CN219190639U - Glazing machine for inner cavity - Google Patents

Abstract

The utility model discloses an inner cavity glazing machine, which comprises a clamping device, wherein the clamping device comprises a reversing shaft and a clamping piece, the reversing shaft extends along the left-right direction, the clamping piece is synchronously connected to the reversing shaft, the front side and the rear side of the clamping device are respectively provided with an avoidance space and a clamping space, the opening of the clamping piece faces the clamping space, and the reversing shaft can reciprocate and rotate and drive the clamping piece to reciprocate between the avoidance space and the clamping space; the material lifting device comprises a material sucking piece capable of moving up and down, and the material sucking piece faces downwards to the avoidance space; the glaze supply device comprises a glaze spraying piece with an upward nozzle, and the glaze spraying piece is positioned at the front side of the material lifting device; the material moving device can drive the material sucking piece to move back and forth between the upper part of the glaze spraying piece and the upper part of the avoiding space, and the automatic overturning and automatic sucking of the ceramic container are realized through the matching of the material clamping device and the material lifting device, so that the automatic effect is improved, the production efficiency is improved, and the labor cost is reduced.

Description

Glazing machine for inner cavity

Technical Field

The utility model relates to the field of inner cavity glazing machines, in particular to an inner cavity glazing machine.

Background

At present, when some formed ceramic containers are in an upward direction in the conveying process, and the ceramic containers are required to be glazed in a cavity, in order to reduce the accumulation of glaze liquid on the inner bottom surface of the ceramic containers, the ceramic containers are required to be reversed and the opening of the ceramic containers is required to be downward, and then the glaze liquid is sprayed into the openings of the ceramic containers, but most of the processes of reversing the ceramic containers are manually operated, so that the efficiency is low, shaking is easy to occur during the operation of workers, the glaze surface is uneven, the product quality is influenced, some manufacturers on the market manually overturn the ceramic containers in advance, the container opening is downwards conveyed, and the ceramic containers are automatically lifted and glaze spraying is realized during the processing, but the production efficiency is also reduced and the labor cost is improved during the manual overturning of the ceramic containers.

Disclosure of Invention

The present utility model aims to provide an intracavity glazing machine which solves one or more of the technical problems of the prior art, and at least provides a beneficial choice or creation condition.

The utility model solves the technical problems as follows:

inner chamber glazing machine includes: the clamping device comprises a reversing shaft and clamping pieces, wherein the reversing shaft extends along the left-right direction, the clamping pieces are synchronously connected to the reversing shaft, the front side and the rear side of the clamping device are respectively provided with an avoidance space and a clamping space, the opening of each clamping piece faces to the clamping space, and the reversing shaft can reciprocate and rotate to drive the clamping pieces to reciprocate between the avoidance space and the clamping space; the material lifting device comprises a material sucking piece capable of moving up and down, and the material sucking piece faces downwards to the avoidance space; the glaze supply device comprises a glaze spraying piece with an upward nozzle, and the glaze spraying piece is positioned at the front side of the lifting device; and the material moving device can drive the material sucking piece to move back and forth between the upper part of the glaze spraying piece and the upper part of the avoiding space.

The technical scheme has at least the following beneficial effects: the ceramic container with the upward opening moves into the clamping space along with the feeding conveyer belt, the opening of the clamping piece is opposite to the ceramic container, the ceramic container enters the opening of the clamping piece along with the continuous transfer of the feeding conveyer belt, the clamping piece is clamped behind the ceramic container, and the counter-rotating shaft rotates, so that the clamping piece is approximately turned over 180 degrees from back to front, the ceramic container is transferred into the avoiding space, the opening of the clamping piece is turned downward, the material sucking piece moves downwards and sucks the outer bottom surface of the ceramic container, and then the material sucking piece is driven by the material transferring device to move to the upper side of the glaze spraying piece, the glaze spraying piece is opened and sprays glaze liquid into the inner cavity of the ceramic container, so that glazing is realized.

As a further improvement of the above technical solution, the present utility model further includes a horizontally extending platform, and the avoidance space is located at a top side of the platform. The ceramic container can be placed on the top surface of the platform after entering the avoidance space, the platform keeps the support on the ceramic container and is used for resisting the pressure of the material sucking part for pressing down and sucking the material, the horizontal platform not only ensures that the ceramic container is turned over and in place, so that the material sucking part can accurately suck the ceramic container, the material sucking stability of the material sucking part is improved, the falling risk of the ceramic container is reduced, the ceramic container is prevented from moving downwards under the pressure action of the material sucking part, the possibility of sucking failure is reduced, meanwhile, when the material sucking part drives the previous batch of ceramic containers to be glazed, the clamping piece can drive the next batch of ceramic containers to be placed on the platform in advance, the clamping state of the next batch of ceramic containers positioned in the material clamping space is recovered, and the production efficiency is improved.

As a further improvement of the technical scheme, the bottom of the platform is connected with the lifting frame, and the lifting frame can drive the platform to move up and down. The horizontal position of counter shaft is fixed, but the ceramic vessel height of different models is inconsistent, through crane adjustment platform's high position for the platform can laminate with the bottleneck of ceramic vessel after the upset, reduces ceramic vessel and the bump of platform, perhaps reduces ceramic vessel's suddenly and falls, is applicable to different models ceramic vessel, improves the suitability.

As another improvement of the technical scheme, the platform is provided with the air blowing nozzle, and the air blowing nozzle faces upwards and is right in a forward and backward movement track of the material sucking piece. The blowing nozzle is fixed on the platform, stability of the blowing nozzle is improved, meanwhile, installation space is reduced, the material moving device can drive the material sucking piece to move to the upper portion of the blowing nozzle, the blowing nozzle is opposite to the inner cavity of the ceramic container, dust in the ceramic container can be blown away when the blowing nozzle works, the dust falls out of the ceramic container under the action of gravity, cleaning of the inner cavity of the ceramic container is achieved, and quality of subsequent glaze spraying is improved.

As another improvement of the above technical solution, the number of the clamping piece, the material absorbing piece and the glaze spraying piece is two or more. The feeding conveyor belt can simultaneously send two or more ceramic containers into the clamping piece, then the corresponding material sucking pieces respectively suck the ceramic containers and take the ceramic containers to the upper part of the glaze spraying piece to realize glazing at the same time, and the production efficiency is improved.

As a further improvement of the technical scheme, the lifting device comprises a lifting driving piece, a transmission piece and a rotary driving piece, wherein the lifting driving piece is connected to the material moving device in a sliding manner along the front-back direction, the material sucking piece is connected to the lifting driving piece in a rotary manner, teeth are arranged on the material sucking piece, the transmission piece is meshed with the teeth of all the material sucking pieces, and the rotary driving piece drives the transmission piece in a rotary manner. After the ceramic container is brought to the upper part of the glaze spraying part by the material absorbing part, the rotary driving part rotates, so that the transmission part drives two or more material absorbing parts to rotate simultaneously, the ceramic container is in a rotating state in the glaze liquid spraying process, the glazing uniformity is improved, and the product quality is improved.

As another improvement of the above technical solution, the clamping piece includes two clamping jaws that can be mutually opened or contracted in the left-right direction. When the two clamping jaws are mutually tightened, the clamping jaw can be clamped on the side wall of the ceramic container, so that the clamping stability of the clamping piece is improved, meanwhile, the clamping piece acts on the side wall of the ceramic container, and the space occupation of the overturning process of the clamping piece is reduced.

As a further improvement of the technical scheme, the clamping jaw is made of silica gel. The sliding friction force between the clamping jaw and the ceramic container is improved, the clamping stability is improved, meanwhile, the softer clamping jaw reduces damage to the outer wall of the ceramic container, and the production quality of products is improved.

As another improvement of the technical scheme, the glaze supplying device comprises an inner glaze box, a glaze barrel and a conveying pipe, wherein a glaze returning hole is formed in the top of the inner glaze box, a glaze spraying piece is arranged in the inner glaze box and located in the middle of the glaze returning hole, a control valve is arranged on the glaze spraying piece, the conveying pipe is communicated with the inner glaze box and the glaze barrel, and a glaze supplying pump is arranged on the conveying pipe. After the oil supply pump is opened, the inner glaze box extracts glaze liquid in the glaze barrel through the conveying pipe and stores the glaze liquid, the material sucking part can control the ceramic container to be close to the inside of the glaze returning hole, the splashing of the glaze liquid is reduced, the control valve can control the valve to control the glaze spraying part to start glaze spraying or stop glaze spraying, and the automatic effect is improved.

As another improvement of the technical scheme, the utility model further comprises a side wiping device positioned at the front side of the glaze spraying piece, the side wiping device comprises a water tank and a sponge belt which is continuously conveyed, the bottom side of the sponge belt stretches into the water tank, and the material moving device can drive the material absorbing piece to move towards the direction above the sponge belt. After the inner cavity of the ceramic container is glazed, the edge of the opening of the ceramic container is provided with redundant glaze liquid, the material moving device drives the material sucking piece to move to the upper part of the sponge belt, so that the edge of the opening of the ceramic container can be in contact with the sponge belt, the residual glaze liquid is erased along with continuous conveying of the sponge belt, after the sponge belt enters a water tank, the sponge belt is washed and cleaned, the opening of the ceramic container with secondary pollution is prevented, and the production precision of products is improved.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present utility model, the drawings that are required to be used in the description of the embodiments will be briefly described below. It is evident that the drawings described are only some embodiments of the utility model, but not all embodiments, and that other designs and drawings can be obtained from these drawings by a person skilled in the art without inventive effort.

FIG. 1 is a block diagram of an intracavity glazing machine according to one embodiment of the present utility model;

FIG. 2 is a block diagram of a clamping device according to an embodiment of the present utility model;

FIG. 3 is a diagram illustrating the connection of a platform, a crane and a blowing nozzle according to an embodiment of the present utility model;

fig. 4 is a block diagram of a material lifting device according to an embodiment of the present utility model.

In the accompanying drawings: 100-frame, 111-counter shaft, 112-clamp, 113-ceramic container, 114-avoidance space, 115-clamping space, 121-suction piece, 140-moving device, 150-blowing nozzle, 161-inner glaze box, 162-back glaze hole, 163-glaze spraying piece, 171-water tank, 172-sponge belt, 180-platform, 210-clamping jaw, 310-lifting frame, 410-lifting driving piece, 420-driving piece, 430-rotation driving piece, 440-mounting frame and 450-moving frame.

Detailed Description

The conception, specific structure, and technical effects produced by the present utility model will be clearly and completely described below with reference to the embodiments and the drawings to fully understand the objects, features, and effects of the present utility model. It is apparent that the described embodiments are only some embodiments of the present utility model, but not all embodiments, and that other embodiments obtained by those skilled in the art without inventive effort are within the scope of the present utility model based on the embodiments of the present utility model. In addition, all connection relationships mentioned herein do not refer to direct connection of the components, but rather, refer to a connection structure that may be better formed by adding or subtracting connection aids depending on the particular implementation. The technical features of the utility model can be interactively combined on the premise of no contradiction and conflict.

In the description of the present utility model, it should be understood that references to orientation descriptions such as upper, lower, front, rear, left, right, etc. are based on the orientation or positional relationship shown in the drawings, are merely for convenience of description of the present utility model and to simplify the description, and do not indicate or imply that the apparatus or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present utility model.

In the description of the present utility model, a number means one or more, a number means two or more, and greater than, less than, exceeding, etc. are understood to not include the present number, and above, below, within, etc. are understood to include the present number. The description of the first and second is for the purpose of distinguishing between technical features only and should not be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated or implicitly indicating the precedence of the technical features indicated.

In the description of the present utility model, unless explicitly defined otherwise, terms such as arrangement, installation, connection, etc. should be construed broadly and the specific meaning of the terms in the present utility model can be reasonably determined by a person skilled in the art in combination with the specific contents of the technical scheme.

Referring to fig. 1, the cavity enamelling machine comprises a frame 100, a clamping device, a lifting device, a enamelling device and a moving device 140. The clamping device comprises a reversing shaft 111 and a clamping piece 112, wherein the reversing shaft 111 is connected to the frame 100 through a bearing and extends along the left-right direction, the clamping piece 112 is synchronously connected to the reversing shaft 111, the front side and the rear side of the clamping device are respectively provided with an avoidance space 114 and a clamping space 115, an opening of the clamping piece 112 faces the clamping space 115, and the reversing shaft 111 can reciprocally rotate and drive the clamping piece 112 to reciprocally overturn between the avoidance space 114 and the clamping space 115; the material lifting device comprises a material sucking piece 121 capable of moving up and down, and the material sucking piece 121 faces downwards to the avoidance space 114; the glaze supplying device comprises a glaze spraying part 163 with an upward nozzle, and the glaze spraying part 163 is positioned at the front side of the lifting device; the material moving device 140 is disposed on the frame 100, and the material moving device 140 can drive the material sucking member 121 to move back and forth between the upper portion of the glaze spraying member 163 and the upper portion of the avoiding space 114.

Specifically, the ceramic container 113 with the opening facing upwards moves into the clamping space 115 along with the feeding conveyer belt, the opening of the clamping piece 112 is opposite to the ceramic container 113, along with the continuous transfer of the feeding conveyer belt, the ceramic container 113 enters the opening of the clamping piece 112, the clamping piece 112 clamps the ceramic container 113, the counter-rotating shaft 111 rotates, the clamping piece 112 is turned over approximately 180 degrees from back to front, the ceramic container 113 is transferred into the avoiding space 114, the opening of the ceramic container is turned downwards, after the suction piece 121 moves downwards and sucks the outer bottom surface of the ceramic container 113, the material transferring device 140 drives the suction piece 121 to move above the glaze spraying piece 163, and the glaze spraying piece 163 is opened and sprays glaze liquid into the inner cavity of the ceramic container 113 to realize glazing.

The material sucking piece 121 can move up and down, so that avoidance of the clamping piece 112 is guaranteed, meanwhile, the ceramic container 113 can be sleeved into the glaze spraying piece 163, glazing effect is improved, automatic overturning and automatic sucking of the ceramic container 113 are achieved through matching of the clamping device and the lifting device, automatic effect is improved, production efficiency is improved, the ceramic container 113 does not need to be overturned manually in advance, and labor cost is reduced. In addition, the ceramic container 113 can be turned upwards or downwards through the reversing shaft 111, the sucking piece 121 adopts a vacuum chuck and is connected with a CV-20HS vacuum generator, so that the suction force of the sucking piece 121 is ensured.

In addition, referring to fig. 2, one end of the reversing shaft 111 is rotated by a motor, two clamping members 112 are clamped on the reversing shaft 111 at intervals by bolts, the clamping members 112 comprise two clamping jaws 210 which can be mutually opened or contracted in the left-right direction, and the clamping jaws 210 are made of silica gel.

Specifically, two clamping jaws 210 can be mutually opened or tightened through the air cylinder, when two clamping jaws 210 are mutually tightened, the clamping jaws 210 can be clamped on the side wall of the ceramic container 113, so that the clamping stability of the clamping piece 112 is improved, meanwhile, the clamping piece 112 acts on the side wall of the ceramic container 113, the space occupation of the overturning process of the clamping piece 112 is reduced, the material of the clamping jaws 210 is silica gel in the embodiment, the sliding friction force between the clamping jaws 210 and the ceramic container 113 is improved, the clamping stability is improved, meanwhile, the damage to the outer wall of the ceramic container 113 is reduced by the softer clamping jaws 210, and the production quality of products is improved.

Further, referring to fig. 3, the present utility model further includes a horizontally extending platform 180, the avoidance space 114 is located at the top side of the platform 180, the bottom of the platform 180 is connected to a lifting frame 310, and the lifting frame 310 can drive the platform 180 to move up and down.

After the clamping piece 112 is overturned along with the reversing shaft 111, the ceramic container 113 enters the avoiding space 114 from the upper part and is placed on the top surface of the platform 180, at this time, the platform 180 forms a supporting effect on the ceramic container 113 to resist the pressure of the material sucking part 121 for sucking the material downwards, the horizontal platform 180 ensures that the ceramic container 113 is overturned in place, the material sucking part 121 can accurately suck the ceramic container 113, the material sucking stability of the material sucking part 121 is improved, the falling risk of the ceramic container 113 is reduced, the ceramic container 113 is prevented from moving downwards and misplacement under the pressure action of the material sucking part 121, the possibility of sucking failure is reduced, meanwhile, when the material sucking part 121 drives the previous batch of ceramic containers 113 to be glazed, the clamping piece 112 can drive the next batch of ceramic containers 113 to be placed on the platform 180 in advance, the clamping state of the next batch of ceramic containers 113 positioned in the material clamping space 115 is restored, and the production efficiency is improved.

In actual use, the transverse position of the counter-rotating shaft 111 is fixed on the frame 100, but the heights of the ceramic containers 113 of different types are inconsistent, and a worker can adjust the height position of the platform 180 through the lifting frame 310 in advance, so that the platform 180 can be attached to the bottle mouth of the overturned ceramic container 113, the collision between the ceramic container 113 and the platform 180 is reduced, or the sudden falling of the ceramic container 113 is reduced, and the counter-rotating shaft is suitable for the ceramic containers 113 of different types and improves the applicability. In this embodiment, the lifting frame 310 is fixed on the frame 100, and the lifting frame 310 may be a scissor type lifting frame, or the height of the cross lifting frame 310 may be adjusted by hand adjusting bolts.

In some embodiments, the platform 180 is provided with a blowing nozzle 150, and the blowing nozzle 150 faces upward to the front-back movement track of the suction member 121.

Specifically, the air blowing nozzle 150 is fixed on the platform 180, so that the stability of the air blowing nozzle 150 is improved, meanwhile, the installation space is reduced, the material moving device 140 can drive the material sucking piece 121 to move to the upper side of the air blowing nozzle 150, so that the air blowing nozzle 150 is opposite to the inner cavity of the ceramic container 113, when the air blowing nozzle 150 works, dust in the ceramic container 113 can be blown away, the dust falls out of the ceramic container 113 under the action of gravity, the inner cavity of the ceramic container 113 is cleaned, and the quality of subsequent glaze spraying is improved.

In this embodiment, the number of the clamping members 112, the sucking member 121, the blowing nozzle 150, and the glaze spraying member 163 is two.

Specifically, the feeding conveyor belt can simultaneously send two ceramic containers 113 into the clamping piece 112, then the corresponding material sucking pieces 121 respectively suck the ceramic containers 113, and the ceramic containers are brought above the blowing nozzle 150 and cleaned at the same time, and then the ceramic containers are brought above the glaze spraying piece 163 and glazed at the same time, so that the production efficiency is improved. In practice, the front and rear positions of the clamping member 112, the suction member 121, the air blowing nozzle 150 and the glaze spraying member 163 are in one-to-one correspondence, and the number of the clamping member 112, the suction member 121, the air blowing nozzle 150 and the glaze spraying member 163 may be one, three, four, etc.

Referring to fig. 4, the lifting device includes a lifting driving member 410, a transmission member 420 and a rotation driving member 430, wherein the lifting driving member 410 is slidably connected to the material moving device 140 along the front-rear direction, the material sucking member 121 is rotatably connected to the lifting driving member 410, teeth are disposed on the material sucking member 121, the transmission member 420 is engaged with the teeth of all the material sucking members 121, and the rotation driving member 430 rotatably drives the transmission member 420.

Specifically, the lifting driving member 410 includes a moving frame 450, a lifting motor and a mounting frame 440, the material moving device 140 drives the moving frame 450 to slide back and forth through a motor screw rod structure, the lifting motor is arranged on the moving frame 450, the driving end of the lifting motor is connected with the mounting frame 440, the mounting frame 440 can move up and down, the material sucking member 121 is rotatably connected on the mounting frame 440 through a bearing, the rotation axis of the material sucking member and the central line of the material sucking member extend along the vertical direction, the rotation driving member 430 is a motor, the motor is arranged on the mounting frame 440, the driving member 420 is a driving belt, and the driving end of the motor is meshed with the driving member 420, so that the driving member 420 can drive all the air sucking members to rotate. When the ceramic glaze spraying device works, the ceramic container 113 is brought to the position above the glaze spraying part 163 by the material sucking part 121, and then the rotary driving part 430 rotates, so that the transmission part 420 drives two or more material sucking parts 121 to rotate simultaneously, the ceramic container 113 is in a rotating state in the glaze liquid spraying process, the glazing uniformity is improved, and the product quality is improved. In addition, the transmission member 420 may be a gear set, and engaged with teeth on each of the suction members 121.

The material transfer device 140 may be a linear driving device such as an air cylinder to drive the movable frame 450, or the lifting motor may be replaced by a lifting air cylinder, and the specific driving device is not limited in this embodiment.

In this embodiment, the glaze supply device includes interior glaze case 161, glaze bucket and conveyer pipe, the top of interior glaze case 161 is equipped with back glaze hole 162, glaze spraying spare 163 sets up in interior glaze case 161 and is located the middle part of back glaze hole 162, be equipped with the control valve on the glaze spraying spare 163, the conveyer pipe intercommunication interior glaze case 161 with the glaze bucket is equipped with the glaze supply pump on the conveyer pipe.

When the glaze spraying device is used, the oil supply pump is opened, the glaze liquid in the glaze barrel is pumped and stored by the inner glaze box 161 through the conveying pipe, after the ceramic container 113 is moved to the upper side of the glaze spraying part 163 by the material sucking part 121, the material sucking part 121 can move downwards to enable the ceramic container 113 to be close to the glaze returning hole 162, the splashing of the glaze liquid is reduced, the control valve is opened, the glaze liquid is sprayed into the inner cavity of the ceramic container 113, the ceramic container 113 rotates along with the material sucking part 121 to ensure uniform glaze spraying, after the glaze spraying is finished, the control valve is closed, and the material sucking part 121 moves the ceramic container 113 to a downwards moving process. In addition, the glaze barrel is internally provided with a stirring rod which continuously rotates, so that the uniformity of the glaze liquid is ensured.

The utility model further comprises a side wiping device positioned at the front side of the glaze spraying part 163, the side wiping device comprises a water tank 171 and a continuously conveyed sponge belt 172, the bottom side of the sponge belt 172 stretches into the water tank 171, and the material moving device 140 can drive the material absorbing part 121 to move towards the direction above the sponge belt 172.

Specifically, after the glazing of the inner cavity of the ceramic container 113 is completed, the edge of the opening of the ceramic container 113 is provided with redundant glaze liquid, the material moving device 140 drives the material sucking piece 121 to move to the upper part of the sponge belt 172, so that the edge of the opening of the ceramic container 113 can be in contact with the sponge belt 172, the residual glaze liquid is erased along with continuous conveying of the sponge belt 172, after the sponge belt 172 enters the water tank 171, the sponge belt 172 is washed and cleaned, secondary pollution to the opening of the ceramic container 113 is prevented, and the product production precision is improved. In practice, the sponge belt 172 is continuously conveyed by the belt conveying apparatus.

The specific working principle of the inner cavity glazing machine of the utility model is as follows: the ceramic container 113 with the upward opening moves into the clamping space 115 along with the feeding conveyer belt, two silica gel clamping jaws 210 on the clamping piece 112 clamp the ceramic container 113, the ceramic container 113 is turned over from the clamping space 115 to the avoiding space 114 by the clamping piece 112 through the rotation of a motor driving counter-rotating shaft 111, the ceramic container 113 is placed on a platform 180 with the adjusted height, then a lifting motor of a lifting device drives a material sucking piece 121 to move downwards to suck the ceramic container 113, a material moving device 140 drives the material sucking piece 121 to move onto a blowing nozzle 150 through a motor screw, the blowing nozzle 150 is a bamboo joint pipe, the motor drives the material sucking piece 121 to rotate, so that high-pressure air sprayed on the blowing nozzle 150 cleans the inner cavity of the container, after cleaning, the material moving device 140 drives the material absorbing member 121 to move above the glaze spraying member 163, the regulating valve on the glaze spraying member 163 is opened, so that glaze liquid can be sprayed into the inner cavity of the rotating ceramic container 113, the redundant glaze liquid flows back to the inner glaze box 161 through the glaze returning hole 162, then the material moving device 140 drives the material absorbing member 121 to move above the sponge belt 172, so that the ceramic container 113 is contacted with the top surface of the sponge belt 172, the sponge belt 172 continuously erases the redundant glaze liquid on the side of the opening of the ceramic container 113 by continuously conveying, and the sponge belt 172 drives the residual glaze liquid to enter the water tank 171 for cleaning, thereby preventing secondary pollution of the ceramic container 113.

While the preferred embodiments of the present utility model have been illustrated and described, the present utility model is not limited to the examples, and various equivalent modifications and substitutions can be made by one skilled in the art without departing from the spirit of the present utility model, and these equivalent modifications and substitutions are intended to be included in the scope of the present utility model as defined in the appended claims.

Claims (10)

1. Inner chamber glazing machine, its characterized in that: comprising the following steps:

the clamping device comprises a reversing shaft (111) and clamping pieces (112), wherein the reversing shaft (111) extends along the left-right direction, the clamping pieces (112) are synchronously connected to the reversing shaft (111), an avoidance space (114) and a clamping space (115) are respectively formed in the front side and the rear side of the clamping device, an opening of each clamping piece (112) faces the clamping space (115), and the reversing shaft (111) can reciprocate and drive the clamping pieces (112) to reciprocate and turn over between the avoidance space (114) and the clamping space (115);

the material lifting device comprises a material sucking piece (121) capable of moving up and down, and the material sucking piece (121) faces downwards to the avoidance space (114);

the glaze supplying device comprises a glaze spraying piece (163) with an upward nozzle, and the glaze spraying piece (163) is positioned at the front side of the lifting device;

and the material moving device (140) can drive the material sucking piece (121) to move back and forth between the upper part of the glaze spraying piece (163) and the upper part of the avoiding space (114).

2. The intracavity glazing machine of claim 1 wherein: the device further comprises a horizontally extending platform (180), and the avoidance space (114) is positioned on the top side of the platform (180).

3. The intracavity glazing machine of claim 2 wherein: the bottom of the platform (180) is connected with a lifting frame (310), and the lifting frame (310) can drive the platform (180) to move up and down.

4. The intracavity glazing machine of claim 2 wherein: the platform (180) is provided with a blowing nozzle (150), and the blowing nozzle (150) faces upwards and is opposite to the front-back movement track of the material sucking piece (121).

5. The intracavity glazing machine of claim 1 wherein: the number of the clamping pieces (112), the material sucking pieces (121) and the glaze spraying pieces (163) is two or more.

6. The intracavity glazing machine of claim 5 wherein: the lifting device comprises a lifting driving piece (410), a transmission piece (420) and a rotary driving piece (430), wherein the lifting driving piece (410) is connected to the material moving device (140) in a sliding mode along the front-back direction, the material sucking piece (121) is connected to the lifting driving piece (410) in a rotating mode, teeth are arranged on the material sucking piece (121), the transmission piece (420) is meshed with the teeth of all the material sucking pieces (121), and the rotary driving piece (430) is used for driving the transmission piece (420) in a rotating mode.

7. The intracavity glazing machine of claim 1 wherein: the clamping piece (112) comprises two clamping jaws (210) which can be mutually opened or contracted along the left-right direction.

8. The intracavity glazing machine of claim 7 wherein: the clamping jaw (210) is made of silica gel.

9. The intracavity glazing machine of claim 1 wherein: the glaze feeding device comprises an inner glaze box (161), a glaze barrel and a conveying pipe, wherein a glaze returning hole (162) is formed in the top of the inner glaze box (161), a glaze spraying piece (163) is arranged in the inner glaze box (161) and located in the middle of the glaze returning hole (162), a control valve is arranged on the glaze spraying piece (163), the conveying pipe is communicated with the inner glaze box (161) and the glaze barrel, and a glaze feeding pump is arranged on the conveying pipe.

10. The intracavity glazing machine of claim 1 wherein: still including being located the edge wiping device of glaze spraying spare (163) front side, edge wiping device includes basin (171) and continuous sponge belt (172) of carrying, the bottom side of sponge belt (172) stretches into in basin (171), move material device (140) can drive material absorbing member (121) are toward the direction of sponge belt (172) top is removed.

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