CN216501374U - Automatic powder removing device for glass surface isolation powder - Google Patents

Abstract

The utility model discloses an automatic powder removing device for isolating powder on the surface of glass, wherein a static eliminating rod is used for pre-removing the static of the isolating powder, then the isolating powder on the lower surface of the glass to be subjected to powder removal is brushed by a brush roller, and the isolating powder entering the brush roller is sprayed and swept by a chip removing blow pipe, is separated from the brush roller, is dissociated in a lower cavity and is sucked into a dust collector by an air exhaust pipe; on the other hand, the purging pipe arranged above the upper surface of the glass to be subjected to powder removal purges the upper surface of the glass to be subjected to powder removal, so that the isolation powder on the upper surface of the glass to be subjected to powder removal dissociates in the upper cavity and is sucked into the dust collector through the air exhaust pipe, most of the isolation powder on the surface of the glass to be subjected to powder removal is removed, the efficiency of subsequent glass deep processing is improved, and the fragile silver layer on the upper surface of the glass to be subjected to powder removal is prevented from being scratched. The utility model solves the problem that the surface silver layer of the LOW-E glass is easily scratched by the isolating powder on the glass in the cleaning process during the existing deep processing of the float glass.

Description

Automatic powder removing device for glass surface isolation powder

Technical Field

The utility model relates to the technical field of glass deep processing, in particular to an automatic powder removing device for isolating powder on the surface of glass.

Background

The surface of the float glass needs to be evenly dusted with the spacer powder for boxing and delivery to various deep processing enterprises. The isolating powder has the functions of preventing the surface of float glass from mildewing in a humid environment and forming an isolating layer between the glass to consume the adhesive force between the glass and the glass.

At glass deep-processing enterprise, during glass-cutting, if not getting rid of isolation powder, then can lead to leaving over a lot of isolation powder on whole cutting section ground and the cutting mesa for constructor stumbles easily on subaerial, and all is glass-cutting's semi-manufactured goods near the cutting bed, and is very dangerous.

In addition, when the glass without the isolation powder is washed after entering the developing machine, the isolation powder is easily remained between the fine (phi 0.06mm) brushes, and the brush rollers need to be frequently cleaned. Particularly, when the surface of LOW-E glass (LOW-emissivity glass) is cleaned, the surface of the LOW-E glass is provided with a silver layer, and if the isolating powder is excessive, the isolating powder remained in the brush can scratch the surface of a LOW-E film slightly.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects in the prior art, an automatic powder removing device for isolating powder on the surface of glass is provided so as to solve the problem that the isolating powder on the glass easily scratches the surface silver layer of the LOW-E glass in the cleaning process during the existing deep processing of float glass.

In order to realize the above-mentioned purpose, provide an automatic gumming device of glass surface isolation powder, include:

the device comprises a treatment box, a plurality of support legs are mounted at the bottom of the treatment box, a feeding port and a discharging port which are coaxially arranged are respectively formed in two opposite sides of the treatment box, and air pumping ports are respectively formed in the top and the bottom of the treatment box;

the two static eliminating rods are fixedly arranged outside the treatment box, the two static eliminating rods are respectively arranged at the upper part and the lower part of the feeding hole, a gap for the glass to be subjected to powder removal to penetrate is formed between the two static eliminating rods, and the gap is aligned to the feeding hole;

the supporting roller shaft is used for placing the glass to be subjected to powder removal and is rotatably arranged in the treatment box;

the device comprises a brush roller, a dust removing blow pipe and a dust removing blow pipe, wherein the brush roller is used for brushing the lower surface of glass to be cleaned, the brush roller is rotatably arranged in a treatment box, a motor used for driving the brush roller is arranged outside the treatment box, the treatment box is internally provided with the dust removing blow pipe, and the dust removing blow pipe is provided with a first air jet port aligned to the brush roller;

the purging pipe is arranged in the treatment box and is provided with a second air jet port aligned to the upper surface of the glass to be subjected to powder removal; and

and the dust collector is connected to the air suction port through an air suction pipe.

Furthermore, a support plate is connected between the support legs on two opposite sides of the treatment box, an air compressor is mounted on the support plate, and pipelines of the air compressor are connected to the scrap removing blow pipe and the blowing pipe.

Furthermore, two support legs are installed on each side of the treatment box, a reinforcing beam is connected between the two support legs, and two ends of the support plate are respectively installed on the reinforcing beam through a damping structure.

Further, the shock-absorbing structure includes:

the opposite two sides of the supporting plate are respectively provided with the inserting columns, the upper part of the reinforcing beam is provided with a vertically arranged accommodating hole, and the inserting columns are movably inserted into the accommodating holes; and

and the pushing spring is arranged between the insertion column and the bottom of the accommodating hole in a cushioning manner.

Furthermore, one side of the bearing plate is connected with a plurality of connecting rods, and one ends of the connecting rods, which are far away from the bearing plate, are connected to the inserting columns.

Furthermore, an installation groove is formed in the middle of the supporting plate, the air compressor is embedded in the installation groove, and an elastic cushion layer is laid on the inner wall of the installation groove.

The automatic powder removing device for the glass surface isolating powder has the advantages that the static electricity of the isolating powder is pre-removed through the static electricity removing rod, the isolating powder on the lower surface of glass to be subjected to powder removal is brushed through the brush roller, and the isolating powder entering the brush roller is separated from the brush roller and dissociated in the lower cavity under the spraying and sweeping of the scrap removing blow pipe and is sucked into the dust collector through the air exhaust pipe; on the other hand, the purging pipe arranged above the upper surface of the glass to be subjected to powder removal purges the upper surface of the glass to be subjected to powder removal, so that the isolation powder on the upper surface of the glass to be subjected to powder removal dissociates in the upper cavity and is sucked into the dust collector through the air exhaust pipe, most of the isolation powder on the surface of the glass to be subjected to powder removal is removed, the efficiency of subsequent glass deep processing is improved, and the fragile silver layer on the upper surface of the glass to be subjected to powder removal is prevented from being scratched.

Drawings

Other features, objects and advantages of the present application will become more apparent upon reading of the following detailed description of non-limiting embodiments thereof, made with reference to the accompanying drawings in which:

fig. 1 is a schematic structural diagram of an automatic powder removing device for glass surface isolation powder according to an embodiment of the utility model.

Fig. 2 is a cross-sectional view of a disposal box of an embodiment of the present invention.

Fig. 3 is a schematic structural view of a shock-absorbing structure according to an embodiment of the present invention.

Detailed Description

The present application will be described in further detail with reference to the following drawings and examples. It is to be understood that the specific embodiments described herein are merely illustrative of the relevant invention and are not limiting of the utility model. It should be noted that, for convenience of description, only the portions related to the present invention are shown in the drawings.

It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict. The present application will be described in detail below with reference to the embodiments with reference to the attached drawings.

Referring to fig. 1 to 3, the present invention provides an automatic powder removing device for glass surface isolation powder, comprising: the electrostatic cleaning device comprises a treatment box 1, two electrostatic elimination rods 2, a supporting roller shaft 3, a brush roller 4, a purging pipe 5 and a dust collector 6.

Wherein, the disposal box 1 is a sealed box body and is in a strip shape. A cavity is formed inside the sealed box body. A plurality of legs 11 are mounted to the bottom of the treatment tank. The relative both sides of handling case 1 are seted up the feed inlet a and the discharge gate b of coaxial setting respectively, and the front side of handling the case promptly is opened and is equipped with the feed inlet, and the rear side of handling the case is opened and is equipped with the discharge gate. The feed inlet and the discharge port are respectively arranged along the length direction of the treatment box, the feed inlet and the discharge port are in a strip shape, the length of the feed inlet and the length of the discharge port are larger than or equal to the width of the original glass, and the width of the feed inlet and the width of the discharge port are adaptive to the width of the original glass.

The disposal box is arranged between the upper piece table and the cutting table. The feed inlet aims at the piece platform, and the discharge gate aims at the cutting bed. The original glass enters the disposal box through the feed inlet, and enters the cutting table through the discharge outlet after the powder removing treatment.

The top and the bottom of the treatment box 1 are respectively provided with an air suction port c. After the original glass sheet enters the feeding hole, the original glass sheet divides the inner cavity of the treatment box into an upper cavity and a lower cavity, the air suction port at the top of the treatment box is communicated with the upper cavity, and the air suction port at the bottom of the treatment box is communicated with the lower cavity.

The two static eliminating rods 2 are fixedly arranged outside the treatment box 1. The static elimination rod is arranged along the length direction of the feed inlet. Two static eliminating rods 2 are respectively arranged at the upper part and the lower part of the feed inlet a. A gap for the glass 9 to be powder-removed to pass through is formed between the two static eliminating rods 2. The slit is aligned with the feed opening a.

Before the original glass sheet enters the feeding hole, static electricity is removed from the upper surface and the lower surface of the original glass sheet, namely the glass 9 to be subjected to powder removal through a static electricity removing rod, and isolation powder attached to the surface of the original glass sheet is subjected to pre-static electricity removal.

The supporting roller shaft 3 is rotatably installed in the treatment tank 1. The supporting roller shaft 3 is used for placing the glass 9 to be subjected to powder removal. After the original glass sheet enters the inside of the treatment box through the feed opening, the support roller 3 is supported on the lower surface of the original glass sheet. In some embodiments, the outside cover of supporting roller axle is equipped with a plurality of anti-skidding gyro wheels, and the supporting roller axle passes through motor drive in order to drive a plurality of anti-skidding gyro wheels and rotate, and a plurality of anti-skidding gyro wheels are used for carrying former piece glass.

The brush roller 4 is rotatably installed in the treatment tank 1. The brush roller 4 is used for brushing off the lower surface of the glass 9 to be powdered. A motor 42 for driving the brush roller 4 is installed outside the treatment tank 1. A dust-removing blowing pipe 41 is installed in the treatment tank 1. The chip-removing blowing pipe 41 is provided with a first air injection port. The first air jet is aligned with the first air jet of the brush roller 4. In this embodiment, as shown in fig. 2, the brush roller is rotated in a counterclockwise direction, and the first air ejection openings are arranged in a direction opposite to the rotational direction of the brush roller, so that the spacer powder brushed by the brush roller is detached from the brush roller.

The purging pipe 5 is installed in the treatment box 1, and the purging pipe is arranged above the brush roller. The purging tube 5 is provided with a second gas injection port aligned with the upper surface of the glass to be powdered 9.

The vacuum cleaner 6 is connected to the suction opening via a suction air duct (not shown in the drawings).

According to the automatic powder removing device for the glass surface isolating powder, disclosed by the utility model, the static electricity of the isolating powder is pre-removed through the static electricity removing rod, the isolating powder on the lower surface of the glass to be subjected to powder removal is brushed through the brush roller, the isolating powder entering the brush roller is sprayed and swept by the chip removing blow pipe, so that the isolating powder is separated from the brush roller, and the isolating powder dissociated in the lower cavity is sucked into a dust collector through the air exhaust pipe; on the other hand, the purging pipe arranged above the upper surface of the glass to be subjected to powder removal purges the upper surface of the glass to be subjected to powder removal, so that the isolation powder on the upper surface of the glass to be subjected to powder removal dissociates in the upper cavity and is sucked into the dust collector through the air exhaust pipe, most of the isolation powder on the surface of the glass to be subjected to powder removal is removed, and the fragile silver layer on the upper surface of the glass to be subjected to powder removal is prevented from being scratched.

In the present embodiment, a support plate 13 is connected between the legs 11 on opposite sides of the treatment tank 1. The support plate 13 is mounted with an air compressor 7. The air compressor 7 is connected with the pipeline of the scrap removing blow pipe 41 and the purging pipe 5. Compressed air is supplied to the chip removing blow pipe and the purging pipe in a pressurization mode through an air compressor.

In a preferred embodiment, a plurality of nozzles are respectively installed on the chip-removing blowing pipe and the purging pipe, and the plurality of nozzles are arranged along the length direction of the chip-removing blowing pipe or the purging pipe.

In this embodiment, two legs 11 are mounted on each side of the bottom of the treatment tank 1. A reinforcing beam 12 is connected between the two legs 11. Both ends of the support plate 13 are respectively mounted to the reinforcing beams 12 through the shock-absorbing structures 8.

Specifically, the shock-absorbing structure 8 includes: a plug-in post 81 and a push spring 82. Wherein, the opposite sides of the support plate 13 are respectively provided with a plugging column 81. The upper portion of reinforcing beam 12 is seted up the vertical holding hole that sets up. The insertion column 81 is movably inserted into the receiving hole. The pushing spring 82 is arranged between the inserting column 81 and the bottom of the containing hole in a cushioning mode.

In this embodiment, as shown in fig. 1, a plurality of connecting rods 14 are connected to each side of the support plate 13. The end of the connecting rod 14 remote from the support plate 13 is connected to the plug-in post 81.

As shown in fig. 3, the support plate 13 is formed at the middle thereof with a mounting groove. The air compressor 7 is embedded in the mounting groove, and the elastic cushion layer 131 is laid on the inner wall of the mounting groove.

In this embodiment, the length of the disposal box is 3500mm, and the width of the float glass to be removed which needs to pass through is 3300 mm; the width of the disposal box is about 600 mm. Two supporting roll shafts are installed in a lower cavity of the treatment box, and the brush roller is arranged between the two supporting roll shafts.

The device is characterized in that a feeding hole and a discharging hole of the disposal box are respectively provided with an optical sensor, when the optical sensor at the feeding hole senses float glass, the device is started, the brush roller rotates at a high speed, the air compressor, the blowing pipe and the blowing pipe are opened, and the dust collector is opened for adsorption. When the optical sensor at the discharge port can not sense float glass, the device stops running, and the functions of saving electricity and using gas are achieved.

The automatic powder removing device for the isolating powder on the surface of the glass can effectively remove 85% of the isolating powder on the float glass, and avoids safety accidents caused by falling of constructors due to the fact that the isolating powder is left on the ground and the table top.

The foregoing description is only exemplary of the preferred embodiments of the application and is illustrative of the principles of the technology employed. It will be understood by those skilled in the art that the scope of the present invention is not limited to the specific combination of the above-mentioned features, but also covers other embodiments formed by any combination of the above-mentioned features or their equivalents without departing from the spirit of the present invention. For example, the above features may be replaced with (but not limited to) features having similar functions disclosed in the present application.

Claims (6)

1. The utility model provides an automatic gumming device of glass surface isolation powder which characterized in that includes:

the device comprises a treatment box, a plurality of support legs are mounted at the bottom of the treatment box, a feeding port and a discharging port which are coaxially arranged are respectively formed in two opposite sides of the treatment box, and air pumping ports are respectively formed in the top and the bottom of the treatment box;

the two static eliminating rods are fixedly arranged outside the treatment box, the two static eliminating rods are respectively arranged at the upper part and the lower part of the feeding hole, a gap for the glass to be subjected to powder removal to penetrate is formed between the two static eliminating rods, and the gap is aligned to the feeding hole;

the supporting roller shaft is used for placing the glass to be subjected to powder removal and is rotatably arranged in the disposal box;

the device comprises a treatment box, a brush roller, a scrap removing blow pipe and a dust removing blow pipe, wherein the brush roller is used for brushing the lower surface of glass to be subjected to dust removal and is rotatably arranged in the treatment box;

the purging pipe is arranged in the treatment box and is provided with a second air jet port aligned to the upper surface of the glass to be subjected to powder removal; and

and the dust collector is connected to the air suction port through an air suction pipe.

2. The automatic powder removing device for the glass surface isolating powder as claimed in claim 1, wherein a support plate is connected between the support legs at two opposite sides of the disposal box, an air compressor is mounted on the support plate, and pipelines of the air compressor are connected to the chip removing blowing pipe and the purging pipe.

3. The automatic powder removing device for the glass surface isolating powder as claimed in claim 2, wherein two support legs are installed at each side of the disposal box, a reinforcing beam is connected between the two support legs, and two ends of the support plate are respectively installed on the reinforcing beam through a shock absorption structure.

4. The automatic powder removing device for glass surface isolation powder as claimed in claim 3, wherein the shock-absorbing structure comprises:

the opposite two sides of the supporting plate are respectively provided with the inserting columns, the upper part of the reinforcing beam is provided with a vertically arranged accommodating hole, and the inserting columns are movably inserted into the accommodating holes; and

and the pushing spring is arranged between the insertion column and the bottom of the accommodating hole in a cushioning manner.

5. The automatic powder removing device for glass surface isolating powder as claimed in claim 4, wherein one side of the support plate is connected with a plurality of connecting rods, and one ends of the connecting rods far away from the support plate are connected with the inserting columns.

6. The automatic powder removing device for the glass surface isolating powder as claimed in claim 2, wherein a mounting groove is formed in the middle of the supporting plate, the air compressor is embedded in the mounting groove, and an elastic cushion layer is laid on the inner wall of the mounting groove.

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