CN214584878U - Device for detecting water vapor concentration by using dual lasers - Google Patents

Abstract

The utility model discloses a device for detecting water vapor concentration by utilizing a twin laser, which comprises a device shell, wherein a hardware circuit board is arranged in the device shell, the upper and lower end sides of the device shell are respectively connected with a transmitting end shell and a receiving end shell, a first laser, a second laser, a first lens and a second lens are arranged in the transmitting end shell, a first reflector is arranged on the surface of the transmitting end shell, and a first light hole and a second light hole are arranged on the first reflector; the receiving end shell is internally provided with a first photoelectric detector and a second photoelectric detector, the surface of the receiving end shell is provided with a second reflector, the second reflector is provided with a third light hole and a fourth light hole, and the first reflector and the second reflector are opposite. The utility model discloses a device can realize that the low temperature interval detects the range and detects taking into account of resolution ratio with the interval steam concentration of high temperature, can improve equipment's full range suitability.

Description

Device for detecting water vapor concentration by using dual lasers

Technical Field

The utility model relates to an environment detection technology field, in particular to utilize dual laser to carry out device that steam concentration detected.

Background

The existing humidity-sensitive capacitive temperature and humidity sensor has the problems of slow humidity fading, large measurement error, long response time and the like. In spectroscopy, the composition of a substance can be resolved by the formation of the absorption line of a gas. The concentration of a gas can be calculated by analyzing the degree of absorption of light of that wavelength by an absorption spectrum of that gas. The tunable laser absorption spectrum technology is used for measuring the environment humidity, has the characteristics of high measurement accuracy, high response speed and good environment adaptability, and can solve the problems of the humidity-sensitive capacitance type temperature and humidity sensor.

In meteorological observation, the temperature and humidity sensor is required to work in a range of-40 ℃ to 60 ℃, the change range of the water vapor concentration in the air is extremely large in the temperature change range, the saturated water vapor concentration is less than 200ppm (the relative humidity is 100% RH) at-40 ℃, the saturated water vapor concentration exceeds 24 ten thousand ppm (the relative humidity is 100% RH) at 60 ℃, and the saturated water vapor concentration is 1300 times of that at-40 ℃ at 60 ℃, so that the challenge is brought to the full-range measurement of the laser humidity sensor.

At present, a water vapor analyzer adopts a laser to perform full-scale measurement, and the mode can meet serious challenges when the full-scale measurement is performed within the temperature range of-40 to 60 ℃. In a low-temperature interval, in order to improve the detection precision and the detection sensitivity of the water vapor concentration, a strong absorption line of a water vapor spectrum is adopted, and the high-precision measurement of the water vapor concentration in the low-temperature interval can be realized by combining a multi-reflection absorption cell. In a high-temperature interval (such as 60 ℃), the saturated water vapor concentration reaches more than twenty million ppm, the water vapor absorption is very strong, the absorption saturation phenomenon occurs, and the absorption spectral line intensity and the absorption path length need to be reduced at the moment. For a single laser, the detection precision and the detection sensitivity of water vapor in a low-temperature interval and a high-temperature interval cannot be considered.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the utility model provides an utilize twin laser to carry out device that steam concentration detected, the same set of light path system of two laser sharing can realize that the interval of low temperature and interval steam concentration of high temperature detect the range and detect taking into account of resolution ratio, can improve equipment's full range suitability.

In order to achieve the above purpose, the technical scheme of the utility model is as follows:

a device for detecting water vapor concentration by using dual lasers comprises a device shell, wherein a hardware circuit board is arranged in the device shell, the side surfaces of the upper end and the lower end of the device shell are respectively connected with a transmitting end shell and a receiving end shell, a first laser, a second laser, a first lens and a second lens are arranged in the transmitting end shell, a first reflector is arranged on the surface of the transmitting end shell, and a first light hole and a second light hole are formed in the first reflector; a first photoelectric detector and a second photoelectric detector are arranged in the receiving end shell, a second reflector is arranged on the surface of the receiving end shell, a third light-transmitting hole and a fourth light-transmitting hole are formed in the second reflector, and the first reflector and the second reflector are opposite; the laser that first laser sent reachs first photoelectric detector behind first lens, first light trap, the third light trap, the laser that the second laser sent reachs the second photoelectric detector behind second lens, second light trap, fourth light trap.

In the above scheme, the first laser is a near-infrared band laser, and the second laser is a mid-infrared band laser.

In the above scheme, the first laser, the first lens, the first light hole, the third light hole and the first photodetector are located on a straight line, and laser emitted by the first laser is directly emitted from the third light hole through the first lens, the first light hole and reaches the first photodetector.

In a further technical scheme, the first light hole is located at the center of the first reflector, and the third light hole is located at the center of the second reflector.

In the above scheme, the laser emitted by the second laser passes through the second lens and the second light-transmitting hole, is reflected for multiple times between the first reflector and the second reflector, and then is emitted from the fourth light-transmitting hole to reach the second photoelectric detector.

In a further technical scheme, the second light hole is located at the edge of the first reflector, and the fourth light hole is located at the edge of the second reflector.

In the above scheme, the first laser, the second laser, the first photodetector and the second photodetector are all electrically connected to the hardware circuit board.

In the above scheme, a cylindrical sintering net is connected between the transmitting end shell and the receiving end shell, and the sintering net is positioned outside the edges of the first reflector and the second reflector.

A method for detecting the concentration of water vapor by using a dual laser adopts the device, in a high-temperature interval, a first laser works, laser emitted by the first laser is converged by a first lens and then enters an open absorption light path from a first light hole, the laser is emitted from a third light hole and is received by a first photoelectric detector, and a hardware circuit board calculates the concentration of the water vapor in the environment according to the absorption degree of the water vapor concentration in the environment to an absorption spectral line; in a low-temperature interval, the second laser works, laser emitted by the second laser enters the open absorption light path from the second light-transmitting hole after being converged by the second lens, the laser is reflected for multiple times between the first reflector and the second reflector, finally is emitted from the fourth light-transmitting hole and is received by the second photoelectric detector, and the water vapor concentration in the environment is calculated by the hardware circuit board according to the absorption degree of the water vapor concentration in the environment to the absorption spectral line; in the transition region between high temperature and low temperature, the first laser and the second laser work simultaneously, and the average value of the output water vapor concentration is used as the system output.

In the scheme, the high-temperature interval is a temperature interval with the temperature higher than 5 ℃, the low-temperature interval is a temperature interval with the temperature lower than-5 ℃, and the transition interval is a temperature interval with the temperature between-5 ℃ and 5 ℃.

Through the technical scheme, the utility model provides an utilize the twin laser to carry out device that vapor concentration detected has following beneficial effect:

1. the utility model discloses a mode of twin laser, same set of light path system is shared to two lasers, can realize that low temperature interval and high temperature interval steam detect the range and detect taking into account of resolution ratio, can improve equipment's full-scale range suitability.

2. The utility model adopts the near infrared laser in the high temperature area, which can avoid the problem of water vapor absorption saturation in the high temperature environment; in a low-temperature area, a mid-infrared laser is adopted, and the light path is reflected for multiple times, so that the water vapor absorption intensity can be improved; the near-infrared laser and the middle-infrared laser work simultaneously in the transition region, and the average value of the output water vapor concentration is used as system output, so that the measurement precision can be improved.

3. The utility model discloses launch between the transition, when the laser instrument switches, the system does not need preheating time, can realize the high-speed measurement of laser humidity.

4. The utility model discloses a position setting of laser instrument, photoelectric detector and light trap can guarantee that the laser of two lasers can not produce and mix the interference, and two lasers can share same light path system.

5. The utility model discloses the position setting of the transmitting terminal casing and the receiving terminal casing of both ends side about device casing and device casing can effectively shorten the length of laser instrument, photoelectric detector to hardware circuit board cable, and introduction of noise reduction can improve the SNR.

6. The utility model discloses connect the sintering net of tube-shape between transmitting terminal shell and receiving terminal shell, can play the effect that prevents the dust pollution speculum, help improving measurement accuracy, increase of service life.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below.

Fig. 1 is a schematic view of an apparatus for detecting water vapor concentration by using a dual laser according to an embodiment of the present invention;

FIG. 2 is a schematic view of a sintering mesh according to an embodiment of the present invention;

fig. 3 is a schematic view of a first reflector disclosed in an embodiment of the present invention;

fig. 4 is a schematic view of a second reflector according to an embodiment of the present invention.

In the figure, 1, a device housing; 2. a transmitting end housing; 3. a receiving end housing; 4. a hardware circuit board; 5. a first laser; 6. a second laser; 7. a first lens; 8. a second lens; 9. a first reflector; 10. a first light-transmitting hole; 11. a second light-transmitting hole; 12. a first photodetector; 13. a second photodetector; 14. a second reflector; 15. a third light-transmitting hole; 16. a fourth light-transmitting hole; 17. sintering the net; 18. a cable; 19. a light spot.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

The utility model provides a device for detecting water vapor concentration by using a twin laser, as shown in figure 1, comprising a device shell 1, wherein a hardware circuit board 4 is arranged in the device shell 1, the side surfaces of the upper end and the lower end of the device shell 1 are respectively connected with a transmitting end shell 2 and a receiving end shell 3, a first laser 5, a second laser 6, a first lens 7 and a second lens 8 are arranged in the transmitting end shell 2, a first reflector 9 is arranged on the surface of the transmitting end shell 2, and a first light hole 10 and a second light hole 11 are arranged on the first reflector 9; a first photoelectric detector 12 and a second photoelectric detector 13 are arranged in the receiving end shell 3, a second reflector 14 is arranged on the surface of the receiving end shell 3, a third light hole 15 and a fourth light hole 16 are formed in the second reflector 14, and the first reflector 9 is opposite to the second reflector 14.

The first laser 5, the second laser 6, the first photoelectric detector 12 and the second photoelectric detector 13 are all electrically connected with the hardware circuit board 4, and the device shell 1 is externally connected with a cable 18. In this embodiment, device casing 1 is the cuboid structure, and transmitting terminal casing 2 and receiving terminal casing 3 are cylindrical structure, and this mechanical structure can effectively shorten laser instrument, photoelectric detector to the cable length of hardware circuit board 4, and the introduction of noise reduction can improve the SNR.

As shown in fig. 3 and 4, the first light hole 10 is located at the center of the first reflector 9, the third light hole 15 is located at the center of the second reflector 14, the first laser 5, the first lens 7, the first light hole 10, the third light hole 15 and the first photodetector 12 are located on a straight line, and the laser light emitted by the first laser 5 passes through the first lens 7, the first light hole 10, and directly exits from the third light hole 15 to reach the first photodetector 12. The second light hole 11 is located at the edge of the first reflector 9, the fourth light hole 16 is located at the edge of the second reflector 14, and the laser light emitted by the second laser 6 passes through the second lens 8 and the second light hole 11, is reflected between the first reflector 9 and the second reflector 14 for multiple times (the light spot 19 is shown in fig. 3 and 4), and then is emitted from the fourth light hole 16 to reach the second photodetector 13. Near-infrared laser transmission mode, laser transmission are put at the central point of two speculum, and well infrared laser ware multiple reflection mode, and laser transmits near the edge of two speculums, and the laser of two lasers can not produce and mix and disturb, and two lasers can share same optical path system.

In this embodiment, the first laser 5 is a near-infrared band laser, and the second laser 6 is a mid-infrared band laser.

In the application with low requirement on humidity measurement response speed, a cylindrical sintering net 17 can be connected between the transmitting end shell and the receiving end shell, as shown in fig. 2, the sintering net 17 is positioned outside the edges of the first reflecting mirror 9 and the second reflecting mirror 14, and plays a role in preventing dust from polluting the reflecting mirrors. In the application occasion with higher requirement on the humidity measurement response speed, the sintering net 17 can not be installed, and the humidity change in the environment can be quickly responded.

A method for utilizing the double laser to carry on the concentration detection of water vapor, adopt the above-mentioned apparatus, in the high temperature interval, the first laser 5 (near-infrared band laser) works, the laser that it sends is after gathering by the first lens 7, enter and absorb the light path from the first light trap 10 openly, the laser is emergent by the third light trap 15, received by the first photodetector 12, calculate the water vapor concentration in the environment according to the water vapor concentration in the environment to the absorption degree of the absorption spectrum line; in a low-temperature interval, the second laser 6 (a middle infrared band laser) works, laser emitted by the second laser enters an open absorption light path from the second light-transmitting hole 11 after being converged by the second lens 8, the laser is reflected for multiple times between the first reflector 9 and the second reflector 14 and finally exits from the fourth light-transmitting hole 16, and is received by the second photoelectric detector 13 (the reflection times of the laser between the first reflector 9 and the second reflector 14 can be changed by changing an incident angle and adjusting the distance between the two reflectors), and the water vapor concentration in the environment is calculated by the hardware circuit board 4 according to the absorption degree of the water vapor concentration in the environment to an absorption spectral line; in the transition region between high temperature and low temperature, the first laser 5 and the second laser 6 work simultaneously, and the average value of the output water vapor concentration is used as the system output.

Wherein the high temperature interval is a temperature interval with the temperature of more than 5 ℃, the low temperature interval is a temperature interval with the temperature of less than-5 ℃, and the transition interval is a temperature interval with the temperature of-5 ℃. And a transition interval is started, and when the laser is switched, the system does not need preheating time, so that the high-speed measurement of the laser humidity can be realized.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (7)

1. A device for detecting water vapor concentration by using dual lasers is characterized by comprising a device shell, wherein a hardware circuit board is arranged in the device shell, the side surfaces of the upper end and the lower end of the device shell are respectively connected with a transmitting end shell and a receiving end shell, a first laser, a second laser, a first lens and a second lens are arranged in the transmitting end shell, a first reflector is arranged on the surface of the transmitting end shell, and a first light hole and a second light hole are formed in the first reflector; a first photoelectric detector and a second photoelectric detector are arranged in the receiving end shell, a second reflector is arranged on the surface of the receiving end shell, a third light-transmitting hole and a fourth light-transmitting hole are formed in the second reflector, and the first reflector and the second reflector are opposite; the laser that first laser sent reachs first photoelectric detector behind first lens, first light trap, the third light trap, the laser that the second laser sent reachs the second photoelectric detector behind second lens, second light trap, fourth light trap.

2. The apparatus of claim 1, wherein the first laser is a near infrared band laser and the second laser is a mid infrared band laser.

3. The apparatus of claim 1, wherein the first laser, the first lens, the first light hole, the third light hole and the first photodetector are aligned, and wherein the laser light emitted from the first laser passes through the first lens, the first light hole, and the third light hole to directly exit the third light hole to the first photodetector.

4. The apparatus of claim 1 or 3, wherein the first hole is located at the center of the first reflector and the third hole is located at the center of the second reflector.

5. The apparatus of claim 1, wherein the second aperture is located at an edge of the first mirror and the fourth aperture is located at an edge of the second mirror.

6. The apparatus of claim 1, wherein the first laser, the second laser, the first photodetector and the second photodetector are electrically connected to a hardware circuit board.

7. The apparatus of claim 1, wherein a cylindrical sintering net is connected between the transmitting end housing and the receiving end housing, and the sintering net is located outside the edges of the first reflector and the second reflector.

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