CN113213165B - Supporting device for vacuum pumping transmission of ultra-white glass at initial pressure and implementation method thereof - Google Patents

Abstract

The invention discloses a supporting device for vacuum pumping transmission of ultra-white glass and an implementation method thereof, wherein the supporting device comprises a transmission base and a supporting component, an ultra-white glass workpiece is placed on a processing backing plate, a vertical spring is compressed downwards, so that the lower surface of the glass workpiece can be attached to the surface of a conveying belt, meanwhile, the gravity of the ultra-white glass workpiece is transferred to the position of the supporting spring, the supporting spring is pressed downwards, so that surface grains of the conveying belt are in mutual inserting contact with a driving roller, the driving roller drives the conveying belt to rotate, the conveying belt drives the ultra-white glass workpiece to be conveyed forwards, and when the weight of the workpiece is insufficient, a counterweight can be added on the surface of the workpiece to realize the conveying effect.

Description

Supporting device for vacuum pumping transmission of ultra-white glass at initial pressure and implementation method thereof

Technical Field

The invention relates to the technical field of ultra-white glass processing, in particular to a supporting device for ultra-white glass primary pressure vacuumizing transmission and an implementation method thereof.

Background

The ultra-white glass is ultra-transparent low-iron glass, also called low-iron glass and high-transparency glass. The glass is a novel high-grade glass variety with high quality and multifunction, the light transmittance can reach more than 91.5%, the glass is characterized by crystal clear, high-grade and elegant, the crystal prince is called as glass family, the ultra-white glass has all machinability of high-quality float glass, the excellent physical, mechanical and optical properties are achieved, various deep processings can be carried out like other high-quality float glass, the ultra-white glass has wide application space and bright market prospect due to the unprecedented excellent quality and product properties, the ultra-white glass generally needs to be subjected to primary vacuum pumping operation in the processing procedure of automobile glass, the primary vacuum pumping is mainly used for removing air between two pieces of glass and PVB films, the glass and PVB films are primarily bonded, the glass is prepared for final forming of a glass high-pressure kettle, the laminated glass after the glass is sleeved with a ferrule in the process of vacuum pumping, the laminated glass is then fixed on a supporting mechanism for glass primary vacuum pumping transmission, and then the glass supporting mechanism enters the vacuum pumping device together, the glass is subjected to the vacuum pumping device, the vacuum pumping operation is carried out along with the vacuum carrier, the vacuum pumping operation is carried out in the vacuum carrier or the vacuum carrier is carried out according to the actual vacuum carrying process, and the size is not suitable for the actual vacuum carrying of the workpiece, and the workpiece cannot be carried out according to the actual vacuum carrying process, and the actual vacuum carrying process is carried by the size is not suitable for carrying the actual vacuum carrier or carrying the vacuum carrier.

Disclosure of Invention

The invention aims to provide a supporting device for carrying out vacuum pumping transmission on ultra-white glass and an implementation method thereof, the device can carry out actual adjustment on an adjusting bolt group according to the weight of an actual workpiece and the actual efficiency of the actual vacuum pumping operation on the initial pressure, control and adjust the length of an actual extending adjusting sleeve of an inner tube, the ultra-white glass workpiece is placed on a processing backing plate, the lower surface of the glass workpiece can be attached to the surface of a conveying belt by downwards compressing a vertical spring, meanwhile, the gravity of the ultra-white glass workpiece is transferred to a supporting spring, the supporting spring is pressed down, the surface texture of the conveying belt is in mutual embedding contact with a driving roller, the driving roller drives the conveying belt to rotate in an auxiliary way, and when the weight of the workpiece is insufficient, a counterweight can be added on the surface of the workpiece to realize the conveying effect, so that the problem in the background technology is solved.

In order to achieve the above purpose, the present invention provides the following technical solutions:

the supporting device for the vacuum pumping transmission of the ultra-white glass at the initial pressure comprises a transmission base and a supporting component, wherein the supporting component is installed at the upper end of the transmission base.

The transmission base comprises an outer frame, fixing bolt holes, a motor clamping groove, a transmission motor, a driving gear, a gear caulking groove, an auxiliary gear, a transmission gear, a driving roller, a transmission shaft, a transmission roller and a torsion spring, wherein the fixing bolt holes are formed in the outer frame, the motor clamping groove is formed in the outer sides of the two ends of the outer frame, the transmission motor is installed in the motor clamping groove, the driving gear is installed on the inner side of the outer frame, the gear caulking groove is formed in the driving gear, the auxiliary gear is installed on the side face of the driving gear, the transmission gear is installed on the side face of the auxiliary gear, the driving roller is installed in the gear caulking groove, the transmission shaft is arranged between the transmission gears, the transmission roller is installed on the transmission shaft, and the torsion spring is arranged on the outer sides of the transmission shafts at the two ends of the transmission roller.

Preferably, the supporting component comprises a mounting base plate, guardrail plates, mounting bolts, vertical sliding grooves, supporting springs, conveying shafts, conveying belts and processing base plates, wherein the guardrail plates are arranged at the upper ends of the inner sides of the mounting base plate, the mounting bolts are arranged on the mounting base plate at the front ends of the guardrail plates, the vertical sliding grooves are respectively arranged at the left end and the right end of the front ends of the guardrail plates, the supporting springs are arranged at the bottom ends of the inner sides of the vertical sliding grooves, the conveying shafts are arranged at the upper ends of the supporting springs, the conveying belts are arranged on the conveying shafts, and the processing base plates are arranged at the tail ends of the conveying shafts.

Preferably, the processing backing plate includes the mainboard body, perpendicular movable groove, perpendicular spring, adjusting sleeve, adjusts inner tube, adjusting bolt group, silica gel backing plate and pivot interface, both ends side is equipped with the pivot interface respectively about the mainboard body, the inboard of the mainboard body is equipped with perpendicular movable groove, the inside bottom center department of perpendicular movable groove is equipped with perpendicular spring, perpendicular spring's upside is equipped with adjusting sleeve, adjusting sleeve's internally mounted adjusts the inner tube, adjusting sleeve's top installation silica gel backing plate, adjusting sleeve's side is equipped with adjusting bolt group.

Preferably, the tail end of the adjusting bolt group penetrates through the adjusting sleeve and is embedded in the vertical tooth groove of the adjusting inner tube.

Preferably, the mounting bolts on the mounting bottom plate penetrate through the mounting bottom plate and are nested in the fixing bolt holes.

Preferably, the surface of the conveying belt is provided with embedded lines, and the embedded lines are embedded and connected with the surface of the driving roller.

The invention provides another technical scheme that: the implementation method of the support device for the vacuum transmission of the ultra-white glass primary pressure comprises the following steps:

step one: according to the weight of an actual ultra-white glass workpiece, adjusting an adjusting bolt group in the vertical movable groove, and adjusting the actual length of the inner pipe extending out of the adjusting sleeve;

step two: placing the ultra-white glass workpiece on a processing backing plate of a supporting component, and pressing down the silica gel backing plate and a vertical spring at the lower side by utilizing the actual weight of the ultra-white glass workpiece to enable the lower bottom surface of the ultra-white glass workpiece to be attached to the surface of a conveying belt;

step three: starting a transmission motor in the transmission base to enable the transmission motor to drive the driving gear to rotate, wherein the driving gear drives the transmission gear to rotate through the auxiliary gear, and meanwhile, the driving gear and the transmission gear respectively drive the driving roller and the transmission roller to rotate in the same direction;

step four: the weight of the ultra-white glass workpiece is transferred to the supporting spring, the supporting spring is pressed down, and meanwhile, the embedded grains on the surface of the conveying belt are connected with the grains between the driving roller in an embedded mode, so that the driving roller drives the conveying belt to rotate, and the conveying belt drives the ultra-white glass workpiece to be conveyed forwards.

Compared with the prior art, the invention has the beneficial effects that:

according to the supporting device for the initial-pressure vacuumizing transmission of the ultra-white glass and the implementation method of the supporting device, the ultra-white glass workpiece is placed on the processing backing plate, the vertical springs are compressed downwards, so that the lower surface of the glass workpiece can be attached to the surface of the conveying belt, meanwhile, the gravity of the ultra-white glass workpiece is transferred to the supporting springs, the supporting springs are pressed downwards, so that surface grains of the conveying belt are in mutual embedding contact with the driving roller, the driving roller drives the conveying belt to rotate in an auxiliary mode, the conveying belt drives the ultra-white glass workpiece to convey forwards, when the weight of the workpiece is insufficient, a counterweight can be added to the surface of the workpiece to achieve the conveying effect, and shutdown vacuumizing operation or vacuumizing operation while conveying operation are performed according to the actual size of the ultra-white glass workpiece so as to adapt to the processing operation of the glass workpiece with different sizes.

Drawings

FIG. 1 is a schematic diagram of the structure of the present invention;

FIG. 2 is a schematic top view of the transmission base of the present invention;

FIG. 3 is a schematic side view in partial cross-section of a transmission mount of the present invention;

FIG. 4 is a schematic view of a support assembly according to the present invention;

FIG. 5 is a schematic top view of the support assembly of the present invention;

FIG. 6 is a schematic side view in partial cross-section of a tooling pallet of the present invention;

fig. 7 is a schematic view of the external partial structure of the working shim plate of the present invention.

In the figure: 1. a transmission base; 101. an outer frame; 102. a fixing bolt hole; 103. a motor clamping groove; 104. a drive motor; 105. a drive gear; 106. a gear caulking groove; 107. an auxiliary gear; 108. a transmission gear; 109. a drive roller; 1010. a transmission shaft; 1011. a driving roller; 1012. a torsion spring; 2. a support assembly; 21. a mounting base plate; 22. a guardrail plate; 23. installing a bolt; 24. a vertical chute; 25. a support spring; 26. a conveying shaft; 27. a conveyor belt; 28. processing a backing plate; 281. a main board body; 282. a vertical movable groove; 283. a vertical spring; 284. adjusting the sleeve; 285. adjusting the inner tube; 286. an adjusting bolt group; 287. a silica gel backing plate; 288. a rotating shaft interface.

Detailed Description

The following description of the embodiments of the present invention 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 invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1, a supporting device for vacuum pumping transmission of ultra-white glass at initial pressure comprises a transmission base 1 and a supporting component 2, wherein the supporting component 2 is arranged at the upper end of the transmission base 1.

Referring to fig. 2-3, the transmission base 1 includes an outer frame 101, a fixing bolt hole 102, a motor clamping groove 103, a transmission motor 104, a driving gear 105, a gear caulking groove 106, an auxiliary gear 107, a transmission gear 108, a driving roller 109, a transmission shaft 1010, a transmission roller 1011 and a torsion spring 1012, the outer frame 101 is provided with the fixing bolt hole 102, the outer sides of two ends of the outer frame 101 are provided with the motor clamping groove 103, the transmission motor 104 is installed in the motor clamping groove 103, the inner side of the outer frame 101, which is positioned at the transmission motor 104, is provided with the driving gear 105, the driving gear 105 is provided with the gear caulking groove 106, the side of the driving gear 105 is provided with the auxiliary gear 107, the side of the auxiliary gear 107 is provided with the transmission gear 108, the transmission roller 109 is installed in the gear caulking groove 106, the transmission shaft 1010 is arranged between the transmission gears 108, the transmission roller 1011 is installed on the transmission shaft 1010, and the outer sides of the transmission shaft 1010 at two ends of the transmission roller 1011 are provided with the torsion spring 1012.

Referring to fig. 4-5, the support assembly 2 includes a mounting base plate 21, a guardrail plate 22, mounting bolts 23, vertical sliding grooves 24, a supporting spring 25, a conveying shaft 26, a conveying belt 27 and a processing backing plate 28, wherein the guardrail plate 22 is arranged at the upper end of the inner side of the mounting base plate 21, the mounting bolts 23 are arranged on the mounting base plate 21 at the front end of the guardrail plate 22, the mounting bolts 23 on the mounting base plate 21 penetrate through the mounting base plate 21 and are nested in fixing bolt holes 102, the vertical sliding grooves 24 are respectively arranged at the left end and the right end of the front surface of the guardrail plate 22, the supporting spring 25 is arranged at the bottom end of the inner side of the vertical sliding grooves 24, the conveying shaft 26 is arranged at the upper end of the supporting spring 25, the conveying belt 27 is arranged on the conveying shaft 26, the surface of the conveying belt 27 is provided with embedded lines, the embedded lines are connected with the surface of the driving roller 109 in an embedded manner, and the processing backing plate 28 is arranged at the tail end of the conveying shaft 26.

Referring to fig. 6-7, the processing pad 28 includes a main board body 281, a vertical movable slot 282, a vertical spring 283, an adjusting sleeve 284, an adjusting inner tube 285, an adjusting bolt group 286, a silica gel pad 287 and a rotating shaft interface 288, wherein the rotating shaft interface 288 is respectively disposed on the left and right end sides of the main board body 281, the vertical movable slot 282 is disposed on the inner side of the main board body 281, the vertical spring 283 is disposed at the center of the inner bottom end of the vertical movable slot 282, the adjusting sleeve 284 is disposed on the upper side of the vertical spring 283, the adjusting inner tube 285 is mounted in the adjusting sleeve 284, the silica gel pad 287 is mounted on the top of the adjusting inner tube 285, the adjusting bolt group 286 is disposed on the side of the adjusting sleeve 284, and the end of the adjusting bolt group 286 penetrates through the adjusting sleeve 284 and is inserted into the vertical tooth slot of the adjusting inner tube 285.

In order to better show the implementation flow of the support device for the ultra-white glass initial pressure vacuumizing transmission, the embodiment now provides an implementation method of the support device for the ultra-white glass initial pressure vacuumizing transmission, which comprises the following steps:

step one: according to the weight of the actual ultra-white glass workpiece, an adjusting bolt group 286 in the vertical movable groove 282 is adjusted, and the actual length of the adjusting inner pipe 285 extending out of the adjusting sleeve 284 is adjusted;

step two: placing the ultra-white glass workpiece on the processing backing plate 28 of the supporting component 2, and pressing down the silica gel backing plate 287 and the vertical springs 283 on the lower side by utilizing the actual weight of the ultra-white glass workpiece, so that the lower bottom surface of the ultra-white glass workpiece is attached to the surface of the conveying belt 27;

step three: starting a transmission motor 104 in the transmission base 1, so that the transmission motor 104 drives a driving gear 105 to rotate, the driving gear 105 drives a transmission gear 108 to rotate through an auxiliary gear 107, and simultaneously, the driving gear 105 and the transmission gear 108 respectively drive a driving roller 109 and a transmission roller 1011 to rotate in the same direction;

step four: the weight of the ultra-white glass workpiece is transferred to the supporting spring 25, the supporting spring 25 is pressed down, and meanwhile, the embedded grains on the surface of the conveying belt 27 are connected with the grains between the driving roller 109 in an embedded mode, so that the driving roller 109 drives the conveying belt 27 to rotate, and the conveying belt 27 drives the ultra-white glass workpiece to be conveyed forwards.

The working principle of the invention is as follows: the invention relates to a supporting device for vacuum pumping transmission of ultra-white glass and an implementation method thereof, the device can carry out actual adjustment on an adjusting bolt group 286 according to the weight of an actual workpiece and the actual efficiency of the actual vacuum pumping operation of the initial pressure, control the length of an adjusting sleeve 284 which extends out of an adjusting inner pipe 285, when the ultra-white glass workpiece is placed on a processing backing plate 28, the lower surface of the glass workpiece can be attached to the surface of a conveying belt 27 by downwards compressing a vertical spring 283, meanwhile, the gravity of the ultra-white glass workpiece is transferred to a supporting spring 25, the supporting spring 25 is pressed down, the surface grain of the conveying belt 27 is in mutual embedding contact with a driving roller 109, the driving roller 109 drives the conveying belt 27 to rotate in an auxiliary way, the conveying belt 27 drives the ultra-white glass workpiece to be conveyed forwards, and when the weight of the workpiece is insufficient, a counterweight can be added on the surface of the workpiece to realize the conveying effect.

To sum up: the invention relates to a supporting device for vacuum pumping transmission of ultra-white glass and an implementation method thereof, the device can carry out actual adjustment on an adjusting bolt group 286 according to the weight of an actual workpiece and the actual efficiency of the actual vacuum pumping operation of the initial pressure, control the actual extension of an adjusting sleeve 284 of an adjusting inner pipe 285, place the ultra-white glass workpiece on a processing backing plate 28, enable the lower surface of the glass workpiece to be attached to the surface of a conveying belt 27 by downwards compressing a vertical spring 283, simultaneously transmit the gravity of the ultra-white glass workpiece to a supporting spring 25, and downwards press the supporting spring 25, enable the surface texture of the conveying belt 27 to be mutually inserted and contacted with a driving roller 109, and be driven by the driving roller 109, the driving roller 1011 is assisted to drive the conveying belt 27 to rotate, so that the conveying belt 27 drives the ultra-white glass workpiece to be conveyed forwards, and when the weight of the workpiece is insufficient, the invention has a complete and reasonable structure, effectively realizes the operation of stopping vacuum pumping operation or the operation while conveying according to the actual size of the ultra-white glass workpiece, so as to adapt to the processing operation of the glass workpieces with different sizes.

The foregoing is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art, who is within the scope of the present invention, should be covered by the protection scope of the present invention by making equivalents and modifications to the technical solution and the inventive concept thereof.

Claims (5)

1. The utility model provides a support arrangement for ultrawhite glass initial pressure evacuation transmission, includes transmission base (1) and supporting component (2), its characterized in that: the upper end of the transmission base (1) is provided with a supporting component (2); the transmission base (1) comprises an outer frame (101), fixing bolt holes (102), a motor clamping groove (103), a transmission motor (104), a driving gear (105), a gear caulking groove (106), an auxiliary gear (107), a transmission gear (108), a driving roller (109), a transmission shaft (1010), a driving roller (1011) and a torsion spring (1012), wherein the fixing bolt holes (102) are formed in the outer frame (101), the motor clamping groove (103) is formed in the outer sides of the two ends of the outer frame (101), the transmission motor (104) is installed in the motor clamping groove (103), the driving gear (105) is installed on the inner side of the outer frame (101) at the position of the transmission motor (104), the gear caulking groove (106) is formed in the driving gear (105), the auxiliary gear (107) is installed on the side face of the driving gear (105), the driving roller (109) is installed in the gear caulking groove (106), the transmission shaft (1010) is arranged between the transmission shafts (1010), the roller (1011) is installed on the outer sides of the transmission shaft (1010), and the torsion spring (1011) is arranged on the outer sides of the transmission shaft (1011).

The supporting assembly (2) comprises a mounting bottom plate (21), a guardrail plate (22), mounting bolts (23), vertical sliding grooves (24), supporting springs (25), a conveying shaft (26), a conveying belt (27) and a processing backing plate (28), wherein the guardrail plate (22) is arranged at the upper end of the inner side of the mounting bottom plate (21), the mounting bolts (23) are arranged on the mounting bottom plate (21) at the front end of the guardrail plate (22), the vertical sliding grooves (24) are respectively arranged at the left end and the right end of the front end of the guardrail plate (22), the supporting springs (25) are arranged at the bottom end of the inner side of each vertical sliding groove (24), the conveying shaft (26) is arranged at the upper end of each supporting spring (25), the conveying belt (27) is arranged on each conveying shaft (26), and the processing backing plate (28) is arranged at the tail end of each conveying shaft (26).

Processing backing plate (28) include mainboard body (281), perpendicular movable groove (282), perpendicular spring (283), adjusting sleeve (284), adjust inner tube (285), adjusting bolt group (286), silica gel backing plate (287) and pivot interface (288), both ends side are equipped with pivot interface (288) respectively about mainboard body (281), the inboard of mainboard body (281) is equipped with perpendicular movable groove (282), the inside bottom center department of perpendicular movable groove (282) is equipped with perpendicular spring (283), the upside of perpendicular spring (283) is equipped with adjusting sleeve (284), the internally mounted of adjusting sleeve (284) adjusts inner tube (285), the top installation silica gel backing plate (287) of adjusting inner tube (285), the side of adjusting sleeve (284) is equipped with adjusting bolt group (286).

2. The support device for vacuum transmission of ultra-white glass primary pressure according to claim 1, wherein: the tail end of the adjusting bolt group (286) penetrates through the adjusting sleeve (284) and is inserted into a vertical tooth socket of the adjusting inner tube (285).

3. The support device for vacuum transmission of ultra-white glass primary pressure according to claim 2, wherein: the mounting bolts (23) on the mounting base plate (21) penetrate through the mounting base plate (21) and are nested in the fixing bolt holes (102).

4. A support device for ultra-white glass initial pressure vacuum transmission as claimed in claim 3, wherein: the surface of the conveying belt (27) is provided with embedded lines, and the embedded lines are embedded and connected with the surface of the driving roller (109).

5. A method of implementing the support device for the initial pressure vacuum transmission of ultra-white glass as claimed in claim 4, comprising the steps of:

s1: according to the weight of the actual ultra-white glass workpiece, an adjusting bolt group (286) in the vertical movable groove (282) is adjusted, and the actual length of the adjusting inner pipe (285) extending out of the adjusting sleeve (284) is adjusted;

s2: placing the ultra-white glass workpiece on a processing backing plate (28) of the supporting component (2), and pressing down a silica gel backing plate (287) and a vertical spring (283) at the lower side by utilizing the actual weight of the ultra-white glass workpiece to enable the lower bottom surface of the ultra-white glass workpiece to be attached to the surface of the conveying belt (27);

s3: a transmission motor (104) in the transmission base (1) is started, so that the transmission motor (104) drives a driving gear (105) to rotate, the driving gear (105) drives a transmission gear (108) to rotate through an auxiliary gear (107), and meanwhile, the driving gear (105) and the transmission gear (108) respectively drive a driving roller (109) and a transmission roller (1011) to rotate in the same direction;

s4: the weight of the ultra-white glass workpiece is transferred to the supporting spring (25), the supporting spring (25) is pressed down, and meanwhile, the embedded grains on the surface of the conveying belt (27) are connected with the grains between the driving roller (109) in an embedded manner, so that the driving roller (109) drives the conveying belt (27) to rotate, and the conveying belt (27) drives the ultra-white glass workpiece to be conveyed forwards.

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