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CN-224231632-U - Full-automatic observation device

CN224231632UCN 224231632 UCN224231632 UCN 224231632UCN-224231632-U

Abstract

The utility model belongs to the technical field of laboratory detection, and discloses a full-automatic observation device which comprises a shell, a bearing assembly and a camera, wherein the bearing assembly and the camera are arranged in the shell, the bearing assembly is used for placing a plurality of sample tubes, the camera is positioned above the bearing assembly and is used for shooting the sample tubes, the bearing assembly can drive the sample tubes to move towards or away from the camera, and a control system is arranged on the shell and is used for controlling the lifting or lowering of the bearing assembly, the opening and closing of the camera and the temperature and humidity in the shell. According to the utility model, the carrying assembly and the camera can prevent an operator from repeatedly taking the sample for observation, so that the operator can observe and analyze the image data shot by the camera, manual repeated operation is effectively avoided, the observation process is simplified, the pollution risk of the sample is greatly reduced, and meanwhile, the temperature and the humidity in the shell can be controlled by the control system, so that the test environment is in a constant temperature and humidity state, and the test accuracy is improved.

Inventors

  • WANG CHUNXU
  • ZHOU WENLING
  • LIU WENFENG
  • LU ZHIHUA
  • GAO YONGLIANG
  • WU FENGJI
  • BAI XIAOLING

Assignees

  • 蒙牛乳业(唐山)有限责任公司
  • 内蒙古蒙牛乳业(集团)股份有限公司

Dates

Publication Date
20260512
Application Date
20250529

Claims (10)

  1. 1. Full-automatic viewing device, its characterized in that includes: The device comprises a shell (100), and a bearing assembly (10) and a camera (20) which are arranged in the shell (100), wherein the bearing assembly (10) is used for placing a plurality of sample test tubes, the camera (20) is positioned above the bearing assembly (10) and is used for shooting the sample test tubes, and the bearing assembly (10) can drive the sample test tubes to move towards or away from the camera (20); The shell (100) is provided with a control system for controlling the lifting or descending of the bearing assembly (10), the opening and closing of the camera (20) and the temperature and humidity in the shell (100).
  2. 2. The full-automatic observation device according to claim 1, wherein the carrying assembly (10) is provided with three groups, and the three groups of carrying assemblies (10) are all arranged in the shell (100) at intervals along the vertical direction, and each group of carrying assemblies (10) is provided with at least 10 stations for placing the sample tubes.
  3. 3. The full-automatic observation device according to claim 1, wherein the bearing assembly (10) comprises a telescopic rod (11), a bearing frame (13) and a fixing frame (14), the telescopic rod (11) is arranged along the vertical direction, the bearing frame (13) is arranged at the top end of the telescopic rod (11), the fixing frame (14) is detachably connected to the bearing frame (13), and the sample test tube is inserted into the fixing frame (14).
  4. 4. A fully automatic viewing device according to claim 3, wherein the carrying assembly (10) further comprises a motor (12), the motor (12) being adapted to drive the telescopic rod (11) to extend or retract.
  5. 5. A fully automatic viewing device according to claim 3, characterized in that the carrier (13) is magnetically connected to the holder (14).
  6. 6. A fully automatic viewing device according to claim 3, wherein a plurality of stations are provided on the holder (14), and each station is provided with an elastic grip in which the sample tube is inserted.
  7. 7. The full-automatic observation device according to claim 1, wherein two cameras (20) are provided, and the two cameras (20) are respectively provided at two opposite sides of the inner top of the housing (100), and heating plates are provided on the cameras (20) to heat the lenses.
  8. 8. The full-automatic observation device according to claim 7, further comprising an illumination lamp (30), wherein the illumination lamp (30) is disposed between the two cameras (20) for a light source at the time of photographing.
  9. 9. The fully automatic viewing device according to claim 1, wherein the control system comprises a first control system (40) and a second control system (50), the carrying assembly (10) and the camera (20) are communicatively connected to the first control system (40), the first control system (40) is used for controlling the lifting or lowering of the carrying assembly (10), the residence time after lifting or lowering, and the opening and closing of the camera (20), and the second control system (50) is used for monitoring and controlling the temperature and the humidity in the housing (100).
  10. 10. The full-automatic viewing device according to claim 1, further comprising a broadcast speaker (60) and a mobile device, wherein the broadcast speaker (60) is disposed outside the housing (100) and is configured to perform a voice alert at the end of the test, and the mobile device is communicatively connected to the full-automatic viewing device to support remote software viewing and test report downloading.

Description

Full-automatic observation device Technical Field The utility model relates to the technical field of laboratory detection, in particular to a full-automatic observation device. Background At present, a laboratory is required to detect hot-washed samples, which are usually placed in a refrigerator at a temperature of 2-8 ℃ and the tissue state of the samples in the test tube is required to be observed once a day and kept stand for more than 72 hours, namely, the samples are required to be observed for 3 times in the whole test process. Because the observation time is overlong, the operator easily forgets to observe the node, and the observation times are more, the temperature in the refrigerator has fluctuation change after the refrigerator is opened for many times, the constant temperature and humidity conditions in the test process can not be reached, and the sample needs to be taken out each time when being observed, and the sample is replaced in the refrigerator after being observed, and the process is complex and extremely easy to pollute the sample, so that the experimental result is not accurate enough. Therefore, how to effectively avoid manual repeated operation, simplify the observation process, reduce the sample pollution risk, and further improve the detection efficiency and the accuracy of the test result is a problem to be solved by the current person in the field. Disclosure of utility model The utility model aims to provide a full-automatic observation device, which is used for effectively avoiding manual repeated operation, simplifying the observation process, reducing the sample pollution risk and further improving the detection efficiency and the accuracy of test results. To achieve the purpose, the utility model adopts the following technical scheme: full-automatic viewing device, wherein includes: The device comprises a shell, a bearing assembly and a camera, wherein the bearing assembly is arranged in the shell and is used for placing a plurality of sample test tubes, the camera is positioned above the bearing assembly and is used for shooting the sample test tubes, and the bearing assembly can drive the sample test tubes to move towards or away from the camera; The shell is provided with a control system for controlling the lifting or descending of the bearing assembly, the opening and closing of the camera, and the temperature and humidity in the shell. Optionally, the carrying assembly is provided with three groups, and the three groups of carrying assemblies are all arranged in the shell at intervals along the vertical direction, and each group of carrying assemblies is provided with at least one station for placing the sample test tube. Optionally, the bearing assembly includes a telescopic rod, a bearing frame and a fixing frame, the telescopic rod is arranged along the vertical direction, the bearing frame is arranged at the top end of the telescopic rod, the fixing frame is detachably connected with the bearing frame, and the sample test tube is inserted into the fixing frame. Optionally, the bearing assembly further comprises a motor for driving the telescopic rod to extend or retract. Optionally, the bearing frame is connected with the fixing frame through magnetic attraction. Optionally, a plurality of stations are arranged on the fixing frame, each station is provided with an elastic gripper, and the sample test tube is inserted into the elastic gripper. Optionally, two cameras are arranged, the two cameras are respectively arranged on two opposite sides of the inner top of the shell, and heating plates are arranged on the cameras to heat the lenses. Optionally, an illuminating lamp is further arranged between the two cameras for providing a light source during shooting. Optionally, the control system comprises a first control system and a second control system, the bearing assembly and the camera are connected to the first control system in a communication way, the first control system is used for controlling the rising or falling of the bearing assembly, the residence time after rising or falling, and the starting and stopping of the camera, and the second control system is used for monitoring and controlling the temperature and the humidity in the shell. Optionally, a broadcast loudspeaker and a mobile device are further arranged, wherein the broadcast loudspeaker is arranged on the outer side of the shell, and is used for carrying out voice reminding when the test is finished, and the mobile device is in communication connection with the full-automatic observation device so as to support remote software to check and test report downloading. The utility model has the beneficial effects that: According to the utility model, the plurality of sample tubes are supported and clamped through the bearing assembly, and the sample tubes are shot by the camera above the bearing assembly, so that the operator can be prevented from repeatedly taking the sample for observation, the o