CN215515785U - Glass unloading equipment - Google Patents

Glass unloading equipment Download PDF

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Publication number
CN215515785U
CN215515785U CN202120562834.7U CN202120562834U CN215515785U CN 215515785 U CN215515785 U CN 215515785U CN 202120562834 U CN202120562834 U CN 202120562834U CN 215515785 U CN215515785 U CN 215515785U
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China
Prior art keywords
glass
positioning
piece
rack
placing
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CN202120562834.7U
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Chinese (zh)
Inventor
董清世
帅建忠
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Dongguan Benson Automobile Glass Co ltd
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Dongguan Benson Automobile Glass Co ltd
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Priority to CN202120562834.7U priority Critical patent/CN215515785U/en
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Abstract

The utility model belongs to the technical field of glass, and particularly relates to glass discharging equipment. This piece equipment under glass includes piece positioner, rack and transfer device down, and wherein, piece positioner is used for being and connects the glass from glass production equipment output such as forced air cooling unit to carry out position adjustment to glass, make glass export from piece positioner down with the same gesture, the rack has the space of placing that supplies glass to place, and transfer device is used for transporting the glass after piece positioner fixes a position to placing in the space of placing of rack down. Use this piece equipment under glass to lower piece to glass, its whole piece process of unloading has simulated the basic handling process of artifical piece operation under, can realize lower piece in order and steadily placing glass, and the piece process of unloading can not lead to the fact the damage to glass, on the basis of guaranteeing that glass is safe, has liberated the labour, has improved glass's piece efficiency and piece security down greatly.

Description

Glass unloading equipment
Technical Field
The utility model belongs to the technical field of glass, and particularly relates to glass discharging equipment.
Background
In the production process of printing glass, after the glass is dried and air-cooled, the glass needs to be discharged, and after the glass is discharged, the glass needs to be placed on a specific placing frame for later use. In a glass production workshop, glass is often conveyed manually, an operator moves between the glass air-cooling equipment and the placing rack to take and place the glass, the labor intensity is high, the glass discharging efficiency is difficult to improve, and the risk that a worker is injured by the large-size glass is also existed.
SUMMERY OF THE UTILITY MODEL
The embodiment of the utility model aims to provide glass unloading equipment to solve the technical problems of high labor intensity, low unloading efficiency and poor safety in manual glass unloading conveying in the prior art.
In order to achieve the purpose, the utility model adopts the technical scheme that: an apparatus for lowering a glass sheet comprising:
the lower sheet positioning device comprises a rack and a positioning mechanism, wherein a glass conveying plane for receiving the lower sheet of glass is arranged on the rack, and the positioning mechanism is arranged on the rack and used for positioning the glass conveyed to the glass conveying plane so that the glass is output from the lower sheet positioning device in the same posture;
the placing frames are arranged beside the rack at intervals along the glass output direction of the lower piece positioning device and used for placing the glass output from the lower piece positioning device;
transfer device sets up between frame and rack, and transfer device is including transporting platform and tilting mechanism, transports the platform and can be in order being to connect and transport the glass of lower piece positioner output to being close to the rack in order being reciprocal linear motion between frame and rack, and tilting mechanism rotates and installs in the lateral part of transporting the platform for carry to the glass on transporting the platform and take off, and put glass to the rack after overturning the plane of placing that is on a parallel with the rack with glass.
In some embodiments, a plurality of conveying rollers are arranged on the frame at intervals along the direction of the lower glass sheet, and the surfaces of the plurality of conveying rollers are positioned on the same plane and form a glass conveying plane;
the lower sheet positioning device also comprises a lifting mechanism, the lifting mechanism comprises a lifting frame, a lifting driving assembly and a plurality of supporting legs for supporting the glass, the lifting frame is movably arranged on the rack, each supporting leg is rotatably arranged on the lifting frame in an equal height way and is positioned at the installation gap between the conveying rollers, and the lifting driving assembly is in driving connection with the lifting frame so as to drive the lifting frame to move up and down relative to the glass conveying plane, so that each supporting leg extends out of or retracts into the corresponding installation gap;
the positioning mechanism comprises a plurality of groups of side positioning assemblies arranged at the four sides of the glass conveying plane, each side positioning assembly comprises a positioning piece and a positioning driving piece in driving connection with the positioning piece, the positioning driving pieces are arranged on the rack, and the positioning pieces are suspended above the glass conveying plane;
when the lifting driving assembly drives the lifting frame to move to enable the supporting legs to extend out of the corresponding mounting gaps, the positioning driving pieces drive the corresponding positioning pieces to move towards the supporting legs, so that the positioning pieces are in contact with and adjust the positions of the glass supported on the supporting legs.
In some embodiments, the plurality of support legs are arranged in a rectangular array, and the plurality of sets of side positioning elements are respectively disposed on four sides of the rectangular array formed by the plurality of support legs.
In some embodiments, the positioning mechanism includes six sets of side positioning elements, wherein two sets of side positioning elements are spaced apart along a first direction, the other two sets of side positioning elements are spaced apart along a second direction and are adjacent to one of the two side positioning elements along the first direction, and the remaining two sets of side positioning elements are spaced apart along the second direction and are adjacent to the other of the two side positioning elements along the first direction, the second direction being perpendicular to the first direction.
In some embodiments, the support feet are universal rubber wheels.
In some embodiments, the glass unloading device further comprises a plurality of conveying belts wound on the lifting frame, the conveying belts and the supporting legs are arranged at the same height and are respectively located at the installation gaps among the conveying rollers, and the conveying belts are parallel to the conveying rollers and are used for outputting the positioned glass along the direction perpendicular to the conveying rollers.
In some embodiments, the transfer device further comprises a fixed support and a movable support, the fixed support is arranged between the rack and the placing rack, the movable support is arranged on the fixed support in a sliding mode, the movable support is provided with a plurality of transfer belts which are arranged at intervals in a rotating mode along the glass output direction of the lower sheet positioning device, the surfaces of the transfer belts are located on the same plane and form a transfer platform, and the turnover mechanism is arranged at the end portion, close to the placing rack, of the movable support.
In some embodiments, the turnover mechanism includes a turnover arm, a vacuum chuck and a turnover motor, the turnover arm is rotatably mounted on the movable support and is opposite to the interval gap between the transfer belts, the vacuum chuck is mounted on the side of the turnover arm departing from the transfer platform, and the output end of the turnover motor is connected with the turnover arm to drive the turnover arm to turn over to be located in the interval gap or turn over from the interval gap, wherein when the turnover arm rotates to be located in the interval gap, the vacuum chuck is located below the transfer platform.
In some embodiments, the turnover mechanism further includes a suction cup driving member, the suction cup driving member is installed on the turnover arm, the vacuum suction cup is installed on an output shaft of the suction cup driving member, the output shaft of the suction cup driving member is parallel to the turnover arm, and the output shaft of the suction cup driving member moves relative to the turnover arm in a telescopic manner so as to drive and adjust the setting position of the vacuum suction cup on the turnover arm.
In some embodiments, the fixed support comprises two slide rails arranged in parallel with the glass output direction of the lower sheet positioning device at intervals, the position of the movable support corresponding to each slide rail is correspondingly provided with a slide block, the slide block is slidably clamped on the corresponding slide rail, the fixed support is further provided with a transfer driving motor, and the output shaft of the transfer driving motor is connected with the movable support.
One or more technical schemes in the glass unloading equipment provided by the utility model at least have one of the following technical effects: when the glass conveying device is used, the lower sheet positioning device is moved to the side of air cooling equipment and the like, and the glass conveying plane is positioned in the output direction of the lower sheet of glass, so that the lower sheet of glass in the working procedures of the air cooling equipment and the like is connected by the glass conveying plane, and the positioning mechanism is used for positioning and adjusting the glass moved to the glass conveying plane, so that the glass is output from the lower sheet positioning device in the same posture; subsequently, the glass output from the lower sheet positioning device is moved to a transfer platform close to the rack to be connected, the transfer platform is moved towards the rack after being connected with the glass, and finally the glass is taken down by the turnover mechanism and is placed on the rack after being turned over to a placement plane parallel to the rack, so that the glass output from the previous process is placed on the rack for standby by the lower sheet. Like this, when carrying out the lower piece to glass, carry out the gesture adjustment to glass through setting up lower piece positioner, through setting up transfer device with the glass after the location on transporting to the rack, and in the transportation, get from transporting the platform through tilting mechanism and put glass, tilting mechanism can adjust the relative planar inclination of placing of glass, make glass place on the rack with the planar state of placing of parallel rack, whole lower piece process has simulated the basic handling process of artifical lower piece operation, can realize lower piece in order and steady the placing of glass, lower piece process can not lead to the fact the damage to glass, on the basis of guaranteeing that glass is safe lower piece, the labour has been liberated, glass's lower piece efficiency and lower piece security have been improved greatly.
Drawings
In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the embodiments or the prior art descriptions will be briefly described 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 based on these drawings without inventive exercise.
FIG. 1 is a schematic structural diagram of a glass run-down apparatus according to an embodiment of the present invention;
FIG. 2 is a schematic view of the lower positioning device of the glass lowering apparatus shown in FIG. 1;
FIG. 3 is a first view illustrating a first partial structure of the lower plate positioning device shown in FIG. 2;
FIG. 4 is a second schematic view of a portion of the lower plate positioning device shown in FIG. 2;
FIG. 5 is a schematic structural view of a lifting mechanism of the lower sheet positioning device shown in FIG. 2;
FIG. 6 is a schematic view of the positioning mechanism of the lower sheet positioning device shown in FIG. 2;
FIG. 7 is a schematic structural view of a side positioning assembly of the positioning mechanism shown in FIG. 6;
FIG. 8 is a schematic view of the transfer device of the glass run-down apparatus shown in FIG. 1;
FIG. 9 is a schematic view of a portion of the transfer device shown in FIG. 8;
fig. 10 is a schematic structural view of a rack of the glass unloading apparatus shown in fig. 1.
Wherein, in the figures, the respective reference numerals:
10. a lower sheet positioning device; 11. a frame; 111. a conveying roller; 112. a glass conveying plane; 113. a mounting gap; 114. a base; 115. a mounting frame; 116. a drive motor; 117. a synchronization lever; 118. a driven wheel; 119. a driving wheel; 12. a lifting mechanism; 121. a lifting frame; 122. a lift drive assembly; 123. supporting legs; 124. a lifting cylinder; 125. a transmission connecting rod; 126. a sleeve; 127. a guide bar; 13. a positioning mechanism; 131. a side positioning assembly; 1311. positioning a driving piece; 1312. a positioning member; 132. a suspension frame; 1321. A cross beam; 1322. a stringer; 14. a conveyor belt; 20. placing a rack; 21. placing the underframe; 22. a support frame; 221. a first support frame; 222. a second support frame; 223. a placement space; 30. a transfer device; 31. A transfer platform; 311. a transfer belt; 312. a spacing gap; 32. a turnover mechanism; 321. a turning arm; 322. A vacuum chuck; 323. turning over a motor; 324. a suction cup driving member; 33. fixing a bracket; 331. a slide rail; 332. a transfer drive motor; 34. moving the support; 341. a slide block.
Detailed Description
In order to make the technical problems, technical solutions and advantageous effects to be solved by the present invention more clearly understood, the present invention is further described in detail below with reference to fig. 1 to 10 and the embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the utility model and are not intended to limit the utility model.
It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or be indirectly on the other element. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or be indirectly connected to the other element.
It will be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like, as used herein, refer to an orientation or positional relationship indicated in the drawings, which is solely for the purpose of facilitating the description and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and is therefore not to be construed as limiting the utility model.
Furthermore, the terms "first", "second" and "first" 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" or "second" 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 defined otherwise.
Reference in the specification to "one embodiment," "some embodiments," or "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment is included in one or more embodiments of the utility model. Thus, appearances of the phrases "in one embodiment," "in some embodiments," "in other embodiments," or the like, in various places throughout this specification are not necessarily all referring to the same embodiment, but rather "one or more but not all embodiments" unless specifically stated otherwise. Furthermore, the particular features, structures, or characteristics may be combined in any suitable manner in one or more embodiments.
As shown in fig. 1 to 10, an embodiment of the present invention provides a glass unloading apparatus, which is suitable for being placed at a unloading end of a glass production apparatus such as an air cooling apparatus, and is used for performing an automatic unloading operation on glass produced by the glass production apparatus, and moving the glass from the production apparatus to a placing rack 20 for temporary storage. Specifically, this glass unloading equipment includes piece positioner 10, rack 20 and transfer device 30 down, wherein, piece positioner 10 down is used for being the glass that connects glass production equipment output such as air-cooled device to carry out position adjustment to glass, make glass export from piece positioner 10 down with the same gesture, rack 20 has the place space 223 that supplies glass to place, and transfer device 30 is used for transporting the glass after piece positioner 10 down fixes a position to placing in place space 223 of rack 20.
Further, as shown in fig. 1 and 2, the lower positioning device 10 includes a frame and a positioning mechanism, the frame is provided with a glass conveying plane for receiving the lower glass, the frame is arranged at a lower end of a specific glass production device such as an air cooling device, and the glass conveying plane is arranged parallel to the direction of glass output from the production device, the positioning mechanism is mounted on the frame and is used for positioning the glass conveyed to the glass conveying plane, so that the glass is output from the lower positioning device 10 in the same posture, wherein the glass output from the lower positioning device 10 in the same posture means that: the positioning mechanism adjusts the placing position and the placing angle of the glass relative to the glass conveying plane, so that the positioned glass has completely overlapped conveying tracks when being output.
Further, as shown in fig. 1 and 10, the placing frame 20 is disposed beside the rack at intervals along the glass output direction of the lower sheet positioning device 10, and is used for placing the glass output from the lower sheet positioning device 10. In this embodiment, the placing rack 20 is the placing rack 20 with the "a" shaped abutting structure as shown in fig. 1 and fig. 2, specifically, the placing rack 20 includes a placing bottom frame 21 and a supporting frame 22 disposed in the middle of the placing bottom frame 21, the supporting frame 22 includes a first supporting frame 221 and a second supporting frame 222, one end of the first supporting frame 221 and one end of the second supporting frame 222 are disposed at an interval and are respectively fixedly connected to the placing bottom frame 21, the other end of the first supporting frame 221 and the other end of the second supporting frame 222 extend away from the placing bottom frame 21 and are fixedly connected to each other, an included angle greater than 90 ° is formed between a plane where the first supporting frame 221 is located and a surface where the placing bottom frame 21 is located, and a placing space 223 where the placing rack 20 is used for placing glass. In this embodiment, after the positioning mechanism of the lower sheet positioning device 10 positions the glass, the side edge of the output glass close to the transfer platform 31 is parallel to the surface of the placing bottom frame 21, so that the side edge of the glass contacting with the placing bottom frame 21 is parallel to the placing bottom frame 21 when the glass is placed, and the glass is prevented from being damaged when the glass is placed.
Furthermore, as shown in fig. 1 and 8, the transferring device 30 is disposed between the rack and the placing rack 20, the transferring device 30 includes a transferring platform 31 and a turning mechanism 32, the transferring platform 31 can move between the rack and the placing rack 20 in a reciprocating linear manner to transfer the glass output by the lower sheet positioning device 10 to a position close to the placing rack 20, the turning mechanism 32 is rotatably mounted on a lateral portion of the transferring platform 31, and is used for taking down the glass conveyed to the transferring platform 31 and placing the glass on the placing rack 20 after the glass is turned to a placing plane parallel to the placing rack 20. Specifically, tilting mechanism 32 rotates to make glass and first carriage 221 parallel back relatively to transporting platform 31, places glass in the place space 223 of rack 20, and like this, the whole laminating of glass is on first carriage 221 to can avoid glass to take place to warp because of the middle part is unsettled.
According to the glass lower sheet setting of the embodiment of the utility model, when the glass lower sheet setting device is used, the lower sheet positioning device 10 is moved to the side of air cooling equipment and the like, and the glass conveying plane is positioned in the output direction of the lower sheet glass, so that the lower sheet glass in the working procedures of the air cooling equipment and the like is connected by the glass conveying plane, and the positioning mechanism is used for positioning and adjusting the glass moved to the glass conveying plane, so that the glass is output from the lower sheet positioning device 10 in the same posture; subsequently, the glass output from the lower sheet positioning device 10 is moved to the transfer platform 31 close to the rack to be connected, the transfer platform 31 is moved to the placing frame 20 after being connected with the glass, and finally the glass is taken down by the turnover mechanism 32 and placed on the placing frame 20 after being turned to the placing plane parallel to the placing frame 20, so that the glass output from the previous process is placed on the placing frame 20 for later use by the lower sheet. Like this, when carrying out the lower piece to glass, carry out the gesture adjustment to glass through setting up lower piece positioner 10, through setting up transfer device 30 glass after will fixing a position transports to rack 20 on, and in the transportation, get from transporting platform 31 through tilting mechanism 32 and put glass, tilting mechanism 32 can adjust the relative planar inclination of placing of glass, make glass place on rack 20 with the planar state of placing of parallel rack 20, the artifical basic handling process of piece operation under whole piece process simulation, can realize the orderly piece of leaving and steadily placing glass, the piece process can not lead to the fact the damage to glass down, on the basis of guaranteeing glass safety piece, the labour has been liberated, glass's piece efficiency and piece security down have been improved greatly.
In another embodiment of the present invention, as shown in fig. 2 to 4, the frame 11 of the glass unloading device includes a base 114 and a mounting rack 115 disposed on the base 114, a plurality of conveying rollers 111 are rotatably mounted on the mounting rack 115 at intervals along a conveying direction of the glass unloading, and surfaces of the plurality of conveying rollers 111 are located on a same plane and form the glass conveying plane 112.
Further, the lower sheet positioning device 10 further includes a lifting mechanism 12, the lifting mechanism 12 includes a lifting frame 121, a lifting driving assembly 122 and a plurality of supporting legs 123 for supporting the glass, the lifting frame 121 is movably mounted on the frame 11, specifically, a mounting space is provided between the mounting frame 115 and the base 114, and the lifting mechanism 12 is disposed below the mounting frame 115 and located in the mounting space; the supporting legs 123 are rotatably mounted on the lifting frame 121 at equal heights, wherein the supporting legs 123 are arranged at equal heights, which means that the vertexes of the supporting legs 123 facing the glass conveying plane 112 are located at the same height.
Furthermore, each supporting foot 123 is located at the installation gap 113 between each conveying roller 111, and the lifting driving assembly 122 is in driving connection with the lifting frame 121 to drive the lifting frame 121 to move up and down relative to the glass conveying plane 112, so that each supporting foot 123 can extend out or retract from the corresponding installation gap 113. Specifically, when the glass is conveyed to the position right above the supporting feet 123 through the conveying roller 111, the lifting driving mechanism drives the lifting frame 121 to move upwards, the supporting feet 123 extend out of the installation gaps 113 of the conveying roller 111, so that the glass is lifted to exceed the glass conveying plane 112, and conversely, when the lifting driving assembly 122 drives the lifting frame 121 to move downwards, and the supporting feet 123 are withdrawn from the installation gaps 113 of the conveying roller 111, the glass moves to be in contact with the conveying roller 111 again, namely to be returned to the glass conveying plane 112 again.
Thus, when the glass sheet discharging device of this embodiment is used, glass sheets discharged from an air cooling device and the like are conveyed onto the conveying rollers 111, that is, the glass sheets are moved to the glass conveying plane 112 through the conveying rollers 111, after the glass sheets are moved to positions right above the supporting legs 123, the conveying rollers 111 stop conveying, the lifting mechanism 12 jacks up the glass sheets moved to positions right above the supporting legs 123 to a height exceeding the glass conveying plane 112, then the positioning driving members 1311 of the positioning mechanism 13 are started to drive the positioning members 1312 at each position to move to contact with the glass from each side of the glass, so as to position the glass, after the glass is positioned, the lifting mechanism 12 can be started again to lower the supporting legs 123 to enable the glass to contact with the conveying rollers 111 again, so that the glass is continuously conveyed to the transfer platform 31 by the conveying rollers 111, and thus, automatic sheet feeding, automatic positioning and automatic sheet discharging after positioning of the glass to be positioned can be realized, the continuous full-automatic positioning of the glass is realized, the positioning efficiency is effectively improved, and the production efficiency is integrally improved.
Further, in the present embodiment, as shown in fig. 2 and fig. 6, the positioning mechanism 13 includes a plurality of sets of side positioning assemblies 131, the plurality of sets of side positioning assemblies 131 are respectively disposed at four sides of the glass conveying plane 112, and in some embodiments, at least one set of side positioning assemblies 131 is disposed at four sides of the glass conveying plane 112. Further, the side positioning assembly 131 includes a positioning member 1312 and a positioning driving member 1311 in driving connection with the positioning member 1312, the positioning driving member 1311 is mounted on the frame 11, the positioning member 1312 is suspended above the glass conveying plane 112, and the positioning driving member 1311 can drive the positioning members 1312 to approach or depart from each other. When the lifting driving assembly 122 drives the lifting frame 121 to move to extend each supporting foot 123 from the corresponding mounting gap 113, that is, when the glass directly above the supporting foot 123 is jacked up to exceed the glass conveying plane 112, each positioning driving member 1311 drives the corresponding positioning member 1312 to move towards the supporting foot 123, that is, each positioning driving member 1311 drives each positioning member 1312 to approach each other, so that each positioning member 1312 contacts with four sides of the glass, respectively, thereby adjusting the position of the glass supported on the supporting foot 123.
It can be understood that, during the positioning process, the glass is supported by the supporting legs 123 rotatably mounted on the lifting frame 121, the supporting legs 123 can rotate 360 ° relative to the lifting frame 1213, and when the positioning element 1312 contacts the glass, if the position of the glass deviates from the set position, the positioning element 1312 can push the glass to deflect or move, so as to adjust the position of the glass, and move the glass to the correct position. Therefore, the positioning driving member 1311 is only required to be controlled to drive the positioning members 1312 to move to the designated positions, so that the positioning members 1312 are in contact with the glass at the designated positions on the four sides of the glass and slightly clamp the glass, and the positioning of the glass can be realized.
In another embodiment of the present invention, as shown in fig. 3, the mounting frame 115 is further provided with a driving motor 116, a synchronizing rod 117, a plurality of driving wheels 119 and a plurality of driven wheels 118, the synchronizing rod 117 is connected to an output shaft of the driving motor 116, the plurality of driven wheels 118 are sleeved on the end portions of the conveying rollers 111 in a one-to-one correspondence manner, the plurality of driving wheels 119 are sleeved on the synchronizing rod 117 at intervals and are meshed with the driven wheels 118 in a one-to-one correspondence manner, so that the driving motor 116 is started, the driving wheels 119 are communicated with the synchronizing rod 117 to rotate together, and the driven wheels 118 are driven to drive the plurality of conveying rollers 111 to convey glass synchronously.
In another embodiment of the present invention, as shown in fig. 3 to 5, the lifting driving assembly 122 includes a lifting cylinder 124 and a transmission link 125, the lifting cylinder 124 is installed on the base 114, one end of the transmission link 125 is connected to an output shaft of the lifting cylinder 124, the other end is connected to the lifting frame 121, the base 114 is provided with four sleeves 126 perpendicular to the glass conveying plane 112, four guide rods 127 are vertically arranged at four corners of the lifting frame 121, and the four guide rods 127 are inserted into the four sleeves 126 in a one-to-one correspondence manner, so that the lifting frame 121 can move up and down relative to the glass conveying plane 112 under the driving of the lifting cylinder 124. Specifically, in the present embodiment, a plurality of lifting cylinders 124 may be disposed on the base 114 to synchronously drive the lifting frame 121 to move, for example, for the rectangular base 114 and the lifting frame 121, two lifting cylinders 124 may be disposed at two corners of the base 114 along the diagonal direction for connecting with two corners of the lifting frame 121 along the diagonal direction, so as to ensure that the lifting frame 121 can be lifted up or lowered down smoothly.
In another embodiment of the present invention, as shown in fig. 4 and 5, the supporting legs 123 are arranged in a rectangular array, that is, the supporting legs 123 are arranged in a rectangular shape in space, and the supporting legs 123 arranged at intervals between two adjacent conveying rollers 111 form a column of a rectangular array, so that the supporting legs 123 are arranged in a rectangular shape, and thus the glass can be supported more stably and reliably. Of course, in some other embodiments, the supporting legs 123 may be arranged in other shapes, and only need to provide stable and reliable support for the glass.
In another embodiment of the present invention, the supporting foot 123 is a universal rubber wheel, that is, the wheel of the universal wheel is a rubber wheel, which ensures sufficient friction between the surface of the wheel and the glass, so that the glass can be smoothly and flexibly deflected and changed in position and angle by the rotation of the supporting foot 123 when being pushed by the positioning element 1312.
Further, in the present embodiment, as shown in fig. 2 and fig. 5, the sets of side positioning assemblies 131 are respectively disposed on four sides of the rectangular array formed by the supporting legs 123, so as to ensure that when the glass is supported on the supporting legs 123, the positioning members 1312 of the sets of side positioning assemblies 131 approach from the four sides of the glass to contact with the glass, and complete the positioning of the glass after the glass is lightly clamped.
In some embodiments of the present invention, as shown in fig. 2 and 6, the positioning mechanism 13 includes four sets of side positioning members 131, wherein two sets of side positioning members 131 are spaced apart along a first direction (indicated by an arrow F1 in fig. 6), and two sets of side positioning members 131 are spaced apart along a second direction (indicated by an arrow F2 in fig. 6), the second direction being perpendicular to the first direction. The first direction is parallel to the width direction of the support legs 123 arranged in a rectangular array, and the second direction is parallel to the length direction. Thus, for some glass with a relatively small layout size, the glass can be accurately positioned by respectively arranging a group of side positioning assemblies 131 on four sides of the glass.
Alternatively, in other embodiments of the present invention, as shown in fig. 2 and 6, the positioning mechanism 13 includes six sets of side positioning assemblies 131, wherein two sets of side positioning assemblies 131 are spaced apart along a first direction (a direction shown by an arrow F1 in fig. 6), the other two sets of side positioning assemblies 131 are spaced apart along a second direction (a direction shown by an arrow F2 in fig. 6) and are adjacent to one of the two side positioning assemblies 131 along the first direction, and the remaining two sets of side positioning assemblies 131 are spaced apart along the second direction and are adjacent to the other set of the two side positioning assemblies 131 along the first direction, and the second direction is perpendicular to the first direction. The first direction is parallel to the width direction of the support legs 123 arranged in a rectangular array, and the second direction is parallel to the length direction. Thus, for some glass with a relatively large layout size, two sets of side positioning assemblies 131 are respectively arranged on two sides of the glass in the length direction, and the two sets of side positioning assemblies 131 are respectively located at two ends of the glass in the length direction, so that the influence on the positioning accuracy caused by the overlarge length of the glass is avoided.
In another embodiment of the present invention, as shown in fig. 2 and fig. 6, the positioning mechanism 13 further includes a suspension frame 132 installed above the glass conveying plane 112, the suspension frame 132 includes a cross beam 1321 arranged along the first direction and two longitudinal beams 1322 arranged at intervals along the second direction, the two positioning driving members 1311 of the two sets of side positioning assemblies 131 arranged along the first direction are installed at intervals on the cross beam 1321, and the four positioning driving members 1311 of the four sets of side positioning assemblies 131 arranged along the second direction are installed at intervals on the two longitudinal beams 1322 in pairs.
Further, as shown in fig. 6 and 7, the positioning driving member 1311 is a linear driving module, the linear driving modules of the side positioning assemblies 131 in the first direction are disposed in parallel on the cross beam 1321, and the linear driving modules of the side positioning assemblies 131 in the second direction are disposed in parallel on the longitudinal beam 1322. Alternatively, the positioning driver 1311 may be a linear driving cylinder, which is arranged in the same manner as the linear driving module.
In another embodiment of the present invention, as shown in FIG. 7, the positioning member 1312 is a roller member rotatably mounted on the output shaft of the positioning driving member 1311, and the roller axis of the roller member is perpendicular to the glass conveying plane 112. Thus, when the positioning element 1312 pushes the glass to move, the positioning element 1312 can rotate relative to the glass, and the positioning element 1312 is in line contact with the glass, thereby preventing the glass from being damaged in the positioning process.
In another embodiment of the present invention, as shown in fig. 1 and fig. 2, the lower sheet positioning device 10 further includes a plurality of conveyor belts 14 wound around the crane 121, the plurality of conveyor belts 14 and the plurality of support legs 123 are disposed at the same height and respectively located at the installation gaps 113 between the conveying rollers 111, specifically, in this embodiment, the plurality of conveyor belts 14 and the plurality of support legs 123 are disposed at the same height, which means: the belt body surface of the conveying belt 14 is located at the same height as the vertex of the supporting leg 123 toward the glass conveying plane 112. Further, the conveying belt 14 is arranged in parallel with the conveying rollers 111, so that after the positioning of the glass is completed and the member to be positioned 1312 retracts, the conveying belt 14 is started to rotate, the positioned glass can be output along the direction perpendicular to the conveying rollers 111, and the transfer mechanism and the placing frame 20 are arranged along the extending direction of the conveying belt 14, so that the transfer platform 31 can receive the glass conveyed from the conveying belt. So, on the one hand can adjust the direction of delivery of glass, and on the other hand, no longer carry through transfer roller 111 with the mode of rolling after the glass location, but carry through the conveyer belt with belt drive's mode, can effectively avoid the position deviation to appear again in follow-up transportation process after the glass location.
In another embodiment of the present invention, as shown in fig. 1, 8 and 9, the above-mentioned transferring device 30 further includes a fixed bracket 33 and a movable bracket 34, the fixed bracket 33 is disposed between the rack and the placing rack 20, the movable bracket 34 is slidably disposed on the fixed bracket 33, a plurality of transferring belts 311 disposed on the movable bracket 34 at intervals are rotated along the glass output direction of the lower sheet positioning device 10, surfaces of the plurality of transferring belts 311 are located on the same plane and form the transferring platform 31, and the turnover mechanism 32 is mounted at an end of the movable bracket 34 close to the placing rack 20. Specifically, in the present embodiment, the transfer belt 311 is disposed in parallel with the conveying belt, so that the glass output from the conveying belt can be picked up by the transfer belt 311 and transferred continuously along the output direction of the conveying belt.
In another embodiment of the present invention, as shown in fig. 1, 8 and 9, the turnover mechanism 32 includes a turnover arm 321, a vacuum chuck 322 and a turnover motor 323, the turnover arm 321 is rotatably mounted on the movable support 34 and is opposite to the interval gap 312 between the transfer belts 311, the vacuum chuck 322 is mounted on the side of the turnover arm 321 away from the transfer platform 31, and the output end of the turnover motor 323 is connected to the turnover arm 321 to drive the turnover arm 321 to turn over into the interval gap 312 or turn over from the interval gap 312, wherein when the turnover arm 321 is rotated into the interval gap 312, the vacuum chuck 322 is located below the transfer platform 31, and when there is glass on the transfer belt 311, the suction surface of the vacuum chuck 322 is opposite to the glass on the transfer belt 311. When the glass placing rack is used, when no glass exists on the transferring platform 31, the turning motor 323 drives the turning arm 321 and the vacuum chuck 322 to rotate to be located in the gap 312, at the moment, the adsorption surface of the vacuum chuck 322 faces upwards to the transferring platform 31, when the transferring platform 31 is used for receiving the glass and moves to be close to the placing rack 20, the turning motor 323 drives the turning mechanism 32 to turn up from the gap 312, the vacuum chuck 322 adsorbs the glass located on the transferring platform 31, then the turning motor 323 further drives the turning arm 321 to rotate, the turning arm 321 rotates to adjust the angle of the glass relative to the placing rack 20, and until the turning arm 321 rotates to be parallel to the placing plane of the placing rack 20 (at the moment, the glass and the placing plane are the plane where the first supporting frame 221 is located), the glass adsorbed by the vacuum chuck 322 is placed on the placing rack 20.
Further, in this embodiment, as shown in fig. 8 and 9, the turnover mechanism 32 includes two or more turnover arms 321, each turnover arm 321 is provided with at least one vacuum chuck 322, and each turnover arm 321 is spaced and corresponds to a different spacing gap 312 between the transfer belts 311, so that a plurality of suction points are provided for sucking glass, and the turnover placing operation of the glass can be completed more stably and reliably.
In this embodiment, as shown in fig. 8 and fig. 9, the turning mechanism 32 further includes a suction cup driving member 324, the suction cup driving member 324 is mounted on the turning arm 321, the vacuum suction cup 322 is mounted on an output shaft of the suction cup driving member, the output shaft of the suction cup driving member 324 is parallel to the turning arm 321, and the output shaft of the suction cup driving member 324 moves telescopically relative to the turning arm 321 to drive and adjust the position of the vacuum suction cup 322 on the turning arm 321, so that, for glasses with different layout sizes, the vacuum suction cup 322 can be ensured to suck the glass at a proper position by adjusting the position of the vacuum suction cup 322 relative to the turning arm 321. Specifically, in the present embodiment, the suction cup driving member 324 is a linear driving module, or a linear driving cylinder.
In this embodiment, as shown in fig. 1 and fig. 8, the fixed bracket 33 includes two slide rails 331 disposed at intervals in parallel with the glass output direction of the lower positioning device 10, a slide block 341 is disposed at a position of the movable bracket 34 corresponding to each slide rail 331, the slide block 341 is slidably engaged with the corresponding slide rail 331, a transfer driving motor 332 is further installed on the fixed bracket 33, an output shaft of the transfer driving motor 332 is connected to the movable bracket 34 and is configured to drive the movable bracket 34 to slide back and forth along the slide rails 331, so that the transfer platform 31 is linearly moved back and forth between the rack and the placement frame 20.
The operation of the glass sheet unloading device according to the above embodiment of the present invention is briefly described below with reference to the accompanying drawings, and it should be noted that the following description is only used to describe the general operation of the device in use, and does not constitute a unique limitation on the operation of the use process, and the operation of the device in a specific use scenario may be distinguished from the following description. Specifically, in this embodiment, the glass sheet discharging apparatus described above may perform sheet discharging on glass according to the following steps:
s10, starting the conveying rollers 111 to convey the glass to the lower piece of the glass production equipment and conveying the glass along the lower piece direction of the glass;
s20, when the first piece of glass is conveyed to the position right above the supporting feet 123, the conveying rollers 111 are closed, and the lifting driving assembly 122 is started to drive the lifting frame 121 to drive the supporting feet 123 to move upwards;
s30, when the first glass is lifted up above the glass conveying plane 112, the lifting driving assembly 122 is turned off, and each positioning driving member 1311 is started to drive the corresponding positioning member 1312 to move towards the first glass;
s40, when each positioning element 1312 moves to contact with the side edge of the first glass, the positioning driving element 1311 is turned off, the current position of each positioning element 1312 is recorded as the preset position, each positioning driving element 1311 retracts from the preset position, the lifting driving assembly 122 drives the lifting frame 121 to move down and make the first glass contact with the conveying rollers 111, and the conveying rollers 111 convey the positioned first glass away.
S50, after the first piece of glass is positioned, the positioning piece 1312 retracts, the conveying belt 14 is started to convey the positioned first piece of glass to the transfer belt 311, before the first piece of glass is positioned, the turnover motor 323 drives the turnover ratio to rotate into the interval gap 312 between the transfer belt 311, the transfer belt 311 is connected with the first piece of glass, the transfer drive motor 332 drives the movable support 34 to move towards the placing frame 20, the drive motor stops driving after the first piece of glass is moved to be close to the placing frame 20, the turnover motor 323 drives the turnover arm 321 to be turned up from the interval gap 312, the vacuum suction cup 322 sucks the first piece of glass while the turnover is carried out, the turnover motor 323 continues to drive the turnover arm 321 to continue to rotate together with the first piece of glass, and the first piece of glass is placed on the placing frame 20 after the first piece of glass is parallel to the first support frame 221;
s60, the lower sheet positioning device 10 continuously presents the glass to be subjected to the lower sheet from the glass production equipment, positions the glass, and the transfer device 30 continuously transfers the glass regulated and positioned by the lower sheet positioning device 10. When step S40 is executed, the positioning driving element 1311 moves to the recorded preset position, and at this time, the position of the current glass is completely the same as the position of the first glass, so that the position of the current glass is adjusted, and the glass always keeps the same posture for output.
In the present embodiment, the positioning mechanism 13 positions the other glass to be positioned in the following according to the position of the first glass, so that the glasses of the same production or processing batch, which are output from the front and back, are output in a uniform posture. Of course, in some other embodiments, before the sheet-positioning device 10 starts to operate, the distance that the positioning driving member 1311 drives the positioning members 1312 to move may be set, so that each positioning member 1312 contacts with four sides of the glass after moving a predetermined distance and lightly grips the glass, so that the glass is positioned by moving the positioning member 1312 by the predetermined distance. The specific positioning process and manner of the glass is not limited herein.
The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the utility model, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. A glass sheet feeding apparatus, comprising:
the lower sheet positioning device comprises a rack and a positioning mechanism, wherein a glass conveying plane for receiving a lower sheet of glass is arranged on the rack, and the positioning mechanism is arranged on the rack and used for positioning the glass conveyed to the glass conveying plane so that the glass is output from the lower sheet positioning device in the same posture;
the placing frames are arranged beside the rack at intervals along the glass output direction of the lower piece positioning device and used for placing the glass output from the lower piece positioning device;
the transfer device is arranged between the rack and the placing rack and comprises a transfer platform and a turnover mechanism, wherein the transfer platform can move in a reciprocating linear mode between the rack and the placing rack to be connected with and transfer the glass output by the lower sheet positioning device to be close to the placing rack, the turnover mechanism is rotatably arranged on the side portion of the transfer platform and used for conveying the glass to the transfer platform, and the glass is overturned to be parallel to the placing plane of the placing rack and then is placed to the placing rack.
2. The glass run apparatus of claim 1, wherein: a plurality of conveying rollers are arranged on the rack at intervals along the direction of the lower glass sheet, and the surfaces of the conveying rollers are positioned on the same plane and form a glass conveying plane;
the lower sheet positioning device also comprises a lifting mechanism, the lifting mechanism comprises a lifting frame, a lifting driving assembly and a plurality of supporting legs for supporting the glass, the lifting frame is movably arranged on the rack, each supporting leg is rotatably arranged on the lifting frame in an equal height manner and is positioned in an installation gap between the conveying rollers, and the lifting driving assembly is in driving connection with the lifting frame so as to drive the lifting frame to move up and down relative to the glass conveying plane, so that each supporting leg extends out of or retracts into the corresponding installation gap;
the positioning mechanism comprises a plurality of groups of side positioning assemblies arranged at the four sides of the glass conveying plane, each side positioning assembly comprises a positioning piece and a positioning driving piece in driving connection with the positioning piece, the positioning driving pieces are mounted on the rack, and the positioning pieces are suspended above the glass conveying plane;
when the lifting driving assembly drives the lifting frame to move to enable the supporting legs to extend out of the corresponding mounting gaps, the positioning driving pieces drive the corresponding positioning pieces to move towards the supporting legs, and therefore the positioning pieces are enabled to contact with and adjust the positions of the glass supported on the supporting legs.
3. The glass run apparatus of claim 2, wherein: the supporting legs are arranged in a rectangular array mode, and the side edge positioning assemblies are arranged on four side edges of the rectangular array formed by the supporting legs respectively.
4. The glass run apparatus of claim 3, wherein: the positioning mechanism comprises six groups of side positioning assemblies, wherein the side positioning assemblies are arranged at intervals along a first direction, the other two groups of side positioning assemblies are arranged at intervals along a second direction and are close to two sides arranged along the first direction, one group of side positioning assemblies are arranged, the rest two groups of side positioning assemblies are arranged at intervals along the second direction and are close to two sides arranged along the first direction, and the other group of side positioning assemblies is arranged in the side positioning assemblies and is vertical to the first direction.
5. The glass run apparatus of claim 2, wherein: the supporting legs are universal rubber wheels.
6. The glass run apparatus of claim 2, wherein: the glass unloading equipment further comprises a plurality of conveying belts wound on the lifting frame, the conveying belts and the supporting legs are arranged at equal heights and are respectively located in installation gaps among the conveying rollers, and the conveying belts are parallel to the conveying rollers and are used for outputting the positioned glass along the direction perpendicular to the conveying rollers.
7. The glass run-down apparatus of any of claims 1-6, wherein: the transfer device further comprises a fixed support and a movable support, the fixed support is arranged between the rack and the placing rack, the movable support is arranged on the fixed support in a sliding mode, the movable support is arranged on the upper edge of the lower sheet positioning device, a plurality of transfer belts are arranged at intervals in a rotating mode in the glass output direction, the surfaces of the transfer belts are located on the same plane and form the transfer platform, and the turnover mechanism is arranged at the end portion, close to the placing rack, of the movable support.
8. The glass sheet descending device of claim 7, wherein: tilting mechanism includes upset arm, vacuum chuck and upset motor, the upset arm rotate install in on the movable support and just to each interval clearance setting between the transportation area, vacuum chuck install in the upset arm deviates from the side of transporting the platform, the output of upset motor with the upset arm links to each other, with the drive the upset arm upset to being located in the interval clearance or following turn up in the interval clearance, wherein, work as the upset arm rotates to being located when in the interval clearance, vacuum chuck is located transport the below of platform.
9. The glass sheet descending device of claim 8, wherein: the turnover mechanism further comprises a sucker driving piece, the sucker driving piece is installed on the turnover arm, the vacuum sucker is installed on an output shaft of the sucker driving piece, the output shaft of the sucker driving piece is parallel to the turnover arm, the output shaft of the sucker driving piece is opposite to the turnover arm, the turnover arm stretches and moves to drive the vacuum sucker to be adjusted in the setting position on the turnover arm.
10. The glass sheet descending device of claim 7, wherein: the fixed bolster is including parallel two slide rails that lower piece positioner's glass output direction interval set up, it corresponds each to remove the support the position department setting of slide rail corresponds and is provided with the slider, slider slip joint in corresponding on the slide rail, still install on the fixed bolster and transport driving motor, transport driving motor's output shaft with it links to each other to remove the support.
CN202120562834.7U 2021-03-18 2021-03-18 Glass unloading equipment Active CN215515785U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN202120562834.7U CN215515785U (en) 2021-03-18 2021-03-18 Glass unloading equipment

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202120562834.7U CN215515785U (en) 2021-03-18 2021-03-18 Glass unloading equipment

Publications (1)

Publication Number Publication Date
CN215515785U true CN215515785U (en) 2022-01-14

Family

ID=79800524

Family Applications (1)

Application Number Title Priority Date Filing Date
CN202120562834.7U Active CN215515785U (en) 2021-03-18 2021-03-18 Glass unloading equipment

Country Status (1)

Country Link
CN (1) CN215515785U (en)

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