CN216736271U - High-efficient tilting mechanism of microcrystalline glass board - Google Patents

Abstract

The utility model discloses a high-efficiency turnover mechanism of a microcrystalline glass plate, which comprises: the first conveyor is provided with a first inlet end; the second conveyor is provided with a second outlet end, and the second outlet end is opposite to the first inlet end; flip structure, including frame, motor, pivot and first roll-over stand, the output shaft of motor with the pivot is connected, the pivot is located between first entry end and the second exit end, the both ends of pivot with the frame rotates to be connected, the pivot is followed its radial through-hole that is used for supplying the microcrystalline glass board to pass through that is equipped with, first roll-over stand with the outer peripheral face of pivot is connected, first roll-over stand with the setting is staggered to the through-hole, first roll-over stand sets up to the open-ended board chamber of putting in the pivot outside. The efficient turnover mechanism for the microcrystalline glass plate can turn over the microcrystalline glass plate needing to be turned over, and the microcrystalline glass plate needing not to be turned over can directly pass through and enter the next working procedure.

Description

High-efficient tilting mechanism of microcrystalline glass board

Technical Field

The utility model relates to the technical field of microcrystalline glass processing equipment, in particular to a high-efficiency turnover mechanism for a microcrystalline glass plate.

Background

In the production process, the microcrystalline glass plate needs to be annealed in an annealing kiln and then enters a crystallization kiln for crystallization. Before entering the crystallization process, some varieties need to be turned over by 180 degrees and then enter a crystallization kiln, and some varieties need not to be turned over and directly enter the crystallization kiln to be crystallized after being turned over. However, in the prior art, the glass turnover machine turns over all the microcrystalline glass, and the microcrystalline glass which does not need to be turned over needs to be carried by hands to bypass the turning process of the glass turnover machine, so that the efficiency is low.

SUMMERY OF THE UTILITY MODEL

The present invention is directed to solving at least one of the problems of the prior art. Therefore, the utility model provides an efficient turnover mechanism for a microcrystalline glass plate.

The solution of the utility model for solving the technical problem is as follows:

an efficient turnover mechanism for a microcrystalline glass sheet, comprising:

the first conveyor is provided with a first inlet end;

the second conveyor is provided with a second outlet end, and the second outlet end is opposite to the first inlet end;

flip structure, flip structure includes frame, motor, pivot and first roll-over stand, the output shaft of motor with the pivot is connected, the pivot is located between first entry end and the second exit end, the both ends of pivot with the frame rotates to be connected, the pivot is followed its radial through-hole that is used for supplying the microcrystalline glass board to pass through that is equipped with, first roll-over stand with the outer peripheral face of pivot is connected, first roll-over stand with the setting of staggering of through-hole, first roll-over stand is erect and is put the board chamber to pivot outside open-ended.

The utility model has at least the following beneficial effects: the efficient turnover mechanism of the microcrystalline glass plate drives the rotating shaft to rotate through the motor so as to adjust the position of the first turnover frame, so that the microcrystalline glass plate to be turned over moves from the second conveyor to the plate placing cavity of the first turnover frame, and then the motor drives the rotating shaft to continuously rotate, so that the first turnover frame drives the microcrystalline glass plate to turn over for 180 degrees and then transmits the microcrystalline glass plate to the first conveyor; in addition, the motor orders about the pivot and rotates the position that comes the adjustment through-hole to the microcrystalline glass board that makes need not the upset directly passes the through-hole from the second conveyer and removes to first conveyer, does not need artifical transport, has improved work efficiency, and can avoid the cracked phenomenon of microcrystalline glass board that artifical transport caused.

As a further improvement of the technical scheme, the first turnover frame comprises an upper clamping plate and a lower clamping plate, the upper clamping plate is located above the lower clamping plate and is parallel to the lower clamping plate, the upper clamping plate and the lower clamping plate are connected with the outer peripheral surface of the rotating shaft, a gap is reserved between the upper clamping plate and the lower clamping plate, and the gap is a plate placing cavity. The glass ceramic plate clamping device is simple in structure and can clamp the glass ceramic plate by arranging the upper clamping plate and the lower clamping plate to form the plate placing cavity.

As a further improvement of the technical scheme, the structure of the upper clamping plate is consistent with that of the lower clamping plate, and the upper clamping plate and the lower clamping plate both comprise two connecting rods, the two connecting rods are connected with the peripheral surface of the rotating shaft, and the two connecting rods are arranged at intervals and in parallel. So set up, can let first conveyer and second conveyer be closer to the pivot setting, first roll-over stand can be along with the rotatory a week of pivot and not collide with first conveyer and second conveyer, moreover, can alleviate the weight of first roll-over stand to reduce the energy consumption of motor.

As a further improvement of the technical scheme, the inner wall surface of the plate placing cavity is provided with a buffer block. The buffer blocks are arranged on the lower surface of the upper clamping plate and the upper surface of the lower clamping plate, so that the friction coefficients of the upper clamping plate, the lower clamping plate and the microcrystalline glass plate can be increased, the microcrystalline glass plate is prevented from flying out from an opening of the plate placing cavity in the overturning process, and the microcrystalline glass plate is prevented from being scratched in the process of contacting with the inner side wall surface of the plate placing cavity; and, the surface that is located the board chamber of pivot sets up the buffer block, can produce buffering shock attenuation effect to the microcrystalline glass board of carrying coming, avoids the microcrystalline glass board because of direct and pivot striking impaired.

As a further improvement of the above technical solution, the turnover structure further includes a divider, an output shaft of the motor is connected with an input shaft of the divider, and the rotating shaft is connected with an output shaft of the divider. A divider is arranged between an output shaft of the motor and the rotating shaft, so that the first roll-over stand can move intermittently under the condition that the output shaft of the motor rotates continuously, and the motor is prevented from being started and stopped frequently.

As a further improvement of the above technical solution, a connecting shaft is arranged between the divider and the rotating shaft, the connecting shaft is provided with a shaft shoulder, one end of the connecting shaft is connected with the output shaft of the divider, and the other end of the connecting shaft is connected with the rotating shaft. The connecting shaft is additionally arranged between the divider and the rotating shaft, so that the torque of the divider can be transmitted to the rotating shaft to enable the rotating shaft to rotate, the shaft shoulder on the connecting shaft can play a role in axial positioning, and the connecting shaft, the rotating shaft connected with the connecting shaft and the divider are prevented from axially moving.

As a further improvement of the technical scheme, the rack is provided with a mounting seat, and the mounting seat is connected with the divider through bolts. The special mounting seat is arranged on the rack for mounting the divider, so that the layout of the turnover mechanism of the microcrystalline glass plate is more attractive, and the reduction of precision caused by vibration and displacement of the divider in the turnover process can be avoided.

As a further improvement of the technical scheme, the device further comprises a second roll-over stand, the second roll-over stand is connected with the outer peripheral surface of the rotating shaft, the second roll-over stand and the first roll-over stand are symmetrically arranged about the central axis of the rotating shaft, and the structure of the second roll-over stand is consistent with that of the first roll-over stand. The second turnover frame is arranged and is symmetrical to the first turnover frame, when the first turnover frame turns over the microcrystalline glass plate to the first conveyor, the next microcrystalline glass plate on the second conveyor can enter the plate placing cavity of the second turnover frame, continuous turnover is achieved, and the work efficiency of the efficient turnover mechanism of the microcrystalline glass plate is improved.

As a further improvement of the technical scheme, the structure of the first conveyor is consistent with that of the second conveyor, and the first conveyor comprises a chassis, a driving shaft, a driven shaft, a belt conveying part and a driving device, wherein the driving shaft and the driven shaft are connected with the chassis in a rotating mode, the belt conveying part is arranged along the axis of the driving shaft at intervals and comprises a plurality of belts, a first belt pulley and a second belt pulley, the first belt pulley is arranged on the driving shaft, the second belt pulley is arranged on the driven shaft, the first belt is sleeved on the first belt pulley and the second belt pulley in a tensioning mode, and the driving device is connected with the driving shaft in a transmission mode. The first conveyor and the second conveyor both adopt a belt transmission mode to transmit the microcrystalline glass plate, and the belt pulley transmission can alleviate load impact, so that the belt conveyor is simple in structure, convenient to adjust, stable in operation, low in noise and low in vibration.

Drawings

In order to more clearly illustrate the technical solution in the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly described below. It is obvious that the drawings described are only some embodiments of the utility model, not all embodiments, and that those skilled in the art will be able to derive other designs and drawings from them without inventive effort.

FIG. 1 is a front view of a high-efficiency turnover mechanism for a microcrystalline glass sheet according to an embodiment of the present invention;

fig. 2 is a top view of a high-efficiency turnover mechanism of a microcrystalline glass sheet according to an embodiment of the present invention;

FIG. 3 is a left side view of the high-efficiency turnover mechanism of the microcrystalline glass plate according to the embodiment of the utility model;

fig. 4 is a schematic structural diagram of another working state of the high-efficiency turnover mechanism of the microcrystalline glass plate in the embodiment of the utility model.

Reference numerals: 100. a first conveyor; 110. a belt; 120. a first pulley; 130. a second pulley; 200. a second conveyor; 300. a motor; 400. a divider; 500. a rotating shaft; 510. a first roll-over stand; 511. placing a plate cavity; 512. a buffer block; 520. a second roll-over stand; 530. a through hole; 600. a frame; 610. supporting legs; 620. a base fixing plate; 630. a mounting seat; 640. a cross brace; 700. a connecting shaft; 710. a bearing seat; 800. a microcrystalline glass sheet.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the accompanying drawings are illustrative only for the purpose of explaining the present invention and are not to be construed as limiting the present invention.

In the description of the present invention, it should be understood that the orientation or positional relationship referred to in the description of the orientation, such as the upper, lower, front, rear, left, right, etc., is based on the orientation or positional relationship shown in the drawings, and is only for convenience of description and simplification of description, and does not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

In the description of the present invention, the meaning of a plurality of means is one or more, the meaning of a plurality of means is two or more, and larger, smaller, larger, etc. are understood as excluding the number, and larger, smaller, inner, etc. are understood as including the number. If the first and second are described for the purpose of distinguishing technical features, they are not to be understood as indicating or implying relative importance or implicitly indicating the number of technical features indicated or implicitly indicating the precedence of the technical features indicated.

In the description of the present invention, unless otherwise specifically limited, terms such as set, installation, connection and the like should be understood in a broad sense, and those skilled in the art can reasonably determine the specific meanings of the above terms in the present invention by combining the specific contents of the technical solutions.

It is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and those skilled in the art can obtain other embodiments without inventive effort based on the embodiments of the present invention, and all embodiments are within the protection scope of the present invention. The technical characteristics of the utility model can be combined interactively on the premise of not conflicting with each other.

Referring to fig. 1 to 4, the high-efficiency turnover mechanism for a crystallized glass sheet in the embodiment of the present invention includes a first conveyor 100, a second conveyor 200, and a turnover structure. Wherein, the first conveyor 100 is provided with a first inlet end and a first outlet end, the second conveyor 200 is provided with a second inlet end and a second outlet end, and the first inlet end and the second outlet end are oppositely arranged.

It is understood that the crystallized glass sheet 800 can be conveyed from the second inlet end to the second outlet end of the second conveyor 200 and can also be conveyed from the first inlet end to the first outlet end of the first conveyor 100. The microcrystalline glass sheet 800 enters the efficient turnover mechanism of the microcrystalline glass sheet in this embodiment from the second inlet end and exits the efficient turnover mechanism of the microcrystalline glass sheet in this embodiment from the first outlet end.

In addition, the turning structure in this embodiment includes a frame 600, a motor 300, a rotating shaft 500 and a first turning frame 510, and an output shaft of the motor 300 is connected to the rotating shaft 500, for example, connected by a coupling. The rotating shaft 500 is located between the first inlet end and the second outlet end, and two ends of the rotating shaft 500 are rotatably connected to the frame 600 through a bearing seat, in this embodiment, an axis of the rotating shaft 500 extends in a front-rear direction. The first turning frame 510 is connected to the outer circumferential surface of the rotating shaft 500, for example, by a welding process or an integral molding process. The first roll-over stand 510 is provided with a plate placing cavity 511 which is opened towards the outer side of the rotating shaft 500.

It should be noted that the rotating shaft 500 in this embodiment is provided with a through hole 530, the through hole 530 is disposed along the radial direction of the rotating shaft 500, and the first turning frame 510 and the through hole 530 are disposed in a staggered manner. In the present embodiment, the through hole 530 has a long strip shape, and the glass-ceramic plate 800 can pass through the rotating shaft 500 from the through hole 530.

When the microcrystalline glass plate 800 needs to be turned over, the motor 300 drives the rotating shaft 500 to rotate so as to open the plate placing cavity 511 of the first turning frame 510 towards the second conveyor 200, the second conveyor 200 conveys the microcrystalline glass plate 800 from the second inlet end to the second outlet end, and conveys the microcrystalline glass plate 800 into the plate placing cavity 511 of the first turning frame 510; then, the motor 300 drives the rotating shaft 500 to rotate 180 degrees, so that the first turning frame 510 turns 180 degrees, the opening of the plate placing cavity 511 faces the first conveyor 100, the first conveyor 100 conveys the microcrystalline glass plate 800 in the plate placing cavity 511 from the first inlet end to the first outlet end, and finally the microcrystalline glass plate 800 leaves the efficient turning mechanism of the microcrystalline glass plate in the embodiment and is conveyed to equipment of the next process.

It can be understood that, in this embodiment, the first conveyor 100 is located at the left side of the second conveyor 200, and after the microcrystalline glass sheet 800 moves into the sheet placing cavity 511, the rotating shaft 500 drives the first turning frame 510 to turn 180 degrees counterclockwise, so as to prevent the microcrystalline glass sheet 800 in the sheet placing cavity 511 from falling and being damaged. In other embodiments, the first conveyor 100 is located at the right side of the second conveyor 200, and after the microcrystalline glass sheet 800 moves into the sheet placing cavity 511, the rotating shaft 500 drives the first turning frame 510 to turn 180 degrees clockwise, so as to prevent the microcrystalline glass sheet 800 from falling down due to the downward opening of the sheet placing cavity 511 when the microcrystalline glass sheet 800 is placed in the sheet placing cavity 511.

When the microcrystalline glass plate 800 does not need to be turned over, the rotating shaft 500 is driven by the motor 300 to rotate, so that the two openings of the through hole 530 arranged on the rotating shaft 500 face the first inlet end and the second outlet end respectively, the microcrystalline glass plate 800 is conveyed from the second inlet end to the second outlet end under the conveying action of the second conveyor 200, enters the first conveyor 100 from the first inlet end after passing through the through hole 530 of the rotating shaft 500, the first conveyor 100 conveys the microcrystalline glass plate 800 from the first inlet end to the first outlet end, and finally, the microcrystalline glass plate leaves the efficient turning mechanism of the microcrystalline glass plate in the embodiment to be sent to equipment in the next process.

In the present embodiment, the opening direction of the board placing cavity 511 is perpendicular to the axial direction of the through hole 530. If the opening of the board placing cavity 511 of the first roll-over stand 510 faces the second outlet end as the original state, the first roll-over stand 510 rotates 90 degrees along with the rotating shaft 500, the two openings of the through hole 530 face the first inlet end and the second outlet end respectively, and the opening of the board placing cavity 511 of the first roll-over stand 510 faces upward or downward.

In some embodiments, the flipping structure further comprises a divider 400, an output shaft of the motor 300 is connected to an input shaft of the divider 400, and the rotating shaft 500 is connected to an output shaft of the divider 400.

The divider 400 in this embodiment is a cam divider, is a mechanism capable of realizing intermittent motion, and has the significant characteristics of high indexing accuracy, stable operation, large transmission torque, self-locking during positioning, compact structure, small volume, low noise, good high-speed performance, long service life, and the like.

In this embodiment, a connecting shaft 700 is disposed between divider 400 and rotating shaft 500, one end of connecting shaft 700 is coupled to divider 400 through a coupler, and the other end of connecting shaft 700 is connected to rotating shaft 500 through a coupler. It is understood that torque may be transmitted to the rotation shaft 500 by providing the connection shaft 700.

In some embodiments, the frame 600 is provided with a bearing seat 710, the connecting shaft 700 is mounted on the bearing seat 710, and the bearing seat 710 plays a role of supporting the connecting shaft 700, reduces a friction coefficient of the connecting shaft 700 during a rotation motion, and ensures a rotation precision of the connecting shaft 700. In addition, a shaft shoulder is arranged on the connecting shaft 700, and the shaft shoulder plays a role in axial positioning, so that the connecting shaft 700, the rotating shaft 500 connected with the connecting shaft 700 and the divider 400 are prevented from axially moving.

In some embodiments, frame 600 has a mounting base 630, and divider 400 is mounted on mounting base 630, and divider 400 is fixed to mounting base 630 by bolting. The installation seat 630 specially used for installing the divider 400 is arranged on the frame 600, so that the layout of the efficient turnover mechanism of the microcrystalline glass plate is more attractive, and the problem that the precision of the divider 400 is reduced due to vibration and displacement in the turnover process can be avoided.

In some embodiments, the structure of the first conveyor 100 includes a chassis, a drive shaft, a driven shaft, a belt conveying member, and a drive device. Wherein, driving shaft and driven shaft all rotate through bearing frame and chassis and are connected, belt conveyor part is equipped with a plurality ofly along the axis interval of driving shaft, belt conveyor part includes belt 110, first belt pulley 120 and second belt pulley 130, all first belt pulleys 120 are established on the driving shaft, all second belt pulleys 130 are established on the driven shaft, drive arrangement is connected with the driving shaft and can drive the driving shaft and drive first belt pulley 120 and rotate, belt 110 cup joints on first belt pulley 120 and second belt pulley 130 with tensioning, second belt pulley 130 rotates under first belt pulley 120 and belt 110's drive.

In this embodiment, the first pulley 120 is located at the first outlet end and the second pulley 130 is located at the first inlet end, the diameter of the first pulley 120 being greater than the diameter of the second pulley 130. It will be appreciated that the first pulley 120, which is a driving pulley, may also be located at the first inlet end, while the second pulley 130, which is a driven pulley, is located at the first outlet end.

It is understood that the ratio of the diameter of the first pulley 120 to the diameter of the second pulley 130 is equal to the ratio of the rotation speed of the second pulley 130 to the rotation speed of the first pulley 120, and the diameters of the first pulley 120 and the second pulley 130 are adjusted according to actual requirements and are not limited in particular.

In the present embodiment, the structure of the second conveyor 200 is identical to that of the first conveyor 100, and a repeated description thereof will not be made. In the present embodiment, the transmission ratio of the first conveyor 100 coincides with the transmission ratio of the second conveyor 200.

In some embodiments, the first conveyor 100 and the second conveyor 200 are provided with tensioning wheels, which can control the tension of the belt 110 to avoid slippage of the belt 110. It will be appreciated that the tensioner is a conventional component in the art and that the construction and principles thereof will be apparent to those skilled in the art and will not be described in detail herein.

It is understood that the belt 110 may be a flat belt or a V-belt, and is not limited thereto.

In some embodiments, the driving device is a motor driving device, and the motor driving device is used to drive the first pulley 120 and the second pulley 130, which can reduce manual operation.

In some embodiments, the first roll-over stand 510 includes an upper plate and a lower plate, the upper plate is located above the lower plate and is parallel to the lower plate, the upper plate and the lower plate are both connected to the outer peripheral surface of the rotating shaft 500, and a gap is left between the upper plate and the lower plate, which is a plate placing cavity 511 and can accommodate the microcrystalline glass plate 800. In the present embodiment, all the second pulleys 130 are located at the front and right sides of the upper plate, respectively.

In some embodiments, the upper plate includes two connecting rods, both of which are connected to the outer circumferential surface of the rotating shaft 500, and the two connecting rods are spaced apart and arranged in parallel. In this embodiment, the second pulley 130 is located between the two connecting rods, i.e. the length of the driven shaft is smaller than the distance between the two connecting rods. The structure of the lower splint is consistent with that of the upper splint.

So set up, first conveyer 100 and second conveyer 200 can be more close to pivot 500 and set up, make the structure of the high-efficient tilting mechanism of whole glass-ceramic plate more compact, let the less glass-ceramic plate 800 of length also can normally transmit first conveyer 100 from second conveyer 200, and first roll-over stand 510 can carry out 360 degrees rotations along with pivot 500 and do not collide with first conveyer 100 and second conveyer 200.

In some embodiments, the inner wall of the plate placing cavity 511 is provided with a buffer block 512. Specifically, the buffer blocks 512 are arranged on the lower surface of the upper clamping plate and the upper surface of the lower clamping plate, so that the friction between the upper surfaces of the upper clamping plate and the lower clamping plate and the surface of the microcrystalline glass plate 800 can be increased, the microcrystalline glass plate 800 is prevented from flying out of an opening of the plate placing cavity 511 in the process of rotating the first roll-over stand 510, and the microcrystalline glass plate 800 is prevented from being scratched in the process of contacting the inner wall surface of the plate placing cavity 511; in addition, the surface of the rotating shaft 500, which is located in the plate placing cavity 511, is also provided with a buffer block 512, so that a buffer and shock absorption effect can be generated on the conveyed microcrystalline glass plate 800, and the microcrystalline glass plate 800 is prevented from being damaged due to direct impact with the outer peripheral surface of the rotating shaft 500.

It can be understood that the buffer block 512 can be made of rubber and the like, and the rubber has high elasticity, so that the microcrystalline glass plate 800 can be well protected, and a good buffer effect can be realized.

It can be understood that, during the operation of the high-efficiency turnover mechanism of the microcrystalline glass plate in the embodiment, the friction between the plate placing cavity 511 and the surface of the microcrystalline glass plate 800 should be smaller than the friction between the belt 110 and the surface of the microcrystalline glass plate 800, so that the microcrystalline glass plate 800 in the plate placing cavity 511 can smoothly move onto the belt 110.

In some embodiments, the turning structure is further provided with a second turning frame 520, the first turning frame 510 and the second turning frame 520 are symmetrically arranged along the central axis of the rotating shaft 500, the second turning frame 520 is connected with the outer circumferential surface of the rotating shaft 500, and the structure of the second turning frame 520 is identical to that of the first turning frame 510.

When the first roll-over stand 510 overturns the microcrystalline glass plate 800 to the first conveyor 100, the plate placing cavity 511 of the first roll-over stand 510 is open towards the first inlet end, and the plate placing cavity 511 of the second roll-over stand 520 is open towards the second outlet end, so that the next microcrystalline glass plate 800 can be accommodated, the microcrystalline glass plate 800 can be overturned continuously by the efficient overturning mechanism of the microcrystalline glass plate in the embodiment, and the work efficiency is improved.

The first roll-over stand 510 and the second roll-over stand 520 are provided on the rotary shaft 500, and the divider 400 is provided between the output shaft of the motor 300 and the rotary shaft 500, so that the divider 400 is provided to allow the first roll-over stand 510 and the second roll-over stand 520 to move intermittently while ensuring the continuous operation of the motor 300. For example, when the microcrystalline glass plate 800 to be turned over moves to the plate placing cavity 511 of the first turning frame 510, the rotating shaft 500 drives the first turning frame 510 to rotate counterclockwise by 90 degrees under the driving action of the motor 300, and then the next microcrystalline glass plate 800 smoothly passes through the through hole 530 of the rotating shaft 500 without turning over.

Then, the rotating shaft 500 continues to drive the first turning frame 510 to rotate 90 degrees counterclockwise, so that the microcrystalline glass plate 800 is turned 180 degrees and can be transferred away by the first conveyor 100, meanwhile, the second turning frame 520 rotates to the second outlet end of the second conveyor 200, so that the microcrystalline glass plate 800 moves into the plate placing cavity 511 of the second turning frame 520 under the action of the second conveyor 200, and then the second turning frame 520 repeats the process of the first turning frame 510.

In some embodiments, the efficient turnover mechanism of the microcrystalline glass plate further comprises a base fixing plate 620, the frame 600 and the bottom frame are provided with a plurality of supporting legs 610, the lower end of each supporting leg 610 is connected with the base fixing plate 620, the stability of the efficient turnover mechanism of the microcrystalline glass plate can be increased, the effect of stabilizing the frame 600 and the bottom frame is achieved, and the efficient turnover mechanism of the microcrystalline glass plate is prevented from swinging due to vibration during working. In this embodiment, the lower end of each support foot 610 is connected to the base fixing plate 620 by bolts.

In some embodiments, the frame 600 and the bottom frame are both provided with a cross brace 640, and the cross brace 640 is disposed between the two support legs 610, so as to improve the stability of the support legs 610. It is understood that one cross brace 640 may be disposed between the two support feet 610, or a plurality of cross braces 640 may be disposed, and is not limited in particular.

While the preferred embodiments of the present invention have been illustrated and described, it will be understood by those skilled in the art that the present invention is not limited to the details of the embodiments shown and described, but is capable of numerous equivalents and substitutions without departing from the spirit of the utility model as set forth in the claims appended hereto.

Claims (9)

1. A high-efficient tilting mechanism of microcrystalline glass board, characterized by includes:

the first conveyor is provided with a first inlet end;

the second conveyor is provided with a second outlet end, and the second outlet end is opposite to the first inlet end;

flip structure, flip structure includes frame, motor, pivot and first roll-over stand, the output shaft of motor with the pivot is connected, the pivot is located between first entry end and the second exit end, the both ends of pivot with the frame rotates to be connected, the pivot is followed its radial through-hole that is used for supplying the microcrystalline glass board to pass through that is equipped with, first roll-over stand with the outer peripheral face of pivot is connected, first roll-over stand with the setting of staggering of through-hole, first roll-over stand is erect and is put the board chamber to pivot outside open-ended.

2. The efficient turnover mechanism for the microcrystalline glass plates as claimed in claim 1, wherein the first turnover frame comprises an upper clamping plate and a lower clamping plate, the upper clamping plate is located above the lower clamping plate and is parallel to the lower clamping plate, the upper clamping plate and the lower clamping plate are both connected with the outer peripheral surface of the rotating shaft, a gap is reserved between the upper clamping plate and the lower clamping plate, and the gap is a plate placing cavity.

3. The efficient turnover mechanism for glass ceramic plates as claimed in claim 2, wherein the upper clamping plate and the lower clamping plate have the same structure and comprise two connecting rods, the two connecting rods are connected with the outer peripheral surface of the rotating shaft, and the two connecting rods are spaced and arranged in parallel.

4. The efficient turnover mechanism for the microcrystalline glass plate as claimed in claim 2, wherein a buffer block is arranged on the inner wall surface of the plate placing cavity.

5. The efficient turnover mechanism for the microcrystalline glass plate as claimed in claim 1, wherein the turnover mechanism further comprises a divider, an output shaft of the motor is connected with an input shaft of the divider, and the rotating shaft is connected with an output shaft of the divider.

6. The efficient turnover mechanism for the microcrystalline glass plates as claimed in claim 5, wherein a connecting shaft is arranged between the divider and the rotating shaft, the connecting shaft is provided with a shaft shoulder, one end of the connecting shaft is connected with an output shaft of the divider, and the other end of the connecting shaft is connected with the rotating shaft.

7. The efficient turnover mechanism for the microcrystalline glass plate as claimed in claim 5, wherein the rack is provided with a mounting seat, and the mounting seat is connected with the divider through bolts.

8. The efficient turnover mechanism for the microcrystalline glass sheets as claimed in any one of claims 1 to 7, further comprising a second turnover frame, wherein the second turnover frame is connected with the outer peripheral surface of the rotating shaft, the second turnover frame and the first turnover frame are symmetrically arranged around the central axis of the rotating shaft, and the structure of the second turnover frame is consistent with that of the first turnover frame.

9. The efficient turnover mechanism for the microcrystalline glass plates as claimed in claim 1, wherein the first conveyor and the second conveyor are identical in structure and comprise a chassis, a driving shaft, a driven shaft, a belt conveying part and a driving device, the driving shaft and the driven shaft are rotatably connected with the chassis, the belt conveying part is arranged in a plurality of positions along the axis of the driving shaft at intervals, the belt conveying part comprises a belt, a first belt pulley and a second belt pulley, the first belt pulley is arranged on the driving shaft, the second belt pulley is arranged on the driven shaft, the first belt is tightly sleeved on the first belt pulley and the second belt pulley, and the driving device is in transmission connection with the driving shaft.

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