CN217436956U - Slide glass mechanism of rectifying - Google Patents

Abstract

The application relates to a slide glass deviation rectifying mechanism which comprises a base frame, a passive calibrating block, an active calibrating component, an active pushing block, a driving component and a passive abutting block; the base frame is used for sliding and jointing the glass slide; the passive calibration block is fixedly connected to the base frame; the active calibration assembly is connected to the base frame, a calibration space for embedding the glass slide is formed between the active calibration assembly and the passive calibration block, and the passive calibration block and the active calibration assembly are used for attaching and positioning the glass slide; the active push block is used for driving the slide glass to be embedded into the calibration space in a sliding manner; the driving component is used for driving the driving push block to slide; the passive butt joint block is connected and is located on the bed frame, and the passive butt joint block stretches into in the calibration space towards the one end of initiative ejector pad. Place the bed frame with the slide on, order about initiative ejector pad and promote in the slide embedding calibration space, passive calibration piece and the laminating slide of initiative calibration subassembly this moment, the initiative ejector pad continues to promote the slide and slides and butt to the correction of passive butt piece in order to accomplish the slide position.

Description

Slide glass mechanism of rectifying

Technical Field

The application relates to the field of coverslippers, in particular to a slide deviation rectifying mechanism.

Background

The sealing machine is a device for automatically gluing and sealing the organized slide sample by using reagents such as dimethylbenzene or neutral resin.

After the slide is glued by the mounting machine, the glued slide needs to be transferred to the next unit for operation, so that the position of the slide needs to be corrected.

SUMMERY OF THE UTILITY MODEL

In order to correct the position of the slide, the application provides a slide deviation rectification mechanism.

The application provides a slide deviation correcting mechanism adopts following technical scheme:

a slide glass deviation rectifying mechanism comprises a base frame, a passive calibrating block, an active calibrating component, an active pushing block, a driving component and a passive abutting block; the base frame is used for horizontally sliding and jointing the glass slide; the passive calibration block is fixedly connected to the base frame; the active calibration assembly is connected to the base frame, a calibration space for embedding the slide glass is formed between the active calibration assembly and the passive calibration block, and the surface of the passive calibration block facing the active calibration assembly and the surface of the active calibration assembly facing the passive calibration block are used for the slide glass to be attached and positioned;

the active push block is connected to the base frame in a sliding mode and used for driving the glass slide to be embedded into the calibration space in a sliding mode; the driving assembly is connected to the base frame and used for driving the driving push block to slide; the passive butt joint block is connected and located on the base frame, one end, facing the active push block, of the passive butt joint block extends into the calibration space, and the end face, facing the active push block, of the passive butt joint block is used for abutting against the surface of the glass slide.

Through adopting above-mentioned technical scheme, when rectifying, on placing the bed frame with the slide level, order about initiative ejector pad through drive assembly and promote slide slip embedding calibration space in, passive calibration piece towards the surface of initiative calibration assembly and the surface of initiative calibration assembly towards passive calibration piece laminate the both ends of slide respectively this moment, initiative ejector pad continues to promote slide and butt to passive butt piece in order to accomplish the correction to the slide position.

Preferably, the active calibration assembly comprises an active calibration block and a driving part, the active calibration block is connected to the base frame in a sliding manner along a direction perpendicular to the sliding direction of the active push block, and the end face of the active calibration block facing the passive calibration block is used for pressing the glass slide; the driving component is used for driving the active calibration block to slide.

By adopting the technical scheme, before deviation rectification, the distance between the active calibration block and the passive calibration block is larger than the width of the glass slide, so that the active push block can better push the glass slide to be embedded into the calibration space in a sliding manner. When the deviation is corrected, the driving push block pushes the glass slide to be embedded into the calibration space in a sliding mode, and meanwhile the driving piece drives the driving calibration block to slide along the direction towards the driven calibration block and press the glass slide tightly. When the slide slides and abuts to the passive abutting block and the passive calibration block, the slide obtains a correct position through the relative pressing force between the active pushing block and the passive abutting block and the relative pressing force between the active calibration block and the passive calibration block, so that the aim of correcting the position of the slide is fulfilled.

Preferably, the passive abutting block is slidably connected to the base frame, and the sliding direction of the passive abutting block is parallel to the sliding direction of the active pushing block; the driving part comprises a driving part and an abutting driving block, and the driving part is connected to the passive abutting block;

the abutting driving block is fixedly connected with the driving calibration block and provided with a driving surface used for sliding fit of the driving piece; when the passive abutting block slides towards the direction far away from the driving pushing block, the driving piece is in sliding fit with the driving surface and enables the driving calibration block to slide towards the direction close to the passive calibration block by abutting against the driving block.

Through adopting above-mentioned technical scheme, when passive butt piece when sliding to the direction of keeping away from initiative ejector pad, the initiative piece slides and laminates to the drive face and makes the initiative calibration block slide to the direction of being close to passive calibration block through the butt drive block, and the initiative calibration block and then promote slide glass butt to passive calibration block to realize calibrating slide glass perpendicular to self position in the direction that slides.

Preferably, the driving part is a roller, the driving part is rotatably connected to the passive abutting block, and the rotation axis of the driving part is vertical.

By adopting the technical scheme, when the driving piece is attached to the driving surface in a sliding manner, the driving piece is convenient for driving the driving calibration block to slide towards the direction close to the driven calibration block.

Preferably, the active alignment assembly further comprises a buffer member, the buffer member has elasticity, one end of the buffer member is connected to the base frame, and the other end of the buffer member is connected to the active alignment block.

By adopting the technical scheme, when the active calibration block is attached to the glass slide, the buffer piece is used for buffering the pressing force of the active calibration block on the glass slide so as to ensure that the active calibration block is not easy to crush the glass slide.

Preferably, the bolster includes connecting seat and extrusion spring, connecting seat fixed connection is in the bed frame, extrusion spring's one end fixed connection in connecting seat, the initiative alignment block is connected to extrusion spring's the other end.

Through adopting above-mentioned technical scheme, when initiative calibration block laminating slide glass, initiative calibration block compresses tightly extrusion spring with the connecting seat jointly to pretightning force through extrusion spring reduces the packing force of initiative calibration block to the slide glass, is difficult with the slide glass crushing with the assurance initiative calibration block.

Preferably, a pressing wheel is arranged on the active calibration block, the pressing wheel is rotationally connected to the end face, facing the passive calibration block, of the active calibration block, the rotation axis of the pressing wheel is vertical, and the periphery of the pressing wheel is in rolling contact with the glass slide; the pressing wheels are arranged in parallel in the sliding direction of the driving push block.

Through adopting above-mentioned technical scheme, when the laminating slide of initiative alignment piece, the initiative ejector pad continues to promote the slide and slides, is convenient for slide slip and butt passive butt piece through setting up the pinch roller.

Preferably, be equipped with the buffer board of vertical setting on the initiative alignment block, the one end fixed connection of buffer board is on the terminal surface of initiative alignment block orientation passive alignment block, the pinch roller rotates the other end of connecting in the buffer board, the buffer board has elasticity, just the nonperpendicular between the slip direction of buffer board and initiative ejector pad.

Through adopting above-mentioned technical scheme, when the laminating slide of initiative calibration block, the buffer board is used for buffering the packing force of initiative calibration block to the slide to guarantee that the initiative calibration block is difficult with the slide crushing.

Preferably, the end face, facing the active calibration component, of the passive calibration block is provided with a plurality of grooves, and the grooves are arranged side by side along the sliding direction parallel to the active push block.

By adopting the technical scheme, the condition that the reagent flows out of the slide glass possibly exists in the glued slide glass, and then the overflowed reagent can be adhered to the end face, facing the active calibration assembly, of the passive calibration block in the slide glass sliding process. Therefore, the contact area between the glass slide and the passive calibration block is reduced by arranging the grooves, and the reagent is prevented from being adhered to the passive calibration block, so that the calibration precision of the glass slide is ensured.

In summary, the present application includes at least one of the following beneficial technical effects:

1. when rectifying, on placing the bed frame with the slide level, order about initiative ejector pad through drive assembly and promote slide slip embedding calibration space in, passive calibration piece laminates the both ends of slide respectively with initiative calibration assembly this moment, and the initiative ejector pad continues to promote slide slip and butt to passive butt piece in order to accomplish the correction to the slide position.

2. When passive butt piece slides to the direction of keeping away from initiative ejector pad, the initiative piece slides and laminates to the drive face and makes initiative calibration block slide to the direction that is close to passive calibration block through the butt drive block, and initiative calibration block and then promote slide glass butt to passive calibration block to realize calibrating the position on slide glass perpendicular to self slip direction.

3. When the active calibration block is attached to the glass slide, the buffer plate is used for buffering pressing force of the active calibration block on the glass slide so as to ensure that the active calibration block is not easy to crush the glass slide.

Drawings

FIG. 1 is a schematic view of the overall structure of a slide deviation correcting mechanism.

Fig. 2 is a schematic structural diagram of a passive calibration block, an active calibration assembly and an active push block.

Fig. 3 is a schematic structural view of a driving part and a passive abutment block.

FIG. 4 is a structural view of the driving member rolling against the driving surface.

Fig. 5 is an enlarged view at a in fig. 4.

Description of reference numerals: 1. a base frame; 11. a sliding surface; 2. a passive calibration block; 21. a groove; 22. a sliding guide surface; 3. an active calibration component; 31. an active calibration block; 311. a buffer plate; 312. a pinch roller; 32. a drive member; 321. a driving member; 322. abutting against the driving block; 3221. a driving surface; 33. a buffer member; 331. a connecting seat; 3311. avoiding holes; 332. a limiting rod; 333. a limiting block; 334. a compression spring; 4. an active push block; 5. a drive assembly; 6. a passive abutment block; 7. and calibrating the space.

Detailed Description

The present application is described in further detail below with reference to figures 1-5.

Referring to fig. 1, the embodiment of the application discloses a slide deviation rectifying mechanism, which comprises a base frame 1, a passive calibration block 2, an active calibration component 3, an active push block 4, a driving component 5 and a passive abutting block 6.

The upper end surface of the base frame 1 is horizontal and is set as a sliding surface 11, and the sliding surface 11 is used for the horizontal sliding and jointing of the glass slide.

The passive alignment block 2 is fixedly attached to the sliding surface 11. The active calibration assembly 3 is arranged on the base frame 1, a calibration space 7 for embedding the glass slide exists between the active calibration assembly 3 and the passive calibration block 2, and the surface of the passive calibration block 2 facing the active calibration assembly 3 and the surface of the active calibration assembly 3 facing the passive calibration block 2 are both used for the fitting and positioning of the glass slide.

The active push block 4 is connected with the sliding surface 11 in a sliding way. The driving assembly 5 is connected to the base frame 1, the driving assembly 5 can be an electric cylinder or an air cylinder, the driving push block 4 is fixedly connected to the driving assembly 5, and the driving assembly 5 is used for driving the driving push block 4 to push the slide glass to be slidingly embedded into the calibration space 7. In the present embodiment, the drive unit 5 is an electric cylinder.

The passive abutting block 6 is connected to the sliding surface 11, one end, facing the active push block 4, of the passive abutting block 6 extends into the calibration space 7, and the end face, facing the active push block 4, of the passive abutting block 6 is used for abutting against the surface of the glass slide. The end face of the passive calibration block 2 facing the calibration space 7 is provided with a plurality of grooves 21, the plurality of grooves 21 are arranged side by side along the sliding direction parallel to the active push block 4, a sliding guide surface 22 is arranged between the adjacent grooves 21, and the sliding guide surface 22 is used for slide fitting of the glass slide.

Referring to fig. 2, the active calibration assembly 3 includes an active calibration block 31, a driving part 32, and a buffer 33.

Initiative calibration block 31 sliding connection is equipped with pinch roller 312 and has elastic buffer board 311 in bed frame 1 on the initiative calibration block 31, and the one end fixed connection of buffer board 311 is on the terminal surface of initiative calibration block 31 towards passive calibration block 2, and pinch roller 312 rotates to be connected in the other end of buffer board 311, and is out of plumb between buffer board 311 and the slip direction of initiative ejector pad 4, and the axis of rotation of pinch roller 312 is vertical, and the periphery of pinch roller 312 is used for rolling the surface of butt slide glass. The pinch roller 312 is equipped with a plurality ofly side by side along the sliding direction that is on a parallel with initiative ejector pad 4, and buffer board 311 is equipped with the same number corresponding to buffer board 311, and in this embodiment, buffer board 311 and pinch roller 312 all are equipped with 3.

The driving part 32 is used for driving the active calibration block 31 to slide horizontally and in a sliding direction perpendicular to the active push block 4.

Referring to fig. 3, the driving member 32 includes an active member 321 and an abutment driving block 322, the active member 321 is provided as a roller, the active member 321 is rotatably connected to the passive abutment block 6, and a rotation axis of the active member 321 is vertical. The contact driving block 322 is fixedly connected to the driving calibration block 31, a driving surface 3221 is disposed on the contact driving block 322, and the driving member 321 is in rolling contact with the driving surface 3221.

Referring to fig. 4, after the driving assembly 5 drives the driving pushing block 4 to push the slide to slide until the slide abuts against the passive abutting block 6, the driving assembly 5 continues to push the slide to slide and drives the passive abutting block 6 to slide in a direction away from the driving pushing block 4, and at this time, the outer periphery of the driving member 321 rolls and abuts against the driving surface 3221 and drives the driving calibration block 31 to slide in a direction close to the passive calibration block 2 by abutting against the driving block 322.

Referring to fig. 5, the buffer 33 includes a connection seat 331, a stopper rod 332, a stopper 333, and a pressing spring 334. The connecting base 331 is fixedly connected to the base frame 1. The limiting rod 332 is horizontally arranged, one end of the limiting rod 332 is connected to the end face, facing the connecting seat 331, of the active calibration block 31, the other end of the limiting rod 332 penetrates through the connecting seat 331 and then extends out and is fixedly connected with the limiting block 333, and the end face, facing the limiting rod 332, of the limiting block 333 is also used for being attached to the connecting seat 331; the connecting seat 331 is provided with an avoiding hole 3311 for the limiting rod 332 to pass through, and the limiting rod 332 is slidably connected in the avoiding hole 3311. The pressing spring 334 is coaxially sleeved on the limiting rod 332, one end of the pressing spring 334 abuts against the end surface of the active calibration block 31 facing the connecting seat 331, and the other end of the pressing spring 334 abuts against the end surface of the connecting seat 331 facing the active calibration block 31. In this embodiment, there are two extrusion springs 334, two limiting rods 332 and two limiting blocks 333.

Referring to fig. 4 and 5, when the outer periphery of the driving member 321 is in rolling contact with the driving surface 3221, the driving block 322 is abutted to enable the driving calibration block 31 to slide in a direction approaching to the driven calibration block 2, at this time, the driving calibration block 31 pushes the limiting rod 332 to slide, and simultaneously, the pressing spring 334 is pressed under the combined action of the connecting seat 331 and the driving calibration block 31, and when the pressing wheel 312 is in rolling contact with the slide glass, the pressing wheel 312 is not easy to crush the slide glass through elastic deformation of the pressing spring 334 and elastic deformation of the buffer plate 311.

The implementation principle of a slide deviation rectifying mechanism in the embodiment of the application is as follows:

when the deviation is corrected, the glass slide is horizontally placed on the base frame 1, and the driving push block 4 is driven by the driving assembly 5 to push the glass slide to be embedded into the calibration space 7 in a sliding manner.

After the driving assembly 5 drives the driving pushing block 4 to push the slide to slide until the slide abuts against the passive abutting block 6, the driving assembly 5 continues to push the slide to slide and drives the passive abutting block 6 to slide in a direction away from the driving pushing block 4, at this time, the outer periphery of the driving piece 321 rolls to abut against the driving surface 3221 and drives the driving calibrating block 31 to slide in a direction close to the passive calibrating block 2 by abutting against the driving block 322. Meanwhile, the active calibration block 31 pushes the limit rod 332 to slide, the compression spring 334 is pressed under the combined action of the connecting seat 331 and the active calibration block 31, when the compression wheel 312 rolls and abuts against the slide glass, the compression wheel 312 is not easy to crush the slide glass through elastic deformation of the compression spring 334 and elastic deformation of the buffer plate 311, and finally the compression wheel 312 and the passive calibration block 2 are both attached to the slide glass, so that the deviation correction of the position of the slide glass is completed.

To reposition the passive abutment block 6 and the active alignment block 31 to align the next slide, the drive assembly 5 removes the force pushing the active push block 4 to slide, and thus the force applied to the passive abutment block 6. Through the elastic force of the pressing spring 334, the driving calibration block 31 is pushed to move in the direction away from the driven calibration block 2, at this time, the driving surface 3221 is attached to the driving member 321 in a sliding manner and drives the driven abutting block 6 to slide in the direction toward the driving pushing block 4, so that the purpose of resetting the driving calibration block 31 and the driven abutting block 6 is achieved.

The above are preferred embodiments of the present application, and the scope of protection of the present application is not limited thereto, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (9)

1. The utility model provides a slide mechanism of rectifying which characterized in that: comprises a base frame (1), a passive calibration block (2), an active calibration component (3), an active push block (4), a driving component (5) and a passive butting block (6); the base frame (1) is used for horizontally sliding and jointing the glass slide; the passive calibration block (2) is fixedly connected to the base frame (1); the active calibration assembly (3) is connected to the base frame (1), a calibration space (7) for embedding a slide glass is arranged between the active calibration assembly (3) and the passive calibration block (2), and the surface of the passive calibration block (2) facing the active calibration assembly (3) and the surface of the active calibration assembly (3) facing the passive calibration block (2) are used for the slide glass to be attached and positioned;

the active push block (4) is connected to the base frame (1) in a sliding manner, and the active push block (4) is used for driving the slide glass to be embedded into the calibration space (7) in a sliding manner; the driving component (5) is connected to the base frame (1), and the driving component (5) is used for driving the driving push block (4) to slide; the passive butt joint block (6) is connected and located on the base frame (1), one end, facing the active push block (4), of the passive butt joint block (6) extends into the calibration space (7), and the end face, facing the active push block (4), of the passive butt joint block (6) is used for abutting against the surface of the glass slide.

2. The slide rectification mechanism of claim 1, wherein: the active calibration assembly (3) comprises an active calibration block (31) and a driving component (32), the active calibration block (31) is connected to the base frame (1) in a sliding mode along a direction perpendicular to the sliding direction of the active push block (4), and the end face, facing the passive calibration block (2), of the active calibration block (31) is used for pressing the glass slide; the driving component (32) is used for driving the active calibration block (31) to slide.

3. The slide rectification mechanism of claim 2, wherein: the passive abutting block (6) is connected to the base frame (1) in a sliding mode, and the sliding direction of the passive abutting block (6) is parallel to the sliding direction of the active push block (4); the driving part (32) comprises a driving piece (321) and an abutting driving block (322), and the driving piece (321) is connected to the passive abutting block (6);

the abutting driving block (322) is fixedly connected to the driving calibration block (31), the abutting driving block (322) is provided with a driving surface (3221), and the driving surface (3221) is used for the sliding fit of the driving piece (321); when the passive abutting block (6) slides towards the direction far away from the active push block (4), the active part (321) is attached to the driving surface (3221) in a sliding mode, and the active calibration block (31) slides towards the direction close to the passive calibration block (2) by abutting against the driving block (322).

4. The slide rectification mechanism of claim 3, wherein: the driving piece (321) is set as a roller, the driving piece (321) is rotatably connected to the passive abutting block (6), and the rotating axis of the driving piece (321) is vertical.

5. The slide rectification mechanism of claim 3, wherein: the active calibration assembly (3) further comprises a buffer member (33), the buffer member (33) has elasticity, one end of the buffer member (33) is connected to the base frame (1), and the other end of the buffer member (33) is connected to the active calibration block (31).

6. The slide rectification mechanism of claim 5, wherein: bolster (33) are including connecting seat (331) and extrusion spring (334), connecting seat (331) fixed connection is in bed frame (1), the one end fixed connection of extrusion spring (334) is in connecting seat (331), initiative alignment block (31) is connected to the other end of extrusion spring (334).

7. The slide rectification mechanism of claim 2, wherein: a pressing wheel (312) is arranged on the active calibration block (31), the pressing wheel (312) is rotatably connected to the end face, facing the passive calibration block (2), of the active calibration block (31), the rotating axis of the pressing wheel (312) is vertical, and the periphery of the pressing wheel (312) is in rolling contact with the glass slide; the pressing wheels (312) are arranged in parallel along the sliding direction of the driving push block (4).

8. The slide rectification mechanism of claim 7, wherein: be equipped with buffer board (311) of vertical setting on initiative alignment block (31), the one end fixed connection of buffer board (311) is on the terminal surface of initiative alignment block (31) orientation passive alignment block (2), pinch roller (312) rotate to be connected in the other end of buffer board (311), buffer board (311) have elasticity, just the nonperpendicular between the slip direction of buffer board (311) and initiative ejector pad (4).

9. The slide rectification mechanism of claim 1, wherein: the end face of the passive calibration block (2) facing the active calibration component (3) is provided with a plurality of grooves (21), and the grooves (21) are arranged side by side along the sliding direction parallel to the active push block (4).

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