CN211261635U - Storage formula glass drying device - Google Patents

Abstract

The utility model discloses a storage formula glass drying device, include: an input lifting plate glass drying device and an output lifting plate glass drying device which are arranged in sequence in the horizontal direction; input lift sheet glass drying device and output lift sheet glass drying device all include: the device comprises a lifting driving part and a plate glass support, wherein an input receiving and conveying device is arranged at the lower part of an input lifting plate glass drying device, an output receiving and conveying device is arranged at the lower part of an output lifting plate glass drying device, a movable input conveying device is arranged at the upper part of the input lifting plate glass drying device, and a movable output conveying device is arranged at the upper part of the output lifting plate glass drying device. Further comprising: the device comprises a heat-insulating layer of the lifting plate glass drying device, a circulating air system of the lifting plate glass drying device and an electric heating assembly of the lifting plate glass drying device. The utility model discloses can transport sheet glass high-efficiently and realize the stoving function.

Description

Storage formula glass drying device

Technical Field

The utility model relates to a technical field of plate glass deep-processing especially relates to a storage formula glass drying device.

Background

The plate glass deep processing glass is a glass product with specific functions, which is prepared by using plate glass formed in one step as a raw material and adopting different processing technologies according to specific use requirements.

Due to the wide application of the flat glass, enterprises for further processing the glass are more and more. In the process of deep processing of the plate glass, the drying process of the plate glass is very important, the plate glass is easy to damage due to overhigh temperature, the production efficiency is low due to overlow temperature, and the production equipment needs to be longer.

The prior plate glass drying device has the following defects:

1) the existing plate glass drying device adopts a straight-through type drying mode, and because the glass needs longer drying process time, the drying efficiency is lower at the same drying temperature.

2) The full automation of the production line of the deep processing of the plate glass is a trend. The straight-through type drying equipment occupies a large factory area, and in the processing process of partial production technology without drying technological processes, the production has to be conducted through the straight-through type drying equipment, so that the production consumes longer time and more electric energy, and the processing quality of the plate glass can be influenced.

How to design an efficient plate glass drying device is a problem to be solved by the technical personnel in the field.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model aims at providing a storage formula glass drying device.

The utility model adopts the technical scheme as follows:

a storage type glass drying device, wherein, includes: an input lifting plate glass drying device and an output lifting plate glass drying device which are sequentially arranged along the horizontal direction;

input lift sheet glass drying device with output lift sheet glass drying device all includes: the lifting driving part is provided with the plate glass supporting piece, and the lifting driving part can drive the plate glass supporting piece to move along the vertical direction;

an input receiving and conveying device is arranged at the lower part of the input lifting plate glass drying device, and the plate glass supporting piece on the input lifting plate glass drying device can penetrate through the input receiving and conveying device in the process of moving along the vertical direction;

an output carrying and conveying device is arranged at the lower part of the output lifting plate glass drying device, and the plate glass supporting piece on the output lifting plate glass drying device can penetrate through the output carrying and conveying device in the process of moving along the vertical direction;

the plate glass output port of the input receiving and conveying device is opposite to the plate glass input port of the output receiving and conveying device;

the upper part of the input lifting plate glass drying device is provided with a movable input conveying device which can move between a movable input working position and a movable input non-working position, the movable input working position is positioned inside the input lifting plate glass drying device, and the movable input non-working position is positioned outside the input lifting plate glass drying device;

the upper part of the output lifting plate glass drying device is provided with a movable output conveying device which can move between a movable output working position and a movable output non-working position, the movable output working position is positioned inside the output lifting plate glass drying device, and the movable output non-working position is positioned outside the input lifting plate glass drying device;

when the movable input conveying device is positioned at the movable input working position and the movable output conveying device is positioned at the movable output working position, the plate glass output port of the movable input conveying device is opposite to the plate glass input port of the movable output conveying device;

further comprising: the heat insulation layer of the lifting plate glass drying device, the circulating air system of the lifting plate glass drying device and the electric heating assembly of the lifting plate glass drying device are arranged on the lifting plate glass drying device;

preferably, the heat-insulating layer of the lifting plate glass drying device is positioned at the periphery of the input lifting plate glass drying device.

The lift sheet glass drying device circulated air system includes: the top circulating air system of the lifting plate glass drying device, the bottom circulating air system of the input lifting plate glass drying device and the bottom circulating air system of the output lifting plate glass drying device;

preferably, the top circulating air system of the lifting plate glass drying device, the bottom circulating air system of the input lifting plate glass drying device and the bottom circulating air system of the output lifting plate glass drying device are all arranged inside the heat insulation layer of the lifting plate glass drying device.

The electric heating component of the lifting plate glass drying device comprises: the device comprises an input lifting plate glass drying device top electric heating assembly, an input lifting plate glass drying device bottom electric heating assembly, an output lifting plate glass drying device top electric heating assembly, an output lifting plate glass drying device bottom electric heating assembly and an upper middle conveying device top electric heating assembly.

In the above storage type glass drying device, each of the lifting driving parts comprises at least two vertical conveying assemblies sequentially arranged along the horizontal direction;

each of the vertical transfer assemblies includes: the conveying chain is provided with at least two chain wheels, and the chain wheels drive the conveying chain to rotate; a plurality of supporting rods arranged at equal intervals are sequentially arranged on the conveying chain, and the central axis of each supporting rod is parallel to the horizontal plane;

preferably, the support rods are in a rectangular array, and the support rods on the same plane form the flat glass support.

The above-mentioned storage type glass drying device, wherein, the input receiving conveyer and the output receiving conveyer both include: a plurality of accepting conveyor drives that set gradually along the horizontal direction, each said accepting conveyor drive all includes: the bearing part rotating shaft and the bearing part rotating wheels are fixedly arranged on the bearing part rotating shaft, the bearing part rotating shaft can rotate around the axial direction of the bearing part rotating shaft, and each bearing part rotating wheel and the bearing part rotating shaft are coaxially arranged.

The above-mentioned storage type glass drying apparatus, wherein the movable input conveyor and the movable output conveyor each comprise: a plurality of movable transmission assemblies sequentially arranged along the horizontal direction; each movable transmission assembly comprises two movable rotating shafts which are opposite and coaxially arranged, a plurality of movable part wheels are fixedly arranged on each movable rotating shaft, and each movable part wheel is coaxially arranged with the movable rotating shaft;

one end, far away from the input lifting flat glass drying device, of each movable rotating shaft is connected with a movable part driving mechanism, each movable part driving mechanism comprises a rotating power piece, each rotating power piece is connected with the corresponding movable rotating shaft, and each rotating power piece drives the corresponding movable rotating shaft to rotate around the axial direction of the corresponding movable rotating shaft; the rotating power part is connected with the horizontal power part, and the horizontal power part drives the rotating power part to move along the axial direction of the movable rotating shaft in the horizontal direction.

Above-mentioned storage formula glass drying device, wherein, movable part actuating mechanism still includes: the vertical power part is connected with the horizontal power part, and the vertical power part drives the horizontal power part to move along the vertical direction.

Above-mentioned storage formula glass drying device wherein, still includes: an upper intermediate conveyor and a lower aisle conveyor, both of which are located between the input and output lift flat glass drying devices, the upper intermediate conveyor being located above the lower aisle conveyor;

when the movable input conveying device is positioned at the movable input working position and the movable output conveying device is positioned at the movable output working position, the plate glass input port of the upper middle conveying device is opposite to the plate glass output port of the movable input conveying device, and the plate glass output port of the upper middle conveying device is opposite to the plate glass input port of the movable output conveying device;

the plate glass input port of the lower channel conveying device is opposite to the plate glass output port of the input receiving conveying device, and the plate glass output port of the lower channel conveying device is opposite to the plate glass input port of the output receiving conveying device.

In the above storage type glass drying device, the lower channel conveying device comprises two plate glass conveying structures arranged at intervals.

The storage type glass drying device further comprises a horizontal input mechanism and a horizontal output mechanism, wherein a plate glass output port of the horizontal input mechanism is opposite to a plate glass input port of the input bearing conveying device, and a plate glass input port of the horizontal output mechanism is opposite to a plate glass input port of the output bearing conveying device.

The storage type glass drying device further comprises a controller, wherein the controller respectively controls the lifting driving part of the input lifting plate glass drying device, the lifting driving part of the output lifting plate glass drying device, the input carrying and conveying device, the output carrying and conveying device, the movable input conveying device and the movable output conveying device.

A method of using a storage glass drying apparatus, wherein the method is suitable for use in any one of the above storage glass drying apparatuses, the method comprising:

step A1: the top electric heating component of the input lifting plate glass drying device is started, and the bottom electric heating component of the input lifting plate glass drying device is started; starting an electric heating assembly at the top of the output lifting plate glass drying device and starting an electric heating assembly at the bottom of the output lifting plate glass drying device; starting an electric heating assembly at the top of the upper middle conveying device;

step A2: the top circulating air system of the input lifting plate glass drying device is started, the bottom circulating air system of the input lifting plate glass drying device is started, the top circulating air system of the output lifting plate glass drying device is started, and the bottom circulating air system of the output lifting plate glass drying device is started;

step A3: when the lifting driving part of the input lifting plate glass drying device drives the plate glass supporting piece of the input lifting plate glass drying device to drive the plate glass to move upwards to the height corresponding to the movable input working position of the movable input conveying device, the lifting driving part of the input lifting plate glass drying device stops, the movable input conveying device moves to the movable input working position, the movable output conveying device moves to the movable output working position, and the lifting driving part of the output lifting plate glass drying device drives the plate glass supporting piece of one output lifting plate glass drying device to move to the height corresponding to the movable output working position of the movable output conveying device, the movable input conveying device receives the plate glass, the movable input conveying device drives the received plate glass to move to the movable output conveying device;

step A4: after the movable output conveying device is driven to move to the movable output non-working position, a plate glass supporting piece of the output lifting plate glass drying device supports plate glass;

step A5: the lifting driving part of the output lifting plate glass drying device drives the plate glass supporting piece of the output lifting plate glass drying device to move downwards, and when the plate glass moves downwards to the output carrying and conveying device along with the plate glass supporting piece of the output lifting plate glass drying device, the output carrying and conveying device carries the plate glass and conveys the plate glass outwards.

A method of using a storage glass drying apparatus, wherein the method is suitable for use in any one of the above storage glass drying apparatuses, the method comprising:

step B1: closing an electric heating assembly at the top of the input lifting plate glass drying device and closing an electric heating assembly at the bottom of the input lifting plate glass drying device; closing an electric heating assembly at the top of the output lifting plate glass drying device and closing an electric heating assembly at the bottom of the output lifting plate glass drying device; closing the electric heating assembly at the top of the upper middle conveying device;

step B2: closing an input lifting plate glass drying device top circulating air system, closing an input lifting plate glass drying device bottom circulating air system, closing an output lifting plate glass drying device top circulating air system, and closing an output lifting plate glass drying device bottom circulating air system;

step B3: the lifting driving part of the input lifting plate glass drying device drives the plate glass supporting piece of the input lifting plate glass drying device to drive the plate glass to move downwards to the input receiving conveying device, so that the input receiving conveying device receives the plate glass;

step B4: the input bearing conveying device is driven to operate, the input bearing conveying device conveys the plate glass to the output bearing conveying device, and the output bearing conveying device conveys the plate glass outwards.

The utility model discloses owing to adopted above-mentioned technique, make it compare the positive effect that has with prior art and be:

(1) the input lifting plate glass drying device and the output lifting plate glass drying device of the utility model realize the drying and transmission of the plate glass by ascending or descending; the input carrying and conveying device and the output carrying and conveying device realize conveying and positioning of the plate glass; the movable input conveying device and the movable output conveying device can be moved to realize that the movable input conveying device and the movable output conveying device do not interfere with the plate glass and the corresponding input lifting plate glass drying device or output lifting plate glass drying device in the plate glass drying and conveying process, and the movable input conveying device and the movable output conveying device can convey the plate glass and realize the drying function.

Drawings

Fig. 1 is the front structural schematic diagram of the storage type glass drying device of the present invention.

Fig. 2 is the side structure schematic diagram of the input lifting plate glass drying device, the input receiving and conveying device and the movable transmission assembly of the storage type glass drying device.

Fig. 3 is the front structure diagram of the input lifting plate glass drying device of the storage type glass drying device of the utility model.

Fig. 4 is the side structure schematic diagram of the input lifting plate glass drying device of the storage type glass drying device of the utility model.

Fig. 5 is a schematic structural view of the movable transmission assembly of the storage type glass drying device of the present invention when connected with the movable portion driving mechanism.

Fig. 6 is a schematic diagram of the storage type glass drying device of the present invention under the control of the controller.

Fig. 7 is a schematic structural diagram of the first support installed at the bottom of the plate glass conveying structure near the input receiving conveying device 300 in the storage type glass drying device of the present invention.

Fig. 8 is a schematic structural diagram of the second support installed at the bottom of the plate glass conveying structure near the output receiving conveying device 400 in the storage type glass drying device of the present invention.

In the drawings: 1. a plate glass; 10. a controller; 100. inputting a lifting plate glass drying device; 110. a lifting drive member; 111. a conveyor chain; 112. a sprocket; 120. a flat glass support; 121. a flat glass support rod; 200. outputting a lifting plate glass drying device; 300. an input receiving transport device; 301. a plate glass input port of the input receiving conveying device; 302. a plate glass output port of the input receiving and conveying device; 310. receiving a conveying driving member; 311. a bearing part rotating shaft; 312. a bearing part rotating wheel; 400. an output receiving transport device; 401. a plate glass input port of the output receiving conveying device; 402. a plate glass output port of the output receiving and conveying device; 500. a mobile input conveyor; 501. a plate glass input port of the movable input conveying device; 502. a plate glass output port of the movable input conveying device; 530. a movable transmission assembly; 531. a movable rotating shaft; 532. a movable part wheel; 540. a movable section drive mechanism; 541. rotating the power member; 542. a horizontal power member; 5421. an intermediate member; 5422. a horizontal screw rod; 543. a vertical power member; 600. a mobile output conveyor; 601. a plate glass input port of the movable output conveying device; 602. a plate glass output port of the movable output conveying device; 700. an upper intermediate transport device; 701. a plate glass input port of the upper intermediate conveyance device; 702. a plate glass outlet of the upper middle conveying device; 800. a lower passage conveying device; 801. a sheet glass input port of the lower channel conveying device; 802. a plate glass output port of the lower channel conveying device; 810. a sheet glass transfer structure; 910. a horizontal input mechanism; 912. a flat glass output port of the horizontal input mechanism; 920. a horizontal output mechanism; 921. a flat glass input port of the horizontal output mechanism; 1000. the heat insulation layer of the lifting plate glass drying device; 1100. a circulating air system of the lifting plate glass drying device; 1101. inputting a circulating air system at the top of the lifting plate glass drying device; 1102. inputting a bottom circulating air system of the lifting plate glass drying device; 1103. outputting a circulating air system at the bottom of the lifting plate glass drying device; 1200. inputting an electric heating component of a lifting plate glass drying device; 1201. inputting an electric heating component at the top of the lifting plate glass drying device; 1202. inputting an electric heating component at the bottom of the lifting plate glass drying device; 1203. outputting an electric heating assembly at the top of the lifting plate glass drying device; 1204. outputting an electric heating assembly at the bottom of the lifting plate glass drying device; 1205. the upper middle conveyor top electrical heating assembly.

Detailed Description

The following description is provided for illustrative purposes, and other advantages and features of the present invention will become apparent to those skilled in the art from the following detailed description.

Please refer to the attached drawings. It should be understood that the structure, ratio, size and the like shown in the drawings attached to the present specification are only used for matching with the content disclosed in the specification, so as to be known and read by those skilled in the art, and are not used for limiting the limit conditions that the present invention can be implemented, so that the present invention has no technical essential meaning, and any structure modification, ratio relationship change or size adjustment should still fall within the scope that the technical content disclosed in the present invention can cover without affecting the function that the present invention can produce and the purpose that the present invention can achieve. Meanwhile, the terms such as "upper", "lower", "left", "right", "middle" and "one" used in the present specification are for convenience of description, and are not intended to limit the scope of the present invention, and changes or adjustments of the relative relationship thereof may be made without substantial technical changes, and the present invention is also regarded as the scope of the present invention.

As shown in fig. 1 to 8, there is shown a storage type glass drying apparatus of a preferred embodiment, which is preferably mounted on a rack (not shown), the storage type glass drying apparatus comprising: an input elevating panel glass drying apparatus 100 and an output elevating panel glass drying apparatus 200 which are sequentially arranged along a horizontal direction.

Further, as a preferred embodiment, the input elevating plate glass drying device 100 and the output elevating plate glass drying device 200 have the same structure, and both the input elevating plate glass drying device 100 and the output elevating plate glass drying device 200 include: the lifting driving part 110, the lifting driving part 110 is provided with a plate glass support 120, and the lifting driving part 110 can drive the plate glass support 120 to move along the vertical direction.

Further, as a preferred embodiment, the lower portion of the input elevating flat glass drying apparatus 100 is provided with an input receiving conveyor 300, and the flat glass support 120 of the input elevating flat glass drying apparatus 100 can pass through the input receiving conveyor 300 while moving in the vertical direction.

Further, as a preferred embodiment, the lower portion of the output elevating flat glass drying device 200 is provided with an output receiving conveyor 400, and the flat glass support 120 of the output elevating flat glass drying device 200 can pass through the output receiving conveyor 400 while moving in the vertical direction.

Further, as a preferred embodiment, the plate glass output port 302 of the input receiving conveyor 300 is opposite to the plate glass input port 401 of the output receiving conveyor 400, and the input receiving conveyor 300 can drive the plate glass 1 to move from the plate glass input port 301 of the input receiving conveyor 300 to the plate glass output port 302 of the input receiving conveyor 300; the output receiving conveyor 400 can drive the sheet glass 1 from the sheet glass inlet 401 of the output receiving conveyor 400 towards the sheet glass outlet 402 of the output receiving conveyor 400.

Further, as a preferred embodiment, the upper portion of the input lift glass panel drying apparatus 100 is provided with a movable input conveyor 500, the movable input conveyor 500 being movable between a movable input working position and a movable input non-working position, the movable input working position being inside the input lift glass panel drying apparatus 100 and the movable input non-working position being outside the input lift glass panel drying apparatus 100. The movable input conveyor 500 may drive the sheet glass 1 from the sheet glass input port 501 of the movable input conveyor 500 toward the sheet glass output port 502 of the movable input conveyor 500.

Further, as a preferred embodiment, a movable output conveyor 600 is provided on the upper portion of the output lifting plate glass drying apparatus 200, and the movable output conveyor 600 is movable between a movable output working position and a movable output non-working position, wherein the movable output working position is located inside the output lifting plate glass drying apparatus 200, and the movable output non-working position is located outside the input lifting plate glass drying apparatus 100. The movable output conveyor 600 can drive the sheet glass 1 to move from the sheet glass input port 601 of the movable output conveyor 600 toward the sheet glass output port 602 of the movable output conveyor 600.

Further, as a preferred embodiment, when the input lift glass drying apparatus 100 is in the movable input working position and the movable output conveyor 600 is in the movable output working position, the glass sheet output port 502 of the movable input conveyor 500 is opposite to the glass sheet input port 601 of the movable output conveyor 600.

The input lifting plate glass drying device 100 and the output lifting plate glass drying device 200 of the utility model realize the conveying of the plate glass 1 by ascending or descending; the input receiving conveyor 300 and the output receiving conveyor 400 carry out the conveyance and positioning of the sheet glass 1.

The movable input conveyor 500 is movable between a movable input working position and a movable input non-working position, so that interference with the sheet glass 1 and the corresponding input elevating sheet glass drying device 100 is avoided during the conveying process of the sheet glass 1.

The movable output transfer device 600 can move between the movable output working position and the movable output non-working position, and thus, the interference between the plate glass 1 and the corresponding output lifting plate glass drying device 200 is avoided in the conveying process of the plate glass 1.

The movable input conveyor 500 and the movable output conveyor 600 are capable of receiving and conveying the sheet glass 1.

The above is merely an example of the preferred embodiments of the present invention, and the embodiments and the protection scope of the present invention are not limited thereby.

The utility model discloses still have following embodiment on above-mentioned basis:

in a further embodiment of the present invention, the lifting driving part 110 comprises at least two vertical conveying assemblies arranged in sequence along the horizontal direction; each vertical conveying assembly comprises two conveying chains 111 arranged in parallel, at least two chain wheels 112 are arranged on the conveying chains 111, and all the chain wheels 112 drive the conveying chains 111 to rotate; a plurality of support bars 121 arranged at equal intervals are sequentially arranged on the conveying chain 111, and the central axis of each support bar 121 is parallel to the horizontal plane. Preferably, a plurality of support bars 121 may be arranged in a rectangular array, and the support bars 121 on the same plane constitute a flat glass support 120.

The utility model discloses a further embodiment, drive all sprockets 112 and rotate round same direction, can drive corresponding conveying chain 111 and remove, the utility model discloses a storage formula glass drying device is before using, in every vertical conveying assembly, through the removal of drive conveying chain 111, adjusts all bracing pieces 121, makes all bracing pieces 121, arranges into rectangular array, and the bracing piece 121 that is on the coplanar constitutes a flat glass support piece 120.

In a further embodiment of the present invention, the number of the vertical conveying assemblies is preferably three, four chain wheels 112 are provided on each conveying chain 111, the central axes of the four chain wheels 112 are parallel, two of the four chain wheels 112 tension the upper part of the conveying chain 111, and the other two chain wheels 112 tension the lower part of the conveying chain 111. The conveying chain 111 reciprocates to move the sheet glass support 120 in the vertical direction.

In a further embodiment of the present invention, the input receiving conveyor 300 and the output receiving conveyor 400 have the same structure; the incoming receiving conveyor 300 comprises a plurality of receiving conveyor drives 310 arranged in series along a horizontal direction, each receiving conveyor drive 310 comprising: the bearing portion rotating shaft 311 and the plurality of bearing portion rotating wheels 312 fixedly arranged on the bearing portion rotating shaft 311, the bearing portion rotating shaft 311 can rotate around the axial direction thereof, and each bearing portion rotating wheel 312 and each bearing portion rotating shaft 311 are coaxially arranged.

In a further embodiment of the present invention, the bearing portion rotating shaft 311 can rotate the connected bearing portion rotating wheel 312. All the receiving section rotating shafts 311 of the input receiving conveyor 300 rotate synchronously, and the sheet glass 1 can be stably driven to move.

In a further embodiment of the present invention, for a more compact structure, the input lifting flat glass drying device top electrical heating assembly 1201 and the input lifting flat glass drying device bottom electrical heating assembly 1202 are located inside the input lifting flat glass drying device 100; the top electrical heating component 1203 of the output lifting flat glass drying device and the bottom electrical heating component 1204 of the output lifting flat glass drying device are positioned inside the output lifting flat glass drying device 200; the upper intermediate conveyor top electrical heating assembly 1205 is positioned on the upper intermediate conveyor; the input lifting plate glass drying device top circulating air system 1101, the input lifting plate glass drying device bottom circulating air system 1102, the output lifting plate glass drying device top circulating air system 1103 and the output lifting plate glass drying device bottom circulating air system 1104 are positioned inside the lifting plate glass drying device insulating layer 1000.

In a further embodiment of the present invention, in order to make the structure more compact, all the receiving portion rotating wheels 312 of the input receiving conveyor 300 are located inside the input lifting flat glass drying device 100, and all the receiving portion rotating wheels 312 of the output receiving conveyor 400 are located inside the output lifting flat glass drying device 200; for more stable connection, both ends of the carrying section rotating shaft 311 of the input carrying conveyor 300 are positioned outside the input elevating flat glass drying device 100; both ends of the carrying section rotating shaft 311 of the output carrying conveyor 400 are located outside the output elevating flat glass drying device 200.

In a further embodiment of the present invention, the movable input conveyor 500 and the movable output conveyor 600 are identical in structure; the movable input conveyor 500 includes a plurality of movable transmission assemblies 530 sequentially arranged in a horizontal direction; each movable transmission assembly 530 comprises two movable rotating shafts 531 which are opposite and coaxially arranged, a plurality of movable part wheels 532 are fixedly arranged on each movable rotating shaft 531, and each movable part wheel 532 is coaxially arranged with the movable rotating shaft 531; one end of each movable rotating shaft 531, which is far away from the input lifting flat glass drying device 100, is connected with a movable part driving mechanism 540, the movable part driving mechanism 540 comprises a rotating power piece 541, the rotating power piece 541 is connected with the movable rotating shaft 531, and the rotating power piece 541 drives the movable rotating shaft 531 to rotate around the axial direction thereof; the rotary power member 541 is connected to the horizontal power member 542, and the horizontal power member 542 drives the rotary power member 541 to move in the horizontal direction along the axial direction of the movable rotary shaft 531.

The utility model discloses a further embodiment, the preferred motor of being connected with movable axis of rotation 531 of power piece 541 rotates, and horizontal power piece 542 includes the intermediate member 5421 of being connected with power piece 541 rotates, and intermediate member 5421 connects the horizontal lead screw 5422 that a level set up, and drive horizontal lead screw 5422 rotates, and horizontal lead screw 5422 drives horizontal power piece 542 and removes.

In a further embodiment of the present invention, the movable portion driving mechanism 540 further includes: vertical power piece 543, horizontal power piece 542 is connected to vertical power piece 543, and horizontal power piece 542 is driven along vertical direction to vertical power piece 543. Vertical power spare 543 is the vertical lead screw that is connected and vertical setting with horizontal power spare 542. The vertical screw rod drives the vertical power piece 543 to move in the vertical direction.

The utility model discloses a further embodiment, movable axis of rotation 531 can have the degree of freedom in level and two vertical directions in the setting of movable portion actuating mechanism 540, that is to say, can realize movable axis of rotation 531 in the inside and outside of input lift flat glass drying device 100 and in the inside and outside removal of output lift flat glass drying device 200 to when movable axis of rotation 531 gets into the inside of input lift flat glass drying device 100 and the inside of output lift flat glass drying device 200, highly adjust movable axis of rotation 531, in order to adapt to the transport to flat glass.

The utility model discloses a in the further embodiment, storage formula glass drying device still includes: an upper middle conveyor 700 and a lower aisle conveyor 800; the upper intermediate conveyance device 700 and the lower passage conveyance device 800 are both located between the input lifting flat glass drying device 100 and the output lifting flat glass drying device 200, and the upper intermediate conveyance device 700 is located above the lower passage conveyance device 800; when the input lifting plate glass drying device 100 is in the movable input working position and the movable output conveying device 600 is in the movable output working position, the plate glass input port 701 of the upper middle conveying device 700 is opposite to the plate glass output port 502 of the movable input conveying device 500, and the plate glass output port 702 of the upper middle conveying device 700 is opposite to the plate glass input port 601 of the movable output conveying device 600; the glass plate input port 801 of the lower channel transfer device 800 is opposed to the glass plate output port 302 of the input receiving conveyor 300, and the glass plate output port 802 of the lower channel transfer device 800 is opposed to the glass plate input port 401 of the output receiving conveyor 400.

The utility model discloses a further embodiment, conveyor 700's setting in the middle of the upper portion is as the flat glass 1 transmission transition device between movable input conveyer 500 and the movable output conveyer 600, and lower passage conveyor 800's setting is as the input and accepts conveyer 300 and the output and accepts the flat glass 1 transmission transition device between the conveyer 400, and this structure makes flat glass 1 can convey high-efficiently, the high-efficient operation of the entire system of being convenient for.

In a further embodiment of the present invention, the lower channel conveying device 800 comprises two spaced plate glass conveying structures 810. Sufficient space is left between the two spaced apart sheet glass transfer structures 810 to allow access for a person or a forklift.

The utility model discloses a further embodiment, first support 821 is installed to the bottom of being close to the sheet glass transport structure 810 that input accepts conveyer 300 in two sheet glass transport structure 810, and first support 821 is in the one end that is close to input accepting conveyer 300 of this sheet glass transport structure 810, and first support 821 is connected through first pivot 831 with this sheet glass transport structure 810, and the rotation of drive first pivot 831, first pivot 831 can drive this sheet glass transport structure 810 upwards or turn up downwards. The second support 822 is installed at the bottom of the plate glass conveying structure 810 close to the output receiving conveying device 400 in the two plate glass conveying structures 810, the second support 822 is located at one end of the plate glass conveying structure 810 close to the output receiving conveying device 400, the second support 822 is connected with the plate glass conveying structure 810 through a second rotating shaft 832 to drive the second rotating shaft 832 to rotate, and the second rotating shaft 832 can drive the plate glass conveying structure 810 to be turned up or down. The structure can enlarge the space reserved for the passage of people or forklifts.

The utility model discloses a in the further embodiment, storage formula glass drying device still includes: a horizontal input mechanism 910 and a horizontal output mechanism 920; the glass sheet outlet 912 of the horizontal feeding mechanism 910 is opposed to the glass sheet inlet 301 of the receiving and transferring device 300, and the glass sheet inlet 921 of the horizontal feeding mechanism 920 is opposed to the glass sheet inlet 401 of the receiving and transferring device 400. The horizontal in-mechanism 910 enables the sheet glass 1 to be more smoothly conveyed onto the in-receiving conveyor 300, and the horizontal out-mechanism 920 enables the sheet glass 1 to be more smoothly sent out from the out-receiving conveyor 400.

Preferably, the upper intermediate conveyor 700, the sheet glass conveying structure 810, the horizontal input mechanism 910, and the horizontal output mechanism 920 are all pulley-driven structures.

The utility model discloses a in the further embodiment, storage formula glass drying device still includes: a controller 10; the controller 10 is connected with the lifting driving part 110 of the input lifting plate glass drying device 100, the lifting driving part 110 of the output lifting plate glass drying device 200, the input receiving and conveying device 300, the output receiving and conveying device 400, the horizontal power piece 542, the rotating power piece 541, the vertical power piece 543, the upper middle conveying device 700, the plate glass conveying structure 810, the horizontal input mechanism 910 and the horizontal output mechanism 920;

in a further embodiment of the present invention, the controller 10 controls the operation and stop of the lifting driving part 110 of the input lifting plate glass drying device 100, the lifting driving part 110 of the output lifting plate glass drying device 200, the input receiving conveyer 300, the output receiving conveyer 400, the horizontal power part 542, the rotating power part 541, the vertical power part 543, the upper middle conveying device 700, the plate glass conveying structure 810, the horizontal input mechanism 910 and the horizontal output mechanism 920.

The following describes the method of use of the present invention:

the utility model discloses a storage formula glass drying device's application method can realize carrying out stoving formula transport and non-stoving formula transport to sheet glass 1.

When the sheet glass 1 is subjected to the drying type conveyance, the method comprises the following steps: the input receiving conveyor 300 is in a stop state, and the movable input conveyor 500 is in a movable input non-working position, the lifting driving part 110 of the input lifting plate glass drying device 100 drives the plate glass support 120 of the input lifting plate glass drying device 100 to move upwards, and the plate glass support 120 of each input lifting plate glass drying device 100 drives the plate glass 1 conveyed to the input receiving conveyor 300 to move upwards in the process of moving upwards and passing through the input receiving conveyor 300, so that the plate glass 1 is sequentially stored on the plate glass support 120 of the input lifting plate glass drying device 100.

Specifically, the use method of the drying type conveying comprises the following steps:

step A1: an input lifting flat glass drying device top electric heating assembly 1201 is started, and an input lifting flat glass drying device bottom electric heating assembly 1202 is started; the top electrical heating component 1203 of the output lifting flat glass drying device is started, and the bottom electrical heating component 1204 of the output lifting flat glass drying device is started; the upper intermediate conveyor top electrical heating assembly 1205 is turned on;

step A2: an input lifting plate glass drying device top circulating air system 1101 is started, an input lifting plate glass drying device bottom circulating air system 1102 is started, an output lifting plate glass drying device top circulating air system 1103 is started, and an output lifting plate glass drying device bottom circulating air system 1104 is started;

step A3: when the elevation driving part 110 of the input elevating panel glass drying apparatus 100 drives the panel glass support 120 of the input elevating panel glass drying apparatus 100 to drive the panel glass 1 to move upward to a height corresponding to the movable input working position of the movable input conveyor 500, the elevation driving part 110 of the input elevating flat glass drying device 100 is stopped, the movable input conveyor 500 is moved to the movable input working position, the movable output conveyor 600 is moved to the movable output working position, and the elevation driving part 110 of the output elevating flat glass drying device 200 drives the flat glass support 120 of one of the output elevating flat glass drying devices 200 to move to a height corresponding to the movable output working position of the movable output conveyor 600, the movable input conveyor 500 receives the flat glass 1, and the movable input conveyor 500 drives the received plate glass 1 to move to the movable output conveyor 600;

step A4: after the movable output conveying device 600 is driven to move to the movable output non-working position, the plate glass supporting piece 120 of the output lifting plate glass drying device 200 receives the plate glass 1;

step A5: the elevation driving part 110 of the output elevating plate glass drying device 200 drives the plate glass support 120 of the output elevating plate glass drying device 200 to move downward, and when the plate glass 1 moves downward onto the output receiving conveyor 400 along with the plate glass support 120 of the output elevating plate glass drying device 200, the output receiving conveyor 400 receives the plate glass 1 and conveys the plate glass 1 outward.

Further, after step a3 when the drying type conveying of the sheet glass 1 is completed, the movable input conveyor 500 moves to the inactive input working position, and the lifting driving part 110 of the input lifting sheet glass drying device 100 drives the sheet glass support 120 to drive the stored next sheet glass 1 to move upwards until the next sheet glass 1 moves to the height corresponding to the active input working position of the movable input conveyor 500; the next sheet glass 1 is subjected to the first-in-first-out conveyance, and when the conditions of step a3 for the non-drying conveyance of the sheet glass 1 are satisfied again, the next sheet glass 1 enters the work cycle.

Further, in the step a5 of performing the drying type conveyance of the sheet glass 1, the process of the lifting driving means 110 of the output lifting sheet glass drying device 200 driving the sheet glass supporting member 120 of the output lifting sheet glass drying device 200 to move downward is performed by moving downward layer by layer in accordance with the rectangular array formed by all the supporting rods 121 of the output lifting sheet glass drying device 200.

More specifically, the method of use of non-drying transport comprises:

step B1: closing an input lifting flat glass drying device top electric heating assembly 1201 and closing an input lifting flat glass drying device bottom electric heating assembly 1202; closing an electric heating assembly 1203 at the top of the output lifting flat glass drying device and closing an electric heating assembly 1204 at the bottom of the output lifting flat glass drying device; the upper intermediate conveyor top electrical heating assembly 1205 is turned off;

step B2: closing an input lifting flat glass drying device top circulating air system 1101, closing an input lifting flat glass drying device bottom circulating air system 1102, closing an output lifting flat glass drying device top circulating air system 1103 and closing an output lifting flat glass drying device bottom circulating air system 1104;

step B3: the lifting driving part 110 of the input lifting plate glass drying device 100 drives the plate glass support 120 of the input lifting plate glass drying device 100 to drive the plate glass 1 to move downwards to the input receiving conveying device 300, so that the input receiving conveying device 300 receives the plate glass 1;

step B4: the input receiving conveyor 300 is driven to operate, the input receiving conveyor 300 conveys the plate glass 1 to the output receiving conveyor 400, and the output receiving conveyor 400 conveys the plate glass 1 outwards.

Further, as a preferred embodiment, the plate glass 1 may be a solar photovoltaic substrate or a plate glass plate.

The utility model relates to a storage type glass drying device and method with high efficiency and small occupied area.

To sum up, the utility model discloses various shortcomings in the prior art have effectively been overcome and high industry value has.

The above is only a preferred embodiment of the present invention, and not intended to limit the scope of the invention, and it should be appreciated by those skilled in the art that various equivalent substitutions and obvious changes made in the specification and drawings should be included within the scope of the present invention.

Claims (9)

1. The utility model provides a storage formula glass drying device which characterized in that includes: an input lifting plate glass drying device (100) and an output lifting plate glass drying device (200) which are arranged in sequence along the horizontal direction;

the input lifting plate glass drying device (100) and the output lifting plate glass drying device (200) both comprise: the lifting device comprises a lifting driving part (110) and a plate glass support (120), wherein the plate glass support (120) is arranged on the lifting driving part (110), and the lifting driving part (110) can drive the plate glass support (120) to move along the vertical direction;

an input receiving and conveying device (300) is arranged at the lower part of the input lifting plate glass drying device (100), and the plate glass supporting piece (120) on the input lifting plate glass drying device (100) can pass through the input receiving and conveying device (300) in the process of moving along the vertical direction;

an output carrying and conveying device (400) is arranged at the lower part of the output lifting plate glass drying device (200), and the plate glass supporting piece (120) on the output lifting plate glass drying device (200) can pass through the output carrying and conveying device (400) in the process of moving along the vertical direction;

the plate glass output port (302) of the input receiving and conveying device (300) is opposite to the plate glass input port (401) of the output receiving and conveying device (400);

a movable input conveying device (500) is arranged at the upper part of the input lifting plate glass drying device (100), the movable input conveying device (500) can move between a movable input working position and a movable input non-working position, the movable input working position is positioned inside the input lifting plate glass drying device (100), and the movable input non-working position is positioned outside the input lifting plate glass drying device (100);

the upper part of the output lifting plate glass drying device (200) is provided with a movable output conveying device (600), the movable output conveying device (600) can move between a movable output working position and a movable output non-working position, the movable output working position is positioned inside the output lifting plate glass drying device (200), and the movable output non-working position is positioned outside the input lifting plate glass drying device (100);

when the movable input conveying device (500) is in the movable input working position and the movable output conveying device (600) is in the movable output working position, the plate glass output port (502) of the movable input conveying device (500) is opposite to the plate glass input port (601) of the movable output conveying device (600);

further comprising: the device comprises a heat insulation layer (1000) of the lifting plate glass drying device, a circulating air system (1100) of the lifting plate glass drying device and an electric heating assembly (1200) of the lifting plate glass drying device;

the circulating air system (1100) of the lifting plate glass drying device comprises: a top circulating air system (1101) of the lifting plate glass drying device, a bottom circulating air system (1102) of the input lifting plate glass drying device and a bottom circulating air system (1103) of the output lifting plate glass drying device;

the electric heating assembly (1200) of the lifting plate glass drying device comprises: an input lifting plate glass drying device top electric heating assembly (1201), an input lifting plate glass drying device bottom electric heating assembly (1202), an output lifting plate glass drying device top electric heating assembly (1203), an output lifting plate glass drying device bottom electric heating assembly (1204), and an upper middle conveyor top electric heating assembly (1205).

2. A storage glass drying apparatus according to claim 1, wherein each of the lifting drive means (110) comprises at least two vertical transport assemblies arranged one after the other in a horizontal direction;

each of the vertical transfer assemblies includes: the conveying device comprises two conveying chains (111) which are arranged in parallel, wherein at least two chain wheels (112) are arranged on the conveying chains (111), and the chain wheels (112) drive the conveying chains (111) to rotate; a plurality of supporting rods (121) which are arranged at equal intervals are sequentially arranged on the conveying chain (111), and the central axis of each supporting rod (121) is parallel to the horizontal plane;

the support rods (121) are in a rectangular array, and the support rods (121) on the same plane form the plate glass support (120).

3. A storage glass drying apparatus according to claim 1, characterized in that the input receiving conveyor (300) and the output receiving conveyor (400) each comprise: a plurality of receiving conveyor drives (310) arranged in series along a horizontal direction, each receiving conveyor drive (310) comprising: the bearing part rotating shaft (311) and a plurality of bearing part rotating wheels (312) fixedly arranged on the bearing part rotating shaft (311), the bearing part rotating shaft (311) can rotate around the axial direction of the bearing part rotating shaft, and each bearing part rotating wheel (312) and the bearing part rotating shaft (311) are coaxially arranged.

4. The storage glass drying apparatus of claim 1, wherein the movable input conveyor (500) and the movable output conveyor (600) each comprise: a plurality of movable transmission assemblies (530) sequentially arranged in a horizontal direction; each movable transmission assembly (530) comprises two opposite and coaxially arranged movable rotating shafts (531), each movable rotating shaft (531) is fixedly provided with a plurality of movable part wheels (532), and each movable part wheel (532) is coaxially arranged with each movable rotating shaft (531);

one end, far away from the input lifting flat glass drying device (100), of each movable rotating shaft (531) is connected with a movable part driving mechanism (540), each movable part driving mechanism (540) comprises a rotating power piece (541), each rotating power piece (541) is connected with the corresponding movable rotating shaft (531), and each rotating power piece (541) drives the corresponding movable rotating shaft (531) to rotate around the axial direction of the corresponding movable rotating shaft (531); the rotating power piece (541) is connected with a horizontal power piece (542), and the horizontal power piece (542) drives the rotating power piece (541) to move along the axial direction of the movable rotating shaft (531) in the horizontal direction.

5. The storage glass drying apparatus of claim 4, wherein the moving part drive mechanism (540) further comprises: vertical power spare (543), horizontal power spare (542) is connected to vertical power spare (543), vertical power spare (543) drive horizontal power spare (542) move along vertical direction.

6. The storage glass drying apparatus of claim 1, further comprising: an upper intermediate conveyor (700) and a lower aisle conveyor (800), both the upper intermediate conveyor (700) and the lower aisle conveyor (800) being located between the input lift sheet glass drying apparatus (100) and the output lift sheet glass drying apparatus (200), the upper intermediate conveyor (700) being located above the lower aisle conveyor (800);

when the movable input conveying device (500) is in the movable input working position and the movable output conveying device (600) is in the movable output working position, the plate glass input port (701) of the upper middle conveying device (700) is opposite to the plate glass output port (502) of the movable input conveying device (500), and the plate glass output port (702) of the upper middle conveying device (700) is opposite to the plate glass input port (601) of the movable output conveying device (600);

the plate glass input port (801) of the lower channel conveying device (800) is opposite to the plate glass output port (302) of the input receiving conveying device (300), and the plate glass output port (802) of the lower channel conveying device (800) is opposite to the plate glass input port (401) of the output receiving conveying device (400).

7. The storage glass drying apparatus of claim 6, wherein the lower channel conveyor (800) comprises two spaced apart sheet glass transfer structures (810).

8. A storage type glass drying apparatus according to claim 1, further comprising a horizontal input mechanism (910) and a horizontal output mechanism (920), wherein the glass sheet output port (912) of the horizontal input mechanism (910) is opposite to the glass sheet input port (301) of the input receiving conveyor (300), and the glass sheet input port (921) of the horizontal output mechanism (920) is opposite to the glass sheet input port (401) of the output receiving conveyor (400).

9. A storage type glass drying apparatus according to claim 1, further comprising a controller (10), wherein the controller (10) controls the elevation driving part (110) of the input elevation panel glass drying apparatus (100), the elevation driving part (110) of the output elevation panel glass drying apparatus (200), the input carrying conveyor (300), the output carrying conveyor (400), the movable input conveyor (500) and the movable output conveyor (600), respectively.

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