ero electronic PKP User Manual
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ero electronic PKP User Manual

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170.IU0.XKP.0D1
5/06
USER MANUAL
USER MANUAL
USER MANUAL
USER MANUAL
USER MANUAL
XKP-0-D1.pmd
1
PKP
PKP
PKP
PKP
PKP
MKP
MKP
MKP
MKP
MKP
25/05/2006, 11.27

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  • Page 1 170.IU0.XKP.0D1 5/06 USER MANUAL USER MANUAL USER MANUAL USER MANUAL USER MANUAL XKP-0-D1.pmd 25/05/2006, 11.27...

  • Page 2: Xkp-0-D1.Pmd

    XKP-0-D1.pmd 25/05/2006, 11.27...

  • Page 3: Table Of Contents

    INDEX INDEX INDEX INDEX INDEX CLOCK CALENDAR ............ 110 OUT FAILURE DETECTION FUNCTION (OFD) ..111 SERIAL LINK ............... 111 MOUNTING REQUIREMENTS ............ 1 LAMP TEST ..............112 OUTLINE AND CUT OUT DIMENSIONS ........2 MANUAL MODE ............112 CONNECTION DIAGRAMS ............4 DIRECT ACCESS TO THE SET POINT ......
  • Page 4 XKP-0-D1.pmd 25/05/2006, 11.27...

  • Page 5: Mounting Requirements

    0 and 50 °C (32 and 122 °F). The instrument can be mounted on a panel up to 15 mm thick with a cutout of 92 x 45 mm (PKP) or 92 x 92 mm (MKP). For outline and cutout dimensions refer to Fig. 2.

  • Page 6: Outline And Cut Out Dimensions

    OUTLINE AND CUT OUT OUTLINE AND CUT OUT OUTLINE AND CUT OUT OUTLINE AND CUT OUT OUTLINE AND CUT OUT DIMENSIONS DIMENSIONS DIMENSIONS DIMENSIONS DIMENSIONS OUTLINE AND CUT-OUT DIMENSIONS FOR PKP MODEL Fig. 2.A XKP-1-D1.pmd 25/05/2006, 11.28...
  • Page 7 OUTLINE AND CUT-OUT DIMENSIONS FOR MKP MODEL Fig. 2.B XKP-1-D1.pmd 25/05/2006, 11.28...

  • Page 8: Connection Diagrams

    CONNECTION DIAGRAMS CONNECTION DIAGRAMS CONNECTION DIAGRAMS CONNECTION DIAGRAMS CONNECTION DIAGRAMS Connections are to be made with the instrument housing installed in its proper location. A) MEASURING INPUTS A) MEASURING INPUTS A) MEASURING INPUTS A) MEASURING INPUTS A) MEASURING INPUTS NOTE NOTE NOTE NOTE...
  • Page 9 A.1) TC INPUT A.1) TC INPUT A.1) TC INPUT A.1) TC INPUT A.1) TC INPUT A.2) RTD INPUT A.2) RTD INPUT A.2) RTD INPUT A.2) RTD INPUT A.2) RTD INPUT Shield Shield Fig. 4 THERMOCOUPLE INPUT WIRING Fig. 5 RTD INPUT WIRING NOTES NOTES NOTES...
  • Page 10 A.3) LINEAR INPUT A.3) LINEAR INPUT A.3) LINEAR INPUT A.3) LINEAR INPUT A.3) LINEAR INPUT 3) When shielded cable is used, it should be grounded at one side only to avoid ground loop currents. 4) The input impedance is equal to: <...
  • Page 11 Shield Fig. 7.C INPUTS WIRING FOR 4-WIRE TRANSMITTER Shield NOTES NOTES NOTES: NOTES NOTES 1) Don’t run input wires together with power cables. 2) Pay attention to the line resistance; a high line resistance may cause measurement errors. 3) When shielded cable is used, it should be grounded at one side only to avoid ground loop currents.
  • Page 12 B) AUXILIARY INPUT B) AUXILIARY INPUT B) AUXILIARY INPUT B) AUXILIARY INPUT B) AUXILIARY INPUT 4) When shielded cable is used, it should be grounded at one side only to avoid ground loop currents. 5) The input impedance is equal to: <...
  • Page 13 IN 1 IN 5 IN 2 IN 6 IN 3 IN 7 IN 4 IN 8 Fig. 9.C - LOGIC INPUTS IN 5, 6, 7 and 8 WIRING Fig. 9.B - LOGIC INPUTS IN 1, 2, 3 and 4 WIRING NOTES NOTES NOTES:...
  • Page 14 D) CURRENT TRANSFORMER INPUT D) CURRENT TRANSFORMER INPUT D) CURRENT TRANSFORMER INPUT D) CURRENT TRANSFORMER INPUT D) CURRENT TRANSFORMER INPUT 3) The minimum active period to perform this measurement is equal to 120 ms. 4) The input impedance is equal to 20 Ω. Current transformer Load...
  • Page 15 E.1) RELAY OUTPUTS E.1) RELAY OUTPUTS E.1) RELAY OUTPUTS E.1) RELAY OUTPUTS E.1) RELAY OUTPUTS The outputs from OUT 1 to OUT 4 are equipped with relays having contact rating equal to 3A/250V AC on resistive load. WARNING WARNING WARNING: When OUT 3 and 4 are used as independent relay WARNING WARNING outputs the addition of the two currents must not exceed 3 A.
  • Page 16 GENERAL NOTES ABOUT RELAY OUTPUT WIRING GENERAL NOTES ABOUT RELAY OUTPUT WIRING GENERAL NOTES ABOUT RELAY OUTPUT WIRING GENERAL NOTES ABOUT RELAY OUTPUT WIRING GENERAL NOTES ABOUT RELAY OUTPUT WIRING NO OUT 15 1) To avoid electrical shock, connect power line at the end of OUT 15 the wiring procedure.
  • Page 17 The same problem may occur when a switch is used in series E.2) VOLTAGE OUTPUTS FOR SSR DRIVE E.2) VOLTAGE OUTPUTS FOR SSR DRIVE E.2) VOLTAGE OUTPUTS FOR SSR DRIVE E.2) VOLTAGE OUTPUTS FOR SSR DRIVE E.2) VOLTAGE OUTPUTS FOR SSR DRIVE with the internal contacts as shown in Fig.
  • Page 18 NOTE NOTE NOTE NOTE NOTE: This output is not isolated. Switching mode Switching mode Switching mode Switching mode Switching mode: isolated zero crossing type. Rated current Rated current A double or reinforced insulation between instrument output Rated current Rated current Rated current: from 50 mA to 1 A.
  • Page 19 E.4) SERVOMOTOR OUTPUT E.4) SERVOMOTOR OUTPUT E.4) SERVOMOTOR OUTPUT E.4) SERVOMOTOR OUTPUT E.4) SERVOMOTOR OUTPUT The two relay output must be interlocked (see chapter "Preliminary hardware setting" paragraph "Out 3 and 4 selection"). (Open the valve) NOTES NOTES: NOTES NOTES NOTES Power Servo-...
  • Page 20 E.5) ANALOG OUTPUTS E.5) ANALOG OUTPUTS E.5) ANALOG OUTPUTS E.5) ANALOG OUTPUTS E.5) ANALOG OUTPUTS OUT 6 OUT 5 Shield Shield OUT 6 OUT 5 Fig. 16.B OUTPUT 6 WIRING NOTE NOTE NOTE NOTE NOTE: 1) Do not run analog output wirings together with AC power cables.
  • Page 21 F) SERIAL INTERFACE F) SERIAL INTERFACE F) SERIAL INTERFACE F) SERIAL INTERFACE F) SERIAL INTERFACE 3) The EIA standard establishes that by RS-485 interface it is possible to connect up to 30 devices with one remote master unit. A'/A A/A' The serial interface of these instruments is based on “High input impedance”...
  • Page 22 G) POWER LINE WIRING G) POWER LINE WIRING G) POWER LINE WIRING G) POWER LINE WIRING G) POWER LINE WIRING 6) For 24 V DC the polarity is a not care condition. 7) The power supply input is fuse protected by a sub miniature N (L2) fuse rated T, 1A, 250 V.

  • Page 23: Preliminary Hardware Settings

    PRELIMINARY HARDWARE SETTINGS PRELIMINARY HARDWARE SETTINGS PRELIMINARY HARDWARE SETTINGS PRELIMINARY HARDWARE SETTINGS PRELIMINARY HARDWARE SETTINGS 4) Push gently the lock C on the left. 5) While the lock C is maintained out, slide out the instrument (see fig. 19.b) How to remove the instrument from its case How to remove the instrument from its case How to remove the instrument from its case How to remove the instrument from its case...
  • Page 24 MAIN INPUT SELECTION MAIN INPUT SELECTION MAIN INPUT SELECTION MAIN INPUT SELECTION MAIN INPUT SELECTION 1 3 5 7 1 3 5 7 Set J103 (see fig. 20) according to the desired input type as J102 J103 shown in the following table. J103 INPUT TYPE 2 4 6 8...
  • Page 25 OUTPUT 3 AND 4 SELECTION OUTPUT 3 AND 4 SELECTION OUTPUT 3 AND 4 SELECTION OUTPUT 3 AND 4 SELECTION OUTPUT 3 AND 4 SELECTION Output 3 and 4 can be set as: Output J 204 J 205 - 2 independent relay outputs Relay close open...
  • Page 26 To select the desired input type, set V301 (see fig. 20) as detailed in the following table: Input V301.1 V301.2 V301.3 V301.4 1 2 3 4 IN CT KY101 KY103 V101 Feedback OPTION CHECK OPTION CHECK OPTION CHECK OPTION CHECK OPTION CHECK This instrument can be supplied with several options.

  • Page 27: Security Code Setting Mode

    Operative mode and Hardware lock Operative mode and Hardware lock Operative mode and Hardware lock Operative mode and Hardware lock Operative mode and Hardware lock SECURITY CODE SETTING MODE SECURITY CODE SETTING MODE SECURITY CODE SETTING MODE SECURITY CODE SETTING MODE SECURITY CODE SETTING MODE By V101 (see fig 22) it is possible to select one of the following operative modes:...
  • Page 28 Security code setting Security code setting Security code setting Security code setting Security code setting: Run time security code Run time security code Run time security code Run time security code Run time security code 1) Remove the instrument from its case. The display will show: 2) Set the internal dip switch V101 as follows: - V101.1 = OFF...
  • Page 29 and the "run time hidden" groups are ever protected by Configuration security code Configuration security code Configuration security code Configuration security code Configuration security code security code. The display will show: Run time groups protected by security code Run time groups protected by security code Run time groups protected by security code Run time groups protected by security code Run time groups protected by security code...

  • Page 30: Run Time And Configuration Modes

    NOTE NOTE NOTE NOTE NOTE: at the end of the security code setting procedure, set RUN TIME AND CONFIGURATION MODES RUN TIME AND CONFIGURATION MODES RUN TIME AND CONFIGURATION MODES RUN TIME AND CONFIGURATION MODES RUN TIME AND CONFIGURATION MODES V101 according to the desired operative mode (see "Operative mode and hardware lock"...

  • Page 31: Keyboard Description

    Keyboard description Keyboard description Keyboard description Keyboard description Keyboard description During parameter modification, it allows you to decrease the value of the selected parameter MENU = is used to select a parameter group During MANUAL mode, it allows to decrease the FUNC = when the instrument is in "normal display mode"...

  • Page 32: Configuration Mode

    +MENU= are used to start the lamp test function (see CONFIGURATION MODE CONFIGURATION MODE CONFIGURATION MODE CONFIGURATION MODE CONFIGURATION MODE paragraph "Lamp test") Switch on the instrument. +FUNC or +FUNC The instrument will start in the same way it was prior to the During parameter modification they allow you to power down (configuration mode or run time mode) increase/decrease the value under modification...

  • Page 33: Monitor Mode

    push-button it is possible to select between: MONITOR MODE MONITOR MODE MONITOR MODE MONITOR MODE MONITOR MODE During the run time mode, it is possible to monitor but not (monitor) this selection allows you to monitor but modify all configuration parameters. not to modify the value assigned to the When it is desired to verify the instrument configuration, configuration parameters...

  • Page 34: Modify Mode

    2) During monitor mode, if no push-button is depressed for more than 10 s (or 30 s according to "t.out" [C.I10] parameter setting), the instrument returns automatically to the normal display mode. The modify mode is started. This display allows you to load the default configuration MODIFY MODE MODIFY MODE MODIFY MODE...
  • Page 35 specific instrument configuration (i.e. setting OUT 3 different CONFIGURATION GROUP 1 [C.dxx] CONFIGURATION GROUP 1 [C.dxx] CONFIGURATION GROUP 1 [C.dxx] CONFIGURATION GROUP 1 [C.dxx] CONFIGURATION GROUP 1 [C.dxx] from servo, all the parameters related to servomotor output MAIN AND AUXILIARY INPUT CONFIGURATION will be skipped).
  • Page 36 8 = TC S From - 50 to 1760 °C 33 = Linear From 0 to 9 = TC R From - 50 to 1760 °C 34 = Linear From 1 to 10 = TC B From 0 to 1820 °C 35 = Linear From...
  • Page 37 - Decimal point position - [C.d03] - Decimal point position - [C.d03] - Decimal point position - [C.d03] - Decimal point position - [C.d03] - Decimal point position - [C.d03] 2) When the square root extraction is enabled the values of the ----.
  • Page 38 - Offset on the main input - [C.d07] - Offset on the main input - [C.d07] - Offset on the main input - [C.d07] 2) Changing the value of this parameter, the "brG.L" (bargraph - Offset on the main input - [C.d07] - Offset on the main input - [C.d07] - initial scale value [C.I03]) and "rL"...
  • Page 39 - Auxiliary input function - [C.d09] - Auxiliary input function - [C.d09] - Auxiliary input function - [C.d09] - Initial scale read-out of the auxiliary input - Initial scale read-out of the auxiliary input - Initial scale read-out of the auxiliary input - Auxiliary input function - [C.d09] - Auxiliary input function - [C.d09] - Initial scale read-out of the auxiliary input...
  • Page 40 - Filter on auxiliary input - [C.d13] - Filter on auxiliary input - [C.d13] - Filter on auxiliary input - [C.d13] - Filter on auxiliary input - [C.d13] - Filter on auxiliary input - [C.d13] CONFIGURATION GROUP 2 [C.Exx] CONFIGURATION GROUP 2 [C.Exx] CONFIGURATION GROUP 2 [C.Exx] CONFIGURATION GROUP 2 [C.Exx] CONFIGURATION GROUP 2 [C.Exx]...
  • Page 41 - OUT 2 function - [C.E02] - OUT 2 function - [C.E02] - OUT 2 function - [C.E02] - OUT 4 function - [C.E04] - OUT 4 function - [C.E04] - OUT 4 function - [C.E04] - OUT 2 function - [C.E02] - OUT 2 function - [C.E02] - OUT 4 function - [C.E04] - OUT 4 function - [C.E04]...
  • Page 42 - Valve position indication - [C.E06] - Valve position indication - [C.E06] - Valve position indication - [C.E06] - OUT 5 range - [C.E08] - OUT 5 range - [C.E08] - OUT 5 range - [C.E08] - Valve position indication - [C.E06] - Valve position indication - [C.E06] - OUT 5 range - [C.E08] - OUT 5 range - [C.E08]...
  • Page 43 - OUT 5 retransmission full scale value - OUT 5 retransmission full scale value - OUT 5 retransmission full scale value - OUT 5 retransmission full scale value - OUT 5 retransmission full scale value NOTE NOTE NOTE: When the option circuitry is not mounted the middle NOTE NOTE - [C.E10]...
  • Page 44 - OUT 6 retransmission full scale value - OUT 6 retransmission full scale value - OUT 6 retransmission full scale value - OUT 6 retransmission full scale value - OUT 6 retransmission full scale value General note about configuration group 2 General note about configuration group 2 General note about configuration group 2 General note about configuration group 2...
  • Page 45 I I ) Exiting from the configuration group 2 also the following CONFIGURATION GROUP 3 [C.Fxx] CONFIGURATION GROUP 3 [C.Fxx] CONFIGURATION GROUP 3 [C.Fxx] CONFIGURATION GROUP 3 [C.Fxx] CONFIGURATION GROUP 3 [C.Fxx] actions are automatically performed: CONTROL OUTPUT CONFIGURATION A) The "Añ.UL” parameter ("Output value for auto to manual transfer"...
  • Page 46 The relation between the Calculated Power Output and the FOR EXAMPLE FOR EXAMPLE FOR EXAMPLE FOR EXAMPLE FOR EXAMPLE: resulting real outputs are shown below: Let's suppose that the first split output operates from 0 % to 33.3 % of the calculated output while the second one operates Real PWR First split from 33.3 % to the 100 % of the calculated output.
  • Page 47 - Main control output bias - [C.F03] - Main control output bias - [C.F03] - Main control output bias - [C.F03] We will set: - Main control output bias - [C.F03] - Main control output bias - [C.F03] Bias 1 = 0 This parameter will be available only when the split range is Gain 1 = 100 / (33.3 - 0) = 3 enabled ("SPLt."...
  • Page 48 - Main control output conditioning - [C.F06] - Main control output conditioning - [C.F06] - Main control output conditioning - [C.F06] - Main control output conditioning - [C.F06] - Main control output conditioning - [C.F06] This parameter will be available only when main control output is configured.
  • Page 49 - Main control output in engineering unit - Main control output in engineering unit - Main control output in engineering unit - Main output initial scale readout - [C.F09] - Main output initial scale readout - [C.F09] - Main output initial scale readout - [C.F09] - Main control output in engineering unit - Main control output in engineering unit - Main output initial scale readout - [C.F09]...
  • Page 50 - Main output auxiliary conditioning - [C.F11] - Main output auxiliary conditioning - [C.F11] - Main output auxiliary conditioning - [C.F11] - Secondary control output conditioning - Secondary control output conditioning - Secondary control output conditioning - Main output auxiliary conditioning - [C.F11] - Main output auxiliary conditioning - [C.F11] - Secondary control output conditioning - Secondary control output conditioning...
  • Page 51 - Secondary control output in engineering unit - Secondary control output in engineering unit - Secondary control output in engineering unit - Secondary control output initial scale value - Secondary control output initial scale value - Secondary control output initial scale value - Secondary control output in engineering unit - Secondary control output in engineering unit - Secondary control output initial scale value...
  • Page 52 - Secondary output auxiliary conditioning - Secondary output auxiliary conditioning - Secondary output auxiliary conditioning - Secondary output auxiliary conditioning - Secondary output auxiliary conditioning General note about configuration group 3 General note about configuration group 3 General note about configuration group 3 General note about configuration group 3 General note about configuration group 3 - [C.F17]...
  • Page 53 - Manual function - [C.G03] - Manual function - [C.G03] - Manual function - [C.G03] CONFIGURATION GROUP 4 [C.Gxx] CONFIGURATION GROUP 4 [C.Gxx] CONFIGURATION GROUP 4 [C.Gxx] CONFIGURATION GROUP 4 [C.Gxx] CONFIGURATION GROUP 4 [C.Gxx] - Manual function - [C.G03] - Manual function - [C.G03] AUXILIARY CONTROL CONFIGURATION This parameter will be available only when at least one control...
  • Page 54 NOTES NOTES NOTES NOTES NOTES: General note about the instrument restarting General note about the instrument restarting General note about the instrument restarting General note about the instrument restarting General note about the instrument restarting 1) When open loop servomotor control drive without valve The two following parameters are used to set the instrument position indication is configured, this parameter is forced to restarting after a power down:...
  • Page 55 - Program restarting after a power failure - Program restarting after a power failure - Program restarting after a power failure - Program restarting after a power failure - Program restarting after a power failure already executed, the first set point equal to - [C.G07] - [C.G07] - [C.G07]...
  • Page 56 - Program restart tracking band - [C.G08] - Program restart tracking band - [C.G08] - Program restart tracking band - [C.G08] - Program restart tracking band - [C.G08] - Program restart tracking band - [C.G08] - When the open loop servomotor control is configured, "SF.Cn"...
  • Page 57 CONFIGURATION GROUP 5 [C.Hxx] CONFIGURATION GROUP 5 [C.Hxx] CONFIGURATION GROUP 5 [C.Hxx] CONFIGURATION GROUP 5 [C.Hxx] CONFIGURATION GROUP 5 [C.Hxx] NOTE: NOTE: NOTE: NOTE: NOTE: for more details about the RUN/HOLD DIGITAL INPUT/OUTPUT CONFIGURATION selection, see the related note at pag.54. Pr.Ab = Input contact used for program abort (Abort when the logic level is equal to "1").
  • Page 58 Notes about logic inputs used for program selection Notes about logic inputs used for program selection Notes about logic inputs used for program selection Notes about logic inputs used for program selection Notes about logic inputs used for program selection 4) A changement on the program selectors status has effect 1) When some logic inputs are programmed as program only at the next RUN request.
  • Page 59 - Logic input DIG1 - contact status - [C.H02] - Logic input DIG1 - contact status - [C.H02] - Logic input DIG1 - contact status - [C.H02] - Logic input DIG1 - contact status - [C.H02] - Logic input DIG1 - contact status - [C.H02] NOTE NOTE NOTE...
  • Page 60 - Logic input DIG 3 function - [C.H05] - Logic input DIG 3 function - [C.H05] - Logic input DIG 3 function - [C.H05] NOTE NOTE NOTE NOTE NOTE: See also all NOTES of the "d1.Fn" ("Logic input 1 - Logic input DIG 3 function - [C.H05] - Logic input DIG 3 function - [C.H05] function"...
  • Page 61 Au.ñA = Input contact used for Auto/Manual selection When "d3.Fn" [C.H05] is equal to “ru.St”, the (Manual when logic level is “1”) instrument toggles from one status to the other O.LIñ = Input contact used for output limiter activation one when the transition from contact close to (Output limited when logic level is “1”) contact open is detected.
  • Page 62 NOTE NOTE NOTE NOTE NOTE: for ABORT function only, the input one when the transition from contact close to status must be maintained for more than 3 contact open is detected. seconds. Pr.SL = Input contact used for program selection (for The steps C.H07 and C.H08 can be repeated for all the The steps C.H07 and C.H08 can be repeated for all the The steps C.H07 and C.H08 can be repeated for all the...
  • Page 63 - Event 1 contact status - [C.H10] - Event 1 contact status - [C.H10] - Event 1 contact status - [C.H10] the output programmed as "end of profile - Event 1 contact status - [C.H10] - Event 1 contact status - [C.H10] annunciator"...
  • Page 64 - Time for the "End of cycle" annunciator - Time for the "End of cycle" annunciator - Time for the "End of cycle" annunciator - Time for the "End of cycle" annunciator - Time for the "End of cycle" annunciator General notes about configuration group 5 General notes about configuration group 5 General notes about configuration group 5...
  • Page 65 - Bargraph initial scale value - [C.I03] - Bargraph initial scale value - [C.I03] - Bargraph initial scale value - [C.I03] CONFIGURATION GROUP 6 [C.Ixx] CONFIGURATION GROUP 6 [C.Ixx] CONFIGURATION GROUP 6 [C.Ixx] CONFIGURATION GROUP 6 [C.Ixx] CONFIGURATION GROUP 6 [C.Ixx] - Bargraph initial scale value - [C.I03] - Bargraph initial scale value - [C.I03] OTHER CONFIGURATION PARAMETERS...
  • Page 66 - Resolution of the deviation bargraph - [C.I05] - Resolution of the deviation bargraph - [C.I05] - Resolution of the deviation bargraph - [C.I05] - Set point display type - [C.I07] - Set point display type - [C.I07] - Set point display type - [C.I07] - Resolution of the deviation bargraph - [C.I05] - Resolution of the deviation bargraph - [C.I05] - Set point display type - [C.I07]...
  • Page 67 - Servomotor behaviour when the output - Servomotor behaviour when the output - Servomotor behaviour when the output - Input threshold to enable the soft start - Input threshold to enable the soft start - Input threshold to enable the soft start - Servomotor behaviour when the output - Servomotor behaviour when the output - Input threshold to enable the soft start...
  • Page 68 - Out failure detection (OFD) - [C.I11] - Out failure detection (OFD) - [C.I11] - Out failure detection (OFD) - [C.I11] - Primary current of the current transformer - Primary current of the current transformer - Primary current of the current transformer - Out failure detection (OFD) - [C.I11] - Out failure detection (OFD) - [C.I11] - Primary current of the current transformer...
  • Page 69 - Automatic start enabling - [C.I14] - Automatic start enabling - [C.I14] - Automatic start enabling - [C.I14] - Hysteresis of the Automatic starting - [C.I15] - Hysteresis of the Automatic starting - [C.I15] - Hysteresis of the Automatic starting - [C.I15] - Automatic start enabling - [C.I14] - Automatic start enabling - [C.I14] - Hysteresis of the Automatic starting - [C.I15]...
  • Page 70 - Current day - [C.I17] - Current day - [C.I17] - Current day - [C.I17] - Current day - [C.I17] - Current day - [C.I17] CONFIGURATION GROUP VERF [C.Lxx] CONFIGURATION GROUP VERF [C.Lxx] CONFIGURATION GROUP VERF [C.Lxx] CONFIGURATION GROUP VERF [C.Lxx] CONFIGURATION GROUP VERF [C.Lxx] CLOCK AND INPUT/OUTPUT TEST This parameter will be available only when the clock calendar...
  • Page 71 - Clock calendar test - [C.L01] - Clock calendar test - [C.L01] - Clock calendar test - [C.L01] - Digital input dIG.1 status - [C.L04] - Digital input dIG.1 status - [C.L04] - Digital input dIG.1 status - [C.L04] - Clock calendar test - [C.L01] - Clock calendar test - [C.L01] - Digital input dIG.1 status - [C.L04] - Digital input dIG.1 status - [C.L04]...

  • Page 72: Run Time Mode

    General note for configuration group "VErF" General note for configuration group "VErF" General note for configuration group "VErF" General note for configuration group "VErF" General note for configuration group "VErF" RUN TIME MODE RUN TIME MODE RUN TIME MODE RUN TIME MODE RUN TIME MODE Returning in the "run time mode", the instrument restarts to control the process, the settings performed into this group do...

  • Page 73: Control Parameters

    CONTROL PARAMETERS CONTROL PARAMETERS CONTROL PARAMETERS CONTROL PARAMETERS CONTROL PARAMETERS ATTENTION ATTENTION ATTENTION: One software key protects one or more run time ATTENTION ATTENTION parameter groups so that when the software key is set, it is possible to modify the run time parameters of all groups. The run time parameters are common for programmer and for The software protection will be automatically restored when the controller mode (exception made for group P and group 9...
  • Page 74 NOTES NOTES NOTES NOTES NOTES: Run time group P [r.Axx] Run time group P [r.Axx] Run time group P [r.Axx] Run time group P [r.Axx] Run time group P [r.Axx] 1) In the following pages we will describe all the parameter of Program editing the instrument.
  • Page 75 - SMART function - [r.b03] - SMART function - [r.b03] - SMART function - [r.b03] Run time group 2 [r.bxx] Run time group 2 [r.bxx] Run time group 2 [r.bxx] Run time group 2 [r.bxx] Run time group 2 [r.bxx] - SMART function - [r.b03] - SMART function - [r.b03] COMMAND...
  • Page 76 from 1 to 90 = it is the simple program selected for the ñO.Fr = all the days from monday to friday clock start. ñO.SA = all the days from monday to saturday from L1 to L9= It is the linked program selected for the = all days clock start.
  • Page 77 Thursday Run time group 3 [r.Cxx] Run time group 3 [r.Cxx] Run time group 3 [r.Cxx] Run time group 3 [r.Cxx] Run time group 3 [r.Cxx] Friday ALARM THRESHOLD AND HYSTERESIS VALUE Saturday Sunday NOTE NOTE NOTE: this is a readable parameter only and it cannot be NOTE NOTE modified.
  • Page 78 - Alarm 2 threshold - [r.C05] - Alarm 2 threshold - [r.C05] - Alarm 2 threshold - [r.C05] Range: - in engineering units within the span limits for process - Alarm 2 threshold - [r.C05] - Alarm 2 threshold - [r.C05] alarm;...
  • Page 79 - high threshold used when the alarm 2 is a - high threshold used when the alarm 2 is a - high threshold used when the alarm 2 is a - Low threshold used when the alarm 3 is a - Low threshold used when the alarm 3 is a - Low threshold used when the alarm 3 is a - high threshold used when the alarm 2 is a...
  • Page 80 NOTE NOTE NOTE NOTE NOTE: The span limits are configured by “ñ.In.L” [C.d05] and NOTES NOTES NOTES NOTES NOTES: “ñ.In.H” [C.d06]. 1) The device is in alarm status when the current, measured during the ON status of the load, is lower than this threshold. 2) The OFD (output failure detection) alarm threshold resolution - Low threshold used when the alarm 4 is a - Low threshold used when the alarm 4 is a...
  • Page 81 - Alarm 1 hysteresis - [r.C16] - Alarm 1 hysteresis - [r.C16] - Alarm 1 hysteresis - [r.C16] - Alarm 4 hysteresis - [r.C19] - Alarm 4 hysteresis - [r.C19] - Alarm 4 hysteresis - [r.C19] - Alarm 1 hysteresis - [r.C16] - Alarm 1 hysteresis - [r.C16] - Alarm 4 hysteresis - [r.C19] - Alarm 4 hysteresis - [r.C19]...
  • Page 82 - Hysteresis (for ON/OFF control) - [r.d02] - Hysteresis (for ON/OFF control) - [r.d02] - Hysteresis (for ON/OFF control) - [r.d02] Run time group 4 [r.dxx] Run time group 4 [r.dxx] Run time group 4 [r.dxx] Run time group 4 [r.dxx] Run time group 4 [r.dxx] - Hysteresis (for ON/OFF control) - [r.d02] - Hysteresis (for ON/OFF control) - [r.d02]...
  • Page 83 - Overlap/dead band between main and - Overlap/dead band between main and - Overlap/dead band between main and NOTES NOTES NOTES NOTES NOTES: - Overlap/dead band between main and - Overlap/dead band between main and secondary outputs - [r.d07] secondary outputs - [r.d07] secondary outputs - [r.d07] secondary outputs - [r.d07] secondary outputs - [r.d07]...
  • Page 84 - Proportional band of the first PID group - Proportional band of the first PID group - Proportional band of the first PID group NOTES NOTES NOTES NOTES NOTES: - Proportional band of the first PID group - Proportional band of the first PID group - [r.d09] - [r.d09] - [r.d09]...
  • Page 85 - Hysteresis (for ON/OFF control) of the first - Hysteresis (for ON/OFF control) of the first - Hysteresis (for ON/OFF control) of the first - Derivative time of the first PID group - [r.d12] - Derivative time of the first PID group - [r.d12] - Derivative time of the first PID group - [r.d12] - Hysteresis (for ON/OFF control) of the first - Hysteresis (for ON/OFF control) of the first...
  • Page 86 - Integral preload of the first PID group - Integral preload of the first PID group - Integral preload of the first PID group - Overlap/dead band between main and - Overlap/dead band between main and - Overlap/dead band between main and - Integral preload of the first PID group - Integral preload of the first PID group - Overlap/dead band between main and...
  • Page 87 - Servo motor dead band - [r.E03] - Servo motor dead band - [r.E03] - Servo motor dead band - [r.E03] Run time group 5 [r.Exx] Run time group 5 [r.Exx] Run time group 5 [r.Exx] Run time group 5 [r.Exx] Run time group 5 [r.Exx] - Servo motor dead band - [r.E03] - Servo motor dead band - [r.E03]...
  • Page 88 - Main control output max rate of rise - [r.E06] - Main control output max rate of rise - [r.E06] - Main control output max rate of rise - [r.E06] - Secondary control output low limit - [r.E08] - Secondary control output low limit - [r.E08] - Secondary control output low limit - [r.E08] - Main control output max rate of rise - [r.E06] - Main control output max rate of rise - [r.E06]...
  • Page 89 - Set point high limit - [r.E13] - Set point high limit - [r.E13] - Set point high limit - [r.E13] will be ignored and the output will step up to the value set by - Set point high limit - [r.E13] - Set point high limit - [r.E13] “Añ.UL”...
  • Page 90 - Time out for the soft start - [r.E16] - Time out for the soft start - [r.E16] - Time out for the soft start - [r.E16] - External control for reverse/direct output - External control for reverse/direct output - External control for reverse/direct output - Time out for the soft start - [r.E16] - Time out for the soft start - [r.E16] - External control for reverse/direct output...
  • Page 91 - Alarm 1 configuration - [r.F02] - Alarm 1 configuration - [r.F02] - Alarm 1 configuration - [r.F02] Run time group 6 [r.Fxx] Run time group 6 [r.Fxx] Run time group 6 [r.Fxx] Run time group 6 [r.Fxx] Run time group 6 [r.Fxx] - Alarm 1 configuration - [r.F02] - Alarm 1 configuration - [r.F02] ALARM SETTING...
  • Page 92 Example Example Example Example Example for A1.Cn (A2.Cn, A3.Cn) = H.A. Example Example Example Example Example for A1.Cn (A2.Cn, A3.Cn) = H.A.A.c Alarm Alarm Threshold Threshold Alarm Alarm Hysteresis Hysteresis Measured Measured Value Value Relay out Relay out Flash Flash LED 1(2, 3) Flash Flash...
  • Page 93 Example Example Example Example Example for A1.Cn (A2.Cn, A3.Cn) = H.L. E= if a manual reset is performed when the alarm condition still exist; the LED gets steady lit, the alarm remains in the Alarm alarm status until the process variable reaches the alarm Threshold threshold minus hysteresis (D).
  • Page 94 NOTES NOTES NOTES NOTES NOTES: NOTE NOTE NOTE NOTE NOTE: When alarm type has been changed the alarm 1) If the alarm is programmed as band or deviation alarm, this threshold will be forced to its default value and alarm status will function masks the alarm condition after a set point change be deleted.
  • Page 95 - Alarm 2 action - [r.F07] - Alarm 2 action - [r.F07] - Alarm 2 action - [r.F07] - Alarm 2 action - [r.F07] - Alarm 2 action - [r.F07] 2) The change from On to OFF has immediate effect, while the change from OFF to On has effect at the next start up or set This parameter is available only when OUT 2 is configured as point change...
  • Page 96 - Alarm 3 configuration - [r.F10] - Alarm 3 configuration - [r.F10] - Alarm 3 configuration - [r.F10] - Alarm 3 standby (mask) function - [r.F12] - Alarm 3 standby (mask) function - [r.F12] - Alarm 3 standby (mask) function - [r.F12] - Alarm 3 configuration - [r.F10] - Alarm 3 configuration - [r.F10] - Alarm 3 standby (mask) function - [r.F12]...
  • Page 97 - Alarm 4 type - [r.F13] - Alarm 4 type - [r.F13] - Alarm 4 type - [r.F13] - Alarm 4 type - [r.F13] - Alarm 4 type - [r.F13] H.L. = High alarm (outside band) with manual reset L.L. = Low alarm (inside band) with manual reset This parameter is available only when OUT 4 is configured as NOTE...
  • Page 98 - OFD (Output Failure Detection) alarm action - OFD (Output Failure Detection) alarm action - OFD (Output Failure Detection) alarm action the alarm threshold plus or minus hysteresis. If the alarm is - OFD (Output Failure Detection) alarm action - OFD (Output Failure Detection) alarm action - [r.F18] - [r.F18] - [r.F18]...
  • Page 99 - Serial link baud rate - [r.G03] - Serial link baud rate - [r.G03] - Serial link baud rate - [r.G03] Run time group 7 [r.Gxx] Run time group 7 [r.Gxx] Run time group 7 [r.Gxx] Run time group 7 [r.Gxx] Run time group 7 [r.Gxx] - Serial link baud rate - [r.G03] - Serial link baud rate - [r.G03]...
  • Page 100 - Servomotor low limit positioning - [r.H02] - Servomotor low limit positioning - [r.H02] - Servomotor low limit positioning - [r.H02] Run time group 8 [r.Hxx] Run time group 8 [r.Hxx] Run time group 8 [r.Hxx] Run time group 8 [r.Hxx] Run time group 8 [r.Hxx] - Servomotor low limit positioning - [r.H02] - Servomotor low limit positioning - [r.H02]...
  • Page 101 - Servomotor high limit positioning - [r.H04] - Servomotor high limit positioning - [r.H04] - Servomotor high limit positioning - [r.H04] - Servomotor high limit positioning - [r.H04] - Servomotor high limit positioning - [r.H04] This procedure is now completed and the calibration values are automatically checked.
  • Page 102 Run time group 9 [r.Ixx] Run time group 9 [r.Ixx] Run time group 9 [r.Ixx] Run time group 9 [r.Ixx] Run time group 9 [r.Ixx] 2) When a program is running and the tracking above value of TRACKING VALUES. the segment in progress has been modified, the new value will be immediately used.
  • Page 103 - Group 9 default data loading - [r.I03] - Group 9 default data loading - [r.I03] - Group 9 default data loading - [r.I03] - Group 9 default data loading - [r.I03] - Group 9 default data loading - [r.I03] Run time group "dF"...
  • Page 104 - Maximum value of proportional band - Maximum value of proportional band - Maximum value of proportional band Run time group "Hd" [r.Mxx] Run time group "Hd" [r.Mxx] Run time group "Hd" [r.Mxx] Run time group "Hd" [r.Mxx] Run time group "Hd" [r.Mxx] - Maximum value of proportional band - Maximum value of proportional band calculated by SMART algorithm - [r.M02]...

  • Page 105: Programmer Mode

    - Relative gain of the secondary output - Relative gain of the secondary output - Relative gain of the secondary output - Relative gain of the secondary output - Relative gain of the secondary output PROGRAMMER MODE PROGRAMMER MODE PROGRAMMER MODE PROGRAMMER MODE PROGRAMMER MODE calculated by SMART algorithm - [r.M05]...
  • Page 106 EDIT EDIT EDIT EDIT EDIT. The MANUAL mode can be activated: In this mode it is possible to select and/or to create a program - manually when the instrument is in STAND-BY mode or and to visualize and/or to modify all data of a program. - automatically at the end of a program execution (if pro- When the instrument is in EDIT mode, by the RUN pushbutton grammed).
  • Page 107 HOLD HOLD HOLD HOLD HOLD JUMP JUMP JUMP. JUMP JUMP This function temporarily stops a running program by a manual This function is used, during HOLD mode, to jump to the action. beginning of the next segment or to the end of the previous The HOLD mode may be activated by the RUN pushbutton one, from where it is desired to restart the program.

  • Page 108: Bargraph Description

    BARGRAPH DESCRIPTION BARGRAPH DESCRIPTION BARGRAPH DESCRIPTION BARGRAPH DESCRIPTION BARGRAPH DESCRIPTION On the left bargraph, with green LED’s, it is possible to show: For MKP model only, two 33 LED’s bargraphs are available. - the process variable scaled as configured by “brG.L” [C.I03] and “brG.H”...

  • Page 109: Indicators

    INDICATORS INDICATORS INDICATORS INDICATORS INDICATORS and it is moving on a ramp up. Flashing fast when the FAST BACKWARD is in progress °C Lit when process variable is in Centigrade degrees. and it is moving on a ramp up. °F Lit when process variable is in Fahrenheit degrees.

  • Page 110: Display Function During Programmer Mode

    Flashes when alarm 2 is in alarm state and it is not DISPLAY FUNCTION DISPLAY FUNCTION DISPLAY FUNCTION DISPLAY FUNCTION DISPLAY FUNCTION DURING PROGRAMMER MODE DURING PROGRAMMER MODE DURING PROGRAMMER MODE DURING PROGRAMMER MODE DURING PROGRAMMER MODE acknowledged. Lit when OUT 3 is used as control output and it is in ON When device operates in programmer mode and a program When device operates in programmer mode and a program When device operates in programmer mode and a program...
  • Page 111 indication. d) Push the FUNC pusbutton again; the lower display shows It will show: "d." followed by the tracking below value programmed for the - the time remaining to the end of the segment, if the specific segment. The instrument will show 0 if no tracking segment in progress is a ramp band is assigned.
  • Page 112 l) Push the FUNC pusbutton again; the lower display shows - Pushing FUNC push-button again, the display will come " Fd." followed by the OUT failure detection alarm status: back to the initial indication. = no alarm All the visualization are not bound to a time out unless OFD AL (flashing) = alarm (output failure detection) is in alarm condition and the alarm has AL (steady) = acknowledged alarm...

  • Page 113: Output Power Off Function

    When device operates in programmer mode and no When device operates in programmer mode and no When device operates in programmer mode and no When device operates in programmer mode and no When device operates in programmer mode and no OUTPUT POWER OFF FUNCTION during pr OUTPUT POWER OFF FUNCTION during pr OUTPUT POWER OFF FUNCTION during programmer mode...

  • Page 114: Clock Calendar

    It is possible to activate the O.P.O. mode by: NOTES NOTES NOTES NOTES NOTES: - serial link A ) If the program selection is made by logic inputs, three - by keyboard different situations may occur: - automatically at the end of a program execution. A.1) the selected program exists, the starting program will be the program selected by logic input;...

  • Page 115: Out Failure Detection Function (Ofd)

    OUT FAILURE DETECTION FUNCTION (OFD) OUT FAILURE DETECTION FUNCTION (OFD) OUT FAILURE DETECTION FUNCTION (OFD) OUT FAILURE DETECTION FUNCTION (OFD) OUT FAILURE DETECTION FUNCTION (OFD) SERIAL LINK SERIAL LINK SERIAL LINK SERIAL LINK SERIAL LINK The device is capable to measure and display: The device can be connected to a host computer by a serial - the current running in a load driven by a time proportional link.

  • Page 116: Lamp Test

    LAMP TEST LAMP TEST LAMP TEST LAMP TEST LAMP TEST When in MANUAL mode the LED's MAN lights up while the When it is desired to verify the display efficiency, put the middle display shows "ñ." followed by the main output values instrument in "normal display mode"...

  • Page 117: Direct Access To The Set Point

    At power up the device starts as configured at “St.Fn” [C.G06] DIRECT ACCESS TO THE SET POINT DIRECT ACCESS TO THE SET POINT DIRECT ACCESS TO THE SET POINT DIRECT ACCESS TO THE SET POINT DIRECT ACCESS TO THE SET POINT configuration parameter.

  • Page 118: General Notes About Program Editing

    GENERAL NOTES ABOUT PROGRAM EDITING GENERAL NOTES ABOUT PROGRAM EDITING GENERAL NOTES ABOUT PROGRAM EDITING GENERAL NOTES ABOUT PROGRAM EDITING GENERAL NOTES ABOUT PROGRAM EDITING EDIT MODE EDIT MODE EDIT MODE EDIT MODE EDIT MODE This instrument allows to create up to 90 simple programs with By the EDIT mode it is possible to create, modify or delete all a free number of segments for each program.
  • Page 119 Run time group P [r.Axx] Run time group P [r.Axx] Run time group P [r.Axx] Run time group P [r.Axx] Run time group P [r.Axx] 2) If no segment is available, the instrument will show the Program editing existing programs only. 3) It is not possible to select a linked program (from L1 to L9) if no simple program is programmed.
  • Page 120 - Event 1 enabling - [r.A04] - Event 1 enabling - [r.A04] - Event 1 enabling - [r.A04] - Event 1 enabling - [r.A04] - Event 1 enabling - [r.A04] program will use the starting measured value as initial set point value. This parameter can be modified only when the selected program is not running, it is not a linked program and output 1 is configured as timer event, break event, end cycle or end...
  • Page 121 - Program 1 - Segment 1 - segment duration - Program 1 - Segment 1 - segment duration - Program 1 - Segment 1 - segment duration - Program 1 - Segment 1 - PID group selection - Program 1 - Segment 1 - PID group selection - Program 1 - Segment 1 - PID group selection - Program 1 - Segment 1 - segment duration - Program 1 - Segment 1 - segment duration...
  • Page 122 Range: from 0 to 10. NOTE 1 NOTE 1 NOTE 1 NOTE 1 NOTE 1: For Break event 2 to 4 and for Break event 10 to 19, NOTE NOTE NOTE NOTE NOTE: setting trK.G equal to 0, the instrument will not the instrument will show on the lower display the respective use, for this segment, the tracking function.
  • Page 123 - Break event reset at the end of program 1 - Break event reset at the end of program 1 - Break event reset at the end of program 1 - Break event reset at the end of program 1 - Break event reset at the end of program 1 ñSP At the end of the program the instrument will - [r.A13]...
  • Page 124 - Program 1 - Timer event 1 - Step 1 - [r.A18] - Program 1 - Timer event 1 - Step 1 - [r.A18] - Program 1 - Timer event 1 - Step 1 - [r.A18] from -100.0 to 100.0 % if the devices is configured with - Program 1 - Timer event 1 - Step 1 - [r.A18] - Program 1 - Timer event 1 - Step 1 - [r.A18] two control outputs (split range excluded).
  • Page 125 General notes about timer events General notes about timer events General notes about timer events General notes about timer events General notes about timer events to add to the selected linked program" [r.A19] (see below) and Up to 14 timer events can be associate to each program. "Number of linked program repetition"...

  • Page 126: Simple Program Management

    SIMPLE PROGRAM MANAGEMENT SIMPLE PROGRAM MANAGEMENT SIMPLE PROGRAM MANAGEMENT SIMPLE PROGRAM MANAGEMENT SIMPLE PROGRAM MANAGEMENT For event enabling, the instrument will show only the number of the outputs configured as timer event, break HOW TO CREATE A SIMPLE PROGRAM HOW TO CREATE A SIMPLE PROGRAM HOW TO CREATE A SIMPLE PROGRAM HOW TO CREATE A SIMPLE PROGRAM HOW TO CREATE A SIMPLE PROGRAM...
  • Page 127 NOTES NOTES NOTES NOTES NOTES: 4) When the final set point of a ramp has been modified and 1) When the final set point of a ramp has been modified and the ramp becomes a soak and the eng. unit of the ramp was the next segment is a soak, the instrument automatically equal to "GrAd", the instrument sets the soak time of this modifies the final set point of the next segment also.
  • Page 128 3) select the final set point of the segment x+1: When it is desired to delete the segment x, proceed as follows: 4) push "RUN" + " " pushbuttons; the display will show the 1) select the Group P (EDIT mode); final set point of the new segment with the "End"...

  • Page 129: Linked Program Management

    LINKED PROGRAM MANAGEMENT LINKED PROGRAM MANAGEMENT LINKED PROGRAM MANAGEMENT LINKED PROGRAM MANAGEMENT LINKED PROGRAM MANAGEMENT 3) When it is desired to end the program, after the last used program number it is sufficent to set "END" for the next HOW TO CREATE A LINKED PROGRAM HOW TO CREATE A LINKED PROGRAM HOW TO CREATE A LINKED PROGRAM HOW TO CREATE A LINKED PROGRAM...

  • Page 130: How To Check A Program

    HOW TO MODIFY A LINKED PROGRAM HOW TO MODIFY A LINKED PROGRAM HOW TO MODIFY A LINKED PROGRAM HOW TO MODIFY A LINKED PROGRAM HOW TO MODIFY A LINKED PROGRAM If an error is detected, one of the following error messages will When it is desired to modify a linked program it is necessary to be shown on the lower display: re-edit it.

  • Page 131: How To Run A Program (Simple Or Linked)

    E.ñ simple program not existing (the central display will instrument shows the linked program from L1 to L9). NOTE NOTE show the number of the not existing program). NOTE NOTE NOTE: for program selection the PRG LED must be lit in This message will be shown when a simple program, steady state.

  • Page 132: Actions Available During Running Mode

    and an error message will be shown (for more details 5) to manually and temporarily stop the program execution about this group of error messages see "How to check a (HOLD); program"). 6) to move forward or backward the executing point of the During RUN mode the arrows LED will show the type of program 60 time faster than the programmed value (HOLD +...
  • Page 133 ABORT ABORT ABORT ABORT ABORT 2) the instrument continues to control the process using a fixed This function allows to definitively stop the program in progress. set point; When it is desired to ABORT the program push the RUN 3) the time count of the timer events will not be stopped; pusbutton and maintain the pressure until the RUN LED will be 4) all standard functions (like alarms, Output failure detection, turned OFF.
  • Page 134 FAST FAST FAST FAST FAST NOTES NOTES NOTES NOTES NOTES: This function allows to move, forward or backward, the point of 1) When the FAST function is activated, the central display will the program in progress 60 time faster than the programmed show the same indication described for the RUN mode.

  • Page 135: Contoller Mode

    4) When the desired point has been reached, restart the CONTOLLER MODE CONTOLLER MODE CONTOLLER MODE CONTOLLER MODE CONTOLLER MODE program. NOTES NOTES NOTES NOTES NOTES: During Controller mode the instrument operates as a standard 1) When the JUMP function is activated, the central display will controller.

  • Page 136: Display Function During Controller Mode

    DISPLAY FUNCTION DURING CONTROLLER MODE DISPLAY FUNCTION DURING CONTROLLER MODE DISPLAY FUNCTION DURING CONTROLLER MODE DISPLAY FUNCTION DURING CONTROLLER MODE DISPLAY FUNCTION DURING CONTROLLER MODE significant digits while the value of the SECONDARY When device is powered and it is operating in automatic mode, output is shown on the two less significant digits.
  • Page 137 0.0 % to 99.9 % or a value within the scale configured by All the seven types of visualization are not bound to a time out “ñC.E.L” [C.F09] and “ñC.E.H” [C.F10] when a scaled unless OFD (output failure detection) is in the not acknowl- readout is applied to the main output.

  • Page 138: Indicators Function During Controller Mode

    INDICATORS function during controller mode INDICATORS function during controller mode INDICATORS function during controller mode INDICATORS function during controller mode INDICATORS function during controller mode Event 3 is activated or when alarm 3 is in alarm state and acknowledged. °C Lit when process variable is in Celsius degrees.

  • Page 139: Smart Function

    SMART FUNCTION SMART FUNCTION SMART FUNCTION SMART FUNCTION SMART FUNCTION NOTES NOTES NOTES: NOTES NOTES 1) When ON/OFF control is programmed (Pb=0), the SMART function is disabled. It is used to automatically optimize the control action. 2) The SMART enabling/disabling can be protected To enable the SMART function proceed as follows: by safety key.
  • Page 140 OUTPUT POWER OFF FUNCTION during contr OUTPUT POWER OFF FUNCTION during contr OUTPUT POWER OFF FUNCTION during contr OUTPUT POWER OFF FUNCTION during contr OUTPUT POWER OFF FUNCTION during controller mode oller mode oller mode oller mode oller mode By this mode it is possible to disable the process control. In this mode, the instrument operate as an indicator and: - the middle display shows O.P.O.;...

  • Page 141: Error Messages

    ERROR MESSAGES ERROR MESSAGES ERROR MESSAGES ERROR MESSAGES ERROR MESSAGES a) When “SF.Cn” [C.G09] is set to “Std.”: a.1) An OVERRANGE is detected and OVERRANGE, UNDERRANGE AND SENSOR LEADS OVERRANGE, UNDERRANGE AND SENSOR LEADS OVERRANGE, UNDERRANGE AND SENSOR LEADS OVERRANGE, UNDERRANGE AND SENSOR LEADS OVERRANGE, UNDERRANGE AND SENSOR LEADS - the device is set for one control output only, the output BREAK DETECTION...
  • Page 142 d) When “SF.Cn” [C.G09] is set to “Undr” These instruments are capable to detect, on the main input, the d.1) if an underrange condition is detected, the power sensor leads break condition. output is forced to the safety value “SF.UL” [C.G10] When the sensor leads break condition is detected, the d.2) if an overrange condition is detected the instrument will instrument shows “OPEn”...
  • Page 143 ON THE AUXILIARY INPUT ON THE AUXILIARY INPUT ON THE AUXILIARY INPUT ON THE AUXILIARY INPUT ON THE AUXILIARY INPUT 2) When a fault condition different from overrange or When the remote set point trim signal exceeds the full scale underrange is detected on the auxiliary input, the alarms, the value programmed by "A.In.t"...
  • Page 144 ERROR MESSAGES ERROR MESSAGES ERROR MESSAGES ERROR MESSAGES ERROR MESSAGES Configuration and run time parameter errors. Configuration and run time parameter errors. Configuration and run time parameter errors. Configuration and run time parameter errors. Configuration and run time parameter errors. When one of this error is detected, following the procedures At the end of each configuration parameter group modification described for standard parameter modification, reach the group...
  • Page 145 Calibration parameter errors Calibration parameter errors Calibration parameter errors Calibration parameter errors Calibration parameter errors The instrument is also capable to detect the following errors: The instrument will show on the lower display one of the E.100 Error during data saving in FRAM following indications: E.110 Error in FRAM handling ñ.I.tc...

  • Page 146: General Informations

    Dimensions Dimensions This instrument is marked CE. - 48 x 96 mm, depth 128 mm for PKP model. Therefore, it is conforming to council directives 89/336/EEC for - 96 x 96 mm, depth 128 mm for MKP model. electromagnetic compatibility and to council directives 73/23/...
  • Page 147 Installation category Installation category Installation category Installation category Installation category: II Temperature drift Temperature drift Temperature drift Temperature drift Temperature drift: (CJ excluded) Ranges Ranges Ranges Ranges Ranges < 200 ppm/°C of span for mV and TC ranges 3, 4, 7, 18, 19, 22. type type type...
  • Page 148 Ranges Ranges Ranges Ranges Ranges C) LINEAR INPUTS C) LINEAR INPUTS C) LINEAR INPUTS C) LINEAR INPUTS C) LINEAR INPUTS type type type type type Read-out Read-out Read-out Read-out Read-out: keyboard programmable between -1999 and +9999. Decimal point Decimal point Decimal point: programmable in any position Decimal point Decimal point...
  • Page 149 CURRENT TRANSFORMER INPUT FOR OUT FAILURE CURRENT TRANSFORMER INPUT FOR OUT FAILURE STANDARD RANGES TABLE CURRENT TRANSFORMER INPUT FOR OUT FAILURE CURRENT TRANSFORMER INPUT FOR OUT FAILURE CURRENT TRANSFORMER INPUT FOR OUT FAILURE Input type Input type Input type Input type Input type impedance impedance...
  • Page 150 CONTROL ACTIONS CONTROL ACTIONS CONTROL ACTIONS CONTROL ACTIONS CONTROL ACTIONS Proportional Band Proportional Band Proportional Band Proportional Band Proportional Band: programmable from 0.5% to 999.0% of Algorithm Algorithm Algorithm Algorithm Algorithm: PID + SMART the input span. T y p e s : T y p e s : T y p e s : T y p e s :...
  • Page 151 Output limiters Output limiters Output limiters Output limiters Output limiters. O U T P U T S O U T P U T S O U T P U T S O U T P U T S O U T P U T S For the main and/or secondary control outputs it is possible to set: Control output updating time...
  • Page 152 Out 1 and 2 - SSR Out 1 and 2 - SSR Out 1 and 2 - SSR Out 1 and 2 - SSR Out 1 and 2 - SSR Contact rating Contact rating Contact rating Contact rating Contact rating: 3 A @ 250 V on resistive load. Type: not Type: not Notes...
  • Page 153 Output type Output type Output type Output type Output type: Isolated output programmable as ALARMS ALARMS ALARMS ALARMS ALARMS - 0-20 mA Alarm action Alarm action Alarm action: direct or reverse function programmable. Alarm action Alarm action - 4-20 mA. Alarm functions Alarm functions Alarm functions: each alarm can be configured as process...
  • Page 154 Deviation alarm Deviation alarm Deviation alarm Deviation alarm Deviation alarm EVENTS EVENTS EVENTS EVENTS EVENTS Operative mode Operative mode Operative mode Operative mode Operative mode: High or low programmable. All the 14 digital outputs are programmable as events. Threshold Threshold Threshold Threshold Threshold: programmable from - 1000 to +1000 digits.

  • Page 155: Maintenance

    AUXILIARY POWER SUPPLY AUXILIARY POWER SUPPLY AUXILIARY POWER SUPPLY AUXILIARY POWER SUPPLY AUXILIARY POWER SUPPLY MAINTENANCE MAINTENANCE MAINTENANCE MAINTENANCE MAINTENANCE Type: Type: Type: Type: Type: 24 V DC + 20% not isolated. 1) REMOVE POWER FROM THE POWER SUPPLY TERMINALS Max.

  • Page 156: Default Parameters

    DEFAULT PARAMETERS DEFAULT PARAMETERS DEFAULT PARAMETERS DEFAULT PARAMETERS DEFAULT PARAMETERS The middle and lower display will show: General notes: General notes: General notes: General notes: General notes: A complete and consistent set of run time and configuration parameters is memorized in the instrument. These data are the A.3) By pushbuttons, select the "On"...
  • Page 157 B.4) Push the FUNC pushbutton. bA1.h The middle display will show: = Initial range value (for process alarm) = 0 (for deviation alarm) = 0.0 (for control output alarm) and then it will show: bA2.L bA2.h = Initial range value (for process alarm) The default parameter loading procedure of all run time = 0 (for deviation alarm) parameters is ended.
  • Page 158 Run time group 4 [r.dxx] Run time group 4 [r.dxx] Run time group 4 [r.dxx] Run time group 4 [r.dxx] Run time group 4 [r.dxx] IP 2 = 50.0 (If only one control output is configured). PARAMETER DEFAULT VALUE 0.0 (If two control outputs, without split = 4.0 % range, are configured).
  • Page 159 Pb 5 = 4.0 % S.OLH = 100.0% HYS 5 = 0.5 % S.rñP = Inf ti 5 = 4.00 mm.ss SC.CY = 15 s (If relay output) td 5 = 1.00 mm.ss 2 s (If SSR output) IP 5 = 50.0 (If only one control output is configured).
  • Page 160 A3.Ac = rEV Run time group 9 [r.Ixx] Run time group 9 [r.Ixx] Run time group 9 [r.Ixx] Run time group 9 [r.Ixx] Run time group 9 [r.Ixx] A3.St = OFF PARAMETER DEFAULT VALUE A4.tP = Proc t.A.1 = 500 A4.Cn = H.A.
  • Page 161 Run time group Hd [r.Lxx] Run time group Hd [r.Lxx] Run time group Hd [r.Lxx] Run time group Hd [r.Lxx] Run time group Hd [r.Lxx] DEFAULT CONFIGURATION AND USER PARAMETERS DEFAULT CONFIGURATION AND USER PARAMETERS DEFAULT CONFIGURATION AND USER PARAMETERS DEFAULT CONFIGURATION AND USER PARAMETERS DEFAULT CONFIGURATION AND USER PARAMETERS PARAMETER...
  • Page 162 - turned OFF the bargraph displays (MKC only); The central display will show: - sets analog retransmissions to the retransmitted initial scale value; and then the display will show: - sets alarms in no alarm condition; - sets events to OFF; - disables the serial link;...
  • Page 163 A.In.F nonE O5.Hr 1000 °C A.In.t 4-20 O5.FL No filter A.In.L °C O6.Fn nonE If option is not mounted A.In.H 1000 °C SP.rt If option is mounted A.I.FL (No filter) O6.rn 4-20 4-20 mA O6.Lr °C O6.Hr 1000 °C Configuration group 2 [C.Exx] Configuration group 2 [C.Exx] O6.FL (No filter)
  • Page 164 d3.St OPEn ----. SC.dP (No decimal figure) I1.Fn nonE SC.E.L I1.St OPEn SC.E.H I2.Fn nonE SC.A.C bEFr I2.St OPEn I3.Fn nonE Configuration group 4 [C.Gxx] Configuration group 4 [C.Gxx] Configuration group 4 [C.Gxx] Configuration group 4 [C.Gxx] Configuration group 4 [C.Gxx] I3.St OPEn PARAM.
  • Page 165 F.E.10 nonE Configuration group 6 [C.Ixx] Configuration group 6 [C.Ixx] Configuration group 6 [C.Ixx] Configuration group 6 [C.Ixx] Configuration group 6 [C.Ixx] S.E.10 OPEn PARAM. VALUE NOTES F.E.11 nonE G.brG S.E.11 OPEn O.brG P.Out F.E.12 nonE brG.L -100 °C S.E.12 OPEn brG.H 1370...
  • Page 166 TABLE 2 TABLE 2 TABLE 2 TABLE 2 TABLE 2 is mounted O2.Fn ALr.2 Configuration group 1 [C.dxx] Configuration group 1 [C.dxx] Configuration group 1 [C.dxx] Configuration group 1 [C.dxx] Configuration group 1 [C.dxx] O3.Fn nonE If option is not mounted PARAM.
  • Page 167 Configuration group 3 [C.Fxx] Configuration group 3 [C.Fxx] Configuration group 3 [C.Fxx] Configuration group 3 [C.Fxx] Configuration group 3 [C.Fxx] Configuration group 4 [C.Gxx] Configuration group 4 [C.Gxx] Configuration group 4 [C.Gxx] Configuration group 4 [C.Gxx] Configuration group 4 [C.Gxx] PARAM.
  • Page 168 I2.Fn nonE S.E.11 OPEn I2.St OPEn F.E.12 nonE I3.Fn nonE S.E.12 OPEn I3.St OPEn F.E.13 nonE I4.Fn nonE S.E.13 OPEn I4.St OPEn F.E.14 nonE I5.Fn nonE S.E.14 OPEn I5.St OPEn F.E.15 nonE I6.Fn nonE S.E.15 OPEn I6.St OPEn F.E.16 nonE I7.Fn nonE S.E.16...
  • Page 169 Configuration group 6 [C.Ixx] Configuration group 6 [C.Ixx] Configuration group 6 [C.Ixx] Configuration group 6 [C.Ixx] Configuration group 6 [C.Ixx] PARAM. VALUE NOTES G.brG O.brG P.Out brG.L -150 °F brG.H 2500 °F brG.d °F SP.AL n.ALG SP.dS OP.SP Sr.bH SS.tr -150 °F t.out...

  • Page 170: Coding

    CODING MODEL: MODEL: MODEL: MODEL: MODEL: MKP = 1/4 DIN PKP = 1/8 DIN INPUT INPUT INPUT: : : : : 1 = Main + Aux-in + Logic Inputs INPUT INPUT 6 = Main + Aux-in + Logic Inputs +OFD (or Feedback selectable)
  • Page 171 xkp-a-D1.pmd 25/05/2006, 11.29...
  • Page 172 Div. of Eurotherm S.r.l Div. of Eurotherm S.r.l Div. of Eurotherm S.r.l Div. of Eurotherm S.r.l Div. of Eurotherm S.r.l Via E. Mattei, 21 28100 Novara Italy Tel. +39 0321481111 Fax +39 0321481112 E-mail eroservice@eurotherm.it Http://www.eroelectronic.com xkp-a-D1.pmd 25/05/2006, 11.29...

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