CN220708343U - Sunroof glass plastic measuring mechanism - Google Patents
Sunroof glass plastic measuring mechanism Download PDFInfo
- Publication number
- CN220708343U CN220708343U CN202322335794.4U CN202322335794U CN220708343U CN 220708343 U CN220708343 U CN 220708343U CN 202322335794 U CN202322335794 U CN 202322335794U CN 220708343 U CN220708343 U CN 220708343U
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- 239000011521 glass Substances 0.000 title claims abstract description 58
- 230000007246 mechanism Effects 0.000 title claims description 19
- 238000007493 shaping process Methods 0.000 claims abstract description 53
- 230000002146 bilateral effect Effects 0.000 claims abstract description 17
- 238000005259 measurement Methods 0.000 claims abstract description 14
- 230000003993 interaction Effects 0.000 claims abstract description 6
- 239000002699 waste material Substances 0.000 claims description 13
- 238000009826 distribution Methods 0.000 claims description 3
- 238000003825 pressing Methods 0.000 abstract description 32
- 239000005357 flat glass Substances 0.000 abstract description 27
- 238000004519 manufacturing process Methods 0.000 abstract description 11
- 238000000034 method Methods 0.000 abstract description 3
- 230000008569 process Effects 0.000 abstract description 3
- 230000002457 bidirectional effect Effects 0.000 description 13
- XEEYBQQBJWHFJM-UHFFFAOYSA-N Iron Chemical compound [Fe] XEEYBQQBJWHFJM-UHFFFAOYSA-N 0.000 description 4
- 230000005540 biological transmission Effects 0.000 description 3
- 230000009471 action Effects 0.000 description 2
- 230000007547 defect Effects 0.000 description 2
- 229910052742 iron Inorganic materials 0.000 description 2
- 230000001681 protective effect Effects 0.000 description 2
- 229910000831 Steel Inorganic materials 0.000 description 1
- 230000009286 beneficial effect Effects 0.000 description 1
- 238000004140 cleaning Methods 0.000 description 1
- 238000010586 diagram Methods 0.000 description 1
- 230000004048 modification Effects 0.000 description 1
- 238000012986 modification Methods 0.000 description 1
- 230000000737 periodic effect Effects 0.000 description 1
- 238000007747 plating Methods 0.000 description 1
- 239000010959 steel Substances 0.000 description 1
- 230000000007 visual effect Effects 0.000 description 1
- 238000003466 welding Methods 0.000 description 1
Classifications
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02P—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
- Y02P40/00—Technologies relating to the processing of minerals
- Y02P40/50—Glass production, e.g. reusing waste heat during processing or shaping
- Y02P40/57—Improving the yield, e-g- reduction of reject rates
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- Automobile Manufacture Line, Endless Track Vehicle, Trailer (AREA)
Abstract
The utility model relates to the technical field of automobile skylight glass production, in particular to an automobile skylight glass production device which comprises a frame, wherein a man-machine interaction screen is fixedly arranged on one side of the frame, a bottom plate is fixedly arranged above the frame, two bilaterally symmetrical trays are fixedly arranged above the bottom plate, and the automobile skylight glass production device further comprises: the lower shaping device is arranged on the bottom plate; the positioning parts are arranged on the two trays; the upper shaping device is arranged on the fixing frames in a plurality of bilateral symmetry. According to the utility model, the positioning component, the upper shaping device and the lower shaping device are arranged on the frame, so that the window glass with different sizes can be fixed on the frame, automatic surface difference measurement and upper pressing or lower pressing shaping can be carried out on the window glass with different sizes, manual operation is not needed in the whole process, the automation degree is high, the production efficiency can be effectively improved, and the labor intensity of workers is reduced.
Description
Technical Field
The utility model relates to the technical field of automobile skylight glass production, in particular to an automobile skylight glass shaping and measuring mechanism.
Background
In the field of automobile part manufacturing, an automobile skylight is a complex and precise assembly product outside a gearbox and an engine, one or more pieces of glass are assembled at the top of an automobile on the surface, and the internal structure of the automobile skylight is very complex in practice, and the automobile skylight comprises an electronic control unit, a motor, a guy cable, a movement mechanism and other parts, so that the automobile skylight realizes the functions of tilting, sliding, complete opening and the like while bringing visual feeling to drivers and passengers. Therefore, the skylight is different from other parts in terms of function division, and belongs to both appearance parts, interior trim parts and functional parts;
however, the existing automobile skylight glass generally realizes the bonding between glass and an iron piece through a wrapping process, but after the glass is taken out of a high-temperature die, the surface difference of the glass cannot meet the requirements due to the fact that the thermal expansion coefficients of the glass and the iron piece are different, so that the surface difference measurement and the shaping of the produced glass are generally required, the conventional industry practice utilizes the lever principle to carry out manual adjustment, the production efficiency is low, the labor intensity is high, the automation degree is low, and the risk of crushing the glass is easy to exist. In view of the above, we propose a sunroof glass shaping measurement mechanism.
Disclosure of Invention
In order to make up for the defects, the utility model provides an automobile skylight glass shaping and measuring mechanism, which aims to overcome the defects that the prior art provides a conventional industrial method for manually adjusting the glass surface difference by utilizing a lever principle, the adjusting mode is low in production efficiency, high in labor intensity and low in automation degree, and the risk of crushing glass is easy to exist.
The technical scheme of the utility model is as follows:
the utility model provides an sunroof glass plastic measuring mechanism, includes the frame, frame one side fixed mounting has man-machine interaction screen, just frame top fixed mounting has the bottom plate, bottom plate top fixed mounting has two bilateral symmetry's trays, two the tray outside all is provided with the mount of a plurality of symmetry, a plurality of mount bottom all and bottom plate fixed connection still include:
the lower shaping device is arranged on the bottom plate and is used for shaping the lower surface of the automobile skylight glass;
the positioning parts are arranged on the two trays and are used for positioning and fixing during shaping of the automobile skylight glass;
the upper shaping devices are arranged on the fixing frames in a plurality of bilateral symmetry and are used for shaping the upper surface of the automobile skylight glass.
Preferably, the middle part of the bottom plate is provided with a waste discharge groove, the waste discharge groove is arranged between the two trays, a connecting pipe is fixedly arranged at the bottom of the waste discharge groove, a waste collection drawer is arranged below the connecting pipe, and the waste collection drawer is slidably connected to the bottom of the rack.
Preferably, the lower shaping device comprises:
the device comprises two long sliding plates and two short sliding plates, wherein the long sliding plates are symmetrical front and back, the short sliding plates are symmetrical left and right, the long sliding plates and the short sliding plates are arranged at the bottom of a bottom plate in a sliding mode, three first ejection heads which are distributed at equal intervals are arranged on the long sliding plates, each first ejection head is located above the bottom plate, and a first power source for driving the first ejection heads to lift is arranged at the bottom of each first ejection head.
Preferably, two long slide each other keep away from one side all be provided with two bilateral symmetry's long telescopic link, every two bilateral symmetry long telescopic link's flexible end and stiff end respectively with every long slide and bottom plate bottom fixed connection, and every two bilateral symmetry all be provided with the second power supply that the long slide of drive removed between the long telescopic link.
Preferably, two short slide boards are provided with two top heads, each top head two is located above the bottom plate, and each top head two bottom is provided with a third power source for driving the top head two bottom to lift, and two sides of the short slide boards, which are far away from each other, are provided with two short telescopic rods which are symmetrical front and back.
Preferably, the telescopic ends and the fixed ends of the short telescopic rods are respectively and fixedly connected with the bottoms of the short sliding plates and the bottom plate, and a fourth power source for driving the short sliding plates to move is arranged between the short telescopic rods.
Preferably, the upper shaping device comprises:
the device comprises two bilaterally symmetrical crossbearers, wherein the bottoms of the crossbearers are fixedly connected with the upper parts of a plurality of bilaterally symmetrical fixing frames respectively, front driving wheels and rear driving wheels which are longitudinally symmetrical are rotationally connected in the crossbearers, a supporting shaft is fixedly connected between the rear driving wheels, two ends of the supporting shaft are rotationally connected in the two crossbearers respectively, and one end of the supporting shaft is provided with a fifth power source for driving the supporting shaft to rotate.
Preferably, each front driving wheel and each rear driving wheel are respectively provided with a driving chain, the driving chains are connected with each other through the driving chains and transmit power, the upper surfaces of the driving chains are fixedly provided with sliding blocks, the bottoms of the sliding blocks are respectively and slidably connected onto two crossbearers, mounting grooves are fixedly arranged between the sliding blocks, two bilaterally symmetrical movable grooves are formed in the rear sides of the inside of the mounting grooves, five protection covers which are distributed at equal intervals are fixedly arranged in the front sides of the mounting grooves, and pen-type sensors are fixedly arranged in the protection covers.
Preferably, two the rotation is connected with two between the removal groove, the one end of two-way screw is provided with its pivoted sixth power supply of drive, just be provided with on the two-way screw about opposite screw thread, and about equal threaded connection in opposite screw thread department have the movable block, two the movable block respectively sliding connection in two removal inslot, and two the equal fixed mounting of movable block front end has the short mounting panel.
Preferably, two the equal sliding connection of short mounting panel is in the mounting groove, and two short mounting panel bottom all is provided with circular briquetting, two all be provided with the seventh power supply that drives its lift on the circular briquetting, two be provided with long mounting plate between the short mounting panel, long mounting plate fixed mounting is in the mounting groove, just long mounting plate bottom is provided with the rectangular briquetting of three equidistance distribution, every rectangular briquetting top all is provided with the eighth power supply that drives its lift.
Compared with the prior art, the utility model has the beneficial effects that:
according to the utility model, the positioning component, the upper shaping device and the lower shaping device are arranged on the frame, so that the window glass with different sizes can be fixed on the frame, automatic surface difference measurement and upper pressing or lower pressing shaping can be carried out on the window glass with different sizes, manual operation is not needed in the whole process, the automation degree is high, the production efficiency can be effectively improved, the labor intensity of workers can be reduced, and the risk of glass fracturing can be reduced.
Drawings
FIG. 1 is a schematic diagram of the overall structure of the present utility model;
FIG. 2 is a cross-sectional view of a frame of the present utility model;
FIG. 3 is a schematic view of the lower shaping device of the present utility model;
FIG. 4 is a schematic view of a tray structure according to the present utility model;
FIG. 5 is a schematic view of the upper shaping device of the present utility model;
fig. 6 is a cross-sectional view of a mounting groove of the present utility model.
In the figure: 1. a frame; 11. a bottom plate; 12. a connecting pipe; 13. a waste collection drawer; 14. a lower shaping device; 141. a long slide plate; 142. a first plug; 143. a long telescopic rod; 144. a short slide plate; 145. a short telescopic rod; 146. a second plug; 15. a fixing frame;
2. a tray; 21. a first mounting seat; 22. positioning a first cylinder; 23. a second mounting seat; 24. positioning a second cylinder; 25. a corner block; 26. a compacting cylinder; 27. a jacking block; 28. jacking the air cylinder;
3. a shaping device; 31. a cross frame; 32. a front driving wheel; 33. a rear driving wheel; 34. a drive chain; 35. a slide block; 36. a mounting groove; 361. a long mounting plate; 362. a strip pressing block; 363. a short mounting plate; 364. a round pressing block; 365. a bidirectional screw; 37. a protective cover;
4. and a man-machine interaction screen.
Detailed Description
The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.
In the description of the present utility model, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings are merely for convenience in describing the present utility model and simplifying the description, and do not indicate or imply that the apparatus or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model.
Referring to fig. 1-6, the present utility model is described in detail by the following embodiments:
the utility model provides an sunroof glass plastic measuring mechanism, which comprises a frame 1, frame 1 one side fixed mounting has man-machine interaction screen 4, and frame 1 top fixed mounting has bottom plate 11, bottom plate 11 top fixed mounting has two bilateral symmetry's tray 2, two tray 2 outsides all are provided with the mount 15 of a plurality of symmetry, a plurality of mount 15 bottom all and bottom plate 11 fixed connection, the exhaust groove has been seted up at bottom plate 11 middle part, the exhaust groove sets up between two trays 2, and exhaust groove bottom fixed mounting has connecting pipe 12, connecting pipe 12 below is provided with collection waste drawer 13, collection waste drawer 13 sliding connection is in frame 1 bottom.
It should be pointed out that the frame 1 is formed by welding square tubes, the square tubes are annealed after being welded to prevent subsequent deformation, surface baking finish treatment is carried out, the fixing frame 15 is also welded by square tubes with the same size, the positions of the tray 2 and the bottom plate 11 are positioned by using positioning pins, the pins are arranged on the bottom plate 11, holes are formed in the tray 2, one side of each hole is matched with a long round hole on one side of each round hole, the bottom plate 11 is made of a steel plate, the surface is galvanized or chromed, the thickness of a plating layer is 15-20 mu m, the flatness of the bottom plate 11 is 0.5mm, and square tubes are used for supporting below the bottom plate 11 to prevent deformation during shaping.
In this embodiment, through setting up human-computer interaction screen 4, can make things convenient for the staff to control whole plastic measuring mechanism by one key, offer the useless groove in bottom plate 11 middle part simultaneously to clean when glass fracturing, if after the glass fracturing, it can directly discharge to collect in collection useless steamer tray 13 from connecting pipe 12, so that the periodic cleaning glass piece.
Lower shaping device 14, lower shaping device 14 sets up on bottom plate 11 for the plastic of sunroof glass lower surface, lower shaping device 14 includes: the two long sliding plates 141 which are symmetrical front and back and the two short sliding plates 144 which are symmetrical left and right are respectively and fixedly connected with the bottoms of the long sliding plates 141 and the bottom plate 11, three first ejection heads 142 which are distributed at equal intervals are arranged on the two long sliding plates 141, each first ejection head 142 is positioned above the bottom plate 11, a first power source for driving the first ejection heads 142 to lift is arranged at the bottom of each first ejection head 142, two long telescopic rods 143 which are symmetrical left and right are arranged at one side, away from each other, of the two long sliding plates 141, the telescopic ends and the fixed ends of each long telescopic rod 143 are respectively and fixedly connected with the bottoms of the long sliding plates 141 and the bottom plate 11, a second power source for driving the long sliding plates 141 to move is arranged between each two long telescopic rods 143, two second ejection heads 146 are arranged on each short sliding plate 144, each ejection head 146 is positioned above the bottom plate 11, a third power source for driving the ejection heads to lift is arranged at the bottom of each ejection heads 146, two sides, two telescopic rods 145 are respectively arranged at one side, which is far away from each other, and two telescopic rods 145 are respectively connected with the two short telescopic rods 145 which are symmetrical front and the two telescopic rods 145 are arranged between each two short sliding plates and the two telescopic rods which are respectively;
it should be noted that, each first power source is a first servo electric cylinder, each first servo electric cylinder is fixedly installed at the bottom of each long slide 141, and a piston rod of each first servo electric cylinder passes through each long slide 141, extends out above the bottom plate 11, and is fixedly connected with the bottom of each first plug 142; each second power source is a first adjusting cylinder, each first adjusting cylinder is fixedly arranged at the bottom of the bottom plate 11, and a piston rod of each first adjusting cylinder is fixedly connected with the side edge of each long sliding plate 141; each third power source is a second servo electric cylinder, each second servo electric cylinder is fixedly arranged at the bottom of each short slide plate 144, and a piston rod of each second servo electric cylinder penetrates through each short slide plate 144, extends out to the upper part of the bottom plate 11 and is fixedly connected with the bottom of each second plug 146; each fourth power source is a second adjusting cylinder, each second adjusting cylinder is fixedly arranged at the bottom of the bottom plate 11, and a piston rod of each second adjusting cylinder is fixedly connected with the side edge of each short sliding plate 144; sliding grooves are formed in the positions, opposite to the first servo electric cylinder and the second servo electric cylinder, of the base plate 11, and the piston rods of the first servo electric cylinder and the second servo electric cylinder conveniently slide on the base plate 11.
In this embodiment, after the skylight glass is placed on the positioning component, the first adjusting cylinder and the second adjusting cylinder are started according to the size of the skylight glass, at this time, the first adjusting cylinder and the second adjusting cylinder can stably push the first long sliding plate 141 and the second short sliding plate 144 to move away from or close to each other under the telescopic guiding action of the first long telescopic rod 143 and the second short telescopic rod 145 arranged on one side of the first adjusting cylinder and the second adjusting cylinder, so that the first long sliding plate 141 and the second short sliding plate 144 can respectively drive the first top 142 and the second top 146 arranged on the first long sliding plate and the second short sliding plate to move below the skylight glass with different sizes, then, according to the measured glass surface difference, each first servo cylinder and each second servo cylinder can synchronously drive the first top 142 and the second top 146 connected on the side of the first servo cylinder to press and reshape the lower surface of the skylight glass.
The positioning parts are arranged on the two trays 2 and used for positioning and fixing during shaping of the automobile skylight glass.
It should be noted that the positioning component includes: the two symmetrical mounting seats 21 are fixedly mounted on the two trays 2 respectively, one side, close to each other, of each mounting seat 21 is fixedly provided with a positioning cylinder 22, two mounting seats 23 which are symmetrical around are arranged between the two mounting seats 21, two mounting seats 23 which are symmetrical around are fixedly mounted on each tray 2, one side, close to each other, of each two mounting seats 23 is fixedly provided with a positioning cylinder 24, two symmetrical around compressing cylinders 26 are arranged between the two mounting seats 23, each two symmetrical around compressing cylinders 26 are fixedly mounted on each tray 2, a piston rod of each two symmetrical around compressing cylinders 26 is fixedly provided with a turning block 25, one side, close to the center of the bottom plate 11, of each two symmetrical around compressing cylinders 26 is fixedly provided with two jacking cylinders 28, each two jacking cylinders 28 are fixedly mounted on each tray 2, and each jacking block 27 is fixedly mounted on each jacking cylinder.
In this embodiment, after the window glass is placed on the four lifting blocks 27, the four lifting cylinders 28 are started to push the four lifting blocks 27, at this time, the four lifting blocks 27 jack up the placed window glass, then the four positioning cylinders two 24 and the two positioning cylinders one 22 are started, and the jacked window glass can be adjusted to a centered position by pushing the piston rods of the four positioning cylinders two 24 and the piston rods of the two positioning cylinders one 22 which are symmetrical left and right, so that the surface difference of the window glass can be accurately measured by using the five pen sensors on the upper shaping device 3, however, when the lower shaping device 14 is used for shaping the lower surface of the window glass in an upward manner, the four pressing cylinders 26 can be started to push the four corner blocks 25 to descend, and the four corner blocks 25 are used for positioning and fixing the pressed window glass, so that the stability of the pressed window glass in the upward shaping process is ensured, and the risk of fracturing the window glass is reduced.
The shaping device 3, the shaping device 3 sets up on a plurality of bilateral symmetry mount 15 for the plastic of sunroof glass upper surface, the shaping device 3 includes: the two left and right symmetric cross frames 31, the bottoms of the two cross frames 31 are respectively and fixedly connected with the upper parts of a plurality of left and right symmetric fixing frames 15, the front driving wheel 32 and the rear driving wheel 33 which are symmetrical front and back are respectively and rotationally connected in the two cross frames 31, a supporting shaft is fixedly connected between the two rear driving wheels 33, two ends of the supporting shaft are respectively and rotationally connected in the two cross frames 31, one end of the supporting shaft is provided with a fifth power source for driving the supporting shaft to rotate, a driving chain 34 is arranged between each front driving wheel 32 and each rear driving wheel 33, the driving chains 34 are connected and transmit power, the upper surfaces of the two driving chains 34 are fixedly provided with sliding blocks 35, the bottoms of the two sliding blocks 35 are respectively and rotationally connected on the two cross frames 31, a mounting groove 36 is fixedly arranged between the two sliding blocks 35, two left and right symmetric moving grooves are formed in the rear side of the inside of the mounting groove 36, five equally-spaced protection covers 37 are fixedly arranged on the front side of the mounting groove 36, pen-type sensors are fixedly arranged in each protection cover 37, a bidirectional screw rod 365 is rotatably connected between the two moving grooves, a sixth power source for driving the bidirectional screw rod 365 to rotate is arranged at one end of the bidirectional screw rod 365, left and right opposite threads are arranged on the bidirectional screw rod 365, moving blocks are connected at the left and right opposite threads in a threaded manner, the two moving blocks are respectively and slidably connected in the two moving grooves, short mounting plates 363 are fixedly arranged at the front ends of the two moving blocks, the two short mounting plates 363 are slidably connected in the mounting groove 36, circular pressing blocks 364 are arranged at the bottoms of the two short mounting plates 363, a seventh power source for driving the two circular pressing blocks 364 to lift is arranged on the two circular pressing blocks 364, a long mounting plate 361 is arranged between the two short mounting plates 363, the long mounting plates 361 are fixedly arranged in the mounting groove 36, and the bottom of the long mounting plate 361 is provided with three equidistant strip pressing blocks 362, and an eighth power source for driving the strip pressing blocks 362 to lift is arranged above each strip pressing block 362.
It should be further noted that the fifth power source is a horizontal driving motor, the horizontal driving motor is fixedly installed on one side of one of the cross frames 31, and an output shaft of the horizontal driving motor is fixedly connected with one end of the supporting shaft; the sixth power source is a servo motor which is fixedly arranged on the side wall of one of the movable grooves, and an output shaft of the servo motor is fixedly connected with one end of the bidirectional screw 365; each seventh power source is a third servo electric cylinder, each third servo electric cylinder is fixedly arranged on each short mounting plate 363, and a piston rod of each third servo electric cylinder penetrates through each short mounting plate 363 and extends out to the lower part of each short mounting plate 363 and is fixedly connected with the upper part of each circular pressing block 364; each eighth power source is a fourth servo electric cylinder, each fourth servo electric cylinder is fixedly arranged on the long mounting plate 361, and a piston rod of each third servo electric cylinder penetrates through the long mounting plate 361, extends out to the lower side of the long mounting plate 361 and is fixedly connected with the upper side of each long pressing block 362; each of the long-strip pressing pieces 362 is capable of swinging but not more flexible, the left and right ends swing up and down by not more than ±25°, and the long-strip pressing pieces 362 are arranged in the left and right direction.
In this embodiment, after the window glass is placed on the positioning component by the manipulator, the horizontal driving motor is started to drive the supporting shaft to rotate, and because the supporting shaft is connected with the two rear driving wheels 33, when the supporting shaft rotates, the two front driving wheels 32 can synchronously rotate, and because a driving chain 34 is arranged between each front driving wheel 32 and each rear driving wheel 33 and is connected with each other through the driving chain 34 and transmits power, when the two front driving wheels 32 rotate, the two driving chains 34 synchronously drive the mounting groove 36 connected with the two sliding blocks 35 to move back and forth above the window glass, at this time, five pen-type sensors mounted on the mounting groove 36 can measure the positioned window glass, and each pen-type sensor is provided with a protective cover 37, so that the pen-type sensors can be prevented from being damaged when the glass is broken by pressing; after the face difference measurement is carried out on the window glass of the five pen-type sensors, the servo motor can be started to drive the bidirectional screw rod 365 to rotate according to the width of the window glass, and as the bidirectional screw rod 365 is provided with left and right opposite threads, the left and right opposite threads are respectively in threaded connection with the two moving blocks, when the bidirectional screw rod 365 rotates, the two moving blocks can be driven to move away from or close to each other, so that the two moving blocks can indirectly drive the round pressing blocks 364 on the two short mounting plates 363 to move to two sides above the glass with different widths, the transmission chain 34 is utilized to drive the two round pressing blocks 364 and the three strip pressing blocks 362 to move to the measured face difference, and then, each servo motor cylinder three and each servo motor cylinder four are started to respectively push each strip pressing block 362 and each round pressing block 364 to descend, and each strip pressing block 362 and each round pressing block 364 can automatically press and shape the surface above the glass.
When the vehicle window glass lifting device is specifically used, firstly, vehicle window glass is placed on four lifting blocks 27 through a mechanical arm, then, four lifting cylinders 28 are started to push the four lifting blocks 27, at the moment, the four lifting blocks 27 lift the placed vehicle window glass, then, four positioning cylinders II 24 and two positioning cylinders I22 are started, and the lifted vehicle window glass can be adjusted to a centered position by pushing piston rods of the four positioning cylinders II 24 which are symmetrical front and back and piston rods of the two positioning cylinders I22 which are symmetrical left and right;
secondly, a horizontal driving motor is started to drive a supporting shaft to rotate, and because the supporting shaft is connected with two rear driving wheels 33, when the supporting shaft rotates, the two front driving wheels 32 can synchronously rotate, and because a driving chain 34 is arranged between each front driving wheel 32 and each rear driving wheel 33 and is connected with each other through the driving chain 34 and transmits power, when the two front driving wheels 32 rotate, the two driving chains 34 synchronously drive a mounting groove 36 connected with two sliding blocks 35 to move forwards and backwards above the window glass, and at the moment, five pen-type sensors arranged on the mounting groove 36 can measure the positioned window glass;
after the surface difference of the window glass is measured, a servo motor is started to drive a bidirectional screw rod 365 to rotate according to the condition of the surface difference of the glass, and as the bidirectional screw rod 365 is provided with left and right opposite threads, the left and right opposite threads are respectively in threaded connection with two moving blocks, when the bidirectional screw rod 365 rotates, the bidirectional screw rod 365 can drive the two moving blocks to move away from or close to each other, so that the two moving blocks can indirectly drive round pressing blocks 364 on two short mounting plates 363 to move to two sides above the glass with different widths, and then the two round pressing blocks 364 and three round pressing blocks 362 can be moved to the measured surface difference by utilizing the transmission of a transmission chain 34, and then each servo motor cylinder III and each servo motor cylinder IV are started to respectively push each round pressing block 364 to descend, and each round pressing block 362 and each round pressing block 364 can automatically press and shape the surface above the glass;
or the first adjusting cylinder and the second adjusting cylinder can be started, at this time, the first adjusting cylinder and the second adjusting cylinder can stably push the two long sliding plates 141 and the two short sliding plates 144 to move away from or close to each other under the telescopic guiding action of the long telescopic rod 143 and the short telescopic rod 145 arranged at one side of the first adjusting cylinder and the second adjusting cylinder, so that the two long sliding plates 141 and the two short sliding plates 144 can respectively drive the first plug 142 and the second plug 146 arranged on the first sliding plates and move to the lower parts of skylight glass with different sizes, then, each first servo cylinder and each second servo cylinder are started, at this time, each first servo cylinder and each second servo cylinder synchronously drive the first plug 142 and the second plug 146 connected on one side of the first servo cylinder and the second servo cylinder can automatically press and reshape the lower surface of the skylight glass, manual operation reshaping is not needed, the degree of automation is higher, the production efficiency can be effectively improved, and the labor intensity of workers can be reduced
However, when the lower shaping device 14 is used to shape the lower surface of the window glass, at this time, the four pressing cylinders 26 can be started to push the four corner blocks 25 to descend, and the four corner blocks 25 are used to fix the pressed window glass, so that the stability of the pressed window glass during shaping is ensured, and the risk of glass fracturing is reduced.
The foregoing has shown and described the basic principles, principal features and advantages of the utility model. It will be understood by those skilled in the art that the present utility model is not limited to the above-described embodiments, and that the above-described embodiments and descriptions are only preferred embodiments of the present utility model, and are not intended to limit the utility model, and that various changes and modifications may be made therein without departing from the spirit and scope of the utility model as claimed. The scope of the utility model is defined by the appended claims and equivalents thereof.
Claims (10)
1. The utility model provides an sunroof glass plastic measuring mechanism, includes frame (1), frame (1) one side fixed mounting has man-machine interaction screen (4), just frame (1) top fixed mounting has bottom plate (11), bottom plate (11) top fixed mounting has two bilateral symmetry's tray (2), two the tray (2) outside all is provided with mount (15) of a plurality of symmetry, a plurality of mount (15) bottom all and bottom plate (11) fixed connection, its characterized in that still includes:
the lower shaping device (14) is arranged on the bottom plate (11) and is used for shaping the lower surface of the automobile skylight glass;
the positioning parts are arranged on the two trays (2) and are used for positioning and fixing during shaping of the automobile skylight glass;
the upper shaping device (3) is arranged on the fixing frames (15) in a plurality of bilateral symmetry modes and is used for shaping the upper surface of the automobile skylight glass.
2. The sunroof glass shaping measurement mechanism according to claim 1, wherein: waste discharge grooves are formed in the middle of the bottom plate (11), the waste discharge grooves are formed between the two trays (2), connecting pipes (12) are fixedly arranged at the bottoms of the waste discharge grooves, waste collection drawers (13) are arranged below the connecting pipes (12), and the waste collection drawers (13) are slidably connected to the bottoms of the frames (1).
3. The sunroof glass shaping measurement mechanism according to claim 1, wherein: the lower shaping device (14) comprises:
two long slide (141) of fore-and-aft symmetry and two bilateral symmetry's short slide (144), two long slide (141) and two short slide (144) all slide and set up in bottom plate (11) bottom, and two all be provided with three equidistance on long slide (141) and distribute first (142) of top, every first (142) of top all is located bottom plate (11) top, and every first (142) bottom of top all is provided with the first power supply that drives its lift.
4. The sunroof glass shaping measurement mechanism according to claim 3, wherein: two long slide (141) each other keep away from one side all be provided with two bilateral symmetry's long telescopic link (143), every two bilateral symmetry the flexible end and the stiff end of long telescopic link (143) respectively with every long slide (141) and bottom plate (11) bottom fixed connection, and every two bilateral symmetry all be provided with the second power supply that drives long slide (141) removal between long telescopic link (143).
5. The sunroof glass shaping measurement mechanism according to claim 3, wherein: two short slide (144) are gone up and all are provided with top two (146), every top two (146) all are located bottom plate (11) top, and every top two (146) bottom all is provided with the third power supply that drives its lift, two one side that short slide (144) kept away from each other all is provided with two fore-and-aft symmetry's short telescopic link (145).
6. The sunroof glass shaping measurement mechanism according to claim 5, wherein: the telescopic ends and the fixed ends of the short telescopic rods (145) are respectively and fixedly connected with the bottoms of the short sliding plates (144) and the bottom plate (11), and fourth power sources for driving the short sliding plates (144) to move are arranged between the short telescopic rods (145) in every two front-back symmetry.
7. The sunroof glass shaping measurement mechanism according to claim 1, wherein: the upper shaping device (3) comprises:
two bilateral symmetry crossbearers (31), two crossbearer (31) bottom respectively with a plurality of bilateral symmetry mount (15) top fixed connection, and two all rotate in crossbearer (31) and be connected with front drive wheel (32) and back drive wheel (33) of fore-and-aft symmetry, two fixedly connected with back shaft between back drive wheel (33), the both ends of back shaft are rotated respectively and are connected in two crossbearers (31), just the one end of back shaft is provided with its pivoted fifth power supply of drive.
8. The sunroof glass shaping measurement mechanism according to claim 7, wherein: every all be provided with drive chain (34) between front drive wheel (32) and rear drive wheel (33), and all connect and transmit power through drive chain (34) between it, two equal fixed mounting of drive chain (34) upper surface has slider (35), two slider (35) bottom sliding connection respectively on two crossbearers (31), and two fixed mounting has mounting groove (36) between slider (35), two bilateral symmetry's removal groove has been seted up to the inside rear side of mounting groove (36), just five equidistant protection casing (37) of distribution are installed to mounting groove (36) front side, every equal fixed mounting has a pen-type sensor in protection casing (37).
9. The sunroof glass shaping measurement mechanism according to claim 8, wherein: two move and be connected with bi-directional screw (365) between the groove, the one end of bi-directional screw (365) is provided with its pivoted sixth power supply of drive, just be provided with on bi-directional screw (365) about opposite screw thread, and about equal threaded connection in opposite screw thread department have the movable block, two movable block sliding connection respectively in two movable grooves, and two equal fixed mounting of movable block front end has short mounting panel (363).
10. The sunroof glass shaping measurement mechanism according to claim 9, wherein: two short mounting panel (363) all sliding connection is in mounting groove (36), and two short mounting panel (363) bottom all is provided with circular briquetting (364), two all be provided with the seventh power supply that drives its lift on circular briquetting (364), two be provided with between short mounting panel (363) long mounting panel (361), long mounting panel (361) fixed mounting is in mounting groove (36), just long mounting panel (361) bottom is provided with rectangular briquetting (362) of three equidistance distribution, every rectangular briquetting (362) top all is provided with the eighth power supply that drives its lift.
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CN202322335794.4U CN220708343U (en) | 2023-08-29 | 2023-08-29 | Sunroof glass plastic measuring mechanism |
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CN202322335794.4U CN220708343U (en) | 2023-08-29 | 2023-08-29 | Sunroof glass plastic measuring mechanism |
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CN220708343U true CN220708343U (en) | 2024-04-02 |
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CN202322335794.4U Active CN220708343U (en) | 2023-08-29 | 2023-08-29 | Sunroof glass plastic measuring mechanism |
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