CN218640303U - Plastic uptake device for biochemical analyzer shell - Google Patents

Abstract

The utility model relates to the technical field of biochemical analyzers, in particular to a blister pack for biochemical analyzer shells, which comprises a base arranged below a workbench, a jacking device arranged on the base, a mounting plate arranged on the jacking device, a movable plate arranged in the mounting plate in a sliding way, an inner supporting clamp arranged on the movable plate, and a shell mold arranged on the movable plate and covering the inner supporting clamp; the movable plate is provided with a first air exhaust cavity, a second air exhaust cavity communicated with the first air exhaust cavity is arranged on the movable plate, and one side of the base is provided with a vacuumizing device which is connected with the first air exhaust cavity and the second air exhaust cavity. The utility model adopts the movable plate which can be moved below the workbench, the shell mould is arranged on the movable plate, the shell mould is lifted to the workbench through the jacking device to complete the plastic suction work, and the mould can be conveniently and rapidly arranged and disassembled; the working efficiency is greatly improved, and the cost is saved.

Description

Plastic uptake device for biochemical analyzer shell

Technical Field

The utility model relates to a biochemical analysis appearance technical field, in particular to plastic uptake device for biochemical analysis appearance shell.

Background

The housing of the biochemical analyzer is one of necessary apparatuses of biochemical analysis equipment, generally made of ABS plastics or other types of plastics, and in the process of housing production and processing, some housing parts have larger radian or taper, and are difficult to produce by using a common lathe, and are generally processed and formed by adopting a mold integration and then a plastic uptake process.

At present, the traditional plastic suction equipment welds a mold on a mold base below a workbench or is fixed with the mold base below the workbench through a screw, a plastic suction material is fixed with a gland on the workbench and is formed after cooling, however, different molds need to be replaced in the production and processing process, so that the method of welding the mold on the mold base below the workbench or fixing the mold with the mold base below the workbench through the screw is inconvenient for the installation and the disassembly of the mold, and the working efficiency is reduced.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects of the prior art, the utility model aims to provide a plastic uptake device for biochemical analyzer shell, it can be convenient for the installation and the dismantlement of mould, improves work efficiency.

In order to achieve the above object, the utility model provides a following technical scheme:

a plastic uptake device for a biochemical analyzer shell comprises a base arranged below a workbench, a jacking device arranged on the base, an installation plate arranged on the jacking device, a moving plate arranged in the installation plate in a sliding manner, an inner support clamp arranged on the moving plate, and a shell mold arranged on the moving plate and covering the inner support clamp; the movable plate is provided with a first air exhaust cavity, a second air exhaust cavity communicated with the first air exhaust cavity is arranged on the movable plate, and one side of the base is provided with a vacuumizing device which is connected with the first air exhaust cavity and the second air exhaust cavity.

As a preferred scheme for a plastic uptake device of biochemical analyzer shell, interior vaulting pole anchor clamps include interior vaulting pole one, interior vaulting pole two, pinion and gear wheel, interior vaulting pole one and interior vaulting pole two are articulated to be the scissors form, and pinion and gear wheel are stack pivoted concentric gear, interior vaulting pole one and big gear wheel gear connection, interior vaulting pole two and pinion gear connection.

As a preferred scheme of a plastic uptake device for biochemical analyzer shell, the structure of interior vaulting pole one and interior vaulting pole two is sickle form, and the upper end of interior vaulting pole one and interior vaulting pole two all sets up to the arc form, and an interior vaulting pole upper end inboard is provided with a plurality of internal teeth that link to each other with the gear wheel, and two upper end outsides of interior vaulting pole are provided with a plurality of external teeth that link to each other with the pinion.

As an optimal selection scheme of a plastic uptake device for biochemical analyzer shell, be provided with the supporting seat on the movable plate, be provided with driving piece two on the supporting seat, driving piece two and pinion and gear wheel connection.

As an optimal selection scheme of a plastic uptake device for biochemical analyzer shell, mounting panel both sides inner wall is provided with rotatable gear one, and the movable plate both sides are provided with the rack with a gear engaged with.

As an optimal selection scheme of a plastic uptake device for biochemical analyzer shell, mounting panel below both sides are provided with driving piece one, and driving piece one is connected with gear one.

As an optimal selection scheme of a plastic uptake device for biochemical analyzer shell, the movable plate below is provided with the dovetail, be provided with on the mounting panel with the dovetail cooperation dovetail of installation.

As a preferred scheme of the plastic uptake device for the housing of the biochemical analyzer of the present invention, the workbench comprises supporting legs disposed below the workbench and a housing mold groove disposed on the workbench, one end of the workbench is rotatably provided with a material pressing frame, the other end of the material pressing frame is provided with a compactor, and the compactor is fixed on one side of the workbench; the inside of workstation both sides all is equipped with the track, is provided with electronic slider on the track, is provided with the heating device who is connected with between the electronic slider of both sides.

As a preferred scheme of a plastic uptake device for biochemical analyzer shell, jacking device is including setting up in the chassis at base both ends, setting up in the lifting rod of chassis both sides and setting up the jacking platform on the lifting rod, and the symmetry is provided with the slider between the lifting rod of both sides, is provided with the screw rod of rotating the connection between the slider of both ends, be provided with in one of them slider with screw rod complex screw thread.

As a preferred scheme for a plastic uptake device of biochemical analyzer shell, the lift bar includes the lower support arm of symmetrical upper bracket and symmetry, and the one end and the chassis of lower support arm are articulated, and the other end of lower support arm is articulated with the one end of upper bracket, and the other end of upper bracket is articulated with the jacking platform, and the slider transversely sets up in the articulated department of the upper bracket and the lower support arm of both sides.

As an optimized scheme of the plastic uptake device for the shell of the biochemical analyzer, the vacuum pumping device is a vacuum pump.

Compared with the prior art, the beneficial effects of the utility model are that:

(1) The utility model adopts the movable plate which can be moved below the workbench, the shell mould is arranged on the movable plate, the shell mould is lifted to the workbench through the jacking device to complete the plastic suction work, and the mould can be conveniently and rapidly arranged and disassembled; the working efficiency is greatly improved, and the cost is saved.

(2) The utility model discloses an inner wall that interior supporting anchor clamps both ends supported the shell mould respectively fixes the shell mould, convenient control and dismantlement shell mould.

(3) The utility model discloses movable plate and mounting panel pass through the dovetail cooperation installation, can stably remove the movable plate.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the technical solutions in the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts. Wherein:

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is an exploded view of the present invention;

FIG. 3 is a schematic view of the structure of the present invention combined with a worktable;

FIG. 4 is a schematic structural view of the inner supporting clamp of the present invention;

FIG. 5 is a schematic view of the installation structure of the track slider of the present invention;

fig. 6 is a schematic bottom view of the shell mold of the present invention;

reference numbers in the figures: 1. a base; 2. a jacking device; 21. a chassis; 22. a lifting bar; 23. a jacking table; 24. a slider; 25. a screw; 3. mounting a plate; 31. a first air extraction cavity; 32. a first gear; 33. dovetail joints; 4. a vacuum pumping device; 5. a first driving part; 6. moving the plate; 61. a second pumping chamber; 62. a rack; 63. a dovetail groove; 7. an inner supporting clamp; 71. a first support rod; 72. a pinion gear; 73. a bull gear; 74. a second inner supporting rod; 8. a supporting seat; 9. a driving part II; 10. a housing mold; 11. a work table; 11-1, supporting legs; 11-2, housing mold grooves; 12. pressing the material frame; 13. a compactor; 14. a track; 15. an electric slider; 16. and (4) a heating device.

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it will be understood that they are presented herein only to illustrate and explain the present invention, and not to limit the present invention.

Example 1

Referring to fig. 1-6, for the first embodiment of the present invention, this embodiment provides a plastic uptake device for a biochemical analyzer housing, a movable plate is arranged below a workbench, a housing mold is mounted on the movable plate, the housing mold is lifted to the workbench by a jacking device to complete plastic uptake work, and the mold can be conveniently and rapidly mounted and dismounted; the working efficiency is greatly improved.

Specifically, the device comprises a base 1 arranged below a workbench 11, a jacking device 2 arranged on the base 1, an installation plate 3 arranged on the jacking device 2, a moving plate 6 arranged in the installation plate 3 in a sliding manner, an inner support clamp 7 arranged on the moving plate 6, and an outer shell mold 10 arranged on the moving plate 6 and covering the inner support clamp 7; a first air pumping cavity 31 is formed in the mounting plate 3, a second air pumping cavity 61 communicated with the first air pumping cavity 31 is formed in the moving plate 6, a vacuumizing device 4 is arranged on one side of the base 1, and the vacuumizing device 4 is connected with the first air pumping cavity 31 and the second air pumping cavity 61; the vacuum pumping device 4 is a vacuum pump, the vacuum pump is connected with the first air pumping cavity 31 and the second air pumping cavity 61 through an air pipe, and the softened ABS plastic is attached to the shell mold 10 through vacuum pumping. The moving plate 6 can be moved out or moved into the lower part of the workbench 11, so that a worker can conveniently take out the shell mold 10 during replacement; the working efficiency is improved. The moving plate 6 is provided with an inner support clamp 7, the shell mold 10 is placed on the moving plate 6, and the inner support clamp 7 supports the inner wall of the shell mold 10 to prevent the shell mold 10 from moving.

Preferably, referring to fig. 4, the inner supporting clamp 7 includes a first inner supporting rod 71, a second inner supporting rod 74, a pinion 72 and a bull gear 73, the first inner supporting rod 71 and the second inner supporting rod 74 are hinged to form a scissors shape, the pinion 72 and the bull gear 73 are concentric gears which rotate in a superposed manner, the first inner supporting rod 71 and the second inner supporting rod 74 are in a sickle shape, the upper ends of the first inner supporting rod 71 and the second inner supporting rod 74 are both arranged in an arc shape, a plurality of inner teeth which are connected with the bull gear 73 and are uniformly distributed are arranged on the inner side of the upper end of the first inner supporting rod 71, and the first inner supporting rod 71 is in gear connection with the bull gear 73; the outer side of the upper end of the second inner stay 74 is provided with a plurality of external teeth which are connected with the pinion 72 and are evenly distributed, and the second inner stay 74 is in gear connection with the pinion 72. The moving plate 6 is provided with a supporting seat 8, the supporting seat 8 is provided with a second driving piece 9, and the second driving piece 9 is connected with the small gear 72 and the large gear 73. The driving member two 9 drives the small gear 72 and the large gear 73 to rotate, so as to drive the inner brace rod one 71 and the inner brace rod two 74 to rotate, so that the two ends respectively abut against the inner wall of the outer shell mold 10, thereby fixing the outer shell mold 10.

Preferably, the inner walls of the two sides of the mounting plate 3 are provided with a first rotatable gear 32, and the two sides of the moving plate 6 are provided with racks 62 engaged with the first gear 32. And driving parts I5 are arranged on two sides below the mounting plate 3, and the driving parts I5 are connected with the gears I32. The driving member one 5 drives the gear one 32 to rotate, so that the moving plate 6 drives the shell mold 10 to move.

Preferably, a dovetail groove 63 is formed below the moving plate 6, and a dovetail 33 fitted to the dovetail groove is formed on the mounting plate 3. Thereby enabling to stably move the moving plate 6.

Preferably, the workbench 11 comprises supporting legs 11-1 arranged below the workbench 11 and a shell mold groove 11-2 arranged on the workbench 11, one end of the workbench 11 is rotatably provided with a pressing frame 12, the pressing frame 12 is rotated to form a certain angle with the surface of the workbench 11, and ABS plastic can be placed in the shell mold groove 11-2; the other end of the material pressing frame 12 is provided with a pressing device 13, and the pressing device 13 is fixed on one side of the workbench 11; the presser 13 is rotated to enable the presser 13 to press or loosen one end of the pressing frame 12, and the pressing frame 12 presses the ABS plastics; the inside of workstation 11 both sides all is equipped with track 14, is provided with electronic slider 15 on the track 14, is provided with between the electronic slider 15 of both sides rather than being connected heating device 16, and heating device 16 is used for heating and softens ABS plastics.

Preferably, the jacking device 2 comprises an underframe 21 arranged at two ends of the base 1, lifting rods 22 arranged at two sides of the underframe 21, and a jacking table 23 arranged on the lifting rods 22, wherein sliding blocks 24 are symmetrically arranged between the lifting rods 22 at two sides, screw rods 25 in rotary connection are arranged between the sliding blocks 24 at two ends, and a thread matched with the screw rods 25 is arranged in one of the sliding blocks 24. The lifting rod 22 comprises a symmetrical upper supporting arm and a symmetrical lower supporting arm, one end of the lower supporting arm is hinged to the base frame 21, the other end of the lower supporting arm is hinged to one end of the upper supporting arm, the other end of the upper supporting arm is hinged to the jacking table 23, and the sliding block 24 is transversely arranged at the hinged positions of the upper supporting arm and the lower supporting arm on two sides. The screw rod 25 is driven to rotate by the driving piece, and one sliding block 24 moves, so that the upper supporting arm and the lower supporting arm are driven to rotate, and the jacking table is lifted.

When the mold is used, the first driving piece 5 drives the first gear 32 to rotate, the first gear 32 is matched with the rack 62 to drive the moving plate 6 to move out of the position right below the workbench 11, a worker places the outer shell mold 10 on the moving plate 6 to enable the inner supporting clamp 7 to be covered in the outer shell mold 10, the second driving piece 9 works to drive the large gear 73 and the small gear 72 to rotate, and the first inner supporting rod 71 and the second inner supporting rod 74 respectively abut against the middle part of the inner wall of the outer shell mold 10 to fix the outer shell mold 10. The first driving piece 5 drives the first gear 42 to rotate reversely, the moving plate 6 is driven to move to the position right below the workbench 11, the jacking device 2 works to enable the upper surface of the shell mold 10 to be level with the workbench 11, the material pressing frame 12 is opened, ABS plastic is placed on the workbench 11, the material pressing frame 12 is put down, the pressing device 13 is rotated, and the pressing device 13 presses one end of the material pressing frame 12. The electric slider 15 works to enable the heating device 16 to move right above the shell mold 10, after the heating device is heated and softened for a period of time, the electric slider 15 drives the heating device 16 to return to the original position, the vacuum pump works to extract vacuum between the shell mold 10 and ABS plastic, and the shell mold 10 is lifted through the jacking device 2, so that the ABS plastic is attached to the shell mold 10 and is subjected to plastic suction molding. After the plastic suction is finished, the jacking device 2 drives the shell mold 10 to descend, and the equipment after the plastic suction is naturally cooled.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: it is also possible to modify the solutions described in the previous embodiments or to substitute some or all of the technical features. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. The utility model provides a plastic uptake device for biochemical analyzer shell which characterized in that: the device comprises a base (1) arranged below a workbench (11), a jacking device (2) arranged on the base (1), a mounting plate (3) arranged on the jacking device (2), a moving plate (6) arranged in the mounting plate (3) in a sliding manner, an inner support clamp (7) arranged on the moving plate (6), and a shell mold (10) arranged on the moving plate (6) and covering the inner support clamp (7); the vacuum extractor is characterized in that a first air extracting cavity (31) is formed in the mounting plate (3), a second air extracting cavity (61) communicated with the first air extracting cavity (31) is formed in the movable plate (6), a vacuum extractor (4) is arranged on one side of the base (1), and the vacuum extractor (4) is connected with the first air extracting cavity (31) and the second air extracting cavity (61).

2. The blister device for biochemical analyzer housings according to claim 1, wherein: the inner supporting clamp (7) comprises a first inner supporting rod (71), a second inner supporting rod (74), a small gear (72) and a large gear (73), the first inner supporting rod (71) and the second inner supporting rod (74) are hinged to form a scissor shape, the small gear (72) and the large gear (73) are concentric gears which rotate in a superposed mode, the first inner supporting rod (71) is in gear connection with the large gear (73), and the second inner supporting rod (74) is in gear connection with the small gear (72).

3. The blister device for biochemical analyzer housings of claim 2, wherein: the structure of the first inner supporting rod (71) and the second inner supporting rod (74) is sickle-shaped, the upper ends of the first inner supporting rod (71) and the second inner supporting rod (74) are arc-shaped, a plurality of inner teeth connected with the large gear (73) are arranged on the inner side of the upper end of the first inner supporting rod (71), and a plurality of outer teeth connected with the small gear (72) are arranged on the outer side of the upper end of the second inner supporting rod (74).

4. The blister device for biochemical analyzer housings of claim 3, wherein: and a supporting seat (8) is arranged on the moving plate (6), a driving piece II (9) is arranged on the supporting seat (8), and the driving piece II (9) is connected with the small gear (72) and the large gear (73).

5. The blister device for biochemical analyzer housings according to claim 1 or 4, wherein: rotatable first gears (32) are arranged on the inner walls of the two sides of the mounting plate (3), and racks (62) meshed with the first gears (32) are arranged on the two sides of the moving plate (6).

6. The blister device for biochemical analyzer housings of claim 5, wherein: and driving parts I (5) are arranged on two sides below the mounting plate (3), and the driving parts I (5) are connected with the gears I (32).

7. The blister device for biochemical analyzer housings according to claim 6, wherein: a dovetail groove (63) is formed below the moving plate (6), and a dovetail tenon (33) matched with the dovetail groove is arranged on the mounting plate (3).

8. The blister device for biochemical analyzer housings according to claim 1 or 7, wherein: the working table (11) comprises supporting legs (11-1) arranged below the working table (11) and a shell mold groove (11-2) arranged on the working table (11), one end of the working table (11) is rotatably provided with a material pressing frame (12), the other end of the material pressing frame (12) is provided with a pressing device (13), and the pressing device (13) is fixed on one side of the working table (11); tracks (14) are arranged inside the two sides of the workbench (11), electric sliders (15) are arranged on the tracks (14), and heating devices (16) connected with the electric sliders (15) are arranged between the electric sliders (15) on the two sides.

9. The blister device for biochemical analyzer housings according to claim 1 or 7, wherein: the jacking device (2) comprises an underframe (21) arranged at two ends of the base (1), lifting rods (22) arranged at two sides of the underframe (21) and jacking tables (23) arranged on the lifting rods (22), sliding blocks (24) are symmetrically arranged between the lifting rods (22) at two sides, screw rods (25) in rotating connection are arranged between the sliding blocks (24) at two ends, and threads matched with the screw rods (25) are arranged in one of the sliding blocks (24).

10. The blister device for biochemical analyzer housings of claim 9, wherein: the lifting rod (22) comprises symmetrical upper supporting arms and symmetrical lower supporting arms, one end of each lower supporting arm is hinged to the bottom frame (21), the other end of each lower supporting arm is hinged to one end of each upper supporting arm, the other end of each upper supporting arm is hinged to the jacking table (23), and the sliding blocks (24) are transversely arranged at the hinged positions of the upper supporting arms and the lower supporting arms on the two sides.

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