ABB AX413 User manual

Type
User manual

This manual is also suitable for

Single and Dual Input Analyzers
for Low Level Conductivity
AX410, AX411, AX413, AX416,
AX418, AX450, AX455 & AX456
User Guide
IM/AX4CO_9
ABB
The Company
We are an established world force in the design and manufacture of instrumentation for industrial
process control, flow measurement, gas and liquid analysis and environmental applications.
As a part of ABB, a world leader in process automation technology, we offer customers
application expertise, service and support worldwide.
We are committed to teamwork, high quality manufacturing, advanced technology and unrivalled
service and support.
The quality, accuracy and performance of the Company’s products result from over 100 years
experience, combined with a continuous program of innovative design and development to
incorporate the latest technology.
The UKAS Calibration Laboratory No. 0255 is just one of the ten flow calibration plants operated
by the Company, and is indicative of our dedication to quality and accuracy.
Health and Safety
To ensure that our products are safe and without risk to health, the following points must be noted:
1. The relevant sections of these instructions must be read carefully before proceeding.
2. Warning labels on containers and packages must be observed.
3. Installation, operation, maintenance and servicing must only be carried out by suitably trained personnel and in accordance with the
information given.
4. Normal safety precautions must be taken to avoid the possibility of an accident occurring when operating in conditions of high pressure and/
or temperature.
5. Chemicals must be stored away from heat, protected from temperature extremes and powders kept dry. Normal safe handling procedures
must be used.
6. When disposing of chemicals ensure that no two chemicals are mixed.
Safety advice concerning the use of the equipment described in this manual or any relevant hazard data sheets (where applicable) may be
obtained from the Company address on the back cover, together with servicing and spares information.
Electrical Safety
This equipment complies with the requirements of CEI/IEC 61010-1:2001-2 'Safety Requirements for Electrical Equipment for
Measurement, Control and Laboratory Use'. If the eqipment is used in a manner NOT specified by the Company, the protection
provided by the equipment may be impaired.
Symbols
One or more of the following symbols may appear on the equipment labelling:
Warning – Refer to the manual for instructions
Caution – Risk of electric shock
Protective earth (ground) terminal
Earth (ground) terminal
Direct current supply only
Alternating current supply only
Both direct and alternating current supply
The equipment is protected
through double insulation
Information in this manual is intended only to assist our customers in the efficient operation of our equipment. Use of this manual for
any other purpose is specifically prohibited and its contents are not to be reproduced in full or part without prior approval of the
Technical Publications Department.
BS EN ISO 9001:2000
Cert. No. Q05907
EN 29001 (ISO 9001)
Lenno, Italy – Cert. No. 9/90A
0255
Stonehouse, U.K.
1
CONTENTS
Section Page
1INTRODUCTION .............................................................. 2
1.1 System Description .................................................2
1.2 PID Control – AX410 and AX450 Analyzers Only ..... 2
1.3 AX400 Series Analyzer Options ............................... 2
2 OPERATION ..................................................................... 3
2.1 Powering Up the Analyzer ....................................... 3
2.2 Displays and Controls..............................................3
2.2.1 Membrane Key Functions ............................3
2.3 Operating Page ....................................................... 6
2.3.1 Single Input Conductivity..............................6
2.3.2 Dual Input Conductivity ................................7
3 OPERATOR VIEWS ......................................................... 9
3.1 View Set Points .......................................................9
3.2 View Outputs ........................................................ 10
3.3 View Hardware ...................................................... 11
3.4 View Software ....................................................... 12
3.5 View Logbook ....................................................... 13
3.6 View Clock ............................................................16
4 SETUP............................................................................ 17
4.1 Sensor Calibration .................................................17
5 PROGRAMMING ...........................................................19
5.1 Security Code ....................................................... 19
5.2 Configure Display ..................................................20
5.3 Configure Sensors.................................................21
5.4 Configure Alarms...................................................30
5.5 Configure Outputs ................................................. 34
5.6 Output Functions .................................................. 39
5.6.1 Bi-Linear Output ........................................39
5.6.2 Logarithmic Output (2-decade) .................. 39
5.6.3 Logarithmic Output (3-decade) .................. 40
5.7 Configure Clock ....................................................41
5.8 Configure Control ..................................................42
5.8.1 Configure Single PID Controller ..................43
5.8.2 Configure Power Failure Recovery Mode.... 46
5.9 Configure Security ................................................. 47
5.10 Configure Logbook ............................................... 47
5.11 Test Outputs and Maintenance ..............................48
Section Page
6INSTALLATION .............................................................. 50
6.1 Siting Requirements .............................................. 50
6.2 Mounting ...............................................................51
6.2.1 Wall-/Pipe-mount Analyzers .......................51
6.2.2 Panel-mount Analyzers ..............................52
6.3 Connections, General............................................53
6.3.1 Relay Contact Protection
and Interference Suppression..................... 54
6.3.2 Cable Entry Knockouts,
Wall-/Pipe-mount Analyzer .........................55
6.4 Wall-/Pipe-mount Analyzer Connections................ 56
6.4.1 Access to Terminals ...................................56
6.4.2 Connections ..............................................57
6.5 Panel-mount Analyzer Connections ....................... 58
6.5.1 Access to Terminals ...................................58
6.5.2 Connections ..............................................59
6.6 ABB Conductivity Sensor Systems Connections ... 60
7 CALIBRATION ...............................................................61
7.1 Equipment Required.............................................. 61
7.2 Preparation ........................................................... 61
7.3 Factory Settings ....................................................62
8SIMPLE FAULT FINDING .............................................. 68
8.1 Error Messages .....................................................68
8.2 No Response to Conductivity Changes .................68
8.3 Checking the Temperature Input............................ 69
SPECIFICATION .................................................................. 70
APPENDIX A ....................................................................... 73
A1 Automatic Temperature Compensation ................. 73
A1.1 Calculation of Temperature Coefficient ....... 74
A2 Relationship Between Conductivity and
Total Dissolved Solids (TDS) Measurement ............ 74
A3 Inferred pH Derived from
Differential Conductivity .........................................75
A3.1 Monitoring on Steam-Raising Plant ............ 75
A3.2 Monitoring on AVT Systems .......................76
A3.3 Monitoring on AVT Systems
with Impurities ............................................ 76
A3.4 Monitoring on Solid Alkaline
Treated Systems ........................................ 77
APPENDIX B ....................................................................... 78
B1 Single PID Controller ............................................. 78
B1.1 Reverse Acting Single PID Control .............78
B1.2 Direct Acting Single PID Control .................79
B2 Ouput Assignment ................................................ 79
B3 Setting Up Three Term (PID)
Control Parameters ...............................................80
B4 Manual Tuning .......................................................80
2
1 INTRODUCTION
Table 1.1 AX400 Series Analyzer Options
ledoMnoitpircseDrezylanAArosneSBrosneS
014XA000,01ot0(ytivitcudnoCedortcelE-2tupnIelgniS )mc/SytivitcudnoCedortcelE-2elbacilppAtoN
114XA000,01ot0(ytivitcudnoCedortcelE-2tupnIlauD )mc/SytivitcudnoCedortcelE-2ytivitcudnoCedortcelE-2
314XAytivitcudnoCedortcelE-4dnaytivitcudnoCedortcelE-2tupnIlauD ytivitcudnoCedortcelE-2ytivitcudnoCedortcelE-4
614XA)PRO(xodeR/HpdnaytivitcudnoCedortcelE-2tupnIlauD ytivitcudnoCedortcelE-2)PRO(xodeR/Hp
814XAnegyxOdevlossiDdnaytivitcudnoCedortcelE-2tupnIlauD ytivitcudnoCedortcelE-2negyxOdevlossiD
034XA)mc/Sm000,2ot0(ytivitcudnoCedortcelE-4tupnIelgniS ytivitcudnoCedortcelE-4elbacilppAtoN
334XA)mc/Sm000,2ot0(ytivitcudnoCedortcelE-4tupnIlauD ytivitcudnoCedortcelE-4ytivitcudnoCedortcelE-4
634XA)PRO(xodeR/HpdnaytivitcudnoCedortcelE-4tupnIlauD ytivitcudnoCedortcelE-4)PRO(xodeR/Hp
834XAnegyxOdevlossiDdnaytivitcudnoCedortcelE-4tupnIlauD ytivitcudnoCedortcelE-4negyxOdevlossiD
054XA)PSU(ytivitcudnoCedortcelE-2tupnIelgniS ytivitcudnoCedortcelE-2elbacilppAtoN
554XA)PSU(ytivitcudnoCedortcelE-2tupnIlauD ytivitcudnoCedortcelE-2ytivitcudnoCedortcelE-2
654XA)PRO(xodeR/Hpdna)PSU(ytivitcudnoCedortcelE-2tupnIlauD ytivitcudnoCedortcelE-2)PRO(xodeR/Hp
064XA)PRO(xodeR/HptupnIelgniS )PRO(xodeR/HpelbacilppAtoN
664XA)PRO(xodeR/HptupnIlauD )PRO(xodeR/Hp)PRO(xodeR/Hp
864XAnegyxOdevlossiDdna)PRO(xodeR/HptupnIlauD )PRO(xodeR/HpnegyxOdevlossiD
084XAnegyxOdevlossiDtupnIelgniS negyxOdevlossiDelbacilppAtoN
884XAnegyxOdevlossiDtupnIlauD negyxOdevlossiDnegyxOdevlossiD
1.1 System Description
The AX410 single input and AX411 dual input conductivity
analyzers have been designed for continuous monitoring and
control of low level conductivity.
The AX450 single input and AX455 dual input conductivity
analyzers have been designed to meet United States
Pharmacopeia (USP 645) requirements for continuous
monitoring and control of low level conductivity.
They are available in wall-/pipe-mount or panel-mount versions
and can be used with either one or two sensors, each with a
temperature input channel. When used with two sensors,
readings can be compared to produce a range of extrapolated
values.
When making temperature compensated measurements, the
sample temperature is sensed by a resistance thermometer
(Pt100 or Pt1000) mounted in the measuring cell.
Analyzer operation and programming are performed using five
tactile membrane keys on the front panel. Programmed
functions are protected from unauthorized alteration by a five-
digit security code.
1.2 PID Control – AX410 and AX450 Analyzers Only
The AX410 and AX450 single input conductivity analyzers
incorporate Proportional Integral Derivative (PID) control as
standard. For a full description of PID control, refer to
Appendix B.
1.3 AX400 Series Analyzer Options
Table 1.1 shows the range of configurations that are possible
for the AX400 Series analyzers. The analyzer detects the type
of input board fitted for each input automatically and displays
only the operating and programming frames applicable to that
input board type. If no input board is fitted for a second input
(Sensor B), Sensor B frames are not displayed.
3
Fig. 2.1 Location of Controls and Displays
Fig. 2.2 Membrane Key Functions
0.000
Dual Cond.
0.000
uS/cm
Alarm
LEDs
Display
Lines
Lower
Display Line
Membrane Keys
uS/cm
Units
Menu Key
Sidescroll Key
Downscroll Key
Up Key
Down Key
B – Advancing to Next Page
C – Moving Between Frames
D – Adjusting and Storing a Parameter Value
E – Selecting and Storing a Parameter Choice
A – Moving Between Menus
For majority
of Frames
Frame 1
Frame 2
Frame 3
Frame 4
Page 1
Frame 1
Frame 2
Frame 3
Page 2
Advance to
next page
or
Frame 1
Frame 2
Frame 3
Page X
Frame 4
Advance to
next Frame
New value is
stored automatically
Parameter Value
Adjust
Parameter X
Y
Z
Select
New value is
automatically stored
Menu 1
Menu 2
Advance to
next menu
2.2.1 Membrane Key Functions – Fig. 2.2
2 OPERATION
2.1 Powering Up the Analyzer
Warning. Ensure all connections are made
correctly, especially to the earth stud – see Section 6.3.
1) Ensure the input sensors are connected correctly.
2) Switch on the power supply to the analyzer. A start-up
screen is displayed while internal checks are performed,
then the conductivity measurement readings screen
(Operating Page) is displayed as conductivity measuring
operation starts.
2.2 Displays and Controls
The display comprises two rows of 4
1
/2 digit, 7-segment digital
displays, which show the actual values of the measured
parameters and alarm set points, and a 6-character dot matrix
display showing the associated units. The lower display line is a
16-character dot matrix display showing the programming
information.
4
…2 OPERATION
To CONFIG. OUTPUTS
(see Fig. 2.3B)
SECURITY CODE
Section 5.1, Page 19
CONFIG. DISPLAY
Set Language
Set Temp. Units Set Backlight
LED Backlight
Temp. UnitsEnglish
Section 5.2, Page 20
Available only if the option board is fitted and
analog features enabled – see Section 7.3
Key
Dual input analyzer only
Use the Sidescroll Key to scroll through the Pages within each Menu
VIEW SETPOINTS VIEW OUTPUTS VIEW HARDWARE VIEW SOFTWARE
A1: Setpoint Analog Output 1 Sensor A Module AX450/2000 Issue
A2: Setpoint Analog Output 2 Sensor B Module
A3: Setpoint
Analog Output 3 Option Board
A4: Setpoint Analog Output 4
A5: Setpoint
Use the Downscroll
Key to scroll through
the Farmes
within each Page
OPERATING PAGE
Section 2.3, Page 6 Section 3.1, Page 9 Section 3.2, Page 10 Section 3.3, Page 11 Section 3.4, Page 12 Section 3.5, Page 13 Section 3.6, Page 16
Alarms
Errors
Power
Cals
VIEW LOGBOOK VIEW CLOCK
Date 05:02:04
Time 12:00
Use the Menu Key
to scroll through
the Menus
CONFIG.ALARMS
Config. Alarm 1
A1: Type
A1: Assign
A1: Failsafe
A1: Action
A1: Setpoint
A1: Hysteresis
A1: Delay
Config. Alarm 2
A2: Type
A2: Assign
A2: Failsafe
A2: Action
A2: Setpoint
A2: Hysteresis
A2: Delay
A3: Assign
A3: Failsafe
A3: Action
A3: Setpoint
A3: Hysteresis
A3: Delay
Config. Alarm 3
A3: Type
Section 5.4, Page 30
Config. Alarm 4
A4: Type
A4: Assign
A4: Failsafe
A4: Action
A4: Setpoint
A4: Hysteresis
A4: Delay
Config. Alarm 5
A5: Type
A5: Assign
A5: Failsafe
A5: Action
A5: Setpoint
A5: Hysteresis
A5: Delay
CONFIG.SENSORS
B: Cond.Units
B: Cell Constant
B: Temp.Comp.
B: Temp. Sensor
B: TDS Factor
B: TDS Units
B: Enable Cals.
Section 5.3, Page 21
Config. Sensor B
Config. Sensor A
A: Cond.Units
A: Cell Constant
A: Temp. Sensor
A: TDS Factor
A: TDS Units
A: Enable Cals.
A: Temp.Comp.
A: Temp.Coeff. B: Temp.Coeff.
After Cat. Limit
Signal Calc
SENSOR CAL.
Cal. User Code
Section 4.1, Page 17
Sensor Cal. B
B: Calibration
B: Sensor Slope
B: Sensor Offset
B: Temp. Slope
B: Temp. Offset
B: Reset?
Sensor Cal. A
A: Calibration
A: Sensor Slope
A: Sensor Offset
A: Temp. Slope
A: Temp. Offset
A: Reset?
B: T.Comp. RangeA: T.Comp. Range
A1: USP Offset
A2:
USP Offset
A3:
USP Offset
A4: USP Offset A5: USP Offset
Fig. 2.3A Overall Programming Chart
5
2 OPERATION…
To
FACTORY SETTINGS
(see Section 7.3, Page 62)
CONFIG.LOGBOOK
Section 5.10, Page 47
Logbook
CONFIG.SECURITY Alter Sec.Code
Alter Cal.Code
Section 5.9, Page 47
CONFIG.CLOCK Set Clock?
Format dd/mm/yy
Date 01:01:02
Time 12:00
Press To AbortPress To Set
Section 5.7, Page 41
CONFIG.SERIAL
TEST/MAINTENANCE
Test Outputs
Test Output 1
Test Output 2
Maintenance
Hold Outputs
Test Output 3
Test Output 4
Section 5.11, Page 48
Load/Save Config
Factory Config.
User Config.
Press To AbortPress To Set
Use the Menu Key
to scroll through
the Menus
Use the Sidescroll Key to scroll through the Pages within each Menu
CONFIG. CONTROL Controller
Section 5.8, Page 42
PID Controller
Control Action
Prop. Band
Integral time
Derivative time
Output Type
Pulses/Minute
Cycle Time
Output Range
OR
OR
Power Recovery
Power Rec. Mode
Default Output
CONFIG.OUTPUTS Config. Output 1
AO1: Assign
AO1: Range
AO1: Span Value
AO1: Zero Value
AO1: Default O/P
AO1: Default Val
Config. Output 2
AO2: Assign
AO2: Range
AO2: Span Value
AO2: Zero Value
AO2: Default O/P
AO2: Default Val
Config. Output 3
AO3: Assign
AO3: Range
AO3: Span Value
AO3: Zero Value
AO3: Default O/P
AO3: Default Val
Section 5.5, Page 34
Config. Output 4
AO4: Assign
AO4: Range
AO4: Span Value
AO4: Zero Value
AO4: Default O/P
AO4: Default Val
AO1: Curve AO2: Curve AO3: Curve AO4: Curve
AO1: Set X Value
AO1: Set Y Value
AO2: Set X Value
AO2: Set Y Value
AO3: Set X Value
AO3: Set Y Value
AO4: Set X Value
AO4: Set Y Value
Displayed only if Option Board fitted
and
Serial Communications feature enabled (Section 7.3) –
see Supplementary Manual
PROFIBUS Datalink Description (IM/PROBUS)
Single input analyzer only
Available only if the option board is fitted and
analog features enabled – see Section 7.3
Key
Use the Downscroll
Key to scroll through
the Frames
within each Page
Automatic Time
Fig. 2.3B Overall Programming Chart
6
2.3 Operating Page
2.3.1 Single Input Conductivity
Measured Values
Conductivity.
Temperature.
Notes.
The displayed conductivity and temperature readings are the actual measured values
of the sample.
AX450 analyzers only – if
A: Cond.Units is set to USP645 (Section 5.3), the displayed
conductivity reading is the uncompensated conductivity value of the sample, i.e. its
value at the displayed temperature.
Control Mode
Conductivity value.
Control mode.
Use the
and keys to switch between manual (Manual) and automatic (Auto) control.
Note. Displayed only if
Controller is set to PID – see Section 5.7.
Control Output
Conductivity value.
Control output (%), manual (
Man) or automatic (Auto).
When
Control Mode is set to Manual (see above), use the and keys to adjust the
control output between 0 and 100%.
Note. Displayed only if Controller is set to PID – see Section 5.7.
Control Set Point
Conductivity value.
Control set point.
Use the
and keys to adjust the control set point between 0 and 250% conductivity.
Note. Displayed only if
Controller is set to PID – see Section 5.7.
Temperature Compensated Conductivity Value – AX450 Analyzers Only
Notes.
This frame is displayed only if
A: Cond.Units is set to USP645 – see Section 5.3.
The displayed reading is the temperature compensated conductivity value i.e. the
value it would be at a sample temperature of 25C (77F).
See Section 3.1.
Enable Cals. set to Yes (Section 5.3) – see Section 4.1.
Enable Cals. set to No (Section 5.3) and Alter Sec. Code not set to zero
(Section 5.9) – see Section 5.1.
Enable Cals. set to No (Section 5.3) and Alter Sec. Code set to zero
(Section 5.9) – see Section 5.2.
Conductivity
0.883
uS/cm
24.8
Deg.C
@ 25 Deg.C
0.886
uS/cm
VIEW SETPOINTS
SENSOR CAL.
CONFIG. DISPLAY
SECURITY CODE
Conductivity
Control Mode
uS/cm
Manual
0.883
----
Setpoint 90.0
uS/cm
% Man.
0.883
60.0
Control Setpoint
uS/cm
1.000
%Sat
150.0
…2 OPERATION
7
Measured Conductivity
Sensor A.
Sensor B.
Notes.
Dual Cond. is displayed only if Signal Calc. is set to No Calculation – see Section 5.3. See
below for an explanation of calculations.
The displayed conductivity readings are the actual values of the sample.
AX455 analyzers only – If
Cond.Units for a sensor is set to USP645 (Section 5.3), the
displayed conductivity reading for that sensor is the uncompensated conductivity
value of the sample, i.e. its value at its measured temperature (see below).
Temperature Compensated Conductivity – AX455 Analyzers Only
Sensor A.
Sensor B.
Notes.
This frame is displayed only if
Cond.Units for either or both sensors is set to USP645
see Section 5.3.
If
Cond.Units for a sensor is set to USP645 (Section 5.3), the displayed conductivity
reading for that sensor is the temperature compensated value, i.e. the value it would be
at a sample temperature of 25C (77F).
Measured Temperature
Sensor A.
Sensor B.
Note. The displayed temperature readings are the actual values of the sample.
See Section 3.1.
Enable Cals. set to Yes (Section 5.3) – see Section 4.1.
Enable Cals. set to No (Section 5.3) and Alter Sec. Code not set to zero
(Section 5.9) – see Section 5.1.
Enable Cals. set to No (Section 5.3) and Alter Sec. Code set to zero
(Section 5.9) – see Section 5.2.
Temperature
25.6
Deg.C
24.4
Deg.C
Dual Cond.
0.883
uS/cm
0.892
uS/cm
@ 25 Deg.C
0.886
uS/cm
0.895
uS/cm
VIEW SETPOINTS
SENSOR CAL.
SECURITY CODE
CONFIG. DISPLAY
Dual Cond.
…2.3 Operating Page
2.3.2 Dual Input Conductivity
2 OPERATION…
8
…2 OPERATION
…2.3 Operating Page
…2.3.2 Dual Input Conductivity
Calculations
A range of computed dual conductivity readings can be displayed, each showing the result of a calculation performed by the analyzer.
In each case, the type of calculation is shown on the lower display line, followed by the result of the calculation.
Calculations performed are:
Difference = A – B
% Rejection = (1–B/A) x 100
% Passage = B/A x 100
Ratio = A/B
Inferred pH = Uses an algorithm to calculate the pH value of the solution, inferred from its conductivity, in the range 7.00 to
11.00 pH. See Appendix A3 for further information on inferred pH.
Note. If the analyzer is used with a cation resin column, Sensor A must be installed before the column and Sensor B after
the column for the calculations, especially inferred pH, to be correct.
9
3 OPERATOR VIEWS
8.300
uS/cm
A1: Setpoint
Sen.A
Temp.A
VIEW SETPOINTS
-----
35.0
Deg.C
A2: Setpoint
Sen.B
3.500
uS/cm
A3: Setpoint
Temp.B
55.0
Deg.C
A4: Setpoint
-----
Off
A5: Setpoint
VIEW OUTPUTS
SENSOR CAL.
CONFIG. DISPLAY
SECURITY CODE
VIEW SETPOINTS
3.1 View Set Points
View Set Points
This page shows alarm set points. The value of each of the set points is shown, together
with the name of the parameter it's assigned to.
Alarm assignments, set point values and relay/LED actions are programmable – see
Section 5.4. Those shown in the following frames are examples only.
Sensor A (Conductivity), Alarm 1 Set Point
Sensor A (Temperature), Alarm 2 Set Point
Sensor B (Conductivity), Alarm 3 Set Point – Dual input analyzers only
Sensor B (Temperature), Alarm 4 Set Point – Dual input analyzers only
Note. Alarm 4 available only if option board fitted and analog features enabled – see
Section 7.3.
Alarm 5 Set Point
Note. Alarm 5 available only if option board fitted and analog features enabled – see
Section 7.3.
See Section 3.2.
Enable Cals. set to Yes (Section 5.3) – see Section 4.1.
Enable Cals. set to No (Section 5.3) and Alter Sec. Code not set to zero
(Section 5.9) – see Section 5.1.
Enable Cals. set to No (Section 5.3) and Alter Sec. Code set to zero
(Section 5.9) – see Section 5.2.
10
Theoretical Analog Output
There are up to four analog outputs, each showing information for one sensor.
Note. Analog outputs 3 and 4 available only if option board fitted and analog features
enabled – see Section 7.3.
Live current output value being retransmitted.
Current output shown as a percentage of full scale for the output range set in
CONFIG.
OUPUTS
– see Section 5.5.
See Section 3.3.
Enable Cals. set to Yes (Section 5.3) – see Section 4.1.
Enable Cals. set to No (Section 5.3) and Alter Sec. Code not set to zero
(Section 5.9) – see Section 5.1.
Enable Cals. set to No (Section 5.3) and Alter Sec. Code set to zero
(Section 5.9) – see Section 5.2.
Advance to analog output 2 (and outputs 3 and 4 if option board fitted and
analog features enabled – see Section 7.3).
50.0
%
Analog Output 1
12.00
mA
VIEW OUTPUTS
-----
VIEW HARDWARE
SENSOR CAL.
SECURITY CODE
CONFIG. DISPLAY
Analog Output 2
…3 OPERATOR VIEWS
3.2 View Outputs
11
Sensor A Module
Shows the type of input board fitted to the analyzer for the Sensor A input.
Cond. 2-Electrode Conductivity
Sensor B Module – Dual input analyzers only
Shows the type of input board fitted to the analyzer for the Sensor B input.
Option Board
Note. Displayed only if the option board is fitted.
Displays the optional features enabled in the Factory Settings page – see Section 7.3.
See Section 3.4.
Enable Cals. set to Yes (Section 5.3) – see Section 4.1.
Enable Cals. set to No (Section 5.3) and Alter Sec. Code not set to zero
(Section 5.9) – see Section 5.1.
Enable Cals. set to No (Section 5.3) and Alter Sec. Code set to zero
(Section 5.9) – see Section 5.2.
Cond.
Cond.
-----
Sensor A Module
VIEW HARDWARE
-----
Option Board
-----
Sensor B Module
-----
Pb DP
Analog
VIEW SOFTWARE
SENSOR CAL.
SECURITY CODE
CONFIG. DISPLAY
VIEW HARDWARE
3 OPERATOR VIEWS…
3.3 View Hardware
12
…3 OPERATOR VIEWS
0.01
AX450/2000 Issue
VIEW SOFTWARE
-----
VIEW LOGBOOK
SENSOR CAL.
SECURITY CODE
CONFIG. DISPLAY
VIEW SOFTWARE
Conductivity
Dual Cond.
Issue
Shows the version number of the software.
Option board fitted and analog features enabled (Section 7.3) and
Logbook set to On (Section 5.10) – see Section 3.5.
Operating Page (option board not fitted) – see Section 2.3
.
Enable Cals. set to Yes (Section 5.3) – see Section 4.1.
Enable Cals. set to No (Section 5.3) and Alter Sec. Code not set to zero
(Section 5.9) – see Section 5.1.
Enable Cals. set to No (Section 5.3) and Alter Sec. Code set to zero
(Section 5.9) – see Section 5.2.
3.4 View Software
13
3.5 View Logbook
Note. The View Logbook function is available only if the option board is fitted and analog features enabled (Section 7.3) and
Logbook is set to On (Section 5.10).
The logbook stores data entries for alarm events, sensor errors, power failures and sensor
calibrations.
View Logbook
Use the
and keys to access the Alarms logbook.
Note. If no entries are stored in the
Alarms logbook, the display shows No More Entries.
Alarms
The
Alarms logbook contains up to 10 entries (entry 1 is the most recent), each comprising
an alarm number, alarm state (On or Off), and the date/time of the occurrence.
Option board fitted and analog features enabled (Section 7.3) – see Section 3.6.
Enable Cals. set to Yes (Section 5.3) – see Section 4.1.
Enable Cals. set to No (Section 5.3) and Alter Sec. Code not set to zero
(Section 5.9) – see Section 5.1.
Enable Cals. set to No (Section 5.3) and Alter Sec. Code set to zero
(Section 5.9) – see Section 5.2.
Advance to entries 2 to 10.
Note. If no more entries are stored, the display shows
No More Entries.
3 OPERATOR VIEWS…
-----
05:02:04 09:54
VIEW LOGBOOK
-----
VIEW CLOCK
SENSOR CAL.
SECURITY CODE
CONFIG. DISPLAY
2 A1
-----
VIEW LOGBOOK
1
Cals
Power
Errors
Alarms
A1
On
14
…3 OPERATOR VIEWS
View Logbook
Use the
and keys to access the Errors logbook.
Note. If no entries are stored in the
Errors logbook, the display shows No More Entries.
Errors
The
Errors logbook contains up to 5 entries (entry 1 is the most recent), each comprising
the sensor letter, error number and the date/time of the occurrence.
Option board fitted and analog features enabled (Section 7.3) – see Section 3.6.
Enable Cals. set to Yes (Section 5.3) – see Section 4.1.
Enable Cals. set to No (Section 5.3) and Alter Sec. Code not set to zero
(Section 5.9) – see Section 5.1.
Enable Cals. set to No (Section 5.3) and Alter Sec. Code set to zero
(Section 5.9) – see Section 5.2.
Advance to entries 2 to 5.
Note. If no more entries are stored, the display shows
No More Entries.
View Logbook
Use the
and keys to access the Power logbook.
Note. If no entries are stored in the
Power logbook, the display shows No More Entries.
Power
The
Power logbook contains up to 2 entries (entry 1 is the most recent), each comprising
the power state (On or Off) and the date/time of the occurrence.
Option board fitted and analog features enabled (Section 7.3) – see Section 3.6.
Enable Cals. set to Yes (Section 5.3) – see Section 4.1.
Enable Cals. set to No (Section 5.3) and Alter Sec. Code not set to zero
(Section 5.9) – see Section 5.1.
Enable Cals. set to No (Section 5.3) and Alter Sec. Code set to zero
(Section 5.9) – see Section 5.2.
Advance to entry 2.
Note. If no more entries are stored, the display shows
No More Entries.
…3.5 Logbook
-----
-----
05:02:04 11:34
VIEW CLOCK
SENSOR CAL.
SECURITY CODE
CONFIG. DISPLAY
2 Sen.A
VIEW LOGBOOK
Errors
1
Sen.A
Pt100
Alarms
Cals
Power
Errors
-----
05:02:04 11:34
VIEW CLOCK
SENSOR CAL.
SECURITY CODE
CONFIG. DISPLAY
2
-----
VIEW LOGBOOK
1
Off
Errors
Alarms
Cals
Power
15
VIEW CLOCK
-----
Calibration
-----
VIEW LOGBOOK
1
Sen.A
05:02:04 11:14
SENSOR CAL.
SECURITY CODE
CONFIG. DISPLAY
2 Sen.A
0.969
Slope
0.016
Power
Errors
Alarms
Cals
User
uS/cm
…3.5 Logbook
View Logbook
Use the
and keys to access the Cals logbook.
Note. If no entries are stored in the Cals logbook, the display shows No More Entries.
Calibration
The
Cals logbook contains up to 5 entries (entry 1 is the most recent), each comprising 2
frames. Frame 1 contains the entry number and sensor letter and shows
User to indicate
a user performed calibration.
Frame 2 contains either the the sensor % slope and sensor offset values (for a conductivity
calibration), or the temperature % slope and temperature offset values (for a temperature
calibration), together with the date/time of the calibration.
Note. If no more entries are stored, the display shows
No More Entries.
Option board fitted and analog features enabled (Section 7.3) – see Section 3.6.
Enable Cals. set to Yes (Section 5.3) – see Section 4.1.
Enable Cals. set to No (Section 5.3) and Alter Sec. Code not set to zero
(Section 5.9) – see Section 5.1.
Enable Cals. set to No (Section 5.3) and Alter Sec. Code set to zero
(Section 5.9) – see Section 5.2.
Advance to entries 2 to 5.
Note. If no more entries are stored, the display shows
No More Entries.
3 OPERATOR VIEWS…
16
Date
Shows the current date.
Time
Shows the current time.
Operating Page – see Section 2.3.
Enable Cals. set to Yes (Section 5.3) – see Section 4.1.
Enable Cals. set to No (Section 5.3) and Alter Sec. Code not set to zero
(Section 5.9) – see Section 5.1.
Enable Cals. set to No (Section 5.3) and Alter Sec. Code set to zero
(Section 5.9) – see Section 5.2.
-----
Date 05:02:04
VIEW CLOCK
-----
-----
Time 12:00
Conductivity
SENSOR CAL.
SECURITY CODE
CONFIG. DISPLAY
VIEW CLOCK
Dual Cond.
…3 OPERATOR VIEWS
3.6 View Clock
Note. The View Clock function is available only if the option board is fitted and analog features enabled – see Section 7.3.
17
4 SETUP
Sensor Calibration
Note. Applicable only if
Enable Cals. is set to Yes – see Section 5.3.
Sensor Calibration Security Code
Note. This frame is displayed only if
Alter Cal. Code is not set to zero – see Section 5.9.
Enter the required code number (between 0000 and 19999) to gain access to the sensor
calibration pages. If an incorrect value is entered, access to the calibration pages is
prevented and the display reverts to the
SENSOR CAL. frame.
Calibrate Sensor A
Sensor B calibration (dual input analyzers only) is identical to Sensor A
calibration.
Single input analyzers only – return to main menu.
Alter Sec. Code not set to zero (Section 5.9) – see Section 5.1.
Alter Sec. Code set to zero (Section 5.9) – see Section 5.2.
Continued below.
Edit or Reset Calibration
Select Edit to manually adjust the Slope and Offset values of the process and temperature
sensors.
Select Reset to reset the sensor calibration data to the standard default settings:
Sensor and Temperature Slope = 1.000
Sensor and Temperature Offset = 0.0
Edit selected – continued on next page.
Reset selected – continued on next page.
4.1 Sensor Calibration
Notes.
Sensor calibration is not usually required as the cell constant 'K' assigned to a cell is sufficiently accurate for most
applications.
TB2 cells are equipped with 2-wire temperature compensators therefore temperature errors can be expected in
applications where the length of the connecting cable exceeds 10m. Carry out an in-situ temperature calibration to
remove these errors.
Sensor Cal. A
-----
SENSOR CAL.
-----
A: Calibration
-----
Cal. User Code
0000
A: Sensor Slope
A: Reset?
Edit
Reset
Reset
Edit
Sensor Cal. B
SECURITY CODE
CONFIG. DISPLAY
SENSOR CAL.
A: Calibration
18
…4 SETUP
…4.1 Sensor Calibration
Sensor Slope
Measured conductivity value.
Sensor slope value.
Use the
and keys to adjust the sensor slope value within the range 0.200 to 5.000
until the measured conductivity value is correct.
Sensor Offset
Measured conductivity value.
Sensor offset value.
Use the
and keys to adjust the sensor offset value within the range –20.00 to 20.00
until the measured conductivity value is correct.
Temperature Slope
Measured temperature value.
Temperature slope value.
Use the
and keys to adjust the temperature slope value within the range 0.200 to
1.500 until the measured temperature value is correct.
Temperature Offset
Measured temperature value.
Temperature offset value.
Use the
and keys to adjust the temperature offset value within the range –40.0 to
40.0C (–40.0 to 104.0F) until the measured temperature value is correct.
Sensor B calibration (dual input analyzers only) is identical to Sensor A
calibration.
Single input analyzers only – return to top of page.
Reset Calibration
Select
Yes and press to reset the calibration data.
Select
No and press to abort.
Return to top of page.
A: Sensor Slope
11.08
1.000
A: Sensor Offset
11.08
mS/cm
0.00
A: Temp. Slope
25.0
Deg.C
1.000
A: Temp. Offset
25.0
Deg.C
0.0
mS/cm
uS/cm
Deg.C
A: Reset?
-----
Yes
No
Sensor Cal. B
Sensor Cal. A
Sensor Cal. A
A: Calibration
set to
Edit
A: Calibration
set to
Reset
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ABB AX413 User manual

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