CN214829907U - Cooling water circulation device based on material pool and glass particle material fishing system - Google Patents

Abstract

The application discloses cooling water circulating device and glass granule drag for material system based on material pond, cooling water circulating device based on material pond includes: the sedimentation tank is communicated with the material tank through a first connecting pipe; the water inlet of the cooling water tower is communicated with the sedimentation tank through a second connecting pipe; the water storage tank is communicated with a water outlet of the cooling water tower through a third connecting pipe and is communicated with the material tank through a fourth connecting pipe; the rose box, the rose box sets up in the sedimentation tank, and be used for accepting the water of arranging into the sedimentation tank of first connecting pipe, this scheme is for prior art, cooling water in the pond carries to the sedimentation tank through first connecting pipe, after the sedimentation tank deposits then cools off the cooling water in the sedimentation tank through cooling tower, and carry to the cistern, cooling water in the pond at last carries to the pond in through the fourth connecting pipe, in order to reduce the temperature of cooling water in the pond, in order to can be to the stable quenching of glass liquid.

Description

Cooling water circulation device based on material pool and glass particle material fishing system

Technical Field

The application relates to the field of glass, in particular to a cooling water circulating device and a glass particle fishing system based on a material pool.

Background

The production of foam glass requires melting furnace glass as a raw material. When the glass in the melting furnace passes through the glass furnace for production, the temperature of the glass liquid in the glass furnace is 1400-1500 ℃, and the temperature of the glass liquid flowing out from the furnace is 1100-200 ℃. The molten glass flows into a material pool containing cooling water, and when the molten glass is subjected to quenching and cooling by using the water, the molten glass is changed into glass particles.

At present, cooling water is in a boiling state under the heating of molten glass, and at the moment, the cold quenching of the molten glass is influenced.

SUMMERY OF THE UTILITY MODEL

In order to solve the problem, the cooling water circulating device and the glass particle fishing system based on the feed tank provided by the application can reduce the temperature of the cooling water in the feed tank.

The application provides a cooling water circle device based on material pond includes:

the sedimentation tank is communicated with the material tank through a first connecting pipe, and the first connecting pipe is provided with a first water pump;

the cooling water tower is provided with a water inlet and a water outlet, and the water inlet of the cooling water tower is communicated with the sedimentation tank through a second connecting pipe;

the water storage tank is communicated with a water outlet of the cooling water tower through a third connecting pipe, the water storage tank is communicated with the material tank through a fourth connecting pipe, the fourth connecting pipe is provided with a second water pump, the water storage tank and the sedimentation tank share the same side wall, and the side wall is lower than the water storage tank and the rest side walls of the sedimentation tank;

and the filter box is arranged in the sedimentation tank and is used for receiving the water of the first connecting pipe, which is discharged into the sedimentation tank.

Several alternatives are provided below, but not as an additional limitation to the above general solution, but merely as a further addition or preference, each alternative being combinable individually for the above general solution or among several alternatives without technical or logical contradictions.

Optionally, the same side wall shared by the reservoir and the sedimentation tank is a first side wall, and the rest side walls are second side walls;

the first side wall is 20-40 cm lower than the second side wall.

Optionally, the top of the filter box is provided with an opening, and the inner wall of the filter box is provided with a channel communicated with the sedimentation tank;

the filter box is internally provided with a filter basket which is arranged at the opening of the filter box.

Optionally, the bottom wall and the side wall of the filter basket are provided with a plurality of filter holes;

and a shunt opening communicated with the filter box is formed in the side wall of the filter basket.

Optionally, the height of the diversion port is 5cm to 10cm higher than the bottom wall of the filter basket.

Optionally, the filter box is provided with a support step, and the outer periphery of the opening of the filter basket is overlapped on the support step.

Optionally, the cooling water circulation device based on the material pool further comprises a flow guide pipe, the flow guide pipe is located in the sedimentation tank, and the bottom of the flow guide pipe is communicated with the sedimentation tank;

one end of the second connecting pipe, which faces the sedimentation tank, is arranged in the guide pipe.

Optionally, the flow guide pipe is mounted on the side wall of the sedimentation tank, and the bottom of the flow guide pipe is open;

the bottom of the flow guide pipe and the bottom wall of the sedimentation tank are provided with a certain gap, and the top of the flow guide pipe is flush with the top of the sedimentation tank.

Optionally, the first connecting pipe, the second connecting pipe and the fourth connecting pipe are all configured with electromagnetic valves.

The application also provides the following technical scheme:

glass particle drags for material system includes the stock chest and any one above the cooling water circulating device based on stock chest.

The utility model provides a cooling water circle device and glass granule drag for material system based on feed tank, the cooling water in the feed tank is carried to the sedimentation tank through first connecting pipe, after the sedimentation tank sediment then cools off the cooling water in the sedimentation tank through cooling tower to carry to the cistern, the cooling water in the final cistern passes through the fourth connecting pipe and carries to the feed tank in, with the temperature that reduces the feed tank cooling water, with can be to the stable quenching of glass liquid.

Drawings

Fig. 1 is a schematic structural diagram of a cooling water circulation device based on a material pool according to an embodiment of the present disclosure;

FIG. 2 is a schematic diagram of the sedimentation tank and the water reservoir of FIG. 1;

FIG. 3 is a schematic view of the filter box of FIG. 1;

FIG. 4 is a schematic structural diagram of a glass particle scooping system according to an embodiment of the present disclosure;

FIG. 5 is a schematic structural diagram of the material guiding bin in FIG. 4;

FIG. 6 is a schematic structural view of a material pool and a material scooping machine;

fig. 7 is a schematic structural view of the fishing hopper in fig. 6.

The reference numerals in the figures are illustrated as follows:

100. a material fishing system;

10. a material pool; 11. an outer frame;

20. fishing out the material machine; 21. a rotating shaft; 22. a motor; 23. a first sprocket; 24. a second sprocket; 25. a chain; 26. fishing a hopper; 261. a water leakage hole; 27. a rotary plate rack;

30. a material guide member; 31. an inlet; 32. an outlet;

40. a cooling water circulating device; 41. a sedimentation tank; 411. a first side wall; 412. a second side wall; 42. a cooling water tower; 43. a reservoir; 44. a filter box; 441. a channel; 442. a filter basket; 443. a shunt port; 444. supporting a step; 45. a first connecting pipe; 451. a second connecting pipe; 452. a third connecting pipe; 453. a fourth connecting pipe; 46. a first water pump; 461. a second water pump; 47. a flow guide pipe; 48. an electromagnetic valve.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

It will be understood that when an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. When a component is referred to as being "disposed on" another component, it can be directly on the other component or intervening components may also be present.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs. The terminology used in the description of the present application herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

As shown in fig. 1 to 3, the present application provides a cooling water circulation device 40 based on a material pool 10, which comprises a sedimentation tank 41, a cooling water tower 42 and a water reservoir 43. Wherein, the sedimentation tank 41 is communicated with the material tank 10 through a first connecting pipe 45; the cooling water tower 42 is a conventional cooling water tower, and has a water inlet (not shown) and a water outlet (not shown), wherein the water inlet of the cooling water tower 42 is communicated with the sedimentation tank 41 through a second connecting pipe 451; the reservoir 43 is connected to the outlet of the cooling tower 42 through a third connection pipe 452, and the reservoir 43 is connected to the material tank 10 through a fourth connection pipe 453.

The cooling water in the material tank 10 is delivered to the sedimentation tank 41 through the first connection pipe 45, at this time, the cooling water may carry glass particles, the portion of the glass particles is precipitated through the sedimentation tank 41, then the cooling water in the sedimentation tank 41 is cooled through the cooling water tower 42 and delivered to the water storage tank 43, and finally the cooling water in the water storage tank 43 is delivered into the material tank 10 through the fourth connection pipe 453, so as to reduce the temperature of the cooling water in the material tank 10, thereby enabling stable quenching of the molten glass.

Wherein, the first connecting pipe 45 is provided with a first water pump 46 to stably convey the cooling water in the material tank 10 to the sedimentation tank 41; the fourth connection pipe 453 is provided with a second water pump 461 to stably feed the cooling water in the reservoir 43 into the pond 10. In this embodiment, the first water pump 46 and the second water pump 461 have the same power to ensure that the water output and the water input of the material tank 10 are the same.

In order to facilitate the control of the first, second, and third connection pipes 45, 451, and 452, referring to one embodiment, as shown in fig. 1, the first, second, and fourth connection pipes 45, 451, and 453 are provided with solenoid valves 48.

When the cooling water tower 42 is shut down due to a trouble or the like, since the cooling water is continuously supplied to the sedimentation tank 41 and the cooling water is continuously discharged from the reservoir 43, problems such as emptying of the cooling water in the reservoir 43 or overflow of the cooling water in the reservoir 43 may occur. In order to solve the technical problem, as shown in fig. 2, the reservoir 43 and the sedimentation tank 41 share the same side wall, and the side wall is lower than the reservoir 43 and the rest of the side walls of the sedimentation tank 41, the same side wall shared by the reservoir 43 and the sedimentation tank 41 is a first side wall 411, and the rest of the side walls are second side walls 412, and the internal cooling water in the reservoir 43 enters the reservoir 43 from the top of the first side wall 411. In the present embodiment, the first side wall 411 is lower than the second side wall 412: 20 cm-40 cm.

In order to enhance the sedimentation effect of the sedimentation tank 41, in the present embodiment, as shown in fig. 1, the cooling water circulation device 40 based on the material tank 10 further includes a filter tank 44, the filter tank 44 is disposed in the sedimentation tank 41 and is used for receiving the water of the first connection pipe 45 discharged into the sedimentation tank 41, and the cooling water is pre-filtered by the filter tank 44, and at the same time, the filtered glass particles can be conveniently taken out. Wherein, the top of the filtering box 44 is opened, and the inner wall of the filtering box 44 is provided with a channel 441 communicated with the sedimentation tank 41.

Further, as shown in fig. 3, a filter basket 442 is disposed in the filter tank 44, the filter basket 442 is mounted at an opening of the filter tank 44, and a plurality of filter holes are formed in a bottom wall and a side wall of the filter basket 442. When the amount of glass particles is large, the filter basket 442 may not filter the cooling water in time, and at this time, a diversion opening 443 communicating with the filter box 44 is opened on the side wall of the filter basket 442, and the excess cooling water flows out of the filter basket 442 through the diversion opening 443.

In this embodiment, the height of the diversion opening 443 is 5cm to 10cm higher than the bottom wall of the filter basket 442. The diverter 443 being too high relative to the bottom wall of the filter basket 442 may cause the filter basket 442 to be less compact; when the diversion opening 443 is too low relative to the bottom wall of the filter basket 442, the filter basket 442 may not filter the cooling water in time, and the cooling water may flow out of the diversion opening 443.

In the fitting relationship between the filter basket 442 and the filter box 44, referring to fig. 3, in one embodiment, the filter box 44 is provided with a supporting step 444, and the outer periphery of the opening of the filter basket 442 is overlapped on the supporting step 444 to facilitate the mounting and dismounting of the filter basket 442.

In order to prevent the glass particles from entering the cooling water tower 42, as shown in fig. 1 and 2, the cooling water circulation device 40 based on the material tank 10 further includes a flow guide pipe 47, wherein the flow guide pipe 47 is located in the sedimentation tank 41, and the bottom of the flow guide pipe 47 is communicated with the sedimentation tank 41; the end of the second connection pipe 451 facing the sedimentation tank 41 is disposed in the flow guide pipe 47. The cooling water in the flow guide pipe 47 is relatively stable with respect to the cooling water in the sedimentation tank 41, so that the cooling water in the flow guide pipe 47 contains less glass particles.

The draft tube 47 is specifically arranged, the draft tube 47 is arranged on the side wall of the sedimentation tank 41, and the bottom of the draft tube 47 is open; the bottom of the draft tube 47 is spaced from the bottom wall of the settling tank 41, and the top of the draft tube is flush with the top of the settling tank 41.

As shown in fig. 1 and fig. 4 to 7, the present application further provides a glass particle scooping system 100, which includes a material pool 10 and a cooling water circulation device 40 based on the material pool 10, wherein the cooling water circulation device 40 based on the material pool 10 can adopt the cooling water circulation device 40 based on the material pool 10 in the above embodiments.

The glass particle fishing system 100 further comprises a fishing machine 20 and a material guiding member 30, cooling water is contained in the material pool 10, when glass liquid flows into the material pool 10, the glass liquid is cooled rapidly through the cooling water, the glass liquid can become glass particles, the glass particles in the material pool 10 are fished out through the fishing machine 20, and then the glass particles are conveyed through the material guiding member 30.

Material fetching machine 20 includes rotary plate frame 27 and installs in a plurality of buckets 26 of rotary plate frame 27 periphery, and rotary plate frame 27 is rotatable to be installed in the material pond 10, and rotary plate frame 27's axis of rotation is the level setting, and each bucket 26 of fetching is the opening setting, and each bucket 26 of fetching is fixed for rotary plate frame 27's opening orientation.

Wherein, drag for material machine 20 to have and drag for the material level and incline the material level, drag for hopper 26 to be located when dragging for the material level, drag for hopper 26 to drag for the interior glass particle of material pond 10 to salvage, drag for hopper 26 to be located when inclining the material level, drag for the opening of hopper 26 and set up down, incline the material. In the present embodiment, the scooping position is located at the bottom of the scooping machine 20, and the dumping position is located at the top of the scooping machine 20; in the process of transferring the fishing material level of the fishing hopper 26 from the fishing material level to the fishing material level, the opening of the fishing hopper 26 is gradually inclined downwards.

In the present embodiment, as shown in fig. 7, a water leakage hole 261 is formed in the bottom of each scooping hopper 26, and when the scooping hopper 26 scoops the glass particles and leaves the cooling water, the water in the scooping hopper 26 can flow out through the water leakage hole 261.

In order to make the glass particles poured from the scooping hopper 26 enter the material guiding member 30, part of the structure of the material guiding member 30 is located below the pouring position, so that the orthographic projection of the scooping hopper 26 located at the pouring position falls into the orthographic projection area of the material guiding member 30. In the specific arrangement of the material guiding member 30, referring to one embodiment, as shown in fig. 5, the material guiding member 30 is a box structure, the box structure is provided with an inlet 31 and an outlet 32 which are opposite to each other, and a material scooping hopper 26 located at the material tilting position, and an orthographic projection of the material scooping hopper 26 falls into an orthographic projection area of the inlet 31 of the material guiding member 30. Of course, in other embodiments, the material guiding member 30 may also be plate-shaped, so as to simplify the structure of the material guiding member 30.

The rotary tray frame 27 is rotatably installed on the material tank 10 through a rotary shaft 21, and two ends of the rotary shaft 21 are fixed on the material tank 10 through bearings and bearing seats. In order to drive the rotating shaft 21 to rotate, referring to one embodiment, as shown in fig. 4, an outer frame 11 is installed outside the material tank 10, a motor 22 is installed on the outer frame 11, an output end of the motor 22 is provided with a first chain wheel 23, the rotating shaft 21 is coaxially provided with a second chain wheel 24, a chain 25 is wound on the first chain wheel 23 and the second chain wheel 24, and the motor 22 drives the rotating shaft 21 to rotate through the chain 25.

The technical features of the above embodiments can be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the above embodiments are not described, but should be considered as the scope of the present specification as long as there is no contradiction between the combinations of the technical features. When technical features in different embodiments are represented in the same drawing, it can be seen that the drawing also discloses a combination of the embodiments concerned.

The above examples only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the claims. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application.

Claims (10)

1. Cooling water circulating device based on material pond, its characterized in that includes:

the sedimentation tank is communicated with the material tank through a first connecting pipe, and the first connecting pipe is provided with a first water pump;

the cooling water tower is provided with a water inlet and a water outlet, and the water inlet of the cooling water tower is communicated with the sedimentation tank through a second connecting pipe;

the water storage tank is communicated with a water outlet of the cooling water tower through a third connecting pipe, the water storage tank is communicated with the material tank through a fourth connecting pipe, the fourth connecting pipe is provided with a second water pump, the water storage tank and the sedimentation tank share the same side wall, and the side wall is lower than the water storage tank and the rest side walls of the sedimentation tank;

and the filter box is arranged in the sedimentation tank and is used for receiving the water of the first connecting pipe, which is discharged into the sedimentation tank.

2. The material pond-based cooling water circulation device according to claim 1, wherein the same side wall shared by the reservoir and the sedimentation tank is a first side wall, and the remaining side walls are second side walls;

the first side wall is 20-40 cm lower than the second side wall.

3. The cooling water circulation device based on the material pool according to claim 1, wherein the top of the filter box is open, and the inner wall of the filter box is provided with a channel communicated with the sedimentation tank;

the filter box is internally provided with a filter basket which is arranged at the opening of the filter box.

4. The material pond-based cooling water circulation device according to claim 3, wherein the bottom wall and the side wall of the filter basket are provided with a plurality of filter holes;

and a shunt opening communicated with the filter box is formed in the side wall of the filter basket.

5. The material pond-based cooling water circulation device according to claim 4, wherein the height of the diversion port is 5-10 cm higher than the bottom wall of the filter basket.

6. The cooling water circulation device according to claim 4, wherein the filter box is provided with a support step on which the outer circumference of the opening of the filter basket is rested.

7. The material pool-based cooling water circulation device according to claim 1, further comprising a flow guide pipe, wherein the flow guide pipe is located in the sedimentation tank, and the bottom of the flow guide pipe is communicated with the sedimentation tank;

one end of the second connecting pipe, which faces the sedimentation tank, is arranged in the guide pipe.

8. The cooling water circulation device based on the material pool of claim 7, wherein the flow guide pipe is installed on the side wall of the sedimentation tank, and the bottom of the flow guide pipe is open;

the bottom of the flow guide pipe and the bottom wall of the sedimentation tank are provided with a certain gap, and the top of the flow guide pipe is flush with the top of the sedimentation tank.

9. The pond-based cooling water circulation device according to claim 1, wherein the first connection pipe, the second connection pipe, and the fourth connection pipe are each provided with a solenoid valve.

10. The glass particle fishing system is characterized by comprising a material pool and the cooling water circulation device based on the material pool, wherein the cooling water circulation device based on the material pool is defined by any one of claims 1 to 9.

Images