CN218404204U - Full-automatic food source microorganism sampler - Google Patents

Abstract

The utility model discloses a full-automatic food source microorganism sample thief relates to sampling equipment technical field, including the detection case, the last fixed surface of detection case installs air device, the right side fixed mounting of detection case has chamber door one, the right side fixedly connected with handle one of chamber door one, the positive fixed mounting of detection case has the observation window, the left side fixed mounting of detection case has chamber door two. The utility model discloses a pulling handle two, make fixed connection be pulled open at the chamber door two on handle two right sides to make the left side of detection case opened, thereby reach the inner chamber that the staff of being convenient for will wait to detect food and put into the detection case, simultaneously through pulling handle one, make fixed connection be pulled open at the left chamber door of handle one, thereby make the right side of detection case opened, thereby reach the upper surface that the staff of being convenient for puts the culture dish fixed connection at the brace table of the inner chamber bottom of detection case.

Description

Full-automatic food source microorganism sampler

Technical Field

The utility model relates to a sampling equipment technical field, concretely relates to full-automatic food source microorganism sample thief.

Background

The microorganisms comprise bacteria, viruses, fungi, some small protists, microalgae and the like, and a large biological population which is tiny and closely related to human beings covers various beneficial and harmful species and widely relates to the fields of food, medicine, industry and agriculture, environmental protection, sports and the like.

When the full-automatic foodborne microorganism sampler is used, the existing full-automatic foodborne microorganism sampler is inconvenient to rapidly extract objects to be detected; when the full-automatic food-borne microorganism sampler is used, microorganisms in the air cannot be discharged by the existing full-automatic food-borne microorganism sampler, and the later detection is inaccurate.

SUMMERY OF THE UTILITY MODEL

The utility model provides a full-automatic food source microorganism sample thief to solve the problem that proposes in the above-mentioned background art.

In order to solve the technical problem, the utility model discloses the technical scheme who adopts is:

the utility model provides a full-automatic food source microorganism sample thief, includes the detection case, the last fixed surface of detection case installs air device, the right side fixed mounting of detection case has chamber door one, the right side fixedly connected with handle one of chamber door one, the positive fixed mounting of detection case has the observation window, the left side fixed mounting of detection case has chamber door two, the left side fixedly connected with handle two of chamber door two.

The inner chamber fixedly connected with hydraulic stem of detection case is one, the last fixed surface of hydraulic stem one is connected with the tray, the upper surface overlap joint of tray has the screen panel, the upper surface overlap joint of screen panel has suction means, suction means's inner chamber fixed mounting has the air-blower, the round hole has been seted up to suction means's lower surface, suction means's last fixed surface is connected with the pipeline, the outer wall rigid coupling of pipeline has the mount, the upper surface of mount and the inner chamber fixed connection of detection case.

The air outlet has been seted up to air device's upper surface, air device's inner chamber is fixed to have cup jointed the vacuum pump, the lower fixed surface of vacuum pump is connected with hydraulic stem two, the lower surface of vacuum pump and the right side fixed mounting that is located hydraulic stem two have the inlet scoop, the lower fixed surface of hydraulic stem two is connected with rubber buffer two, the outer wall of rubber buffer two cup joints with air device's inner chamber activity, the export has been seted up to air device's lower surface.

The utility model discloses technical scheme's further improvement lies in: the outer wall of pipeline just is located the fixed stop that has cup jointed on right side of mount, fixed stop's right side just is located the lower fixed surface of pipeline and is connected with the control box, the right side of pipeline just is located the right side fixed mounting of control box and has air device.

The utility model discloses technical scheme's further improvement lies in: the outer wall of the upper end of the air device is fixedly sleeved with the inner cavity of the detection box, the inner cavity of the detection box is fixedly connected with a supporting table, and a culture dish is lapped on the upper surface of the supporting table and below the air device.

The utility model discloses technical scheme's further improvement lies in: the inner chamber bottom fixedly connected with motor of control box, the last fixed surface of motor is connected with the drive rim plate, the last fixed surface of drive rim plate is connected with and supports rotary mechanism, the last fixed surface who supports rotary mechanism installs the threaded rod, the outer wall of threaded rod cup joints with the inner chamber screw thread of control box.

The utility model discloses technical scheme's further improvement lies in: the upper surface of threaded rod fixedly connected with rubber buffer one, the outer wall of rubber buffer one cup joints with the inner chamber activity of pipeline.

The utility model discloses technical scheme's further improvement lies in: the supporting and rotating mechanism comprises a triangular support, the lower surface of the triangular support is fixedly connected with the upper surface of the driving wheel disc, the outer wall of the triangular support is movably sleeved with a ball body, the upper surface of the ball body is fixedly connected with a second ring, the outer wall of the second ring is movably sleeved with a pull rod, the upper end inner cavity of the pull rod is movably sleeved with a first ring, and the upper surface of the first ring is fixedly connected with the lower surface of the threaded rod.

Owing to adopted above-mentioned technical scheme, the utility model discloses relative prior art, the technological progress who gains is:

1. the utility model provides a full-automatic food source microorganism sampler, which adopts the mutual matching of a second handle, a second box door, a detection box, a first hydraulic rod, a tray, a mesh cover, a suction device, a fixing frame, a pipeline, an air blower, a first pulling handle, a first box door, a culture dish, a support table and a first box door, and the second box door fixedly connected with the right side of the second handle is pulled open by pulling the second handle, so that the left side of the detection box is opened, thereby facilitating a worker to place food to be detected into an inner cavity of the detection box, and simultaneously, the first box door fixedly connected with the left side of the first handle is pulled open by pulling the first handle, thereby the right side of the detection box is opened, thereby facilitating the worker to place the culture dish on the upper surface of the support table fixedly connected with the bottom of the inner cavity of the detection box, and close the first box door, through the effect of the hydraulic stem one of fixed connection in the inner chamber bottom of detection case, make the tray of fixed connection at a hydraulic stem upper surface reciprocate, thereby make the screen panel rebound of overlap joint at the tray upper surface, thereby reach and fix the screen panel between suction means and tray, thereby prevent that the waiting of tray upper surface from waiting to detect food and dropping, effect through the mount of fixed connection at the inner chamber of detection case, make the pipeline of fixed cup joint at the mount inner wall fix in the inner chamber of detection case, thereby make the suction means of fixed connection at the pipeline lower surface fix the upper surface at the screen panel, effect through the air-blower of fixed mounting at suction means's inner chamber, make the food of tray upper surface get into suction means's inner chamber under the filtration of screen panel, thereby reach the mesh of drawing the test sample fast.

2. The utility model provides a full-automatic food source microorganism sampler, which adopts the mutual matching of a motor, a driving wheel disc, a triangular support, a ball body, a ring II, a pull rod, a ring I, a threaded rod, a control box, a rubber plug I, a pipeline, a hydraulic rod II, a rubber plug II, an air device, a vacuum pump, an air suction inlet, a detection box, an air outlet and a culture dish, the driving wheel disc fixedly connected with the upper surface of the motor is rotated by starting the motor, so that the triangular support fixedly connected with the upper surface of the driving wheel disc is rotated, the ring II fixedly connected with the upper surface of the ball body is rotated by driving the pull rod under the action of the triangular support under the action of the ball body movably sleeved on the outer wall of the triangular support, so that the ring I movably sleeved in the inner cavity of the pull rod is rotated, thereby the threaded rod fixedly connected with the upper surface of the ring I is moved upwards under the action of the control box, thereby the rubber plug I fixedly connected with the upper surface of the threaded rod moves upwards, thereby the inner cavity of the pipeline is blocked, meanwhile, the rubber plug II fixedly connected with the lower surface of the hydraulic rod II moves upwards under the action of the hydraulic rod II, thereby the lower surface of the air device is opened, the air in the inner cavity at the right side of the detection box is discharged from the air outlet through the air suction port under the action of the vacuum pump, thereby the purpose of improving the detection result is achieved, the vacuum pump is closed, the lower surface of the air device is closed under the action of the hydraulic rod II, the inner cavity of the pipeline is opened under the action of the motor, the vacuum pump is started at the same time, thereby the food in the inner cavity of the suction device enters the inner cavity of the air device through the pipeline, the inner cavity of the pipeline is blocked under the action of the motor, and under the action of the vacuum pump, the air that makes the entering is discharged once more to reach the purpose that improves the testing result, through the effect of hydraulic stem two, make the lower surface of air device opened, make food drop to the upper surface of culture dish from the export, thereby reach the purpose of collecting the microorganism in the food.

Drawings

Fig. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic cross-sectional view of the present invention;

FIG. 3 is a schematic cross-sectional view of the air device of the present invention;

fig. 4 is a schematic sectional structural view of the control box of the present invention;

fig. 5 is an enlarged schematic view of the a position of the present invention.

In the figure: 1. a detection box; 2. an air device; 3. a first box door; 4. a first handle; 5. an observation window; 6. a second box door; 7. a second handle; 11. a first hydraulic rod; 12. a tray; 13. a support table; 14. a mesh enclosure; 15. a suction device; 16. a fixed mount; 17. a pipeline; 18. a control box; 19. a culture dish; 110. fixing a baffle plate; 151. a blower; 152. a circular hole; 181. a rubber plug I; 182. a threaded rod; 183. a motor; 184. a drive wheel disc; 185. a supporting and rotating mechanism; 1851. a first circular ring; 1852. a pull rod; 1853. a second circular ring; 1854. a sphere; 1855. a triangular bracket; 21. an air outlet; 22. a vacuum pump; 23. a second hydraulic rod; 24. a rubber plug II; 25. an outlet; 26. an air suction opening.

Detailed Description

The present invention will be described in further detail with reference to the following examples:

example 1

As shown in fig. 1-5, the utility model provides a full-automatic food source microorganism sample thief, including detection case 1, the last fixed surface of detection case 1 installs air device 2, the right side fixed mounting of detection case 1 has first chamber door 3, the right side fixedly connected with handle one 4 of first chamber door 3, the positive fixed mounting of detection case 1 has observation window 5, the left side fixed mounting of detection case 1 has second chamber door 6, the left side fixedly connected with handle two 7 of second chamber door 6, the inner chamber fixedly connected with hydraulic stem one 11 of detection case 1, the last fixed surface of hydraulic stem one 11 is connected with tray 12, the upper surface of tray 12 has mesh enclosure 14, the upper surface of mesh enclosure 14 has suction device 15, suction device 15's inner chamber fixed mounting has air-blower 151, suction device 15's lower surface has seted up round hole 152, suction device 15's last fixed surface is connected with pipeline 17, pipeline 17's outer wall fixed cover has connect with mount 16, the upper surface of mount 16 and detection case 1's inner chamber fixed connection, air outlet 21 has been seted up to the upper surface of air device 2, air device 2's inner chamber has round hole 22, the lower fixed surface of vacuum pump 22 has the lower surface of vacuum pump 22, the outer wall fixed mounting of two, the outer wall of vacuum pump 23 has the outer wall of vacuum pump 23, the outer wall fixed mounting has the outer wall of vacuum pump 23 is connected with the air plug 24 that the air outlet of two is connected with two, the air plug 24, the air plug is located the air outlet of air outlet 24, the outer chamber 24 of air plug 2, the outer wall fixed mounting of air plug 23, the inner chamber fixed mounting of two outer wall of air plug 23, the air plug 23 is connected with the air plug 23, the inner chamber fixed mounting of air plug 24.

In the embodiment, by pulling the second handle 7, the second door 6 fixedly connected to the right side of the second handle 7 is pulled open, so that the left side of the detection box 1 is opened, thereby achieving the purpose that a worker can put food to be detected into the inner cavity of the detection box 1, and simultaneously by pulling the first handle 4, the first door 3 fixedly connected to the left side of the first handle 4 is pulled open, thereby the right side of the detection box 1 is opened, thereby achieving the purpose that the worker can put a culture dish 19 on the upper surface of a support platform 13 fixedly connected to the bottom of the inner cavity of the detection box 1, close the first door 3, enable air in the inner cavity at the right side of the detection box 1 to be discharged through the action of the air device 2, and enable a tray 12 fixedly connected to the upper surface of the first hydraulic rod 11 to move up and down through the action of the first hydraulic rod 11 fixedly connected to the bottom of the inner cavity of the detection box 1, so that the mesh enclosure 14 lapped on the upper surface of the tray 12 moves upwards, thereby fixing the mesh enclosure 14 between the suction device 15 and the tray 12, thereby preventing the food to be detected on the upper surface of the tray 12 from falling off, the pipeline 17 fixedly sleeved on the inner wall of the fixing frame 16 is fixed in the inner cavity of the detection box 1 under the action of the fixing frame 16 fixedly connected on the inner cavity of the detection box 1, thereby the suction device 15 fixedly connected on the lower surface of the pipeline 17 is fixed on the upper surface of the mesh enclosure 14, the food on the upper surface of the tray 12 enters the inner cavity of the suction device 15 under the filtration of the mesh enclosure 14 under the action of the blower 151 fixedly arranged in the inner cavity of the suction device 15, the food in the inner cavity of the suction device 15 enters the inner cavity of the air device 2 through the pipeline 17 by starting the vacuum pump 22, the inner cavity of the pipeline 17 is blocked under the action of the motor 183, and the action of the vacuum pump 22, the air is discharged again, so as to improve the detection result, and the lower surface of the air device 2 is opened by the action of the second hydraulic rod 23, so that the food falls from the outlet 25 to the upper surface of the culture dish 19.

Example 2

As shown in fig. 1-5, on the basis of embodiment 1, the utility model provides a technical solution: preferably, the outer wall of pipeline 17 just is located the fixed stop 110 that has cup jointed in right side of mount 16, the right side of fixed stop 110 just is located the lower fixed surface of pipeline 17 and is connected with control box 18, the right side of pipeline 17 just is located the right side fixed mounting of control box 18 and has air device 2, the upper end outer wall of air device 2 cup joints with the inner chamber of detection case 1 is fixed, the inner chamber fixed connection of detection case 1 has a supporting bench 13, the upper surface of supporting bench 13 just is located the below overlap joint of air device 2 and has culture dish 19.

In the embodiment, by pulling the second handle 7, the second door 6 fixedly connected to the right side of the second handle 7 is pulled open, so that the left side of the detection box 1 is opened, thereby facilitating the worker to put the food to be detected into the inner cavity of the detection box 1, and by pulling the first handle 4, the first door 3 fixedly connected to the left side of the first handle 4 is pulled open, thereby facilitating the worker to put the culture dish 19 on the upper surface of the support platform 13 fixedly connected to the bottom of the inner cavity of the detection box 1, and close the first door 3, and by the action of the first hydraulic rod 11 fixedly connected to the bottom of the inner cavity of the detection box 1, the tray 12 fixedly connected to the upper surface of the first hydraulic rod 11 can move up and down, thereby make the screen panel 14 of overlap joint at tray 12 upper surface to the rebound, thereby reach and fix screen panel 14 between suction means 15 and tray 12, thereby prevent that the food that awaits measuring of tray 12 upper surface from dropping, through the effect of the mount 16 of fixed connection at the inner chamber of detection case 1, make fixed cup connect in the inner chamber of detection case 1 is fixed to pipeline 17 of mount 16 inner wall, thereby make the suction means 15 of fixed connection at the pipeline 17 lower surface fix the upper surface at screen panel 14, through the effect of the air-blower 151 of fixed mounting at the inner chamber of suction means 15, make the food of tray 12 upper surface get into the inner chamber of suction means 15 under the filtration of screen panel 14, thereby reach the mesh of drawing the detection sample fast.

Example 3

As shown in fig. 1-5, on the basis of embodiment 1, the utility model provides a technical solution: preferably, the bottom of the inner cavity of the control box 18 is fixedly connected with the motor 183, the upper surface of the motor 183 is fixedly connected with the driving wheel disc 184, the upper surface of the driving wheel disc 184 is fixedly connected with the supporting rotating mechanism 185, the upper surface of the supporting rotating mechanism 185 is fixedly provided with the threaded rod 182, the outer wall of the threaded rod 182 is in threaded sleeve joint with the inner cavity of the control box 18, the upper surface of the threaded rod 182 is fixedly connected with the first rubber plug 181, the outer wall of the first rubber plug 181 is movably sleeved with the inner cavity of the pipeline 17, the supporting rotating mechanism 185 comprises a triangular bracket 1855, the lower surface of the triangular bracket 1855 is fixedly connected with the upper surface of the driving wheel disc 184, the outer wall of the triangular bracket 1855 is movably sleeved with the ball 1854, the upper surface of the ball 1854 is fixedly connected with a second ring 1853, the outer wall of the second ring 1853 is movably sleeved with a pull rod 1852, the inner cavity at the upper end of the pull rod 1852 is movably sleeved with a first ring 1851, and the upper surface of the first ring 1851 is fixedly connected with the lower surface of the threaded rod 182.

In this embodiment, the motor 183 is started to rotate the driving wheel 184 fixedly connected to the upper surface of the motor 183, so as to rotate the triangular bracket 1855 fixedly connected to the upper surface of the driving wheel 184, and the ring two 1853 fixedly connected to the upper surface of the ball 1854 is driven by the triangular bracket 1855 to rotate the pull rod 1852 under the action of the ball 1854 movably sleeved on the outer wall of the triangular bracket 1855, so as to rotate the ring one 1851 movably sleeved in the inner cavity of the pull rod 1852, so as to move the threaded rod 182 fixedly connected to the upper surface of the ring one 1851 upward under the action of the control box 18, so as to move the rubber plug one 181 fixedly connected to the upper surface of the threaded rod 182 upward, so as to block the inner cavity of the pipeline 17, and to move the rubber plug two 24 fixedly connected to the lower surface of the hydraulic rod two 23 upward under the action of the hydraulic rod two 23, so that the lower surface of the air device 2 is opened, the air in the right inner cavity of the detection box 1 is exhausted from the air outlet 21 through the air suction opening 26 by the action of the vacuum pump 22, thereby achieving the purpose of improving the detection result, the vacuum pump 22 is closed, the lower surface of the air device 2 is closed by the action of the hydraulic rod II 23, the inner cavity of the pipeline 17 is opened by the action of the motor 183, the vacuum pump 22 is started simultaneously, so that the food in the inner cavity of the suction device 15 enters the inner cavity of the air device 2 through the pipeline 17, the inner cavity of the pipeline 17 is blocked by the action of the motor 183, the entered air is exhausted again by the action of the vacuum pump 22, thereby achieving the purpose of improving the detection result, the lower surface of the air device 2 is opened by the action of the hydraulic rod II 23, so that the food falls to the upper surface of the culture dish 19 from the outlet 25, thereby achieving the purpose of collecting the microorganisms in the food.

The working principle of the fully automatic food source microorganism sampler is described in detail below.

As shown in fig. 1-5, by pulling the second handle 7, the second door 6 fixedly connected to the right side of the second handle 7 is pulled open, so that the left side of the detection box 1 is opened, thereby facilitating the worker to place the food to be detected into the inner cavity of the detection box 1, and by pulling the first handle 4, the first door 3 fixedly connected to the left side of the first handle 4 is pulled open, thereby facilitating the worker to place the culture dish 19 on the upper surface of the support platform 13 fixedly connected to the bottom of the inner cavity of the detection box 1, closing the first door 3, and by starting the motor 183, the driving wheel disc 184 fixedly connected to the upper surface of the motor 183 is rotated, thereby causing the tripod 1855 fixedly connected to the upper surface of the driving wheel disc 184 to rotate, and by the action of the ball 1854 movably sleeved on the outer wall of the tripod 1855, the second ring 1853 fixedly connected to the upper surface of the sphere 1854 drives the pull rod 1852 to rotate under the action of the triangular bracket 1855, so that the first ring 1851 movably sleeved in the inner cavity of the pull rod 1852 rotates, so that the threaded rod 182 fixedly connected to the upper surface of the first ring 1851 moves upwards under the action of the control box 18, so that the first rubber plug 181 fixedly connected to the upper surface of the threaded rod 182 moves upwards to block the inner cavity of the pipeline 17, and the second rubber plug 24 fixedly connected to the lower surface of the second hydraulic rod 23 moves upwards under the action of the second hydraulic rod 23, so that the lower surface of the air device 2 is opened, air in the inner cavity on the right side of the detection box 1 is exhausted from the air outlet 21 through the air suction port 26 under the action of the vacuum pump 22, the vacuum pump 22 is closed, and the lower surface of the air device 2 is closed under the action of the second hydraulic rod 23, the inner cavity of the pipeline 17 is opened through the action of the motor 183, the tray 12 fixedly connected to the upper surface of the hydraulic rod 11 can move up and down through the action of the hydraulic rod 11 fixedly connected to the bottom of the inner cavity of the detection box 1, so that the mesh enclosure 14 overlapped on the upper surface of the tray 12 moves upwards, and the mesh enclosure 14 is fixed between the suction device 15 and the tray 12, so that food to be detected on the upper surface of the tray 12 is prevented from falling off, the pipeline 17 fixedly sleeved on the inner wall of the fixed frame 16 is fixed in the inner cavity of the detection box 1 through the action of the fixed frame 16 fixedly connected to the inner cavity of the detection box 1, so that the suction device 15 fixedly connected to the lower surface of the pipeline 17 is fixed on the upper surface of the mesh enclosure 14, the food on the upper surface of the tray 12 enters the inner cavity of the suction device 15 under the filtering of the mesh enclosure 14 through the action of the air blower 151 fixedly installed in the inner cavity of the suction device 15, the vacuum pump 22 is started, so that the food in the inner cavity of the suction device 15 enters the inner cavity of the air device 2 through the action of the motor 183, the action of the air outlet of the vacuum pump 22, so that the air outlet of the food is opened, and the culture dish 2 is improved, and the culture device 23 is further, and the culture dish 2 is improved.

The present invention has been described in general terms, but it will be apparent to those skilled in the art that modifications and improvements can be made based on the present invention. Therefore, modifications or improvements without departing from the spirit of the invention are within the scope of the invention.

Claims (6)

1. The utility model provides a full-automatic food source microorganism sample thief, includes detection case (1), its characterized in that: the air device (2) is fixedly installed on the upper surface of the detection box (1), a box door I (3) is fixedly installed on the right side of the detection box (1), a handle I (4) is fixedly connected to the right side of the box door I (3), an observation window (5) is fixedly installed on the front side of the detection box (1), a box door II (6) is fixedly installed on the left side of the detection box (1), and a handle II (7) is fixedly connected to the left side of the box door II (6);

the detection device comprises a detection box (1), a first hydraulic rod (11) is fixedly connected to the inner cavity of the detection box (1), a tray (12) is fixedly connected to the upper surface of the first hydraulic rod (11), a mesh enclosure (14) is lapped on the upper surface of the tray (12), a suction device (15) is lapped on the upper surface of the mesh enclosure (14), an air blower (151) is fixedly mounted in the inner cavity of the suction device (15), a round hole (152) is formed in the lower surface of the suction device (15), a pipeline (17) is fixedly connected to the upper surface of the suction device (15), a fixing frame (16) is fixedly connected to the outer wall of the pipeline (17), and the upper surface of the fixing frame (16) is fixedly connected with the inner cavity of the detection box (1);

air outlet (21) have been seted up to the upper surface of air device (2), vacuum pump (22) have been cup jointed to the inner chamber fixed of air device (2), the lower fixed surface of vacuum pump (22) is connected with two (23) hydraulic stems, the right side fixed mounting that the lower surface of vacuum pump (22) just is located two (23) hydraulic stems has inlet scoop (26), the lower fixed surface of two (23) hydraulic stems is connected with rubber buffer two (24), the outer wall of rubber buffer two (24) cup joints with the inner chamber activity of air device (2), export (25) have been seted up to the lower surface of air device (2).

2. The fully automatic food-borne microorganism sampler according to claim 1, wherein: the outer wall of pipeline (17) just is located the fixed stop (110) that has cup jointed in right side of mount (16), the right side of fixed stop (110) just is located lower fixed surface of pipeline (17) and is connected with control box (18), the right side of pipeline (17) just is located the right side fixed mounting of control box (18) and has air device (2).

3. The fully automatic food-borne microorganism sampler according to claim 1, wherein: the upper end outer wall of air device (2) cup joints with the inner chamber of detection case (1) is fixed, the inner chamber fixedly connected with brace table (13) of detection case (1), the upper surface of brace table (13) and the below overlap joint that is located air device (2) have culture dish (19).

4. The fully automatic food-borne microorganism sampler according to claim 2, wherein: the inner chamber bottom fixedly connected with motor (183) of control box (18), the last fixed surface of motor (183) is connected with drive rim plate (184), the last fixed surface of drive rim plate (184) is connected with supports rotary mechanism (185), the last fixed surface who supports rotary mechanism (185) installs threaded rod (182), the outer wall of threaded rod (182) and the inner chamber screw thread of control box (18) cup joint.

5. The fully automatic food-borne microorganism sampler according to claim 4, wherein: the upper surface fixed connection of threaded rod (182) has rubber buffer (181), the outer wall of rubber buffer (181) and the inner chamber activity of pipeline (17) are cup jointed.

6. The fully automatic food-borne microorganism sampler according to claim 4, wherein: the supporting and rotating mechanism (185) comprises a triangular support (1855), the lower surface of the triangular support (1855) is fixedly connected with the upper surface of the driving wheel disc (184), a sphere (1854) is movably sleeved on the outer wall of the triangular support (1855), a second ring (1853) is fixedly connected with the upper surface of the sphere (1854), a pull rod (1852) is movably sleeved on the outer wall of the second ring (1853), a first ring (1851) is movably sleeved on an inner cavity at the upper end of the pull rod (1852), and the upper surface of the first ring (1851) is fixedly connected with the lower surface of the threaded rod (182).

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