JUMO AQUIS touch S Assembly Instructions Manual
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JUMO AQUIS touch S Assembly Instructions Manual

JUMO AQUIS touch S Assembly Instructions Manual

Modular multichannel measuring device for liquid analysis with integrated controller and paperless recorder
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JUMO AQUIS touch S
Modular multichannel measuring device for
liquid analysis with integrated controller and
paperless recorder
Assembly instructions
Volume 2(2)
20258100T94Z201K000
V3.00/EN/00610006

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  • Page 1 JUMO AQUIS touch S Modular multichannel measuring device for liquid analysis with integrated controller and paperless recorder Assembly instructions Volume 2(2) 20258100T94Z201K000 V3.00/EN/00610006...
  • Page 2 Caution! If the device or a sensor connected to it fails abruptly, it is likely that a dangerous overdosage has occurred! For this case, appropriate precautionary measures must be taken. NOTE! Read these installation instructions before starting up the device. Store these installation instructions in a place that is accessible to all users at all times.

  • Page 3: Table Of Contents

    Digital sensors ................. 31 10.10.1 General .................... 31 10.10.2 Configuration ................... 32 10.10.3 Sensor alarms .................. 38 10.10.4 CIP/SIP definition (JUMO digiLine pH only) ........41 10.10.5 Calibration timer ................41 10.11 Input alarm functions ............... 42 10.11.1 Alarms for analog signals and digital sensors ......... 42...
  • Page 4 Inhalt 10.12 Calibration timer ................46 10.12.1 Configuration of the calibration timers ..........46 10.13 Serial interfaces ................47 Calibration in general .............49 11.1 Important information ............... 49 11.2 General information ................. 49 11.2.1 General procedure for calibration ............ 49 11.3 Calibration logbook ................
  • Page 5 Inhalt 14.3.1 Zero-point calibration ............... 70 Calibrating CR conductivity sensors ......71 15.1 Important information ............... 71 15.2 General information ................. 71 15.2.1 Calibration methods for CR conductivity sensors (conductive) ..71 15.2.2 Calibration presets for CR conductivity sensors ......72 15.3 CR calibration routines ..............
  • Page 6 Inhalt Calibrating O-DO sensors ..........99 18.1 Important information ............... 99 18.2 General information ................. 99 18.2.1 Calibration methods for O-DO sensors .......... 100 18.2.2 Calibration default settings for O-DO sensors ....... 100 18.3 O-DO calibration routine ..............102 18.3.1 End value calibration ..............102 18.3.2 Two-point Calibration ..............
  • Page 7 Troubleshooting and remedies for digital sensors ......129 21.1.1 Possible faults on sensors with JUMO digiLine electronics ... 129 21.1.2 Possible faults on digital JUMO ecoLine and tecLine sensors ..132 21.2 Planning the cabling for digital sensors ......... 135 21.2.1 Voltage supply to the bus with DC 5 V from a...
  • Page 8 Inhalt...

  • Page 9: Configuration

    NOTE! Changes to the configuration settings described in this chapter can be made directly on the device or via the JUMO PC setup program. NOTE! Settings in the "Configuration" menu can be changed only if a user with corre- sponding user rights is logged in.

  • Page 10: Basic Settings

    Configuration point Selection/ Explanation setting option Device name up to 20 text characters Device ID, e.g. for identification of exported mea- surement data in the JUMO PCA 3000 evalua- tion software National language German Setting the operating language English Additional languages can be installed on the de- vice using the setup program.

  • Page 11: Display

    10 Configuration 10.4 Display 10.4.1 General Open: Device Menu > Configuration > Display > General Configuration point Selection/ Explanation setting option Lock touchscreen Selection from Digital signal that blocks operation of the touch- binary selector screen (e.g. key switch for locking operation) Simulation of When this function is activated, alternating on/off inputs...

  • Page 12: Screen

    10 Configuration 10.4.2 Screen Open: Device Menu > Configuration > Display > Screen Configuration item Selection/ Explanation setting option Activation of screen- inactive Type of screensaver activation saver time to switch off control signal Wait time for screen- 10 to 32767 s only with activation of the screensaver after saver wait time:...

  • Page 13: Operating Loop

    10 Configuration 10.5 Operating loop 10.5.1 General screens Open: Device Menu > Configuration > Operation Loop > General Screen > General Screen 1 to 2 Configuration point Selection/ Explanation setting option Gener. screen type 2-part screen Selection of the type of overview screen; 4-part screen 2-part screen: Display of 2 main values, 2 sec- ond values, 1 additional value and 3 binary val-...

  • Page 14: Detailed Screens

    10 Configuration 10.5.2 Detailed screens Open: Device menu > Configuration > Operation Loop > Individual screen > Individual screen 1 to 6 Configuration point Selection/ Explanation setting option Screen title up to 31 text characters Title of the individual screen Input signal main val- Selection from Signal source of the analog value displayed as...

  • Page 15: Analog Inputs

    Each value pair assigns a display value (Y-column) to a measuring value (X-column). Up to 8 linearization tables can be stored. To cre- ate a linearization table, you need the JUMO PC setup program. ⇨ Operating manual B 202581.0...
  • Page 16 10 Configuration Configuration point Selection/ Explanation setting option 0 to 99999 Ω only for IN 5: Resistance value between the slid- er (S) and start point (A) in a resistance transmit- ter/potentiometer when the slider is at the start point. 6 to 99999 Ω...

  • Page 17: Universal Inputs Of Base Unit And Optional Boards

    10 Configuration 10.6.2 Universal inputs of base unit and optional boards Base unit universal input: IN 6 Optional board universal inputs: IN 11/12 Open: Device Menu > Configuration > Analog Inputs > Universal Input 1 to 3 > Configuration Configuration point Selection/ Explanation setting option Description...
  • Page 18 Each value pair assigns a display value (Y-column) to a measuring value (X-column). Up to 8 linearization tables can be stored. To cre- ate a linearization table, you need the JUMO PC setup program. ⇨ Operating manual B 202581.0...

  • Page 19: Calibration Timer

    10 Configuration Configuration point Selection/ Explanation setting option 6 to 4000 Ω only for IN 11/12: Span of the variable resistance value between the slider (S) and start point (A) 0 to 4000 Ω only for IN 11/12: Resistance value between the slider (S) and end point (E) in a resistance poten- tiometer when the slider is at the end point.
  • Page 20 10 Configuration ⇨ Chapter 10.12 "Calibration timer", page 46...

  • Page 21: Ph/Redox/Nh Analysis Inputs

    10 Configuration 10.6.4 pH/Redox/NH analysis inputs Open: Device Menu > Configuration > Analog Inputs > Analysis Input 1 to 4 > Configuration Configuration point Selection/ Explanation setting option Description up to 15 text characters Designation for the input Electrode type pH standard Type of electrode connected pH antimony...

  • Page 22: Calibration Timer

    10 Configuration Configuration point Selection/ Explanation setting option Text sensor alarm up to 21 text characters Text for the alarm/event list in case of sensor er- Alarms 1/2 Analog input alarms are used to monitor measured values in relation to adjustable limit values. The alarm settings for all analog device functions are explained together.

  • Page 23: Cr/Ci Analysis Inputs (Conductive/Inductive Conductivity)

    10 Configuration 10.6.6 CR/Ci analysis inputs (conductive/inductive conductivity) Open: Device Menu > Configuration > Analog Inputs > Analysis Input 1 to 4 > Configuration Configuration point Selection/ Explanation setting option Description up to 15 text characters Designation for the input Compensation tem- Selection from Analog input of the compensation thermometer...

  • Page 24: Calibration Timer

    10 Configuration Configuration point Selection/ Explanation setting option Alarm/Event list possible only for conductive conductivity event measurement: alarm Assignment of the sensor failure notification to alarm list or event list Sensor alarm 0 to 999 s possible only for conductive conductivity delay measurement: The sensor alarm is suppressed for the set dura-...
  • Page 25 10 Configuration The following table shows which binary value combinations activate the individ- ual measuring ranges: Active measuring Binary signal Digital signal range Measuring range selection 1 Measuring range switching 2 Measuring range 1 Measuring range 2 Measuring range 3 Measuring range 4...
  • Page 26 10 Configuration CR/Ci measuring range configuration Open: Device Menu > Configuration > Analog Inputs > Analysis Input 1 to 4 > Measuring Range 1 to 4 Configuration point Selection/ Explanation setting option TDS factor 0.01 to 2.00 only for conductive conductivity with TDS compensation: Conversion factor from measured conductivity to display unit (see configuration item "Unit"...
  • Page 27 Each value pair assigns a display value (Y-column) to a measuring value (X-column). Up to 8 linearization tables can be stored. To cre- ate a linearization table, you need the JUMO PC setup program. ⇨ Operating manual B 202581.0...

  • Page 28: Analog Outputs Of Base Unit And Optional Boards

    10 Configuration 10.7 Analog outputs of base unit and optional boards Open: Device Menu > Configuration > Analog Outputs > Analog Output 1 to 9 Configuration point Selection/ Explanation setting option Description up to 15 text characters Designation for the output Signal Selection from Analog signal source of the output...

  • Page 29: Digital Inputs Of Base Unit And Optional Boards

    10 Configuration Configuration point Selection/ Explanation setting option Response at hold Specification of the analog output value when the high hold function is activated, during calibration of NAMUR low one of the sensors for the particular output or at NAMUR high error (overrange/underrange) hold safety value...

  • Page 30: Digital Outputs Of Base Unit And Optional Boards

    10 Configuration 10.9 Digital outputs of base unit and optional boards Open: Device Menu > Configuration > Digital Outputs > Digital Output 1 to 17 Configuration point Selection/ Explanation setting option Description up to 21 text characters Designation for the output Signal Selection from Digital signal source for the output...

  • Page 31: Digital Sensors

    10 Configuration 10.10 Digital sensors NOTE! For operation of digital sensors, you need the extra code "JUMO digiLine pro- tocol activated“ (see Chapter 4.2 "Order Details", page 17) NOTE! Only one serial interface of the device can be configured for operation of digital sensors.

  • Page 32: Configuration

    The alarm settings for all analog device functions are explained together. ⇨ Chapter 10.11.1 "Alarms for analog signals and digital sensors", page 42 Only for sensors with JUMO digiLine pH/ORP/T Configuration point Selection/ Explanation setting option TAG checking...
  • Page 33 Temperature offset -10 to+10 °C Correction value that is added to the measured temperature value This setting is saved in the configuration of the JUMO digiLine electronics. The unit for the item set in "Parameter" appears in the entry field.
  • Page 34 Sensor temperature: The integrat- ed temperature probe of the O-DO sensor supplies the compensation temperature. Interface: The AQUIS touch S trans- mits the compensation temperature to the sensor electronics via the inter- face. The source of the compensa- tion temperature is set in the configuration point "Compensation...
  • Page 35 Filter Time Constant 0 to 25 s Optimization of measured value up- dating in the JUMO digiLine electron- The higher the value of the filter time const., the slower the measured val- ue is updated.
  • Page 36 10 Configuration For digital JUMO tecLine sensors only Configuration point Selection/ Explanation setting option Measuring range Setting of the measuring range for the various measurands of digital Free chlorine pH-dependent 2 ppm JUMO tecLine sensors Open chlorine measurement 20 ppm...
  • Page 37 10 Configuration Configuration point Selection/ Explanation setting option pH compensation source Selection from Analog available only with pH-compensa- selection tion activated: Analog input of the pH-value sensor for pH-compensated measurement of free chlorine The unit for the particular sensor value appears in the entry field.

  • Page 38: Sensor Alarms

    JUMO AQUIS touch S. The settings for the alarm conditions themselves are made in the configuration of the individual sensor electronics or stipulated by the specifications for the particular sensor.
  • Page 39 Alarm for sensor calibration due (see "Calibration data" in the JUMO digiLine pH operating manual) CIP/SIP/Autoclaving warning Pre-alarm for maximum number of CIP/SIP/autoclaving cycles (see "Sensor monitoring" in the JUMO digiLine pH operating manual) CIP/SIP/Autoclaving alarm Alarm for maximum number of CIP/SIP/autoclaving cy- cles (see "Sensor monitoring"...
  • Page 40 Alarm for redox value out of range Calibration timer alarm Alarm for sensor calibration due (see "Calibration data" in the JUMO digiLine ORP operating manual) Digital input state Signal state of the digital input of the sensor electronics JUMO digiLine T...

  • Page 41: Cip/Sip Definition (Jumo Digiline Ph Only)

    S, if the CIP, SIP or autoclaving counters in the JUMO digiLine electronics have reached the maximum number of permissible cycles. This setting is saved in the configuration of the JUMO digiLine electronics. 10.10.5 Calibration timer Open Calibration Timer Settings Digital Sensors: Device Menu >...

  • Page 42: Input Alarm Functions

    10 Configuration 10.11 Input alarm functions 10.11.1 Alarms for analog signals and digital sensors Open Temperature Inputs Alarm Configuration: Device Menu > Configuration > Analog Inputs > Temperature Inputs 1 to 2 Open Universal Inputs Alarm Configuration: Device Menu > Configuration > Analog Inputs > Universal Input 1 to 3 >...
  • Page 43 10 Configuration Configuration point Selection/ Explanation setting option Alarm type inactive Four alarm types (comparator functions) can be minimum alarm selected to monitor measured values for violation maximum alarm of limit values. ⇨ alarm window Characteristic lines after the table invert alarm window only for Limit value alarms to USP <645>...
  • Page 44 10 Configuration Minimum alarm (On-signal when value drops below lower limit) Binary value Hysteresis Input signal Limit value Maximum alarm(On-signal when value exceeds upper limit) Binary value Hysteresis Input signal Limit value Alarm window (On-signal within a configurable value range Binary value Hysteresis...

  • Page 45: Digital Signal Alarms

    10 Configuration 10.11.2 Digital signal alarms Open Alarm Configuration For Binary Inputs: Device Menu > Configuration > Binary Inputs > Binary Inputs 1 to 9 Open Alarm Configuration For External Binary Inputs: Device Menu > Configuration > External Binary Inputs > External Binary Inputs 1 to 8 Open Alarm Configuration For Logic Formula: Device Menu >...

  • Page 46: Calibration Timer

    JUMO AQUIS touch S. For sensors with JUMO digiLine electronics, only the calibration interval can be set. With pH and redox sensors with JUMO digiLine electronics, the calibration alarm is active automatically. The texts for alarm...

  • Page 47: Serial Interfaces

    (see order details for extra code "JUMO digiLine protocol activated") In the JUMO AQUIS touch P, either the inter- face on the base unit or the optional serial in- terface (if present) can be configured for digital sensors (JUMO digiLine operation).
  • Page 48 When connecting digital JUMO ecoLine sensors, the data format of the JUMO AQUIS touch S must be set to "8-1-no parity" prior to startup. Otherwise, the sensors will not begin operation. Format: Useful bit – stop bit – parity bit...

  • Page 49: Calibration In General

    11 Calibration in general 11.1 Important information WARNING! During the calibration, the relays and analog output signals assume the states configured for the calibration! The response of the output signals is set for each output in its "Response at calibration" configuration point. ⇨...
  • Page 50 11 Calibration in general • You must be logged in as a user with the right to perform calibrations. Fac- tory-preset users have all of these rights. ⇨ "Passwords and user rights", page 77 • You must ensure that the calibration default settings for the individual analy- sis inputs and, possibly, the universal inputs are set correctly.

  • Page 51: Calibration Logbook

    11 Calibration in general 11.3 Calibration logbook A separate logbook is maintained for each analysis and universal input. The last 10 successful calibrations of the input concerned are saved in the cal- ibration logbook. Canceled or failed calibrations (calibrations outside the per- missible limits) are not saved in the logbook, but rather noted in the event list.
  • Page 52 Tapping the "Details" button opens the selected logbook entry in the detail view. The detail view displays a table with all calibration values from a calibration pro- cedure. The "Service" button is used for diagnostic purposes by trained person- nel or JUMO Service.
  • Page 53 11 Calibration in general Assessment criteria pH calibrations (glass electrodes and ISFET connected to analysis measuring inputs as well as standard sig- nals connected to universal inputs) Calibration value [unit] — — < ≤ < < ≤ < Zero point [pH] 6 to 8 <...
  • Page 54 11 Calibration in general Calibration of conductivity sensors (analysis measuring inputs and standard signals connected to universal inputs) Calibration value [unit] — — < ≤ < < ≤ 150 < Rel. cell constant (CR) [%] 75 to 125 < ≤ <...

  • Page 55: Calibrating A Ph Measuring Chain

    The three- point calibration can be performed only for pH sensors on analysis inputs. It is not available for JUMO digiLine pH sensors. This method requires 3 buffer solutions with defined pH-values as references.

  • Page 56: Calibration Default Settings For Ph Sensors

    12 Calibrating a pH measuring chain 12.2.2 Calibration default settings for pH sensors Before you can perform a calibration, you must first enter the necessary calibra- tion default settings. The possible settings for the pH Calibration are described in the following. Open the calibration default settings: Device Menu >...
  • Page 57 "pH buf- brating and adjusting technical fer 1 to 3" are hidden. pH measuring instruments You need the JUMO PC setup program acc. to DIN 19267 to edit buffer set tables. Buffer 1 pH-value...
  • Page 58 12 Calibrating a pH measuring chain Parameter Possible settings Explanation Temperature com- Selection from Analog selection Temperature input for automatic acqui- pensation sition of the test/sample solution tem- perature during the calibration...

  • Page 59: Ph Calibration Routines

    Device Menu > Calibration > Select Analysis Input for pH/redox/ > Open Zero-Point Calibration for pH sensors with JUMO digiLine electronics: Device Menu > Calibration > Digital Sensor 1 to 6 > Open Zero- Point Calibration...
  • Page 60 12 Calibrating a pH measuring chain Step Action Entry of the pH-value of the buffer solution • without buffer recognition: Check whether the "pH buffer 1" matches the pH-value of the buffer solution used. If a buffer set table was not specified, the "buffer 1 pH"...

  • Page 61: Two-Point And Three-Point Calibration

    Device Menu > Calibration > Analysis Input Select Analysis Input for pH/redox/NH > Open Two-Point or Three-Point Calibration for pH sensors with JUMO digiLine electronics: Device Menu > Calibration > Digital Sensor 1 to 6 > Open Two- Point Calibration...
  • Page 62 12 Calibrating a pH measuring chain Step Action Entry of the pH-value of the buffer solution • without buffer recognition: Check whether the "pH buffer 1" matches the pH-value of the buffer solution used. If a buffer set table was not specified, the "buffer 1 pH"...

  • Page 63: Calibrating Redox Sensors

    13 Calibrating redox sensors 13.1 Important information WARNING! During the calibration, the relays and analog output signals assume the states configured for the calibration! The response of the output signals is set for each output in its "Response at calibration" configuration point. ⇨...

  • Page 64: Calibration Default Settings For Redox Sensors

    13 Calibrating redox sensors 13.2.2 Calibration default settings for Redox sensors Before you can perform a calibration, you must first enter the necessary calibra- tion default settings. The possible settings for the Redox calibration are de- scribed in the following. Open the calibration default settings: Device Menu >...

  • Page 65: Redox Calibration Routines

    Device Menu > Calibration > Select Analysis Input for pH/redox/ > Zero-Point Calibration for redox sensors with JUMO digiLine electronics: Device Menu > Calibration > Digital Sensor 1 to 6 > Zero-Point Calibration Check that the "Redox test solution" value displayed matches the Redox value of the test solution.
  • Page 66 13 Calibrating redox sensors Step Action Clean the Redox electrode and immerse it in the test solution. Wait until the measured value displayed stabilizes and then confirm the result of the measurement by pressing "OK". A protocol summarizing the calibration values determined then ap- pears.

  • Page 67: Two-Point Calibration

    Device Menu > Calibration > Select Analysis Input for pH/redox/ > Two-Point Calibration for redox sensors with JUMO digiLine electronics: Device Menu > Calibration > Digital Sensor 1 to 6 > Two-Point Calibration Enter the concentration value of the first reference solution in per- cent.
  • Page 68 13 Calibrating redox sensors...

  • Page 69: Calibrating Ammonia Sensors

    14 Calibrating ammonia sensors 14.1 Important information WARNING! During the calibration, the relays and analog output signals assume the states configured for the calibration! The response of the output signals is set for each output in its "Response at calibration" configuration point. ⇨...

  • Page 70: Ammonia Calibration Routines

    14 Calibrating ammonia sensors 14.3 Ammonia calibration routines NOTE! You must be logged in with corresponding user rights to perform calibrations. ⇨ Chapter 8.2.1 "Log-on/Log-out", page 91 14.3.1 Zero-point calibration Step Action Start the Zero-point calibration. Device Menu > Calibration > Select Analysis Input for pH/redox/ >...

  • Page 71: Calibrating Cr Conductivity Sensors

    15 Calibrating CR conductivity sensors 15.1 Important information WARNING! During the calibration, the relays and analog output signals assume the states configured for the calibration! The response of the output signals is set for each output in its "Response at calibration" configuration point. ⇨...

  • Page 72: Calibration Presets For Cr Conductivity Sensors

    15 Calibrating CR conductivity sensors 15.2.2 Calibration presets for CR conductivity sensors Before you can perform a calibration, you must first enter the necessary calibra- tion default settings. The possible settings for the CR calibration are described in the following. Open the calibration default settings: Device menu >...
  • Page 73 15 Calibrating CR conductivity sensors Calibration presets for calibrating the relative cell constant Parameter Possible settings Explanation Reference conductivi- 0 to 9999 mS/cm Conductivity of the reference solution Calibration presets for calibrating the temperature coefficient Parameter Possible settings Explanation Temperature com- Selection from Temperature input for automatic acquisition of the pensation...

  • Page 74: Cr Calibration Routines

    15 Calibrating CR conductivity sensors 15.3 CR calibration routines NOTE! Conductivity measuring inputs can be configured with measuring range change- over. Accordingly, calibrations must be performed for all "accessible measuring ranges". NOTE! You must be logged in with corresponding user rights to perform calibrations. ⇨...
  • Page 75 15 Calibrating CR conductivity sensors Step Action Ensure that • the sensor has been cleaned and is immersed in the test solu- tion, • the set reference conductivity matches the conductivity value of the test solution. Wait until the measured value displayed stabilizes and then con- firm the result of the measurement by pressing "OK".

  • Page 76: Calibrating The Temperature Coefficient

    15 Calibrating CR conductivity sensors 15.3.2 Calibrating the temperature coefficient Step Action Start calibration of the temperature coefficient. Device menu > Calibration > Select CR Analysis Input > TC Cali- bration Clean the sensor and immerse it in the sample solution. Ensure that the rel.
  • Page 77 15 Calibrating CR conductivity sensors Step Action • with temperature acquisition A prerequisite is that temperature compensation was specified in the calibration the presets. Bring the temperature of the sample solution to the requested val- ues of the reference and operation temperatures in succession. The order does not matter.
  • Page 78 15 Calibrating CR conductivity sensors...

  • Page 79: Calibrating Ci Conductivity Sensors

    16 Calibrating Ci conductivity sensors 16.1 Important information WARNING! During the calibration, the relays and analog output signals assume the states configured for the calibration! The response of the output signals is set for each output in its "Response at calibration" configuration point. ⇨...

  • Page 80: Calibration Presets For Ci Conductivity Sensors

    16 Calibrating Ci conductivity sensors TC curve (for nonlinear temperature coefficients) If the conductivity of a liquid whose temperature coefficient changes with tem- perature has to be measured, this method can determine 5 temperature coeffi- cients for 5 temperature intervals. In this way, it is possible to determine a good approximation of the temperature coefficient curve.
  • Page 81 16 Calibrating Ci conductivity sensors Sample screen: Ci calibration presets The calibration default settings enable the calibration routines to be accessed in the particular calibration menu. Calibration routines that are not enabled are not visible in the calibration menu. Additional calibration default settings are explained in the following table. Calibration presets for calibrating the relative cell constant Parameter Possible settings...
  • Page 82 16 Calibrating Ci conductivity sensors Calibration presets for calibrating the TC curve Parameter Possible settings Explanation Temperature com- Selection from Temperature input for automatic acquisition of the pensation analog selection test/sample solution temperature during the calibra- tion Starting temperature -50 to +250 °C The starting and final temperatures of the range for which a temperature coefficient curve is to be deter- Final temperature...

  • Page 83: Ci Calibration Routines

    16 Calibrating Ci conductivity sensors 16.3 Ci calibration routines NOTE! Conductivity measuring inputs can be configured with measuring range change- over. Accordingly, calibrations must be performed for all "accessible measuring ranges". NOTE! You must be logged in with corresponding user rights to perform calibrations. ⇨...
  • Page 84 16 Calibrating Ci conductivity sensors Step Action Ensure that • the sensor has been cleaned and is immersed in the test solu- tion, • the set reference conductivity matches the conductivity value of the test solution. Wait until the measured value displayed stabilizes and then con- firm the result of the measurement by pressing "OK".

  • Page 85: Calibrating The Temperature Coefficient (Tc)

    16 Calibrating Ci conductivity sensors 16.3.2 Calibrating the temperature coefficient (TC) Step Action Start calibration of the temperature coefficient. Device menu > Calibration > Select Ci analysis input or universal input > TC calibration Clean the sensor and immerse it in the sample solution. Ensure that the rel.
  • Page 86 16 Calibrating Ci conductivity sensors Step Action • with temperature acquisition A prerequisite is that temperature compensation was specified in the calibration the presets. Bring the temperature of the sample solution to the requested val- ues of the reference and operation temperatures in succession. The order does not matter.

  • Page 87: Calibrating The Tc Curve

    16 Calibrating Ci conductivity sensors 16.3.3 Calibrating the TC curve Step Action Start the desired calibration of the TC curve. Device menu > Calibration > Analysis input 1 to 4 (Ci) or universal input 1 to 3 r TC curve Clean the sensor and immerse it in the sample solution.
  • Page 88 16 Calibrating Ci conductivity sensors...

  • Page 89: Calibrating Universal Inputs

    17 Calibrating universal inputs 17.1 Important information WARNING! During the calibration, the relays and analog output signals assume the states configured for the calibration! The response of the output signals is set for each output in its "Response at calibration" configuration point. ⇨...
  • Page 90 17 Calibrating universal inputs Two-point Calibration The zero point and slope of the measuring characteristic curve are determined with the aid of 2 measurings of 2 different reference solutions. Two test solutions with defined values of the respective measurand are needed as a references.

  • Page 91: Universal Inputs Calibration Default Settings

    17 Calibrating universal inputs 17.2.2 Universal inputs calibration default settings Which calibration default settings are available depends on the configuration settings of the universal input. Open the calibration default settings: Device menu > Calibration > Select Universal Input > Calibration default settings Calibration default settings for the individual operation modes •...
  • Page 92 17 Calibrating universal inputs • free chlorine, pH/Temp.-compensated In the universal inputs calibration default settings for the "free chlorine, pH/T- compensated" operation mode, the slope calibration is enabled and preconfig- ured as the only available calibration routine. Sample screen: Universal input calibra- tion default settings in "free chlorine, pH/T- compensated"...

  • Page 93: Universal Input Calibration Routines

    17 Calibrating universal inputs 17.3 Universal input calibration routines This chapter explains the universal inputs calibration routines for the "linear scal- ing" and "free chlorine, pH/T-compensated" operation modes. The explanations in the corresponding calibration chapters for the "pH value measurement" and "Conductivity measurement" operation modes apply, except that three-point calibration for pH sensors is not available for universal inputs (see Chapter 17.2.1 "Calibration methods for universal inputs", page 89).

  • Page 94: Zero Point/Slope Calibration (Linear Scaling)

    17 Calibrating universal inputs 17.3.1 Zero point/slope calibration (linear scaling) Step Action Start the desired Calibration routine. Device menu > Calibration > Select Universal Input > Zero-point calibration Clean the sensor and immerse it in the test solution. Wait until the measured value displayed stabilizes and then confirm the result of the measurement by pressing "OK".

  • Page 95: Two-Point Calibration (Linear Scaling)

    17 Calibrating universal inputs 17.3.2 Two-point calibration (linear scaling) Step Action Start the desired Calibration routine. Device menu > Calibration > Select Universal Input > Two-point calibration Clean the sensor and immerse it in the first test solution. Wait until the measuring value displayed stabiliz- es and then confirm the result of the measurement by pressing "OK".
  • Page 96 17 Calibrating universal inputs...

  • Page 97: Slope Calibration (Free Chlorine, Ph/Temp.-Compensated)

    17 Calibrating universal inputs 17.3.3 Slope calibration (free chlorine, pH/Temp.-compensated) Step Action Start the slope calibration. Device menu > Calibration > Select Universal Input > Slope Cali- bration Clean the sensor and immerse it in the test solution. Check the displayed values for the pH value and temperature.
  • Page 98 17 Calibrating universal inputs Step Action A protocol summarizing the calibration values determined then ap- pears. Acknowledge the protocol by pressing "OK". Failed calibrations are canceled at this point and discarded. Press "Yes" to accept the Calibration values determined and enter the Calibration in the Calibration logbook.

  • Page 99: Calibrating O-Do Sensors

    18 Calibrating O-DO sensors 18.1 Important information WARNING! During the calibration, the relays and analog output signals assume the states configured for the calibration! The response of the output signals is set for each output in its "Response at calibration" configuration point. ⇨...

  • Page 100: Calibration Methods For O-Do Sensors

    18 Calibrating O-DO sensors 18.2.1 Calibration methods for O-DO sensors End value calibration With end value calibration, the slope of the sensor is calibrated beyond the de- fined state of 100 % oxygen saturation. This state can in principle be achieved in two ways: •...
  • Page 101 Temperature input: The integrated temperature probe of the O-DO sensor supplies the compensation tempera- ture. Interface: The AQUIS touch S trans- mits the compensation temperature to the sensor electronics via the interface. The source of the compensation tem- perature is set in the configuration point "Compensation temperature".

  • Page 102: O-Do Calibration Routine

    18 Calibrating O-DO sensors 18.3 O-DO calibration routine NOTE! You must be logged in with corresponding user rights to perform calibrations. ⇨ Chapter 8.2.1 "Log-on/Log-out", page 91 NOTE! Digital sensors need to be linked before they can be calibrated? ⇨ Chapter 8.2.7 "Digital sensors", page 97 18.3.1 End value calibration...
  • Page 103 18 Calibrating O-DO sensors Step Action The device displays the current measured value of oxygen satura- tion and the test material temperature. The setpoint value for oxy- gen saturation of 100 %Sat is set automatically by the device. The user does not need to make any entries here. Wait until the measured value displayed stabilizes and then con- firm the result of the measurement by pressing "OK"...

  • Page 104: Two-Point Calibration

    18 Calibrating O-DO sensors 18.3.2 Two-point Calibration Step Action Start the two-point calibration. Device Menu > Calibration > Digital Sensor 1 to 6 > Two-Point Calibration To determine the zero point, prepare a water sulfite solution (sulfite concentration < 2 %). If temperature compensation was not specified in the calibration default settings, enter the temperature of the test materials used here manually.
  • Page 105 18 Calibrating O-DO sensors Step Action Immerse the sensor in air-saturated water or position it in water va- por-saturated air (see Chapter 18.2.1 "Calibration methods for O- DO sensors", page 100). If you use water vapor-saturated air, en- sure constant air pressure, constant temperature and that no water drops adhere to the membrane during the calibration procedure.
  • Page 106 18 Calibrating O-DO sensors...

  • Page 107: Calibrating Turbidity Sensors

    19 Calibrating turbidity sensors 19.1 Important information WARNING! During the calibration, the relays and analog output signals assume the states configured for the calibration! The response of the output signals is set for each output in its "Response at calibration" configuration point. ⇨...

  • Page 108: Calibration Presets For Turbidity Sensors

    19 Calibrating turbidity sensors 19.2.2 Calibration presets for turbidity sensors Before you can perform a calibration, you must first enter the necessary calibra- tion default settings. The possible settings for the calibration of turbidity sensors are described in the following. Open the calibration default settings: Device Menu >...

  • Page 109: Calibration Routines For Turbidity Sensors

    19 Calibrating turbidity sensors 19.3 Calibration routines for turbidity sensors NOTE! Turbidity sensors can be configured with automatic selection of the measuring range. Accordingly, calibrations must be performed for all "accessible measur- ing ranges". NOTE! You must be logged in with corresponding user rights to perform calibrations. ⇨...
  • Page 110 19 Calibrating turbidity sensors Step Action The device displays the current measured value of the formazine reference solution. Enter the actual turbidity value of the reference solution. Wait until the measured value displayed stabilizes and then con- firm the result of the measurement by pressing "OK" A protocol summarizing the calibration values determined then ap- pears.

  • Page 111: Technical Data

    20 Technical data 20.1 Analog inputs base unit 20.1.1 Temperature measurement input (IN 4) Probe-/Signal type Connection type Measuring Measuring accu- Ambient range racy temperature influence -200 to +850 °C ≤ 0.05 % of MR ≤ 50 ppm/K Pt100 DIN EN 60751 2-wire/3-wire -200 to +850 °C ≤...

  • Page 112: Temperature Measurement Input (In 5)

    20 Technical data 20.1.2 Temperature measurement input (IN 5) Probe-/Signal type Connection type Measuring Measuring accu- Ambient range racy temperature influence -200 to +850 °C ≤ 0.05 % of MR ≤ 50 ppm/K Pt100 DIN EN 60751 2-wire/3-wire -200 to +850 °C ≤ 0.1 % of MR ≤...

  • Page 113: Analog Inputs Optional Boards

    20 Technical data 20.2 Analog inputs optional boards 20.2.1 Universal input (IN 11, IN 12) Probe-/Signal type Connection type Measuring Measuring accu- Ambient range racy temperature influence -200 to +850 °C ≤ 0.05 % of MR ≤ 50 ppm/K Pt100 DIN EN 60751 2-wire/3-wire -200 to +850 °C ≤...

  • Page 114: Analysis Input: Cr (Resistive Conductivity)

    20 Technical data 20.2.3 Analysis input: CR (resistive conductivity) Units µs/cm ms/cm kΩ × cm MΩ × cm Display ranges 0.0000 to 9.9999 00.000 to 99.999 000.00 to 999.99 0000.0 to 9999.9 00000 to 99999 Temperature compensation TC-linear, natural water DIN EN 27888, natural water with expanded range, ASTM D-1125-95 for neutral (NaCl), acid (HCl) and alkali (NaOH) impurities...

  • Page 115: Analysis Input: Ci (Conductivity, Inductive)

    20 Technical data 20.2.4 Analysis input: Ci (conductivity, inductive) Units µs/cm ms/cm Measuring/display ranges 0.0000 to 9.9999 00.000 to 99.999 000.00 to 999.99 0000.0 to 9999.9 00000 to 99999 Temperature compensation TC linear TC curve natural water natural water with expanded temperature range NaOH 0 to 12% NaOH 25 to 50% 0 to 25 %...

  • Page 116: Temperature Compensations

    20 Technical data 20.2.5 Temperature compensations Compensation type Compensation range TC linear -50 to +250 °C TC curve -50 to +250 °C -50 to +250 °C natural water according to DIN EN 27888 0 to 36 °C natural water with 0 to 100 °C expanded temperature range ASTM D-1125-95 (neutral, alkaline, and...

  • Page 117: Measuring Circuit Monitoring, Optional Boards

    20 Technical data 20.2.6 Measuring circuit monitoring, optional boards Input/Sensor Underrange / Short circuit/ open circuit Special fea- overrange sensor break tures pH-value (glass elec- Configurable Configurable trode) Impedance mea- Impedance mea- surement surement pH-value (ISFET) Resistive conductivity Configurable Only with 4-wire circuit Inductive conductivity Universal input for con-...

  • Page 118: Analog Outputs Of Base Unit And Optional Boards

    Configuration. Sensors and transmitters should be supplied from voltage supply outputs on the JUMO AQUIS touch S. An externally supplied voltage signal must not have a voltage over 28 V. All digital inputs IN 1 to 3 are suitable for connecting proximity switches. Recommended types are: Wachendorff P2C2B1208NO3A2 and Balluff BES M12EG-PSC80F-BP03.

  • Page 119: Digital Outputs, Optional Boards

    20 Technical data 20.7 Digital outputs, optional boards Optional card Switching out- Ampacity at re- Contact life Special features sistive load Relay output, dual nor- 2 normally open 3 A at AC 250 V 150,000 mally open contacts contacts switching cycles Relay output, single 1 changeover Changeover contact...

  • Page 120: Voltage Supply Outputs, Power Supply Unit Board

    20 Technical data 20.9 Voltage supply outputs, power supply unit board Description Output voltage Total ampaci- Connection PWR OUT AC 110 to 240 V +10/-15%; Spring-cage ter- 48 to 63 Hz or minals AC/DC 20 to 30 V; 48 to 63 Hz The sum total of the output currents for the two PWR OUT connections must not exceed the total ampacity.

  • Page 121: Interfaces

    = 9600 baud and more than 2 digital sensors on the bus Baud rates above 9600 are supported only by JUMO tecLine sensors and JUMO sensors with JUMO digiLine electronics. JUMO ecoLine sensors support only a baud rate of 9600.

  • Page 122: Ethernet Optional Board (10/100Base-T)

    Modbus TCP/IP enables Modbus users to communicate via a LAN, provided this is connected to the LAN (e.g. via gateways). To configure Modbus communication you will require the interface description for the JUMO AQUIS touch S. Enlist the help of your network administrator or an IT specialist for the IP-configuration.

  • Page 123: Usb Interfaces Base Unit

    Type A Read/write device settings, Save service data Update the firmware USB device interface Device setting via PC JUMO PC setup USB port setup program, program, Type Mini-B Extract, archive, evalu- JUMO PCC/PCA 3000 measurement data software Use requires the USB host socket (see Chapter 4.2 "Order Details", page 17, Extra Code 269).

  • Page 124: Electrical Data

    20 Technical data 20.12 Electrical data Voltage supply (switch-mode) AC 110 to 240 V +10/-15%; 48 to 63 Hz or AC/DC 20 to 30 V; 48 to 63 Hz electrical safety According to EN 61010, part 1 overvoltage category III, pollution degree 2 Max.

  • Page 125: Housing

    20 Technical data 20.14 Housing geographic height for operation maximum 2000 m above sea level Case type Surface-mounted case made of plastic (ABS) for indoor use only Materials Terminal compartment cover screws: 1.4567 stainless steel Mounting plate: 1.4301 stainless steel Dimensions 301.5 mm ×...

  • Page 126: Functions

    History function Archiving/evaluation Yes (via JUMO PCA3000 evalu- ation software) A freely configurable set of input variables can be pooled in one group. Each group has its own display screen. The group affiliation is considered for data storage to enable eval- uation via PC.
  • Page 127 20 Technical data The history function allows the user to scroll the diagram back in the recording time period. All measured data stored in the ring buffer can thus be viewed on the device.

  • Page 128: Customized Linearization

    20 Technical data 20.15.3 Customized linearization Number of grid points up to 40 value pairs Interpolation Linear Formula entry 4th degree polynominal Durch die Eingabe von Stützstellen (Wertepaare der kundensp. Kennlinie) kann eine genäherte Kennlinie eingegeben werden. Linear interpolation means forming a slope function from 2 grid points.

  • Page 129: Annex

    21 Annex 21.1 Troubleshooting and remedies for digital sensors 21.1.1 Possible faults on sensors with JUMO digiLine electronics Fault symptom Possible cause Remedy A sensor is not detected af- The serial interface of the device Check the following serial inter-...
  • Page 130 21 Annex Fault symptom Possible cause Remedy Sensors are not linked The JUMO AQUIS touch S cannot Follow the instructions in the oper- unambiguously assign the sen- ating manual for startup of digital sors to specific inputs for digital sensors.
  • Page 131 Poor contact in the bus cabling Check for reliable contact at all sors malfunction sporadical- plug connectors and terminals in the JUMO AQUIS touch S. In- spect the cabling for damage. (bus status appears as "Yel- The occurrence and clearing of low"...

  • Page 132: Possible Faults On Digital Jumo Ecoline And Tecline Sensors

    21 Annex 21.1.2 Possible faults on digital JUMO ecoLine and tecLine sensors Fault symptom Possible cause Remedy A sensor is not detected af- The serial interface of the device Check the following serial inter- ter being connected and is concerned is configured incorrect-...
  • Page 133 JUMO DSM linking (cf. Chapter "Sub- software. Then, the sensor must menu for linking", page 99). be put into operation at the JUMO AQUIS touch S (initial startup). Base addresses • JUMO ecoLine O-DO (Type 202613): 10 •...
  • Page 134 21 Annex Fault symptom Possible cause Remedy All sensors connected to the The bus voltage supply has failed. Diagnose the failure of the voltage bus simultaneously mal- supply with a multimeter and re- function continuously. place the faulty voltage source or correct the short-circuit in the volt- ("Bus fault"...

  • Page 135: Planning The Cabling For Digital Sensors

    JUMO digiLine hub is used, the slide switch on the JUMO digiLine hub must be set to the position for DC 5 V as the input voltage. With the switch in this posi- tion, the input voltage of DC 5 V is fed through to the outputs of the JUMO dig- iLine hub.
  • Page 136 (cf. Chapter 21.2.4 "Voltage drop calculation", page 142). Stub line from a JUMO digiLine hub or Y-distributor up to a sensor with JUMO digiLine electronics...
  • Page 137 The use of numerous terminating resistors in a bus, however, can severely disrupt the signal. Sensor type Maximum length per branch Max. number of con- Comment nectable sensors JUMO digiLine pH/ 50 m Bus termination ORP/T is not permissi- JUMO ecoLine O-DO 50 m...

  • Page 138: Voltage Supply To The Bus With Dc 5 V From A Jumo Digiline Hub

    JUMO digiLine hub. In this case, the JUMO digiLine hub must be supplied with DC 24 V. The slide switch on the JUMO digiLine hub must be set to the position for DC 24 V as the input voltage. The electronics of the JUMO digiLine hub gen- erate the bus supply voltage of DC 5 V internally and supply its outputs with this voltage.
  • Page 139 Sensor type Maximum length per branch Max. number of con- Bus termination nectable sensors is not permissi- JUMO digiLine pH/ 50 m ORP/T JUMO ecoLine O-DO 50 m Bus termination JUMO ecoLine NTU...

  • Page 140: Voltage Supply To The Bus With Dc 24 V

    (cf. Chapter 21.2.4 "Voltage drop calculation", page 142). Stub line from a JUMO digiLine hub or Y-distributor up to a sensor with JUMO digiLine electronics...
  • Page 141 The use of numerous terminating resistors in a bus, however, can severely disrupt the signal. Sensor type Maximum length per branch Max. number of con- Comment nectable sensors digital JUMO ecoLine 50 m Bus termination sensors is not permissi- (Types 20263x)

  • Page 142: Voltage Drop Calculation

    21.2.4 Voltage drop calculation In the case of a JUMO digiLine bus with line topology (Y-adapter or JUMO dig- iLine hub with 5.3 V through a separate power supply unit) there is inevitably a voltage drop between the supply voltage feed-in and each sensor. The amount of the voltage drop depends on the sensor type, the number of sensors, the length of the bus, and the distribution of the sensors on the bus.
  • Page 143 The required minimum voltage of the sensors is shown in the following table. Sensor Minimum voltage JUMO digiLine pH/ORP/T 4.2 V JUMO ecoLine O-DO JUMO ecoLine NTU The voltage at sensor 1 (JUMO digiLine pH) is well above the minimum value...
  • Page 144 For the operation of JUMO ecoLine sensors, it is generally recommended to use JUMO digiLine hubs and to generate the DC 5.3 ‫ټ‬ V supply voltage within the JUMO digiLine hub. NOTE! The voltage drop calculation shown here does not apply for the use of JUMO tecLine sensors (types 20263x).

  • Page 145: China

    21 Annex 21.3 China...
  • Page 146 21 Annex...
  • Page 150 JUMO GmbH & Co. KG JUMO Instrument Co. Ltd. JUMO Process Control, Inc. Street address: JUMO House 6733 Myers Road Moritz-Juchheim-Straße 1 Temple Bank, Riverway East Syracuse, NY 13057, USA 36039 Fulda, Germany Harlow, Essex CM 20 2DY, UK Phone:...

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