NL8303954A - DEVICE FOR SELECTIVE MEASUREMENT OF AN INFRARED RADIATION ABSORBING COMPONENT OF A MIXTURE. - Google Patents

Description

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Device for selectively measuring an infrared radiation absorbing component of a mixture.

The invention relates to a device for selectively measuring an infrared radiation-absorbing component of a mixture, wherein the mixture is periodically irradiated by radiation pulses from a radiation source.

Such devices are necessary for high sensitivity gas analyzers in the field of high-resolution spectroscopy, which continuously monitor, for example, the composition of off-gas streams or the occurrence of certain gas components therein, and in particular in process engineering and for the application of measures to protect the environment are gaining in importance.

The hitherto available thermal light sources 15 in the infrared spectral region have a number of drawbacks, in particular consisting of the fact that the spectral emission takes place in a broadband region *

On the one hand, this drawback has the result that in many optical systems too low signal-to-noise ratios are obtained, and on the other hand undesirable light wavelengths are present in the emission spectrum, which lower the selectivity.

An opto-electronic gas analysis device is known (BMFT-Forschungsbericht T 81-209), in which the concentration of an IR active gas is determined using a pulsed driven diode laser.

However, these laser systems that can be used in many applications have disadvantages, which in particular consist in that the system tends to become instable with regard to frequency and amplitude, that gaps in the emission spectrum occur, and that considerable investment costs are required. . In addition, in the infrared region of longer waves, expensive cooling units are required for the operation of the diode laser.

The object of the invention is to develop an apparatus which generates periodic radiation pulses of a high radiation intensity and preferably emits the vibration-rotation line spectrum characteristic of certain gases. According to the invention a device is provided for this purpose, as described in the preamble, characterized in that an all-round closed cylinder, which has a piston freely movable in the direction of the axis of the cylinder, is filled with a gas or a gas mixture , which is periodically compressed by the oscillating piston and heated adiabatically during the compression phase and excited to emit a rotational vibration spectrum, and the cylinder having at least one radiation exit window.

The advantages achieved with the proposed device consist in particular of the fact that, with simple means and little energy expenditure, radiation pulses of high emissivity and spectral selectivity are obtained, which are free from the occurrence of disturbances as a result of chopper devices for short interruption of the beam, and whose pulse frequency and amplitude can be set with great accuracy to a fixed value and kept constant with little effort.

The design can expediently be such that the piston is moved by a device for generating electromagnetic forces acting on the piston.

A more specific embodiment is characterized in that a) the all-round closed cylinder consists of a non-magnetic material and the piston of a ferromagnetic material, b} at least one of the two ends of the cylinder is enclosed by a magnetic coil, of which the magnetic alternating field acts on the piston and effects its movement in the direction of the axis of the cylinder, and c). each of the magnet coils is connected to the output of a control device which supplies the magnet coils 40 with an alternating voltage, the height and frequency of which are adjustable 8303954 **, e * - 3.

The design can further be such that a screw spring 5 engaging the piston against tilting is engaging on each of the two free front surfaces of the piston.

In the device according to the invention it is particularly expedient that the optical window of the cylinder is designed as an optical filter filtering out spectral regions.

In order to obtain the most favorable temperature for measuring the emissive gas, the design can further be such that the emissive gas is mixed with a non-emissive additive gas, whose adiabatic coefficient at a fixed compression ratio ensures such high possible temperature increase.

The inner surface of the cylinder can furthermore advantageously be radiation-reflecting.

The invention will now be further elucidated on the basis of an exemplary embodiment, in which the features given above are shown with reference to the drawing. In the drawing: Fig. 1 shows a device for measuring at least one component of a gas mixture with a selective radiation source, and Fig. 2 shows a selective radiation source in simplified view without a cooling device.

The basic structure of an infrared analyzer using the proposed radiation source is shown in Fig. 1. The radiation emitted periodically by a selective radiation source 1 in the form of radiation pulses is transmitted by a first lens system 2, an optical wide-band filter 3, which filters out the major part of the radiation frequency not required for the absorption measurements 35, a measuring cuvette 4, through which the measuring gas flows, and whose gas pressure is measured with a pressure gauge 5 ', and a second lens system 6 on a thermal or opto-electronic detector 7 behind which a 40 electronic measured value processing for forming 8 3 0 3 9 5 4 4> - 4 - the ratio of measuring radiation to reference radiation is connected. The selective radiation source 1 is fed from a control device 9 with an alternating voltage, the amplitude and / or frequency of which can be set to fixed values. A reference cuvette 4a is arranged parallel to the measuring cuvette 4.

The radiation passing through the reference cuvette is conducted onto a reference detector 7a.

The formation of a reference signal is also possible in a known manner according to the irradiation bi-frequency principle, when the cylinder 10 is filled with a gas mixture, whereby part of the emitted spectrum is not absorbed by the mixture to be analyzed.

When using a radiation source with time-constant radiation instead of the selective radiation source 1, it is required to provide a filter wheel, which is driven by a stepper motor, between the first lens system 2 and the wide-band filter 3 as chopper in the beam path. and is equipped with gas filters and / or solid interference flashes. This interference sensitive device can be completely dispensed with when the selective radiation source 1 is used.

Such a radiation source 1 is shown in fig. 2 in a simplified representation. In a cylinder 10 of non-magnetic material closed on all sides, a piston 11 consisting of ferromagnetic material is arranged freely movable in the direction of the axis 12 of the cylinder 10. Each of the two ends of the cylinder 10 is enclosed by a magnetic coil 13, the magnetic fields of which act on the piston 11 and effect its movement in the direction of the axis 12 of the cylinder 10. The magnet coils 13 are connected to the output of the control device 9, which supplies the magnet coils 35 with an alternating voltage, the height and frequency of which are adjustable, and which has a phase shift of 180 ° on the magnet coils. The frequency of the alternating voltage is preferably set to the resonance frequency of the vibration-sensitive system consisting of the piston 11 40 and the gas filling of the cylinder 10.

The cylinder 10 is filled with a gas 14, which is periodically compressed and expanded by the piston 11 oscillating in the magnetic alternating field of the magnet coils 13, and is heated adiabatically during the compression phase and excited to produce a rotational vibration spectrum.

At least one of the front surfaces of the cylinder 10 is designed as an optical window 15 for the light emission, and consists of a radiation-transmitting material.

It is also possible to arrange an optical window 15 on each of the two front surfaces of the cylinder 10, and to connect, for example, a measuring device of the construction shown in Fig. 1 behind each of the two optical windows.

A low-friction guiding of the piston 11 is achieved in particular in that on each of the two free front surfaces of the piston 11 a coil spring 16 engages the piston 11 against tilting, and that a material with a small diameter is used for the cylinder 10. friction coefficient, such as Teflon or graphite.

In certain application cases it may be advantageous to design the optical window 15 of the cylinder 10 as a determined spectral region filtering optical filter.

The effectiveness of the radiation source 1 can be increased in a simple manner in that the emitting gas 14 is mixed with a non-emitting additive gas 17, the adiabatic coefficient of which causes the highest temperature increase at a determined compression ratio.

Argon, crypton or helium can be used as additive gases.

It may also be advantageous in certain application cases if the radiation-emitting gas 14 consists of at least two components, and for example a mixture of HF and H2 O or N and CO2 or CO and CO2 is used.

The intensity of the emitted radiation can be increased in a simple manner, because the inner surface of the cylinder 10 is made radiation-reflecting. For example, with a cylinder made of non-magnetic stainless steel, it is possible by high-gloss polishing.

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List reference numbers in the drawing: 1. Selective radiation source 2. First lens system 3. Wide band filter 4. Measuring cuvette 5. Pressure gauge 6. Second lens system 7. Thermal detector 8. Measured value processing 9. Steering for 1 10. Cylinder 11. Piston 12. Axle of 1 13. Solenoid coil 14. Gas in 10 15. Optical window at 10 16. Coil spring 17. Non-emitting additive gas in 10 4a. Reference cuvette 7a. Reference detector.

8303954

Claims (8)

An apparatus for selectively measuring an infrared radiation absorbing component of a mixture, wherein the mixture is periodically irradiated by radiation pulses from a radiation source, characterized in that an all-round closed cylinder (10), which in the direction of the axis (12) of the cylinder (10) has freely movable piston (11), is filled with a gas (14) or a gas mixture, which is periodically compressed by the oscillating piston (11) and during the compression phase is heated adiabatically and excited to emit a rotational vibration spectrum, and that the cylinder (10) has at least one window (15) for the radiation to exit. 2. Device according to claim 1, characterized in that the piston (11) is moved by a device for generating electromagnetic forces acting on the piston (11). Device according to claim 1, characterized in that a) the all-round closed cylinder (10) consists of a non-magnetic material and the piston (11) of a ferromagnetic material, b) at least one of the two ends of the cylinder (10) is enclosed by a magnetic coil (13), the magnetic field of which acts on the piston (11), and its movement in the direction of the axis (12) of the cylinder (10), and c each of the magnet coils (13) is connected to the output of a control device (9), which feeds the magnet coils (13) with an alternating voltage, the height and frequency of which are adjustable. 4. Device according to claim 1, characterized in that a screw spring (16) engages the piston (11) against the tilting piston (11) on each of the two free front surfaces 8303954-9 of the piston (11). 5. Device according to claim 1, characterized in that the optical window (15) of the cylinder (10) is designed as a determined spectral regions filtering out optical filter. 6. Device according to claim 1, characterized in that the emissive gas (14) is mixed with a non-emissive additive gas (17), whose adiabatic coefficient ensures the highest possible temperature increase at a determined compression ratio. 7. Device according to claim 1, characterized in that the radiation-emitting gas (14) consists of at least two components. 8. Device as claimed in claim 1, characterized in that the inner surface of the cylinder (10) is radiation-reflecting, 8303954