CN215983403U - Zero water sodium metasilicate cooling device for product - Google Patents

Abstract

The utility model relates to the technical field of inorganic silicide production, in particular to a cooling device for a zero-water sodium metasilicate product. The cooling device has reasonable design, realizes the cooling of the zero-water sodium metasilicate product, shortens the cooling time and greatly improves the cooling efficiency.

Description

Zero water sodium metasilicate cooling device for product

Technical Field

The utility model relates to the technical field of inorganic silicide production, in particular to a cooling device for a zero-water sodium metasilicate product.

Background

Granular sodium metasilicate free of water is generally produced by a heating and drying method, sodium silicate and caustic soda water are subjected to a thermal reaction, then hot air drying granulation is adopted, and a finished product is obtained by screening and is packaged for sale. The method is an international universal advanced process form, and the product quality can meet the standard requirement. The temperature of the dried finished product is higher by about 120 ℃, so that the finished product cannot be directly packaged, the finished product can only be placed into a cooling bin to be cooled and then can be packaged, but the finished product is cooled by the cooling bin, so that the cooling time is long, the cooling efficiency is low, and the heat dissipation of partial products is poor due to the fact that the products are stacked together.

SUMMERY OF THE UTILITY MODEL

The technical problem to be solved by the utility model is as follows: to prior art's not enough, provide a zero water sodium metasilicate cooling device for product, utilize this cooling device can carry out effective cooling to the product, shortened cooling time, improved cooling efficiency.

In order to solve the technical problems, the technical scheme of the utility model is as follows:

the utility model provides a zero water sodium metasilicate cooling device for product, cooling device includes cooling device body and sealed lid, the one end of cooling device body is equipped with the inlet pipe, the other end of cooling device body is equipped with the discharging pipe, the top of sealed lid is equipped with the air outlet, be equipped with vibrating device and a plurality of air intake on the outer wall of cooling device body, the inside of cooling device body is equipped with screen cloth and a plurality of cold wind distributor, every air intake of cold wind distributor intercommunication.

As an improved technical scheme, the cold air distributor comprises a cylindrical body, a plurality of cold air distribution pipes communicated with the body are arranged on the outer wall of the body, and a plurality of air distribution holes are uniformly formed in the pipe wall of each cold air distribution pipe.

As an improved technical scheme, the cold air distribution pipes are respectively arranged on the outer wall of the body in unequal heights and at equal intervals.

As an improved technical solution, the vibration device is a vibration motor disposed on the front and back outer walls of the cooling device body.

As an improved technical scheme, the cold air distributor is arranged below the screen.

As an improved technical scheme, the screen is obliquely arranged inside the cooling device body, and the aperture of the screen is smaller than the grain diameter of the product.

After the technical scheme is adopted, the utility model has the beneficial effects that:

because zero water sodium metasilicate cooling device for product, cooling device include cooling device body and sealed lid, and the one end of cooling device body is equipped with the inlet pipe, the other end of cooling device body is equipped with the discharging pipe, and the top of sealed lid is equipped with the air outlet, is equipped with vibrating device and a plurality of air intake on the outer wall of cooling device body, and the inside of cooling device body is equipped with screen cloth and a plurality of cold wind distributor, and an air intake of every cold wind distributor intercommunication. In the actual production, treat the inside back that the zero water sodium metasilicate product of refrigerated got into the cooling device body from the inlet pipe, scatter on the screen cloth, pass through the pipe-line transportation with the cooling air under the effect of air-blower to the cold wind distributor that is linked together with the air intake in, cold wind is inside the cooling device body through cold wind distributor homodisperse, then carry out the heat exchange with zero water sodium metasilicate product, the realization is to the cooling of product, simultaneously among the whole product cooling process, can realize stirring from top to bottom to the product through vibrating device, more help the cooling of cold wind to the product, the product after the cooling packs after discharging from the discharging pipe, smuggle thermal wind from the air exit and discharge secretly. The cooling device has reasonable design, realizes the cooling of the zero-water sodium metasilicate product, shortens the cooling time and greatly improves the cooling efficiency.

Because the cold air distributor includes the columniform body, be equipped with a plurality of cold air distributing pipes that are linked together with the body on the outer wall of body, evenly be equipped with a plurality of air distribution holes on the pipe wall of cold air distributing pipe. The cold air enters the body and then enters the cold air distribution pipe, and passes through the plurality of air distribution holes on the cold air distribution pipe to be uniformly dispersed. The cold air distributor adopts the structure, is reasonable in design, facilitates the uniform distribution of cold air, and realizes the distribution of the cold air at different positions inside the cooling device body.

Because a plurality of cold wind distributing pipes respectively highly vary and equidistant setting is on the outer wall of body. By adopting the design, the distribution range of cold air in the cooling device body is increased, and the cooling of the product is facilitated.

The vibration device is a vibration motor arranged on the front and back outer walls of the cooling device body. The vibrating force that vibrating motor produced after the start-up transmits for the cooling device body, has realized stirring from top to bottom to the product on the screen cloth, guarantees that the product of different positions and the different face of product all fully contact with cold wind, more helps the cooling to the product.

The cold air distributor is arranged below the screen. The flow rate of the cold air is reduced, the contact time of the cold air and the product is prolonged, and the product is cooled more easily.

The screen is obliquely arranged inside the cooling device body, and the aperture of the screen is smaller than the particle size of the product. The screen cloth is obliquely arranged, so that products can be discharged from the discharge pipe conveniently, the aperture of the screen cloth is smaller than the particle size of the products, and the products can be prevented from penetrating through the screen cloth and scattering on the inner wall of the bottom of the cooling device body in the cooling process.

Drawings

FIG. 1 is a schematic structural diagram of a cooling device for a zero-water sodium metasilicate product of the present invention;

FIG. 2 is a schematic view of the cold air distributor shown in FIG. 1;

the device comprises a cooling device body, a cooling device inlet 10, a sealing cover 2, an air outlet 20, a feeding pipe 3, a discharging pipe 4, a vibrating motor 5, a screen 6, a cold air distributor 7, a cooling device body 70 and a cold air distribution pipe 71.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail below with reference to the accompanying drawings and examples. It should be understood that the specific embodiments described herein are merely illustrative of the utility model and are not intended to limit the utility model.

A cooling device for a zero-water sodium metasilicate product is shown in figures 1 and 2, and comprises a cooling device body 1 and a sealing cover 2, wherein a feeding pipe 3 is arranged at one end of the cooling device body 2, a discharging pipe 4 is arranged at the other end of the cooling device body 1, an air outlet 20 is arranged at the top of the sealing cover 2, a vibrating device (a vibrating motor 5) and a plurality of air inlets 10 (arranged on the outer wall of the front side of the cooling device body) are arranged on the outer wall of the cooling device body 1, a screen 6 and a plurality of cold air distributors 7 (fixed on the inner wall of the cooling device body through supports) are arranged inside the cooling device body 1, and each cold air distributor 7 is communicated with one air inlet 10; the cold air distributor 7 includes a cylindrical body 70, a plurality of cold air distribution pipes 71 communicated with the body 70 are arranged on the outer wall of the body 70, and a plurality of air distribution holes are uniformly arranged on the pipe wall of the cold air distribution pipes 71.

In actual production, a to-be-cooled zero-water sodium metasilicate product enters the inside of a cooling device body from a feeding pipe and then is scattered on a screen, cooling air is conveyed to a cold air distributor communicated with an air inlet through a pipeline under the action of an air blower, the cold air enters the inside of the body and then enters a cold air distribution pipe, the cold air passes through a plurality of air distribution holes in the cold air distribution pipe and is uniformly dispersed, the cold air slowly flows and contacts with the zero-water sodium metasilicate product distributed on the screen to exchange heat, the product is cooled, meanwhile, in the whole product cooling process, a vibrating device (a vibrating motor) is started, the product is turned up and down, the products at different positions on the screen and different surfaces of the product are ensured to be fully contacted with the cold air, the cold air is more beneficial to cooling the product, and the cooled product is packaged after being discharged from a discharging pipe, the wind carrying heat is discharged from the air outlet. Above-mentioned cooling device, reasonable in design has shortened the cooling time, has improved cooling efficiency greatly.

Wherein a plurality of cold wind distributing pipes 71 highly inequality and equidistant setting respectively are on the outer wall of body. By adopting the design, the distribution range of cold air in the cooling device body is increased, and the cooling of the product is facilitated.

Wherein the cold air distributor 7 is arranged below the screen 6. After being distributed by the cold air distributor, the cold air slowly flows from bottom to top to exchange heat with high-temperature products on the screen, and the cold air distributor is arranged below the screen, so that the flow rate of the cold air is reduced, the contact time of the cold air and the products is prolonged, and the cold air distributor is more beneficial to cooling the products.

Wherein the screen 6 is obliquely arranged inside the cooling device body 1, and the aperture of the screen 6 is smaller than the grain diameter of the product. The screen cloth is obliquely arranged, so that products can be discharged from the discharge pipe conveniently, the aperture of the screen cloth is smaller than the particle size of the products, and the products can be prevented from penetrating through the screen cloth and scattering on the inner wall of the bottom of the cooling device body in the cooling process.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the utility model, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (6)

1. The utility model provides a zero water sodium metasilicate cooling device for product which characterized in that: the cooling device comprises a cooling device body and a sealing cover, wherein one end of the cooling device body is provided with an inlet pipe, the other end of the cooling device body is provided with a discharge pipe, the top of the sealing cover is provided with an air outlet, the outer wall of the cooling device body is provided with a vibrating device and a plurality of air inlets, the inside of the cooling device body is provided with a screen and a plurality of cold air distributors, and each cold air distributor is communicated with one air inlet.

2. The cooling device for zero-water sodium metasilicate products according to claim 1, wherein: the cold wind distributor includes the columniform body, be equipped with on the outer wall of body a plurality of with the gas distribution pipe that the body communicates mutually, evenly be equipped with a plurality of air distribution holes on the pipe wall of gas distribution pipe.

3. The cooling device for zero-water sodium metasilicate products according to claim 2, wherein: a plurality of the gas distribution pipes are arranged on the outer wall of the body at unequal heights and equal intervals.

4. The cooling device for zero-water sodium metasilicate products according to claim 1, wherein: the vibration device is a vibration motor arranged on the outer walls of the front side and the back side of the cooling device body.

5. The cooling device for zero-water sodium metasilicate products according to claim 1, wherein: the cold air distributor is arranged below the screen.

6. The cooling device for zero-water sodium metasilicate products according to claim 1, wherein: the screen is obliquely arranged in the cooling device body, and the aperture of the screen is smaller than the particle size of the product.

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