CN220463659U - Automatic positioning device for multilayer hollow glass - Google Patents

Abstract

The utility model discloses an automatic positioning device for multi-layer hollow glass, which comprises an operation table, wherein a left-right moving mechanism is arranged at the top of the operation table, the left-right moving mechanism comprises a first through groove, the top of the operation table is provided with the first through groove, a first rotating shaft is arranged in the first through groove, a carrying plate is arranged on the outer side of the first rotating shaft, and the automatic positioning device for multi-layer hollow glass can drive a right movable clamping plate to move left and right by starting a first servo motor and can fix and position glass with different lengths by matching with a left fixed clamping plate, and can drive a rear clamping plate to move back and forth by starting a second servo motor, so that glass with different widths can be fixed and positioned.

Description

Automatic positioning device for multilayer hollow glass

Technical Field

The utility model relates to the technical field of glass positioning, in particular to an automatic positioning device for multi-layer hollow glass.

Background

The hollow glass is a new type building material with good heat-insulating, sound-insulating, beautiful and applicable properties and can reduce self weight of building, and is made up by using two (or three) glass sheets and using high-strength high-air-tightness composite adhesive to bond the glass sheets and aluminium alloy frame containing drying agent. Hollow glass has many properties superior to that of common double glass, and thus has been accepted worldwide, and is a glass product in which two or more sheets of glass are uniformly spaced by effective support and sealed by peripheral bonding, so that a dry gas space is formed between the glass sheets. The main materials are glass, warm edge spacing bars, bent angle bolts, butyl rubber, polysulfide rubber and drying agent. The hollow glass is composed of two or more layers of flat glass. And bonding and sealing two or more pieces of glass with sealing strips and glass strips by using a high-strength high-air-tightness composite adhesive at the periphery. And the middle is filled with drying gas, and the frame is filled with drying agent to ensure the dryness of air between glass sheets. The glass sheet with different performances such as colorless transparent float glass embossed glass, heat absorbing glass, heat reflecting glass, wire glass, toughened glass and the like and frames (aluminum frames or glass strips and the like) can be selected according to requirements, and the glass sheet is manufactured through cementing, welding or welding.

In view of the above, there is a need for innovative designs based on the original hollow glass positioning devices.

Disclosure of Invention

The utility model aims to provide an automatic positioning device for multi-layer hollow glass, which solves the problems that most of positioning devices are only suitable for glass of one specification type, the devices are required to be replaced when glass of different specifications is processed, and the operation is complicated and the efficiency is low.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the automatic positioning device for the multilayer hollow glass comprises an operation table, wherein a left-right moving mechanism is arranged at the top of the operation table, the left-right moving mechanism comprises a first through groove, the top of the operation table is provided with a first through groove, a first rotating shaft is arranged in the first through groove, a carrying plate is arranged on the outer side of the first rotating shaft, a right movable clamping plate is fixed at the top of the carrying plate above the operation table, a left fixed clamping plate is fixed at the position, far away from the right movable clamping plate, of the top of the operation table, a first servo motor is fixed at the end part of the first rotating shaft, penetrating through the inner part of the operation table, and fixedly arranged on the side of the operation table;

front and rear clamping mechanisms are arranged on the right movable clamping plate and the left fixed clamping plate, the front and rear clamping mechanisms comprise grooves, the grooves are formed in one sides of the right movable clamping plate and the left fixed clamping plate, a second rotating shaft is arranged in the grooves, a movable plate is arranged on the outer side of the second rotating shaft, the end parts of the movable plate penetrate through the grooves and are fixedly provided with rear clamping plates, the end parts of the second rotating shaft penetrate through the right movable clamping plate and the left fixed clamping plate, a second servo motor is fixed inside the right movable clamping plate and the left fixed clamping plate and fixedly arranged at the end parts of the right movable clamping plate and the left fixed clamping plate, and a front clamping plate is fixed at one side of the right movable clamping plate and one side of the left fixed clamping plate, which are far away from the rear clamping plate;

and the right movable clamping plate and the left fixed clamping plate are respectively provided with a fixing mechanism.

Preferably, the fixing mechanism comprises a second through groove, the right movable clamping plate and the left fixed clamping plate are respectively provided with a second through groove, an inner plate is arranged in the second through groove, one end of the inner plate is fixed with a screw rod, a nut is arranged at the end part of the screw rod, a movable plate is fixed at the other end part of the inner plate, a third rotating shaft penetrates through the movable plate, a handle is fixed at the top of the third rotating shaft, and a pressing plate is fixed at the bottom of the third rotating shaft.

Preferably, the first rotating shaft is in threaded connection with the carrying plate, and the outer side of the carrying plate is mutually attached to the inner side of the first through groove.

Preferably, the left fixed clamping plate and the front clamping plate are combined to form an L-shaped structure, the right movable clamping plate and the front clamping plate are combined to form an L-shaped structure, the second rotating shaft and the movable plate are in threaded connection, and meanwhile the outer side of the movable plate is mutually attached to the inner side of the groove.

Preferably, the moving plate and the third rotating shaft are in threaded connection.

Preferably, the outside of inner panel and the inboard of second through groove laminate each other, and the inner panel design is cuboid structure to lead screw and nut are threaded connection.

Compared with the prior art, the utility model has the beneficial effects that: this automatic positioner of multilayer cavity glass, left side fixed grip block 4 and preceding grip block 506 make up into "L" type structure, can be to the fixed location of a corner of not unidimensional glass, thereby guaranteed the starting end of not unidimensional glass all in a position, be favorable to the location of the glass processing equipment of operation panel top, through starting first servo motor, can drive right movable grip block and control the removal, cooperation left side fixed grip block, can be to the fixed location of glass of different length, through starting second servo motor, can drive back grip block back and forth movement, thereby can be to the fixed location of glass of different width, in sum, can be to the fixed location of glass of different sizes, through rotatory handle, can drive third pivot and clamp plate and do the reciprocate, thereby can be fixed to the top of glass, and third pivot and clamp plate can back-and-forth movement, when processing the glass of different sizes, can not shelter from the position that glass needs to process.

Drawings

FIG. 1 is a schematic top view of the present utility model;

FIG. 2 is a schematic view of an inner panel front sectional mounting structure of the present utility model;

FIG. 3 is a schematic diagram of a front cross-sectional mounting structure of a movable plate according to the present utility model;

FIG. 4 is a schematic view of an inner panel mounting structure according to the present utility model.

In the figure: 1. an operation table; 2. a left-right moving mechanism; 201. a first through groove; 202. a first rotating shaft; 203. a carrying plate; 204. a first servo motor; 3. a right movable clamping plate; 4. a left fixed clamping plate; 5. front and rear clamping mechanisms; 501. a groove; 502. a second rotating shaft; 503. a movable plate; 504. a rear clamping plate; 505. a second servo motor; 506. a front clamping plate; 6. a fixing mechanism; 601. a second through slot; 602. an inner plate; 603. a screw rod; 604. a nut; 605. a moving plate; 606. a third rotating shaft; 607. a handle; 608. and (5) pressing plates.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-4, the present utility model provides the following technical solutions: the automatic positioning device for the multilayer hollow glass comprises an operation table 1, wherein a left-right moving mechanism 2 is arranged at the top of the operation table 1, the left-right moving mechanism 2 comprises a first through groove 201, the top of the operation table 1 is provided with the first through groove 201, a first rotating shaft 202 is arranged in the first through groove 201, a carrying plate 203 is arranged on the outer side of the first rotating shaft 202, a right movable clamping plate 3 is fixed on the top of the carrying plate 203 above the operation table 1, a left fixed clamping plate 4 is fixed on the top of the operation table 1, far away from the right movable clamping plate 3, a first servo motor 204 is fixed at the end part of the first rotating shaft 202, penetrating through the inside of the operation table 1, and the first servo motor 204 is fixedly arranged on the side of the operation table 1;

the right movable clamping plate 3 and the left fixed clamping plate 4 are respectively provided with a front clamping mechanism 5 and a rear clamping mechanism 5, the front clamping mechanisms 5 comprise grooves 501, grooves 501 are respectively formed in one sides of the right movable clamping plate 3 and the left fixed clamping plate 4, a second rotating shaft 502 is arranged in the grooves 501, movable plates 503 are arranged on the outer sides of the second rotating shafts 502, end parts of the movable plates 503 penetrate through the grooves 501 and are fixedly provided with rear clamping plates 504, end parts of the second rotating shafts 502 penetrate through the right movable clamping plate 3 and the left fixed clamping plate 4 and are fixedly provided with second servo motors 505, the second servo motors 505 are fixedly arranged at the end parts of the right movable clamping plate 3 and the left fixed clamping plate 4, and front clamping plates 506 are respectively fixed at positions, far away from the rear clamping plates 504, of one sides of the right movable clamping plate 3 and the left fixed clamping plate 4;

the right movable clamping plate 3 and the left fixed clamping plate 4 are respectively provided with a fixing mechanism 6.

The fixing mechanism 6 comprises a second through groove 601, the right movable clamping plate 3 and the left fixed clamping plate 4 are respectively provided with the second through groove 601, an inner plate 602 is arranged in the second through groove 601, a screw rod 603 is fixed at one end of the inner plate 602, a nut 604 is arranged at the end of the screw rod 603, a movable plate 605 is fixed at the other end of the inner plate 602, a third rotating shaft 606 penetrates through the movable plate 605, a handle 607 is fixed at the top of the third rotating shaft 606, and a pressing plate 608 is fixed at the bottom of the third rotating shaft 606.

The first rotating shaft 202 is in threaded connection with the carrying plate 203, the outer side of the carrying plate 203 is mutually attached to the inner side of the first through groove 201, the first servo motor 204 is started to drive the first rotating shaft 202 to rotate positively and negatively, so that the carrying plate 203 and the right movable clamping plate 3 can move leftwards or rightwards, the distance between the right movable clamping plate 3 and the left fixed clamping plate 4 can be changed, and glass with different lengths can be positioned.

The left fixed clamping plate 4 and the front clamping plate 506 are combined to form an L-shaped structure, the right movable clamping plate 3 and the front clamping plate 506 are combined to form an L-shaped structure, the second rotating shaft 502 and the movable plate 503 are in threaded connection, meanwhile, the outer side of the movable plate 503 and the inner side of the groove 501 are mutually attached, the second rotating shaft 502 can be driven to rotate by starting the second servo motor 505, and accordingly the movable plate 503 and the rear clamping plate 504 can be made to move forwards and backwards, the distance between the rear clamping plate 504 and the front clamping plate 506 can be changed, and glass with different widths can be positioned.

The movable plate 605 and the third rotating shaft 606 are in threaded connection, and the third rotating shaft 606 can drive the pressing plate 608 to move downwards by rotating the third rotating shaft 606, so that the top of glass can be fixed, and the situation that the glass moves up and down during glass processing is avoided.

The outside of inner panel 602 and the inboard of second through groove 601 laminate each other, and inner panel 602 designs to the cuboid structure to lead screw 603 and nut 604 are threaded connection, have guaranteed that inner panel 602 can be at the inside back-and-forth movement of second through groove 601, thereby can adjust the position of movable plate 605, have guaranteed when processing the glass to different sizes, movable plate 605 can remove, can not shelter from the position that glass needs processing.

Working principle: when the automatic positioning device for the multi-layer hollow glass is used, firstly, the glass is placed on the top of the operation table 1, then the left side of the glass is attached to the right side of the left fixed clamping plate 4, and then the front side of the glass is attached to the rear side of the front clamping plate 506, so that the glass is positioned on the top of the operation table 1;

then, the first servo motor 204 is started, at this time, the first servo motor 204 drives the first rotating shaft 202 to rotate, and as the first rotating shaft 202 and the carrying plate 203 are in threaded connection, and the outer side of the carrying plate 203 is mutually attached to the inner side of the first through groove 201, the carrying plate 203 and the right movable clamping plate 3 move to the left side, so that glass fixing and positioning of different lengths can be completed by matching with the left fixed clamping plate 4;

then, the second servo motor 505 is started, at this time, the second servo motor 505 drives the second rotating shaft 502 to rotate, and as the second rotating shaft 502 and the movable plate 503 are in threaded connection and the outer side of the movable plate 503 is mutually attached to the inner side of the groove 501, the movable plate 503 and the rear clamping plate 504 move close to the front clamping plate 506, so that glass with different widths can be fixedly positioned;

then, according to the processing condition of glass, the position of the moving plate 605 is moved, so that the moving plate 605 does not obstruct the processing of glass, the nut 604 is rotated, the nut 604 is far away from the left fixed clamping plate 4, then the moving plate 605 is moved, the moving plate 605 drives the inner plate 602 to move in the second through groove 601, after the position of the moving plate 605 is adjusted, the nut 604 is rotated, one side of the nut 604 is attached to one side of the left fixed clamping plate 4, the moving plate 605 is fixed, then the handle 607 is rotated, and then the handle 607 drives the third rotating shaft 606 to rotate, and the third rotating shaft 606 and the moving plate 605 are in threaded connection, so that the third rotating shaft 606 and the pressing plate 608 move downwards to fix the top of the glass, thereby ensuring the processing stability of the glass.

Although the present utility model has been described with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements and changes may be made without departing from the spirit and principles of the present utility model.

Claims (6)

1. Automatic positioner of multilayer cavity glass, including operation panel (1), its characterized in that: the top of operation panel (1) is provided with left and right movement mechanism (2), left and right movement mechanism (2) are including first logical groove (201), first logical groove (201) has been seted up at the top of operation panel (1), the internally mounted in first logical groove (201) has first pivot (202), the outside of first pivot (202) is provided with carries thing board (203), the top that carries thing board (203) is located the top of operation panel (1) is fixed with right movable grip block (3), the top of operation panel (1) is kept away from right movable grip block (3) department and is fixed with left fixed grip block (4), the tip of first pivot (202) runs through the inside of operation panel (1) and is fixed with first servo motor (204), first servo motor (204) fixed mounting is in the avris of operation panel (1).

Front and rear clamping mechanisms (5) are arranged on the right movable clamping plate (3) and the left fixed clamping plate (4), the front and rear clamping mechanisms (5) comprise grooves (501), the grooves (501) are formed in one sides of the right movable clamping plate (3) and the left fixed clamping plate (4), a second rotating shaft (502) is arranged in the grooves (501), a movable plate (503) is arranged on the outer side of the second rotating shaft (502), a rear clamping plate (504) is fixed in the grooves (501) in a penetrating manner at the end part of the movable plate (503), a second servo motor (505) is fixed in the right movable clamping plate (3) and the left fixed clamping plate (4), and a front clamping plate (506) is fixed at one side, far away from the rear clamping plate (504), of the right movable clamping plate (3) and the left fixed clamping plate (4);

the right movable clamping plate (3) and the left fixed clamping plate (4) are respectively provided with a fixing mechanism (6).

2. The automated positioning apparatus of multiple layer hollow glass of claim 1, wherein: the fixing mechanism (6) comprises a second through groove (601), the second through groove (601) is formed in each of the right movable clamping plate (3) and the left fixed clamping plate (4), an inner plate (602) is arranged in each of the second through grooves (601), a screw rod (603) is fixed at one end of each inner plate (602), a nut (604) is arranged at the end of each screw rod (603), a movable plate (605) is fixed at the other end of each inner plate (602), a third rotating shaft (606) penetrates through the movable plate (605), a handle (607) is fixed at the top of each third rotating shaft (606), and a pressing plate (608) is fixed at the bottom of each third rotating shaft (606).

3. The automated positioning apparatus of multiple layer hollow glass of claim 1, wherein: the first rotating shaft (202) is in threaded connection with the carrying plate (203), and the outer side of the carrying plate (203) is mutually attached to the inner side of the first through groove (201).

4. The automated positioning apparatus of multiple layer hollow glass of claim 1, wherein: the left fixed clamping plate (4) and the front clamping plate (506) are combined to form an L-shaped structure, the right movable clamping plate (3) and the front clamping plate (506) are combined to form an L-shaped structure, the second rotating shaft (502) and the movable plate (503) are in threaded connection, and meanwhile the outer side of the movable plate (503) and the inner side of the groove (501) are mutually attached.

5. The automated positioning apparatus of multiple layer hollow glass of claim 2, wherein: the moving plate (605) and the third rotating shaft (606) are in threaded connection.

6. The automated positioning apparatus of multiple layer hollow glass of claim 2, wherein: the outer side of the inner plate (602) is mutually attached to the inner side of the second through groove (601), the inner plate (602) is of a cuboid structure, and the screw rod (603) and the nut (604) are in threaded connection.