FR3022999A1 - OPTICAL CHAMBER FOR GAS DETECTION DEVICE - Google Patents

Abstract

The invention relates to an optical chamber (4) for a gas detection device which comprises reflection means for reflecting a radiation (R) coming from a radiation source (1) and for sending it back to a detector (2) of radiation, the reflection means comprising a first series of adjacent mirrors (Mi) and a second series of adjacent mirrors (M'i). The mirrors (Mi) of the first series and the mirrors (M'i) of the second series are of ellipsoid type of truncated revolution. The first series of mirrors and the second series of mirrors are arranged relative to one another so that the radiation emitted by the radiation source (1) is reflected alternately by a mirror (M'i) of the second series and mirror (Mi) of the first series and define an optical path from the radiation source (1) to the radiation detector (2).

Description

TECHNICAL FIELD OF THE INVENTION The present invention relates to an optical chamber for a gas detection device and to a gas detection device integrating said optical chamber. The invention particularly relates to an NDIR type gas detection device (for "Non-Dispersive lnfrared"). State of the art It is known from patent EP1987346B1 a gas detection device comprising a radiation source arranged to emit light radiation, a radiation detector and reflection means forming an optical chamber in which are sent the emitted light radiation. The reflection means comprises a plurality of adjacent reflective surfaces which are arranged such that each radiation emitted by the source is returned directly to the detector by one of the reflecting surfaces. The reflective surfaces are each defined by an arc having a radius and a center. Another solution is described in patent application EP2526404A1. In this solution, radiation emitted by the radiation source follows an optical path to the detector through an optical guide. Compared with the previous patent, this solution has the advantage of lengthening the optical path and therefore increasing the sensitivity of the device. However, it requires particular attention in the positioning of the radiation source and the detector with respect to the optical guide. The least displacement of the components substantially modifies the signal obtained at the output and therefore the accuracy of the device.

The object of the invention is to provide an optical chamber for gas detection device allowing the device to have a very satisfactory sensitivity, without increasing its size. The device of the invention including said optical chamber will be particularly insensitive to the relative movements of the radiation source and the detector relative to the optical chamber. SUMMARY OF THE INVENTION This object is achieved by an optical chamber for a gas detection device comprising reflection means for reflecting radiation from a radiation source and for returning it to a radiation detector. The reflection means comprising a first series of adjacent mirrors and a second series of adjacent mirrors. The mirrors of the first series and the mirrors of the second series are bifocal. The first series of mirrors and the second series of mirrors are arranged relative to each other so that the radiation emitted by the radiation source is reflected alternately by a mirror of the second series and by a mirror of the first series and defines an optical path from the radiation source to the radiation detector. According to the invention, for n mirrors in the second series and n-1 mirrors in the first series, with n greater than or equal to three, the mirrors are arranged so that: a mirror M'i of the second series is arranged to focusing the radiation towards a mirror M'i of the first series, the mirror Mi being located at the focus of the mirror M'i of the second series, i being between 1 and n-1, a mirror Mi of the first series is arranged for focusing the radiation towards a mirror M'i + 1 of the second series, i being between 1 and n-1, a mirror M'i of the second series, with i = n, is arranged to focus the radiation towards the detector, a mirror M'i of the second series, with i = 1, is arranged to receive the radiation from the radiation source.

Advantageously, the mirrors of the first series and the mirrors of the second series are of ellipsoidal type of truncated revolution. According to another feature, the mirrors are arranged so that the optical path followed by the radiation follows a circular path.

According to another feature, the chamber comprises two parts fixed one on the other, a lower part in which are made the mirrors of the first series and an upper part assembled on the lower part and in which are made the mirrors of the second series. According to another feature, the mirrors of the first series and the mirrors of the second series have an ellipsoidal shape and each ellipsoid shape is obtained by molding in the first part and the second part of the optical chamber. According to another feature, each mirror has a reflective surface formed by depositing a reflective layer on the ellipsoid shape.

According to another feature, the reflective layer is deposited by PVD or by electrolysis and comprises for example gold. According to another feature, the optical chamber is intended to be located vis-à-vis the radiation source and an output intended to be located vis-à-vis the radiation detector. The invention also relates to a detection device comprising a radiation source arranged to emit radiation, a radiation detector and an optical chamber in which the gas to be analyzed is located and arranged to transmit radiation from the radiation source to the detector. of radiation, the optical chamber being as defined above. According to a feature of the device, the radiation source and the radiation detector are arranged next to each other. According to another feature, the radiation source and the radiation detector are fixed on the same electronic card.

According to another feature, the radiation source comprises at least one light emitting diode. According to another feature, the radiation detector comprises at least one photodiode.

BRIEF DESCRIPTION OF THE FIGURES Other features and advantages will appear in the following detailed description with reference to the accompanying drawings, in which: FIG. 1 is an exploded and perspective view of the detection device of the invention, FIG. 2 represents in perspective the lower part of the optical chamber of the device, Figure 3 schematically illustrates the operating principle of the device of the invention.

DETAILED DESCRIPTION OF AT LEAST ONE EMBODIMENT The invention relates to an optical chamber for a gas detection device and the corresponding gas detection device. The detection device is intended to determine the concentration of a gas, such as for example carbon dioxide.

With reference to FIG. 1, such a device comprises a radiation source 1 comprising, for example, at least one light-emitting diode and arranged to emit radiation (R, FIG. 3).

The device also comprises a radiation detector 2 arranged to detect the radiation emitted by the source 1. The detector 2 comprises, for example, at least one photodiode intended to capture the radiation emitted by the source 1 and transform it into an electrical signal to be processed. . Advantageously, the radiation source 1 and the detector 2 are fixed on an electronic card 3 integrated in the device. Ideally, the radiation source and detector are positioned on the map next to each other. The device also comprises a closed optical chamber 4, inside which the radiation R is emitted. The optical chamber 4, which is the subject of the invention, comprises an input 40 in front of which the radiation source 1 is positioned and an output 41 in front of which is positioned the detector 2 (FIG. 2) The optical chamber 4 comprises reflection means arranged to reflect the radiation R emitted by the source 1 and make it converge towards the detector 2.

According to the invention, the reflection means comprise a first series of adjacent mirrors Mi and a second series of adjacent mirrors M'i. The first series of mirrors Mi and the second series of mirrors M'i are arranged so that the radiation R emitted by the source 1 is reflected and focused alternately by a mirror of the second series and then by a mirror of the first series of following a zigzag-shaped optical path from the radiation source 1 to the detector 2. To achieve this result, the optical chamber employs bifocal mirrors. Each mirror thus comprises, if one follows the optical path, a first focus located upstream of the mirror and a second focus located downstream of the mirror. FIG. 3 illustrates this principle: the radiation source 1 emits radiation towards a first mirror M'1 of the second series, the radiation source 1 being located at the first focus of the first mirror M'1 of the second series . the first mirror M'l of the second series reflects the received radiation R and focuses it to a first mirror M1 of the first series located at the second focus of the first mirror M'l of the second series. the first mirror M1 of the first series reflects the received radiation R and focuses it towards a second mirror M'2 of the second series, distinct from the first mirror M'1 of the second series and located at the second focus of the first mirror M1 of the first series (the first mirror M'l of the second series occupying the first focus of the first mirror M1 of the first series), the second mirror M'2 of the second series reflects the received radiation R and focuses it to a second mirror M2 of the first series, distinct from the first mirror M1 of the first series and located at the second focus of the second mirror M'2 of the second series (the first mirror M1 of the first series occupying the first focus of the second mirror M'2 of the second second series). The process described above continues between mirrors of the first series and mirrors of the second series until the radiation reaches the detector 2. The mirrors are thus arranged to advance the radiation inside the optical chamber. from the radiation source 1 to the detector 2. The use of bifocals makes it possible to focus the radiation from the source to the detector and thus obtain a device of great sensitivity. In a general way, for n mirrors in the second series and n-1 mirrors in the first series, with n greater than or equal to three, we can write that: a mirror M'i of the second series focuses the radiation R towards a mirror Mi of the first series, the mirror Mi being located at the focus of the mirror M'i of the second series, i being between 1 and n-1, a mirror Mi of the first series focuses the radiation R towards a mirror M i + 1 of the second series, i being between 1 and n-1, a mirror M'i of the second series, with i = n, focuses the radiation R towards the detector, - a mirror M'i of the second series, with i = 1, receives radiation from the radiation source.

Advantageously, the bifocals used in the first series and in the second series are ellipsoid truncated revolution type. The ellipsoid shape of truncated revolution gives the mirror the property of having two foci, which makes it possible, thanks to the arrangement of the invention, to focus a maximum of the radiation on the detector 2 and to limit the bounces inside the the optical chamber 4. Preferably, the first mirror M'l of the second series is oriented so as to focus the radiation towards the first mirror M1 of the first series while being in line with the radiation source 1 and having the radiation source 1 located at its first focus. Preferably, the last mirror M'n is located directly above the detector 2 and is oriented so as to focus the radiation coming from the mirror Mn-1 of the first series towards the detector 2, the detector being located at its second focus. Each mirror is for example made by depositing a reflective layer on a piece of plastic material. The reflective layer is for example a layer of gold deposited by PVD ("Physical Vapor Deposition") or by electrolysis. Advantageously, the optical chamber 4 is formed of two distinct parts 42, 43 attached to one another, an upper portion 43 being fixed on a lower portion 42 so as to obtain a closed optical chamber. A screw 44 is for example provided for fixing the two parts together. The mirrors Mi of the first series are formed in the lower part 42 and the mirrors M'i of the second series are formed in the upper part 43. The lower part 42 has a first opening forming said input 40 of the radiation and a second opening forming said output 41 of the radiation R. Preferably, the ellipsoid shape of the mirrors is obtained by molding in the first portion 42 and in the second portion 43 of the optical chamber. According to the invention, the mirrors Mi, M'i of the first series and of the second series are arranged so that the radiation follows a circular optical path inside the chamber. This arrangement makes it possible in particular to obtain an optical path that is as long as possible while limiting the size of the device. According to the invention, the optical chamber 4 is fixed directly, by its first part 42, on the electronic card 3 so that the radiation source 1 and the detector 2 is in vis-à-vis respectively of the input 40 of the optical chamber and the output 41 of the optical chamber.

The device may comprise integrated processing means (not shown) making it possible to analyze the electrical signal obtained at the output of the detector 2 with respect to the signal emitted by the source 1 in order to deduce therefrom the concentration of the gas present in the optical chamber. 3. These processing means may also be independent of the device and separated therefrom. The solution of the invention thus has several advantages listed below: the device is particularly compact, while allowing to propose an optical path long enough to make the device accurate, the signal obtained at the output is relatively insensitive to the relative movements of the source and the detector with respect to the entrance and the exit of the optical chamber, control of the number of rebounds undergone by the radiation, these bounces attenuating the optical signal transmitted to the detector, low electrical consumption due in particular to the use of a light emitting diode.

Claims (15)

REVENDICATIONS1. An optical chamber (4) for a gas detection device comprising: reflection means for reflecting radiation (R) from a radiation source (1) and for returning it to a radiation detector (2), characterized in that that: the reflection means comprise a first series of adjacent mirrors (Mi) and a second series of adjacent mirrors (M'i), the mirrors (Mi) of the first series and the mirrors (M'i) of the second series The first series of mirrors and the second series of mirrors are arranged with respect to one another so that the radiation emitted by the radiation source (1) is reflected alternately by a mirror (M '). i) of the second series and by a mirror (Mi) of the first series and defines an optical path from the radiation source (1) to the radiation detector (2). 2. Optical chamber according to claim 1, characterized in that, for n mirrors in the second series and n-1 mirrors in the first series, with n greater than or equal to three, the mirrors are arranged so that: a mirror M i of the second series is arranged to focus the radiation to a mirror M'i of the first series, the mirror Mi being located at the focus of the mirror M'i of the second series, i being between 1 and n-1, a mirror Mi of the first series is arranged to focus the radiation towards a mirror M'i + 1 of the second series, i being between 1 and n-1, a mirror M'i of the second series, with i = n , is arranged to focus the radiation towards the detector, a mirror M'i of the second series, with i = 1, is arranged to receive radiation from the radiation source. 3. Optical chamber according to claim 1 or 2, characterized in that the mirrors (Mi) of the first series and the mirrors (M'i) of the second series are ellipsoid type truncated revolution. 4. Optical chamber according to one of claims 1 to 3, characterized in that the mirrors are arranged so that the optical path followed by the radiation (R) follows a circular path. 5. Optical chamber according to one of claims 1 to 4, characterized in that it comprises two parts fixed to one another, a lower portion (42) in which are formed the mirrors (Mi) of the first series and an upper part (43) assembled on the lower part and in which are made mirrors (M'i) of the second series. 6. Optical chamber according to claim 5, characterized in that the mirrors (Mi) of the first series and the mirrors (M'i) of the second series have an ellipsoid shape and in that each ellipsoid shape is obtained by molding in the first portion (42) and the second portion (43) of the optical chamber. 7. Optical chamber according to claim 6, characterized in that each mirror comprises a reflective surface formed by depositing a reflective layer on the ellipsoid shape. 8. Optical chamber according to claim 7, characterized in that the reflective layer is deposited by PVD or electrolysis. 9. Optical chamber according to claim 7 or 8, characterized in that the reflective layer comprises gold. 10. Optical chamber according to one of claims 1 to 9, characterized in that it comprises an inlet (40) intended to be located vis-à-vis the radiation source and an outlet (41) intended to be located opposite the radiation detector. 11. Detection device comprising a radiation source (1) arranged to emit radiation (R), a radiation detector (2) and an optical chamber (4) in which the gas to be analyzed is located and arranged to transmit the radiation (R) from the radiation source to the radiation detector (2), characterized in that the optical chamber (4) is as defined in one of claims 1 to 9. 12. Device according to claim 11, characterized in that the radiation source (1) and the radiation detector (2) are arranged next to each other. 13. Device according to claim 12, characterized in that the radiation source (1) and the radiation detector (2) are fixed on the same electronic card (3). 14. Device according to one of claims 11 to 13, characterized in that the radiation source (1) comprises at least one light emitting diode. 15. Device according to one of claims 11 to 14, characterized in that the detector (2) of radiation comprises at least one photodiode.5