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Title:
GAS SENSOR
Document Type and Number:
WIPO Patent Application WO/2018/115076
Kind Code:
A1
Abstract:
The invention relates to a gas sensor (1), in particular an oxygen sensor, which gas sensor comprises: • - a gas chamber (2) with a supply opening (3) and a discharge opening (4) positioned opposite of the supply opening (3), such that gas can flow through the gas chamber (2); • - magnetic field means (5) for providing a magnetic field in the gas chamber (2); • - a light source (6) generating a light beam (7), which light beam extends through the gas chamber (2); and • - a detector (8) for detecting the light beam, which detector (8) is arranged opposite of the light source (7).

Inventors:
MASSEY ALAN (GB)
SHINDE YOGESH (IN)
Application Number:
PCT/EP2017/083733
Publication Date:
June 28, 2018
Filing Date:
December 20, 2017
Export Citation:
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Assignee:
EATON LTD (GB)
International Classes:
G01N21/61; G01N21/17; G01N21/21; G01N21/3504
Foreign References:
DE102009008624A12010-08-26
US20110248178A12011-10-13
EP1217369A12002-06-26
Other References:
BRECHA R J: "NONINVASIVE MAGNETOMETRY BASED ON MAGNETIC ROTATION SPECTROSCOPY OFOXYGEN", APPLIED OPTICS, OPTICAL SOCIETY OF AMERICA, WASHINGTON, DC; US, vol. 37, no. 21, 20 July 1998 (1998-07-20), pages 4834 - 4839, XP000769798, ISSN: 0003-6935, DOI: 10.1364/AO.37.004834
XIAODONG XU: "THE FARADAY EFFECT AND DISPERSION IN LIQUIDS", October 2014 (2014-10-01), XP055457811, Retrieved from the Internet [retrieved on 20180308]
KOJI MOTOMURA ET AL: "High-resolution spectroscopy of hyperfine Zeeman components of the sodium D_1 line by coherent population trapping", JOURNAL OF THE OPTICAL SOCIETY OF AMERICA - B., vol. 19, no. 10, October 2002 (2002-10-01), US, pages 2456 - 6320, XP055475973, ISSN: 0740-3224, DOI: 10.1364/JOSAB.19.002456
Attorney, Agent or Firm:
EATON IP GROUP EMEA (CH)
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Claims:
Claims

1. Gas sensor, in particular an oxygen sensor, which gas sensor comprises:

- a gas chamber with a supply opening and a discharge opening, such that gas can flow through the gas chamber;

- magnetic field means for providing a magnetic field in the gas chamber;

- a light source generating a light beam, which light beam extends through the gas chamber; and

- a detector for detecting the light beam, which detector is arranged opposite of the light source.

2. Gas sensor according to claim 1, wherein the light beam extends through the magnetic field.

3. Gas sensor according to claim 2, wherein the detector is a photo diode for detecting the intensity of the light beam.

4. Gas sensor according to claim 3, wherein a second photo diode is provided, which second photo diode detects the intensity of the light beam upstream of the magnetic field.

5. Gas sensor according to any of the claims 2 - 4, wherein the magnetic field means comprise at least two electromagnets arranged on opposite sides of the gas chamber and parallel to the light beam.

6. Gas sensor according to claim 2, wherein the detector is a wave length detector for detecting the wave length of the light beam.

7. Gas sensor according to claim 1, wherein the light source provides a polarized light beam having a wavelength equal to the maximum absorption wavelength of the gas to be sensed with a maximum deviation of 10% and wherein the detector comprises a polarization detector to detect a change in the polarization of the light beam.

8. Gas sensor according to claim 1, wherein an optical grating, which is sensitive for changes in density of the gas in the gas chamber, is provided in the gas chamber, wherein the light beam is directed to the optical grating and wherein the detector comprises a light beam position sensor, which is arranged opposite of the optical grating for detecting the diffracted light spot position.

9. Gas sensor according to claim 8 further comprising control means for controlling the magnetic field means such that a standing pressure wave is generated in the gas chamber.

Description:
Gas sensor

The invention relates to a gas sensor, in particular an oxygen sensor. Gas sensors are used in a number of applications, such as in consumer, industrial, automotive and aerospace applications to monitor concentration of various gases. Monitoring of the 02 concentration is a common requirements among wide applications like, healthcare, HVAC systems, Hazardous areas, fuel tank systems etc.

However, oxygen sensors, especially known as lambda sensors require a high gas temperature, typically over 400°C, for the sensor to work. Those temperatures could provide a risk in certain processes and is not always suitable.

It is an object of the invention to provide a gas sensor, which can function at lower temperatures, especially at room temperature.

This object is achieved according to the invention with a gas sensor, in particular an oxygen sensor, which gas sensor comprises:

- a gas chamber with a supply opening and a discharge opening, such that gas can flow through the gas chamber;

- magnetic field means for providing a magnetic field in the gas chamber;

- a light source generating a light beam, which light beam extends through the gas chamber; and

- a detector for detecting the light beam, which detector is arranged opposite of the light source.

Some gases, like oxygen, exhibit paramagnetic properties when subjected to a magnetic field. These paramagnetic properties result in a local change in density or concentration of the gas at the position of the magnetic field.

With the invention a gas, showing paramagnetic properties, is subjected to a magnetic field and by using a light beam and detector for detecting the light beam, one can measure the change between the light beam when no magnetic field is present and when a magnetic field is present. Based on the difference one can calculate the concentration of the gas in the gas sensor.

In a preferred embodiment of the gas sensor according to the invention, the light beam extends through the magnetic field. As the density of the gases changes in the magnetic field, the light beam will be subjected to this change in density, which can be detected by the detector.

Preferably, the detector is a photo diode for detecting the intensity of the light beam. When the density of the gas increases, more of the light beam will be absorbed and less light will hit the photo diode. So by measuring the intensity of the light beam without a magnetic field and then measuring the intensity of the light beam with the magnetic field by the photo diode will result in a value, which corresponds to the concentration of gas in the gas chamber.

In another embodiment of the gas sensor according to the invention a second photo diode is provided, which second photo diode detects the intensity of the light beam upstream of the magnetic field.

With the second photo diode, the magnetic field can remain constant and does not need to be alternatingly switched on and off, in order to obtain a reference signal and a signal influenced by the concentration of the gas. The difference between the reference signal of the second photo diode and the photo diode of the detector will provide a constant indication of the concentration of gas flowing through the gas chamber.

In another preferred embodiment of the gas sensor according to the invention the magnetic field means comprise at least two electromagnets arranged on opposite sides of the gas chamber and parallel to the light beam.

By alternatingly switching one or the other electromagnet on and off, an oscillation in the output of the photo diode is achieved, which provides an indication for the concentration of the gas in the gas chamber.

Another option is to have a light beam extending through a hollow electromagnet, and by turning on and off said electromagnet a similar oscillation in the output of the photo diode can be obtained out of which the concentration of the gas can be derived.

In yet another embodiment of the gas sensor according to the invention, the detector is a wave length detector for detecting the wave length of the light beam.

When the magnetic field is oscillated, the wavelength of the light beam will be changed due to the oscillation in the density of the gas in the gas chamber. This change in wavelength provides again an indication for the concentration of the gas in the gas chamber.

In yet another embodiment of the gas sensor according to the invention the light source provides a polarized light beam having a wavelength matching to the absorption wavelength of the gas to be sensed with a maximum deviation of 10% and wherein the detector comprises a polarization detector to detect a change in the polarization of the light beam.

When the magnetic field is provided, the gas will exhibit its paramagnetic properties and accordingly change the orientation of the polarized light beam, which can be detected by the detector. For an efficient detection of the concentration of the gas in the gas chamber, the wavelength of the light beam should be in the same range as the maximum absorption wavelength of the gas, which should be detected by the sensor.

In yet another embodiment of the gas sensor according to the invention an optical grating, which is sensitive to changes in density of the gas in the gas chamber, is provided in the gas chamber, wherein the light beam is directed to the optical grating and wherein the detector comprises a light beam position sensor, which is arranged opposite of the optical grating.

Because the optical grating is sensitive to changes in the density of the gas in the gas chamber, the optical grating will change and the light beam directed to the optical grating will be diffracted. The angle of the light beam exiting from the optical grating thus changes which can be detected by the light beam position sensor. The amount of deviation of the position of the light beam provides an indication for the concentration of gas in the gas chamber.

The optical grating could be an acousto-optic crystal. By changing the magnetic field in the gas chamber, the density of the gas will change generating a pressure wave in the gas or an acoustic signal, which will be picked up by the acousto- optic crystal. As a result, the optical grating formed by the acousto-optic crystal will change depending on the pressure wave picked up by the crystal.

Yet another embodiment of the gas sensor according to the invention further comprising control means for controlling the magnetic field means such that a standing pressure wave is generated in the gas chamber.

The standing pressure wave will provide zones of high density and low density in the gas present in the gas chamber and as a result these alternating zones of high density and low density will provide an optical grating.

These and other features of the invention will be elucidated in conjunction with the accompanying drawings.

Figure 1 shows a schematic view of a first embodiment of a gas sensor according to the invention.

Figure 2 shows a schematic view of a second embodiment of a gas sensor according to the invention.

Figure 3 shows a schematic view of a third embodiment of a gas sensor according to the invention.

Figure 1 shows a first embodiment 1 of a gas sensor according to the invention. The gas sensor 1 has a gas chamber 2 with a supply opening 3 and a discharge opening 4 arranged opposite of the supply opening 3. This allows for a gas flow of gas G through the gas chamber 2.

An electrical coil 5 is arranged in the gas chamber 5. The electrical coil 5 is supplied with an alternating current, such that a magnetic field is generated in the gas chamber 2.

A laser 6 generates a light beam 7, which extends through the gas chamber 2 and after exiting the gas chamber 2 the light beam is incident on a sensor 8. This sensor 8 could be a photo diode, which registers the intensity of the light beam 7 or which registers the wave length of the light beam 7. When a paramagnetic gas flows through the gas chamber 2, the magnetic field generated by the coil 5 ensures that the density of the gas changes, which has an effect on the amount of absorption of the light beam and / or the wavelength and / or the polarization of the light beam.

Figure 2 shows a second embodiment 10 of a gas sensor according to the invention. The gas sensor 10 has a gas chamber 11 with a supply opening 12 and a discharge opening 13. Two electromagnets 14, 15 are arranged on opposite sides of the gas chamber 11.

A laser 16 generates a light beam 17, which is incident on a partial transparent mirror 18 to obtain two light beams 19, 20. The light beam 19 is deflected and hits a first photo diode 21 to provide a reference signal. Such a reference signal photo diode can also be applied to the embodiment of figure 1. The second light beam 22 extends straight through the gas chamber 11 and is incident on the second photo diode 22.

By alternating switching on and off the two electromagnets 14, 15 an oscillation will be generated in the signal generated by the photo sensor 22. The amplitude of this oscillation is a measure for the concentration of the gas G flowing from the supply opening 12 through the gas chamber 11 to the discharge opening 13.

Figure 3 shows a third embodiment 30 of a gas sensor according to the invention. The gas sensor 30 has a gas chamber 31 with a supply opening 32 and a discharge opening 33.

An electrical coil 34 is arranged in the gas chamber 31. The electrical coil 34 is supplied with an alternating current to provide a magnetic field. By controlling the current supplied to the electrical coil 34, a pressure wave 35 can be generated in the gas.

An acousto-optic crystal 36 is provided downstream of the coil 34. This acousto-optic crystal 36 provides a changing optical grating depending on the incident pressure wave 35.

A laser 37 further generates a light beam 38, which is incident on the acousto-optic crystal 36, which will diffract the light beam 39, such that the angle of the light beam 39 is changed. With the position sensor 38 this angle of the light beam 39 can be determined and provides an indication for the strength of the pressure wave 35. Because the pressure wave 35 is the result of the paramagnetic properties of the gas G subjected to the magnetic field generated by the coil 34, it also provides an indication for the concentration of the gas G.