WO2020125554A1

WO2020125554A1 - Spectrophotometer inspection system and method

Info

Publication number: WO2020125554A1
Application number: PCT/CN2019/125192
Authority: WO
Inventors: 陈巍; 祝铭; 李剑平; 张亮; 周志盛; 梁元博; 赵强星; 周轩; 吕建成
Original assignee: 中国科学院深圳先进技术研究院
Priority date: 2018-12-17
Filing date: 2019-12-13
Publication date: 2020-06-25
Also published as: CN111323380B; CN111323380A

Abstract

A spectrophotometer inspection system and method. The inspection system comprises: a light source device (10) for providing an incident light beam; a sample accommodation device (20) comprising multiple accommodation cavities where samples to be inspected are accommodated; a light beam scanning device (30) for reflecting the incident light beam and passing same through the accommodation cavity; and a spectrum detection device (40) for receiving the light beam passing through the accommodation cavity and obtaining the spectrum of the light beam passing through the accommodation cavity. According to the spectrophotometer inspection system, the rapid spectrophotometric measurement on multiple samples is achieved in a single light source and a single spectrum module, the influences of the light intensity and the fluctuation of an output spectrum on a spectrophotometer are eliminated, and the system detection precision is improved. In addition, the structure is made more compact for integration, and costs are reduced.

Description

Spectrophotometer detection system and detection method

Technical field

The invention belongs to the technical field of optical measurement, and particularly relates to a spectrophotometer detection system and a detection method thereof.

Background technique

The spectrophotometer uses the absorption spectrum of the substance to infer the type and content of the substance component. The basic law of spectrophotometry is Lambert-Beer law (Lambert-Beer law), which describes the relationship between the intensity of a substance's absorption of light at a certain wavelength and the concentration of the light-absorbing substance and the thickness of the liquid layer. The specific formula is: A=Lg(I/I ₀ )=A×b×c, where A is the absorbance, I is the transmitted light intensity, I ₀ is the incident light intensity, b is the length of the absorption path, and c is the light-absorbing substance concentration.

Spectrophotometers often use xenon lamps, deuterium lamps, tungsten halogen lamps, etc. as light sources. These light sources have a relatively wide spectrum that can cover multiple wavelength bands. This type of incoherent light source has a certain intensity fluctuation during operation, which affects the stability of the absorption spectrometer of traditional structure. Furthermore, the spectral output characteristics of these light sources are not stable enough, that is, there will be a proportional difference in the output at different wavelengths. The instability of the energy output of the light source and the spectral output will introduce errors into the time-sharing spectrum. The method of adding a reference optical path is commonly used in the detection of scientific instruments to eliminate the influence of the instability of the energy output of the light source and the spectral output on the measurement results. The reference optical path is generally a solvent that does not contain any solute components compared to the detection optical path containing the sample. Measure the test light path containing the sample first and then move the sample cell to measure the reference light path. Lambert-Beer law is applied to the reference spectrum measurement, the expression is:

Abs _λ represents the absorbance at the wavelength λ, I _0λ represents the spectrum collected by the reference optical path; I _λ represents the spectrum collected by the signal optical path. By this way of spectral subtraction, the influence of light source instability on the experimental results is eliminated.

There are two common ways of implementing the reference optical path. The first is to switch the reference optical path and the sample optical path by switching the position of the sample cell. In this way, there is a position deviation when resetting due to the movement accuracy of the machine, which reduces the measurement accuracy of the system. The second is to rely on multiple light sources or spectral detection modules to achieve the simultaneous acquisition of the reference optical path and the sample optical path. This approach will introduce new errors and reduce measurement accuracy, such as differences in the characteristics of different light sources and differences in the spectral response of different spectral detection modules. In addition, the dual light source or dual spectrum detection module also greatly increases the cost of the spectrophotometer detection system.

The measurement time is an important parameter for the spectrophotometer. First, the single measurement time determines whether the spectrophotometer can be used for in-situ measurement, such as in-situ measurement of water quality parameters (chemical oxygen demand, total organic carbon, etc.). It can be satisfied that the measurement time is completed on the order of milliseconds, and the change of the water composition caused by the water flow can be almost ignored. Furthermore, in a spectrophotometer with a reference optical path, the measurement time also determines the reference optical path and the sample optical path in the successive measurement. The influence of the instability of the light source on the two measurement results ultimately affects the detection accuracy. In summary, rapid measurement is one of the core features of spectrophotometers.

In the prior art, the patent application publication number is CN107941717A, and the Chinese patent of the invention titled a static multi-sample cell spectrophotometer uses a linear structure lined up, and then relies on a stepper motor to move multiple sample cells Measure at the optical path. The more sample channels in the whole process, the longer it takes. The measurement of the "5-connected cell" structure must be in the order of minutes, and it takes up a lot of space, making it difficult to miniaturize the system.

Summary of the invention

(1) Technical problems to be solved by the present invention

The technical problem to be solved by the present invention is: how to realize rapid spectrophotometric measurement of multiple samples to be tested on a single light source and a single spectrum detection module.

(2) The technical solution adopted by the present invention

In order to achieve the above objectives, the present invention adopts the following technical solutions:

A spectrophotometer detection system, including:

Light source device for providing incident light beam;

The sample containing device includes a plurality of containing chambers for containing the sample to be tested;

A beam scanning device for reflecting the incident beam through the accommodating cavity;

The spectrum detection device is used for receiving the light beam passing through the accommodating cavity and acquiring the spectrum of the light beam passing through the accommodating cavity.

Optionally, the spectrophotometer detection system further includes: a driving device for driving the light beam scanning device to perform time-division spatial scanning to reflect the incident light beam through each containing cavity in a time-division and space-division manner.

Optionally, the spectrophotometer detection system further includes: a plurality of reflecting mirrors, the reflecting mirrors correspond to the accommodating cavity in one-to-one correspondence, the reflecting mirrors are used to reflect the incident beam onto the beam scanning device The light beam reflects through the corresponding cavity.

Optionally, the light source device includes:

Light emitting element, used to emit incident light beam;

The beam shaper is used to quasi-parallel shape the incident light beam emitted by the light-emitting element.

Optionally, the spectrophotometer detection system further includes: a first lens with positive refractive power, a focal point of the first lens coincides with the center of the beam scanning device, and the first lens is used to scan the beam scanning device The light beam reflected onto the incident light beam by time-sharing reflects through each accommodating cavity.

Optionally, the light source device includes:

Light emitting element, used to emit incident light beam;

An optical element group with positive refractive power is used to focus the incident light beam emitted by the light-emitting element onto the center of the light beam scanning device.

Optionally, the sample receiving device includes a receiving tray, a first window cover, and a second window cover, and the receiving tray is provided with a plurality of through holes penetrating the first and second opposing surfaces of the receiving tray , The first window cover is disposed on the first surface, and the second window cover is disposed on the second surface, thereby forming a plurality of the receiving chambers.

Optionally, the spectrum detection device includes:

Multiple multimode optical fibers, each multimode optical fiber includes opposing first end surfaces and second end surfaces, the second end surfaces of the multiple multimode optical fibers are linearly arranged, and the first end surface and the receiving cavity are one by one Correspondingly, the first end surface is used to receive the light beam passing through the corresponding accommodating cavity;

In the optical fiber spectrometer, the entrance slit meets a plurality of linearly arranged second end faces, and the optical fiber spectrometer is used to receive the light beam emitted from the second end face.

The invention also discloses a liquid in-situ spectrophotometer detection system, including a casing and the above spectrophotometer detection system, the spectrophotometer detection system is provided in the casing, and the casing is partially recessed to form a liquid in-situ measurement window , Opposite sides of the liquid in-situ measurement window are respectively provided with a first light-transmitting portion and a second light-transmitting portion, and the beam scanning device is further used to reflect incident light beams through the first light-transmitting portion and In the second light-transmitting part, the spectrum detection device is further used to receive the light beam passing through the second light-transmitting part and acquire the spectrum of the light beam in the second light-transmitting part.

The invention also discloses a detection method of the spectrophotometer detection system. The detection method includes:

The light source device provides the incident beam;

The beam scanning device reflects the incident light beam through the accommodating cavity of the sample accommodating device, and the accommodating cavity of the sample accommodating device contains the sample to be tested and the reference sample;

The spectrum detection device receives the light beam passing through the accommodating cavity, and acquires the spectrum of the light beam passing through the accommodating cavity, where the spectrum includes the spectrum of the sample to be tested and the spectrum of the reference sample;

The absorption spectrum of the sample to be measured is obtained according to the spectrum of the sample to be measured and the spectrum of the reference sample.

(3) Beneficial effects

The spectrophotometer detection system disclosed by the invention realizes the rapid spectrophotometric measurement of multiple samples under the condition of a single light source and a single spectral module, eliminates the influence of light source intensity and output spectrum fluctuations on the spectrophotometer, improves the detection accuracy of the system, and can also make The structure is more compact and easy to integrate, while reducing costs.

BRIEF DESCRIPTION

1 is a flowchart of a detection method of a spectrophotometer detection system according to an embodiment of the present invention;

2 is a schematic diagram of a spectrophotometer detection system according to Embodiment 1 of the present invention;

FIG. 3 is an exploded view of the structure of the sample holding device according to the first embodiment of the present invention;

4 is a schematic diagram of the arrangement of the first end faces of multiple multimode optical fibers according to Embodiment 1 of the present invention;

5 is a schematic diagram of the arrangement of second end faces of multiple multimode optical fibers according to Embodiment 1 of the present invention;

6 is a schematic diagram of a spectrophotometer detection system according to Embodiment 2 of the present invention;

7 is a schematic diagram of a liquid in-situ spectrophotometer detection system according to Embodiment 3 of the present invention.

detailed description

In order to make the objectives, technical solutions, and advantages of the present invention clearer, the present invention will be further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are only used to explain the present invention, and are not intended to limit the present invention.

As shown in FIG. 1, the detection method of the spectrophotometer detection system according to the embodiment of the present invention includes the following steps S10 to S30:

Step S10: the light source device 10 provides an incident light beam;

Step S20: The beam scanning device 30 reflects the incident beam through the accommodating cavity of the sample accommodating device 20, wherein the accommodating cavity of the sample accommodating device (20) contains the sample to be tested and the reference sample;

Step S30: The spectrum detection device 40 receives the light beam passing through the accommodating cavity and acquires the spectrum of the light beam passing through the accommodating cavity, where the spectrum includes the spectrum of the sample to be tested and the spectrum of the reference sample.

Step S40: Obtain the absorption spectrum of the sample to be tested according to the spectrum of the sample to be tested and the spectrum of the reference sample.

Further, the following uses two different embodiments to explain how to use the spectrophotometer detection system for measurement.

Example one

As shown in FIG. 2, the spectrophotometer detection system according to Embodiment 1 of the present invention includes a light source device 10, a sample holding device 20, a beam scanning device 30 and a spectrum detection device 40. Among them, the light source device 10 is used to provide the incident light beam required for detection, the sample receiving device 20 includes a plurality of receiving cavities for receiving the sample to be tested, and the beam scanning device 30 is used to reflect the incident light beam to pass through the receiving cavity, The spectrum detecting device 40 is used to receive the light beam passing through the accommodating cavity and acquire the spectrum of the light beam passing through the accommodating cavity.

Specifically, the beam scanning device 30 is further used to reflect the incident light beam through each receiving cavity in a time-sharing manner, so as to realize the measurement of each sample to be measured. As a preferred embodiment, the spectrophotometer detection system further includes a driving device 50 for driving the light beam scanning device 30 to rotate in a time-sharing manner, so that the light beam scanning device 30 reflects the incident light beam in a time-sharing manner.

Further, as a preferred embodiment, as shown in FIG. 3, the sample receiving device 20 includes a receiving tray 21, a first window cover 22 and a second window cover 23, and a plurality of opposing In the through holes 21a of the first surface and the second surface, the first window cover 22 is disposed on the first surface, and the second window cover 22 is disposed on the second surface, thereby forming a plurality of accommodating cavities. Further, the plurality of through holes 21a are arranged in an array to form a honeycomb structure. The cross-sectional shape of the through hole 21a is a regular hexagon, and the shape of the accommodating disk 21 is a cylindrical shape. The thickness of the accommodating tray 21 is preferably 10 mm, the diameter of the circumscribed circle of the through hole 21 a is 5 mm, the material of the accommodating tray 21 is made of ordinary glass, and the material of the first window cover 22 and the second window cover 23 is preferably made of ultraviolet fused silica material . Further, both the first window cover 22 and the second window cover 23 adopt a detachable design. When loading the sample, the first window cover 22 is opened, different liquid samples are filled into the through holes 21a, and then the first window The cover 22 is closed, and finally the sample holding device 20 is put back into the system for measurement, and the first window cover 22 and the second window cover 23 are removed for cleaning at the same time when cleaning.

Further, the light source device 10 includes a light emitting element 11 and a beam shaper 12, the light emitting element 11 is used to emit an incident light beam, and the beam shaper 12 is used to quasi-parallel shape the incident light beam emitted by the light emitting element 11. The light-emitting element 11 preferentially uses a flashing xenon lamp. Further, the spectrophotometer detection system further includes a plurality of reflecting mirrors 60, the reflecting mirrors 60 correspond to the accommodating cavities one by one, and the reflecting mirrors 60 are used to reflect the incident beams reflected by the beam scanning device 30 to the beams passing thereon through the corresponding The cavity is accommodated. Wherein, both the surface of the reflecting mirror 60 and the reflecting surface of the beam scanning device 30 are coated with an ultraviolet enhanced reflecting film. Through the function of the reflecting mirror 60 and the beam scanning device 30, the incident beam can pass through the accommodating cavity quasi-parallel.

As a preferred embodiment, the spectrum detection device 40 includes a plurality of multimode optical fibers 41 and a fiber spectrometer 42, as shown in FIGS. 4 and 5, each multimode optical fiber 41 includes opposing first end surfaces 41a and second end surfaces 41b. The second end surfaces 41b of the multi-mode optical fibers 41 are arranged linearly. The first end surfaces 41a and the accommodating cavities are in one-to-one correspondence. The first end surface 41a is used to receive the light beam passing through the corresponding accommodating cavities. The entrance slit of the optical fiber spectrometer 42 is aligned with the plurality of linearly arranged second end faces 41b. The optical fiber spectrometer 42 is used to receive the light beam emitted from the second end face 41b.

Further, the spectrophotometer detection system further includes a second lens 80 for focusing the light beam passing through the corresponding accommodating cavity onto the first end surface 41a, and the first end surface 41a is located on the second lens 80 At the focal point, the first end surface 41a is perpendicular to the optical axis of the light beam passing through the corresponding receiving cavity. Among them, the diameter of the second lens 80 is larger than the outer diameter of the accommodating disk 21.

Further, the detection system of the spectrophotometer of the present invention controls the timing of the light-emitting element 11, the optical fiber spectrometer 42 and the optical scanning device 20 through a timing controller to realize time-sharing measurement. The detection process of the spectrophotometer detection system is described below.

First measurement: The optical fiber spectrometer 42 sends out a first trigger signal, which first triggers the optical scanning device 20 to reach the first preset angle. Then, the light-emitting element 11 is triggered to generate pulsed light, and the light beam emitted by the light-emitting element 11 becomes a quasi-parallel light after passing through the beam shaper 12. The quasi-parallel beam passes through the optical scanning device 20 and is reflected to the mirror 60. The mirror 60 directs the light beam to the containing cavity, and the light beam passes through the first sample to be measured in the containing cavity. The light beam passes through the first sample to be tested and then reaches the second lens 80. The second lens 80 is used to focus the light beam passing through the corresponding accommodating cavity onto the first end surface 41a. The light beam passes through the multimode optical fiber 41 and exits from the second end surface 41b. The entrance slit of the optical fiber spectrometer 42 coincides with the second end surface 41b, and the direction of the slit is the same as the direction in which the plurality of second end surfaces 41b are linearly arranged. Finally, the measurement results are obtained through data analysis to obtain the first spectrum. In the second measurement, the optical fiber spectrometer 42 sends out a second trigger signal, which first triggers the optical scanning device 20 to reach the second preset angle. The subsequent steps are the same as in the first measurement, and the second spectrum is finally obtained. By analogy, after multiple measurements, the test of multiple test samples can be completed, and one of the multiple test samples is the reference sample.

Example 2

Of course, in other embodiments, as shown in FIG. 6, the light source device 10 includes a light-emitting element 11 and an optical element group 13 with positive refractive power. The optical element group 13 may be a lens group or a concave mirror group, and the light-emitting element 11 is used to emit For the incident light beam, the optical element group 13 is used to focus the incident light beam emitted by the light-emitting element 11 onto the center of the beam scanning device 30. Further, the spectrophotometer detection system further includes a first lens 70 having positive refractive power, the focal point of the first lens 70 coincides with the center of the beam scanning device 30, and the first lens 70 is used to reflect the beam scanning device 30 in a time-sharing manner. The light beam onto which the light beam is reflected reflects through each accommodating cavity. This allows the incident beam to pass through the receiving cavity quasi-parallel. The other parts of the second embodiment are the same as those of the first embodiment, and will not be repeated here.

In the second embodiment, the detection process of the spectrophotometer detection system may also be:

First measurement: The optical fiber spectrometer 42 sends out a first trigger signal, which first triggers the optical scanning device 20 to reach the first preset angle. Then, the light-emitting element 11 is triggered to generate pulsed light. The light beam emitted by the light-emitting element 11 passes through the optical element group 13 and is focused on the center of the beam scanning device 30. The beam scanning device 30 reflects the beam to the first lens 70, the beam passes through the first lens 70 and becomes a quasi-parallel beam, and the beam passes through the first sample to be measured in the accommodating cavity. The light beam passes through the first sample to be tested and then reaches the second lens 80. The second lens 80 is used to focus the light beam passing through the corresponding accommodating cavity onto the first end surface 41a. The light beam passes through the multimode optical fiber 41 and exits from the second end surface 41b. The entrance slit of the optical fiber spectrometer 42 coincides with the second end surface 41b, and the direction of the slit is the same as the direction in which the plurality of second end surfaces 41b are linearly arranged. Finally, the measurement results are obtained through data analysis to obtain the first spectrum. In the second measurement, the optical fiber spectrometer 42 sends out a second trigger signal, which first triggers the optical scanning device 20 to reach the second preset angle. The subsequent steps are the same as in the first measurement, and the second spectrum is finally obtained. By analogy, after multiple measurements, the test of multiple test samples can be completed, and one of the multiple test samples is the reference sample.

The spectrophotometer detection system disclosed in the embodiments of the present invention realizes rapid spectrophotometric measurement of multiple samples under the condition of a single light source and a single spectral module, eliminating the influence of light source intensity and output spectrum fluctuations on the spectrophotometer, and improving the detection accuracy of the system. In addition, it can make the structure more compact and easy to integrate, while reducing costs.

Example Three

As shown in FIG. 7, the liquid in-situ spectrophotometer detection system according to the third embodiment of the present invention includes a housing 90 and the spectrophotometer detection system in the first or second embodiment, the spectrophotometer detection system is provided at In the housing 90, a portion of the housing 90 is recessed to form a liquid in-situ measurement window 91, and opposite sides of the liquid in-situ measurement window 91 are respectively provided with a first light-transmitting portion 92) and a second light-transmitting portion 93. The beam scanning device 30 is also used to reflect the incident light beam through the first light-transmitting portion 92 and the second light-transmitting portion 93 in sequence, and the spectrum detection device 40 is also used to receive the second light-transmitting The light beam of the portion 93, and acquire the spectrum of the light beam of the second light transmitting portion 93.

The entire liquid in-situ spectrophotometer detection system is immersed in the liquid to be measured for measurement. Wherein, the light source device 10 is used to provide the incident light beam required for detection, and the sample containing device 20 is a pure solvent containing cavity corresponding to the liquid to be measured, and its length is the same as the liquid in-situ measurement window 91. The beam scanning device 30 is used to reflect the incident light beam to pass through the sample holding device 20 or the liquid in-situ measurement window 91, and the spectrum detection device 40 is used to receive the light beam passing through the accommodating cavity and acquire the light beam passing through the accommodating cavity spectrum.

Specifically, the beam scanning device 30 is further used to reflect the incident light beam through the sample holding device 20 or the liquid in-situ measurement window 91 in a time-sharing manner, so as to realize the in-situ reference measurement of the liquid to be measured.

As a preferred embodiment, the spectrophotometer detection system further includes a driving device 50 for driving the beam scanning device 30 to perform spatial scanning in a time-sharing manner, so that the beam scanning device 30 reflects the incident light beam in a time-sharing manner.

Further, the light source device 10 includes a light emitting element 11 and a beam shaper 12, the light emitting element 11 is used to emit an incident light beam, and the beam shaper 12 is used to quasi-parallel shape the incident light beam emitted by the light emitting element 11. The light-emitting element 11 preferentially uses a flashing xenon lamp.

Further, the spectrophotometer detection system further includes two reflecting mirrors 60 for reflecting the light beam onto which the incident light beam is reflected by the beam scanning device 30 through the corresponding sample receiving device 20 or liquid in-situ measurement window 90. Wherein, both the surface of the reflecting mirror 60 and the reflecting surface of the beam scanning device 30 are coated with an ultraviolet enhanced reflecting film. Through the action of the mirror 60 and the beam scanning device 30, the incident light beam can pass through the sample receiving device 20 or the liquid in-situ measurement window 90 quasi-parallel.

As a preferred embodiment, the spectrum detection device 40 includes a Y-type multimode optical fiber 41 and an optical fiber spectrometer 42.

Further, the spectrophotometer detection system further includes two second convex lenses 80 for focusing the light beam passing through the corresponding accommodating cavity to the end surface of the Y-shaped optical fiber 41.

Further, the detection system of the spectrophotometer of the present invention controls the timing of the light-emitting element 11, the optical fiber spectrometer 42 and the optical scanning device 30 through the timing controller to realize time-sharing measurement. The detection process of the spectrophotometer detection system is described below.

Reference measurement: The optical fiber spectrometer 42 sends out a first trigger signal, which first triggers the optical scanning device 30 to reach the first preset angle. Then, the light-emitting element 11 is triggered to generate pulsed light, and the light beam emitted by the light-emitting element 11 becomes a quasi-parallel light after passing through the beam shaper 12. The quasi-parallel beam passes through the optical scanning device 30 and is reflected to the mirror 60. The reflecting mirror 60 directs the light beam to the sample containing device 20, and the light beam passes through the pure solvent of the liquid to be measured in the accommodating cavity. The light beam passes through the sample receiving device 20 to the second convex lens 80, and is used to focus the light beam passing through the corresponding receiving cavity to the first end surface of the Y-shaped optical fiber. The light beam passes through the multimode optical fiber 41 and exits from the second end surface. The entrance slit of the optical fiber spectrometer 42 coincides with the second end surface of the Y-shaped optical fiber 41. Finally, the measurement results are obtained through data analysis to obtain the first spectrum. During the in-situ measurement of the liquid to be measured, the optical fiber spectrometer 42 sends out a second trigger signal, which first triggers the optical scanning device 30 to reach the second preset angle. The subsequent steps are the same as in the first measurement, and the second spectrum is finally obtained. The second spectrum is subtracted from the first spectrum to obtain the in-situ absorption spectrum of the liquid to be measured.

Although the illustrative specific embodiments of the present invention have been described above so that those skilled in the art can understand the present invention, the present invention is not limited to the scope of the specific embodiments. For those of ordinary skill in the art, as long as each As long as such changes are within the spirit and scope of the present invention as defined and determined by the appended claims, all inventions using the concept of the present invention are included in the protection.

Claims

A spectrophotometer detection system, which includes:

Light source device for providing incident light beam;

The sample containing device includes a plurality of containing chambers for containing the sample to be tested;

A beam scanning device for reflecting the incident beam through the accommodating cavity;

The spectrum detection device is used for receiving the light beam passing through the accommodating cavity and acquiring the spectrum of the light beam passing through the accommodating cavity.
The spectrophotometer detection system according to claim 1, wherein the spectrophotometer detection system further comprises: a driving device for driving the light beam scanning device to perform space-time spatial scanning, so that Reflect the incident beam through each receiving cavity.
The spectrophotometer detection system according to claim 2, wherein the spectrophotometer detection system further comprises: a plurality of mirrors, the mirrors correspond to the accommodating cavity in one-to-one correspondence, the mirrors are used to The light beam scanning device reflects the incident light beam onto the light beam and reflects through the corresponding cavity.
The spectrophotometer detection system according to claim 3, wherein the light source device comprises:

Light emitting element, used to emit incident light beam;

The beam shaper is used to quasi-parallel shape the incident light beam emitted by the light-emitting element.
The spectrophotometer detection system according to claim 2, wherein the spectrophotometer detection system further comprises: a first lens having a positive refractive power, the focal point of the first lens coincides with the center of the beam scanning device, the The first lens is used to reflect the incident light beam onto the light beam scanning device in a time-sharing manner, and to reflect the light beam therethrough through each accommodating cavity.
The spectrophotometer detection system according to claim 5, wherein the light source device comprises:

Light emitting element, used to emit incident light beam;

An optical element group with positive refractive power is used to focus the incident light beam emitted by the light-emitting element onto the center of the light beam scanning device.
The spectrophotometer detection system according to claim 1, wherein the sample receiving device includes a receiving tray, a first window cover, and a second window cover, and a plurality of opposing surfaces extending through the receiving tray are provided in the receiving tray Through holes of the first surface and the second surface, the first window cover is disposed on the first surface, and the second window cover is disposed on the second surface, thereby forming a plurality of the accommodations Cavity.
The spectrophotometer detection system according to claim 1, wherein the spectrum detection device comprises:

Multiple multimode optical fibers, each multimode optical fiber includes opposing first end surfaces and second end surfaces, the second end surfaces of the multiple multimode optical fibers are linearly arranged, and the first end surface and the receiving cavity are one by one Correspondingly, the first end surface is used to receive the light beam passing through the corresponding accommodating cavity;

In the optical fiber spectrometer, the entrance slit meets a plurality of linearly arranged second end faces, and the optical fiber spectrometer is used to receive the light beam emitted from the second end face.
A liquid in-situ spectrophotometer detection system, which includes a housing and the spectrophotometer detection system of claim 1, the spectrophotometer detection system is disposed in the housing, and the housing is partially recessed to form an in-situ liquid measurement A window, on opposite sides of the liquid in-situ measurement window are respectively provided with a first light-transmitting portion and a second light-transmitting portion, and the beam scanning device is further used to reflect the incident light beam through the first light-transmitting portion in sequence With the second light-transmitting part, the spectrum detection device is further used to receive the light beam passing through the second light-transmitting part and acquire the spectrum of the light beam of the second light-transmitting part.
The liquid in-situ spectrophotometer detection system according to claim 9, wherein the spectrophotometer detection system further comprises: a driving device for driving the light beam scanning device to perform space-time spatial scanning to time-sharing, The incident beam is reflected spatially through each receiving cavity.
The liquid in-situ spectrophotometer detection system according to claim 9, wherein the spectrophotometer detection system further comprises: a plurality of mirrors, the mirrors correspond to the accommodating cavity in one-to-one correspondence, the reflection The mirror is used to reflect the light beam reflected by the light beam scanning device to the light beam passing therethrough through the corresponding receiving cavity.
The liquid in-situ spectrophotometer detection system according to claim 11, wherein the light source device comprises:

Light emitting element, used to emit incident light beam;

The beam shaper is used to quasi-parallel shape the incident light beam emitted by the light-emitting element.
The liquid in-situ spectrophotometer detection system according to claim 9, wherein the spectrophotometer detection system further comprises: a first lens having positive refractive power, the focal point of the first lens and the beam scanning device The centers coincide, and the first lens is used to reflect the incident light beam onto the light beam scanning device in a time-sharing manner, and to reflect the light beam passing through each accommodating cavity.
The liquid in-situ spectrophotometer detection system according to claim 13, wherein the light source device comprises:

Light emitting element, used to emit incident light beam;

An optical element group with positive refractive power is used to focus the incident light beam emitted by the light-emitting element onto the center of the light beam scanning device.
The liquid in-situ spectrophotometer detection system according to claim 9, wherein the sample holding device includes a holding tray, a first window cover, and a second window cover, a plurality of through trays are provided in the holding tray Through holes of the first surface and the second surface of the disc, the first window cover is disposed on the first surface, and the second window cover is disposed on the second surface, thereby forming a plurality of述容置腔。 Retaining cavity.
The liquid in-situ spectrophotometer detection system according to claim 9, wherein the spectrum detection device comprises:

Multiple multimode optical fibers, each multimode optical fiber includes opposing first end surfaces and second end surfaces, the second end surfaces of the multiple multimode optical fibers are linearly arranged, and the first end surface and the receiving cavity are one by one Correspondingly, the first end surface is used to receive the light beam passing through the corresponding accommodating cavity;

In the optical fiber spectrometer, the entrance slit meets a plurality of linearly arranged second end faces, and the optical fiber spectrometer is used to receive the light beam emitted from the second end face.
A detection method of a spectrophotometer detection system according to claim 1, wherein the detection method comprises:

The light source device provides the incident beam;

The beam scanning device reflects the incident beam through the accommodating cavity of the sample accommodating device, wherein the accommodating cavity of the sample accommodating device contains the sample to be tested and the reference sample;

The spectrum detection device receives the light beam passing through the accommodating cavity, and acquires the spectrum of the light beam passing through the accommodating cavity, where the spectrum includes the spectrum of the sample to be tested and the spectrum of the reference sample;

The absorption spectrum of the sample to be measured is obtained according to the spectrum of the sample to be measured and the spectrum of the reference sample.