CN211972141U - Powder adding device and glass chemical toughening production equipment - Google Patents

Abstract

A powder adding device and glass chemical toughening production equipment. This powder adds device includes: the feeding pipe is provided with a feeding end and a discharging end, and the feeding end is used for being communicated with equipment for storing powder; the storage hopper is communicated with the discharge end of the feeding pipe; the storage box is communicated with the lower end of the storage material; the vibration storage bin is communicated with the storage box; the feeding pipes are communicated with the vibration bin; the first switch mechanism is used for opening or closing a communication passage between the storage hopper and the storage box; and the second switch mechanism is used for opening or closing a communication passage between the storage box and the vibration storage bin. This powder adds device simple structure, occupation space are little, low cost, can realize that the automation of TSP material powder adds in the glass tempering production operation, and this powder adds the device and can the direct mount to current glass tempering production line in addition, need not to carry out extensive transformation to current glass tempering production line, has extremely strong application prospect.

Description

Powder adding device and glass chemical toughening production equipment

Technical Field

The utility model relates to a glass tempering technical field, concretely relates to powder adds device and glass chemical tempering production facility.

Background

In the glass processing industry, the glass is generally strengthened by a chemical strengthening method to obtain toughened glass with higher strength, and the principle is that the glass or glass products to be toughened are placed in a high-temperature molten salt bath containing potassium nitrate to be soaked for a certain time, and sodium ions and lithium ions with small ionic radii in the glass and potassium ions with larger ionic radii in the salt bath containing potassium nitrate are replaced, so that a compressive stress layer is generated on the surface of the glass, and the purpose of improving the strength of the glass is achieved.

The operation flow of the existing glass toughening production line is that glass to be strengthened is fed into a holding furnace, and then the glass with the strengthened glass is conveyed to a toughening furnace by the holding furnace. Usually, the toughening furnace needs to add TSP material powder before starting operation. However, the existing operation of adding the TSP material powder is implemented manually, so that the glass tempering production line has the problems of more operators, high labor intensity, long production time, low efficiency and the like.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that a simple structure, occupation space are little, low cost's powder adds device is provided, through using the powder adds the device and can realize that the automation of TSP material powder adds in the glass tempering production operation, moreover the powder adds the device and can directly install on current glass tempering production line, need not to carry out extensive transformation to current glass tempering production line, has extremely strong application prospect.

The utility model aims to solve another technical problem that a glass chemical tempering production facility is provided, it includes as above the powder add the device, can realize the automatic interpolation of TSP material powder to reduce operation personnel's intensity of labour, and improve production efficiency.

In order to solve the technical problem, the utility model provides an adopted technical scheme is to provide a powder adds device, include:

the feeding pipe is provided with a feeding end and a discharging end, and the feeding end is communicated with equipment for storing powder;

the storage hopper is communicated with the discharge end of the feeding pipe;

the upper end of the storage box with adjustable volume is communicated with the lower end of the stored material;

the upper end of the vibration storage bin is communicated with the lower end of the storage box;

the upper end of each feeding pipe is communicated with the lower end of the vibration storage bin;

the first switch mechanism is used for opening or closing a communication passage between the storage hopper and the storage box;

and the second switch mechanism is used for opening or closing a communication passage between the storage box and the vibration storage bin.

In the powder adding device provided by the utility model, the upper end of the storage box is provided with a feeding hole, and the storage box is communicated with the storage hopper through the feeding hole; the first switch mechanism comprises a first partition plate and a first driver, the first partition plate is movably inserted into the storage box, the first partition plate is provided with a first door opening position and a first door closing position, the first partition plate closes the feeding port when in the first door closing position, and the first partition plate opens the feeding port when in the first door opening position; the first driver is connected with the first partition plate and used for driving the first partition plate to move between the first door opening position and the first door closing position.

In the powder adding device provided by the utility model, the lower end of the storage box is provided with a discharge hole, and the storage box is communicated with the vibration bin through the discharge hole; the second switch mechanism comprises a second partition plate and a second driver, the second partition plate is movably inserted into the storage box, the second partition plate is provided with a second door opening position and a second door closing position, the second partition plate closes the discharge hole when in the second door closing position, and the second partition plate opens the discharge hole when in the second door opening position; the second driver is connected with the second partition plate and used for driving the second partition plate to move between the second door opening position and the second door closing position.

In the powder adding device provided by the utility model, the storage box comprises an upper box body and a lower box body, the upper end of the upper box body is butted with the storage hopper, the lower end of the lower box body is butted with the vibration material bin, and the upper box body can be inserted into the lower box body in a vertically movable manner; the storage box also comprises an adjusting structure for adjusting the depth of the upper box body inserted into the lower box body.

The utility model provides an among the powder adds the device, adjust the structure including being fixed in go up the first pedestal in the box body outside, be fixed in second pedestal and adjusting screw in the box body outside down, adjusting screw passes from bottom to top first pedestal holds on the top the second pedestal, adjusting screw with threaded connection between the first pedestal.

The utility model provides an among the powder adds the device, the vibration feed bin include the box and install in the shock dynamo in the box outside.

The utility model provides an among the powder adds the device, each the lower extreme of conveying pipe all is equipped with the shower nozzle.

For solving foretell another technical problem, the utility model adopts the technical scheme that a glass chemical tempering production facility is provided, including heat preservation stove and tempering furnace, but the arrangement of heat preservation stove horizontal migration in tempering furnace's top, most importantly, glass chemical tempering production facility still includes as above the powder add the device, the powder add the device install in the outside of heat preservation stove.

The utility model provides an among the glass chemical tempering production facility, the powder add the device through with mounting plate that the storage box is connected fixes on the heat preservation stove.

The utility model provides an among the glass chemical tempering production facility, glass chemical tempering production facility is still including the storage bucket that is used for saving the powder, the exit of storage bucket is equipped with the strength conveyer, the strength conveyer through automatic butt joint with the feed end of inlet pipe is connected.

Implement the utility model provides a powder adds device and glass chemical tempering production facility can reach following beneficial effect:

1. the powder adding device is simple in structure, small in occupied space and low in cost, automatic addition of TSP material powder in glass tempering production operation can be achieved through the powder adding device, the powder adding device can be directly installed on an existing glass tempering production line, large-scale transformation on the existing glass tempering production line is not needed, and the powder adding device has a strong application prospect.

2. The chemical glass toughening production equipment is provided with the powder adding device, so that the automatic addition of the TSP material powder can be realized, the labor intensity of operators is reduced, and the production efficiency is improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the provided drawings without creative efforts:

FIG. 1 is a schematic perspective view (I) of a powder adding device provided by the present invention;

FIG. 2 is a schematic perspective view (II) of the powder adding device provided by the present invention;

fig. 3 is a schematic plan view of the glass chemical tempering production equipment provided by the utility model.

The reference numerals in the detailed description illustrate:

feed pipe	1	Storage hopper	2
				Storage box	3	Vibration storage bin	4
Feeding pipe	5	First partition board	61
				First cylinder	62	Second partition plate	71
The second cylinder	72	Upper box body	31
				Lower box body	32	First seat body	33
Second seat body	34	Adjusting screw	35
				Box body	41	Vibration motor	42
Spray head	51	Fixing plate	8
				Heat preservation furnace	100	Tempering furnace	200
Powder adding device	300	Mounting base plate	400
				Charging basket	500

Detailed Description

In order to better understand the technical solutions, the technical solutions will be described in detail below with reference to the drawings and the specific embodiments of the specification, and it should be understood that the specific features in the embodiments and examples of the present invention are detailed descriptions of the technical solutions of the present application, but not limitations of the technical solutions of the present application, and the technical features in the embodiments and examples of the present invention can be combined with each other without conflict.

Example one

The present embodiment provides a powder adding apparatus 300. Referring to fig. 1 and 2, the powder adding apparatus 300 includes a feeding pipe 1, a storage hopper 2, a storage box 3 with an adjustable volume, a vibration bin 4, a plurality of feeding pipes 5, a first switch mechanism, and a second switch mechanism. The feeding pipe 1 is provided with a feeding end and a discharging end, and the feeding end is communicated with equipment for storing powder; the storage hopper 2 is communicated with the discharge end of the feeding pipe 1; the upper end of the storage box 3 is communicated with the lower end of the stored material; the upper end of the vibration storage bin 4 is communicated with the lower end of the storage box 3; the upper end of each feeding pipe 5 is communicated with the lower end of the vibration storage bin 4; the first switch mechanism is used for opening or closing a communication passage between the storage hopper 2 and the storage box 3; the second switch mechanism is used for opening or closing a communication passage between the storage box 3 and the vibration storage bin 4.

When the first switch mechanism opens the communication passage between the storage hopper 2 and the storage box 3 and the second switch mechanism is used for closing the communication passage between the storage box 3 and the vibration bin 4, the powder in the powder storage device can enter the storage hopper 2 through the feeding pipe 1 under the action of the pneumatic conveyor and finally fall into the storage box 3. When the powder in the storage box 3 needs to be added into a designated device (for example, the toughening furnace 200), the lower end of the feeding pipe 5 is only required to be aligned with the designated device, then the communication path between the storage hopper 2 and the storage box 3 is closed through the first switch mechanism, meanwhile, the second switch mechanism is used for opening the communication path between the storage box 3 and the vibrating bin 4, at this time, the powder in the storage box 3 falls into the vibrating bin 4, and the vibrating bin 4 vibrates, so that the powder in the vibrating bin 4 is added into the designated device through the feeding pipe 5.

In this embodiment, the upper end of the storage box 3 is provided with a feeding port, and the storage box 3 is communicated with the storage hopper 2 through the feeding port; the first switch mechanism comprises a first partition plate 61 and a first driver, the first partition plate 61 is movably inserted into the storage box 3, the first partition plate 61 has a first door opening position and a first door closing position, the first partition plate 61 closes the feeding port when in the first door closing position, and the first partition plate 61 opens the feeding port when in the first door opening position; the first actuator is connected to the first partition 61 for actuating the first partition 61 to move between the first door-open position and the first door-closed position. Specifically, the first driver is installed in the storage box 3, the first partition plate 61 is transversely inserted into one end of the feeding port of the storage box 3, the first driver includes two first cylinders 62, piston rods of the two first cylinders 62 are connected with the first partition plate 61, and the first partition plate 61 moves on a horizontal plane under the driving of the two first cylinders 62, so that the position switching between a first door opening position and a first door closing position is realized.

In some other embodiments, the first driver may also be an electric motor, and a gear transmission may also be adopted between the first driving motor and the first partition board 61. It should be understood that these embodiments are within the scope of the present invention.

In this embodiment, the lower end of the storage box 3 is provided with a discharge hole, and the storage box 3 is communicated with the vibration bin 4 through the discharge hole; the second switch mechanism comprises a second partition plate 71 and a second driver, the second partition plate 71 is movably inserted into the storage box 3, the second partition plate 71 has a second door-opening position and a second door-closing position, the second partition plate 71 closes the discharge hole in the second door-closing position, and the second partition plate 71 opens the discharge hole in the second door-opening position; the second actuator is connected to the second partition 71 for actuating the second partition 71 to move between the second open door position and the second closed door position. Specifically, the second driver is installed in the storage box 3, the second partition plate 71 is transversely inserted into one end of the discharge hole of the storage box 3, the second driver includes two second air cylinders 72, piston rods of the two second air cylinders 72 are connected with the second partition plate 71, and the second partition plate 71 moves on a horizontal plane under the driving of the two second air cylinders 72, so that the position switching between the second door opening position and the second door closing position is realized.

In some other embodiments, the second driver may also be a motor, and a pulley transmission may be used between the second driving motor and the second partition 71. It should be understood that these embodiments are within the scope of the present invention.

In this embodiment, the storage box 3 includes an upper box body 31 and a lower box body 32, the upper end of the upper box body 31 is butted with the storage hopper 2, the lower end of the lower box body 32 is butted with the vibration bin 4, and the upper box body 31 can be inserted into the lower box body 32 in an up-and-down moving manner; the magazine 3 further comprises an adjusting structure for adjusting the depth of the upper box 31 inserted into the lower box 32. Specifically, the adjusting structure includes a first seat 33 fixed to the outer side of the upper box 31, a second seat 34 fixed to the outer side of the lower box 32, and an adjusting screw 35, the adjusting screw 35 penetrates the first seat 33 from bottom to top and supports the second seat 34, and the adjusting screw 35 is in threaded connection with the first seat 33. Thus, the height of the upper case 31 with respect to the lower case 32, that is, the depth of the upper case 31 inserted into the lower case 32, can be adjusted by screwing the adjusting screw 35. It should be understood that the volume of the magazine 3 is smaller the deeper the upper case 31 is inserted into the lower case 32, and the volume of the magazine 3 is larger the shallower the upper case 31 is inserted into the lower case 32, thereby achieving the adjustable volume of the magazine 3.

In this embodiment, the vibration material bin 4 includes a box 41 and a vibration motor 42 installed outside the box 41. Preferably, the lower end of the box body 41 is funnel-shaped, which is beneficial to the whole falling of the powder in the vibration bin 4.

In this embodiment, each of the feeding pipes 5 has a nozzle 51 at a lower end thereof, and the feeding pipes 5 are connected by two fixing plates 8, so that the nozzles 51 at the lower ends of the feeding pipes 5 are arranged in a row, thereby facilitating the uniform addition of powder.

Example two

The present embodiment provides a glass chemical toughening production device, referring to fig. 3, comprising a holding furnace 100 and a toughening furnace 200, wherein the holding furnace 100 is horizontally movably arranged above the toughening furnace 200, and most importantly, the glass chemical toughening production device further comprises a powder adding device 300 according to the first embodiment, and the powder adding device 300 is installed outside the holding furnace 100.

In this embodiment, the powder adding device 300 is fixed on the holding furnace 100 through a mounting base plate 400 connected to the storage box 3. Specifically, the glass chemical tempering production equipment comprises a plurality of tempering furnaces 200, the plurality of tempering furnaces 200 are arranged in a straight line in the front-back direction, and the holding furnace 100 can be linearly arranged above the plurality of tempering furnaces 200. The powder adding means 300 is fixed to the front side of the holding furnace 100 by the mounting base 400 (see fig. 1).

In this embodiment, the chemical tempering glass production equipment further comprises a charging bucket 500 for storing powder, wherein a pneumatic conveyor is arranged at an outlet of the charging bucket 500, and the pneumatic conveyor is connected with a feeding end of the feeding pipe 1 through an automatic butt joint. Specifically, the charging bucket 500 stores TSP material powder, a pneumatic conveyor at an outlet of the charging bucket 500 is connected with a hose, and the hose is connected with the feeding end through an automatic butt joint.

The automatic TSP material powder adding operation steps of the glass chemical toughening production equipment are as follows:

1) the holding furnace 100 is operated to a designated feeding position, at this time, an automatic butt joint at the feeding end of the feeding pipe 1 is aligned with a hose connected with the charging basket 500, and the automatic butt joint is automatically butted with the hose, so that the charging basket 500 is connected with the powder adding device 300;

2) after the pneumatic conveyor conveys a proper amount of TSP material powder to the powder adding device 300, the automatic butt joint automatically disconnects the hose, so that the charging basket 500 is separated from the powder adding device 300;

3) the heat preservation furnace 100 runs to a toughening furnace 200 to which TSP material powder is to be added, and the furnace cover of the toughening furnace 200 is opened;

4) the first partition plate 61 of the powder adding device 300 moves to a first door opening position, the second partition plate 71 moves to a second door closing position, and the TSP powder in the storage hopper 2 is conveyed into the storage box 3;

5) the first partition plate 61 of the powder adding device 300 moves to a first door closing position, the second partition plate 71 moves to a second door opening position, and the TSP material powder in the storage box 3 is conveyed to the vibrating bin 4;

6) the vibration bin 4 vibrates to send out TSP material powder inside to the lower toughening furnace 200 through the plurality of feeding pipes 5;

during the feeding process, the holding furnace 100 preferably moves at a constant speed.

It should be understood that the addition of the TSP material powder to each of the toughening furnaces 200 can be completed by repeating the above steps. The whole process can be carried out without human participation, and full-automatic TSP material powder addition is realized.

In conclusion, implement the utility model provides a powder adds device 300 and glass chemical tempering production facility can reach following beneficial effect:

1. the powder adding device 300 is simple in structure, small in occupied space and low in cost, automatic addition of TSP material powder in glass tempering production operation can be achieved through the powder adding device 300, the powder adding device 300 can be directly installed on an existing glass tempering production line, large-scale transformation on the existing glass tempering production line is not needed, and the powder adding device has a strong application prospect.

2. The chemical glass toughening production equipment is provided with the powder adding device 300, so that the automatic addition of TSP material powder can be realized, the labor intensity of operators is reduced, and the production efficiency is improved.

In the description of the present invention, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", etc. indicate the position or positional relationship based on the position or positional relationship shown in the drawings, and are only for convenience of description of the present invention and to simplify the description, but do not indicate or imply that the structure or unit to which the reference is made must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present invention. Furthermore, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless otherwise specified.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an illustrative embodiment," "an example," "a specific example," or "some examples" or the like mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

While the embodiments of the present invention have been described with reference to the accompanying drawings, the present invention is not limited to the above-described embodiments, which are merely illustrative and not restrictive, and many modifications may be made by one skilled in the art without departing from the spirit and scope of the present invention as defined in the appended claims.

Claims (10)

1. A powder adding device is characterized by comprising:

the feeding pipe is provided with a feeding end and a discharging end, and the feeding end is communicated with equipment for storing powder;

the storage hopper is communicated with the discharge end of the feeding pipe;

the upper end of the storage box with adjustable volume is communicated with the lower end of the stored material;

the upper end of the vibration storage bin is communicated with the lower end of the storage box;

the upper end of each feeding pipe is communicated with the lower end of the vibration storage bin;

the first switch mechanism is used for opening or closing a communication passage between the storage hopper and the storage box;

and the second switch mechanism is used for opening or closing a communication passage between the storage box and the vibration storage bin.

2. The powder adding device of claim 1, wherein the storage box has a feed inlet at its upper end, and the storage box is communicated with the storage hopper through the feed inlet; the first switch mechanism comprises a first partition plate and a first driver, the first partition plate is movably inserted into the storage box, the first partition plate is provided with a first door opening position and a first door closing position, the first partition plate closes the feeding port when in the first door closing position, and the first partition plate opens the feeding port when in the first door opening position; the first driver is connected with the first partition plate and used for driving the first partition plate to move between the first door opening position and the first door closing position.

3. The powder adding device as recited in claim 1, wherein the storage box has a discharge port at a lower end thereof, and the storage box is communicated with the vibration bin through the discharge port; the second switch mechanism comprises a second partition plate and a second driver, the second partition plate is movably inserted into the storage box, the second partition plate is provided with a second door opening position and a second door closing position, the second partition plate closes the discharge hole when in the second door closing position, and the second partition plate opens the discharge hole when in the second door opening position; the second driver is connected with the second partition plate and used for driving the second partition plate to move between the second door opening position and the second door closing position.

4. The powder adding device according to claim 1, wherein the storage box comprises an upper box body and a lower box body, the upper end of the upper box body is butted with the storage hopper, the lower end of the lower box body is butted with the vibration bin, and the upper box body can be inserted into the lower box body in an up-and-down moving manner; the storage box also comprises an adjusting structure for adjusting the depth of the upper box body inserted into the lower box body.

5. The powder adding device of claim 4, wherein the adjusting structure comprises a first seat fixed on the outer side of the upper box, a second seat fixed on the outer side of the lower box, and an adjusting screw, the adjusting screw passes through the first seat from bottom to top and supports the second seat, and the adjusting screw is in threaded connection with the first seat.

6. The powder adding device of claim 1, wherein the vibration silo comprises a box body and a vibration motor arranged outside the box body.

7. The powder adding apparatus according to claim 1, wherein a nozzle is provided at a lower end of each of said feed pipes.

8. A glass chemical tempering production device, comprising a holding furnace and a tempering furnace, wherein the holding furnace is horizontally arranged above the tempering furnace, the glass chemical tempering production device is characterized by further comprising a powder adding device according to any one of claims 1 to 7, and the powder adding device is arranged outside the holding furnace.

9. The chemical tempering production equipment for glass according to claim 8, wherein said powder adding device is fixed on said holding furnace through a mounting base plate connected with said storage box.

10. The chemical tempering production equipment for glass according to claim 8, further comprising a material barrel for storing powder, wherein a pneumatic conveyor is arranged at an outlet of the material barrel, and the pneumatic conveyor is connected with a feeding end of the feeding pipe through an automatic butt joint.

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