A circulating reagent detection result imaging acquisition device

The cyclic reagent testing result imaging acquisition device solves the problems of reagent exposure, manual timing errors, and data dispersion in traditional testing through closed-loop cyclic transmission and automated timing. It achieves efficient and safe biological reagent testing and data management, and reduces the risk of cross-infection.

CN224500646UActive Publication Date: 2026-07-14CHENGDU TIANWEI INTELLIGENT TECHNOLOGY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
CHENGDU TIANWEI INTELLIGENT TECHNOLOGY CO LTD
Filing Date
2025-07-31
Publication Date
2026-07-14

AI Technical Summary

Technical Problem

Traditional biological reagent testing has safety hazards caused by exposed reagents, errors in manual timing, scattered data management, low efficiency in uploading results, and risks of personnel gathering, which affect the effectiveness of disease prevention and control.

Method used

The device employs a cyclic reagent testing result imaging acquisition system. Through closed-loop cyclic transmission, automated timing, data association and storage, and multi-node image acquisition, it achieves reagent contactless operation, parameter consistency detection, and centralized data management, supporting rapid uploading and batch processing.

Benefits of technology

It effectively avoids reagent leakage and infection risks, improves the reliability and transmission speed of test data, reduces personnel stay time, lowers the risk of cross-infection, and supports cross-regional data sharing and epidemiological investigations.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model relates to the field of internet of things image transmission equipment technology provides a kind of cyclic reagent detection result imaging acquisition equipment, including casing, top cover and placing groove, the top of casing is provided with top cover, the front of casing is equidistantly provided with placing groove, the bottom of casing is provided with storage box, the top end in casing is equipped with baffle, baffle is located the bottom of top cover, the both sides in casing are fixed with side frame, the top of side frame is fixedly connected with baffle, the utility model discloses through closed loop type's circulation transmission and processing flow, solve the security risk of reagent exposure placement in traditional detection.In reagent reaction stage, reagent chip is placed in the concave reagent groove of turntable, realizes closed circulation transmission with turntable, whole process does not need manual contact, and physical isolation is formed by fence frame, support disc and other structures, effectively avoid the risk of reagent leakage or operator contact infection, especially suitable for infectious disease detection scene.
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Description

Technical Field

[0001] This utility model relates to the field of Internet of Things (IoT) image transmission equipment technology, and in particular to a cyclic reagent testing result imaging acquisition device. Background Technology

[0002] At high-traffic biological disease collection points such as hospitals, communities, customs, airports, and disease control centers, biological reagent testing is a crucial link in disease screening and prevention. However, traditional testing methods have many problems:

[0003] In traditional testing, reagent kits and test strips are exposed during the reaction stage without isolation and protection, making them susceptible to environmental interference that affects reaction stability. This can also expose operators to infectious samples, increasing the risk of cross-infection, which is particularly prominent in the testing of infectious diseases such as HIV.

[0004] In terms of time control, relying on manual timing can easily lead to inaccurate reaction times due to negligence or fatigue when the sample size is large, affecting the sensitivity and specificity of the test results, potentially causing misjudgments and interfering with disease prevention and control decisions.

[0005] There are shortcomings in the processing and management of results: results are judged manually on-site, lacking a standardized recording mechanism, making it difficult to trace key parameters; data is stored in a scattered manner, making it impossible to centrally manage and share across regions, which is not conducive to work such as epidemiological investigations of infectious diseases and restricts the accuracy of prevention and control.

[0006] The result is low upload efficiency. Traditional mobile phone photo upload requires manual operation, which is time-consuming and the image quality is affected by shooting conditions. It is difficult to meet the real-time transmission needs of large-scale detection and delays information feedback.

[0007] More importantly, the traditional process requires one-on-one sequential processing, which leads to long queues and crowds of people waiting for testing. This increases the risk of virus transmission, especially during infectious disease outbreaks, violates prevention and control principles, and poses an even greater risk in densely populated cross-border locations such as airports.

[0008] Therefore, this utility model provides a cyclic reagent detection result imaging acquisition device. Utility Model Content

[0009] The purpose of this invention is to provide a cyclic reagent detection result imaging acquisition device, which solves the above-mentioned problems by using this device.

[0010] To solve the above-mentioned technical problems, the present invention provides the following technical solution: a circulating reagent detection result imaging acquisition device, including a housing, a top cover and a placement slot. The top of the housing is provided with a top cover, the front of the housing is provided with placement slots at equal intervals, the bottom of the housing is provided with a storage box, the top of the inside of the housing is installed with a partition, the partition is located at the bottom of the top cover, and the two sides inside the housing are fixed with side frames, the top of the side frames is fixedly connected to the partition.

[0011] Support plates are installed at equal intervals between the side frames. A main shaft is rotatably installed in the middle of the support plate. A turntable is installed on the top of the support plate. Reagent slots are opened at equal intervals inside the turntable. A discharge slot is opened on one side of the front end of the support plate. A stepper motor is installed on the top of the partition. The rotating shaft at the bottom of the stepper motor protrudes from the bottom of the partition and is connected to the top of the main shaft. A scraper is installed at the bottom of the main shaft and is located on the top of the storage box.

[0012] A guide frame is installed between the upper and lower adjacent discharge troughs, and a baffle frame is installed inside the placement trough. The baffle frame is set at the front end of the top of the turntable. Three camera modules are set above each layer of the turntable, and an indicator light is set at the front end of the support plate.

[0013] Preferably, a control component is provided at the rear end of the stepper motor, a hub is provided on one side of the control component, and a lithium battery pack is provided at the front end of the stepper motor.

[0014] Preferably, a touch display module is provided on the front of the top cover, and a power button is provided on one side of the touch display module.

[0015] Preferably, a power button is located at the rear of the casing, an ACV interface is located above the power button, a DCV interface is located to one side of the power button, a reverse button is located to one side of the DCV interface, an Ethernet port is located to one side of the reverse button, a USB interface is located to one side of the Ethernet port, and a SIM card slot is located above the reverse button.

[0016] Preferably, guide plates are fixed on both sides of the bottom inside the casing, a sliding groove is provided at the bottom of the storage box, and a sensing component is provided at the middle of the rear end of the storage box. The sensing component is fixed to the bottom inside the casing.

[0017] Preferably, the size of the chute matches the size of the guide plate, allowing the storage box to slide onto the guide plate via the chute.

[0018] Preferably, a camera module is installed above the fence frame, a camera module is installed in the middle of the turntable, and a camera module is installed at the tail end of the turntable.

[0019] Preferably, the size of the reagent tank matches the size of the discharge tank, and the three guide frames correspond to each other.

[0020] Compared with the prior art, the beneficial effects of this utility model are as follows:

[0021] 1. The circulating reagent detection result imaging acquisition device of this utility model solves the safety hazards of reagent exposure in traditional detection through a closed-loop circulating transmission and processing process. During the reagent reaction stage, the reagent chip is placed in the concave reagent slot of the turntable and circulates with the turntable in a closed loop. No manual contact is required throughout the process, and physical isolation is formed by structures such as the enclosure frame and support plate, which effectively avoids the risk of reagent leakage or infection of operators through contact. It is especially suitable for infectious disease detection scenarios.

[0022] 2. The cyclic reagent detection result imaging acquisition device described in this utility model abandons the traditional manual timing method and achieves timing through the coordinated control of the Linux motherboard and the acquisition driver board. After the operator sets the biological reaction time on the touch display module, the parameters are processed by the Linux motherboard and transmitted to the acquisition driver board via the RS232 interface. The driver board then controls the speed of the stepper motor via the CAN bus, thereby controlling the residence time of the reagent at each node. This automated timing mechanism is not affected by the number of samples. Even when multiple reagents are detected simultaneously, it can still ensure that the reaction time of each reagent is consistent, avoiding the result deviation caused by manual timing errors and significantly improving the reliability of the detection data.

[0023] 3. The circulating reagent testing result imaging acquisition device described in this utility model establishes a complete data association and storage system, solving the problems of lack of process recording and data dispersion in traditional manual judgment. After the patient information is entered through a barcode scanner connected via USB interface, the control component automatically associates and stores the patient information with image data and detection parameters collected from multiple nodes, which can be queried at any time via a touch display module. Simultaneously, the data supports uploading to the cloud system via Ethernet port or SIM card slot, realizing centralized management and sharing of testing data. This function is of great significance for epidemiological investigations and data statistical analysis of infectious diseases, facilitating rapid tracing of case-related information and providing data support for epidemic prevention and control.

[0024] 4. The circulating reagent testing result imaging acquisition device of this utility model adopts a multi-node image acquisition mechanism. As the reagent rotates with the turntable, it passes through three camera modules in sequence. Each node's camera completes image acquisition with the assistance of a supplementary light, ensuring the comprehensiveness of the test image. The acquired image data can be uploaded to the relevant system in real time via Ethernet or 4G network (relying on the 4G module and SIM card slot integrated into the Linux motherboard). Compared with the traditional mobile phone photo upload method, the transmission speed is faster, the stability is higher, and the tedious steps of manual operation are avoided. In addition, the circulating transmission design allows the reagent placement, testing, and storage process to be carried out continuously, significantly shortening the testing cycle of a single reagent.

[0025] 5. The circulating reagent testing result imaging acquisition device described in this utility model reduces personnel dwell time through automated process design. Operators only need to place the reagent chip in the placement slot; subsequent transmission, testing, and storage are all automatically completed by the device. Parameters can be remotely set via a touch display module, eliminating the need for close-range operation. Simultaneously, the multi-reagent circulating processing capability supports batch testing, avoiding the queuing and crowding problems caused by traditional single-sample testing, and reducing the risk of secondary infection from infectious diseases.

[0026] 6. The circulating reagent testing result imaging acquisition device of this utility model features an automated waste reagent collection mechanism. Tested reagents are discharged into a collection box via a discharge chute and guide frame. A scraper driven by the main shaft levels the waste reagents, preventing accumulation and blockage. The collection box's sensing components monitor its installation status in real time, ensuring safe waste reagent storage. This design not only reduces the frequency of manual cleaning but also avoids the problem of waste reagent accumulation affecting equipment operation, thus improving the equipment's continuous working capacity.

[0027] 7. The circulating reagent testing result imaging acquisition device described in this utility model possesses high adaptability and scalability at both the hardware and software levels. The control component adopts the Rockchip RK3288 chip solution, which has powerful image processing capabilities and supports functions such as a 12.3-inch touch display, multi-camera module access, and 4G / Wi-Fi network connection, adapting to the testing needs of different types of reagent chips. In terms of interfaces, it integrates multiple interfaces such as USB, HDMI, Ethernet, and SIM card, supporting peripheral expansion such as barcode scanners, external storage devices, and printers. In terms of application scenarios, it can meet the needs of clinical testing in hospitals and can also be used for reagent analysis in fields such as agriculture, animal husbandry, water quality, and food safety, possessing broad applicability.

[0028] 8. The circulating reagent testing result imaging acquisition device described in this utility model combines professionalism and convenience in its operation design: operators can complete parameter settings and data queries through the touch display module, and the red and green light status of the indicator lights provides intuitive feedback on the reagent placement status; in case of abnormality, pressing the reverse button controls the turntable to reverse and remove the reagent, ensuring operational flexibility. The self-checking function of the control components automatically detects the position of the mechanical structure and the installation status of the storage box when the device is started, proactively avoiding the risk of failure. This user-friendly design reduces the professional skill requirements for operators, making it easy to promote and use in primary healthcare or testing institutions. Attached Figure Description

[0029] Figure 1 The overall structure in this utility model Figure 1 ;

[0030] Figure 2The overall structure in this utility model Figure 2 ;

[0031] Figure 3 This is a front view of the structural cross-section of this utility model;

[0032] Figure 4 This is a breakdown of the rotary mechanism structure in this utility model. Figure 1 ;

[0033] Figure 5 This is a breakdown of the rotary mechanism structure in this utility model. Figure 2 ;

[0034] Figure 6 The rotary mechanism structure in this utility model Figure 1 ;

[0035] Figure 7 The rotary mechanism structure in this utility model Figure 2 ;

[0036] Figure 8 The rotary mechanism structure in this utility model Figure 3 ;

[0037] Figure 9 This is a partial structural diagram of the present invention;

[0038] Figure 10 This is a disassembled structural diagram of the casing and storage box in this utility model;

[0039] Figure 11 This is a structural diagram of the bottom of the storage box in this utility model;

[0040] Figure 12 This is a hardware structure block diagram of this utility model.

[0041] The following are the labeling symbols in the diagram: 1. Housing; 11. Partition; 12. Control component; 13. Lithium battery pack; 14. Hub; 2. Top cover; 21. Power button; 22. Touch display module; 3. Storage box; 31. Guide plate; 32. Sensing component; 33. Slide; 4. Placement slot; 41. Enclosure frame; 42. Indicator light; 43. Material guide frame; 44. Camera module; 5. Power button; 51. AC220V interface; 52. DC24V interface; 53. Reverse button; 54. Ethernet port; 55. USB interface; 56. SIM card slot; 6. Side frame; 61. Support plate; 62. Turntable; 63. Reagent tank; 64. Discharge chute; 65. Main shaft; 66. Stepper motor; 67. Scraper. Detailed Implementation

[0042] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0043] To further understand the content of this utility model, a detailed description of this utility model will be provided in conjunction with the accompanying drawings.

[0044] Combination Figures 1 to 12 As shown, the present invention provides a circulating reagent detection result imaging acquisition device, including a housing 1, a top cover 2, and a placement slot 4. The top cover 2 is provided on the top of the housing 1, and the placement slot 4 is provided at equal intervals on the front of the housing 1. A storage box 3 is provided on the bottom of the housing 1. A partition 11 is installed at the top inside the housing 1 and is located at the bottom of the top cover 2. Side frames 6 are fixed on both sides inside the housing 1, and the top of the side frames 6 is fixedly connected to the partition 11.

[0045] Support plates 61 are installed at equal intervals between the side frames 6. A main shaft 65 is rotatably installed in the middle of the support plate 61. A turntable 62 is installed on the top of the support plate 61. Reagent slots 63 are opened at equal intervals inside the turntable 62. A discharge slot 64 is opened on one side of the front end of the support plate 61. A stepper motor 66 is installed on the top of the partition 11. The shaft at the bottom of the stepper motor 66 protrudes from the bottom of the partition 11 and is connected to the top of the main shaft 65. A scraper 67 is installed at the bottom of the main shaft 65. The scraper 67 is located on the top of the storage box 3.

[0046] A guide frame 43 is installed between adjacent discharge troughs 64. A baffle frame 41 is installed inside the placement trough 4. The baffle frame 41 is located at the front end of the top of the turntable 62. Three camera modules 44 are installed above each turntable 62. An indicator light 42 is installed at the front end of the support plate 61.

[0047] A control component 12 is provided at the rear end of the stepper motor 66, a hub 14 is provided on one side of the control component 12, and a lithium battery pack 13 is provided at the front end of the stepper motor 66.

[0048] A touch display module 22 is provided on the front of the top cover 2, and a power button 21 is provided on one side of the touch display module 22.

[0049] A power button 5 is located at the rear of the casing 1. An AC220V interface 51 is located on the top of the power button 5. A DC24V interface 52 is located on one side of the power button 5. A back button 53 is located on one side of the DC24V interface 52. An Ethernet port 54 is located on one side of the back button 53. A USB interface 55 is located on one side of the Ethernet port 54. A SIM card slot 56 is located above the back button 53.

[0050] Guide plates 31 are fixed on both sides of the bottom inside the casing 1. A sliding groove 33 is provided at the bottom of the storage box 3. A sensing component 32 is provided at the middle position of the rear end of the storage box 3. The sensing component 32 is fixed to the bottom inside the casing 1.

[0051] The dimensions of the slide 33 match the dimensions of the guide plate 31, allowing the storage box 3 to slide onto the guide plate 31 via the slide 33.

[0052] A camera module 44 is set above the fence frame 41, a camera module 44 is set in the middle of the turntable 62, and a camera module 44 is set at the tail end of the turntable 62.

[0053] The dimensions of reagent tank 63 match the dimensions of discharge tank 64, and the three guide frames 43 correspond to each other.

[0054] A method for acquiring imaging results of a cyclic reagent testing device, the method comprising the following steps:

[0055] S1. Equipment Start-up and Initialization: Power is supplied through the AC220V interface 51 or DC24V interface 52 of the housing 1. Press the power button 5 and the power switch button 21 to turn on the equipment. The control component 12 automatically checks the status of each component, including whether the storage box 3 is installed in place through the guide plate 31 and the slide 33 and whether the sensor component 32 provides normal feedback, and whether the mechanical structure of the turntable 62 and the spindle 65 is in the initial position.

[0056] Afterwards, the operator sets the detection parameters through the touch display module 22 on the top cover 2. The parameters are processed by the control component 12 and then transmitted to the relevant components through the hub 14.

[0057] S2. Reagent Placement and Circulation: The operator places the reagent chip into the reagent tank 63 through the enclosure frame 41 of the placement tank 4. At this time, the camera module 44 detects the placed reagent, the indicator light 42 turns red, and the control component 12 controls the stepper motor 66 to run. The stepper motor 66 drives the turntable 62 to rotate through the main shaft 65, realizing the circulation of the reagent.

[0058] S3. Multi-node image acquisition: As the turntable 62 rotates, the reagent passes through three positions in sequence: above the enclosure frame 41, in the middle of the turntable 62, and at the tail end of the turntable 62. The camera module 44 at each position captures images of the reagent, which can be uploaded to the relevant system via Ethernet port 54 or SIM card slot 56.

[0059] S4. Waste reagent collection: The reagents after testing are discharged through the discharge trough 64 in the support plate 61 and discharged into the collection box 3 through the guide frame 43. The main shaft 65 drives the scraper 67 to rotate, which can scrape the waste reagents flat and prevent the waste reagents from accumulating.

[0060] S5. Data Management and Equipment Control: Medical record information is entered through a barcode scanner connected via USB interface 55 and stored in association with test data via control component 12. It can be queried through the touch display module 22 on top cover 2.

[0061] If an abnormality occurs, press the reverse button 53 on the casing 1 to control the turntable 62 to reverse. After the test is completed, press the power button 21 and the power button 5 to turn off the machine.

[0062] Specifically,

[0063] I. Control components (12) include the Linux motherboard and the acquisition driver board;

[0064] (1) Linux motherboard: DC-A288-UN-V05, adopts Rockchip RK3288Cortex-A17 quad-core chip solution, with a frequency of up to 1.6GHz, has strong image processing and computing performance, meets the functional requirements of human-computer interaction, video, industrial control, etc. The onboard interface integrates 4G module and Wi-Fi module, integrates USB port to collect image information from camera module 44, integrates HDMI interface to drive 12.3-inch IPS touch display module 22 for display, integrates audio interface to control speaker for audio output, and supports common external devices.

[0065] (2) Acquisition driver board: The Microchip DSPIC30F5011 is used as the main control chip to acquire the power on / off button 21, the reverse button 53, the storage box 3 position switch and other level signals. The CAN communication circuit is designed to control the DM-J4310-2EC stepper motor 66. The RS232 communication circuit is designed to communicate and interact with the Linux motherboard to drive the fill light and indicator light 42.

[0066] II. External interfaces: SIM card slot 56, USB interface 55, power interface and RJ45 Ethernet port 54;

[0067] (1) SIM card slot 56: SIM card can be inserted.

[0068] (2) USB interface 55: Connect the barcode scanner and transmit the barcode scanner results to this device.

[0069] (3) The power interface is divided into AC220V interface 51 and DC24V interface 52. This device supports DC24V and AC220V power supply. It is not recommended to supply power at the same time.

[0070] (4) RJ45 Ethernet port 54: Supports 100 Mbps network and can connect to the Internet or local area network.

[0071] III. Control buttons include power on / off button 21, power button 5, and rewind button 53:

[0072] (1) Power on / off button 21: One-button switch, which controls the power on or off of the equipment when pressed.

[0073] (2) Reverse button 53: Pressing it controls the turntable 62 to reverse; in case of malfunction or need to check whether the biological reagent chip is effective, it can control the turntable 62 to reverse and take out the chip for inspection.

[0074] (3) Power button 5: The power on / off button for the entire equipment.

[0075] IV. Display Function:

[0076] (1) Touch display module 22: i.e. display screen, the whole machine operates on the 307mm×132mm display screen and displays status.

[0077] (2) Indicator light 42: indicates the status of the equipment, with two states: red and green; located at the reagent placement inlet of each layer.

[0078] V. Data Acquisition Equipment:

[0079] Each turntable 62 of the device has three cameras above it, namely camera modules 44. The cameras are located at the entrance for placing biological reagent chips, the middle of turntable 62, and the tail end of turntable 62, respectively. They have recognition and photography functions to collect data from the biological reagent chips. A supplementary light is placed next to each camera to compensate for the ambient brightness of the biological reagent chips being tested.

[0080] VI. Waste Reagent Storage: The waste reagent storage box 3 is located below the casing 1 and is used to hold the biological reagent chips after the test is completed. An inductive metal proximity switch is installed at the rear of the waste reagent storage box 3 to detect whether the waste reagent storage box 3 is installed in place.

[0081] 7. Barcode scanner: Connects to the device's USB interface 55 and uses the barcode scanner to identify and input medical record information.

[0082] Working principle:

[0083] I. The rotary mechanism consists of a turntable 62, a main shaft 65, and a stepper motor 66;

[0084] The biological reaction time of the biological reagent chip to be tested is set by the touch screen. The screen sends the information to the Linux motherboard through the motherboard. The Linux motherboard then sends the information to the acquisition driver board through the RS232 interface. The acquisition driver board controls the speed of the stepper motor 66 through the CAN bus, thereby controlling the time when the biological reagent chip is placed, so as to achieve cyclic acquisition of the biological reagent chip.

[0085] 2. The storage mechanism consists of a storage box 3, a guide plate 31, a sensing component 32, and a slide 33. The sensing component 32 can be an inductive metal proximity switch.

[0086] When the biological reagent chip is rotated to the last concave reagent slot 63 by the rotary mechanism, the reagent slot 63 is aligned with the discharge slot 64. Due to gravity, the biological reagent chip falls downwards and is finally transferred into the storage box 3 by the guide frame 43. An inductive metal proximity switch is installed at the rear of the storage box 3 to detect whether the storage box 3 is installed in place.

[0087] III. The acquisition mechanism consists of a support plate 61, a camera module 44, and a fill light;

[0088] Each layer of the device has a turntable 62 placed above the support plate 61, which has 11 concave reagent slots 63 for biological reagent chips. The reagent slots 63 have a modular adaptation design that can accommodate biological reagent chips of various shapes.

[0089] The medical record information is transmitted to this device via an external barcode scanner. After the device detects the biological reagent chip, it binds the medical record information to the biological reagent chip and takes two photos of the biological reagent chip. The terminal device uploads the images to the server terminal via Wi-Fi or 4G network, and a professional physician reviews the test results online.

[0090] Applicable testing items include:

[0091] (1) Clinical infectious diseases: AIDS, hepatitis B, hepatitis C, tuberculosis, etc.;

[0092] (2) Agriculture and animal husbandry: drug residues, infectious diseases of livestock and poultry, livestock and poultry diseases, etc.;

[0093] (3) Water quality: toxic and harmful substances such as heavy metals in the water;

[0094] (4) Food safety: pesticide residues, heavy metal residues, etc.

[0095] It should be noted that, in this document, relational terms such as "first" and "second" are used only to distinguish one entity or operation from another, and do not necessarily require or imply any such actual relationship or order between these entities or operations. Furthermore, the terms "comprising," "including," or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such process, method, article, or apparatus.

[0096] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A circulating reagent detection result imaging acquisition device, comprising a housing (1), a top cover (2), and a placement slot (4), characterized in that: The top of the housing (1) is provided with a top cover (2), the front of the housing (1) is provided with equally spaced placement slots (4), the bottom of the housing (1) is provided with a storage box (3), the top of the inside of the housing (1) is provided with a partition (11), the partition (11) is located at the bottom of the top cover (2), and the two sides inside the housing (1) are fixed with side frames (6), the top of the side frames (6) is fixedly connected to the partition (11); Support plates (61) are installed at equal intervals between the side frames (6). A main shaft (65) is rotatably installed in the middle of the support plate (61). A turntable (62) is installed on the top of the support plate (61). A reagent tank (63) is opened at equal intervals inside the turntable (62). A discharge chute (64) is opened on one side of the front end of the support plate (61). A stepper motor (66) is installed on the top of the partition (11). The shaft at the bottom of the stepper motor (66) protrudes from the bottom of the partition (11) and is connected to the top of the main shaft (65). A scraper (67) is installed at the bottom of the main shaft (65). The scraper (67) is located on the top of the storage box (3). A guide frame (43) is installed between the upper and lower adjacent discharge troughs (64), and a baffle frame (41) is installed inside the placement trough (4). The baffle frame (41) is located at the front end of the top of the turntable (62). Three camera modules (44) are installed above each layer of the turntable (62), and an indicator light (42) is installed at the front end of the support plate (61).

2. The cyclic reagent detection result imaging acquisition device according to claim 1, characterized in that: A control component (12) is provided at the rear end of the stepper motor (66), a hub (14) is provided on one side of the control component (12), and a lithium battery pack (13) is provided at the front end of the stepper motor (66).

3. The cyclic reagent detection result imaging acquisition device according to claim 1, characterized in that: The top cover (2) is provided with a touch display module (22) at the front, and a power button (21) is provided on one side of the touch display module (22).

4. The cyclic reagent detection result imaging acquisition device according to claim 1, characterized in that: A power button (5) is provided at the rear end of the casing (1). An AC220V interface (51) is provided at the top of the power button (5). A DC24V interface (52) is provided on one side of the power button (5). A back button (53) is provided on one side of the DC24V interface (52). An Ethernet port (54) is provided on one side of the back button (53). A USB interface (55) is provided on one side of the Ethernet port (54). A SIM card slot (56) is provided above the back button (53).

5. The cyclic reagent detection result imaging acquisition device according to claim 1, characterized in that: Guide plates (31) are fixed on both sides of the bottom of the casing (1). A sliding groove (33) is provided at the bottom of the storage box (3). A sensing component (32) is provided at the middle of the rear end of the storage box (3). The sensing component (32) is fixed to the bottom of the casing (1).

6. The cyclic reagent detection result imaging acquisition device according to claim 5, characterized in that: The size of the slide (33) matches the size of the guide plate (31), and the storage box (3) can slide on the guide plate (31) through the slide (33).

7. The cyclic reagent detection result imaging acquisition device according to claim 1, characterized in that: A camera module (44) is set above the enclosure frame (41), a camera module (44) is set in the middle of the turntable (62), and a camera module (44) is set at the tail end of the turntable (62).

8. The cyclic reagent detection result imaging acquisition device according to claim 1, characterized in that: The size of the reagent tank (63) matches the size of the discharge tank (64), and the three guide frames (43) correspond to each other.