Section Calibration Ozone | Emerson Process Management 53eA instruction

MODEL 54eA	SECTION 12.0
	CALIBRATION - OZONE

SECTION 12.0

CALIBRATION - OZONE

12.1 INTRODUCTION

As Figure 12-1 shows, an ozone sensor generates a current directly proportional to the concentration of ozone in the sample. Calibrating the sensor requires exposing it to a solution containing no ozone (zero standard) and to a solution containing a known amount of ozone (full-scale standard).

The zero standard is necessary because ozone sensors, even when no ozone is in the sample, generate a small current called the residual current. The analyzer compensates for the residual current by subtracting it from the measured current before converting the result to an ozone value. New sensors require zeroing before being placed in service, and sensors should be zeroed whenever the electrolyte solution is replaced. Either of the fol- lowing makes a good zero standard:

•Deionized water.

•Tap water known to contain no ozone. Expose tap water to ozone-free air for several hours.

The purpose of the full-scale standard is to establish the slope of the calibration curve. Because stable ozone stan- dards do not exist, the sensor must be calibrated against a test run on a grab sample of the process liquid. Several manufacturers offer portable test kits for this purpose. Observe the following precautions when taking and testing the grab sample.

•Take the grab sample from a point as close to the sensor as possible. Be sure that taking the sample does not alter the flow of the sample to the sensor. It is best to install the sample tap just downstream from the sensor.

•Ozone solutions are unstable. Run the test immediately after taking the sample. Try to calibrate the sensor when the ozone concentration is at the upper end of the normal operating range.

FIGURE 12-1. Sensor Current as a Function of Ozone Concentration

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Emerson Process Management 53eA Section Calibration Ozone, Sensor Current as a Function of Ozone Concentration

Contents

Model 54eA Amperometric Hart Analyzer/Controller Essential Instructions Page Model 54eA ANALYZER/CONTROLLER 10.0 11.012.0 13.0 Section Title List of FiguresIii Section Specifications Features and Applications Specifications General PowerOutput Accuracy ± 0.05 mA Alarms Weight/Shipping Weight 5 lb/6 lb 2 kg/2.5 kg Specifications Oxygen Specifications Free ChlorineSpecifications Total Chlorine Specifications Ozone Ordering Information 115/230 VAC, 50/60 Hz Power24 VDC Installation Section InstallationUnpacking and Inspection Pipe and Wall Mounting Dimensions Pipe mounting Panel Mounting Dimensions Panel mounting POWER, ALARM, and Output Wiring Section WiringGeneral 454EPH02 Wiring Model 499A oxygen, chlorine, and ozone sensors Sensor WiringGeneral 4054eA01 4054eA03 4054eA02 4054eA04 4054eA07 Alarm Status Section Display and OperationGeneral Description Display Section Software Configuration Program Settings List Choices Factory Settings Configure Choices Factory Settings Temperature compensation Section Menu Tree for the 54eA Controller Main Menu Main Alarm setpoints Alarm 2 setpoint MA 0.00 ppm 20 mA 20.00 ppm Output 1 12.00 mA Ranging the Outputs Alarm setpoints Output setpointsSimulated test Setpoint 1.000 ppm 4mA 0.000 ppm 20mA 10.00 ppm Simulated tests Test alarm 1 OpenTest output Configure Display Temp units C Output 1 mA Output 2 mA Display contrast Timeout OnLanguage English Display left Display right Out Output 1 control OutputsOutput Measurement Ctrl mode Normal Output 1 SetupOutput 1 Control Range 4-20 mA Dampen 0 sec Hold Last Value Hold setup Using hold Changing Alarm Parameters Always configure the control parameters Before makingChanges in the alarm setup Alarm Control Settings Alarm 1 control Alarm 1 setupAlarm 2 control Alarm Low Setpoint 0.000 ppm Low Alarm High Alarm Alarm Fault Feed limit DisableTimeout 3600 sec Feed limit timer setup Alarm 4 setup Feed limit timer Interval timerTimer Disable Timer Time activated Interval 24.0 hr Interval timer setup PH sensor Enable PH sensor DisableUsing the 499ACL-01 sensor PH comp Manual PH value 7.00 pH Glass imp lo 20 MΩ Diagnostics OffAutocal Standard Temp coeff Operate iso 7.00 pH Sensor iso 7.00 pH Temperature Compensation and Temperature Units Temp comp AutoTemp units C Temp comp Manual Temp units C 60 Hz Noise Reduction Main sensor cal Bar units mm Hg Bar meas AutoBarometric Pressure Lock program Lock config Noise rejection Main sensor calSecurity Lock all Condition Definitions Controller Mode PriorityAction Definitions Section Calibration Temperature Introduction Adjust temp + 025.1 C Temperature Calibration Section Calibration Dissolved Oxygen Dissolved Oxygen Concentration Sensor must be in zero solution Zeroing the Sensor Stabilizing . . . Wait Calibrating the Sensor in AIR Section Calibrate 8.32 ppm Calibrating the Sensor Against a Standard Instrument Zero main sensor Adjust temperature Calibrate main sensorStandardize Calibrating Barometric Pressure Section Calibration Free Chlorine 499ACL-01 Sensor Current as a Function of Free Chlorine Concentration Calibrate main sensor Calibrate 1.100 ppm Full Scale Calibration Dual range cal Output trimCalibrate low point Dual Slope Calibration Low point 2.000 ppm Calibrate high point Section Calibration Free Chlorine 498CL-01 Introduction Ppm 100ppm 000 ppm Section Calibration Free Chlorine 498CL-01 Section Calibration Total Chlorine This page intentionally left blank Section Calibration Monochloramine Sensor Current as a Function of Monochloramine Concentration Ppm 100ppm Section Calibration Ozone Sensor Current as a Function of Ozone Concentration Ppm 100ppm Section PH at 25C Standards Nominal pH Autocal buffer Automatic TWO-POINT Calibration 10.02 pH Pt 04.00pH 25C Calibrate pointManual TWO-POINT Calibration 10.01 pH Pt 4.00pH 25.0C Standardization ONE-POINT Calibration Pt calibration Standardize pH pH slope PH slope 60.00 mV/pH Section Calibration Current Outputs Trimming the Outputs Section PID and TPC Control PID Control Code Control Loop Adjustment and Tuning Proportional Gain Plus Integral ResetProcess Reaction Curve Method Process Reaction Curve Section Time Proportional Control TPC Mode Code Section Troubleshooting Troubleshooting When a Fault Message is ShowingFault message Explanation See Section Overview Temperature error low or high High input currentCheck sensor zero PH low or high input voltage Troubleshooting When no Fault Message is Showing Oxygen Problem See SectionSense line open Failure factory and Failure eeprom Zero current is too high Possible error warning during in-process calibrationZero reading Is unstable Barometric pressure reading is too high or too low Process readings are erraticReadings drift Sensor does not respond to changes in oxygen level Problem Zero current is unstable Sensor can be calibrated, but the current is too low Sensor does not respond to changes in chlorine level Chlorine readings are too low Problem See Section Sensor does not respond to changes in monochloramine level Readings are too low Troubleshooting When no Fault Message is Showing Ozone Sensor does not respond to changes in ozone level Ozone readings are too low Troubleshooting When no Fault Message is Showing pH Sensor does not respond to known pH changes Controller will not accept manual slope100 Process pH readings are noisy 101 Troubleshooting not Related to Measurement Problems Problem ActionSimulating Inputs Dissolved Oxygen Sensor Polarizing Voltage Resistance Expected current Simulating Inputs Other Amperometric Measurements Simulate Chlorine and Ozone 103 Voltage mV PH at 25C Simulating pH input when the preamplifier is in the sensor104 Simulating temperature Simulating Temperature105 Measuring Reference Voltage 106 Section Maintenance Replacement Parts Part Number Description Section Return of Material General Warranty Specifications subject to change without notice