Percent dissociation, Percent ammonia, Nitriding potential – Super Systems Hydrogen Nitrider Analyzer User Manual

Basic Nitriding Sampling System – Hydrogen Analyzer

Super Systems Inc.

Page 6 of 12

Percent Dissociation

Dissociation is derived from the amount of Hydrogen in the sample gas.

Percent Ammonia

The amount of Ammonia can also be inferred from the Hydrogen value.

Nitriding Potential

The accurate calculation of Nitriding Potential (K

N

) requires the flow rates of other gases that are being

introduced into the process. These flow rates are measured in SCFH (Standard Cubic Feet per Hour). K

N

can only be calculated by entering the flow of Nitrogen (N

2

), Ammonia (NH

3

) and % Dissociated Ammonia

(%DA). These values are entered at the bottom of the main screen when K

N

is selected.

Output Configuration

There are two 4-20mA outputs that can be configured for any of the four parameters. For each input, the

operator can select the Source (H

2

, DA, NH

3

, K

N

), the zero value (the value to be represented by 4mA) and

the span value (the value to be represented by 20mA).

•

Output 1 can be measured from Terminal #1121(+) and 1111 (-).

•

Output 2 can be measured from Terminal #1121(+) and 1131 (-).

Output Calibration

Accurate retransmission of the selected parameters can only be obtained through calibrating both of the

analog outputs. This is done at the factory prior to shipment, however it is a relatively simple procedure

that can be performed in the field if desired. To perform a calibration, a multimeter with a current input

is required. Please keep in mind that the accuracy of the instrument used to calibrate the outputs is

directly related to the accuracy of the outputs after calibration, so a meter calibrated against NIST

(National Institute of Standards and Technology) standards is preferred. Before performing any

calibrations, all other devices must be disconnected from the analog outputs. Multiple devices on the

outputs will cause inaccurate measurement of current.

Attach the leads of the multimeter to the terminals for Output 1. The positive lead should be attached to

Terminal #1121 and the negative lead to Terminal 1111. Select “Zero Output 1” and press the “Prep for

Cal” button. The low limit of the output is 4mA, so 4.000 is shown as the default measured value. Ideally

the meter connected to the outputs will also show 4.000. If the two values are not close enough to obtain

the desired level of accuracy, a calibration should be performed.

If, for example, the meter connected to the outputs reads 4.216mA, then the value “4.216” should be

entered on the screen as the Measured Value. Once the value has been entered, press the “calibrate”

button. This will offset the mA output of the instrument in an amount that results in an exact output of

4.000mA. When the calibration is complete, the multimeter should be reading 4.000mA (+/- .005).

The procedure can be repeated for the Span of Output 1. When “Span Output 1” is selected and “Prep for

Cal” is pressed, the instrument will output the high output limit, which is 20mA. The multimeter will

display the actual output from the instrument, and if it is not within the desired tolerance it can be

calibrated using the same procedure as above.

To calibrate Output 2, attach the leads of the multimeter to Terminal #1121 (+) and the negative lead to

Terminal 1131 (-) and follow the same procedure that was used for the first output.

Sensor Calibration

A proper calibration of the sensor requires two gases. The first gas should be pure Nitrogen or Argon.

This contains no Hydrogen, and is therefore referred to as the Zero Gas. The second gas is the Span Gas.

The Span Gas should ideally contain a quantity of Hydrogen similar to the amount of Hydrogen in the

process gas. The Span Gas should also include any other gases that are present in the process gas in