CN220036246U - Integrated assembled purification laboratory - Google Patents

Abstract

The utility model discloses an integrated assembled purification laboratory, and relates to the technical field of purification laboratories. The utility model comprises the following steps: the base plate is provided with four positioning grooves distributed in a rectangular array, and positioning blocks are arranged in the positioning grooves; the four upright posts are provided with positioning holes and two symmetrically distributed slots, and the positioning blocks are in plug-in fit with the positioning holes; the four wallboards are respectively provided with raised strips which are in plug-in fit with the slots on the opposite sides of the wallboards; and the top plate is fixedly connected with the upright post through a bolt. The utility model adopts an integrated assembly mode, and forms a purification laboratory through the interconnection of the bottom plate, the four upright posts, the four wall plates and the top plate, thereby being convenient for quick disassembly and movement operation and having more practicability.

Description

Integrated assembled purification laboratory

Technical Field

The utility model relates to the technical field of purification laboratories, in particular to an integrated assembled purification laboratory.

Background

The purification laboratory is a part of a laboratory, plays a role in protecting the safety of experimental samples, is also one of important measures for experimental success and safety protection of experimental personnel, is fixed in position, is usually manufactured in a foundation house for a long time, is in an idle state after the application is finished, occupies resources, and is high in use cost in a short time, and therefore the integrated assembly type purification laboratory is provided.

Disclosure of Invention

The utility model aims at: in order to solve the technical problems that the existing purification laboratory is fixed in position, a foundation house is generally adopted, the purification laboratory is manufactured for a long time, and is in an idle state after the application is finished, so that resources are occupied, and the use cost is high in a short time.

The utility model adopts the following technical scheme for realizing the purposes:

an integrated, assembled purification laboratory comprising:

the base plate is provided with four positioning grooves distributed in a rectangular array, and positioning blocks are arranged in the positioning grooves;

the four upright posts are provided with positioning holes and two symmetrically distributed slots, and the positioning blocks are in plug-in fit with the positioning holes;

the four wallboards are respectively provided with raised strips which are in plug-in fit with the slots on the opposite sides of the wallboards;

and the top plate is fixedly connected with the upright post through a bolt.

Further, a locating plate with an L-shaped structure is arranged on the upright post.

Further, the method further comprises the following steps:

and the partition plates are detachably arranged on the four wallboards.

Further, the wallboard is provided with a connecting groove, the partition board is provided with four connecting blocks distributed in rectangular arrays, and the connecting blocks are in plug-in fit with the connecting groove.

Further, four fixing plates distributed in rectangular arrays are arranged on the bottom plate, connecting rods are arranged on the fixing plates, and moving wheels are rotatably arranged on the connecting rods.

Further, one end of the connecting rod is hinged with the fixed plate, and a buffer piece is arranged between the connecting rod and the fixed plate.

Further, the buffer piece includes a fixed section of thick bamboo of hinging on the connecting rod, offer the movable groove in the fixed section of thick bamboo and all slide the stopper and the slide bar that set up in the movable groove and fixed connection, the free end and the fixed plate of slide bar are articulated, be provided with buffer spring between stopper and the movable groove.

Further, the movable groove is in a step shape, and a step structure is formed between the limiting block and the sliding rod.

The beneficial effects of the utility model are as follows: the utility model adopts an integrated assembly mode, and forms a purification laboratory through the interconnection of the bottom plate, the four upright posts, the four wall plates and the top plate, thereby being convenient for quick disassembly and movement operation and having more practicability.

Drawings

FIG. 1 is a perspective view of the structure of the present utility model;

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

FIG. 3 is an enlarged view of the utility model at A in FIG. 2;

FIG. 4 is an exploded perspective view of a portion of the construction of the present utility model;

FIG. 5 is an enlarged view of the utility model at B in FIG. 4;

fig. 6 is an enlarged view of the present utility model at C in fig. 4.

Reference numerals: 1. a bottom plate; 2. a positioning groove; 3. a positioning block; 4. a column; 5. positioning holes; 6. a slot; 7. a wallboard; 8. a convex strip; 9. a top plate; 10. a positioning plate; 11. a partition plate; 12. a connecting groove; 13. a connecting block; 14. a fixing plate; 15. a connecting rod; 16. a moving wheel; 17. a buffer member; 1701. a fixed cylinder; 1702. a movable groove; 1703. a limiting block; 1704. a slide bar; 1705. and a buffer spring.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present utility model more clear, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model.

As shown in fig. 1-6, an integrated, assembled purification laboratory according to one embodiment of the present utility model includes: the base plate 1 is provided with four positioning grooves 2 distributed in a rectangular array, positioning blocks 3 are arranged in the positioning grooves 2, the base plate 1 is rectangular in structure and in the horizontal direction, the four positioning grooves 2 are respectively positioned at four corners of the base plate 1, and the four positioning blocks 3 are respectively fixedly arranged in the four positioning grooves 2; the four upright posts 4 are provided with positioning holes 5 and two symmetrically distributed slots 6, the positioning blocks 3 are in plug-in fit with the positioning holes 5, the four upright posts 4 are distributed in a vertical direction and in a rectangular array, the slots 6 are formed in the upright posts 4 along the length direction, the positioning holes 5 are positioned at the bottom ends of the upright posts 4, and the positioning blocks 3 are in plug-in fit with the positioning holes 5 in the horizontal direction; the four wallboards 7, the opposite sides of the wallboards 7 are respectively provided with a convex strip 8 which is in plug-in fit with the slot 6, the four wallboards 7 are distributed in a rectangular array in the vertical direction, the convex strips 8 are fixedly connected with the wallboards 7 in the vertical direction, and the convex strips 8 are in plug-in fit with the slot 6 in the vertical direction; the top plate 9 is fixedly connected with the upright posts 4 through bolts, the top plate 9 is rectangular and is in a horizontal direction, screw holes I are formed in four corners of the top plate 9, screw holes II are formed in the top ends of the four upright posts 4, the bolts are in threaded fit with the screw holes I and the screw holes II, in an initial state, the bottom plate 1, the four upright posts 4, the four wall plates 7 and the top plate 9 are in a separated state, when in use, the bottom plate 1 is in a horizontal direction, the four upright posts 4 are vertically and sequentially spliced with the bottom plate 1, the four positioning blocks 3 are respectively corresponding to and inserted into the four positioning holes 5 until the bottom ends of the four upright posts 4 are respectively positioned in the four positioning grooves 2, then the four wall plates 7 are vertically and spliced, two convex strips 8 on opposite sides of the wall plates 7 are respectively inserted into slots 6 on the two adjacent upright posts 4 along the vertical direction, until the bottom of the wallboard 7 is attached to the bottom plate 1, the top of the wallboard 7 is flush with the top of the upright post 4, repeated operation is performed to complete the splicing of the rest three wallboards 7, finally, the top plate 9 is in the horizontal direction, the top plate 9 is buckled on the four upright posts 4 and the four wallboards 7, the four screw holes I are respectively communicated with the four screw holes II, the top plate 9 is connected and fixed with the upright posts 4 through bolts, the area surrounded by the bottom plate 1, the four upright posts 4, the four wallboards 7 and the top plate 9 is a purification laboratory area, so as to complete the integrated assembly of the purification laboratory, otherwise, when the purification laboratory is disassembled, the operation is reversely performed, in the above way, the purification laboratory is formed by adopting the integrated assembly mode through the interconnection of the bottom plate 1, the four upright posts 4, the four wallboards 7 and the top plate 9, and the rapid disassembly and movement operation are convenient, therefore, the utility model has better practicability.

As shown in fig. 4, in some embodiments, the upright 4 is provided with a positioning plate 10 having an L-shaped structure, and referring to the above, the positioning plate 10 is fixed on the top end of the upright 4, and when the top plate 9 is fastened on the four uprights 4 and the four wallboards 7, the top plate 9 is conveniently and rapidly positioned by the design of the four positioning plates 10, so that the assembly is more convenient.

As shown in fig. 2-6, in some embodiments, further comprising: baffle 11, can dismantle the setting on four wallboards 7, baffle 11 is the horizontal direction, will purify the regional equipment district and the workspace of distributing from top to bottom of laboratory through baffle 11, refer to above, after accomplishing the concatenation of all three wallboard 7, make baffle 11 be the horizontal direction and install on four wallboards 7, later install the required equipment of purification laboratory to the equipment district, carry out the equipment of roof 9 again at last, through the design of baffle 11, realize work and equipment separately.

As shown in fig. 6, in some embodiments, the wallboard 7 is configured with a connecting slot 12, the connecting slot 12 is in a vertical direction, four connecting blocks 13 distributed in rectangular arrays are arranged on the partition 11, the connecting blocks 13 are fixedly connected with the partition 11, the connecting blocks 13 are in plug-in fit with the connecting slot 12, the connecting blocks 13 are in disassembly fit with the connecting slots 12 in the vertical direction, after the splicing of the three other wallboards 7 is completed, the partition 11 is in a horizontal direction, the four connecting blocks 13 are respectively corresponding to and plug-in into the four connecting slots 12, and then the partition 11 is pushed downwards until the wallboard cannot continue.

As shown in fig. 1-3, in some embodiments, four fixing plates 14 distributed in rectangular arrays are disposed on the bottom plate 1, the fixing plates 14 are horizontally and fixedly disposed at the bottom of the bottom plate 1, connecting rods 15 are disposed on the fixing plates 14, and moving wheels 16 are rotatably disposed on the connecting rods 15, and after the integrated assembly of the purification laboratory is completed, the whole short-distance movement of the purification laboratory can be performed through the cooperation of the fixing plates 14, the connecting rods 15 and the moving wheels 16.

As shown in fig. 3, in some embodiments, one end of the connecting rod 15 is hinged to the fixed plate 14, the specific shape of the connecting rod 15 is as shown in fig. 3, and a buffer member 17 is disposed between the connecting rod 15 and the fixed plate 14, and when the purification laboratory is moved in a short distance, as described above, the vibration caused by the uneven ground can be reduced by the design of the buffer member 17, so that the stability of the purification laboratory is improved to a certain extent when the purification laboratory is moved in a short distance.

As shown in fig. 3, in some embodiments, the buffer member 17 includes a fixed cylinder 1701 hinged on the connecting rod 15, a movable slot 1702 opened in the fixed cylinder 1701, and a stopper 1703 and a slide rod 1704 both slidably disposed in the movable slot 1702 and fixedly connected to each other, the movable slot 1702 is opened on the fixed cylinder 1701 along the length direction of the fixed cylinder 1701, the free end of the slide rod 1704 is hinged with the fixed plate 14, a buffer spring 1705 is disposed between the stopper 1703 and the movable slot 1702, in the initial state, the buffer spring 1705 is in a natural state, when the whole purification laboratory is moved for a short distance, the connecting rod 15 rotates around the hinge point to drive the fixed cylinder 1701 to rotate around the hinge point, so that the stopper 1703 and the slide rod 1704 are forced to slide in the movable slot 1702, thereby forcing the buffer spring 1705 to repeatedly be squeezed and reset, and vibration caused by uneven ground is reduced by elastic potential energy of the buffer spring 1705.

As shown in fig. 3, in some embodiments, the movable slot 1702 is configured in a step shape, a step structure is formed between the stopper 1703 and the slide rod 1704, and, with reference to the above, by the step design, the stopper 1703 and the slide rod 1704 are limited in sliding, so as to avoid the two from deviating from the original sliding track.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present utility model. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the utility model. Thus, the present utility model is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (8)

1. An integrated, assembled purification laboratory, comprising:

the base plate (1) is provided with four positioning grooves (2) distributed in a rectangular array, and positioning blocks (3) are arranged in the positioning grooves (2);

the four upright posts (4), wherein positioning holes (5) and two symmetrically distributed slots (6) are formed in the upright posts (4), and the positioning blocks (3) are in plug-in fit with the positioning holes (5);

the four wallboards (7), wherein convex strips (8) which are in plug-in fit with the slots (6) are arranged on the opposite sides of the wallboards (7);

and the top plate (9) is fixedly connected with the upright post (4) through a bolt.

2. The integrated, assembled purification laboratory according to claim 1, characterized in that the upright (4) is provided with a positioning plate (10) of L-shaped configuration.

3. The integrated, modular decontamination laboratory of claim 1, further comprising:

and the partition plates (11) are detachably arranged on the four wallboards (7).

4. An integrated assembly purification laboratory according to claim 3, characterized in that the wallboard (7) is provided with a connecting groove (12), the partition board (11) is provided with four connecting blocks (13) distributed in rectangular array, and the connecting blocks (13) are in plug-in fit with the connecting groove (12).

5. The integrated assembled purification laboratory according to claim 1, characterized in that four rectangular array distributed fixed plates (14) are arranged on the bottom plate (1), connecting rods (15) are arranged on the fixed plates (14), and moving wheels (16) are rotatably arranged on the connecting rods (15).

6. The integrated and assembled purification laboratory according to claim 5, characterized in that one end of the connecting rod (15) is hinged to the fixed plate (14), and a buffer (17) is arranged between the connecting rod (15) and the fixed plate (14).

7. The integrated assembly type purification laboratory according to claim 6, wherein the buffer member (17) comprises a fixed cylinder (1701) hinged on the connecting rod (15), a movable groove (1702) formed in the fixed cylinder (1701), and a limiting block (1703) and a sliding rod (1704) which are both arranged in the movable groove (1702) in a sliding manner and fixedly connected, the free end of the sliding rod (1704) is hinged with the fixed plate (14), and a buffer spring (1705) is arranged between the limiting block (1703) and the movable groove (1702).

8. The integrated, assembled purification laboratory of claim 7, wherein said movable trough (1702) is stepped in configuration, with a stepped configuration formed between said stopper (1703) and slide bar (1704).