CN214881146U - Hollow glass inflation device - Google Patents

Abstract

The utility model discloses a cavity glass aerating device, the device fixed mounting are in cavity glass's transmission band top, include: the conveying belt comprises a fixed seat arranged at the bottom of the conveying belt, an inflating device fixedly arranged on the fixed seat and a glue supply device arranged on the fixed seat; the inflator includes: the device comprises a support frame fixedly arranged on a fixed seat, a transmission device fixedly arranged at the top of the support frame, and an inflation needle arranged at the output end of the transmission device; one end of the inflation needle is fixedly inserted with the conical heating nozzle, and the inflation needle is communicated with the inflation tube. The utility model discloses a toper heating nozzle opens a hole in the sealing layer first when heating refrigerated inert gas and conveniently aerifys, overflows from aerifing the needle after being full of gas in the cavity glass to infrared image detection device detects the gaseous cold and hot distribution condition in aerifing the needle, avoids cavity glass inert gas's atmospheric pressure too big destruction sealing layer, and then reaches the harmless inflated effect.

Description

Hollow glass inflation device

Technical Field

The utility model belongs to cavity glass manufacture equipment field, especially a cavity glass aerating device.

Background

The hollow glass filled with inert gas needs two sealing layers, the first sealing layer needs to maintain the vacuum state in the hollow glass, the first sealing layer is sealed after the inflation is finished so as to ensure that the filled inert gas can be sealed in the gap of the hollow glass, the existing air pressure detection device detects the hollow layer, but the detection data has network delay in the transmission and the gas density of each gas is different from the pressure value, so that the vacuum is easily filled with excessive or small amount of gas, and the hollow glass sealing layer is often damaged by the filled excessive inert gas.

Disclosure of Invention

The purpose of the invention is as follows: provides a hollow glass inflation device to solve the problems in the prior art.

The technical scheme is as follows: an insulating glass aerating device, the device fixed mounting includes above insulating glass's transmission band: the conveying belt comprises a fixed seat arranged at the bottom of the conveying belt, an inflating device fixedly arranged on the fixed seat and a glue supply device arranged on the fixed seat;

the inflator includes: the device comprises a support frame fixedly arranged on a fixed seat, a transmission device fixedly arranged at the top of the support frame, and an inflation needle arranged at the output end of the transmission device; the inflation needle is of a hollow structure, one end of the inflation needle is fixedly inserted with the conical heating nozzle, the inflation needle is communicated with the inflation tube, and the other end of the inflation tube is communicated with the inflation valve and is communicated with the inflator.

In a further embodiment, the transmission comprises: the lifting mechanism comprises a support plate fixedly arranged on a support frame, a screw rod assembly fixedly arranged on the support frame, a lifting pressure cylinder fixedly arranged on the screw rod assembly, and a piston rod arranged in the lifting pressure cylinder and inserted through a panel of the support frame; one end of the lead screw component is in transmission connection with a driving motor.

In a further embodiment, the inflation needle is fixedly connected with the output end of the piston rod through the connecting seat.

In a further embodiment, the outside of the gas-filled tube is provided with a cooling device; an infrared image detection device is arranged on the support frame.

In a further embodiment, a gap is arranged between the conical heating nozzle and the inflation needle, and the conical heating nozzle is provided with a plurality of through holes.

In a further embodiment, a rubber supply pipe is inserted into one side of the conical heating nozzle and is communicated with the rubber supply device.

In a further embodiment, the support frame is further provided with an electric push rod, and the output end of the electric push rod is fixedly connected with the conical heating nozzle.

Has the advantages that: the utility model discloses a toper heating nozzle opens a hole in the first sealing layer when heating refrigerated inert gas and conveniently aerifys, overflows from aerifing the needle after being full of gas in the cavity glass to infrared image detection device detects the gaseous cold and hot distribution condition in aerifing the needle, and then detects the inflation condition of inert gas in the cavity glass, avoids the too big damage sealing layer of inert gas's atmospheric pressure in the cavity glass, and then reaches the harmless inflated effect.

Drawings

Fig. 1 is a schematic structural view of a hollow glass inflator according to the present invention.

FIG. 2 is an enlarged view of point A in FIG. 1

Fig. 3 is a plan view of the hollow glass inflator of the present invention.

The reference signs are: the device comprises a fixed seat 1, an inflation device 2, an inflation needle 20, an inflation tube 21, a glue supply device 4, a support frame 5, a support plate 50, a transmission device 6, a lead screw assembly 60, a driving motor 61, a lifting cylinder 62, a piston rod 63, a conical heating nozzle 7, a through hole 70, a cooling device 8, a glue supply tube 9, a conveying belt 11, an electric push rod 12 and an infrared image detection device 13.

Detailed Description

In the following description, numerous specific details are set forth in order to provide a more thorough understanding of the present invention. It will be apparent, however, to one skilled in the art, that the present invention may be practiced without one or more of these specific details. In other instances, well-known features have not been described in order to avoid obscuring the present invention.

The applicant finds that inert gas is filled in hollow glass, the index of the heat transfer coefficient of the hollow glass can be effectively reduced, and then the effects of heat preservation and cold insulation are achieved, the hollow glass filled with the inert gas needs two sealing layers, the first sealing layer needs to maintain the vacuum state in the hollow glass, the second sealing layer needs to be carried out simultaneously with an inflation tool, so that the filled inert gas can be sealed in a hollow glass gap, the existing air pressure detection device is used for detecting the hollow layer, but network delay exists in the transmission of detection data, and then excessive gas is filled in the vacuum, and the hollow glass sealing layer can be damaged frequently by the excessive inert gas.

An insulated glass inflator as shown in fig. 1 to 3 includes: the device comprises a fixed seat 1, an inflation device 2, an inflation needle 20, an inflation tube 21, a glue supply device 4, a support frame 5, a support plate 50, a transmission device 6, a lead screw assembly 60, a driving motor 61, a lifting cylinder 62, a piston rod 63, a conical heating nozzle 7, a through hole 70, a cooling device 8, a glue supply tube 9, a conveying belt 11, an electric push rod 12 and an infrared image detection device 13.

Wherein the device fixed mounting includes above cavity glass's transmission band: the device comprises a fixed seat 1 arranged at the bottom of a conveying belt 11, an inflating device 2 fixedly arranged on the fixed seat 1 and a glue supply device 4 arranged on the fixed seat 1;

the inflator 2 includes: the device comprises a support frame 5 fixedly arranged on a fixed seat 1, a transmission device 6 fixedly arranged at the top of the support frame 5, and an inflation needle 20 arranged at the output end of the transmission device 6; the inflation needle 20 is of a hollow structure, one end of the inflation needle 20 is fixedly inserted with the conical heating nozzle 7, the inflation needle 20 is communicated with the inflation tube 21, and the other end of the inflation tube 21 is communicated with the inflation valve and communicated with the inflator.

The transmission 6 comprises: the lifting mechanism comprises a support plate 50 fixedly arranged on a support frame 5, a screw rod assembly 60 fixedly arranged on the support frame 5, a lifting pressure cylinder 62 fixedly arranged on the screw rod assembly 60, and a piston rod 63 arranged in the lifting pressure cylinder 62 and penetrating through a panel of the support frame 5; one end of the screw assembly 60 is in transmission connection with a driving motor 61, and then the power of the driving motor 61 drives a lifting pressure cylinder 62 to move on the guide rails at the two sides of the screw assembly 60, so that the position of the inflation needle 20 is adjusted according to the thickness of the hollow glass and the position of the inflation inlet.

The inflation needle 20 is fixedly connected with the output end of the piston rod 63 through the connecting seat, and the lifting pressure cylinder 62 drives the piston rod 63 to move and simultaneously drives the inflation needle 20 to move up and down, so that the first sealing layer is pulled out and inserted in the inflation process.

A cooling device 8 is arranged outside the inflation tube 21; the cooling device 8 is sleeved outside the inflation tube 21 by adopting a winding condenser, so that the inert gas inflated in the inflation process can be cooled, and the inflation end of the inflation needle 20 is cooled; the infrared image detection device 13 arranged on the support frame 5 can monitor the cold and hot conditions of the inflating needle 20 in real time, and further judge whether the inert gas in the hollow glass is full of inert gas.

Be equipped with the space between toper heating nozzle 7 and the inflating needle 20, a plurality of through-holes 70 have been seted up on the toper heating nozzle 7, the one side grafting of toper heating nozzle 7 has supply rubber pipe 9, supply rubber pipe 9 and glue supply device 4 intercommunication, and then the colloid in the glue supply device 4 gets into toper heating nozzle 7 through supply rubber pipe 9 and spills over from toper heating nozzle 7 through-hole 70 once more, and electric putter 12 drives toper heating nozzle 7 and rises, and the colloid fuses with the hot melt adhesive of first sealing layer, repairs the inflation inlet that originally melts.

Still install electric putter 12 on support frame 5, electric putter 12's output and toper heating mouth 7 fixed connection, and then electric putter 12 drives toper heating mouth 7 up-and-down motion, and electric putter 12 drives toper heating mouth 7 downstream before aerifing, acts on toper heating mouth 7 on first sealing layer, and then rises behind the hot melt outlet inflation mouth on first sealing layer, and electric putter 12 drives toper heating mouth 7 downstream after the completion of aerifing, and the hot melt adhesive supply is in the inflation mouth department of first sealing layer, blocks up to make it form sealedly to the inflation mouth.

The working principle is as follows:

the hollow glass with the first sealing layer is vacuumized and then placed on the conveying belt 11, the hollow glass is conveyed by the conveying belt 11 to the lower part of the inflating device 2, and the position of the inflating needle 20 is adjusted according to the thickness of the hollow glass and the position of an inflating opening; the power of the driving motor 61 drives the lifting pressure cylinder 62 to move on the guide rails at two sides of the lead screw component 60, so that the inflating needle 20 corresponds to the first sealing layer, the lifting pressure cylinder 62 drives the piston rod 63 to move and simultaneously drives the inflating needle 20 to move up and down, the conical heating nozzle 7 is melted out of the inflating hole in the first sealing layer in the descending process, the inflating needle 20 extends into the inflating hole, the inflator is started, the inert gas enters the hollow glass through the cooling device 8, and the temperature of the inert gas is increased through the conical heating nozzle 7; after the hollow glass is filled with air, the hollow glass overflows into the inflating needle 20 from the bottom, when the infrared image detection device 13 detects the overflow condition, the lifting and lowering hydraulic cylinder 62 drives the piston rod 63 to move upwards, the inflating needle 20 and the conical heating nozzle 7 move upwards, the electric push rod 12 drives the conical heating nozzle 7 to move downwards in the direction opposite to the direction of the inflating needle 20, so that the inflating needle 20 is far away from the conical heating nozzle 7, the electric push rod 12 drives the conical heating nozzle 7 to move downwards before inflation, the conical heating nozzle 7 acts on a first sealing layer, then the conical heating nozzle 7 is heated and melted out of the inflating opening on the first sealing layer and then rises, after inflation is completed, the electric push rod 12 drives the conical heating nozzle 7 to move downwards, hot melt adhesive is supplemented at the inflating opening of the first sealing layer to block the inflating opening to form sealing, the hot melt adhesive overflows from the conical heating nozzle 7 through the plurality of through holes 70 to be combined with the first sealing layer, and then the repair of the inflation hole is completed to prevent the inert gas inflated into the inflation hole from gushing out, and the second sealant treatment is timely carried out on the hollow glass after the inflation is completed.

The utility model discloses a toper heating mouth 7 is opened a hole in the first sealing layer when heating refrigerated inert gas and is convenient for aerify needle 20 and get into and aerify, spill over from aerifing needle 20 after being full of gas in the cavity glass to infrared image detection device 13 detects the gaseous cold and hot distribution condition in aerifing needle 20, and then detects cavity glass in inert gas's the condition of aerifing, avoid cavity glass in inert gas's atmospheric pressure too big destruction sealing layer, and then reach the harmless inflated effect.

The preferred embodiments of the present invention have been described in detail with reference to the accompanying drawings, however, the present invention is not limited to the details of the above embodiments, and the technical concept of the present invention can be modified to perform various equivalent transformations, which all belong to the protection scope of the present invention.

Claims (7)

1. An insulating glass aerating device, which is characterized in that the device is fixedly arranged above a conveying belt of insulating glass, and comprises: the conveying belt comprises a fixed seat arranged at the bottom of the conveying belt, an inflating device fixedly arranged on the fixed seat and a glue supply device arranged on the fixed seat;

the inflator includes: the device comprises a support frame fixedly arranged on a fixed seat, a transmission device fixedly arranged at the top of the support frame, and an inflation needle arranged at the output end of the transmission device; the inflation needle is of a hollow structure, one end of the inflation needle is fixedly inserted with the conical heating nozzle, the inflation needle is communicated with the inflation tube, and the other end of the inflation tube is communicated with the inflation valve and is communicated with the inflator.

2. The insulated glass inflation device of claim 1, wherein the actuator comprises: the lifting mechanism comprises a support plate fixedly arranged on a support frame, a screw rod assembly fixedly arranged on the support frame, a lifting pressure cylinder fixedly arranged on the screw rod assembly, and a piston rod arranged in the lifting pressure cylinder and inserted through a panel of the support frame; one end of the lead screw component is in transmission connection with a driving motor.

3. The hollow glass inflation device of claim 1, wherein the inflation needle is fixedly connected with the output end of the piston rod through a connecting seat.

4. The hollow glass inflation device of claim 1, wherein a cooling device is provided outside the inflation tube; an infrared image detection device is arranged on the support frame.

5. The hollow glass inflation device of claim 1, wherein a gap is provided between the conical heating nozzle and the inflation needle, and the conical heating nozzle is provided with a plurality of through holes.

6. The hollow glass inflation device of claim 1, wherein a rubber supply tube is inserted into one side of the conical heating nozzle, and the rubber supply tube is communicated with the rubber supply device.

7. The hollow glass inflation device of claim 1, wherein the support frame is further provided with an electric push rod, and an output end of the electric push rod is fixedly connected with the conical heating nozzle.

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