DX-Series FTIR Gas Analyser - Geotech Environmental...DX-Series FTIR Gas Analyser On-site Series...

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DX-Series FTIR Gas Analyser On-site Series Instruction and Operating Manual For the Gasmet DX4000 and Gasmet DX4015 models Version E1.14 (May 28, 2015)

Transcript of DX-Series FTIR Gas Analyser - Geotech Environmental...DX-Series FTIR Gas Analyser On-site Series...

Page 1: DX-Series FTIR Gas Analyser - Geotech Environmental...DX-Series FTIR Gas Analyser On-site Series Instruction and Operating Manual For the Gasmet DX4000 and Gasmet DX4015 models Version

DX-Series FTIR Gas Analyser

On-site Series

Instruction and Operating Manual

For the

Gasmet DX4000 and Gasmet DX4015 models

Version E1.14 (May 28, 2015)

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WARRANTY STATEMENT This warranty applies to the Gasmet brand name products sold with this warranty statement. This warranty is applicable in all countries and may be enforced in any country where Gasmet Technologies Oy or its subsidiaries or its authorised service providers offer warranty service subject to the terms and conditions set forth in this warranty statement. Gasmet Technologies Oy and its subsidiaries guarantee that all products manufactured and sold by it are free of defects in materials and workmanship under normal use during the warranty period. The products of Gasmet Technologies Oy and its subsidiaries are manufactured using new materials or new and used materials equivalent to new in performance and reliability. Spare parts may be new or equivalent to new. Gasmet Technologies Oy and its subsidiaries agree to either replace or repair free of charge (Ex Works Helsinki, Incoterms 2000) any such defective product or part that is returned to its repair facility within one (1) year of the delivery date. All parts or products removed under this warranty become the property of Gasmet Technologies Oy or its subsidiaries. The replacement product or part takes on the warranty status of the removed product or part. The warranty does not extend to any product from which the serial number has been removed or that has been damaged or rendered defective (a) as a result of accident, misuse, abuse, normal wear of components or other external causes; (b) by operation outside the usage parameters stated in the user documentation that is provided with the product; (c) by the use of parts not manufactured by Gasmet Technologies Oy and its subsidiaries; or (d) by modification or service by anyone other than Gasmet Technologies Oy and its subsidiaries. Gasmet Technologies Oy and its subsidiaries are not liable for any damages caused by the product or the failure of the product to perform, including any loss of profits or savings, incidental damages, or consequential damages. Gasmet Technologies Oy shall not be liable for technical or editorial errors or omissions contained herein. The information in this document is provided “as is” without guarantee of any kind and is subject to change without notice. Should you find any errors, we would appreciate if you notified us. Gasmet™, Calcmet™, Calcmet Lite™, and GICCOR™ are trademarks of Gasmet Technologies Oy. Windows® is a registered trademark of Microsoft Corporation. Teflon® is a registered trademark of E.I. du Pont de Nemours & Co., Inc. Viton® and Kalrez® are registered trademarks of DuPont Dow Elastomers. Bluetooth® is a registered trademark of Bluetooth SIG, Inc.

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CONTENTS

WARRANTY STATEMENT ........................................................................................................ 2

CONTENTS ................................................................................................................................... 3

FIGURES ....................................................................................................................................... 5

TABLES ......................................................................................................................................... 6

PREFACE ...................................................................................................................................... 7

INTRODUCTION ......................................................................................................................... 8

PRINCIPLE OF MEASUREMENT ........................................................................................... 9

1.1 PRINCIPLES OF INFRARED SPECTROSCOPY ....................................................................... 9 1.2 COMPONENTS OF A FOURIER TRANSFORM INFRARED SPECTROMETER ......................... 11 1.3 QUANTITATIVE ANALYSIS OF FTIR SPECTRA .................................................................. 13 1.4 MULTI-COMPONENT ANALYSIS.......................................................................................... 15 1.5 THE SPECTRAL RESOLUTION OF FTIR ANALYSIS ........................................................... 16

3 GASMET DX-SERIES FTIR GAS ANALYSER ................................................................. 17

3.1 INTRODUCTION ..................................................................................................................... 17 3.1.1 Applications of the Gasmet DX-Series Analyser ................................................ 18 3.1.3 Structure of the Gasmet DX-Series Analyser ..................................................... 18

3.2 GASMET DX-SERIES TECHNICAL DATA ............................................................................. 19 3.2.1 General Parameters ................................................................................................ 19 3.2.2 Spectrometer ............................................................................................................ 19 3.2.3 Sample Cell .............................................................................................................. 20 3.2.4 Measuring Parameters ........................................................................................... 20 3.2.5 Electrical Connectors .............................................................................................. 20 3.2.6 Gas Inlet and Outlet Conditions ............................................................................ 20 3.2.7 Computer and Electronics ...................................................................................... 21 3.2.8 Enclosure .................................................................................................................. 21

4 INSTALLATION ..................................................................................................................... 24

4.1 SUPPLY SCHEDULE ............................................................................................................. 24 4.1.1 Package .................................................................................................................... 24 4.1.2 Contents of the Gasmet Package ......................................................................... 24 4.1.3 Settings ..................................................................................................................... 24

4.2 AMBIENT CONDITIONS ......................................................................................................... 25 4.2.1 Storing and Transporting Gasmet ........................................................................ 25 4.2.2 Installation Location ................................................................................................ 25 4.2.3 Explosion Protection ............................................................................................... 25

4.3 SAMPLE GAS SUPPLY ......................................................................................................... 26 4.4 GAS FITTINGS ...................................................................................................................... 27 4.5 ON-BOARD SAMPLE PUMP (ONLY IN THE DX4015 MODEL) .............................................. 28 4.6 POWER CONNECTION .......................................................................................................... 28

4.6.1 Power Supply ........................................................................................................... 28 4.6.2 Fuses ......................................................................................................................... 28

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4.7 SIGNAL CONNECTIONS ........................................................................................................ 28 4.7.1 Optional Analogue Output Signals ....................................................................... 29 4.7.2 RS232 Interface ....................................................................................................... 29

5 START-UP ................................................................................................................................ 30

5.1 CONNECTIONS ..................................................................................................................... 30 5.2 INSTALLING SOFTWARE ...................................................................................................... 30

5.2.1 Installing Calibration Files ...................................................................................... 31 5.2.2 Installing Optional Expansion Cards .................................................................... 31 5.2.3 HASP Licensies and Keyes ................................................................................... 32 5.2.4 Uninstalling Calcmet Software .............................................................................. 32

5.3 SWITCHING THE ANALYSER'S POWER ON .......................................................................... 33 5.4 OPERATION .......................................................................................................................... 33

5.4.1 Using the Calcmet Software .................................................................................. 33 5.4.2 Setting the Measurement Times ........................................................................... 35 5.4.3 Zero Calibration ....................................................................................................... 36 5.4.4 Measuring the Sample Spectrum ......................................................................... 38 5.4.5 Checking the Hardware .......................................................................................... 39 5.4.6 Analyzing the Sample Spectrum ........................................................................... 39

5.5 SAMPLE CALCMET SESSION ............................................................................................... 39 5.4.1 Step 1: Select the Components That Will Be Analyzed .................................... 40 5.4.2 Step 2: Measure the Background ......................................................................... 40 5.4.3 Step 3: Measure and Analyze the Sample .......................................................... 40 5.4.4 Step 4: Verify the Results ...................................................................................... 40

6 MAINTENANCE ..................................................................................................................... 42

6.1 SAFETY PRECAUTIONS ........................................................................................................ 42 6.2 MAINTENANCE PLAN ........................................................................................................... 42 6.3 VISUAL INSPECTION............................................................................................................. 43 6.4 SAMPLE CELL INSPECTION ................................................................................................. 43 6.5 REPLACEMENT OF OPTOELECTRONIC COMPONENTS ........................................................ 44

7 ANALYSER INSPECTION .................................................................................................... 45

7.1 GASMET FTIR GAS ANALYSER INSPECTION SHEET ......................................................... 46

APPENDIX A: VOCABULARY ................................................................................................ 47

APPENDIX B: GASMET SALES AND SUPPORT OFFICES ............................................ 48

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FIGURES Figure 1. The four normal modes of vibration of carbon dioxide CO2 molecule. ............ 10 Figure 2. An absorbance spectrum of carbon dioxide CO2 measured with a DX4015

model. c(CO2) = 50 ppm, T = 50 oC, absorption path length = 9.8 m. ........................ 11 Figure 3. The basic components of an FTIR spectrometer are infrared source,

interferometer, sample cell, detector, and signal and data processing unit. .............. 11 Figure 4. A Michelson interferometer is a unique part of an FTIR spectrometer. ........... 12 Figure 5. A typical interferogram. ............................................................................................ 13 Figure 6. An example of spectra for multi-component analysis. The spectral analysis

routine in Calcmet software performs all calculations automatically. .......................... 15 Figure 7. Basic structure of the Gasmet DX-Series analysers. ......................................... 19 Figure 8. Dimensional drawing of the DX4000 analyser enclosure. ................................. 22 Figure 9. Dimensional drawing of the DX4015 analyser enclosure. ................................. 23 Figure 10. Sample gas fittings of the DX4000 (upper) and DX4015 (lower) models. .... 27 Figure 11. Gasmet DX-Series connector unit. ...................................................................... 29 Figure 12. 'Welcome to Calcmet' dialogue. ........................................................................... 34 Figure 13. 'Options / Measuring Times' dialogue. ................................................................ 35 Figure 14. A typical background spectrum. ........................................................................... 37

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TABLES Table 1. ‘Welcome to Calcmet – Analyzer’ parameters. ..................................................... 34 Table 2. Commands for setting measuring times. ................................................................ 36 Table 3. Zero calibration measurement commands............................................................. 37 Table 4. Single measurement commands. ............................................................................ 38 Table 5. Continuous measurement commands. ................................................................... 39 Table 6. Commands for checking hardware status. ............................................................. 39 Table 7. Maintenance plan. ...................................................................................................... 43

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PREFACE Thank you for choosing Gasmet, the state-of-the-art FTIR gas analyser manufactured by Gasmet Technologies Oy. Gasmet is a high-technology product made of high quality components. The substantial investment of Gasmet Technologies Oy in R & D is targeted at innovative, customer-driven solutions. Working closely with customers and global distribution network, the company offers extensive technical applications support services. Along with high reliability, the products of Gasmet Technologies Oy offer easy operation and consistent and accurate results, together with competitive pricing. The development of the powerful technology of FTIR has required uncompromising commitment and expertise in several fields of high technology. As a result, the products of Gasmet Technologies Oy are not only superior in performance, but also simple to operate and maintain. The continuing philosophy of Gasmet Technologies Oy is to provide reliable measurements in a variety of industrial applications now and in the future. Wherever you are and whatever your applications are, we hope you will find the Gasmet gas analyser and its appliances fast, accurate, reliable, and easy to use.

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INTRODUCTION This instructions manual provides information of the Gasmet DX-Series Fourier transform infrared (FTIR) gas analyser. Please read this manual carefully and thoroughly prior to using the analyser. Improper use of the analyser may damage the equipment. Chapter 2 Principle of Measurement discusses theoretical aspects of infrared spectroscopy. These fundamentals help understanding the physical principles the Gasmet system is based on. Chapter 3 Gasmet DX-Series FTIR Gas Analyser provides information about the Gasmet DX-Series hardware and technical specifications. Chapter 4 Installation provides information of installing the Gasmet DX-Series gas analyser. Use this paragraph to check the contents of the Gasmet package and to get Gasmet from storage into operational condition. Chapter 5 Start-up provides some basic information of the operation of the Gasmet DX-Series. This chapter is recommended to read before any operation. Chapter 6 Maintenance describes the maintenance operations that are necessary periodically. Chapter 7 Analyser Inspection describes what should be done when the analyser is used the first time. This chapter includes inspection sheet, which should be filled within 30 days from the date of delivery to ensure that the warranty is valid in full. To learn how to operate the Gasmet analyser with the Calcmet controlling and analysing software, please refer to the Calcmet User’s Guide and Reference Manual. This instructions manual is copyrighted 2005-2015 by Gasmet Technologies Oy. All rights reserved. No part of this manual may be reproduced in whole or in part in any form without a prior written permission by Gasmet Technologies Oy.

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PRINCIPLE OF MEASUREMENT

1.1 Principles of Infrared Spectroscopy

Infrared (IR) spectroscopy is a technique for chemical analysis and determination of molecular structure in solid, liquid, and gas state. The principles that molecular vibrations occur in the infrared region of the electromagnetic spectrum and functional groups in chemical compounds have characteristic absorption frequencies are the basis of this technique. The frequencies of the most interest range from 2.5 to 16 µm. However, in IR spectroscopy it is common to use the reciprocal of the wavelength, called 'wave number', and thus this range becomes 4000 - 625 cm-1. An absorption spectrum demonstrates graphically to what extent the sample gas absorbs the different wavelengths of the infrared radiation. The spectrum shows the transmission of the infrared radiation through the gas as a function of wavelength. For each wavelength, the transmittance T is the intensity of the infrared radiation that has passed through the sample gas divided by the intensity of the infrared radiation that has entered the sample gas. When there is no absorption, the value of transmittance T is 1 (or 100 %), which indicates that 100 % of the infrared radiation at that wavelength goes through the sample gas. If the intensity of the radiation entering the sample is I0 and the intensity of the radiation that has passed through the sample is I, the transmittance T is:

Besides using transmittance T, the absorbance scale presents the absorption of the infrared radiation. Absorbance A is equal to the logarithm of the transmittance reciprocal:

The advantage of using the absorbance scale is that the value of absorbance is directly proportional to the thickness of the sample gas (absorption path length), and the concentration of the sample gas. Figure 1 shows how a carbon dioxide CO2 molecule behaves when it interacts with

T = I / Io, T = transmittance I = passed intensity I = incident intensity

A = log10(I / T), A = absorbance T = transmittance

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infrared radiation. All different vibrations, rotations, and their combinations result in absorption bands of specific wavelengths of the infrared radiation.

Figure 1. The four normal modes of vibration of carbon dioxide CO2 molecule.

The infrared absorption spectrum is unique to all different gas molecules. It is possible to identify any gas component from its IR spectrum. Figure 2 shows a carbon dioxide CO2 infrared absorbance spectrum. It can be seen that the anti-symmetric vibration band at 2349 cm-1 is the most intensive band while others are either outside of the range (900 - 4220 cm-1) or too weak in intensity. The band at ~3660 cm-1 is the combination band (i.e. sum) of υ1 and υ2.

Symmetric stretch υ1 at 1388 cm-1 (This mode is not infrared active)

Anti-symmetric stretch υ3 at 2349 cm-1

In-plane bend υ2 at 667 cm-1

Out-of-plane bend υ2 at 667 cm-1

O C O

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Figure 2. An absorbance spectrum of carbon dioxide CO2 measured with a DX4015 model. c(CO2) = 50 ppm, T = 50 oC, absorption path length = 9.8 m.

1.2 Components of a Fourier Transform Infrared Spectrometer

Figure 3 shows the basic parts that are typical for all non-dispersive FTIR spectrometers. A parallel, polychromatic radiation from an IR source is directed to an interferometer. The modulated beam is reflected through the gas sample cell. Finally, the detector detects the intensity of the infrared beam. The detected signal is digitized and Fourier transformed by the computer resulting in an IR spectrum of the sample gas.

Figure 3. The basic components of an FTIR spectrometer are infrared source, interferometer, sample cell, detector, and signal and data processing unit.

The unique part of an FTIR spectrometer is the interferometer. Figure 4 shows a

Infrared source

Interferometer Detector Signal and

data processing unit

Sample cell

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Michelson type interferometer. A mirror collects and collimates the infrared radiation from the source before it strikes the beam splitter. The beam splitter ideally transmits one-half of the radiation, and reflects the other half. Both transmitted and reflected beams strike plane mirrors, which reflect the two beams back to the beam splitter. Thus, one-half of the infrared radiation that finally goes to the sample gas has first been reflected from the beam splitter onto the moving mirror, and then back to the beam splitter. The other half of the infrared radiation going to the sample gas has first gone through the beam splitter and then reflected from the fixed mirror back onto the beam splitter. When these two beams from two optical paths are reunited, interference occurs at the beam splitter. The strength of the interference is depended on the optical path difference between the beams caused by the position of the moving mirror.

Source

Beamsplitter

Radiation to the sample gas and detector

Moving mirror

Fixed mirror

Figure 4. A Michelson interferometer is a unique part of an FTIR spectrometer.

The optical path length difference (OPD) between the two optical paths of a Michelson interferometer is two times the physical displacement of the moving mirror. An interferogram is the interference signal measured by the detector as a function of the OPD. Figure 5 shows a typical interferogram produced by the interferometer. The graph shows the intensity of the infrared radiation as a function of the displacement of the moving mirror. At the peak position, the optical path length is the same for the radiation that comes from the moving mirror as it is for the radiation that comes from the fixed mirror.

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Figure 5. A typical interferogram.

The spectrum is computed from the digitized interferogram by performing a Fourier transform by a computer utilizing a Fast Fourier Transform (FFT) algorithm.

1.3 Quantitative Analysis of FTIR Spectra

The basic law for spectroscopic quantitative analysis is Beer's law (also known as the Beer-Lambert law). It shows how the concentration of the sample gas is related to the measured absorbance of the sample spectrum:

log( / ) log( / )I I T A abc0 1= = = Io = intensity of infrared radiation entering the sample I = intensity of the infrared radiation that has passed through the sample A = absorbance T = transmittance a = a (υ) = absorptivity (depends on wavelength) b = optical path length c = sample concentration

Vol

tage

U (m

v)

Optical path difference x/2 (cm-1)

- L 0 + L

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The absorptivity a characterizes the capacity of the molecule to absorb infrared radiation. The value of a varies from a molecule to another and as a function of wavelength, but is constant for a given molecule at a given wavelength. The quantity b is the optical path length, that is, the distance the infrared radiation beam traverses in the gas sample. The quantity c indicates the concentration of the sample gas molecules in the sample. If the optical path length is constant, Beer's law states that the absorbance is directly proportional to the concentration of the sample gas at a given wavelength. Since Beer's law is additive, the total absorbance A is equal to the sum of the values of A of each gas component. Two conditions limit the use of the Beer's law in practice. The radiation is monochromatic, and the sample absorptivity does not vary with concentration. If the sample concentration range is wide, the change in the sample environment can cause absorptivity changes and deviations from Beer's law. For narrow concentration ranges and for low absorbance values a plot of concentration versus absorbance is nearly linear. The changes in the gas pressure caused by molecular collisions may bring about broadening in the absorption line shape of the sample gas. This affects all infrared bands. As the temperature increases, the population distribution of the molecules in different energy levels changes. The changes in the temperature cause changes in the absorption line shape of the sample gas. To measure the concentration of a gas compound, it is necessary to calculate the number of gas molecules in the sample cell. The number of the gas molecules in the sample cell depends linearly on both the gas pressure and the volume of the sample cell, and reciprocally on the gas temperature (ideal gas equation of state):

Any changes in sample gas temperature and/or pressure in the sample cell directly affect the measured gas compound concentration. In addition, gas pressure or temperature changes may affect the line shape of the measured absorbance spectrum, and thus the accuracy of the analysis results.

pV = nRT, p = pressure V = volume n = number of gas molecules R = gas constant = 8.314 JK-1mol-1 T = temperature

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1.4 Multi-component Analysis

The degree of absorption of infrared radiation at each wavelength relates quantitatively to the number of absorbing molecules in the sample gas. Since there is a linear relationship between the absorbance and the number of absorbing molecules, quantitative multi-component analysis of gas mixtures is feasible. To perform multi-component analysis we need a sample spectrum. In addition, we need reference spectra of all the gas components that may exist in the sample. A reference spectrum is a spectrum of one single gas component of specific concentration. In multi-component analysis, we try to combine these reference spectra with appropriate multipliers in order to get a spectrum that is as close as possible to the sample spectrum. If we succeed in forming a spectrum similar to the sample spectrum, we get the concentration of each gas component in the sample gas using the multipliers of the individual reference spectra, if we know the concentrations of the reference gases. For example, suppose we have a sample spectrum and reference spectra like those shown in Figure 6. In this case, we know that the sample gas consists of gases Reference 1 and Reference 2. We have the reference spectra available and we know that these reference spectra represent concentrations of 10 ppm and 8 ppm, respectively. To find out the concentration of each component in the sample gas, we try to form the measured sample spectrum using a linear combination of the two reference spectra. We find out that if we multiply the spectrum Reference 1 by 5 and the spectrum Reference 2 by 2, and combine these two spectra we get a spectrum that is similar to the sample spectrum. Accordingly, the sample gas contains reference gas 1 at five times the amount in the reference spectrum 1, and reference gas 2 at two times the amount in the reference spectrum 2. The analysis indicates that the sample indeed consists of these two reference gases. The concentration of the reference gas 1 in the sample is found to be 50 ppm (= 5 x 10 ppm), and the concentration of the reference gas 2 in the sample is 16 ppm (= 2 x 8 ppm).

0

0.05

0.1

0.15

0.2

0.25

0.3

Sample

Reference 1

Reference 2

Figure 6. An example of spectra for multi-component analysis. The spectral analysis routine in Calcmet software performs all calculations automatically.

Abs

orba

nce

(in a

bsor

banc

e un

its)

Wave number (cm-1)

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1.5 The Spectral Resolution of FTIR Analysis

The spectral resolution of the measurement indicates how accurately it is possible to separate different wavelengths of radiation in the absorption spectrum. High resolution allows one to detect visually the exact location of narrow absorbance peaks and reduces spectral overlap. If it were possible to achieve infinite resolution, no deviations of Beer's law due to wide concentration range would occur. Thus, it would seem beneficial to have high resolution in order to get good results for the analysis. However, increasing the resolution causes other problems. For example, spectral noise increases and makes the analysis less precise. Furthermore, as high a resolution as possible does not maximize the information content of the measurement. Jaakkola et al. have shown1 that low-resolution FTIR spectroscopy offers some valuable advantages compared to the traditional high-resolution FTIR gas phase spectroscopy, especially in non-laboratory environments. This makes the use of low resolution quite worthwhile. To achieve precise quantitative analysis results, a low-resolution measurement should be used if the spectral analysis program can mathematically solve the spectral overlap. There are two reasons for the increase of the signal-to-noise ratio of an FTIR spectrum: • In an FTIR spectrometer, the length of the measured interferogram determines the

resolution. The longer the interferogram, the more data points is required, and the higher the resolution. In a high-resolution study, the time required by a single measurement is also long, so that we are able to accumulate less data in a fixed time, leading to higher noise level. Thus, the longer the measured interferogram is, the lower the signal-to-noise ratio.

• High resolution requires a small aperture to prevent a phenomenon called aperture broadening. Small aperture, in turn, reduces the signal and thus signal-to-noise ratio.

1 See, for example, P. Jaakkola, J. D. Tate, M. Paakkunainen, J. Kauppinen, and P. Saarinen, "Instrumental Resolution Considerations for Fourier Transform Infrared Gas-Phase Spectroscopy," Applied Spectroscopy 51 (1997) 1159 - 1169.

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3 GASMET DX-SERIES FTIR GAS ANALYSER

3.1 Introduction

The Gasmet gas analysers are divided into four categories: On-line/CX- and FCX-Series, On-site/DX-Series, In-lab/CR-Series, and In-situ -Series depending on their properties and customers' application. All Gasmet analysers incorporate a Fourier transform infrared (FTIR) spectrometer, a temperature-controlled sample cell, and signal processing electronics. The analyser offers versatility and high performance for all users. The Gasmet On-site/DX-Series includes the DX4000 and DX4015 models, which both are portable multi-component gas analysers for demanding industrial applications. The Gasmet DX-Series in designed for on-site measurements. It is an ideal tool to measure trace concentrations of pollutants in wet, corrosive gas streams. The sample cell maximum temperature is 180 °C (210 °C in a special configuration) in the DX4000 and 50 °C in the DX4015 model. Sample cell absorption path length is selected according to the application. The DX4000 model analysers are used typically in stack emissions monitoring, catalytic process control, and other applications where multiple gas compounds need to be monitored accurately in hot and wet gas. The sample cell heating ensures that condensation is not a problem even in high water vapour concentrations. The DX4000 analysers are designed to be used in together with the Gasmet portable sampling system (PSS), heated sample lines, and a heated sample probe. The DX4015 model is meant for ambient air measurements in applications such as industrial air quality monitoring and occupational health measurements. It can be also used in emergency response situation after incidents involving toxic chemical compounds. The key features of the Gasmet DX4015 include a high sensitivity sample cell for lowest possible detection limits and a built-in-pump, which means that there is no need to use a separate sampling system. The Gasmet DX-Series incorporates advanced hardware and software to provide a portable high-speed gas analysis system. It brings analytical laboratory performance in non-laboratory conditions and eliminates the equipment, calibration, and service costs associated with multiple, single component gas analysers. The Gasmet DX-Series allows simple calibration using only single component calibration gases. The user can easily configure the analyser for a new set of compounds. The software of Gasmet is based on the powerful multi-component analysis software, Calcmet. It is used to compute the concentrations of the different components present in the sample gas. The reference spectra needed in the analysis are stored in the computer and are simply loaded from the library folder when used in the analysis of an unknown sample. Calcmet software is described in the Calcmet User's Guide and Reference Manual.

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3.1.1 Applications of the Gasmet DX-Series Analyser

The Gasmet DX-Series enables identification and quantification of multiple gaseous compounds simultaneously and accurately, with results available in seconds. The Gasmet DX-Series is a versatile gas analyser that can be used in several applications. It is specially designed for: • Emissions monitoring • Process gas monitoring • Scientific research • Industrial hygiene • Emergency response

3.1.3 Structure of the Gasmet DX-Series Analyser

Figure 7 outlines the structure of a DX-Series gas analyser. The infrared source produces broadband radiation, which interferometer modulates. The interferometer actually performs an optical inverse Fourier transform of the infrared radiation emitted by the infrared source. The modulated infrared radiation passes through the sample cell where sample gas absorbs certain wavelengths of the radiation. The detector detects the transmitted infrared radiation. The A/D converter digitizes the signal. The on-board digital signal processor (DSP) performs a mathematical Fourier transform on the digitized interferogram resulting in a spectrum. Fast Fourier Transform (FFT) is used to compute the spectrum from the interferogram. The transmittance spectrum is the ratio of the sample spectrum to the background spectrum. The absorbance spectrum is computed from the transmittance spectrum. Gasmet uses the Calcmet software to compute the concentrations of the components present in the sample gas from the absorbance spectrum. The data and signal processing electronics control the operation of Gasmet. An external PC compatible computer controls the Gasmet DX-Series analyser. A unique part of Gasmet is the Gasmet Technologies Oy's GICCOR (an acronym for 'Genzel interferometer with a cube corner retroflector') interferometer. It is rugged and withstands the demanding environmental conditions of non-laboratory environment. The GICCOR interferometer modulates the infrared radiation coming from the infrared source, as discussed previously. The modulated infrared radiation passes through the temperature controlled sample cell. The gas sample is introduced into the gas cell through standard gas fittings. Thermoelectrically cooled detector then detects the transmitted infrared radiation.

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Figure 7. Basic structure of the Gasmet DX-Series analysers.

3.2 Gasmet DX-Series Technical Data

3.2.1 General Parameters

Measurement principle: FTIR (Fourier Transform Infrared) spectroscopy Performance: Simultaneous analysis of up to 50 gas compounds Response time: < 120 s depending on the gas flow, measurement time, or sample cell Operating temperature: -10 − +40 °C, optimum +10 − +25 °C, non-condensing Storage temperature: −20 − +60 °C, non-condensing Power supply: 300 W, 100 – 240 VAC, 50 - 60 Hz (DX4000) or 12 VDC (DX4015)

3.2.2 Spectrometer

Interferometer: Gasmet Technologies Oy’s GICCOR interferometer Resolution: 8 cm-1 (4 cm-1 is an option) Scan frequency: 10 spectra/second Aperture: 1’’ Detector: Thermo-electrically cooled mercury cadmium telluride (MCT) detector IR source: Ceramic (SiC), at 1550 K temperature Beam splitter: ZnSe Optical window material: ZnSe Wave number range: 900 – 4200 cm-1 with ZnSe/MCTP

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3.2.3 Sample Cell

Structure: Multi-pass; fixed path length of 2.5, 5.0, or 9.8 m Material: 100 % gold and rhodium coated aluminium Mirrors: Fixed rhodium supported gold coating Volume: 0.45 dm3 Connectors: Swagelok 6 mm, 8 mm or 1/4" (DX4000); Swagelok 6 mm or 1/4"

(DX4015) Gaskets: Viton o-rings. Kalrez o-rings are optional. Temperature: 180 °C is a maximum for DX4000 (210 °C in a special configuration); 50

°C is a maximum for DX4015 Maximum sample gas pressure: two bars Flow rate: 1 - 5 dm3/min Response time: < 30 seconds Required gas filtration: Filtration of particulates [two (2) microns)] Sample gas condition: Non-condensing The Gasmet DX-Series models are equipped with optimised sample cell in accordance with customer order specification. The gas cell is located inside a temperature-controlled oven.

3.2.4 Measuring Parameters

Zero point calibration: 24 hours calibration with nitrogen (5.0 or higher N2 recommended) Zero point drift: 2 % of smallest measuring range per zero-point calibration interval Sensitivity drift: None Linear derivation: 2 % of smallest measuring range Temperature drift: 2 % of smallest measuring range per 10 °C change Pressure influence: 1 % change of measuring value for 1 % sample pressure change

3.2.5 Electrical Connectors

Digital interface: RS232, 9-pole D-connectors. RS232 cable connects the DX-Series to an external computer.

Power connection: Standard plug CEE-22 Relay connection: External PC Analogue input/output: External PC PSS control connector: For DX4000. DX4015 has an option for a 12 VDC power connection

3.2.6 Gas Inlet and Outlet Conditions

Gas temperature: Non-condensing. The sample gas temperature should be the same as the sample cell temperature

Sample pump: External in the DX4000 model, internal in the DX4015 model Flow rate: 1 - 5 dm3/min

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Gas filtration: Filtration of particulates (2 µm) required Sample gas pressure: Ambient

3.2.7 Computer and Electronics

A/D converter: Dynamic range 95 dB Signal Processor: 32 bit floating point DSP 120 MFLOPS speed Computer: External, not included Operating system: Microsoft Windows (XP is preferred) Analysis software: Calcmet

3.2.8 Enclosure

Material: Aluminium Dimensions (mm): 445 ∗ 164 ∗ 390 (Figure 8 and Figure 9) Weight: 13.9 kg (DX4000), 14.9 kg (DX4015) CE label: According to EMI guideline 89/336/EC CE mark indicates compliance with directive 89/336/EEC for electromagnetic compatibility. The CE marked Gasmet models are certified by the manufacturer as follows: Immunity: EN 61000-6-2 (1999). Emission: EN 50081-2 (1993).

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Figure 8. Dimensional drawing of the DX4000 analyser enclosure.

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Figure 9. Dimensional drawing of the DX4015 analyser enclosure.

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4 INSTALLATION

4.1 Supply Schedule

4.1.1 Package

Gasmet is shipped in a wooden box. To open the box, first open the lid of the box. Remove any additional smaller items on the top of the analyser. Finally lift Gasmet out of the box. Check that no items listed in chapter 4.1.2 Contents of the Gasmet Package remain inside the box. The gas fittings are closed with caps in order to prevent contamination by dirt and dust. Please do not remove caps until you connect the sample gas lines.

4.1.2 Contents of the Gasmet Package

The package contains: • Gasmet gas analyser • DVD-ROM, including:

1. Application Tools folder (ADS application tools and Gasmet Tools application tools)

2. Gasmet Software folder (Calcmet setup) 3. Quality Documents folder (ISO 9001 Certificate, MCERTS Documents,

Finnish Defence Forces Research Institute of Technology's Vibration Test, and TÜV Documents)

4. User Manuals folder a) Gasmet Instruction and Operating Manual b) Calcmet User's Guide and Reference Manual

5. CalcmetLibrary folder, which includes the instrument-specific reference files, reference spectra Excel sheet (description of the installed reference spectra) and library .lib file, all under a specific serial number.

6. Test folder (factory-measured SNR spectra, background spectra, and .ini file) • Accessories:

1. RS232 cable 2. Power cable for European 230 VAC use 3. Control cable for the portable sampling system (optional for the DX4000)

4.1.3 Settings

The following functions have been factory set in accordance with customer order specification • sample cell temperature • alarm limit values in Calcmet software • software and analysis options in Calcmet software

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4.2 Ambient Conditions

4.2.1 Storing and Transporting Gasmet

The instrument must be stored, installed, and operated in a dry and condensation-free place. It is essential to avoid condensation within the analyser. The environment should be clean enough so that no dirt will accumulate on or inside of Gasmet. When Gasmet is in the package or not in use, store the equipment in following conditions: • -20 - +60 °C storage temperature • 5 - 95 % relative humidity, non-condensing Gasmet should not be exposed to strong mechanical vibration or shocks. Shocks during transport, for example, can cause serious damage. When transporting the instrument, use the original box with original shock absorbing materials.

4.2.2 Installation Location

The Gasmet DX-Series must be preferably mounted horizontally. An extreme inclination of the enclosure may interfere with the operation of the analyser. The installation location must be preferably free of strong vibrations. It is recommended that the instrument is operated in the following environmental conditions: • -10 - +40 °C operating temperature in short term use • 10 - 25 °C operating temperature in long term use • < 90 % relative humidity at 20 °C, non-condensing The ambient temperature of operation location must preferably be stable. In some cases, temperature changes may affect the analysis results and the accuracy of the measurements decreases. Re-measuring the background (zero) spectrum eliminates the influence of the temperature. Gasmet DX-Series enclosure serves as heat radiator plate. Do not block the air circulation.

4.2.3 Explosion Protection

For your own safety, Gasmet must not be used in hazardous areas. The standard enclosure is not explosion proof. Gasmet should not be used to measure explosive gas mixtures or gases that might form an explosive gas mixture with the ambient air. Gasmet Technologies Oy assumes no responsibility if Gasmet is used in hazardous areas.

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4.3 Sample Gas Supply

The sampling system is as crucial to the success of the measurement as the analyser itself is. When you connect Gasmet to the sampling system, please observe the following:

1 Use proper sampling system. Most installations require heated sample lines, heated

particle filters, and a heated sample pump (for the DX4000 model only). Some installations require special sample line materials, stainless steel for example, to avoid adsorption of specific components.

2 During operation, keep gas flow constant. Maximum recommended flow rate is 300

dm3/h (in the DX4000 model only). If the gas flow is high, a considerable backpressure builds up in the sample cell due to flow resistance. This may lead to significant measuring errors.

3 If the sample gas contains condensable components, heated sample lines must be

used or condensable components have to be removed. If condensation is expected in the sample gas line, install a condensate separator at the lowest point of the line. The analyser will be damaged if condensation enters or is inside the sample cell.

4 Sample gas and zero gas must be at the same temperature as the analyser’s sample

gas cell. 5 Install an external dust filter (two microns) if the sample gas contains particles. A

heated filter is obligatory if the sample gas contains condensable components. 6 Extremely reactive gases in high concentrations [for example, chlorine gas c(Cl2) > 5

%], solid particles, and condense must never be introduced in the gas cell 7 If an external gas pump is installed (in the DX4000 model only), the analyser should

control the power supply of this pump. The pump remains switched off until the gas analyser has reached stable operation condition. Sample cell should never be in contact with sample gas unless the analyser has reached stable operation conditions. User must ensure that all necessary gas supply lines are connected and the operating temperature of all parts (heated lines, sampling systems, and analyser) is reached.

8 During zero-point calibration (background measurement), zero gas must be flowed

into the sample cell. Like the sample gas, the zero gas should flow through the sampling system before it reaches the analyser.

9 All the sample gas and zero gas valves should be controlled by the control outputs. 10 The sample cell must be empty of the sample gas when the power is off. Always

purge the sample cell with dry N2 gas before switching the power off.

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DX4000 DX4015

4.4 Gas Fittings

As seen in Figure 10, all sample gas fittings in the DX-Series models are located on the back plate of the instrument. The sample gas connectors are: • SAMPLE IN and OUT are Swagelok 6 mm and 8 mm or ¼’’ fittings in the

DX4000 model, respectively. Outer diameter of the connecting tube is 6 mm, 8 mm, or ¼’’.

• The DX4015 model has a ZERO IN inlet in addition to the SAMPLE IN and OUT fittings. It is used for flushing the sample gas cell prior a background spectrum measurement.

The analyser's purge gas fitting is located on the front of the enclosure. PURGE connector is a Swagelok fitting, as well. Only N2 or dry and clean instrument air should be used to purge the analyser.

Figure 10. Sample gas fittings of the DX4000 (upper) and DX4015 (lower) models.

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When connecting Gasmet to the sampling system, please observe the following: 1 Connect the sample gas supply to the SAMPLE IN fitting (6 mm or ¼’’). The sample

gas temperature must be the same as the sample cell temperature. Gasmet factory calibration is valid with original temperature settings only.

2 Connect the sample gas outlet to the OUT fitting (8 mm or ¼’’). Direct the gas to a

suitable output line, for example to an exhaust gas channel, if available. Use short tubes. Throttling the sample gas outlet will increase the pressure in the sample cell. Uncontrolled pressure increase in the sample cell may result in large measuring errors.

4.5 On-board Sample Pump (only in the DX4015 model)

The maximum sample gas temperature of the DX4015 model is 50 °C. As the temperature is rather low, sampling system can be relatively simple. The DX4015 model is equipped with an on-board sample pump package, which has a neoprene diaphragm pump. Power supply is 12 VDC, maximum pressure 1.0 bar, and maximum flow is 2.8 l/min.

4.6 Power Connection

4.6.1 Power Supply

The required mains input is 100 - 240 VAC, 50 - 60 Hz. Hold-up time of Gasmet is 20 ms from loss of AC input. Use an uninterruptible power supply (UPS) if the electric power is subject to major disturbances or power failures. If no mains (AC electrical power supply) input is available, the DX4015 model can be operated with an optional 12 VDC power. Connect the power cable to Gasmet power supply unit that is equipped with standard CEE-22 plug. Never connect Gasmet to a mains (AC electrical power) supply that has no protective ground.

4.6.2 Fuses

If you have to replace fuses, you may only use those that correspond exactly to specified values (3.15 AT, physical size 5 x 20 mm). Before checking the fuses, switch the power off. Fuses are located behind the IEC (International Electrotechnical Commission) power inlet unit (see Figure 11). Please see the Service Manual how to replace the fuses.

4.7 Signal Connections

When you connect the Gasmet DX-Series to the sampling system, please use shielded cables only. Otherwise, the specified electromagnetic interference protection will be compromised.

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4.7.1 Optional Analogue Output Signals

Analogue output signals are available, if the computer used to operate DX-Series can be equipped with analogue output boards. Refer to their respective instruction manuals and Calcmet User's Guide and Reference Manual on how to use analogue outputs.

4.7.2 RS232 Interface

RS232 interface is used for communication between the DX-Series and the external computer. For parameter settings, please refer Calcmet User's Guide and Reference Manual.

Figure 11. Gasmet DX-Series connector unit.

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5 START-UP Before you start to operate with Gasmet FTIR gas analyser, read this Manual and Calcmet for Windows User's Guide and Reference Manual carefully and thoroughly. If you do not understand something or you are unsure what to do, please contact the nearest distributor or Gasmet Technologies Oy main office.

5.1 Connections

Make sure that all gas connections, power cable, and serial cable are connected correctly. Connect the serial cable to the external computer. Open the external computer and install the Calcmet software.

5.2 Installing Software

Before installing Calcmet, installing of HASP drivers is necessary regardless of the fact that no HASP license key is required to run Calcmet in Standard mode. Next, to install Calcmet to your PC, run the ‘Calcmet.msi’ installer package from your Calcmet software CD. You may optionally also create the following folders to your hard disk, although they are created during the install or when the directory is first required once the software is running: C:\CalcmetLibrary\ (recommended folder for reference spectra) C:\CalcmetDemoLib\ (recommended folder for demo libraries) C:\CalcmetSamples\ (recommended folder for sample spectra and residuals) C:\CalcmetResults\ (recommended folder for analysis results) C:\CalcmetBackgrounds\ (recommended folder for background spectra) C:\CalcmetLog\ (recommended folder for log files) After the setup procedure, you should have the following files in the C:\Program Files\Gasmet Technologies\Calcmet\ directory: Calcmet.exe The executable main program file DLPORTIO.dll Application extension file PCI-Dask.dll Application extension file ADAMTCP.dll Application extension file hasp_windows_82882.dll Application extension file TcAdsDll.dll Application extension file Calcmet.MET Preset analysis method definitions MEASURINGTIMES.MES Preset measuring timing definitions CalibrationInfo.dat Latest calibration information (example) CALCMET.BKG Latest background (example) Version history.txt Version information text file Once the files have been installed, it will still be necessary to set the reference spectrum libraries (calibrations), and other settings to make the measurements and analysis. Refer to the later chapters of this manual for description on setting all the analysis and measuring parameters.

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The installation also includes the default library, three demo libraries tailored for different applications and some sample spectra. These are for demonstration and training purposes only and should not be used for analyzing any real measurements. All the demo library files can be found in C:\CalcmetDemoLib\ and the reference spectra for the demo libraries are situated in respective sub folders under the same path. The folder C:\CalcmetDemoLib\DemoSamples\ contains the demo sample spectra.

5.2.1 Installing Calibration Files

Optionally there can be calibrations supplied with the analyser. To use the calibrations, it is necessary to copy the calibrations (reference spectra) and analysis settings to a specific location to make use of them. The default directory for calibration files (*.REF) is C:\CalcmetLibrary\. This is where the reference spectra from the install disk or CD should be copied. In addition to the reference spectra, there may be predefined analysis settings (*.LIB). After installing the software, these optional files need to the copied to the library directory, which is usually C:\CalcmetLibrary\. Once these analysis library settings have been copied to the program directory, it is possible to make use of them by selecting the application library in [OPTIONS] [APPLICATION] within the Calcmet program. If the reference spectrum files (*.REF) and library files (*.LIB) were copied from a CD, it may be that the files are write protected. To make later any changes to settings, it will be necessary to inactivate write protection from these files. This can be done by opening the file properties of all these files, and unchecking the “Read-Only” option.

5.2.2 Installing Optional Expansion Cards

If you need to use optional relay cards, analogue input, or output cards with Windows XP, it is necessary to install drivers for these expansion cards. This additional procedure is not necessary if you do not have any of the optional expansion cards installed on your PC. The following setup packages are essential to using the optional expansion cards. Please use the appropriate setup program(s) to install the required driver(s) from the card manufacturer CD(s) or the Calcmet software CD. Alternately, please contact your distributor to obtain the correct setup package. Expansion card used Setup package name Old Gasmet PC with ISA relay cards port95Nt.exe

Any ADLink PCI expansion card(s) PCIS-DASK V4.14.zip

ADAM5000/TCP Ethernet eADAMUtility.exe

Beckhoff Ethernet PLC / IO tcat_2100_1328.exe

Gasmet PC watchdog v1.3_wdt_dio_lx800.rar

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Please note that in most cases after installing the drivers, restarting of Windows might be necessary.

5.2.3 HASP Licensies and Keyes

If you have been supplied with a HASP license key, the key is required to run the software in the correct operating mode. The software will only run in Standard mode without a key. The HASP key may be inserted at any time while the software is running or before it is launched. When the key is inserted for the first time, it may take a short period of time before the key is actually found. All currently available Calcmet software licenses to date: Standard • no key required, no cost • basic functionality Professional • key required • fast measurement mode (<1s) enabled • all advanced features will be contained in future updates of this version free of

further charge 4030Std • key required • measuring and expansion cards are not supported with DX4030 models • 250 gas reference spectra library included 4030Pro • As 4030Std, but with measuring and expansion cards supported Important notice: If the HASP key is damaged, either electrically or physically, do not throw it away unless you are prepared to pay the license fee again. By returning the key, you will be provided with a new key at the list price of a replacement key, but not at the price of a new license.

5.2.4 Uninstalling Calcmet Software

There are two ways Calcmet can be correctly removed from your system. Failing to uninstall the software correctly in one of the following ways may prevent further installations of the software: - relaunching the installation package and choosing the ‘Remove’ option

- through the Windows ‘Control Panel → Add/Remove Programs’

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5.3 Switching the Analyser's Power On

Prior to switching the analyser’s power

• Check the power supply setting. The mains voltage must meet the specified

values: 115 VAC or 230 VAC, 50 - 60 Hz. Check the analyser’s setting voltage! • Make sure that sample-conditioning system is operationally ready, if applicable.

All parts of the sampling system must be at the same temperature as the temperature in the sample cell and all dust particles must be filtered. Before the sample cell is at the target temperature, make sure that the sample cell is empty or filled with zero gas. Never let the sample gas to the cold sample cell.

The power switch is located on the rear panel of the enclosure. Switch the power on. After switching the power on, the sample cell starts to heat to the target temperature. The heating process will take about 30 - 45 minute to reach 180 °C.

5.4 Operation

Calcmet is the software for operating and controlling the Gasmet analyser system via RS232 serial line. Calcmet runs on an external PC compatible computer with Windows XP operating system. This chapter describes the typical procedures that the user is likely to carry out with the Calcmet program, for more information read the Calcmet for Windows User's Guide and Reference Manual.

5.4.1 Using the Calcmet Software

The Calcmet analysis and controlling software resides on an external PC computer that is connected to the analyser with the proprietary Gasmet RS232 serial cable. Once the hardware is turned on, the Calcmet software on the external computer must be started. Run the program C:\Program Files\Gasmet Technologies\Calcmet\Calcmet.exe to start the application. The installation package should also have created a desktop and program menu shortcut under ‘Start → Programs → Gasmet Technologies’ for this purpose. The software and PC may also be started before the analyser, but you should not try to start any measuring function before the analyser is connected, turned on, and stabilized. When the software is starting up, there will be a Window displaying “STARTING CALCMET - Please wait…”. The start-up takes normally a few seconds, but the exact start-up time depends on the processing power of the PC and the size of the library currently in use. When the software is started for the first time after installation, a dialogue appears that asks for some system information (Figure 12). If the PC is connected to the Gasmet analyser, or if you are planning to use any optional expansion cards with the software, it is important to set these parameters correctly. The explanation of the parameters is in

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Table 1.

Figure 12. 'Welcome to Calcmet' dialogue.

If you need to change the parameters later, this can be done from the Calcmet menu [Tools] [Configuration…]. The same ‘Welcome to Calcmet’ interface will appear, but the window title will be changed to ‘Configuration settings’. Please see the Calcmet for Windows User's Guide for details.

Parameter Options Action

SERIAL NUMBER Serial number of the Gasmet analyser, the field is disabled if the serial number differs from zero

SERIAL PORT Calcmet automatically detects the available ports. Assumes that COM1 always exists.

Serial port on the PC where Gasmet analyser is or will be connected. Please note that the actual interface may be RS232, RS422 or RS485.

BAUD RATE 9600 / 19200 / 57600 / 115200 / 230400 / 460800 / 921600

Baud rate for communicating with Gasmet. This value must match the analyser hardware setting. Most new analysers use 57600 baud rate.

DATA FORMAT 16 bit / 24 bit This setting depends on the analyzer EPROM.

MODE Standard / Fast / Other Fast mode is only available with Professional license, others depending on key inserted.

Table 1. ‘Welcome to Calcmet – Analyzer’ parameters.

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If you are planning to make measurements with the software and if the analyser has been shut down, it is recommended to wait some time for the analyser to stabilize before starting the actual measurements. You should wait at least • For the sample cell to reach the set, stable temperature • One (1) hour for temperature stabilization in the analyser If the analyser has been stored in a low temperature condition, the temperature stabilization can take longer than an hour. For more information on analyser hardware, refer to the instructions manual of the analyser.

5.4.2 Setting the Measurement Times

The measuring times are set on the Measuring Times dialogue (Figure 13). Table 2 lists the Measuring Times dialogue settings. If there are no external valves or pump connected for automatic, continuous operation, only the SamplingTime and Measuring Interval need to be set. For multi point sampling, the measuring time list can contain any number of entries. Once the end of the list is reached during continuous measuring the cycle will restart from the first position on the list.

Figure 13. 'Options / Measuring Times' dialogue.

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Parameters Options Action

Line number 0 - 16 Line number zero is used for single point sampling. For multi point sampling line numbers start from one.

Flush Time (s) 0 - 10000 s Sample cell flush time in seconds. After zero calibration, the analyser waits this time before starting new sample measurement.

Pump Time (s) 10 s / 30 s / 1 min / 3 min / 5 min / continuous or any desired value between 1-9999 s.

Pump operating time in seconds. Before measuring the sample, the sample pump will be running this time.

Sampling time (s) 1 s / 5 s / 20 s / 1 min / 3 min / 5 min or any desired value between 1-300 s.

Sample measurement time. The respective zero calibration measuring times are set automatically to 10 s / 30 s / 1 min / 3 min / 5 min / 10 min. For multi point sampling the zero calibration time is calculated from the longest sampling time in the list.

Measuring Interval (s)

0 - 10000 s Time in seconds between starting successive sample measurements when using Continuous measuring. If this value is less than Sampling time, it has no effect.

Number of samples

1 - Number of samples to measure on the same sample line, before moving to the next item on the measuring times list.

Table 2. Commands for setting measuring times.

5.4.3 Zero Calibration

It is first necessary to measure the background spectrum (zero calibration) for subsequent sample spectrum measurements. Before making the zero calibration, wait until the instrument has reached a steady condition. The sample cell temperature and interferometer temperatures must be stable. For the zero calibration measurement, the sample cell must be filled with zero gas like pure N2 or O2. Make sure there is no sample gas or other unwanted substances in the sample cell. The sample cell must be flushed with the zero gas a few minutes before initiating the background measurement. Please remember to use a heated line that is in the same temperature as the sample cell when flushing in the zero gas. To start the background measurement, open the Measure menu and choose the command Background Table 3. If it is necessary to change the measuring time for the zero calibration, first run a single measurement from one of the toolbar buttons. The zero calibration time is adjusted automatically to be suitable for the last single measurement. For continuous measuring, the background time is calculated from the largest sample measuring time in the Measuring times dialogue.

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Action Commands

1 Run a single measurement with the desired time from the toolbar, the background time is adjusted accordingly.

[OPTIONS] [MEASURING TIMES]

Set the sample measuring time(s). The zero calibration time in continous measuring will be set automatically according to the largest sample measuring time in the measuring times list.

<OK>

2 Perform the measurement. [MEASURE] [BACKGROUND]

Table 3. Zero calibration measurement commands.

A typical background spectrum is presented in Figure 14. The background graph does not present absorbance nor transmittance spectrum. The background is a single beam spectrum that shows the actual absolute intensity of infrared radiation that is transmitted through the zero gas filled sample cell. The background spectrum is used as the zero level, to which the actual sample measurements are later compared. This zero level is needed to calculate the absorbance or transmittance values of the sample.

Figure 14. A typical background spectrum.

In normal conditions, the shape of the background spectrum should be near to that shown in Figure 14. The absorbance peak at 2350 cm-1 results from CO2 that is typically present in the optical path. The smaller peaks in the range of 1300 - 1800 cm-1 result from humidity that is also normally present in the optical path.

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5.4.4 Measuring the Sample Spectrum

5.4.4.1 Single Measurement When the zero calibration is completed, the analyser is ready for the sample measurements. Open the Measure menu and choose the command Single to make a single measurement of the sample (Table 4). The sample will be measured according to the last single measurement made. If the Analyse option is on, the sample will be automatically analysed, too. To measure the sample spectrum without automatic analysis, uncheck the parameter Analyse in the settings menu.

Action Commands

1 Set the sample measuring time. [OPTIONS] [MEASURING TIMES]

Set the sample measuring time, if necessary. If you change the time longer, the background should be remeasured.

<OK>

2 Measure the sample. [MEASURE] [SINGLE]

Table 4. Single measurement commands.

5.4.4.2 Continuous Measurement

To make continuous measurements, open the Measure menu and choose the command Continuous. The sample will be measured continuously until <Cancel> button is pressed. The results will be shown and updated on the screen continuously after each measurement. If the result autosaving option is set on, the results of each measurement will be saved to the disk. In addition to the sample, the background can be measured automatically at time intervals specified by the user. Furthermore, time intervals can be specified for purging the sample cell. If it is necessary to change these measuring parameters for the continuous sample measurement, open the menu Measure and choose the command Measuring times (Table 5). Set the value for Measurement time (s) to indicate the appropriate measurement time.

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Action Commands

1 Set the measuring parameters: measuring time, measurement interval, and sample cell flush time.

[OPTIONS] [MEASURING TIMES]

Set the measuring parameters, if necessary. If you change the measuring time longer, the background should be re-measured.

<OK>

2 Start continuous measuring. [MEASURE] [CONTINUOUS]

3 Stop continuous measuring. <Cancel>

Table 5. Continuous measurement commands.

5.4.5 Checking the Hardware

It is recommended to write regularly down the interferogram centre and the maximum peak height from the Hardware Status display (Table 6). This could be done, for example, once a day right after the zero calibration. If the values have changed noticeably, it may indicate that some parts need cleaning or calibration. For example, decreasing amplitude of the interferogram peak height may indicate that the optics of the sample cell are getting dirty. Before running this command, the temperatures of the analyser should be fully stabilized. If some readings appear to be abnormal, try resetting the whole analyser before any other maintenance operation.

Action Commands

1 View hardware information [VIEW] [HARDWARE STATUS]

2 Exit display <OK>

Table 6. Commands for checking hardware status.

5.4.6 Analyzing the Sample Spectrum

To analyze correctly the sample, a good quality background must be measured, an analysis library specified and set, and the sample itself measured. When all these three components are first done correctly, reliable analysis results can be obtained. For more information, please consult the Calcmet User's Guide and Reference Manual.

5.5 Sample Calcmet Session

Suppose that the reference spectrum library is already specified, but there is no background spectrum, or sample. To measure and analyze a sample, proceed as follows:

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5.4.1 Step 1: Select the Components That Will Be Analyzed

In the analysis library, you have to include all those components in the analysis that are present in the sample gas mixture. If there is a significant amount of some substance in the sample that is not listed in the library, the results of the analysis are likely to be incorrect. To include or exclude components from the analysis, open the Analysis Settings dialogue in the Edit menu. To toggle the analysis of any component ON or OFF, click the check box next to the component name. The components that are currently included in the analysis are shown with a tick mark.

5.4.2 Step 2: Measure the Background

When measuring the background, the sample cell must be filled with a zero gas. Zero gas must not absorb infrared radiation. A typical zero gas is nitrogen (N2). Be sure there are no other substances in the sample cell at the time of background measurement. In addition, make sure Gasmet is fully stabilized. The power must have been turned on at least 30 minutes earlier or longer if the temperatures of the system have not yet stabilized. For precise measurements, let the system stabilize longer. Every time any environmental conditions change, it is recommended to re-measure the background. Even if there has been no noticeable change, it is good practice to re-measure the background every now and then, at least every 24 hours. To start measuring the background, open the Measure menu and choose the command Background. The time of the background measurement will be automatically adjusted suitable with respect to the actual sample measuring time. If you change the sample measuring time longer, measure the background again. When the background measurement has finished, a graph displaying the background spectrum will be shown on the screen.

5.4.3 Step 3: Measure and Analyze the Sample

To change the measuring time for the sample measurement, open the Options menu and choose the command Measuring Times. Set the value for Sampling Time (s) to indicate the appropriate measurement time. The measurement time can be, for example, 20 seconds or 1 minute. The smaller the concentrations measured are, the longer the measurement times should be. Next, open the Measure menu and choose the command Single to make a single measurement of the sample. The analysis results are shown on the screen, if the Analyze option in the Options menu is checked.

5.4.4 Step 4: Verify the Results

A good indication of how good the analysis was and how good the results are is the residual graph. Open the View menu and choose the command Residual. This graph shows the residual between the measured sample spectrum and the model used in the analysis for the selected component. If the residual does not show any clear peaks but

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noise, and the peak heights are close to zero everywhere, the analysis was successful. In successful measurements, the residual peaks must be below 0.01 in the absorbance scale, and for precise measurements even better. If there are any clear spectral structures, or the base line is tilted, try to include some possibly missing components to the analysis and analyze the sample again to get better results. Sometimes it also may be necessary to measure the background again to get better results. Shortcut to display the residual together with the respective reference spectrum is to double-click the maximum residual number of the component in the result display. The maximum residual number is displayed in the last column of the result display.

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6 MAINTENANCE

6.1 Safety Precautions

Improper handling of any components inside Gasmet may damage the equipment. Thus, adjustment of any components inside Gasmet avoids warranty. Any service operations that require opening the case of Gasmet should be performed only by Gasmet Technologies Oy qualified technician. The case should be opened only when Gasmet is turned off, and the power cable and the gas lines disconnected. The user should pay attention to the following points: 1 Every time after the measurements and before turning off the power of Gasmet,

the sample cell should be carefully flushed with nitrogen gas or dry instrument air. Sample cell should be closed with caps if the sample lines are disconnected from the gas cell. If corrosive gases remain in the sample cell when the power has been switched off, the optics inside the sample cell will be damaged. Measuring strongly acid or caustic gases may shorten the lifetime of the sample cell.

2 If the sample gas contains solid particles, it should be filtered before introducing it

into the sample cell. If it is not filtered, dirt will accumulate in the sample cell and lower the quality of the measurements. Any liquid droplets or aerosols inside the gas cell may destroy sample cell mirrors or optical windows.

3 After power has been switched off for a longer period or the unit is used in extremely

humid ambient conditions, it is recommended to purge the spectrometer and detector with dry nitrogen gas to avoid ice formation on the detector window.

4 The pressure and temperature of the sample gas should always be kept as stable as

possible. However, the gas entering the sample cell should already be as close as possible to the sample cell temperature.

5 Intensive shocks may damage the analyser. Be always very careful when you

move or transport the instrument. 6 Use a soft cloth to wipe off the dirt on the case. The case of Gasmet is not

waterproof. Do not apply running water when cleaning the case. Do not use strong detergents or acetone. If the instrument is used in dusty conditions, it is recommended to vacuum clean the dust filters (and replace if necessary) at least once a month. The filters are located on the front and back panels of the instrument.

6.2 Maintenance Plan

Table 7 presents a rough maintenance plan. The maintenance required depends strongly on the application. The maintenance work procedures are described in this manual. Operations that are more detailed are described in the Service Manual.

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Maintenance interval

Maintenance work

1 month Visual inspection and sample conditioning system inspection (according to the instructions given by manufacturer(s) of the system components). Vacuum clean the dust filters.

6 - 12 months Water calibration (performed by trained service personnel).

Approximately 12 months

Annual service: analyser inspection, cleaning, and tuning (performed by trained service personnel).

2 – 3 years IR source replacement (performed by trained service personnel).

3 – 5 years Laser source replacement (performed by trained service personnel).

Table 7. Maintenance plan.

In principle, Gasmet requires no calibration except zero calibration after the original factory set-up. Water vapour calibration is however an exception to the rule. It is highly recommended that its calibration is performed at least 1 - 2 times a year especially after a relocation of the analyser or if any optical parts have been replaced or aligned.

6.3 Visual Inspection

When you make the visual inspection check that: • there exist enough zero gas for automatic background measurements (with

automated sampling system) • sampling system, sample lines and gas connectors are in good condition • sample cell temperature is correct • sample line temperatures are correct • sample gas flow is correct • purge gas flow is correct

6.4 Sample Cell Inspection

The sample cell inspection can be made for all types of sample cells. Only a qualified technician may perform sample cell inspection. Sample cell inspection is described in detail in the Service Manual. The operation includes following procedures: • sample cell optical window check • sample cell mirror inspection • water calibration • operational test

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6.5 Replacement of Optoelectronic Components

Only trained service personnel may perform replacement of any of the optoelectronic components. Expected lifetime of the detector is five (5) years and laser tube three (3) years. However, to avoid any unexpected faults it is recommended that • infrared light source is replaced once in every 2 - 3 years • laser tube and its power source is replaced once in 3 - 5 years • detector is replaced if necessary

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7 ANALYSER INSPECTION The analyser must be inspected within 30 days from the date of delivery, to ensure that the warranty is valid in full. Please check the following points and fill the Gasmet FTIR Gas Analyser Inspection Sheet on the next page. If you noticed that something is missing or the analyser is damaged during transportation, please contact the nearest distributor or Gasmet Technologies Oy. Before you make this inspection, it is recommended to read Calcmet User's Guide and Reference Manual and Gasmet Instruction & Operating Manual, especially Chapter 5 Start-up. 1. Check the condition of the shipping box. 2. Check that no items listed in Chapter 4.1.2 Contents of the Gasmet Package are

missing.

3. Check visually that the analyser's enclosure is undamaged.

4. Connect serial and power cable. 5. Install the Calcmet program to an external PC. 6. Switch the analyser’s power on.

7. Wait before the analyser has reached the stable operating conditions. Then check

the Hardware Status and write down all the parameters in the inspection sheet.

8. After checking Hardware Status, measure a single sample spectrum with pure nitrogen and use 20 seconds measuring time. Save the sample spectrum. Print also the sample spectrum on a paper. The sample spectrum includes a lot of information that can be used for troubleshooting purposes. It is important to use the factory-measured background in this test. Do not measure a new background!

9. Send copy of the filled Gasmet FTIR Gas Analyser Inspection Sheet to Gasmet

Technologies Oy by fax, mail, or e-mail. Please see the contact information at the bottom of the page or on the last page of this manual.

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7.1 Gasmet FTIR Gas Analyser Inspection Sheet

Gasmet model: __________________ Date of delivery: _________________

Serial number: __________________ Representative company: _________________

1. Condition of the shipping box � Correct � Remarks ______________________________________________________________________________ ______________________________________________________________________________ 2. Contents of the Gasmet package � Correct � Remarks ______________________________________________________________________________ ______________________________________________________________________________ 3. Visual inspection � Correct � Remarks ______________________________________________________________________________ ______________________________________________________________________________ 4. Software � Software installed from the software DVD � Software runs correctly � Factory measured background file Calcmet.bkg moved from the software DVD to the external

computer ______________________________________________________________________________ ______________________________________________________________________________ 4. Hardware Status parameters Time measured: __________________ Interferogram Centre: _________________ Status: __________________ Interferometer Temp.: _________________ Source Intensity: __________________ Sample Cell Temp.: _________________ Interferogram Height: __________________ Software version: _________________ 5. Sample spectrum successfully measured (20 s) with pure nitrogen gas using factory measured background and saved. � Yes � No Please attach the sample spectrum to this form. Name: _____________________________________________________________________ Position: _____________________________________________________________________ Date: _____________________________________________________________________ Send a copy of this filled Gasmet FTIR Gas Analyser Inspection Sheet to Gasmet Technologies Oy by fax, mail, or electronic mail. See the contact information on the bottom of the page.

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APPENDIX A: VOCABULARY Absorbance A measure of the amount of infrared radiation absorbed by a sample gas as a

function of frequency.

Beam splitter A component in the interferometer that reflects half of the infrared radiation and transmits the other half.

Beer's law The law stating that the absorbance is linearly proportional to the concentration of the gas (see page 13).

Detector The component that measures the intensity of the infrared radiation and converts this value into electrical signal.

Fourier transform (FT)

The mathematical algorithm to get spectral data out of the interferogram. The algorithm transforms the intensity as a function of time values to intensity as a function of wavelength.

Infrared (IR) Electromagnetic radiation that has wavelengths ranging from 0.75 µm to 1000 µm (14000 - 10 cm-1).

Interferogram The measured intensity as a function of optical path length difference

Interferometer The device that produces interference signal of the infrared radiation.

Noise Detected signals that do not come from the sources that we actually want to measure.

Reference spectrum

A spectrum that is used as a known reference when determining the concentrations of unknown gas components.

Resolution The degree to which different frequencies can be distinguished from each other.

Signal-to-noise ratio (SNR)

The ratio of the amplitude of the actual measured signal to the amplitude of the noise at the same point.

Spectrum A graph that shows the transmission of the infrared radiation through the gas as a function of wavelength

Transmittance The ratio of the infrared radiation transmitted through the sample gas to the amount of the infrared radiation entering the sample gas.

Wavelength Another form of expressing the frequency of the infrared radiation: the distance between two peaks in the oscillation.

Wave number Number of wavelengths in a centimetre. For example, if the wavelength is 10 µm, the corresponding wave number is 1000 cm-1.

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APPENDIX B: GASMET SALES AND SUPPORT OFFICES

Manufacturer Gasmet Technologies Oy

Pulttitie 8 00880 Helsinki

FINLAND

Tel. (+358) 9 7590 0400 Fax (+358) 9 7590 0435

[email protected]

Subsidiary in North America Gasmet Technologies Inc.

956A The Queensway Toronto, Ontario, M8Z 1P5

CANADA

Tel: +1 866-685-0050 [email protected]

Subsidiary in Asia Gasmet Technologies (Asia) Ltd.

Unit 1, 7/F, Fook Hong Industrial Building,

No. 19 Sheung Yuet Road, Kowloon Bay

Kowloon HONG KONG

Tel: +852 3568-7585 Fax: +852 3568-4600

[email protected]

Distributors Please see our website at http://www.gasmet.com