CN215922896U - A feed bin that is used for automatic unloading of going up of vacuum coating equipment - Google Patents

Abstract

The utility model discloses a storage bin for automatic feeding and discharging of vacuum coating equipment, which relates to the technical field of storage bins and comprises a frame, wherein the frame is a cube formed by fixedly connecting a plurality of stand columns, a plurality of cross beams, a plurality of longitudinal beams and hanging beams; the plurality of drawing assemblies are vertically and uniformly distributed in the frame, and any drawing assembly is in sliding connection with the frame through the lower guide rail seat and the upper guide rail seat. According to the utility model, a plurality of drawing assemblies which are vertically arranged are uniformly arranged in the frame to vertically store the flitch, so that the unloading and buffering functions of the flitch are realized; a shifting fork rod at the bottom of the drawing component can be matched with an external linear drawing and releasing shifting fork mechanism to push the drawing component to reciprocate so as to complete the blanking and feeding actions of the material plate; the top of feed bin is equipped with can with the hanging beam that outside elevating system cooperation was used, makes things convenient for the feed bin to fill with when full, can be convenient quick place the feed bin on the dolly or take off from the dolly.

Description

A feed bin that is used for automatic unloading of going up of vacuum coating equipment

Technical Field

The utility model belongs to the technical field of storage bins, and particularly relates to a storage bin for automatic loading and unloading of vacuum coating equipment.

Background

Vacuum deposition is a common deposition technique in the photovoltaic and semiconductor industries of touch panels, solar cells, etc., and known methods include Physical Vapor Deposition (PVD) and Chemical Vapor Deposition (CVD). At present, automatic continuous vacuum coating equipment becomes one of the trends of coating equipment development, and one of the key points is the automation of a substrate loading and unloading mode for realizing the automatic continuous work of the vacuum coating equipment. The design of the substrate automatic loading and unloading mechanism of the vacuum coating equipment needs to consider the compatibility with the coating process of the coating chamber and other front and back processes, and also considers the performance stability and the cost factor.

In the prior art, the substrate of the coating drum of the coating equipment is inconvenient to manually take and place, and during manual operation, the coated substrate is easy to damage products when being additionally transferred and cached. In order to realize mechanical automation of feeding and discharging of vacuum coating equipment, a matched device and a storage bin are specially developed, but the existing storage bin is too complex in design, high in manufacturing cost, low in cost performance and inconvenient for later-stage maintenance.

Therefore, the utility model provides a storage bin for automatic feeding and discharging of vacuum coating equipment, which aims to solve the problems in the background art.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a storage bin for automatic feeding and discharging of vacuum coating equipment, which is used for solving the problems that the storage bin of the existing coating equipment is too complex in design, high in manufacturing cost, low in cost performance and inconvenient for later maintenance.

In order to achieve the purpose, the utility model provides the following technical scheme:

a storage bin for automatic feeding and discharging of vacuum coating equipment comprises a frame, wherein the frame is a cube formed by fixedly connecting a plurality of stand columns, a plurality of cross beams, a plurality of longitudinal beams and hanging beams;

the drawing components are vertically and uniformly distributed in the frame, and any drawing component is in sliding connection with the frame through the lower guide rail seat and the upper guide rail seat.

As a still further scheme of the utility model: the hanging beam is arranged in the middle of the two longitudinal beams at the top of the frame, and two ends of the hanging beam are fixedly connected with the two cross beams at the top of the frame respectively.

As a still further scheme of the utility model: the cross beams and the longitudinal beams at the bottom of the frame are at the same horizontal height.

As a still further scheme of the utility model: the drawing component comprises a hanging plate, a shifting fork rod, a plurality of hanging pins, an upper movable guide rail and a lower movable guide rail, wherein the hanging pins are fixedly connected to the top and the bottom of the same side of the hanging plate respectively.

As a still further scheme of the utility model: the shifting fork rod is assembled with an external linear retracting shifting fork mechanism, and the upper movable guide rail and the lower movable guide rail are respectively connected with the upper guide rail seat and the lower guide rail seat in a sliding manner.

As a still further scheme of the utility model: the lower guide rail seat comprises a lower rail seat, a lower fixed guide rail and a lower magnet, the upper guide rail seat comprises an upper rail seat, an upper fixed guide rail and an upper magnet, and the lower rail seat and the upper rail seat are both bending plates.

As a still further scheme of the utility model: the horizontal side of the lower rail seat is fixedly connected to the top surfaces of the two longitudinal beams at the bottom of the frame, and the horizontal side of the upper rail seat is fixedly connected to the bottom surfaces of the two longitudinal beams at the top of the frame; and one vertical side of the lower rail seat and one vertical side of the upper rail seat are positioned on the same vertical plane.

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

1. according to the utility model, a plurality of drawing components which are vertically arranged are uniformly arranged in a frame, the number of the drawing components is matched with that of vacuum coating equipment, and the drawing components can extend out of the frame in a sliding manner; meanwhile, a flitch can be vertically placed on the drawing component, and unloading buffering of the flitch of the vacuum coating equipment is realized.

2. The pulling assembly is matched with an external linear retracting and releasing fork mechanism through a fork rod at the bottom, the pulling assembly is pushed to slide out of the bin, and after a material plate is hung on a hanging plate through a hanging pin, the linear retracting and releasing fork mechanism drives the pulling assembly to reset to complete one-time blanking action; conversely, when the steps are reversely implemented, the feeding action of the material plate is realized.

3. The utility model can be used in cooperation with external equipment, the bin can realize reciprocating linear motion on the ground through the external equipment, when the bin moves to a calibration position, the bin stops moving, and the linear retracting and releasing shifting fork mechanism is clamped with the corresponding drawing component to drive the drawing component to reciprocate; simultaneously, the top of feed bin is equipped with the hanging beam that can use with the cooperation of outside elevating system, when making things convenient for the feed bin to fill with, can be convenient quick place the feed bin on the dolly or take off from the dolly.

Drawings

In order to facilitate understanding for those skilled in the art, the present invention will be further described with reference to the accompanying drawings.

FIG. 1 is a schematic view of an overall structure of a storage bin for automatic loading and unloading of vacuum coating equipment;

FIG. 2 is a schematic view of a frame structure;

FIG. 3 is a schematic view of the push-pull assembly;

FIG. 4 is a schematic view of the structure of the lower rail seat;

FIG. 5 is a schematic structural view of an upper rail seat;

FIG. 6 is a schematic view of the assembly of the bin, the lifting mechanism and the slide rail according to the present invention;

FIG. 7 is a schematic view of the assembly of the double-bin and the vacuum coating apparatus and the robot.

In the figure: 1. a frame; 2. a pull assembly; 3. a lower guide rail seat; 4. an upper guide rail seat;

101. a column; 102. a cross beam; 103. a stringer; 104. a hanging beam;

201. hanging the plate; 202. a fork lever; 203. hanging a pin; 204. an upper movable guide rail; 205. a lower movable guide rail;

301. a lower rail seat; 302. a lower fixed guide rail; 303. magnetic attraction is carried out;

401. a rail seat is arranged; 402. an upper fixed guide rail; 403. and (6) magnetically attracting.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the detailed description and specific examples, while indicating the preferred embodiment of the utility model, are intended for purposes of illustration only and are not intended to limit the scope of the utility model. The components of embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the utility model, as claimed, but is merely representative of selected embodiments of the utility model. All other embodiments, which can be derived by a person skilled in the art from the embodiments of the present invention without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-5, in the embodiment of the utility model, a storage bin for automatic loading and unloading of vacuum coating equipment comprises a frame 1, wherein the frame 1 is a cuboid structure formed by assembling four vertically arranged upright posts 101, four cross beams 102, four longitudinal beams 103 and a hanging beam 104, the tops of the four upright posts 101 are fixedly connected with the two cross beams 102 and the two longitudinal beams 103, and the end surfaces of the two cross beams 102 and the two longitudinal beams 103 at the tops are respectively connected to the four corners of the tops of the upright posts 101; the two cross beams 102 and the two longitudinal beams 103 at the bottom are at the same horizontal height, and the horizontal height is determined according to the length of the drawing assembly 2 and the assembly requirement of the frame 1 from the bottom surface of the upright 101; the hanging beam 104 is arranged at the center of the top of the frame 1, and the hanging beam 104 is positioned between the two longitudinal beams 103 and is used for being matched with the lifting mechanism, so that the lifting mechanism can drive the frame 1 to ascend or descend integrally; through the above process, the installation of the whole frame 1 is completed, wherein the cross beams 102, the longitudinal beams 103 and the hanging beams 104 can be fixed together by welding, and can also be detachably connected by bolt connection.

The top surfaces of two longitudinal beams 103 at the bottom of the frame 1 are provided with a plurality of lower guide rail seats 3 which are uniformly distributed, the number of the lower guide rail seats 3 is matched with that of the drawing assemblies 2, the number of the drawing assemblies 2 is determined according to the model of the vacuum coating equipment, the drawing assemblies can be the same as that of the plates of the vacuum coating equipment, and the drawing assemblies can also be more than three than the plates to ensure that the capacity of the storage bin meets the requirement of stable operation of the vacuum coating equipment and play a role of buffering and transferring; lower rail seat 3 is inhaled 303 assembly by lower rail seat 301, lower fixed guide 302 and magnetism down and is constituteed, lower rail seat 301 wholly is the board of bending, and the both ends of lower rail seat 301 parallel plate are fixed on the top surface of two longerons 103 of frame 1 bottom through bolted connection respectively, and fixed guide 302 is used for assembling pull subassembly 2 under the outside fixedly connected with of the perpendicular board of lower rail, and magnetism is inhaled 303 under the afterbody of lower guide still fixedly mounted and is used for preventing pull subassembly 2 from roll-off naturally.

Install the upper guideway seat 4 that sets up with lower guideway seat 3 one-to-one on the bottom surface of two longerons 103 of frame 1 bottom, upper guideway seat 4 is by upper guideway seat 401, go up fixed guide 402 and last magnetism and inhale 403 assembly and constitute, upper guideway seat 401 is whole to be the board of bending, the both ends of going up the rail seat 401 parallel plate are respectively through bolt fixed connection on the bottom surface of two longerons 103 at frame 1 top, fixed guide 402 is used for using with the lower guideway cooperation and is used for assembling pull subassembly 2 on the outside fixedly connected with of upper guideway vertical plate, the last guide is installed at the afterbody of lower magnetism and is inhaled 303 homonymy and inhale 403 and inhale 303 cooperation and use with lower magnetism and be used for preventing pull subassembly 2 natural roll-off.

As shown in fig. 3, the drawing and pulling assembly 2 of the present invention includes a hanging plate 201, the hanging plate 201 is formed by fixedly connecting an outer ring mounting plate and an inner reinforcing plate, the mounting plate and the reinforcing plate can be fixedly connected into a whole by welding, or the whole plate can be integrally processed by machining, and the design of the outer ring mounting plate and the inner reinforcing plate of the hanging plate 201 can effectively enhance the overall structural strength of the hanging plate 201; two hanging pins 203 which are symmetrically arranged are arranged on one side of the top of the mounting plate of the hanging plate 201, and the two hanging pins 203 can penetrate through two mounting holes on the top of the plate; the bottom of the mounting plate is also provided with two hanging pins 203 at the corresponding positions on the same side of the top hanging pin 203, and the two hanging pins 203 can penetrate through two mounting holes at the bottom of the flitch; the four hanging pins 203 are matched for use, so that the plate can be stably hung in the stock bin.

The top and the bottom of the mounting plate of the hanging plate 201 are provided with an upper movable guide rail 204 and a lower movable guide rail 205 which are respectively matched with the upper rail seat 401 and the lower rail seat 301 on one side opposite to the hanging pin 203; when the plate is installed, the side provided with the hanging pins 203 is the front side, and when the plate is installed, the upper movable guide rail 204 and the lower movable guide rail 205 are suspended in the right side of the hanging plate 201 in a calibrated distance, so that the four hanging pins 203 can completely extend out of the frame 1 when the drawing assembly 2 is calibrated, and the plate can be ensured to extend out by a certain distance, so that the plate is not influenced by the frame 1 when being hung on the hanging plate 201; simultaneously, at the right-hand member of link plate 201 mounting panel bottom, be equipped with downwardly extending's fork lever 202, fork lever 202 is used for on the one hand and uses with the cooperation of outside straight line receive and release fork mechanism to provide power for the slip of pull subassembly 2, and on the other hand still makes pull subassembly 2 can not shift out outside frame 1 when outwards sliding.

Further, as shown in fig. 6, when the storage bin is actually used, the storage bin is used in cooperation with external equipment, wherein the storage bin is placed on the storage bin bottom tray, and the storage bin bottom tray is used in cooperation with two slide rails fixed on the ground, so that the storage bin bottom tray can drive the storage bin to linearly and reciprocally slide relative to the ground, and the length of the slide rails is designed according to a field, but at least needs to be more than twice as long as the storage bin, so that the storage bin can be free from the influence of the storage bin bottom tray when being loaded and unloaded; the end of the sliding rail is provided with a frame, the top of the frame is provided with two lifting mechanisms, the claws of the lifting mechanisms can be hung on the hanging beam 104 to realize the ascending and descending of the stock bin, so that the stock bin can be conveniently and rapidly placed on or taken down from the trolley when the stock bin is filled with the material plates.

Further, as shown in fig. 7, when the storage bin is in use, two storage bins can be simultaneously arranged, the two storage bins are an upper storage bin and a lower storage bin respectively, the configuration of the two storage bins is the same, and a material plate suspended from the upper storage bin is an unprocessed material plate and is used for supplying materials to the vacuum coating equipment in real time; the flitch that feed bin hung is the finished product, and the flitch after vacuum coating equipment processing can be stored in feed bin down, and the quantity that feed bin stored the flitch down can satisfy a work flow's work load at least, has realized the function that the flitch unloading was cushioned.

Further, when the storage bin is used, a linear retracting and releasing fork mechanism matched with the drawing components 2 is arranged outside the storage bin, the linear retracting and releasing fork mechanism is arranged at the calibration position of the sliding rail, and when the storage bin is used, each drawing component 2 stops moving to the position of the linear retracting and releasing fork mechanism along with the storage bin; then, the linear retracting and releasing shifting fork mechanism is connected with a shifting fork rod 202 of the drawing component 2 to drive the drawing component 2 to slide outside the frame 1; then, an external mechanical arm clamps the plate to a calibration position; at this time, the four assembling holes of the flitch are simultaneously penetrated by the four hanging pins 203 of the drawing assembly 2; after the flitch is stably hung on the drawing component 2, the linear retracting and releasing shifting fork mechanism drives the drawing component 2 to reset and then is separated from the shifting fork rod 202, and one blanking action of the flitch is finished; along with the removal of feed bin, accomplish the reciprocating sliding of each pull subassembly 2, realize the unloading buffer function of feed bin.

Further, when the above steps are performed reversely, the feeding action of the flitch is performed, and details are not described herein.

The foregoing is merely exemplary and illustrative of the present invention, and various modifications, additions and substitutions of the specific embodiments described herein may be made by those skilled in the art without departing from the scope of the utility model as defined in the accompanying claims.

Claims (7)

1. The utility model provides a feed bin that is used for automatic unloading of going up of vacuum coating equipment which characterized in that includes:

the frame (1) is formed by fixedly connecting a plurality of upright posts (101), a plurality of cross beams (102), a plurality of longitudinal beams (103) and hanging beams (104) to form a cube;

the drawing components (2) are vertically and uniformly distributed in the frame (1), and the drawing components (2) are connected with the frame (1) in a sliding mode through the lower guide rail seat (3) and the upper guide rail seat (4).

2. The storage bin for automatic loading and unloading of vacuum coating equipment according to claim 1, wherein the hanging beam (104) is arranged at the middle position of two longitudinal beams (103) at the top of the frame (1), and two ends of the hanging beam (104) are respectively fixedly connected with two cross beams (102) at the top of the frame (1).

3. The storage bin for automatic loading and unloading of vacuum coating equipment according to claim 1, wherein the cross beam (102) and the longitudinal beam (103) at the bottom of the frame (1) are at the same horizontal height.

4. The storage bin for automatic loading and unloading of vacuum coating equipment according to claim 1, wherein the drawing assembly (2) comprises a hanging plate (201), a shifting fork rod (202), a plurality of hanging pins (203), an upper movable guide rail (204) and a lower movable guide rail (205), and the plurality of hanging pins (203) are fixedly connected to the top and the bottom of the same side of the hanging plate (201) respectively.

5. The storage bin for automatic loading and unloading of vacuum coating equipment according to claim 4, wherein the fork rod (202) is assembled with an external linear retracting fork mechanism, and the upper movable guide rail (204) and the lower movable guide rail (205) are slidably connected with the upper guide rail seat (4) and the lower guide rail seat (3), respectively.

6. The storage bin for automatic loading and unloading of vacuum coating equipment according to claim 1, wherein the lower guide rail seat (3) comprises a lower rail seat (301), a lower fixed guide rail (302) and a lower magnet (303), the upper guide rail seat (4) comprises an upper rail seat (401), an upper fixed guide rail (402) and an upper magnet (403), and the lower rail seat (301) and the upper rail seat (401) are both bent plates.

7. The storage bin for automatic loading and unloading of vacuum coating equipment as claimed in claim 6, wherein the horizontal side of the lower rail seat (301) is fixedly connected to the top surfaces of the two longitudinal beams (103) at the bottom of the frame (1), and the horizontal side of the upper rail seat (401) is fixedly connected to the bottom surfaces of the two longitudinal beams (103) at the top of the frame (1); and one vertical side of the lower rail seat (301) and one vertical side of the upper rail seat (401) are positioned on the same vertical plane.

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