CN219079521U - Microorganism detecting instrument - Google Patents

Abstract

The utility model relates to a microorganism detection instrument, and belongs to the technical field of detection equipment. The method mainly aims at the problem of low detection efficiency; the device comprises a detection frame, a support frame, a digital microscope, a storage table, a battery and a cover plate; the detection frame is provided with a placing groove and a mounting groove; the support frame is arranged on the detection frame; the digital microscope is arranged on the detection frame in a sliding way; the support frame is provided with an adjusting mechanism for driving the digital microscope to move along the vertical direction; the storage table is provided with a storage groove; the storage grooves are uniformly arranged on the object placing table in a circular ring shape for one circle; the detection frame is provided with a driving mechanism for driving the object placing table to intermittently drive; the battery is arranged in the detection frame and is electrically connected with the driving mechanism and the digital microscope; the battery is detachably connected with the detection frame; the apron sets up on detecting the frame, and the apron is connected with detecting the frame is removable. The utility model can rapidly and continuously detect microorganisms and greatly improve the detection efficiency.

Description

Microorganism detecting instrument

Technical Field

The utility model relates to the technical field of detection equipment, in particular to a microorganism detection instrument.

Background

Microorganisms are a collective term for all microorganisms that are difficult for an individual to observe with the naked eye. Microorganisms include bacteria, viruses, fungi, and a few algae, among others. One of the most important effects of microorganisms on humans is the prevalence of infectious diseases. Of the human diseases, 50% are caused by viruses. Microorganisms have led to a history of human diseases, i.e. a history of human fight against them. In the prevention and treatment of diseases, human beings have made great progress, but newly emerging and reproduced microbial infections continue to occur, like a great number of viral diseases, there is a constant lack of effective therapeutic drugs.

In the prior art, when detecting microorganisms, a culture dish is required to be placed in a detection area of a detector, the detector is started to detect, after detection is completed, the detector is closed, the culture dish is taken out, a new culture dish is taken out and placed in the detection area of the detector to detect, and the steps are required to be repeated; the waiting time of feeding and discharging is increased, and the detection efficiency is reduced.

Disclosure of Invention

The utility model aims at solving the problems in the background technology and provides a microorganism detection instrument capable of rapidly and continuously detecting.

The technical scheme of the utility model is as follows: a microorganism detecting instrument comprises a detecting frame, a supporting frame, a digital microscope, a storage table, a battery and a cover plate;

the detection frame is provided with a placing groove and a mounting groove; the support frame is arranged on the detection frame; the digital microscope is arranged on the detection frame in a sliding way; the support frame is provided with an adjusting mechanism for driving the digital microscope to move along the vertical direction; the storage table is provided with a storage groove; the storage grooves are uniformly arranged on the object placing table in a circular ring shape for one circle; the detection frame is provided with a driving mechanism for driving the object placing table to intermittently drive; the battery is arranged in the detection frame and is electrically connected with the driving mechanism and the digital microscope; the battery is detachably connected with the detection frame; the battery is positioned at the mounting groove; the apron sets up on detecting the frame, and the apron is located mounting groove department, and the apron is connected with detecting the frame is removable.

Preferably, the adjusting mechanism comprises a hand wheel, a screw rod and a lifting block; the lifting block is arranged on the supporting frame in a sliding way; the screw rod is rotatably arranged on the support frame; the lifting block is in threaded connection with the screw rod; the hand wheel is arranged at the upper end of the screw rod; the digital microscope is arranged on the lifting block.

Preferably, the driving mechanism comprises a driving motor, a driving dial and a grooved wheel; the driving motor is arranged on the detection frame, and the output end of the driving motor is connected with the driving dial; the grooved pulley is arranged on the object placing table; the driving plate is meshed with the grooved pulley.

Preferably, a supporting plate is arranged in the detection frame; the driving motor is arranged on the supporting plate; the grooved pulley is rotationally connected with the supporting plate.

Preferably, the detection frame is provided with a fixed limit column and a movable limit column; the cover plate is provided with a limit groove; the limit grooves are two; the cover plate is clamped with the fixed limit column and the movable limit column; the movable limit column is connected with the detection frame in a sliding way; the detection frame is provided with a pushing mechanism for pushing the movable limit column to move; the pushing mechanism comprises a sliding column and an elastic piece; the detection frame is provided with a sliding groove; the sliding column is arranged in the sliding groove; the movable limiting column is arranged on the sliding column in a sliding way; the elastic component sets up in the periphery side of slip post, and the both ends of elastic component are connected with detection frame and activity spacing post respectively.

Preferably, a light supplementing lamp is arranged in the detection frame; the light supplementing lamp is positioned at the digital microscope; the battery is electrically connected with the light supplementing lamp.

Preferably, the lower end of the detection frame is provided with a plurality of foot pads.

Compared with the prior art, the utility model has the following beneficial technical effects:

in the utility model, a culture dish to be detected is put into a storage groove from a placement groove, and a supporting plate is used for supporting a driving motor and a grooved wheel; the driving motor drives the driving plate to rotate, the driving plate and the grooved pulley are meshed for transmission, thereby the grooved pulley rotates a certain angle, each time the driving plate rotates a circle, the grooved pulley rotates once, the grooved pulley drives the storage table to rotate, thereby the detection sample in the storage groove can be driven to rotate to the lower part of the digital microscope, detection is carried out through the digital microscope, the detection process is smoother through adjusting the rotating speed of the driving motor, and the efficiency is high, thereby the culture dish at the storage groove can be moved to the detection frame, dust and bacteria are prevented from falling into the culture dish, and the culture dish after detection is moved to the storage groove, an operator can take out, after taking out, the new culture dish to be detected can be placed again, the storage groove can be just rotated to the lower part of the digital microscope in sequence, the culture dish can be detected in sequence, the rotating speed of the storage groove can be regulated, the detection process is smoother and the efficiency is high, the detection of substances in the digital microscope in the culture dish can be detected, the operation is not affected, the loading and unloading are prevented, therefore, the detection efficiency can be improved, the culture dish can be placed back to the detection sequence in sequence, and the culture dish can be sequentially placed in sequence, and the result can be avoided.

Drawings

FIG. 1 is a schematic diagram of an embodiment of the present utility model;

FIG. 2 is a cross-sectional view of an embodiment of the present utility model;

FIG. 3 is a schematic view of a partial structure of an embodiment of the present utility model;

fig. 4 is a partial structural cross-sectional view of an embodiment of the present utility model.

Reference numerals: 1. a detection frame; 101. a placement groove; 102. a mounting groove; 103. a sliding groove; 2. a support frame; 3. a digital microscope; 4. an adjusting mechanism; 401. a hand wheel; 402. a screw rod; 403. a lifting block; 5. a light supplementing lamp; 6. a storage table; 601. a storage groove; 7. a driving mechanism; 701. a driving motor; 702. an active dial; 703. a sheave; 8. a support plate; 9. a battery; 10. a cover plate; 1001. a limit groove; 111. fixing a limit column; 112. a movable limit column; 12. a pushing mechanism; 1201. a sliding column; 1202. an elastic member.

Detailed Description

Example 1

As shown in fig. 1-4, the microorganism detecting instrument provided by the utility model comprises a detecting rack 1, a supporting rack 2, a digital microscope 3, a placing table 6, a battery 9 and a cover plate 10;

the detection frame 1 is provided with a placement groove 101 and a mounting groove 102; the support frame 2 is arranged on the detection frame 1; the digital microscope 3 is arranged on the detection frame 1 in a sliding way; the support frame 2 is provided with an adjusting mechanism 4 for driving the digital microscope 3 to move along the vertical direction; the storage tank 601 is arranged on the object placing table 6; the storage tanks 601 are provided with a plurality of storage tanks 601, and the storage tanks 601 are uniformly arranged on the object placing table 6 in a circular ring shape for one circle; the detection frame 1 is provided with a driving mechanism 7 for driving the object placing table 6 to intermittently drive; the battery 9 is arranged in the detection frame 1, and the battery 9 is electrically connected with the driving mechanism 7 and the digital microscope 3; the battery 9 is detachably connected with the detection frame 1; the battery 9 is positioned at the mounting groove 102; the cover plate 10 is arranged on the detection frame 1, the cover plate 10 is positioned at the mounting groove 102, and the cover plate 10 is detachably connected with the detection frame 1. A light supplementing lamp 5 is arranged in the detection frame 1; the light supplementing lamp 5 is positioned at the digital microscope 3; the battery 9 is electrically connected with the light supplementing lamp 5; the light filling lamp 5 can make the light filling carry out in the darker messenger of environment, conveniently detects. The lower end of the detection frame 1 is provided with a plurality of foot pads; the callus on the sole can make the detection frame 1 place more steadily.

The drive mechanism 7 includes a drive motor 701, a drive dial 702, and a sheave 703; the driving motor 701 is arranged on the detection frame 1, and the output end of the driving motor 701 is connected with the driving dial 702; the grooved pulley 703 is arranged on the object placing table 6; the driving dial 702 is engaged with the sheave 703. A supporting plate 8 is arranged in the detection frame 1; the driving motor 701 is provided on the support plate 8; the sheave 703 is rotatably connected to the support plate 8.

The digital microscope displayed by the computer is adopted to transmit the sample image seen by the microscope to the computer through a camera arranged in the microscope, and the microscopic image analysis software arranged on the computer is used for tracking and analyzing, so that a series of valuable qualitative and quantitative data are obtained. The method is mainly used for microorganism identification, cell morphology examination, urine forming component analysis, fiber fineness detection and the like. Has the characteristics of full-automatic scanning, strong image analysis function, strong expansibility and the like

In this embodiment, the culture dish to be detected is placed into the storage tank 601 from the placement tank 101, and the support plate 8 is used for supporting the driving motor 701 and the sheave 703; the driving motor 701 drives the driving plate 702 to rotate, the driving plate 702 and the grooved pulley 703 are meshed for transmission, thereby the grooved pulley 703 rotates a certain angle, each time the driving plate 702 rotates a circle, the grooved pulley 703 rotates once, the grooved pulley 703 drives the storage table 6 to rotate, thereby the detection sample in the storage tank 601 can be driven to rotate to the lower part of the digital microscope 3, detection is carried out through the digital microscope 3, the detection process can be smoother through adjusting the rotating speed of the driving motor 701, and the efficiency is high, thereby the culture dish at the position of the storage tank 101 can be moved into the detection frame 1, dust and bacteria are prevented from falling into the culture dish, and the culture dish after detection is moved to the position of the storage tank 101, so that an operator can take out, after taking out, a new culture dish to be detected can be placed again, when the driving mechanism 7 drives the storage table 6 to rotate, the storage tank 601 can be just sequentially rotated to the lower part of the digital microscope 3, thereby the detection process can be more smooth and the efficiency is high, the detection process can be carried out by adjusting the rotating speed of the driving mechanism 7, the storage table 6 can be more smoothly, the detection process can be more disordered, the detection process can be carried out in the digital microscope, the detection process can not be sequentially influenced by the detection process, and the detection process can be sequentially placed in the detection process, and the detection result can be sequentially and can be sequentially improved, and can be sequentially placed, and the detection result can be prevented from being sequentially and placed in the position 101.

Example two

As shown in fig. 1-4, in comparison with the first embodiment, the adjusting mechanism 4 of the present embodiment includes a hand wheel 401, a screw 402 and a lifting block 403; the lifting block 403 is arranged on the support frame 2 in a sliding way; the screw rod 402 is rotatably arranged on the support frame 2; the lifting block 403 is in threaded connection with the screw rod 402; the hand wheel 401 is arranged at the upper end of the screw rod 402; the digital microscope 3 is provided on the lifting block 403.

In this embodiment, when the position of the digital microscope 3 needs to be adjusted, the hand wheel 401 is rotated, the hand wheel 401 drives the screw rod 402 to rotate, the screw rod 402 drives the lifting block 403 to move, and the lifting block 403 drives the digital microscope 3 to move, so that the digital microscope 3 is adjusted to move, and the position of the digital microscope 3 can be reasonably adjusted and controlled according to the detection object.

Example III

As shown in fig. 1-4, in the microorganism detecting apparatus according to the present utility model, compared with the first embodiment or the second embodiment, the fixed limiting column 111 and the movable limiting column 112 are disposed on the detecting rack 1 in the present embodiment; the cover plate 10 is provided with a limit groove 1001; two limit grooves 1001 are provided; the cover plate 10 is clamped with the fixed limit column 111 and the movable limit column 112; the movable limit column 112 is in sliding connection with the detection frame 1; the detection frame 1 is provided with a pushing mechanism 12 for pushing the movable limiting column 112 to move. The pushing mechanism 12 includes a slide column 1201 and an elastic member 1202; the detection frame 1 is provided with a sliding groove 103; the slide column 1201 is provided in the slide groove 103; the movable limiting column 112 is slidably arranged on the sliding column 1201; the elastic member 1202 is provided on the outer peripheral side of the slide column 1201, and both ends of the elastic member 1202 are connected to the detection frame 1 and the movable stopper column 112, respectively.

In this embodiment, when the cover plate 10 is installed, firstly, one limit groove 1001 of the cover plate 10 is aligned with the fixed limit post 111 and is inserted into the limit groove 1001, then the other limit groove 1001 is aligned with the movable limit post 112, the movable limit post 112 is pushed, the movable limit post 112 can move to the limit groove 1001 and is inserted into the limit groove 1001, the elastic piece 1202 pushes the movable limit post 112 to move, the movable limit post 112 is clamped on the cover plate 10 and can limit the cover plate 10, and the movement of the cover plate 10 is prevented.

The embodiments of the present utility model have been described in detail with reference to the drawings, but the present utility model is not limited thereto, and various changes can be made within the knowledge of those skilled in the art without departing from the spirit of the present utility model.

Claims (7)

1. The microorganism detection instrument is characterized by comprising a detection frame (1), a support frame (2), a digital microscope (3), a storage table (6), a battery (9) and a cover plate (10);

a placing groove (101) and a mounting groove (102) are arranged on the detection frame (1); the support frame (2) is arranged on the detection frame (1); the digital microscope (3) is arranged on the detection frame (1) in a sliding way; an adjusting mechanism (4) for driving the digital microscope (3) to move along the vertical direction is arranged on the supporting frame (2); a storage groove (601) is arranged on the object placing table (6); the storage tanks (601) are provided with a plurality of storage tanks (601), and the storage tanks (601) are uniformly arranged on the object placing table (6) in a circle in a ring shape; a driving mechanism (7) for driving the object placing table (6) to intermittently drive is arranged on the detection frame (1); the battery (9) is arranged in the detection frame (1), and the battery (9) is electrically connected with the driving mechanism (7) and the digital microscope (3); the battery (9) is detachably connected with the detection frame (1); the battery (9) is positioned at the mounting groove (102); the cover plate (10) is arranged on the detection frame (1), the cover plate (10) is positioned at the installation groove (102), and the cover plate (10) is detachably connected with the detection frame (1).

2. A microbiological detection device according to claim 1, wherein the adjustment mechanism (4) comprises a hand wheel (401), a screw (402) and a lifting block (403); the lifting block (403) is arranged on the supporting frame (2) in a sliding way; the screw rod (402) is rotatably arranged on the support frame (2); the lifting block (403) is in threaded connection with the screw rod (402); the hand wheel (401) is arranged at the upper end of the screw rod (402); the digital microscope (3) is arranged on the lifting block (403).

3. A microbiological detection device according to claim 1, wherein the drive mechanism (7) comprises a drive motor (701), a drive plate (702) and a sheave (703); the driving motor (701) is arranged on the detection frame (1), and the output end of the driving motor (701) is connected with the driving dial (702); the grooved wheel (703) is arranged on the object placing table (6); the driving plate (702) is meshed with the grooved wheel (703).

4. A microbiological detection device according to claim 3, wherein a support plate (8) is provided in the detection frame (1); the driving motor (701) is arranged on the supporting plate (8); the grooved wheel (703) is rotatably connected with the supporting plate (8).

5. A microbiological detection device according to claim 1, characterized in that the detection frame (1) is provided with a fixed limit column (111) and a movable limit column (112); a limit groove (1001) is formed in the cover plate (10); two limit grooves (1001) are formed; the cover plate (10) is clamped with the fixed limit column (111) and the movable limit column (112); the movable limit column (112) is in sliding connection with the detection frame (1); a pushing mechanism (12) for pushing the movable limiting column (112) to move is arranged on the detection frame (1); the pushing mechanism (12) comprises a sliding column (1201) and an elastic piece (1202); a sliding groove (103) is arranged on the detection frame (1); the sliding column (1201) is arranged in the sliding groove (103); the movable limiting column (112) is arranged on the sliding column (1201) in a sliding way; the elastic piece (1202) is arranged on the outer periphery side of the sliding column (1201), and two ends of the elastic piece (1202) are respectively connected with the detection frame (1) and the movable limiting column (112).

6. A microbiological detection device according to claim 1, characterized in that a light-supplementing lamp (5) is arranged in the detection frame (1); the light supplementing lamp (5) is positioned at the digital microscope (3); the battery (9) is electrically connected with the light supplementing lamp (5).

7. A microbiological detection device according to claim 1, wherein the lower end of the detection frame (1) is provided with a plurality of foot pads.

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