A1,A2) for Watchdog and alarm output CAN-connector 9 pol. Sub-D USB 1 and 2 Ethernet RJ45 Option slot © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 24: Function Of The Led's At The Back Of The Device

    This LED gives information about the condition of the Watchdog: - LED off: No error or device off - LED flashes red: The Watchdog has triggered, a serious problem is available. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 25: Turn-Switch For Plc Operating Mode Selection

    6.2.3 System Watchdog 6.2.3.1 General The SE-707 device hardware has a hardware watchdog with an output as potential-free semi-conductor relay output lead through at a device connector. If the Watchdog output is really evaluated depends on the discretion of the plant manufacturer! 6.2.3.2 Mode of operation...

  • Page 26: System Logger Entry

    The “good” state of the alarm relay is an opened contact. For each single configured alarm can be freely determined in the alarm processing of the SE-707, whether there should be an influence on the alarm relay in case of alarm, or not.

  • Page 27: Mounting / Dismounting The Sd Card

    The SD™ medium must be kept in an antistatic box. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 28: Connecting The Power Supply

    6.4 Connecting the power supply The SE-707 device belongs to protection class 3. The system power supply must be provided with a 24VDC SELV voltage (safety extra-low voltage). The internal voltage conditioning unit is equipped with a galvanic isolation. The PE connection is directly connected to the housing potential.

  • Page 29: Packaging The Can Cable With Shield Connection

    The preparation of the data and signal cables is an important factor for the electromagnetic compatibility (EMC) of this SE-707, both in terms of interference immunity and emission. The RS232 interface and CAN interface are connected via D sub miniature plug connectors in accordance with DIN 41652.

  • Page 30: Connecting The Programming Interface Rj45

    PC must be in the same subnet work (e.g. 192.168.0.xxx). Connector assignment: RJ45 Pin-No. Signal Description connector TXD- TXD+ RXD+ RXD- Socket, 8pole RJ45 Cables connected to the programming interface must be laid separately from the low-voltage cables. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 31: Connection Can

    11-bit identifier. The type of configuration selected depends on the software protocol. The baud rate can be selected in a wide range, and only the standard CiA baud rates are implemented (recommended 125kBaud max.). The SE-707 is the master on the CAN bus. Connector Pin-No.
  • Page 32 Baud rate and cable lengths Baud rate Max. length 20 kBaud 1600m 50 kBaud 800m 100 kBaud 400m 125 kBaud 320m 250 kBaud 160m 500 kBaud © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 33: Connection Of The Alarm Socket

    Voltage: 24 V AC/DC max. Current: 300 mA max. On-resistance: 4 Ohm max. Alarm connector: Wago multipole connector Art.-No. 733-106, maximum cross section: 0,5mm² Function Watchdog and Alarm at SE-707: Watchdog No voltage Alarm 1 - contact: Open Closed Open...
  • Page 34 The following table contains the most important electrical data concerning PROFIBUS certified cable: Parameter Value Impendence 150 Ω ± 15 Ω Capacity per units < 30 pF/m length Loop resistance 110 Ω/km Wire gauge 0,64 mm Table: Characteristics of PROFIBUS certified Cable © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 35 Second stage bootloader is waiting for firmware. Yellow Bootloader netX (= romloader) is waiting for second stage bootloader. Power supply for the device is missing or hardware defect. Table: System status LED states © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 36 “on” for 100 ms, followed by “off” for 100 ms. Flashing, acyclic The indicator turns on and off in irregular intervals. Table: LED state definitions for the PROFIBUS DP Master protocol © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 37: Connection Of The Profinet Io Device (Slave) Interface (Option)

    TERM RX – Receive Data – TERM Bob Smith Termination TERM Table: Ethernet interface channel 0 and channel 1 pin assignments Note Auto-crossover function is supported by the netJACK modules. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 38 "on" for approximately 50 ms, followed by "off" for 50 ms. The indicator turns on and off in irregular intervals to indicate low Ethernet activity. Table: LED state definitions for the PROFINET IO-Device protocol © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 39: Connection Of Apc With The Se-707

    Program Controller SE-707 6.11 Connection of a PC with the SE-707 6.11.1 Cabling The communication from the PC to the control takes place ideally over Ethernet and TCP/IP protocol. With a direct connection, without Ethernet-Hub or Switch, a crossed "Crossover" cable is to be used. Control-laterally a standardized RJ45 socket is attached.

  • Page 40: Length Of The Network Line (Segment Length)

    <Properties> the window with the LAN connection properties is opened. In the window <Local Area Connection Properties> the item <Internet Protocol Version 4 (TCP/IPv4)> must be selected by double click. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 41: Settings Of The Ip-Address In The Device

    6.12.5 Settings of the IP-address in the device By the delivered visualization application With the delivery of a SE-707 control, a visualization application is installed, which permits to adjust the IP-address. → How the address has to be entered is explained in chapter Host Interface.

  • Page 42: Operation

    Program Controller SE-707 7 Operation 7.1 Start-up behaviour The SE-707 carries out a system test after power on. The PLC does not switch to Run or Stop until no hardware errors have been found. The system test includes the following: •...

  • Page 43: Start Up Behaviour Starting

    After switching on the tension, the user program is loaded from the CompactFlash™ into the RAM and the PLC is started. Procedure: Power on Hardware- o.k. PLC- Programm present Battery o.k. Reset-cold Start (PLC.INI) Startup=STOP Startup=WARM (Default) PLC-Status: PLC- Status: PLC- Status: PLC- Status: „Power on“ „Stop“ „Run“ „System Fault“ © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 44: Operating Dialogue Of The Control Software

    Note: The unit operation depends on the configuration of the respective unit(s) and values. Therefore the layout of the display can deviate. This example shows however the basic operation of the SE-707 devices. 8.1 Operation Warning If you do changes in OPERATING mode, the changes immediately affect process operation.

  • Page 45: Start Screen

    The device starts with the operation overview screen after switching on. At first you have to log on by operating the “LogIn” button. Login access data for the first device start for the administrator are: User: administrator, Password: Stange .Replace the default password by your own password! →...

  • Page 46: Manual Operation For Set Value And Tracks ("Manual")

    Further set values are displayed Track+ Further tracks are displayed Jump Jump in program The left value scale can be adapted to the respective set value by touching the scale. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 47: Program Jump

    • or a program is loaded from the program memory into the operating memory. The entered start time can be up to 31 days in the future. Another future start time is not accepted. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 48: Program Change In Actual Segment

    - Set values - Tracks - Change process step number - Insert segment - Copy segment - Delete segment © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 49: Controller

    The Y(+) and Y(-) buttons are only active, if the displayed controller is from “3-point-step” type and the state of the controller output is already in manual mode by means of the “Manual” button. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 50: Pid Parameter

    - The control parameters (Xp, Tn, Tv) are calculated from the amplitude and period of the oscillation - The parameters resulting from the optimization are automatically registered in the currently active parameter set of the controller and used directly after terminating the optimization. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 51: Control Zone Tolerance Values / Limit Values

    The SE-Designer is a visualisation tool with the functionality to create the graphic representation and the integration of process- oriented data for the plant overview screen. You will find further information in the SE-Designer operating manual. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 52: Alarms

    Appearing alarms are displayed by red highlighted text “Alarm” on all pages in OPERATION menu: - flashing = new value alarm - static = alarm is acknowledged but is still present © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 53: Alarm History

    These three state messages may occur in combination: Overvoltage at 0..10 V or overcurrent at 0..20 mA or under 4 mA at 4.. 20 mA or overvoltage at thermocouple = „B↓“; Overcurrent at measuring range 4..20 mA = „↑“. Switchover via button: Limit values Tolerances Formula © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 54: Process Data Limit Values

    - State: “OK” as long as no error occurs “ ↑” in case of range overshooting “ ↓” in case of range undershooting “ F” in case of a calculation error (for instance division by 0) © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 55: Operating-Hours Meter (Option)

    - Batch No. - Program - Program No. - Process Start - Process End - Process Time - User - Data Count - Alarms - File Name - File Size - State © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 56: Logger Graph (Option)

    The button "Ruler" enables the setting of the width of the ruler. "Group +/-" Switching over between the groups. "Chart" Assignment of the chart diagram colors. "Pens" Pen configuration for the assignment of pen colors. → Logger Configuration © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 57: Logger Header (Option)

    → Logger Parameter 8.1.25 Configuration The device configuration overview screen is called by operating the “Configuration” button. Here the pre-settings of the operating parameters are made → see chapter Configuration. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 58: Login

    The user login of the login code is called by operating the "LogIn" button. The SE-707 automatically recognizes which user rights belong to this code and displays the user name on the left side next to the “Operation” button after the user and the corresponding code was entered.

  • Page 59: Login Level Authorisation

    View Program Loops Change Program Segments/Loops Import Program Export Program Process Data View Process Data View Process Data (AV, LV, TOL, Formula) Change Limit Values Change Tolerances Change Variable Value © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 60 Data Logger View Data Logger Data Logger General View Log Data Administrate Log Data Import Log data Configure Logger Pins Process Start Edit Batch Name Edit Header Data Edit Comment Text © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 61: Program

    Already occupied program numbers cannot be used. Input a program name and confirm with “OK”. Thereafter the screen view changes to the segment overview in order to add desired segments to the program. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 62: Programming Segments

    Program Controller SE-707 8.2.3 Programming segments Programming the SE-707 takes place segment wise; each segment is defined by a process step and the segment time which is valid for all set values and digital tracks. New segments are always inserted below the actual marked segments in the column “Segments”.

  • Page 63: Delete Programs

    The operating program cannot be loaded if a program is already running in the controller. 8.2.7 Sort programs In order to sort the programs in the program overview select the “Sort name” and/or “Sort No.” button and the programs are sorted accordingly. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 64: Store And Load Program List

    Note Data loss possible! A possibly already existing older file “PROGRAMS.ZIP” is overwritten on data medium during storing! programs device program list deleted/overwritten during loading! © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 65: Loops

    If program segments are inserted or deleted the loops must be accordingly adapted! If the final program segment is programmed with a time of 00:00:00 it must not be the end segment of a loop! © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 66: Configuration

    Select the “Configuration” button on the OPERATION screen page in order to reach the configuration level. The following configuration settings can be made by selecting the desired configuration menu and operating the “Enter” button. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 67: Standard Settings

    Time delay step 2 [Minutes], value range 0 up to 1440 Brightness step 2 [%],value range 0..100 The screensaver can be equipped with a customer logo. Please contact our support for further information. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 68: Host Interface

    Program Controller SE-707 8.3.1.3 Host Interface The settings for the Ethernet interface between SE-707 and control system (ECS, InTouch, etc.) are made here. Functions for the host interface: Function Input Range Description Interface description, 24 Unicode characters Ethernet protocol Control system interface protocol, Ethernet (RJ45 socket)

  • Page 69: Siemens Modbus Connection (Option)

    Power failure time for programmer in minutes, 0...6000 (00:00:00...100:00:00) Program loops Yes / No Program Number Min Program number, range lower limit (1...9999) Program Number Max Program number, range upper limit (1...9999) © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 70: User Interface

    - Connection Data Server: Here the IP-address of the device which should be connected can be set for the remote control software. - Exit Application: Terminates the remote control. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 71: Hardware

    “CAN base from version 3” is used in the configuration. Further information about the configuration: CAN and/or SIOS operating manual. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 72: Hardware Options

    Start number of analogue inputs in process image CAN base I/O slot 4 8.3.2.2 Hardware Options The Profinet I/O-Device and Profibus DP (Slave) interface for fieldbus modules is selected and established under the hardware options. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 73: Profinet Io Device Interface

    • The device name may not have the form n.n.n.n ( n = 0...999 ) • The device name may not begin with the character string "port-xyz-" ( x,y,z = 0...9 ) (Source: https://support.industry.siemens.com) © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 74 1) Values are determined automatically and cannot be changed; they are only displayed for information and should facilitate the project planning of data for Profinet Controller! 2) The reserve bytes serve for providing corresponding gaps for value extensions in the assignment of the data modules (“Reserve Values”). © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 75 1) Values are determined automatically and cannot be changed; they are only displayed for information and should facilitate the project planning of data for Profinet Controller! 2) The reserve bytes serve for providing corresponding gaps for value extensions in the assignment of the data modules (“Reserve Values”). © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 76: Profibus-Dp Slave Interface

    Data name in the device Description, value range Description Block description, max. 24 characters Target range Digital input Digital outputs Function inputs Function output Target address Value depending on target range, 1 .. 2737 © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 77 Function FA1600 Module available FA1601 Communication runs FA1607 Data exchange active (watchdog triggered) FA1608 Module missing / defect / no licence FA1609 No communication FA1615 Data exchange inactive (watchdog deactivate) © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 78: Profibus Function Description

    Controlling and monitoring take place via simple twisted two-wire connection line. By this way the measured value can be transferred together with the device status. PROFIBUS-PA is applicable as well in intrinsically safe areas. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 79 DP master (the DPM1 which had been defined during projecting). Multi-master systems work with medium bus cycle times. Figure 3: PROFIBUS-DP multi-master system © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 80 The PROFIBUS transmission protocol offers two ways of bus access: the token-passing communication among complex bus participants (masters) and subordinately the master-slave communication among the masters and the peripheral devices (slaves). Figure 4: All 3 PROFIBUS variants use a uniform bus access procedure © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 81 –off of stations, or a step-by-step system start-up. Later enhancements have no influence on stations which are already in operation; there is automatically recognized whether a participant has failed or has been inserted to the system. → Connecting the PROFIBUS-DP-Slave Interface © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 82 Variablenwert, Zählerwert, 1 AO (256..257) Analogue outputs PAW 256 Stellwert Y, Y Heizen. Y Kühlen, 1 AO (258..259) 2 AO values PAW 258 Regler-Istwert, Regler-Sollwert Figure 5: Process image structure © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 83 Data length of the digital output modules amounts 8 Bytes; • Data length of the analogue input modules amounts 1 word; • Data length of the analogue output modules amounts 1 word. Figure 6: Example for a PROFIBUS-DP system © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 84 All analogue outputs Configuration examples: Plug-in place Configuration Examples 1*DI, 1*DO, 1*AI, 1*A0 4*DI, 1*DO, 2*AI, 2*AO 4*DO, 4*AO • Transfer the projected configuration to the target system (= CPU315-2DP). © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 85 PLC (Figure 8). Figure 7: Properties of the DP slave Figure 8: Physical assignment of the DP slave © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 86: Functions

    Functions for digital and analogue inputs/outputs: Function Input Range Parameter: Number Number of digital inputs Digital inputs Max. 24 characters Function Input Range Parameter: Number Number digital outputs Digital outputs Max. 24 characters © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 87: Actual Values

    Range: -9.99999E15 to +9.99999E15 Number of filter values 0…9 Number of sequenced values which are ignored if they are located in the “filter window” Filter window 00,01…99,99 % (related to actual value range) © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 88 ) If current is measured, the supplied 50 Ω-resistance must be connected to the voltage input (0..+10V) of the appurtenant channel if using STANGE CAN-IW8XL and CAN-IW4XL cards. The resistance causes a voltage drop of 0 (0.2)..1 V, which is converted correspondingly, provided the correct measuring range has been selected.
  • Page 89 ATTENTION! The function may be only activated if cyclic actual values come in like the STANGE CAN periphery, because measured values are "thrown away". If values come in e.g. over the Profibus-Slave module, the actual value would deviate from the actually...
  • Page 90 For each actual value up to 5 correction point are freely definable. After the input of the number of correction points the actual value correction point input and the definition of the correction values takes place. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 91 1400 Δx = Δ AV Measuring value – 3 = m · Δx = 0,005 (1400 – 900) = 2,5 1400 = 5,5  AV = 1405,50 °C 1400 Display © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 92 If the table of the older device should not be entered sorted in ascending order, differences in the actual value processing result. In this case the result must be checked necessarily and where required the correction table adapted.) © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 93 XL modules. If several actual values are configured “fast” for these modules by mistake, then only the last actual value of the corresponding module is measured favoured. Thermocouples cannot be measured favoured. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 94: Analogue Outputs

    Number of the selected operand in “Function Code” Output functions Normal Invers Scaling Output range 0..10 Volt, 0..20 mA, 4..20 mA Scaling factor Input range: -9.99999E15 to +9.99999E15 Scaling offset Input range: -9.99999E15 to +9.99999E15 © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 95 Factor = 0.5, Offset = 50; the DAC-value amounts to a range of 50...100 % (e.g. 5...10 V). Example for CAN slave: Factor = 0.1, Offset = 500, setpoint value range = 0...450.0; the slave value is in a range between 500 and 545. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 96: Free Linearization Curves

    The actual value range is defined by the largest and the smallest entry range, i.e. these values correspond to 0...100 % of the value range. (See the example on the following page) © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 97 To define the pictured linearization curve, therefore, six pairs of values are required. The range configured for the appurtenant actual value (see CONFIGURATION Actual Values) is only relevant for a contingent DAC output. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 98: Set Values

    None, PLC time in sec. / min. / h. Ramp or Jump Ramp / Jump Gradient code None, 1/second, 1/minute, 1/hour Manual values at program load Delete / not delete © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 99 Program stop at the end of each segment; static input Continuation at Segment END ("Step by Step") Program continuation at the end of a segment in "step by step" mode; impulse input © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 100 The set value is moved to the new value continuously in the programmed segment time and is calculated step by step. The output intervals ("steps") are defined to 0.1 sec). © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 101: Control Zones

    Number for substitute actual value, depending on type Substitute set value type None, set value, actual value, formula value, variables Substitute set value number Number for substitute actual value, depending on type © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 102 Control zone range ≥ range of controller actual value ≥ range of controller setpoint value Absolute values of range The minimum cycle time controls the cycles only on average. There is no guarantee that this time is kept under any conditions © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 103 Configuration of the analog Y output Digital Output 2 = ”Cooling”): for a linear PID controller L FO 0049 “Heating”, CZ 1 = O 0001 L FO 0050 ”Cooling”, CZ 1 = O 0002 © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 104 For all controllers the manipulated variable Y is calculated and displayed with a very high resolution as REAL number. The manipulated variable Y of a linear controller can be outputted as analogue value over the periphery (Modbus, CAN, Profibus, Profinet, …). A resolution of 12 Bit (=4096 steps) is used for the STANGE Elektronik periphery. 2-point PID Controller The Manipulated Variable Output Y of the linear controller is the basis for the 2-point PID controller;...
  • Page 105 The switching distance defines the distance between both operating ranges heating and cooling. Here the ON/OFF-turning points are confirmed for each operating range with the hysteresis for heating and cooling. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 106 The switching distance of Split-Range Controller contains a “–“ or “+” as sign, with which an overlapping ATTENTION or a dead zone between the “Heating” and “Cooling” outputs can be realized. Compared with the previous devices (SE-4xx, SE-5xx) this sign can be entered exactly inverted! © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 107 In normal calculation processes this constant C 2 has no perceptible effect. AV 2 AV 3 (air quantity) (gas quantity) The X1 formula value is applied as substitute actual value to the “air-gas-relation” control zone. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 108 The input of the manual value is possible (is also represented in the display), but an output of a manual value (analogue output/function output) takes place if the controller is active again. Controlling takes place during switching on from the last working point for all types of controllers. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 109 …). The tolerance values are entered during OPERATION. The input takes place in % from the controller range! Change-over to the substitute setpoint value or the substitute actual value is then taken into consideration. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 110 • The Y-MANUAL-Mode is not influenced by this function. • Controller A and controller B can be scaled independently from each other for a “Heating/Cooling” controller (split range) in difference to 4xx and 5xx devices! © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 111 Note that the SE-707 controller scan rate of all control zones is set fixed to 0.1 seconds. For the older devices the scan rate could be set variable between 0.1 and 1.0 seconds (task tables).
  • Page 112 Curve 2.) Here the value of parameter 43 is reduced in relation to curve 1 that leads to a closer process of the transient procedure. Curve 3.) An enlargement of parameter 43 leads to a further bend of the transient procedure, it is transient "softer". © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 113 - if function input FI 1144 is activated (impulse of 200 msec). After the storage function output FO 1304 is set automatically for acknowledgement, and reset when Y-tracking is started again. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 114 Slighter damping; stronger reaction upon Earlier “switch-off” before reaching setpoint interferences value; contingently slow approach to the setpoint value Higher damping; slighter reaction upon Later “switch-off” before reaching setpoint Smaller interferences value; contingently overshooting © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 115 Xp = ∆x x 2 x 100 % Tn = 6 x Tv Tv = 0,1 x T Xp = ∆x x 3,4 x 100 % Tn = 0,73 x T © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 116 Xp = 1,7 x F Tn = Tg Tv = 0,5 x Tn Xp = 2,9 x F Tn = 1,2 x Tg Parameters automatically determined are registered under the just selected parameter set. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 117 Tolerance alarm: FO990 at zone 1, FO998 at zone 2 etc.; this output is triggered if at least one tolerance deviation is available during actual value input comparison of the controller. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 118 (FO990 ..) takes place. A possibly configured replacement actual value comes not into play for the determination of tolerances. The replacement actual value is used in connection with the actual value break. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 119 Break 512.5 Break Break 507.0 Break Break Break 450.0 Break Break Break Break Max repl. Break Break Break Max. aver. value The colored highlighted fields have to be considered particularly. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 120 The method of resolution is here a soft "interception" of the set value rise before reaching the hold phase. For this purpose a tolerance is used in the SE-707 that recognizes if the temperature actual value approaches the target set value up to a certain measure.
  • Page 121 No (always active) Operand number 1 01 (same actual value, like the control zone) Operand number 2 01 (same set value, like the control zone) Plus-Tolerance + 50.0 Minus-Tolerance - 50.0 © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 122: Tolerances

    Controller set value (RS) Tolerance code 2 Inactive (operand 2, subtrahend) Set value (Sv) Actual value (Av) Formula value (Xv) Variable value (Va) Manipulated variable (Y) Manipulated variable heating (Yh) © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 123 Target set value (TargetSv) X – Sv Funct. input tolerance release Function output Av – X “minus tolerance undershot” X – X Av – TargetSv X – TargetSv Sv - TargetSv © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 124 Such a tolerance is very useful if the point is to initiate something shortly before the end of the ramp segment. An example for using such a tolerance can be found in the previous chapter under “Foresighted controller manipulation at the beginning of a hold phase”. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 125: Limit Values

    Value display format corresponding to format enumeration Limit value -9.99999E15 to +9.99999E15 Hysteresis -9999 to +9999 ) These limit values are not relevant if “yes” is selected at “Limit values Read/Write” is selected! © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 126 Limit value positive hysteresis (monitoring for undershooting) Limit value outp. NOTE: In case of monitoring for undershooting the limit value output must be inquired negatively (0 = undershooting). © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 127 In the internal PLC there must exist the following statements: 0681 (Output 2 is active as soon as the actual remaining segment 0684 time is less than 30 sec.) 0170 0002 © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 128: Alarm Monitoring

    >0: Alarm time in seconds, 32 Bit; by priority given time remains then unconsidered! Range: 0.0 to 9999.9 seconds Logging Collect alarm in data logger: Yes / No Control alarm relay No / Yes © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 129 Alarms can be acknowledged on user’s choice simultaneously in one action on the device alarm overview page, or one by one after having been selected individually. Alarms can also be acknowledged simultaneously (FI 506) via function inputs. A single acknowledgment is not intended via FIs. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 130 Control alarm relay (No / Yes) For each single configured alarm in the SE-707 alarm monitoring can be freely determined if it has an influence on the alarm relay (connector at the device next to the power supply) in case of an alarm or not.
  • Page 131 If yes, take out and check formatted, or is defective. on PC and if necessary reformat (FAT32). If defective, request a new SD card at Fa. STANGE; use only original SD card from STANGE! NetJack missing, NetJack module missing or Check availability of NetJack module defective, licence is defective.

  • Page 132: Formula / Constants

    (x to the y) (Logarithm of 10) (Natural logarithm) Sinus (Xradiant) Cosinus (Xradiant) Tangens (Xradiant) (Set value) (Actual value) (Constant) (Variable) (Formula value) (Manipulated variable) (Controller actual value) (Controller set value) © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 133 A formula reset makes a formula value change to a defined value. A constant value, but also a process value can be used as reset value. The SE-707 formula processing considers multiplication and division first, then addition and subtraction. ATTENTION This was not the case for the previous device generation (SE-4xx, SE-5xx).

  • Page 134: Plc Statement List

    FOs. Here is usually worked with “Set” and “Reset” but not with “=”. FO 2000...2799: Digital output variables; these variables are not assigned to a fixed function and can be read and written by the PLC. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 135 - The PLC timers are not mains failure safe. After a mains failure an elapsed timer time is deleted. - An automatic checking of the inputs does not take place; the compliance of principles for the PLC programming is subject to the user! © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 136 Both flip-flops have the same behaviour in normal operation; in case of power failure and a subsequent return of voltage FF1 holds the last switch position, while FF2 is reset. An output programmed as flip-flop behaves like FF2. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 137 The pulse generator from example 6 starts with the pause time. About 200 ms have to be added to the pause time (because of the logic queries). Therefor not suitable as precision clock! © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 138 0001 0089 Tolerance overshooting 0002 0090 Tolerance undershooting 0003 0314 Alarm Input 10 (On the following page: example for control parameters dependent on actual value with 8 PID parameter sets) © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 139 FI 0161...FI 0163: Inputs of the PID parameter selection for Control Zone 1 The function of the statement list is based on the sequential operating manner of the PLC. The commands in brackets can be ignored. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 140: Analogue Variables

    (as it is for the computer function inputs and outputs). Digital input variables can only be read; output variables can be read and written. For each of the 800 digital variables function inputs and outputs 2000…2799 are reserved (see also REFERENCE LISTS of the function inputs and outputs). © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 141 Initialization value unsigned integer 16 Bit, range: 0 to 65535 ATTENTION! Each variable needs an own address! The variable type memory requirements assignment has to be strictly considered in order to exclude overlaps! © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 142: Digital Tracks

    To interlock two tracks against each other, each track must be configured interlocked vice versa against the other one; for example: Header page: (Track) 1 Criteria: Display Line 3 Entry: (Track) 02 Header page: (Track) 2 Criteria: Display Line 3 Entry: (Track) 01 © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 143: Process Steps

    Possibly used process steps are no longer available in before written set value programs or were defined in another way; these programs must then necessarily be deleted manually or at least be revised manually. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 144: Analogue Multiplexers

    Manipulated variable Cooling (Yc) Controller actual value (CA) Controller set value (CS) Constant Value-No. input 1 - 4 Number according to value type input Output variable Output variable output: None Variable number © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 145: Bcd/Bin Decoders

    Scaling factor, only for numeric values Range: -9.99999E15 to +9.99999E15 Correction offset Scaling offset, only for numeric values Range: -9.99999E15 to +9.99999E15 FO start address Function output start number: 2000...2799 © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 146 FO 2027: 128 FO 2028: 256 FO 2029: 512 FO 2030 Sign bit: 0 = positive value, 1 = negative value; the sign bit always follows up to the most significant bit © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 147 FO 2071: 1, if value = FO 2072: 1, if value = FO 2073: 1, if value = FO 2074: 1, if value = FO 2075: 1, if value = © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 148: Special Functions

    • Consideration of correction values • Choice between endogas and direct gassing Calculation example: formula: CO= 20%, T= 930°C, = 1173mV C-level = 1.269% formula: CO= 20%, T= 900°C, = 0.5% C-level = 0.3475% © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 149 Up to two C-level calculations can be made in parallel; the mode of operation of the C-level calculation can be best viewed in the following graph: Function block C-level calculation © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 150 Display format ##0.00 Float lower limit Float lower limit 0.01 Float upper limit Float upper limit 1.00 Control system address 4508 Control system address 4510 Initialization mode None Initialization mode None © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 151 Typical actual value range: 1100..1300 mV Actual value number CO2 Number of actual value, which value is used as CO2 actual value. Dimension unit of actual value: Volume percent Typical actual value range: 0.01..1.00 % © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 152: Humidity Calculation

    Number of actual values (1…48) which value is used as wet-bulb temperature (°C). Variables No. Air Pressure Number of variables (1...80) which value is used as barometric air pressure (mbar); none = default air pressure 1013 mbar © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 153: Data Logger (Option)

    Important note about SD card medium: Only industrial SD media checked and released by STANGE may be used. Otherwise reliable log data storage cannot be ensured. Obviously there are considerable differences depending on data security and compatibility of SD media! Important note about ECS The operating mode of "Programmer Start"...
  • Page 154 The PLC is registered as user in this case because of creating the signal. Note: An actual user can only be assigned at start via device operation and/or the remote client … but this is certainly the normal case. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 155 Then the PLC passes this standard command to FI961 in order to start the log data recording. FO1305: This function output is logic 1 as long as a log data recording is active. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 156 FO1313: Log data archive full, error: This function output goes to logic 1, if the number of archived log files and/or the total size of log data reach the maximum possible limit values. A loss of log data is unavoidable here! © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 157 Program Controller SE-707 Operating page “Process-Start”“ Process start flow-chart © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 158 Monitoring for the end of data recording and then, in this example, terminate data recording after 5 seconds: 1305 If batch recording active 1311 and not process start and programmer not active: then after 5 seconds Trigger off batch end © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 159 - Delete log files corresponding to deletion criteria Alarm limit log files storage The alarm limit log data storage, range 50.0% to 95.0%: If this value is exceed, then comes © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 160 Log value range lower limit, input range -9.99999E15 to +9.99999E15 (Only for numeric data!) Upper Range Limit Log value range lower limit, input range -9.99999E15 to +9.99999E15 (Only for numeric data!) © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 161 Save during batch run Header data is stored during running batch (trigger signal FI977 to FI996): Yes or No Save at batch end Header data is stored at batch end: Yes or No © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 162 Batch description Start time End time Program No. Program name File name Header data field 1 Header data field 2 Header data field 20 Alignment Value alignment: Left-aligned Centred Right-aligned © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 163: Operating-Hours Meter (Option)

    Operating-Hours Meter: Characteristics Menu: → Configuration → Special Functions → Hour Meter Each of at most 24 meters in the SE-707 • can count up to 99999 hours (resolution 1 second). • has a "release"-input (the meter runs with logical "1").

  • Page 164: User Administration

    Program Controller SE-707 8.3.5 User Administration The SE-707 is equipped with a user administration for prevention of unauthorized manipulations at the Unit Operation as well as for conformability and documentation possibility of user interventions (event logging, audit trail). Details are described in the following.

  • Page 165: User Groups

    Manual set value Programmer/table, manual / automatic switching, input manual values View operating program View programmer/operating program Change operating program Programmer/operating program, change values Insert segment operating program Programmer/operating program, insert/copy/delete © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 166 Import log data Configure logger pins Configure logger pins Process start Process start Edit batch name Edit batch name Edit header data Edit header data Edit comment text Edit comment text © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 167: Automatic User Login

    Change Hour Meter, User Level 1 Invisible/Inactive/Activated Change Hour Meter, User Level 2 Invisible/Inactive/Activated Change Hour Meter, User Level 3 Invisible/Inactive/Activated Administration General Invisible/Inactive/Activated Force Dig. and Analog I/O´s Invisible/Inactive/Activated © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 168: Settings

    Always check the clock time one more time after time zone offset and daylight saving time were changed! Note The clock and the other parameters on the configuration page should only be changed if no batch data are recorded by the data logger! © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 169: Language Dialogue

    It is possible to create groups for set values and tracks. In these groups is defined which values are represented with which pin colours. The operator can change later between the pre-defined groups by simple keystroke. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 170: Administrate Configuration

    NOTE It must be pointed out that a possibly available older configuration file is overwritten. No security query or warning takes place. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 171: Import Configuration From Se-5Xx Or Se-4Xx Device

    It has to be considered that a possibly already existing older configuration is overwritten without comment. A configuration saved with the program ECS-Konf (ending .KON as well) cannot be imported directly to the SE-707 device. Based on the file size can be recognized whether a “.KON” file was created by ECS-VIEW or ECS-Konf: ECS-VIEW files are always smaller than 128 KByte;...

  • Page 172: Update Firmware And/Or License Update

    • Copy the corresponding firmware update package to the folder “Stange Update” on the USB stick. Copy the ZIP file of the update package 1:1 to the folder without extracting it. There may only be one of such a file in this folder because there is no further dialogue for file selection.

  • Page 173: Hardware Test

    DHCP. The here displayed IP address is relevant for connections to a control computer (ECS, InTouch etc.) and to the “SE-7xx Windows Client” (remote control software). The IP address is only displayed in the SE-707 device! In case of a remote control via a “SE-7xx Windows Client”...

  • Page 174: Licence Information

    Switch off forcing all Input/Outputs Switching between the inputs and outputs 8.3.9.6 Save diagnosis data Diagnosis data can be stored on an USB stick via the “Save diagnosis data” button. © 2018 by STANGE Elektronik GmbH Subject to technical modifications...

  • Page 175: Index

    Control zone limit values · 53 Guidelines for Grounding and Wiring · 23 Control zone tolerance values · 53 Guidelines for the installation of the SE-707 devices · 19 Controller · 51 Copy programs · 64 Copyright protection · 8 Creating programs ·...
  • Page 176 PE connection · 10 Symbol declaration · 6 PID Parameter · 52 System logger entry · 27 Plant overview · 53 System time · 14 PLC Statement List · 137 © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 177 User interface · 73 Tolerance values · 56 User Profile Modbus · 170 Tolerances · 125 Transport · 11, 13 Transport inspection · 13 Weight · 14 Wiring instructions · 33 © 2018 by STANGE Elektronik GmbH Subject to technical modifications...
  • Page 178 SE-7xx REFERENCE LISTS Function Inputs REFERENCE LISTS Alphabetical Search Index for FI-groups (FI) ... (Function Inputs) Page Alarm display ..................................... 10 Alarm number (BCD/binary) ................................10 Alarms (malfunction messages) ................................6 Analog multiplexer selection ................................14 CAN peripherals ....................................15 Control zone No.
  • Page 179 SE-7xx REFERENCE LISTS Function Inputs (FI) 2...
  • Page 180 SE-7xx REFERENCE LISTS Function Inputs since Input Host-Interface Function periodically continuous Rev. word discr PID control zone OFF / ON 0025 1101.08 1624 Control Zone 01 0026 1101.09 1625 Control Zone 02 (Control Zone 01..20) 0027 1101.10 1626 Control Zone 03 0028 1101.11 1627...
  • Page 181 SE-7xx REFERENCE LISTS Function Inputs since Input Host-Interface Function periodically continuous Rev. word discr 0091 1105.10 1690 Control Zone 19 0092 1105.11 1691 Control Zone 20 Substitute actual value 0097 1106.00 1696 Control Zone 01 activation 0098 1106.01 1697 Control Zone 02 0099 1106.02 1698...
  • Page 182 SE-7xx REFERENCE LISTS Function Inputs since Input Host-Interface Function periodically continuous Rev. word discr 0157 1109.12 1756 Control Zone 19: Y-AUTO-MAN 0158 1109.13 1757 Y-MAN constant value 0159 1109.14 1758 Control Zone 20: Y-AUTO-MAN 0160 1109.15 1759 Y-MAN constant value PID Control parameter 0161 1110.00...
  • Page 183 SE-7xx REFERENCE LISTS Function Inputs since Input Host-Interface Function periodically continuous Rev. word discr 0216 1113.07 1815 Value 2 0217 1113.08 1816 Value 2 0218 1113.09 1817 Control Zone 20: Value 2 0219 1113.10 1818 Value 2 0220 1113.11 1819 Value 2 Control zone No.
  • Page 184 SE-7xx REFERENCE LISTS Function Inputs since Input Host-Interface Function periodically continuous Rev. word discr 0312 1119.07 1911 Alarm Input 008 0313 1119.08 1912 Alarm Input 009 0314 1119.09 1913 Alarm Input 010 0315 1119.10 1914 Alarm Input 011 0316 1119.11 1915 Alarm Input 012 0317...
  • Page 185 SE-7xx REFERENCE LISTS Function Inputs since Input Host-Interface Function periodically continuous Rev. word discr 0372 1123.03 1971 Alarm Input 068 0373 1123.04 1972 Alarm Input 069 0374 1123.05 1973 Alarm Input 070 0375 1123.06 1974 Alarm Input 071 0376 1123.07 1975 Alarm Input 072 0377...
  • Page 186 SE-7xx REFERENCE LISTS Function Inputs since Input Host-Interface Function periodically continuous Rev. word discr 0432 1126.15 2031 Alarm Input 128 0433 1127.00 2032 Alarm Input 129 0434 1127.01 2033 Alarm Input 130 0435 1127.02 2034 Alarm Input 131 0436 1127.03 2035 Alarm Input 132 0437...
  • Page 187 SE-7xx REFERENCE LISTS Function Inputs since Input Host-Interface Function periodically continuous Rev. word discr 0492 1130.11 2091 Alarm Input 188 0493 1130.12 2092 Alarm Input 189 0494 1130.13 2093 Alarm Input 190 0495 1130.14 2094 Alarm Input 191 0496 1130.15 2095 Alarm Input 192 0497...
  • Page 188 SE-7xx REFERENCE LISTS Function Inputs since Input Host-Interface Function periodically continuous Rev. word discr 0557 1320.04 5124 Control System Input 005 0558 1320.05 5125 Control System Input 006 0559 1320.06 5126 Control System Input 007 0560 1320.07 5127 Control System Input 008 0561 1320.08 5128...
  • Page 189 SE-7xx REFERENCE LISTS Function Inputs since Input Host-Interface Function periodically continuous Rev. word discr 0617 1324.00 5184 Control System Input 065 0618 1324.01 5185 Control System Input 066 0619 1324.02 5186 Control System Input 067 0620 1324.03 5187 Control System Input 068 0621 1324.04 5188...
  • Page 190 SE-7xx REFERENCE LISTS Function Inputs since Input Host-Interface Function periodically continuous Rev. word discr 0677 1327.12 5244 Control System Input 125 0678 1327.13 5245 Control System Input 126 0679 1327.14 5246 Control System Input 127 0680 1327.15 5247 Control System Input 128 Programmer control inputs 0809 1150.08...
  • Page 191 SE-7xx REFERENCE LISTS Function Inputs since Input Host-Interface Function periodically continuous Rev. word discr 0866 1154.01 2465 Enable 0867 1154.02 2466 0868 1154.03 2467 0869 1154.04 2468 Formula 12: Reset 0870 1154.05 2469 Enable 0871 1154.06 2470 0872 1154.07 2471 0873 1154.08 2472...
  • Page 192 SE-7xx REFERENCE LISTS Function Inputs since Input Host-Interface Function periodically continuous Rev. word discr Data Logger 7.0.1.1 1160.00 2560 Start 1160.01 2561 1160.02 2562 Reset 1160.03 2563 Cycle 1/2 selection 1160.04 2564 Cycle release 1160.05 2565 Data set trigger 1160.06 2566 Process start 1161.00...
  • Page 193 SE-7xx REFERENCE LISTS Function Inputs since Input Host-Interface Function periodically continuous Rev. word discr 1131 1170.10 2730 Control Zone 11 1132 1170.11 2731 Control Zone 12 1133 1170.12 2732 Control Zone 13 1134 1170.13 2733 Control Zone 14 1135 1170.14 2734 Control Zone 15 1136...
  • Page 194 SE-7xx REFERENCE LISTS Function Inputs since Input Host-Interface Function periodically continuous Rev. word discr 2042 1502.10 8042 Digital Input Variable 043 2043 1502.11 8043 Digital Input Variable 044 2044 1502.12 8044 Digital Input Variable 045 2045 1502.13 8045 Digital Input Variable 046 2046 1502.14 8046...
  • Page 195 SE-7xx REFERENCE LISTS Function Inputs since Input Host-Interface Function periodically continuous Rev. word discr 2102 1506.06 8102 Digital Input Variable 103 2103 1506.07 8103 Digital Input Variable 104 2104 1506.08 8104 Digital Input Variable 105 2105 1506.09 8105 Digital Input Variable 106 2106 1506.10 8106...
  • Page 196 SE-7xx REFERENCE LISTS Function Inputs since Input Host-Interface Function periodically continuous Rev. word discr 2162 1510.02 8162 Digital Input Variable 163 2163 1510.03 8163 Digital Input Variable 164 2164 1510.04 8164 Digital Input Variable 165 2165 1510.05 8165 Digital Input Variable 166 2166 1510.06 8166...
  • Page 197 SE-7xx REFERENCE LISTS Function Inputs since Input Host-Interface Function periodically continuous Rev. word discr 2222 1513.14 8222 Digital Input Variable 223 2223 1513.15 8223 Digital Input Variable 224 2224 1514.00 8224 Digital Input Variable 225 2225 1514.01 8225 Digital Input Variable 226 2226 1514.02 8226...
  • Page 198 SE-7xx REFERENCE LISTS Function Inputs since Input Host-Interface Function periodically continuous Rev. word discr 2282 1517.10 8282 Digital Input Variable 283 2283 1517.11 8283 Digital Input Variable 284 2284 1517.12 8284 Digital Input Variable 285 2285 1517.13 8285 Digital Input Variable 286 2286 1517.14 8286...
  • Page 199 SE-7xx REFERENCE LISTS Function Inputs since Input Host-Interface Function periodically continuous Rev. word discr 2342 1521.06 8342 Digital Input Variable 343 2343 1521.07 8343 Digital Input Variable 344 2344 1521.08 8344 Digital Input Variable 345 2345 1521.09 8345 Digital Input Variable 346 2346 1521.10 8346...
  • Page 200 SE-7xx REFERENCE LISTS Function Inputs since Input Host-Interface Function periodically continuous Rev. word discr 2402 1525.02 8402 Digital Input Variable 403 2403 1525.03 8403 Digital Input Variable 404 2404 1525.04 8404 Digital Input Variable 405 2405 1525.05 8405 Digital Input Variable 406 2406 1525.06 8406...
  • Page 201 SE-7xx REFERENCE LISTS Function Inputs since Input Host-Interface Function periodically continuous Rev. word discr 2462 1528.14 8462 Digital Input Variable 463 2463 1528.15 8463 Digital Input Variable 464 2464 1529.00 8464 Digital Input Variable 465 2465 1529.01 8465 Digital Input Variable 466 2466 1529.02 8466...
  • Page 202 SE-7xx REFERENCE LISTS Function Inputs since Input Host-Interface Function periodically continuous Rev. word discr 2522 1532.10 8522 Digital Input Variable 523 2523 1532.11 8523 Digital Input Variable 524 2524 1532.12 8524 Digital Input Variable 525 2525 1532.13 8525 Digital Input Variable 526 2526 1532.14 8526...
  • Page 203 SE-7xx REFERENCE LISTS Function Inputs since Input Host-Interface Function periodically continuous Rev. word discr 2582 1536.06 8582 Digital Input Variable 583 2583 1536.07 8583 Digital Input Variable 584 2584 1536.08 8584 Digital Input Variable 585 2585 1536.09 8585 Digital Input Variable 586 2586 1536.10 8586...
  • Page 204 SE-7xx REFERENCE LISTS Function Inputs since Input Host-Interface Function periodically continuous Rev. word discr 2642 1540.02 8642 Digital Input Variable 643 2643 1540.03 8643 Digital Input Variable 644 2644 1540.04 8644 Digital Input Variable 645 2645 1540.05 8645 Digital Input Variable 646 2646 1540.06 8646...
  • Page 205 SE-7xx REFERENCE LISTS Function Inputs since Input Host-Interface Function periodically continuous Rev. word discr 2702 1543.14 8702 Digital Input Variable 703 2703 1543.15 8703 Digital Input Variable 704 2704 1544.00 8704 Digital Input Variable 705 2705 1544.01 8705 Digital Input Variable 706 2706 1544.02 8706...
  • Page 206 SE-7xx REFERENCE LISTS Function Inputs since Input Host-Interface Function periodically continuous Rev. word discr 2762 1547.10 8762 Digital Input Variable 763 2763 1547.11 8763 Digital Input Variable 764 2764 1547.12 8764 Digital Input Variable 765 2765 1547.13 8765 Digital Input Variable 766 2766 1547.14 8766...
  • Page 207 SE-7xx REFERENCE LISTS Function Outputs REFERENCE LISTS Alphabetical Search Index for FO-groups (FO) ... (Function Outputs) Page Actual segment number (binary) ................................. 13 Actual value defective (e.g. thermo-couple sensor break) ........................3 Alarm display ..................................... 14 Alarm (error message) ..................................6 Alarms (Internal) ....................................
  • Page 208 SE-7xx REFERENCE LISTS Function Outputs (FO) 2...
  • Page 209 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. Actual value defective 0001 1200.00 3200 Actual Value 01 defective (e.g. thermo-couple sensor break) 0002 1200.01 3201 Actual Value 02 defective 0003 1200.02 3202 Actual Value 03 defective (Actual Value 01..48) 0004 1200.03...
  • Page 210 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 0060 1203.11 3259 Output 2 0061 1203.12 3260 Control Zone 07: Output 1 0062 1203.13 3261 Output 2 0063 1203.14 3262 Control Zone 08: Output 1 0064 1203.15 3263...
  • Page 211 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 0119 1207.06 3318 Tolerance 16: Overshot 0120 1207.07 3319 Undershot 0121 1207.08 3320 Tolerance 17: Overshot 0122 1207.09 3321 Undershot 0123 1207.10 3322 Tolerance 18: Overshot 0124 1207.11 3323...
  • Page 212 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 0178 1211.01 3377 Limit Value 10 0179 1211.02 3378 Limit Value 11 0180 1211.03 3379 Limit Value 12 0181 1211.04 3380 Limit Value 13 0182 1211.05 3381 Limit Value 14 0183...
  • Page 213 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 0237 1214.12 3436 Alarm Output 029 0238 1214.13 3437 Alarm Output 030 0239 1214.14 3438 Alarm Output 031 0240 1214.15 3439 Alarm Output 032 0241 1215.00 3440 Alarm Output 033 0242...
  • Page 214 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 0297 1218.08 3496 Alarm Output 089 0298 1218.09 3497 Alarm Output 090 0299 1218.10 3498 Alarm Output 091 0300 1218.11 3499 Alarm Output 092 0301 1218.12 3500 Alarm Output 093 0302...
  • Page 215 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 0357 1222.04 3556 Alarm Output 149 0358 1222.05 3557 Alarm Output 150 0359 1222.06 3558 Alarm Output 151 0360 1222.07 3559 Alarm Output 152 0361 1222.08 3560 Alarm Output 153 0362...
  • Page 216 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. Alarm priority 0417 1226.00 3616 Priority 1 0418 1226.01 3617 Priority 2 0419 1226.02 3618 Priority 3 0420 1226.03 3619 Priority 4 0421 1226.04 3620 Priority 5 0422 1226.05 3621...
  • Page 217 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 0475 1333.02 5330 Control System Output 051 0476 1333.03 5331 Control System Output 052 0477 1333.04 5332 Control System Output 053 0478 1333.05 5333 Control System Output 054 0479 1333.06 5334...
  • Page 218 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 0535 1336.14 5390 Control System Output 111 0536 1336.15 5391 Control System Output 112 0537 1337.00 5392 Control System Output 113 0538 1337.01 5393 Control System Output 114 0539 1337.02 5394...
  • Page 219 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 0719 1244.14 3918 Digital Track 31 0720 1244.15 3919 Digital Track 32 0721 1245.00 3920 Digital Track 33 0722 1245.01 3921 Digital Track 34 0723 1245.02 3922 Digital Track 35 0724...
  • Page 220 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 0772 1248.03 3971 Process Step 04 0773 1248.04 3972 Process Step 05 0774 1248.05 3973 Process Step 06 0775 1248.06 3974 Process Step 07 0776 1248.07 3975 Process Step 08 0777...
  • Page 221 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 0832 1251.15 4031 0833 1252.00 4032 Formula 02: Handshake reset 0834 1252.01 4033 Handshake enable 0835 1252.02 4034 Range undershot 0836 1252.03 4035 Range overshot 0837 1252.04 4036 Calculation error...
  • Page 222 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 0892 1255.11 4091 Range overshot 0893 1255.12 4092 Calculation error 0894 1255.13 4093 0895 1255.14 4094 0896 1255.15 4095 0897 1256.00 4096 Formula 10: Handshake reset 0898 1256.01 4097...
  • Page 223 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 0952 1259.07 4151 0953 1259.08 4152 Formula 17: Handshake reset 0954 1259.09 4153 Handshake enable 0955 1259.10 4154 Range undershot 0956 1259.11 4155 Range overshot 0957 1259.12 4156 Calculation error...
  • Page 224 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 1011 1263.02 4210 Lower limit value undershot 1012 1263.03 4211 Upper limit value overshot * 1013 1263.04 4212 Actual value break alarm * 1014 1263.05 4213 Actual value tolerance alarm 1015 1262.06...
  • Page 225 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 1071 1266.14 4270 1072 1266.15 4271 1073 1267.00 4272 Contr. Z. 12: -tolerance undershot 1074 1267.01 4273 +tolerance overshot 1075 1267.02 4274 Lower limit value undershot 1076 1267.03 4275...
  • Page 226 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 1131 1270.10 4330 Lower limit value undershot 1132 1270.11 4331 Upper limit value overshot 1133 1270.12 4332 Actual value break alarm * 1134 1270.13 4333 Actual value tolerance alarm * 1135 1270.14 4334...
  • Page 227 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 1214 1275.13 4413 BCD 20 1215 1275.14 4414 BCD 40 1216 1275.15 4415 BCD 80 Manual Y active 1233 1277.00 4432 Control Zone 01 1234 1277.01 4433 Control Zone 02 (Control Zone 01..20)
  • Page 228 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 1295 1280.14 4494 Control Zone 15 1296 1280.15 4495 Control Zone 16 1297 1281.00 4496 Control Zone 17 1298 1281.01 4497 Control Zone 18 1299 1281.02 4498 Control Zone 19 1300...
  • Page 229 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 1366 1285.05 4565 constant 1367 1285.06 4566 falling 1368 1285.07 4567 ramp segment 1369 1285.08 4568 Setp. V. 05: rising 1370 1285.09 4569 constant 1371 1285.10 4570 falling 1372...
  • Page 230 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 1426 1289.01 4625 constant 1427 1289.02 4626 falling 1428 1289.03 4627 ramp segment 1429 1289.04 4628 Setp. V. 20: rising 1430 1289.05 4629 constant 1431 1289.06 4630 falling 1432...
  • Page 231 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 1484 1292.11 4683 Error CAN Node 11: Communication, config. 1485 1292.12 4684 Error CAN Node 12: Communication, config. 1486 1292.13 4685 Error CAN Node 13: Communication, config. 1487 1292.14 4686...
  • Page 232 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 2028 1551.12 8828 Digital Output Variables 029 2029 1551.13 8829 Digital Output Variables 030 2030 1551.14 8830 Digital Output Variables 031 2031 1551.15 8831 Digital Output Variables 032 2032 1552.00 8832...
  • Page 233 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 2088 1555.08 8888 Digital Output Variables 089 2089 1555.09 8889 Digital Output Variables 090 2090 1555.10 8890 Digital Output Variables 091 2091 1555.11 8891 Digital Output Variables 092 2092 1555.12 8892...
  • Page 234 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 2148 1559.04 8948 Digital Output Variables 149 2149 1559.05 8949 Digital Output Variables 150 2150 1559.06 8950 Digital Output Variables 151 2151 1559.07 8951 Digital Output Variables 152 2152 1559.08 8952...
  • Page 235 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 2208 1563.00 9008 Digital Output Variables 209 2209 1563.01 9009 Digital Output Variables 210 2210 1563.02 9010 Digital Output Variables 211 2211 1563.03 9011 Digital Output Variables 212 2212 1563.04 9012...
  • Page 236 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 2268 1566.12 9068 Digital Output Variables 269 2269 1566.13 9069 Digital Output Variables 270 2270 1566.14 9070 Digital Output Variables 271 2271 1566.15 9071 Digital Output Variables 272 2272 1567.00 9072...
  • Page 237 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 2328 1570.08 9128 Digital Output Variables 329 2329 1570.09 9129 Digital Output Variables 330 2330 1570.10 9130 Digital Output Variables 331 2331 1570.11 9131 Digital Output Variables 332 2332 1570.12 9132...
  • Page 238 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 2388 1574.04 9188 Digital Output Variables 389 2389 1574.05 9189 Digital Output Variables 390 2390 1574.06 9190 Digital Output Variables 391 2391 1574.07 9191 Digital Output Variables 392 2392 1574.08 9192...
  • Page 239 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 2448 1578.00 9248 Digital Output Variables 449 2449 1578.01 9249 Digital Output Variables 450 2450 1578.02 9250 Digital Output Variables 451 2451 1578.03 9251 Digital Output Variables 452 2452 1578.04 9252...
  • Page 240 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 2508 1581.12 9308 Digital Output Variables 509 2509 1581.13 9309 Digital Output Variables 510 2510 1581.14 9310 Digital Output Variables 511 2511 1581.15 9311 Digital Output Variables 512 2512 1582.00 9312...
  • Page 241 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 2568 1585.08 9368 Digital Output Variables 569 2569 1585.09 9369 Digital Output Variables 570 2570 1585.10 9370 Digital Output Variables 571 2571 1585.11 9371 Digital Output Variables 572 2572 1585.12 9372...
  • Page 242 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 2628 1589.04 9428 Digital Output Variables 629 2629 1589.05 9429 Digital Output Variables 630 2630 1589.06 9430 Digital Output Variables 631 2631 1589.07 9431 Digital Output Variables 632 2632 1589.08 9432...
  • Page 243 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 2688 1593.00 9488 Digital Output Variables 689 2689 1593.01 9489 Digital Output Variables 690 2690 1593.02 9490 Digital Output Variables 691 2691 1593.03 9491 Digital Output Variables 692 2692 1593.04 9492...
  • Page 244 SE-7xx REFERENCE LISTS Function Outputs since Outp. Host-Interface Function periodically continuous Rev. word discr. 2748 1596.12 9548 Digital Output Variables 749 2749 1596.13 9549 Digital Output Variables 750 2750 1596.14 9550 Digital Output Variables 751 2751 1596.15 9551 Digital Output Variables 752 2752 1597.00 9552...

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