CN217807419U - Transfer frame device and glass transfer system - Google Patents

Abstract

The utility model belongs to the technical field of the glass transfer apparatus, a transport frame device and glass transfer system are related to. Wherein, the transfer frame device is used for transferring the glass between two adjacent processing devices. The conveying roller assembly is started to work, the glass of the outlet platform of the last processing device is transferred to the conveying roller assembly, then the output end of the first power source stretches out and pushes the object placing platform to the bearing surface to be abutted against the bottom wall of the glass, and therefore the bearing surface of the object placing platform supports the glass. When needing to carry the glass of treating processing to next skill device, the output of first power supply contracts in order to drive the supporter and descend to the diapire separation of loading face and glass to make glass pass through the entry platform that transfer roller subassembly transported next processingequipment, accomplish the quick transportation of glass between two adjacent processingequipment, saved the manpower, realize high-efficient production.

Description

Transfer frame device and glass transfer system

Technical Field

The utility model belongs to the technical field of the glass transfer apparatus, especially, relate to a transport frame device and glass transfer system.

Background

In building glass's deep-processing process, specifically in the glass plate body from cutting to edging workshop section, edging to tempering workshop section and cavity workshop section accomplish beat glue the back and store the course of working such as solidification, because of attributes such as the glass plate body size is big and the glass plate body is breakable, the transportation and the storage process of giving cutting to edging, edging to tempering workshop section have brought the loaded down with trivial details work of a lot of difficulties.

Specifically, after the glass is glued in the hollow working section, because the glass is too heavy, each part of the glass is easy to be dislocated, and then a part of the area sinks, so that the glass needs to be transported to a place with a larger level for standing for a period of time after the gluing is finished, and then the next processing procedure can be carried out.

In view of the above problems, the related art contemplates that the transportation and storage problems of the glass product manufacturing enterprises are solved by an automatic transportation line transportation method, but in the prior art, a transportation rack device is generally adopted to transport and store the glass plate. Due to the fragile property of glass, when the glass plate is conveyed to the empty transfer frame device from the equipment outlet of the previous processing process, the glass plate is easily placed out of level or is directly cracked, so that the glass plate still needs to be manually conveyed to the empty transfer frame device from the equipment outlet of the previous processing process, and the glass plate on the transfer frame device is conveyed to the equipment inlet of the next processing process after standing for a period of time. Furthermore, the prior art transfer rack device can only store a small amount of glass at a time.

Therefore, the transfer frame device in the prior art has the problem that the efficiency of glass between processing equipment of two adjacent processing procedures is lower in the transfer process due to the fact that automatic transfer and mass storage cannot be achieved simultaneously.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a transport frame device and glass transfer system, the transport frame device that aims at solving among the prior art exists because can't realize automatic transfer and store in batches simultaneously, and leads to the lower problem of glass of efficiency in the transfer process between two adjacent manufacturing procedure's the processing equipment.

In order to achieve the purpose, the utility model adopts the technical proposal that: a transfer rack device for transferring glass between two adjacent processing devices, the transfer rack device comprising:

a base;

the conveying roller assembly is assembled on the base and provided with a first position and a second position which are arranged at intervals, the first position is in butt joint with the outlet platform of the previous processing device, the second position is in butt joint with the inlet platform of the next processing device, and the conveying roller assembly conveys the glass along the direction from the first position to the second position;

the lifting frame assembly is assembled on the base and combined with the conveying roller assembly, the lifting frame assembly comprises a first power source and at least one object placing platform, the object placing platform is provided with a bearing surface, and the output end of the first power source drives the object placing platform to ascend or descend along the vertical direction;

the control assembly, control assembly and first power supply, conveying roller assembly all electric connection.

As a further limitation of this embodiment, the number of the object placing platforms is plural, and the plural object placing platforms are arranged at intervals along the vertical direction to form the object placing rack;

the storage rack rises to enable the glass conveyed by the conveying roller assembly to be sequentially transferred to the bearing surfaces, and each bearing surface correspondingly bears one piece of glass;

the rack descends to transfer the glass on each bearing surface to the conveying roller assembly in sequence.

As a further limitation of this embodiment, the platforms are disposed parallel to each other, and the planes of the platforms and the conveyor roller assembly are parallel to each other.

As the further limited of this embodiment, transport frame device still contains the direction subassembly, and the direction subassembly is installed on the base, and the direction subassembly is used for leading each platform when moving along vertical direction.

As the further limited of this embodiment, the guiding assembly includes the third power source, and the transport frame device still includes the bracing piece, and the casing of third power source is equipped with the guide way, and guide way and bracing piece are established each other in the cover.

As a further limitation of this embodiment, the guiding assembly further comprises a self-locking member for limiting the object holder when the output end of the first power source stops moving.

As a further limitation of this embodiment, the transfer roller assembly includes a plurality of transfer roller modules, each transfer roller module includes a second power source, a transfer roller and a connecting rod, one end of the connecting rod is in driving connection with the output end of the second power source, the other end of the connecting rod is connected with the transfer roller, and the connecting rod of each transfer roller module is arranged in an array along the direction from the first position to the second position.

As a further limitation of this embodiment, each connecting rod is correspondingly provided with at least one conveying roller;

or, each connecting rod corresponds and sets up a plurality of transfer rollers, and the transfer roller sets up along the extending direction interval that corresponds the connecting rod.

As a further limitation of this embodiment, the transfer rack device further includes a moving assembly, the moving assembly includes a plurality of roller modules, and the plurality of roller modules are mounted on the base at intervals;

or the transfer frame device also comprises a moving assembly, the moving assembly comprises a roller module and a rail which are mutually matched, the roller module is arranged on the base, and the rail is arranged on the working ground where the base is located.

According to the utility model discloses an on the other hand, a glass transfer system is proposed, glass transfer system contains the transfer frame device among the above-mentioned technical scheme.

The utility model discloses following beneficial effect has at least:

the utility model discloses a transfer frame device contains base, conveying roller subassembly, lifter subassembly and control assembly, and lifter subassembly and conveying roller subassembly are complex to be assembled on the base, and the lifter subassembly contains first power supply and at least one platform, and the output of first power supply pushes away platform along vertical direction. In the use process, the first position of the conveying roller assembly is in butt joint with the outlet platform of the last processing device, then the conveying roller assembly is started to work, the glass of the outlet platform of the last processing device is conveyed to the conveying roller assembly until the glass is conveyed to the second position by the conveying roller assembly, then the output end of the first power source extends out and pushes the storage platform to abut against the bottom wall of the bearing surface and the bottom wall of the glass, and therefore the bearing surface of the storage platform supports the glass. When needing to carry the glass of treating processing to next technician's device, the second position of conveying roller subassembly and next processingequipment's entry platform dock, the output shrink of first power supply descends to the diapire separation of loading end and glass in order to drive thing platform to make glass pass through conveying roller subassembly and transfer to next processingequipment's entry platform, accomplishes the quick transportation of glass between two adjacent processingequipment, has saved the manpower, realizes high-efficient production.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required for the embodiments or the prior art descriptions will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without inventive labor.

FIG. 1 is an assembled perspective view of a conveyor roller assembly and base and moving assembly according to a first embodiment of the present invention;

FIG. 2 is an enlarged detail view of A in FIG. 1;

fig. 3 is a three-dimensional structure diagram of the crane assembly of the utility model;

fig. 4 is a three-dimensional structure diagram of the guiding component of the present invention;

fig. 5 is a general assembly three-dimensional structure view of one of the cases of the transfer rack device according to the first embodiment of the present invention;

fig. 6 is a perspective view of a general assembly of a transfer frame device according to a second embodiment of the present invention;

FIG. 7 is an enlarged detail view of B in FIG. 6;

fig. 8 is a perspective view of the moving assembly of fig. 6.

Wherein, in the figures, the respective reference numerals:

1. a conveyor roller assembly; 11. a first position; 12. a second position; 13. a transfer roller module; 130. a second power source; 131. a conveying roller; 1311. a buffer layer; 132. a connecting rod; 2. a lift cage assembly; 20. a rack; 201. a placement platform; 2011. a bearing surface; 2012. a surrounding wall; 2013. a cross beam; 22. a first power source; 3. a roller module; 31. a track; 311. a transmission assembly; 32. a fourth power source; 322. a drive shaft; 4. a base; 41. a support bar; 21. a guide assembly; 210. a self-locking member; 2100. an output end; 211. A guide groove; 212. a third power source.

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 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 drawings are exemplary and intended to be used for explaining the present invention, and should not be construed as limiting the present invention.

In the description of the present invention, it is to be understood that the terms "length", "width", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are merely for convenience of description and simplicity of description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be construed as limiting the present invention.

Furthermore, the terms "first", "second", etc. are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first," "second," etc. may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically limited otherwise.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," and "fixed" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

Interpretation definitions: in the present application, the direction from the first position 11 to the second position 12 is defined as the direction indicated by the linear arrow direction X, as shown in fig. 5 and 6. Accordingly, when the rotation direction of the conveying roller 131 is clockwise at this time, the glass is conveyed in the direction X.

As shown in fig. 1, 2 and 5, the transfer rack device of the present application is used for transferring glass between two adjacent processing devices, and by using the device, the glass at the outlet platform (not shown) of the previous processing device (not shown) can be rapidly transferred to the transfer rack device for mass storage, and then the glass on the transfer rack device is transferred to the inlet platform (not shown) of the next processing device (not shown), so as to realize efficient transfer and efficient production.

Wherein, please refer to fig. 1, the utility model discloses a transfer frame device contains base 4, transfer roller subassembly 1, crane subassembly 2 and control assembly, and crane subassembly 2 and the compound assembly of transfer roller subassembly 1 are on base 4, and crane subassembly 2 contains first power supply 22 and a plurality of platform 201, and a plurality of platform 201 form supporter 20 along vertical direction interval arrangement, and the output of first power supply 22 comes and goes along vertical direction and pushes away supporter 20.

In the use, the first position 11 of conveying roller subassembly 1 and the butt joint of last processingequipment's export platform, then, conveying roller subassembly 1 opens work, transports the glass of last processingequipment's export platform to conveying roller subassembly 1 on, then the output of first power supply 22 stretches out and pushes up supporter 20 to the diapire butt of loading end and glass to make the loading end of each thing platform 201 support a glass in proper order. Circulating in this way, when the article placing rack 20 is fully loaded, the second position 12 of the conveying roller assembly 1 is in butt joint with the inlet platform of the next processing device, the output end of the first power source 22 contracts and pushes the article placing rack 20 to separate from the bottom wall of the glass, so that the glass of each article placing platform 201 is sequentially transferred to the inlet platform of the next processing device through the conveying roller assembly 1, the rapid transfer and mass storage of the glass between two adjacent processing devices are completed, and the problems that the glass between processing equipment of two adjacent processing procedures is easy to deform and the production efficiency is low in the transfer process due to the fact that the automatic transfer and mass storage cannot be simultaneously realized in the transfer rack device in the prior art are solved.

A first embodiment of the present application will now be explained in detail.

The conveyor roll assembly 1 comprises a plurality of conveyor roll modules 13. The transfer roller assembly 1 has a first position 11 and a second position 12 spaced apart, the first position 11 for interfacing with the exit platform of a previous processing device and the second position 12 for interfacing with the entry platform of a next processing device. The plurality of transfer roller modules 13 are arranged at intervals in the direction from the first position 11 to the second position 12.

It is to be understood that the present application is explained with the directions of the first position 11 and the second position 12 being straight directions.

Wherein, the conveying roller module 13 includes a second power source 130 and a conveying roller 131, the conveying roller 131 and the second power source 130 are arranged in a one-to-one correspondence manner, and the conveying roller 131 is connected with the output end of the corresponding second power source 130 in a driving manner.

In use, the first station 11 is docked with an exit platform (not shown) of a previous processing device so that glass exiting the exit platform is transferred to the first station 11. Specifically, the end of the glass that first exits the exit platform enters the transfer rack assembly from the first location 11.

Meanwhile, referring to fig. 1, each second power source 130 of the transfer rack device of the present application drives the corresponding transfer roller 131 to rotate, and after the glass contacts with the transfer roller 131 (specifically, the transfer roller 131 supports the glass, that is, the bottom wall of the glass covers the transfer roller 131), each transfer roller 131 generates a force towards the second position 12 to the glass during the rotation process, so that one end of the glass (that is, the end coming out from the outlet platform of the previous processing device at first) is transferred from the first position 11 to the second position 12 until the whole glass is transferred onto the transfer rack device.

The glass is then transferred from the second location 12 to the entry platform (not shown) of the next processing device, i.e. the transfer of the glass from the transfer rack device to the next processing device is achieved.

When two processingequipment intervals are far away, realize the quick and automatic transportation of glass between two adjacent manufacturing procedure's the processing equipment, saved the manpower, realize falling this.

Of course, whole transfer process is controlled by control assembly (not shown), and control assembly can accurately detect the position information that glass transported second position 12, and secondly control assembly control transfer roller module 13 stops the transmission to place this glass steadily on transporting the frame device, specifically on each transfer roller 131, realize big glass of batch and transport fast, saved a large amount of manpowers and handling time. Specifically, the control component may adopt a contact sensor or a photoelectric sensor, and the contact sensor or the photoelectric sensor is a control device with a wide application range, and therefore, the detailed description is omitted.

With continued reference to fig. 1, 2 and 5, the conveying roller 131 rotates clockwise.

In one embodiment, the conveyor roller module 13 further comprises a connecting rod 132, and the connecting rod 132 and the second power source 130 are disposed in a one-to-one correspondence.

Preferably, one conveyor roller module 13 contains at least one second power source 130 and one conveyor roller 131. The output of the second power source 130 and the corresponding conveying roller 131 are connected to a connecting rod 132. That is, the output end of the second power source 130 is connected to one end of the connecting rod 132, the other end of the connecting rod 132 is provided with the conveying roller 131, and the connecting rod 132 drives the corresponding conveying roller 131 to rotate synchronously.

It can be understood that when the direction from the first position 11 to the second position 12 is a straight line, the conveying rollers 131 on each conveying roller module 13 are arranged in parallel with each other, so that each conveying roller module 13 is arranged in a linear array along the direction from the first position 11 to the second position 12. And, in order to prevent the glass from being deformed due to uneven stress during the transfer, a predetermined interval is provided between the adjacent two transfer rollers 131, that is, a predetermined interval is provided between the adjacent two connecting bars 132.

In an embodiment, referring to fig. 1, 2 and 5, a plurality of conveying rollers 131 may be disposed on each connecting rod 132, and the plurality of conveying rollers 131 of each connecting rod 132 are disposed at intervals along the extending direction of the connecting rod 132. A support rod 41 is disposed on the base 4 in the following technical solution, and optionally, each second power source 130 is mounted on the base 4 through the support rod 41.

In another embodiment, each connecting rod 132 may be provided with a corresponding conveying roller 131. Specifically, the transfer rollers 131 have a certain axial length, and the transfer rollers 131 are disposed to extend in the extending direction of the corresponding connecting rods 132. And the axial length of the conveying rollers 131 is at least adapted to the width dimension of the glass to be produced. Specifically, the axial length of the conveying roller 131 and the width dimension of the produced glass are substantially equal; or the axial length of the conveying roller 131 is slightly smaller than the width of the produced glass, and the conveying roller 131 can stably support the glass only by ensuring that the glass can be stably supported, so that the glass is not particularly limited.

In the present embodiment, with continued reference to fig. 2, each of the conveying rollers 131 is provided with a buffer layer 1311, the buffer layer 1311 is disposed around the circumferential side wall of the conveying roller 131, and the buffer layer 1311 is in contact with the surface of the glass during the transferring process.

Preferably, the buffer layer 1311 is an elastic member such as silicone rubber, which can effectively reduce scratching on the glass surface and reduce the problem of glass breaking due to impact during transportation.

In order to prevent the glass from tilting and slipping, the plurality of connecting rods 132 are located at the same height with respect to the work floor, and the sizes of the respective conveying rollers 131 are uniform.

In order to prevent the glass from shifting in the first direction X when moving on each of the transfer rollers 131, a bearing (not shown) or the like is provided at a connection position of each of the transfer rollers 131 and the corresponding connection rod 132 to enhance stability during rotation of each of the transfer rollers 131 to prevent the shift in the rotation direction of the transfer rollers 131.

When the device is used in the operation process of producing large-plate glass products in a hollow working section, after glue injection of a hollow wire, due to the fact that the weight of glass is too large, dislocation of all parts of the glass is easily caused, and then a part of the area sinks, so that the glass is directly conveyed to the device after glue injection is completed, then the glass is transferred to a packaging area for solidification, and after solidification, next boxing operation is completed. The curing time is usually more than twelve hours, and the device can obviously improve the site tidiness and safety and improve the product quality.

In the present embodiment, referring to fig. 3 and 5, the transfer rack device includes a lifting rack assembly 2. The lifting frame assembly 2 and the conveying roller assembly 1 are assembled and molded in a composite mode.

Specifically, with continued reference to fig. 3, the lift truck assembly 2 includes a rack 20 and a first power source 22.

Referring to fig. 5, fig. 5 is a general assembly three-dimensional structure diagram of a transfer rack device according to a first embodiment of the present invention, wherein the storage rack 20 includes a storage platform 201, as shown in fig. 5.

Of course, in order to improve the transportation efficiency and storage capacity, the rack 20 may also include a plurality of platforms 201, as shown in fig. 3.

Specifically, with reference to fig. 3, each of the platforms 201 includes a wall 2012 and a beam 2013, and the beams 2013 are disposed on the wall 2012 in parallel and spaced apart to form the hollow-out platform 201. Platform 201 has a bearing surface 2011, which is known to be the combination of the top surface of enclosure wall 2012 and the top surfaces of beams 2013.

Specifically, a plurality of storage platforms 201 are spaced apart in a vertical direction (it can be understood that the transfer rack device of the present application is generally installed on the floor or horizontal work table of a production plant) to form the storage rack 20.

Specifically, the compound assembly molding of the crane assembly 2 and the transfer roller assembly 1 can be understood as follows: one or more transfer roller modules 13 are disposed between two adjacent crossbeams 2013 of each storage platform 201. And, interval and evenly set up between two adjacent transfer roller modules 13, evenly arrange between two adjacent thing platform 201 (evenly arrange between two adjacent crossbeams 2013 promptly), all stagger the design each other between the leg 2012 of each thing platform 201 and each transfer roller module 13 to prevent that thing platform 201 (being crossbeam 2013 and leg 2012) from producing interference with transfer roller module 13 in the in-process that goes up and down.

It will be appreciated that the distance between the first position 11 and the second position 12 is substantially equal to the length or width of the glass being produced, and that the area of the placement platform 201 is slightly larger than or substantially equal to the footprint of the glass being produced.

Wherein, the output end of the first power source 22 is connected with the shelf 20 in a driving manner, and the output end of the first power source 22 pushes the bottom of the shelf 20 and drives the shelf 20 to move along the vertical direction, i.e. drives the shelf 20 to ascend or descend. Specifically, first power supply 22 drives supporter 20 along vertical direction rebound to make the roof of a plurality of platform 201, the diapire of glass on bearing 2011 and the transfer roller 131 mutually supports promptly, and the glass conveying and the storage process of this platform 201 are accomplished to the diapire that bears in glass completely. That is, when the rack 20 is raised, the glass on the conveying roller assembly 1 is sequentially transferred to the bearing surfaces 2011, and each bearing surface 2011 correspondingly bears one piece of glass.

In other embodiments, the rack device can also be installed on the ceiling of the production workshop, and the output end of the first power source 22 pushes the bottom of the rack 20 and drives the rack 20 to move in the vertical direction. Specifically, the first power source 22 drives the article placing shelf 20 to move downward along the vertical direction, so that the top walls of the article placing platforms 201, i.e., the bearing surface 2011 and the bottom walls of the glass on the conveying rollers 131 are abutted against each other, which is not shown temporarily.

Specifically, in this embodiment, the first position 11 and the second position 12 are each provided with a sensing switch, such as a contact switch (not shown), when the glass is transferred from the exit platform of the previous processing device to the first position 11, the corresponding sensing switch sends a triggering signal of the glass to the control assembly, and the control assembly controls the start-up operation of the transfer roller assembly 1.

When the glass is conveyed to the conveying roller module 13 and the whole glass is placed on the conveying roller module 13 (i.e. when the end of the glass coming out from the outlet platform first reaches the second position 12, the whole glass is on the conveying roller module 13 at this time), the corresponding inductive switch sends a trigger signal of the glass to the control assembly, and the control assembly controls the conveying roller assembly 1 to stop working.

Subsequently, the control component controls the crane component 2 to start, i.e. the output end of the first power source 22 pushes against the bottom of the rack 20, so that the bearing surface 2011 of the platform 201 and the bottom wall of the outlet platform are flush with each other. Preferably, the flatness requirement of the bearing surface 2011 is high in order to prevent the glass from deforming.

Of course, at this time, the top plane of the object placing platform 201 just contacts with the bottom surface of the corresponding glass, and the top plane of the object placing platform 201, i.e. the bearing surface 2011 is just tangential to each of the conveying rollers 131. It can be known that, at this moment, after storage platform 201 continued to rise a distance, the main effort that bears glass was changed for corresponding storage platform 201 by each transfer roller 131, is about to glass be conveyed on storage platform 201 to realize the transportation task of single glass.

It can be known that, in the present application, the article shelf 20 is located at a position right below the conveying roller module 13 in an unloaded state (i.e. when the article platform 201 does not carry glass yet).

Preferably, first power supply 22 drives supporter 20 and moves along vertical direction so that each storage platform 201's bearing surface 2011 in proper order with the mutual butt of the glass of transfer roller module 13, also make each storage platform 201 in proper order the glass of a piece of transfer roller module 13 conveying. First, the uppermost storage platform 201 is pushed to a position flush with the bottom wall of the outlet platform, and then the bottom wall of the glass is completely separated from the conveying roller module 13 with the continuous pushing of the output end of the first power source 22, so that the glass is completely loaded on the top plane of the storage platform 201, i.e. the bearing surface 2011.

Then, the control component continues to control the lifting frame component 2, so that a predetermined distance is pulled away between the previous object placing platform 201 and the next adjacent object placing platform 201, and the next object placing platform 201 can bear glass conveniently.

Finally, the control module initiates a second transfer mode, repeats the previous transfer process, and so on, the plurality of platforms 201 sequentially support a piece of glass from top to bottom. The transfer frame device and the last working platform work synchronously, so that automatic glass conveying is realized, glass can be transferred quickly during production, the storage process of the glass is completed synchronously, the problem that the field of a production workshop is scarce in actual production can be solved, manpower is completely liberated, and the defects of large demand and low working efficiency of labor resource allocation are overcome.

When the shelf 20 is transferred to a fully loaded state, it can be used to be stored in a warehouse or a packaging area for a short time, so as to facilitate the next processing procedure of the glass. When the glass of the rack 20 reaches the condition for the next processing procedure, the control component controls the crane component 2 to start, that is, the output end of the first power source 22 contracts, so that the bearing surface 2011 of one of the object placing platforms 201 and the top wall of the inlet platform of the next processing device are flush with each other. Meanwhile, the conveying roller assembly 1 is started to work, and the conveying roller module 13 drives the glass of the corresponding object placing platform 201 to move towards the direction of the inlet platform. Analogize from this, the output of first power supply 22 contracts for each platform 201 descends to the position of the mutual parallel and level of roof of corresponding loading face 2011 and entry platform in proper order, accomplishes the process that glass transported the entry platform of next processingequipment from each platform 201.

This transfer principle is in accordance with the above-described principle of glass transfer from the exit platform to the transfer rack device and will not be explained in detail.

Preferably, each of the platforms 201 is parallel to each other, and the planes of the platforms 201 and the conveying roller assembly 1 are parallel to each other, specifically, the planes of the bearing surfaces 2011 of the platforms 201 and the side walls of the conveying rollers 131 contacting the glass when rotating are parallel to each other. That is, when glass is transferred onto the conveying roller assembly 1, the transfer rack device can quickly transfer and store glass onto the carrying surface 2011 without adjusting the angle in the horizontal direction.

In this embodiment, referring to fig. 3, the transporting rack device further includes a guiding assembly 21, the guiding assembly 21 is installed on the base 4, and the guiding assembly 21 is used for guiding each of the platforms 201 when moving along the vertical direction, so as to maintain the stability of the platforms 201, prevent the glass on the platforms 201 from tilting and shaking, and reduce the damage of the glass during transportation.

Specifically, referring to fig. 4, the guiding assembly 21 includes a third power source 212, an extending end of the third power source 212 is mounted on the base 4, a guiding groove 211 is formed on an outer wall of a housing of the third power source 212, and a plurality of supporting rods 41 are mounted on the base 4 at intervals. The supporting rod 41 and the guiding groove 211 are sleeved with each other, and when the first power source 22 moves, one end of the housing of the third power source 212 moves synchronously to drive the guiding groove 211 to move along the extending direction of the supporting rod 41, which can be known as the extending direction of the supporting rod 41 is the direction in which the object shelf 20 moves back and forth in the present embodiment.

In one embodiment, the guiding assembly 21 further comprises a self-locking element 210, in this embodiment, the self-locking element 210 is a cylinder, and when the first power source 22 receives the signal of stopping working, the output end 2100 of the cylinder extends to abut against the middle of two adjacent platforms 201 for locking the shelf 20 and enhancing the stability of the platforms 201.

Optionally, the output end of the self-locking element 210 may abut against any of the cross-members 2013 of the platform 201.

In this embodiment, the transportation frame device further includes a sensing switch, such as a contact switch (not shown). Specifically, the inductive switch is in the second position 12 and the glass transfer is automatically stopped when the inductive switch detects that one end of the glass is close to the second position 12. In the production process, a plurality of operators can be reduced, and the steps of manual carrying, lower frame transfer, forklift transfer and the like in the glass processing process are reduced. And the space of the site can be saved, the defects and defective products generated in the process of lifting the glass by manual operation are effectively reduced, and the potential safety hazards of personnel and equipment are reduced.

In this embodiment, referring to fig. 1, fig. 2 and fig. 5, the transfer frame device further includes a moving assembly, the moving assembly includes a plurality of roller modules 3, and the roller modules 3 and the conveying roller assembly 1 are respectively installed on two opposite sides of the base 4.

It will be appreciated that the roller modules 3 are mounted on the ground facing side of the base 4 for moving the entire transfer rack assembly. The lifting frame component 2 is arranged on one side of the base 4 where the conveying roller component 1 is arranged.

Preferably, the plurality of roller modules 3 are spaced and evenly arranged.

Specifically, after the storage platform 201 is filled with glass, the roller module 3 is manually driven by a person, and the whole transfer frame device is transferred to a processing area of a next process, specifically, an inlet platform of a processing device of the next process.

A second embodiment of the present application will now be explained in detail.

In one embodiment, referring to fig. 6 to 8, the transfer frame device further includes a moving assembly, the moving assembly includes a roller module 3 and a rail 31, the roller module 3 and the conveyor roller assembly 1 are respectively mounted on two opposite sides of the base 4. It will be appreciated that the roller modules 3 are mounted on the side of the base 4 facing the ground for moving the entire transfer rack arrangement. The lifting frame assembly 2 is arranged on one side of the base 4 where the conveying roller assembly 1 is arranged.

Wherein the rails 31 are installed on the working floor where the transfer rack device is located. Preferably, the number of the tracks 31 is two or more, and of course, the number of the tracks 31 may be one. The rails 31 are installed side by side on a work floor on which the transfer rack device is installed. The transporting frame device is fixed above the two ground rails 31, after the storage platform 201 is filled with glass, a person starts a power supply, and the driving roller module 3 can move along the extending direction of the rails 31.

Specifically, the moving assembly further comprises a fourth power source 32, the fourth power source 32 is connected with a transmission shaft 322, and the transmission shaft 322 connects two or more roller modules 3 side by side together, so as to realize that the two or more roller modules 3 side by side move on the track 31 synchronously.

Optionally, the moving assembly further includes a transmission assembly 311, and the transmission assembly 311 may be a transmission assembly with a speed reducing effect, or may be a chain directly.

Preferably, the two ends of the rail 31 are connected to the processing devices of the two processes. Specifically, one end of the rail 31 is connected to an outlet stage of the processing device of the previous process, and the other end of the rail 31 is connected to an inlet stage of the processing device of the next process. When the whole transfer rack device filled with glass reaches the position corresponding to the inlet platform of the processing device in the next process, the transfer rack device triggers a positioning switch (not shown) installed at one end of the rail 31 to drive the roller module 3 to stop running, so that the transfer and butt joint work is completed.

The control assembly starts a second conveying frame device conveying mode, the last conveying process is repeated, the circulation operation is performed so that the conveying frame device can move between the two processing devices, the glass can be conveyed quickly and automatically, manpower is liberated, and the production efficiency is improved.

Compared with the first embodiment, the second embodiment has the same structure except that the above structure is different, and the description thereof is omitted.

According to another aspect of the present application, a glass transfer system is provided that includes a transfer rack apparatus provided in one of the two embodiments described above. In the process of producing and processing glass, the glass is quickly and automatically transferred between two adjacent processing devices, so that the labor is saved, and the cost is reduced.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not intended to limit the present invention, and any modifications, equivalents, improvements, etc. made within the spirit and principles of the present invention should be included within the scope of the present invention.

Claims (10)

1. A transfer rack device for transferring glass between two adjacent processing devices, the transfer rack device comprising:

a base (4);

the glass conveying device comprises a conveying roller assembly (1), wherein the conveying roller assembly (1) is assembled on the base (4), the conveying roller assembly (1) is provided with a first position (11) and a second position (12) which are arranged at intervals, the first position (11) is in butt joint with an outlet platform of the last processing device, the second position (12) is in butt joint with an inlet platform of the next processing device, and the conveying roller assembly (1) conveys glass along the direction from the first position to the second position;

the lifting frame assembly (2) is assembled on the base (4) and compounded with the conveying roller assembly (1), the lifting frame assembly (2) comprises a first power source (22) and at least one object placing platform (201), the object placing platform (201) is provided with a bearing surface (2011), and the output end of the first power source (22) drives the object placing platform (201) to ascend or descend along the vertical direction;

the control assembly is electrically connected with the first power source (22) and the conveying roller assembly (1).

2. The rack arrangement according to claim 1, wherein the plurality of platforms (201) is provided in plurality, the plurality of platforms (201) being spaced apart in a vertical direction to form a rack (20);

the storage rack (20) ascends to enable the glass conveyed by the conveying roller assembly (1) to be sequentially conveyed to the bearing surfaces (2011), and each bearing surface (2011) correspondingly bears one piece of glass;

the commodity shelf (20) descends to enable the glass of each bearing surface (2011) to be sequentially transferred to the conveying roller assembly (1).

3. The transfer rack device according to claim 2, wherein the object platforms (201) are arranged in parallel with each other, and the planes of the object platforms (201) and the conveying roller assembly (1) are parallel with each other.

4. The rack arrangement according to claim 2 or 3, characterized in that the rack arrangement further comprises a guiding assembly (21), the guiding assembly (21) being mounted on the base (4), the guiding assembly (21) being adapted to guide each of the platforms (201) when moving in a vertical direction.

5. The rack device according to claim 4, characterized in that the guiding assembly (21) comprises a third power source (212), the rack device further comprises a supporting rod (41), the housing of the third power source (212) is provided with a guiding groove (211), and the guiding groove (211) and the supporting rod (41) are sleeved with each other.

6. The rack apparatus according to claim 5, wherein the guide assembly 21 further comprises a self-locking member (210), the self-locking member (210) being used for limiting the rack (20) when the output end of the first power source (22) stops moving.

7. The transfer rack apparatus according to claim 1, wherein the transfer roller assembly (1) comprises a plurality of transfer roller modules (13), each of the transfer roller modules (13) comprises a second power source (130), a transfer roller (131) and a connecting rod (132), one end of the connecting rod (132) is drivingly connected with an output end of the second power source (130), the other end of the connecting rod (132) is connected with the transfer roller (131), and the connecting rods (132) of each of the transfer roller modules (13) are arranged in an array along a direction from the first position (11) to the second position (12).

8. The rack device of claim 7,

each connecting rod (132) is correspondingly provided with at least one conveying roller (131);

or, each connecting rod (132) corresponds and sets up a plurality ofly transfer roller (131), transfer roller (131) are along corresponding the extending direction interval setting of connecting rod (132).

9. The transfer rack apparatus of claim 8,

the transfer rack device also comprises a moving assembly, the moving assembly comprises a plurality of roller modules (3), and the plurality of roller modules (3) are arranged on the base (4) at intervals;

or, the transfer rack device further comprises a moving assembly, the moving assembly comprises mutually matched roller modules (3) and rails (31), the roller modules (3) are installed on the base (4), and the rails (31) are installed on the working ground where the base (4) is located.

10. A glass transfer system comprising the transfer rack device of any one of claims 1-9.

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