CN114814098B

CN114814098B - Korean arborvitae test analysis equipment

Info

Publication number: CN114814098B
Application number: CN202210436534.3A
Authority: CN
Inventors: 陶雷; 单琳; 高敏杰; 赵佳; 郭洪生; 孙红艳; 王新莹
Original assignee: Heilongjiang Forest Botanical Garden (heilongjiang Forest Plant Institute); Northeast Forestry University
Current assignee: Heilongjiang Forest Botanical Garden (heilongjiang Forest Plant Institute); Northeast Forestry University
Priority date: 2022-04-25
Filing date: 2022-04-25
Publication date: 2023-01-24
Anticipated expiration: 2042-04-25
Also published as: CN114814098A

Abstract

The invention relates to the field of scientific research, in particular to Korean thuja test analysis equipment. Whole artificial touching is avoided, avoids extra microorganism to influence experiment analysis result, and the test tube is disinfected the back and is directly used, reduces air pollution. The sterilizing equipment, the mobile device, the back-pull device, the transfer device, a pedestal, shine the test tube with the ultraviolet lamp, the door handle that shifts makes the sterilizing door shift up, shift the handle and make the test-tube rack move, shift the back-pull handle, make back drawstring pole drive back-pull through the back drawstring cover and rotate the seat and move, the installation prevents changeing the dog, shift the handle and make the rotation silk braid shift branch through shifting the fixed rod area and shift up, the test tube clamping jaw centre gripping test tube under clamping jaw connecting rod and clamping jaw pressure spring effect, the connection gear is shifted in the updraught, shift away and prevent changeing the dog, open the motor, make motor transfer gear pass through the transfer gear and make the clamping part change, motor gear makes the double gear that shifts take the test-tube rack to rotate simultaneously, the test-tube rack is rotated in the area, make thuja sample fully fuse with experimental reagent.

Description

Korean arborvitae test analysis equipment

Technical Field

The invention relates to the field of scientific research, in particular to a Korean thuja test analysis device.

Background

For example, CN202110115565.4 is a high-efficiency mixing and dissolving device for pharmaceutical test analysis, which relates to the technical field of pharmaceutical tests, and particularly relates to a high-efficiency mixing and dissolving device for pharmaceutical test analysis, which solves the problem that the internal volume of a stirring device cannot be changed according to the amount of prepared reagents, and solid particles are difficult to dissolve by stirring.

Disclosure of Invention

The invention aims to provide a Korean arborvitae test analysis device, which avoids human touch in the whole process, avoids influence of additional microorganisms on an experimental analysis result, is directly used after a test tube is sterilized and reduces air pollution.

The purpose of the invention is realized by the following technical scheme:

a Korean arborvitae test analysis device comprises a sterilization device, a moving device, a back-pull device, a transfer device and a base, wherein the sterilization device is connected with the base, the moving device is connected with the base, the back-pull device is connected with the transfer device, and the base of the transfer device is connected with the transfer device.

As a further optimization of the technical scheme, the invention provides a korean arborvitae test analysis device, wherein the sterilization device comprises a sterilization housing, an ultraviolet lamp, a door moving screw rod seat, a door moving screw rod, a door moving handle, a door moving screw sleeve, a door moving connecting seat, a door moving sliding block and a sterilization door, the ultraviolet lamp is fixedly connected with the sterilization housing, the door moving screw rod seat is welded with the sterilization housing, the door moving screw rod is rotatably connected with the door moving screw rod seat, the door moving handle is fixedly connected with the door moving screw rod, the door moving screw sleeve is in threaded connection with the door moving screw rod, the door moving screw sleeve is welded with the door moving connecting seat, the door moving connecting seat is in sliding connection with the door moving sliding block, and the sterilization door is welded with the door moving connecting seat.

As a further optimization of the technical solution, the moving device of the analysis device for the korean arborvitae test comprises a moving handle, a moving screw rod, a moving screw sleeve, a test tube rack, a moving slide block, a moving slide rail a and a moving slide rail B, wherein the moving handle is fixedly connected with the moving screw rod, the moving screw sleeve is in threaded connection with the moving screw rod, the test tube rack is fixedly connected with the moving screw sleeve, the moving slide block is fixedly connected with the test tube rack, and the moving slide block is respectively in sliding connection with the moving slide rail a and the moving slide rail B.

As a further optimization of the technical solution, the invention provides a korean thuja test analysis device, wherein the backward pulling device comprises a backward pulling handle, a backward pulling rod seat, a backward pulling rod, a backward pulling slide rod, a backward pulling sleeve, a backward pulling rotation seat and an anti-rotation stop block, the backward pulling handle is fixedly connected with the backward pulling rod, the backward pulling rod is rotatably connected with the backward pulling rod seat, the backward pulling slide rod is fixedly connected with the backward pulling rod seat, the backward pulling sleeve is in threaded connection with the backward pulling rod, the backward pulling sleeve is in sliding connection with the backward pulling slide rod, the backward pulling rotation seat is in welded connection with the backward pulling sleeve, and the anti-rotation stop block is in fit connection with the backward pulling sleeve.

As a further optimization of the technical solution, the invention provides a korean arborvitae test analysis device, which comprises a transfer handle, a transfer screw rod, a rotary screw sleeve, a transfer support, a transfer gear, a transfer connecting plate, a transfer fixing rod, a transfer support rod, a test tube clamping jaw, a clamping jaw connecting rod, a clamping jaw pressure spring, a transfer connecting gear, a connecting gear seat, a motor transfer gear, a motor, a long chain, a transfer double gear, a short chain, a test tube rack rotary gear and a rotary test tube rack.

As a further optimization of the technical scheme, the korean arborvitae test analysis device comprises a base plate, supporting legs, a movable screw rod seat, a motor seat and a double-gear seat, wherein the supporting legs are welded to the base plate, the movable screw rod seat, the motor seat and the double-gear seat are welded to the base plate, a sterilization housing and a door moving screw rod seat are welded to the base plate, a movable slide rail a and a movable slide rail B are fixedly connected to the base plate, a movable screw rod is rotatably connected to the movable screw rod seat, a rear screw rod seat is fixedly connected to the base plate, a connecting gear seat is welded to the base plate, a motor is fixedly connected to the motor seat, a double gear is rotatably connected to the double-gear seat, and a rotary test tube rack is rotatably connected to the base plate.

The Korean arborvitae test analysis equipment has the beneficial effects that: before use, a test tube is placed in a sterilization housing, an ultraviolet lamp is turned on to irradiate for more than half an hour, then a door moving handle is rotated to rotate a door moving screw rod to drive a door moving screw sleeve to move upwards, a door moving connecting seat is enabled to move upwards along a door moving sliding block sliding groove, a sterilization door is driven to move upwards, the door moving handle is rotated to drive a moving screw rod to rotate, the moving screw sleeve drives a test tube frame to slide along a moving sliding rail A and a moving sliding rail B under the action of a moving sliding block, so that the test tube frame is adjusted to a required position, a rear pull handle is rotated to rotate the rear pull screw rod, the rear pull screw sleeve is driven to slide to the required position along the rear pull sliding rod and stay, meanwhile, a rear pull rotating seat moves along with the rear pull rotating seat, an anti-rotation stop block is installed to block a transfer support to rotate, the transfer handle is rotated to drive the transfer screw rod to rotate, and the rotating screw sleeve is enabled to move upwards to transfer a connecting plate, move up through shifting the dead lever drive and shift branch, the test tube clamping jaw centre gripping test tube shifts up under clamping jaw connecting rod and clamping jaw pressure spring combined action, will shift connecting gear and draw up along connecting the gear seat, connect motor transfer gear and transfer gear, it prevents changeing the dog to move aside, open the motor, motor output shaft drives motor transfer gear, motor gear rotates, make the transfer connecting gear drive and shift gear revolve, make the transfer support drive whole clamping part and rotate, the dog that prevents changeing of secondary erection blocks the transfer support and rotates afterwards, motor gear drives the transfer gear through the long chain and rotates simultaneously, drive test-tube rack rotating gear through the short double-tooth chain afterwards and rotate, make and rotate the test-tube rack, put the test tube like rotating the test-tube rack afterwards, make thuja sample and experiment reagent fully fuse.

Drawings

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

FIG. 1 is a first general structural diagram of the present invention;

FIG. 2 is a schematic view of the overall structure of the present invention;

FIG. 3 is a first structural view of the sterilization device of the present invention;

FIG. 4 is a schematic structural diagram of a sterilization device according to the present invention;

FIG. 5 is a schematic structural diagram of a sterilization device according to the present invention;

FIG. 6 is a first structural diagram of a mobile device according to the present invention;

FIG. 7 is a second block diagram of the mobile device according to the present invention;

FIG. 8 is a schematic view of the construction of the back pull apparatus of the present invention;

FIG. 9 is a first structural view of the transferring device of the present invention;

FIG. 10 is a second schematic structural view of the transfer device of the present invention;

FIG. 11 is a third schematic structural view of the transfer device of the present invention;

FIG. 12 is a fourth schematic structural view of the transfer device of the present invention;

fig. 13 is a schematic view of the base structure of the present invention.

In the figure: a sterilizing device 1; 1-1 of a sterilizing housing; an ultraviolet lamp 1-2; 1-3 of a sliding door screw rod seat; 1-4 of a door moving screw rod; 1-5 of a sliding door handle; 1-6 of a sliding door thread sleeve; a sliding door connecting seat 1-7; 1-8 of a sliding door slider; 1-9 of a sterilization door; a mobile device 2; moving the handle 2-1; moving the screw rod 2-2; 2-3 of moving a silk sleeve; 2-4 parts of a test tube rack; 2-5 of a movable slide block; moving a sliding rail A2-6; a movable slide rail B2-7; a back-pull device 3; 3-1 of a rear pull handle; 3-2 parts of a rear wire drawing rod seat; 3-3 of a rear tension rod; pulling back the slide bar 3-4; 3-5 parts of a rear wire drawing sleeve; pulling back the rotating seat 3-6; 3-7 of an anti-rotation stop block; a transfer device 4; a transfer handle 4-1; 4-2 of a transfer screw rod; rotating the screw sleeve by 4-3; 4-4 of a transfer support; 4-5 of a transfer gear; transferring the connecting plates 4-6; transferring the fixed rods 4-7; 4-8 of a transfer strut; 4-9 parts of a test tube clamping jaw; 4-10 parts of a clamping jaw connecting rod; 4-11 parts of a clamping jaw pressure spring; transfer connecting gears 4-12; connecting the gear seat 4-13; 4-14 of motor transfer gears; 4-15 parts of motor gear; 4-16 of a motor; 4-17 parts of long chain; 4-18 of double transfer gears; 4-19 parts of a short chain; the test tube rack rotates the gear 4-20; rotating the test tube rack 4-21; a base 5; a bottom plate 5-1; 5-2 parts of supporting legs; 5-3 of a movable screw rod seat; 5-4 parts of a motor base; 5-5 parts of a double-gear seat.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The fixed connection in this device indicates that fix through modes such as welding, thread tightening, combines different service environment, uses different fixed mode, the rotation connection indicate through drying by the fire the dress at epaxial with the bearing, be provided with the spring on axle or the shaft hole and keep off the ring groove, realize rotating through keeping off the axial fixity that the ring card realized the bearing in the ring inslot, sliding connection indicate to connect through the slip of slider in spout or guide rail, articulated indicate through carrying out the connected mode that moves about on connecting elements such as hinge, round pin axle and minor axis, required sealed department all realizes sealedly through sealing washer or O shape circle.

The first embodiment is as follows:

the following describes the embodiment with reference to fig. 1 to 13, and the korean arborvitae test analysis apparatus includes a sterilization device 1, a moving device 2, a back-pull device 3, a transfer device 4, and a base 5, wherein the sterilization device 1 is connected to the base 5, the moving device 2 is connected to the base 5, the back-pull device 3 is connected to the transfer device 4, and the transfer device 4 is connected to the base 5.

The second embodiment is as follows:

the following describes the present embodiment with reference to fig. 1-13, and the present embodiment further describes the first embodiment, where the sterilization apparatus 1 includes a sterilization housing 1-1, an ultraviolet lamp 1-2, a door-moving screw rod seat 1-3, a door-moving screw rod 1-4, a door-moving handle 1-5, a door-moving screw sleeve 1-6, a door-moving connecting seat 1-7, a door-moving slider 1-8, and a sterilization door 1-9, the ultraviolet lamp 1-2 is fixedly connected with the sterilization housing 1-1, the door-moving screw rod seat 1-3 is welded with the sterilization housing 1-1, the door-moving screw rod 1-4 is rotatably connected with the door-moving screw rod seat 1-3, and the door-moving handle 1-5 is fixedly connected with the door-moving screw rod 1-4, the sliding door screw sleeve 1-6 is in threaded connection with a sliding door screw rod 1-4, the sliding door screw sleeve 1-6 is in welded connection with a sliding door connecting seat 1-7, the sliding door connecting seat 1-7 is in sliding connection with a sliding door sliding block 1-8, and the sterilization door 1-9 is in welded connection with a sliding door connecting seat 1-7. Before use, a test tube is placed into a sterilization housing 1-1, an ultraviolet lamp 1-2 is turned on to irradiate for more than half an hour, then a sliding door handle 1-5 is rotated to enable the sliding door screw rod 1-4 to rotate to drive the sliding door screw sleeve 1-6 to move upwards, so that the sliding door connecting seat 1-7 moves upwards along a sliding groove 1-8 of the sliding door sliding block to drive the sterilization door 1-9 to move upwards.

The third concrete implementation mode:

the following describes the embodiment with reference to fig. 1 to 13, and the embodiment further describes the first embodiment, where the moving device 2 includes a moving handle 2-1, a moving screw rod 2-2, a moving screw sleeve 2-3, a test tube rack 2-4, a moving slider 2-5, a moving slide rail A2-6, and a moving slide rail B2-7, the moving handle 2-1 is fixedly connected to the moving screw rod 2-2, the moving screw sleeve 2-3 is connected to the moving screw rod 2-2 through a screw thread, the test tube rack 2-4 is fixedly connected to the moving screw sleeve 2-3, the moving slider 2-5 is fixedly connected to the test tube rack 2-4, the moving slider 2-5 is respectively connected to the moving slide rail A2-6 and the moving slide rail B2-7 in a sliding manner, and the moving handle 2-1 is rotated to drive the moving screw rod 2-2 to rotate, so that the moving screw sleeve 2-3 drives the test tube rack 2-4 to slide along the moving slide rail A2-6 and the moving slide rail B2-7 under the action of the moving slider 2-5, thereby adjusting the test tube rack 2-4 to a desired position.

The fourth concrete implementation mode:

the following describes the present embodiment with reference to fig. 1 to 13, and the present embodiment further describes the first embodiment, wherein the rear drawing device 3 includes a rear drawing handle 3-1, a rear drawing rod base 3-2, a rear drawing rod base 3-3, a rear drawing rod 3-4, a rear drawing sleeve 3-5, a rear drawing rotation base 3-6, and an anti-rotation stopper 3-7, the rear drawing handle 3-1 is fixedly connected to the rear drawing rod base 3-3, the rear drawing rod base 3-3 is rotatably connected to the rear drawing rod base 3-2, the rear drawing rod base 3-4 is fixedly connected to the rear drawing rod base 3-2, the rear drawing sleeve 3-5 is threadedly connected to the rear drawing rod base 3-3, the rear drawing sleeve 3-5 is slidably connected to the rear drawing rod base 3-4, the rear drawing rotation base 3-6 is welded to the rear drawing sleeve 3-5, the anti-rotation stopper 3-7 is cooperatively connected to the rear drawing sleeve 3-5, and the rear drawing handle 3-1 is rotated to rotate the rear drawing rod base 3-5 and to move the rear drawing sleeve 3-5 to the rear drawing sleeve 3-6.

The fifth concrete implementation mode:

the first embodiment is further described by the embodiment with reference to fig. 1-13, the transfer device 4 comprises a transfer handle 4-1, a transfer screw rod 4-2, a rotary screw sleeve 4-3, a transfer support 4-4, a transfer gear 4-5, a transfer connecting plate 4-6, a transfer fixing rod 4-7, a transfer support rod 4-8, a test tube clamping jaw 4-9, a clamping jaw connecting rod 4-10, a clamping jaw pressure spring 4-11, a transfer connecting gear 4-12, a connecting gear seat 4-13, a motor transfer gear 4-14, a motor gear 4-15, a motor 4-16, a long chain 4-17, a transfer double gear 4-18, a short chain 4-19, a test tube rack rotary gear 4-20 and a rotary test tube rack 4-21, a transfer support 4-4 is rotatably connected with a back-pull rotating seat 3-6, a transfer handle 4-1 is fixedly connected with a transfer screw rod 4-2, a transfer screw rod 4-2 is rotatably connected with a transfer support 4-4, a rotating screw sleeve 4-3 is in threaded connection with the transfer screw rod 4-2, a transfer gear 4-5 is fixedly connected with the transfer support 4-4, a transfer connecting plate 4-6 is welded with the rotating screw sleeve 4-3, a transfer fixing rod 4-7 is fixedly connected with the transfer connecting plate 4-6, a transfer support rod 4-8 is fixedly connected with a transfer fixing rod 4-7, a test tube clamping jaw 4-9 is in matched connection with a transfer support rod 4-8, a clamping jaw connecting rod 4-10 is in sliding connection with a test tube clamping jaw 4-9, a clamping jaw pressure spring 4-11 is respectively connected with a test tube clamping jaw 4-9, the clamping jaw connecting rods 4-10 are connected in a matching way, the transfer connecting gears 4-12 are connected with the connecting gear seats 4-13 in a sliding way, the transfer connecting gears 4-12 are connected with the transfer gears 4-5, the transfer connecting gears 4-12 are connected with the motor transfer gears 4-14, the motor transfer gears 4-14 and the motor gears 4-15 are both fixedly connected with the motors 4-16, the motor gears 4-15 are in transmission connection with the long chains 4-17, the transfer double gears 4-18 are in transmission connection with the short chains 4-19, the short chains 4-19 are in transmission connection with the test tube rack rotating gears 4-20, the test tube rack rotating gears 4-20 are fixedly connected with the rotating test tube racks 4-21, an anti-rotation stop block 3-7 is installed to block a transfer support 4-4 from rotating, a transfer handle 4-1 is rotated to drive a transfer screw rod 4-2 to rotate, a rotary screw sleeve 4-3 is enabled to move upwards with a transfer connecting plate 4-6, a transfer fixing rod 4-7 is used for driving a transfer support rod 4-8 to move upwards, a test tube clamping jaw 4-9 clamps a test tube to move upwards under the combined action of a clamping jaw connecting rod 4-10 and a clamping jaw pressure spring 4-11, a transfer connecting gear 4-12 is pulled upwards along a connecting gear seat 4-13 to connect a motor transfer gear 4-14 with a transfer gear 4-5, the anti-rotation stop block 3-7 is removed, a motor 4-16 is started, an output shaft of the motor 4-16 drives a motor transfer gear 4-14 and a motor gear 4-15 to rotate, and the transfer connecting gear 4-12 drives the transfer gear 4-5 to rotate, the whole clamping component is driven to rotate by the transfer support 4-4, then the anti-rotation stop blocks 3-7 are installed again to stop the transfer support 4-4 from rotating, meanwhile, the motor gear 4-15 drives the transfer double gears 4-18 to rotate through the long chain 4-17, then the test tube rack rotating gear 4-20 is driven to rotate through the short chain 4-19, the test tube rack 4-21 is rotated, and then the test tube is placed on the test tube rack 4-21 to be rotated, so that the thuja sample and the experimental reagent are fully fused.

The sixth specific implementation mode:

the first embodiment is further described with reference to fig. 1-13, where the base 5 includes a bottom plate 5-1, support legs 5-2, a movable screw seat 5-3, a motor seat 5-4, a double gear seat 5-5, the support legs 5-2 are welded to the bottom plate 5-1, the movable screw seat 5-3, the motor seat 5-4, and the double gear seat 5-5 are all welded to the bottom plate 5-1, the sterilization enclosure 1-1 and the sliding door screw seat 1-3 are all welded to the bottom plate 5-1, the movable slide rail A2-6 and the movable slide rail B2-7 are all fixedly connected to the bottom plate 5-1, the movable screw 2-2 is rotatably connected to the movable screw seat 5-3, the rear screw seat 3-2 is fixedly connected to the bottom plate 5-1, the connecting gear seat 4-13 is welded to the bottom plate 5-1, the motor 4-16 is fixedly connected to the motor seat 5-4, the double gear 4-18 is rotatably connected to the double gear seat 5-5, and the pipe rack is rotatably connected to the bottom plate 5-1-21.

The invention relates to a Korean arborvitae test analysis device, which has the working principle that: before use, a test tube is placed in a sterilization housing 1-1, an ultraviolet lamp 1-2 is turned on to irradiate for more than half an hour, then a door moving handle 1-5 is rotated to enable a door moving screw rod 1-4 to rotate, a door moving screw sleeve 1-6 is driven to move upwards, a door moving connecting seat 1-7 is driven to move upwards along a sliding groove 1-8 of a door moving slide block, a sterilization door 1-9 is driven to move upwards, a moving handle 2-1 is rotated to drive a moving screw rod 2-2 to rotate, a moving screw sleeve 2-3 drives a test tube rack 2-4 to slide along a moving slide rail A2-6 and a moving slide rail B2-7 under the action of the moving slide block 2-5, so that the test tube rack 2-4 is adjusted to a required position, a rear pull handle 3-1 is rotated to enable a rear pull screw rod 3-3 to rotate, driving a rear wire drawing sleeve 3-5 to slide to a required position along a rear pull slide bar 3-4 and then stay, simultaneously moving a rear pull rotating seat 3-6, installing an anti-rotation stop dog 3-7 to block a transfer support 4-4 to rotate, rotating a transfer handle 4-1 to drive a transfer screw 4-2 to rotate, enabling the rotary wire drawing sleeve 4-3 to move up with a transfer connecting plate 4-6, driving a transfer support rod 4-8 to move up through a transfer fixing rod 4-7, clamping a test tube by a test tube clamping jaw 4-9 under the combined action of a clamping jaw connecting rod 4-10 and a clamping jaw pressure spring 4-11 to move up, pulling a transfer connecting gear 4-12 up along a connecting gear seat 4-13, connecting a motor transfer gear 4-14 and a transfer gear 4-5, removing the anti-rotation stop dog 3-7, opening a motor 4-16, an output shaft of a motor 4-16 drives a motor transfer gear 4-14 and a motor gear 4-15 to rotate, so that a transfer connecting gear 4-12 drives a transfer gear 4-5 to rotate, a transfer support 4-4 drives an integral clamping component to rotate, then an anti-rotation stop block 3-7 is installed again to stop the transfer support 4-4 from rotating, meanwhile, the motor gear 4-15 drives a transfer double gear 4-18 to rotate through a long chain 4-17, then a test tube rack rotating gear 4-20 is driven to rotate through a short chain 4-19, so that a rotating test tube rack 4-21 rotates, and then a test tube is placed like the rotating test tube rack 4-21, so that a thuja sample and an experimental reagent are fully fused.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims

1. A Korean arborvitae test analysis device, characterized in that: the sterilization device comprises a sterilization device (1), a moving device (2), a back-pull device (3), a transfer device (4) and a base (5), wherein the sterilization device (1) is connected with the base (5), the moving device (2) is connected with the base (5), the back-pull device (3) is connected with the transfer device (4), and the transfer device (4) is connected with the base (5);

the sterilization device (1) comprises a sterilization housing (1-1), an ultraviolet lamp (1-2), a sliding door screw rod seat (1-3), a sliding door screw rod (1-4), a sliding door handle (1-5), a sliding door screw sleeve (1-6), a sliding door connecting seat (1-7), a sliding door sliding block (1-8) and a sterilization door (1-9), wherein the ultraviolet lamp (1-2) is fixedly connected with the sterilization housing (1-1), the sliding door screw rod seat (1-3) is welded with the sterilization housing (1-1), the sliding door screw rod (1-4) is rotatably connected with the sliding door screw rod seat (1-3), the sliding door handle (1-5) is fixedly connected with the sliding door screw rod (1-4), the sliding door screw sleeve (1-6) is in threaded connection with the sliding door screw rod (1-4), the sliding door screw sleeve (1-6) is welded with the sliding door connecting seat (1-7), the sliding door connecting seat (1-7) is connected with the sliding door sliding rod (1-8), and the sliding door connecting seat (1-9) is welded with the sterilization door sliding door (7);

the moving device (2) comprises a moving handle (2-1), a moving screw rod (2-2), a moving screw sleeve (2-3), a test tube rack (2-4), a moving sliding block (2-5), a moving sliding rail A (2-6) and a moving sliding rail B (2-7), wherein the moving handle (2-1) is fixedly connected with the moving screw rod (2-2), the moving screw sleeve (2-3) is in threaded connection with the moving screw rod (2-2), the test tube rack (2-4) is fixedly connected with the moving screw sleeve (2-3), the moving sliding block (2-5) is fixedly connected with the test tube rack (2-4), and the moving sliding block (2-5) is respectively in sliding connection with the moving sliding rail A (2-6) and the moving sliding rail B (2-7);

the rear pulling device (3) comprises a rear pulling handle (3-1), a rear pulling rod seat (3-2), a rear pulling rod (3-3), a rear pulling slide rod (3-4), a rear pulling sleeve (3-5), a rear pulling rotating seat (3-6) and an anti-rotation stop dog (3-7), the rear pulling handle (3-1) is fixedly connected with the rear pulling rod (3-3), the rear pulling rod (3-3) is rotatably connected with the rear pulling rod seat (3-2), the rear pulling slide rod (3-4) is fixedly connected with the rear pulling rod seat (3-2), the rear pulling sleeve (3-5) is in threaded connection with the rear pulling rod (3-3), the rear pulling sleeve (3-5) is in sliding connection with the rear pulling slide rod (3-4), the rear pulling rotating seat (3-6) is in welded connection with the rear pulling sleeve (3-5), and the anti-rotation stop dog (3-7) is in matched connection with the rear pulling sleeve (3-5);

the transfer device (4) comprises a transfer handle (4-1), a transfer screw rod (4-2), a rotary screw sleeve (4-3), a transfer support (4-4), a transfer gear (4-5), a transfer connecting plate (4-6), a transfer fixing rod (4-7), a transfer support rod (4-8), a test tube clamping jaw (4-9), a clamping jaw connecting rod (4-10), a clamping jaw pressure spring (4-11), a transfer connecting gear (4-12), a connecting gear seat (4-13), a motor transfer gear (4-14), a motor gear (4-15), a motor (4-16), a long chain (4-17), a transfer double gear (4-18), a short chain (4-19), a test tube rack rotary gear (4-20) and a rotary test tube rack (4-21), the transfer support (4-4) is rotationally connected with the rear pull rotating seat (3-6), the transfer handle (4-1) is fixedly connected with the transfer screw rod (4-2), the transfer screw rod (4-2) is rotationally connected with the transfer support (4-4), the rotary screw sleeve (4-3) is in threaded connection with the transfer screw rod (4-2), the transfer gear (4-5) is fixedly connected with the transfer support (4-4), the transfer connecting plate (4-6) is welded with the rotary wire sleeve (4-3), the transfer fixing rod (4-7) is fixedly connected with the transfer connecting plate (4-6), the transfer support rod (4-8) is fixedly connected with the transfer fixing rod (4-7), the test tube clamping jaw (4-9) is matched and connected with the transfer support rod (4-8), the clamping jaw connecting rod (4-10) is slidably connected with the test tube clamping jaw (4-9), the clamping jaw pressure spring (4-11) is respectively matched and connected with the test tube clamping jaw (4-9) and the clamping jaw connecting rod (4-10), the transfer connecting gear (4-12) is slidably connected with the connecting gear seat (4-13), the transfer connecting gear (4-12) is connected with the transfer gear (4-5), the transfer connecting gear (4-12) is connected with the motor transfer gear (4-14), the motor transfer gear (4-14) and the motor gear (4-15) are both fixedly connected with the motor (4-16), the motor gear (4-15) is connected with the long chain (4-17), the transfer chain (4-17) is connected with the long chain (18-17), and the short chain (18-17), the short chains (4-19) are in transmission connection with the test tube rack rotating gears (4-20), and the test tube rack rotating gears (4-20) are fixedly connected with the rotating test tube racks (4-21).

2. The thuja koraiensis test analysis apparatus as set forth in claim 1, wherein: the base (5) comprises a bottom plate (5-1), supporting legs (5-2), a movable screw rod seat (5-3), a motor base (5-4) and a double-gear seat (5-5), wherein the supporting legs (5-2) are welded with the bottom plate (5-1), the movable screw rod seat (5-3), the motor base (5-4) and the double-gear seat (5-5) are welded with the bottom plate (5-1), a sterilization encloser (1-1) and a door-moving screw rod seat (1-3) are welded with the bottom plate (5-1), a movable sliding rail A (2-6) and a movable sliding rail B (2-7) are fixedly connected with the bottom plate (5-1), a movable screw rod (2-2) is rotationally connected with the movable screw rod seat (5-3), a rear screw rod seat (3-2) is fixedly connected with the bottom plate (5-1), a connecting gear seat (4-13) is welded with the bottom plate (5-1), a motor (4-16) is fixedly connected with the motor base (5-4), a rear screw rod seat (3) is rotationally connected with the double-4) and a test tube rack (5-1) is rotationally connected with the double-1).