CN116286310A - Laboratory microorganism detection system and detection method thereof - Google Patents

Abstract

The invention relates to biological detection, in particular to a laboratory microorganism detection system and a detection method thereof, wherein the method comprises the following steps: step one: storing the microorganism specimen culture dishes in a plurality of storage spaces; step two: driving the conversion ring and the telescopic mechanism III to move, and moving the microbial specimen culture dish to be taken out to a notch arranged on the accommodating cavity; step three: driving the two rotary semi-rings to move, clamping the microorganism specimen culture dish by the two rotary semi-rings and taking out the microorganism specimen culture dish; the biological specimen stored at any position can be taken out for detection.

Description

Laboratory microorganism detection system and detection method thereof

Technical Field

The invention relates to biological detection, in particular to a laboratory microorganism detection system and a detection method thereof.

Background

In the prior art, there are many technical means for detecting microorganisms, such as CN202110669416.2, a microorganism detection device, a microorganism detection system and a microorganism detection method, which disclose a technical scheme for detecting microorganisms entirely without dead angles by a rotation method, but the patent cannot take out biological samples stored at any position for detection.

Disclosure of Invention

The invention aims to provide a laboratory microorganism detection system and a detection method thereof, which can take out biological samples stored at any positions for detection.

The aim of the invention is achieved by the following technical scheme:

a laboratory microorganism detection method comprising the steps of:

step one: storing the microorganism specimen culture dishes in a plurality of storage spaces;

step two: driving the conversion ring and the telescopic mechanism III to move, and moving the microbial specimen culture dish to be taken out to a notch arranged on the accommodating cavity;

step three: and driving the two rotary semi-rings to move, and clamping and taking out the microbial specimen culture dish by the two rotary semi-rings.

The laboratory microorganism detection system comprises a device support, wherein a screw rod I is rotationally connected to the device support, a power mechanism I for driving the screw rod I to rotate is fixedly connected to the device support, the power mechanism I is preferably a servo motor, a telescopic mechanism I is fixedly connected to the device support, and a mounting frame is fixedly connected to a telescopic end of the telescopic mechanism I;

the device bracket is slidably connected with a sliding block I, the sliding block I is connected to a screw rod I through threads, a positioning belt pulley I is fixedly connected to the sliding block I, a swinging rod I is rotationally connected to the sliding block I, a power mechanism II for driving the swinging rod I to rotate is fixedly connected to the sliding block I, the power mechanism II is preferably a servo motor, a traversing bracket is rotationally connected to the swinging rod I, two screw rods II are rotationally connected to the traversing bracket, a power mechanism III for driving the screw rod II to rotate is fixedly connected to the traversing bracket, the power mechanism III is preferably a servo motor, a centering belt pulley I is fixedly connected to the traversing bracket, the centering belt pulley I is in transmission connection with the positioning belt pulley I, and the transmission ratio between the centering belt pulley I and the positioning belt pulley I is one;

the two sliding blocks II are respectively connected to the two screw rods II through threads, positioning belt wheels II are fixedly connected to the two sliding blocks II, swinging rods II are respectively and rotatably connected to the two sliding blocks II, a power mechanism IV for driving the swinging rods II to rotate is fixedly connected to the sliding blocks II, the power mechanism IV is preferably a servo motor, telescopic mechanisms II are respectively and rotatably connected to the two swinging rods II, clamping half rings are respectively and fixedly connected to the telescopic ends of the two telescopic mechanisms II, two rotating half rings are in transmission connection between the two clamping half rings, friction driving wheels are respectively and rotatably connected to the telescopic ends of the two telescopic mechanisms II, a power mechanism V for driving the friction driving wheels to rotate is fixedly connected to the telescopic ends of the telescopic mechanisms II, the power mechanism V is preferably a servo motor, a centering belt wheel II is fixedly connected to the two telescopic mechanisms II, the two centering belt wheels II are respectively and rotatably connected with the two positioning belt wheels II, and the transmission ratio between the centering belt wheels II and the positioning belt wheels II is one;

fixedly connected with connection pad on the device support, fixedly connected with telescopic machanism III on the connection pad, fixedly connected with accomodates the cavity on telescopic machanism III's the flexible end, be provided with the breach on accomodating the cavity, accomodate a plurality of separation discs of fixedly connected with in the cavity, a plurality of separation discs are separated into accomodating the cavity and are taken in the layer, all rotate in every accomodating the layer and be connected with the change ring, a plurality of rotation baffle of equal fixedly connected with on every change ring, a plurality of rotation baffle separate into a plurality of storage spaces with accomodating the layer, equal fixedly connected with two backup pads in every storage space, equal sliding connection has the clamping board in every backup pad, fixedly connected with compression spring between clamping board and the backup pad, accomodate the power unit VI that the internal fixedly connected with drive change ring of cavity rotates, power unit VI is servo motor preferably.

Drawings

The invention will be described in further detail with reference to the accompanying drawings and detailed description.

FIG. 1 is a schematic diagram of a laboratory microorganism detection method of the present invention;

FIG. 2 is a schematic diagram of a laboratory microorganism detection system of the present invention;

FIG. 3 is a schematic diagram of a laboratory microorganism detection system of the present invention;

FIG. 4 is a schematic view of the device holder structure of the present invention;

FIG. 5 is a schematic view of the sliding block I of the present invention;

FIG. 6 is a schematic view of a slider II according to the present invention;

FIG. 7 is a schematic view of a clamping half ring structure of the present invention;

FIG. 8 is a schematic view of the structure of the accommodating cavity of the present invention;

FIG. 9 is a schematic view of the structure of the accommodating cavity of the present invention;

FIG. 10 is a schematic view of the housing cavity structure of the present invention;

fig. 11 is a schematic structural view of the conversion ring of the present invention.

In the figure:

a device holder 11; a screw rod I12; a telescopic mechanism I13; a mounting rack 14;

a sliding block I21; positioning belt wheel I22; swing lever i 23; traversing the support 24; a screw II 25; righting the belt wheel I26;

a sliding block II 31; positioning belt wheel II 32; swing lever ii 33; a telescopic mechanism II 34; clamping the semi-ring 35; rotating the half ring 36; friction drive wheel 37; righting a belt pulley II 38;

a land 41; telescoping mechanism III 42; a housing cavity 43; a notch 44; a divider disk 45;

a switching ring 51; rotating the baffle plate 52; a support plate 53; and a clamping plate 54.

Detailed Description

The invention is described in further detail below with reference to the accompanying drawings.

As shown in FIG. 1, the steps and functions of a laboratory microorganism detection method are described in detail below;

a laboratory microorganism detection method comprising the steps of:

step one: storing the microorganism specimen culture dishes in a plurality of storage spaces;

step two: the conversion ring 51 and the telescopic mechanism III 42 are driven to move, and the microbial specimen culture dish to be taken out is moved to a notch 44 arranged on the accommodating cavity 43;

step three: the two rotary half rings 36 are driven to move, and the two rotary half rings 36 clamp and take out the microorganism specimen culture dish.

As shown in fig. 2 to 11, in order to facilitate the implementation of a laboratory microorganism detection method, a laboratory microorganism detection system is designed, and the structure and function of the laboratory microorganism detection system will be described in detail;

the laboratory microorganism detection system comprises a device bracket 11, wherein a screw rod I12 is rotationally connected to the device bracket 11, a power mechanism I for driving the screw rod I12 to rotate is fixedly connected to the device bracket 11, the power mechanism I is preferably a servo motor, a telescopic mechanism I13 is fixedly connected to the device bracket 11, and a mounting frame 14 is fixedly connected to a telescopic end of the telescopic mechanism I13;

the device bracket 11 is slidably connected with a sliding block I21, the sliding block I21 is connected to a screw rod I12 through threads, a positioning belt wheel I22 is fixedly connected to the sliding block I21, a swinging rod I23 is rotatably connected to the sliding block I21, a power mechanism II for driving the swinging rod I23 to rotate is fixedly connected to the sliding block I21, the power mechanism II is preferably a servo motor, a traversing bracket 24 is rotatably connected to the swinging rod I23, two screw rods II 25 are rotatably connected to the traversing bracket 24, a power mechanism III for driving the screw rod II 25 to rotate is fixedly connected to the traversing bracket 24, the power mechanism III is preferably a servo motor, a centering belt wheel I26 is fixedly connected to the traversing bracket 24, the centering belt wheel I26 is in transmission connection with the positioning belt wheel I22, and the transmission ratio between the centering belt wheel I26 and the positioning belt wheel I22 is one;

the transverse moving support 24 is slidably connected with two sliding blocks II 31, the two sliding blocks II 31 are respectively connected to two screw rods II 25 through threads, positioning belt wheels II 32 are fixedly connected to the two sliding blocks II 31, swinging rods II 33 are rotatably connected to the two sliding blocks II 31, a power mechanism IV for driving the swinging rods II 33 to rotate is fixedly connected to the sliding blocks II 31, the power mechanism IV is preferably a servo motor, telescopic mechanisms II 34 are rotatably connected to the two swinging rods II 33, clamping half rings 35 are fixedly connected to telescopic ends of the two telescopic mechanisms II 34, two rotating half rings 36 are in transmission connection between the two clamping half rings 35, friction driving wheels 37 are rotatably connected to telescopic ends of the two telescopic mechanisms II 34, friction driving wheels 37 are in friction transmission with the two rotating half rings 36 respectively, a power mechanism V for driving the friction driving wheels 37 to rotate is fixedly connected to telescopic ends of the telescopic mechanisms II 34, the power mechanism V is preferably a servo motor, two centering belt wheels II 38 are fixedly connected to the two centering belt wheels II 38 and are respectively connected with the two positioning belt wheels 32 and a transmission ratio II 32;

the device bracket 11 is fixedly connected with a connecting disc 41, the connecting disc 41 is fixedly connected with a telescopic mechanism III 42, the telescopic end of the telescopic mechanism III 42 is fixedly connected with a storage cavity 43, a notch 44 is arranged on the storage cavity 43, a plurality of separation discs 45 are fixedly connected in the storage cavity 43, the storage cavity 43 is divided into a plurality of storage layers by the plurality of separation discs 45, a conversion ring 51 is rotatably connected in each storage layer, a plurality of rotary baffles 52 are fixedly connected to each conversion ring 51, the storage layers are divided into a plurality of storage spaces by the plurality of rotary baffles 52, two support plates 53 are fixedly connected in each storage space, clamping plates 54 are fixedly connected to each support plate 53 in a sliding manner, compression springs are fixedly connected between the clamping plates 54 and the support plates 53, a power mechanism VI for driving the conversion rings 51 to rotate is fixedly connected in the storage cavity 43, and the power mechanism VI is preferably a servo motor.

When the detecting device is used, as shown in fig. 3, a detecting device to be used is arranged on the mounting frame 14, the telescopic mechanism I13 is started, the telescopic mechanism I13 can be a hydraulic cylinder or an electric push rod, the telescopic end of the telescopic mechanism I13 drives the mounting frame 14 to move, the height of the mounting frame 14 is adjusted, the mounting frame 14 can drive the detecting device to be used to move, the height of the detecting device to be used is adjusted, and different use requirements are met;

each accommodating space is internally provided with a temperature control mechanism, the temperature control mechanism can be a refrigerating mechanism or a heating mechanism, the temperature in each accommodating space is controlled, the temperature of each accommodating space can be regulated according to different use requirements, a microorganism specimen culture dish is placed in each accommodating space, as shown in fig. 11, the microorganism specimen culture dish or the culture dish in which the microorganism specimen is placed between two clamping plates 54, the two clamping plates 54 clamp the side edges of the culture dish, the culture dish is further fixed, a plurality of rotating baffles 52 separate accommodating layers, a certain heat preservation and insulation effect is achieved, and each accommodating space can be regulated in temperature according to the culture requirements of the culture dish, so that different use requirements are met;

further, a closing door is provided at the notch 44 provided on the accommodating cavity 43, although not shown in the figure, a person skilled in the art may set the closing door according to different use requirements, and the closing door is provided to open and close the notch 44;

when the culture dish at any position needs to be taken out for detection, a telescopic mechanism III 42 is started, the telescopic mechanism III 42 can be a hydraulic cylinder or an electric push rod, and the telescopic end of the telescopic mechanism III 42 drives the accommodating cavity 43 to move, so that the height of the accommodating cavity 43 is adjusted, the heights of a plurality of accommodating spaces are adjusted, and the height of the accommodating space needing to take out the culture dish can be clamped by the two clamping semi-rings 35;

a plurality of power mechanisms VI are arranged in the accommodating cavity 43, the power mechanisms VI can drive the conversion rings 51 to rotate respectively, further, according to different use requirements, the power mechanisms VI are started, the output shafts of the power mechanisms VI start to rotate, the output shafts of the power mechanisms VI drive the conversion rings 51 to rotate, the conversion rings 51 drive the supporting plates 53 to rotate, the supporting plates 53 drive the two clamping plates 54 to rotate, and further, the culture dish is driven to rotate, so that the culture dish moves to the notch 44, the closing door is opened, and the culture dish can be taken out;

as shown in fig. 3 and 2, the process of taking out is from fig. 3 to fig. 2, fig. 2 is in the state of taking out, fig. 3 is in the state of observing, a power mechanism ii is started, an output shaft of the power mechanism ii starts to rotate, the output shaft of the power mechanism ii drives a swinging rod i 23 to swing, the swinging rod i 23 drives a traversing bracket 24 to swing, in the process of swinging the traversing bracket 24, because a positioning belt wheel i 22 is fixed, the positioning belt wheel i 22 fixes the centering belt wheel i 26, the centering belt wheel i 26 cannot rotate relatively, the centering belt wheel i 26 fixes the traversing bracket 24, the traversing bracket 24 always keeps in a horizontal state in the process of swinging the swinging rod i 23, a power mechanism iv starts to rotate, the output shaft of the power mechanism iv drives a swinging rod ii 33 to swing, the swinging rod ii 33 drives a telescopic mechanism ii 34 to move, the telescopic mechanism ii 34 drives a clamping half ring 35 to move, and the clamping half ring 35 drives a rotating half ring 36 to move, and in the process of fixing the positioning belt wheel ii 32 is fixedly connected to a sliding block ii 31, the positioning belt wheel ii 32 fixes the centering belt wheel i 26, the traversing belt wheel i 24 always keeps in a horizontal state in the process of swinging rod ii, and the two belt wheels 38 cannot rotate relatively in the horizontal state of swinging ii, and the two belt wheels 33 are always in the horizontal state of swinging ii 38;

further, the two rotating half rings 36 move to two sides of the culture dish to be taken out, the telescopic mechanism II 34 is started, the telescopic mechanism II 34 can be a hydraulic cylinder or an electric push rod, the telescopic end of the telescopic mechanism II 34 drives the clamping half ring 35 to move, the clamping half ring 35 drives the rotating half ring 36 to move, the two rotating half rings 36 are close to each other to clamp the culture dish, the power mechanism II and the power mechanism IV are started again, and the culture dish is detected from the state shown in the figure 2 to the state shown in the figure 3;

further, the power mechanism III can be started according to different use requirements, the output shaft of the power mechanism III starts to rotate, the output shaft of the power mechanism III drives the screw rod II 25 to rotate, the screw rod II 25 drives the sliding block II 31 to move through threads when rotating, the sliding block II 31 transversely moves, the sliding block II 31 drives the swinging rod II 33 to transversely move, the swinging rod II 33 drives the telescopic mechanism II 34 to move, the telescopic mechanism II 34 drives the clamping semi-ring 35 to move, the clamping semi-ring 35 drives the rotating semi-ring 36 to move, and the two rotating semi-rings 36 move to different positions according to different use requirements;

further, the power mechanism I can be started according to different use requirements, the output shaft of the power mechanism I starts to rotate, the output shaft of the power mechanism I drives the screw rod I12 to rotate, the screw rod I12 drives the sliding block I21 to move through threads when rotating, the sliding block I21 moves transversely, the sliding block I21 drives the swinging rod I23 to move transversely, the swinging rod I23 drives the transverse moving support 24 to move transversely, and then the position of the transverse moving support 24 is adjusted according to different use requirements;

further, as shown in fig. 3, in the process of detection, since the culture dish can be required to be rotated during detection, the detection angle of the culture dish can be adjusted, the power mechanism V is started, the output shaft of the power mechanism V starts to rotate, the output shaft of the power mechanism V drives the friction driving wheel 37 to rotate, the friction driving wheel 37 drives the rotating half rings 36 to rotate, and the two rotating half rings 36 rotate to drive the culture dish to rotate, so that the angle of the culture dish can be adjusted, and different detection requirements can be met;

it should be noted that, after the detection is completed, the two rotating half rings 36 need to be reset, so that the two rotating half rings 36 respectively move into the two clamping half rings 35, thereby ensuring that the two clamping half rings 35 can be separated; after the detection is completed, moving from fig. 3 to fig. 2, the culture dish is put back into the receiving cavity 43.

Claims (10)

1. A laboratory microorganism detection method, characterized in that: the method comprises the following steps:

step one: storing the microorganism specimen culture dishes in a plurality of storage spaces;

step two: the conversion ring (51) and the telescopic mechanism III (42) are driven to move, and the microbial specimen culture dish to be taken out is moved to a notch (44) arranged on the accommodating cavity (43);

step three: the two rotary half rings (36) are driven to move, and the two rotary half rings (36) clamp and take out the microbial specimen culture dish.

2. A laboratory microorganism detection method according to claim 1, wherein: the accommodating cavity (43) is fixedly connected to the telescopic end of the telescopic mechanism III (42), the telescopic mechanism III (42) is fixedly connected to the connecting disc (41), and the connecting disc (41) is fixedly connected to the device bracket (11).

3. A laboratory microorganism detection method according to claim 2, wherein: the device bracket (11) is rotatably connected with a screw rod I (12).

4. A laboratory microorganism detection method according to claim 2, wherein: the device is characterized in that a telescopic mechanism I (13) is fixedly connected to the device support (11), and a mounting frame (14) is fixedly connected to the telescopic end of the telescopic mechanism I (13).

5. A laboratory microorganism detection method according to claim 3, wherein: the device is characterized in that a sliding block I (21) is connected to the device support (11) in a sliding mode, the sliding block I (21) is connected to the screw rod I (12) through threads, a swinging rod I (23) is connected to the sliding block I (21) in a rotating mode, a traversing support (24) is connected to the swinging rod I (23) in a rotating mode, and two screw rods II (25) are connected to the traversing support (24) in a rotating mode.

6. A laboratory microorganism detection method according to claim 5, wherein: the sliding block I (21) is fixedly connected with a positioning belt wheel I (22), the transverse moving support (24) is fixedly connected with a righting belt wheel I (26), the righting belt wheel I (26) is in transmission connection with the positioning belt wheel I (22), and the transmission ratio between the righting belt wheel I (26) and the positioning belt wheel I (22) is one.

7. A laboratory microorganism detection method according to claim 5, wherein: the sliding support is characterized in that two sliding blocks II (31) are connected to the sliding support (24) in a sliding mode, the two sliding blocks II (31) are respectively connected to the two screw rods II (25) through threads, swing rods II (33) are respectively connected to the two sliding blocks II (31) in a rotating mode, telescopic mechanisms II (34) are respectively connected to the two swing rods II (33) in a rotating mode, clamping half rings (35) are respectively fixedly connected to telescopic ends of the two telescopic mechanisms II (34), two rotating half rings (36) are connected between the two clamping half rings (35) in a transmission mode, friction driving wheels (37) are respectively connected to the telescopic ends of the two telescopic mechanisms II (34) in a rotating mode, and the two friction driving wheels (37) are respectively in friction transmission with the two rotating half rings (36).

8. A laboratory microorganism detection method according to claim 7, wherein: the two sliding blocks II (31) are fixedly connected with positioning belt wheels II (32), the two telescopic mechanisms II (34) are fixedly connected with centering belt wheels II (38), the two centering belt wheels II (38) are respectively connected with the two positioning belt wheels II (32) in a transmission way, and the transmission ratio between the centering belt wheels II (38) and the positioning belt wheels II (32) is one.

9. A laboratory microorganism detection method according to claim 7, wherein: a plurality of separation discs (45) are fixedly connected in the accommodating cavity (43), and the accommodating cavity (43) is separated into a plurality of accommodating layers by the plurality of separation discs (45).

10. A laboratory microorganism detection method according to claim 9, wherein: all rotate in every storage layer and be connected with conversion ring (51), all fixedly connected with a plurality of rotation baffle (52) on every conversion ring (51), a plurality of storage spaces are separated into with the storage layer to a plurality of rotation baffle (52), all fixedly connected with two backup pads (53) in every storage space, all sliding connection has clamping board (54) on every backup pad (53), fixedly connected with compression spring between clamping board (54) and the backup pad (53).

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