CN212364066U - Optical path adjustable gas absorption cell and gas detection device - Google Patents

Abstract

The utility model discloses an optical path adjustable gas absorption cell and a gas detection device, wherein the optical path adjustable gas absorption cell comprises an air chamber, a guide mechanism, an installation block, a reflector group and a driving mechanism, and the guide mechanism comprises a fixed block and a guide rod; the mounting block is sleeved on the guide rod; the reflector group is fixed on the mounting block; the driving mechanism is connected with the mounting block. The utility model provides a technical scheme's beneficial effect is: the plurality of light input ports are arranged on the side wall of the air chamber, the reflector group sequentially reaches positions corresponding to the light input ports through the driving mechanism, if laser beams with different wavelengths are input into the light input ports, the wavelengths respectively correspond to the absorption wavelength of a gas to be detected, the concentration of various gases to be detected can be detected simultaneously, if laser beams with the same wavelength are input into the light input ports, the optical path of the emitted laser beams can be changed by adjusting the position of the reflector group, and the minimum optical path of a certain gas reaching certain testing precision is tested.

Description

Optical path adjustable gas absorption cell and gas detection device

Technical Field

The utility model belongs to the technical field of gaseous detection technique and specifically relates to an adjustable gas absorption cell of optical path and gaseous detection device are related to.

Background

The gas detection device based on the TDLAS technology combines high and new technologies such as optoelectronics, spectroscopy, weak signal processing and the like. Compared with the traditional gas sensor device (an electrochemical method, a meteorological chromatography method, an adsorption method and the like), the device has the characteristics of higher sensitivity, more accurate measurement data, higher response speed, online real-time measurement and the like. And the test tasks under different environments are completed through the selection of the replaceable air chamber. And the detection of the customized gas (H2O, NO, CH4, FH, etc.) can be performed according to the customer's requirements.

Most of existing gas detection devices based on the TDLAS technology can only detect the concentration of a certain specific gas, but cannot detect multiple gases simultaneously, and are large in limitation; in addition, for a specific gas in the gas chamber, theoretically, the larger the optical distance of the laser beam passing through the gas chamber is, the higher the gas detection accuracy is, but the gas chamber with a long optical distance is expensive, so that it is necessary to test the minimum optical distance (for convenience of description, it is called as an optimal optical distance) of the gas to be detected to reach a certain test accuracy, however, at present, the optical distance of the laser beam in the gas chamber of most gas detection devices based on the TDLAS technology cannot be adjusted, so that the optical distance of the laser beam cannot be adjusted to the optimal optical distance according to specific situations.

SUMMERY OF THE UTILITY MODEL

In view of the above, there is a need for a gas detection device that can detect multiple gases simultaneously and has an adjustable optical path, thereby facilitating adjustment of the optical path of the laser beam in the gas chamber to an optimal optical path.

In a first aspect, the present invention provides an optical path adjustable gas absorption cell, including: an air chamber, a guide mechanism, a mounting block, a reflector group and a driving mechanism,

the air chamber is provided with a long absorption cavity, the side wall of the air chamber is provided with a plurality of light input ports communicated with the absorption cavity along the length direction of the air chamber, the top wall or the bottom wall of the air chamber is provided with a light receiving port communicated with the absorption cavity, and the air chamber is also provided with an air inlet and an air outlet communicated with the absorption cavity;

the guide mechanism comprises a fixed block and a guide rod, the fixed block is positioned in the absorption cavity and fixed on the inner wall of the air chamber, the guide rod is positioned in the absorption cavity and fixed on the fixed block, and the guide rod extends along the length direction of the air chamber;

the mounting block is provided with a slotted hole matched with the guide rod, and the mounting block is sleeved on the guide rod and can slide along the guide rod;

the reflector group is fixed on the mounting block and is used for reflecting the laser beam incident from the light input port at least once so as to enable the laser beam to be emitted from the light receiving port;

the drive mechanism is connected with the mounting block and is used for moving the mounting block.

In a second aspect, the present invention further provides a gas detection device comprising the optical path adjustable gas absorption cell provided by the present invention, a plurality of input devices and a receiving device,

the number of the input devices is the same as that of the light input ports of the optical path adjustable gas absorption cell, and the input devices correspond to the light input ports one by one, and are all installed at the corresponding light input ports and are used for emitting laser beams into the corresponding light input ports;

the receiving device is arranged at a light receiving port of the optical path adjustable gas absorption cell and is used for receiving the laser rays emitted from the light receiving port and detecting the received laser rays.

Compared with the prior art, the utility model provides a technical scheme's beneficial effect is: the plurality of light input ports are arranged on the side wall of the air chamber, the reflector group sequentially reaches the positions corresponding to the light input ports through the driving mechanism, if laser beams with different wavelengths are input into the light input ports, the wavelengths respectively correspond to the absorption wavelengths of a gas to be detected, the concentration of various gases to be detected can be detected simultaneously, if laser beams with the same wavelength are input into the light input ports, the optical path of the emitted laser beams can be changed by adjusting the position of the reflector group, and therefore the minimum optical path of a certain specific gas reaching certain testing precision can be tested.

Drawings

Fig. 1 is a diagram of an embodiment of an optical path adjustable gas absorption cell (with a front cover omitted) provided by the present invention;

FIG. 2 is a front view of the optical path tunable gas absorption cell of FIG. 1;

FIG. 3 is a left side view of the optical path tunable gas absorption cell of FIG. 1;

FIG. 4 is a cross-sectional view taken along section A-A of FIG. 3;

FIG. 5 is a cross-sectional view taken along section B-B of FIG. 3;

in the figure: the device comprises a 1-optical path adjustable gas absorption cell, an 11-gas chamber, a 111-light input port, a 112-light receiving port, a 113-first optical collimator, a 114-second optical collimator, a 115-fixing hole, a 116-sealing groove, a 12-guiding mechanism, a 121-fixing block, a 122-guide rod, a 13-mounting block, a 14-reflector group, a 15-driving mechanism, a 151-lead screw and a 152-stepping motor.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Referring to fig. 1, the present invention provides an optical path adjustable gas absorption cell 1, which includes an air chamber 11, a guiding mechanism 12, a mounting block 13, a reflector group 14 and a driving mechanism 15.

Referring to fig. 1 and 2, the air chamber 11 has a long absorption cavity, a plurality of light input ports 111 communicated with the absorption cavity are formed on a side wall of the air chamber 11 along a length direction of the air chamber 11, a light receiving port 112 communicated with the absorption cavity is formed on a top wall or a bottom wall of the air chamber 11, and an air inlet and an air outlet (not shown) communicated with the absorption cavity are further formed on the air chamber 11. In this embodiment, the light-receiving opening 112 is opened in the bottom wall of the gas chamber 11.

Referring to fig. 2 to 5, the guiding mechanism 12 includes a fixing block 121 and a guide rod 122, the fixing block 121 is located in the absorption cavity and fixed on the inner wall of the air chamber 11, the guide rod 122 is located in the absorption cavity and fixed on the fixing block 121, and the guide rod 122 extends along the length direction of the air chamber 11. In this embodiment, the number of the guide rods 122 is two, the two guide rods 122 are parallel to each other, the number of the fixing blocks 121 is also two, and both ends of the two guide rods 122 are respectively fixed to the two fixing blocks 121.

Referring to fig. 2 to 5, the mounting block 13 is provided with a slot hole matching with the guide rod 122, and the mounting block 13 is sleeved on the guide rod 122 and can slide along the guide rod 122. In this embodiment, the number of the slots is two, and the two guide rods 122 respectively pass through the two slots, so that the mounting block 13 can slide along the guide rods 122.

Referring to fig. 1, 2 and 4, the mirror group 14 is fixed on the mounting block 13 and is configured to reflect the laser beam incident from the light input port 111 at least once, so that the laser beam is emitted from the light receiving port 112. In this embodiment, the reflector group 14 is a single reflector, and the included angle between the reflector surface and the axis of each light input port 111 is 45 °, so that the laser beam incident laterally can be reflected downward. In other embodiments, the reflector assembly 14 may include a plurality of reflectors to increase the optical path of the laser beam, and it should be noted that other embodiments obtained by merely changing the number and arrangement of the reflectors in the reflector assembly 14 fall within the scope of the present invention.

Referring to fig. 1 and 2, the driving mechanism 15 is connected to the mounting block 13 and is used for moving the mounting block 13.

Specifically, referring to fig. 1 and 2, the mounting block 13 is provided with a screw hole; the driving mechanism 15 comprises a screw rod 151 and a stepping motor 152, the screw rod 151 is in threaded connection with the screw hole, the screw rod 151 is parallel to the guide rod 122, the screw rod 151 is further in rotary connection with the mounting block 13, and the stepping motor 152 is connected with the screw rod 151 and used for driving the screw rod 151 to rotate. When the installation device is used, the stepping motor 152 drives the screw rod 151 to rotate, and the installation block 13 cannot rotate due to the limit of the guide rod 122, so that the rotation of the screw rod 151 is converted into the translational movement of the installation block 13, and the installation block 13 moves along the screw rod 151, thereby driving the reflector group 14 to move.

Specifically, referring to fig. 1, 2 and 4, the number of the light input ports 111 is three, and in other embodiments, the number of the light input ports 111 may also be more than three, which is not limited by the present invention, and each of the light input ports 111 is uniformly arranged on the sidewall of the air chamber 11. Each of the light input ports 111 is located on a straight line, and each of the light input ports 111 and the light receiving port 112 is located on a plane parallel to the guide rod 122.

Preferably, referring to fig. 1, fig. 2 and fig. 4, a first optical collimator 113 is embedded in each light input port 111, and each first optical collimator 113 is coaxially disposed with the corresponding light input port 111. The first optical collimator 113 functions to convert the laser beam in the input optical fiber (not shown) into collimated light (parallel light) and then to inject the collimated light into the gas cell 11.

Preferably, referring to fig. 1, 2 and 4, a second optical collimator 114 is embedded in the light receiving opening 112, and the second optical collimator 114 is coaxial with the light receiving opening 112. The second optical collimator 114 functions to couple the parallel (or nearly parallel) laser beam emitted from the gas cell 11 into an output optical fiber (not shown), and then to guide the laser beam into a receiver through the output optical fiber.

Preferably, referring to fig. 1, the air chamber 11 includes an air chamber body and a front cover (not shown), and the front cover is detachably connected to the air chamber body. In this embodiment, the air inlet and the air outlet are formed on the cover plate, and the air chamber body is formed with a plurality of fixing holes 115, so that the front cover can be conveniently detached from or attached to the air chamber body. When the air chamber breaks down, the front cover can be opened for maintenance.

Preferably, referring to fig. 2, the gas chamber main body is further provided with a sealing groove 116 matched with the front cover, and the optical path adjustable gas absorption cell further includes a sealing gasket (not shown) matched with the sealing groove 116, where the sealing gasket is embedded in the sealing groove 116, so as to cooperate with the cover plate to seal the gas chamber 11, and ensure that gas only enters and exits from the gas inlet and the gas outlet on the cover plate.

The utility model also provides a gaseous detection device, including adjustable gaseous absorption cell of optical distance 1, a plurality of input device and a receiving arrangement (not shown).

The number of the input devices is the same as that of the light input ports 111 of the optical path adjustable gas absorption cell 1, and the input devices are in one-to-one correspondence, each input device is installed at the corresponding light input port 111, and each input device is used for injecting a laser beam into the corresponding light input port 111.

The receiving device is installed at the light receiving port 112 of the optical path adjustable gas absorption cell 1, and the receiving device is used for receiving the laser ray emitted from the light receiving port 112 and detecting the received laser ray, in this embodiment, the receiving device is connected with the second optical collimator 114 through an optical fiber.

For better understanding of the present invention, the following detailed description is made with reference to fig. 1 to 5 to illustrate the working process of the gas detection device provided by the present invention: the gas detection device comprises two working modes:

(1) multiple gas simultaneous detection mode

The gas mixture to be detected is introduced into the gas chamber 11, and laser beams with different wavelengths, each corresponding to the absorption wavelength of a specific gas to be detected, are injected into the light input ports 111 through the input devices, in this embodiment, the three input devices can respectively output a laser beam corresponding to the absorption wavelength of a specific gas to be detected, so that the three input devices can respond to three kinds of gas, and then the stepping motor 152 is started, so that the mounting block 13 slides along the guide rod 122, so that the reflector assembly 14 reaches the position corresponding to the first light input port 111, and at this time, the reflector assembly 14 reflects the laser beam incident from the first input device downward, and is emitted from the light-receiving opening 112, and is received by the receiving device, which detects the power of the laser beam, calculating the concentration of the gas to be detected corresponding to the first input device in the gas chamber 11 according to the power and the optical path length; then, the screw rod 151 is driven to rotate continuously by the stepping motor 152, so that the reflecting mirror group 14 reaches a position corresponding to the second light input port 111, the concentration of the gas to be detected corresponding to the second input device can be detected by the same method, the reflecting mirror group 14 is driven to reach a position corresponding to the third light input port 111 continuously by the stepping motor 152, the concentration of the gas to be detected corresponding to the third input device is detected, and the simultaneous detection of the three gases is realized;

(2) same gas optimal optical path test mode

Introducing gas to be detected into the gas chamber 11, injecting laser beams with the same wavelength into each light input port 111 through each input device, wherein the wavelength corresponds to the absorption wavelength of the gas to be detected, then starting the stepping motor 152, enabling the mounting block 13 to slide along the guide rod 122, so that the reflector group 14 reaches the position corresponding to the first light input port 111, at the moment, the reflector group 14 reflects the laser beams injected by the first input device downwards, and the laser beams are emitted from the light receiving port 112 and received by the receiving device, the receiving device detects the power of the laser beams, and the concentration of the gas to be detected in the gas chamber 11 is calculated according to the power and the optical path length; then, the screw rod 151 is driven to rotate by the stepping motor 152, so that the reflecting mirror group 14 sequentially reaches positions corresponding to the second light input port 111 and the third light input port 111, the concentration of the gas to be detected can be detected by the same method, and the concentration value of the gas to be detected obtained by three times of detection and the corresponding optical path length are analyzed, so that the minimum optical path of the gas reaching a certain detection precision is obtained.

To sum up, the utility model discloses an arrange a plurality of light input ports 111 on the lateral wall of air chamber 11, and make the speculum group 14 arrive the position that corresponds with each light input port 111 in proper order through actuating mechanism 15, if the laser beam of the different wavelength of input in each light input port 111, each wavelength corresponds the absorption wavelength who waits to detect gaseous respectively, can detect the concentration of multiple gas that awaits measuring simultaneously, if the laser beam of the same wavelength of input in each light input port 111, then the optical path of the laser beam that the position change of speculum group 14 jetted out is adjusted to the accessible, thereby can testify a certain specific gas and reach the minimum optical path of certain measuring accuracy.

The above description of the present invention does not limit the scope of the present invention. Any other corresponding changes and modifications made according to the technical idea of the present invention should be included in the scope of the claims of the present invention.

Claims (8)

1. An optical path adjustable gas absorption cell, comprising: an air chamber, a guide mechanism, a mounting block, a reflector group and a driving mechanism,

the air chamber is provided with a long absorption cavity, the side wall of the air chamber is provided with a plurality of light input ports communicated with the absorption cavity along the length direction of the air chamber, the top wall or the bottom wall of the air chamber is provided with a light receiving port communicated with the absorption cavity, and the air chamber is also provided with an air inlet and an air outlet communicated with the absorption cavity;

the guide mechanism comprises a fixed block and a guide rod, the fixed block is positioned in the absorption cavity and fixed on the inner wall of the air chamber, the guide rod is positioned in the absorption cavity and fixed on the fixed block, and the guide rod extends along the length direction of the air chamber;

the mounting block is provided with a slotted hole matched with the guide rod, and the mounting block is sleeved on the guide rod and can slide along the guide rod;

the reflector group is fixed on the mounting block and is used for reflecting the laser beam incident from the light input port at least once so as to enable the laser beam to be emitted from the light receiving port;

the drive mechanism is connected with the mounting block and is used for moving the mounting block.

2. The optical path adjustable gas absorption cell as claimed in claim 1, wherein the mounting block is provided with a screw hole;

the driving mechanism comprises a screw rod and a stepping motor, the screw rod is in threaded connection with the screw hole and parallel to the guide rod, the screw rod is further in rotating connection with the mounting block, and the stepping motor is connected with the screw rod and used for driving the screw rod to rotate.

3. The optical path tunable gas absorption cell of claim 2 wherein the number of said light input ports is three, and each of said light input ports is uniformly disposed on the sidewall of said gas cell.

4. The optical path tunable gas absorption cell of claim 1 wherein a first optical collimator is embedded in each of the light input ports, each of the first optical collimators being coaxially disposed with the corresponding light input port.

5. The optical path tunable gas absorption cell according to claim 1, wherein a second optical collimator is embedded in the light receiving port, and the second optical collimator is disposed coaxially with the light receiving port.

6. The optical path tunable gas absorption cell of claim 1 wherein the gas cell comprises a gas cell body and a front cover, the front cover being removably attached to the gas cell body.

7. The optical path adjustable gas absorption cell according to claim 6, wherein the gas chamber body further has a sealing groove matching with the front cover, and the optical path adjustable gas absorption cell further includes a sealing gasket matching with the sealing groove, and the sealing gasket is embedded in the sealing groove.

8. A gas detection device comprising the optical path adjustable gas absorption cell according to any one of claims 1 to 7, a plurality of input devices and a receiving device,

the number of the input devices is the same as that of the light input ports of the optical path adjustable gas absorption cell, and the input devices correspond to the light input ports one by one, and are all installed at the corresponding light input ports and are used for emitting laser beams into the corresponding light input ports;

the receiving device is arranged at a light receiving port of the optical path adjustable gas absorption cell and is used for receiving the laser rays emitted from the light receiving port and detecting the received laser rays.

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