CN216814795U - A quick cooling device for production of silicone adhesive - Google Patents

Abstract

The utility model discloses a quick cooling device for producing silicone adhesive, which comprises a tank body, a base and a cooling unit, wherein the tank body is provided with a plurality of cooling holes; the tank body is internally provided with an isolation sleeve which divides the tank body into a main cooling chamber and an auxiliary cooling chamber; the cooling unit is arranged in the main cooling chamber; two ends of the tank body are provided with material conveying interfaces connected with the material conveying pipes; the cooling unit comprises two flow distribution plates, a plurality of spiral pipes, a main liquid inlet pipe and a main liquid outlet pipe; the main liquid inlet pipe and the main liquid outlet pipe are detachably connected with the refrigerant conveying device; a horizontal straight-through pipe is arranged between the flow distribution plates; the bottom of one end of the tank body is provided with a secondary liquid inlet pipe, and the top of the other end of the tank body is provided with a secondary liquid outlet pipe. According to the utility model, the cooling unit is arranged in the main cooling chamber by additionally arranging the isolation sleeve, and the cooling unit and the secondary cooling chamber cool the silicone adhesive from the inner side and the outer side, so that the heat dissipation is more uniform; the cooling unit is composed of a plurality of spiral pipes and a straight-through pipe, so that the effective contact area between the silicone adhesive and the cooling unit is increased, the heat exchange efficiency is higher, and the cooling efficiency is higher.

Description

A quick cooling device for production of silicone adhesive

Technical Field

The utility model relates to the field of production and preparation of silicone adhesive, in particular to a quick cooling device for production of silicone adhesive.

Background

Silicone adhesive is a commonly used adhesive material. Silicone adhesives are generally maintained at elevated temperatures during their preparation in order to ensure that the silicone adhesive is in a liquid state and does not block its flow. The silicone adhesive needs to be cooled after preparation is complete.

At present, a factory introduces silicone adhesive into a material guide pipe of a cooling device, then continuously flows cooling liquid outside the material guide pipe, and takes away heat of the silicone adhesive by using the cooling liquid to realize cooling of the silicone adhesive.

However, when the cooling is performed by adopting the method, the cooling liquid is only contacted with the wall of the material guide pipe, so that the heat dissipation of the silicone adhesive close to the wall of the material guide pipe is inevitably faster than that of the silicone adhesive far away from the wall of the material guide pipe, and the integral heat dissipation of the silicone adhesive is uneven, thereby affecting the heat dissipation effect; moreover, the cooling liquid outside the material guide pipe is only used for heat dissipation, and the contact area of the cooling liquid and the silicone adhesive is limited, so that the heat exchange rate of the cooling liquid and the silicone adhesive is low, the cooling efficiency is limited, and the production efficiency of the silicone adhesive is finally influenced.

Therefore, the existing silicone adhesive cooling device has the problems of uneven heat dissipation and low cooling efficiency of the silicone adhesive.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a quick cooling device for silicone adhesive production. The utility model has the advantages of relatively more uniform heat dissipation of the silicone adhesive and relatively higher cooling efficiency.

The technical scheme of the utility model is as follows: a quick cooling device for silicone adhesive production comprises a tank body, a base arranged at the bottom of the tank body and a cooling unit arranged in the tank body; an isolation sleeve is horizontally arranged in the tank body and divides the tank body into an inner part and an outer part, the inner part is a main cooling chamber, and the outer part is a secondary cooling chamber; the cooling unit is arranged in the main cooling chamber; the two ends of the tank body are respectively provided with a material conveying interface which is in penetrating connection with the main cooling chamber, and the material conveying interfaces are detachably connected with material conveying pipes; the cooling unit comprises two vertically arranged splitter plates, a plurality of spiral pipes uniformly distributed between the two splitter plates, and a main liquid inlet pipe and a main liquid outlet pipe which are respectively connected with the corresponding splitter plates; the main liquid inlet pipe and the main liquid outlet pipe sequentially penetrate through the isolation sleeve and the tank body and are detachably connected with the refrigerant conveying device through the connecting seat, and the refrigerant conveying device is used for conveying refrigerants; a straight-through pipe horizontally positioned in the middle of the spiral pipes is arranged between the two splitter plates; the bottom of one end of the tank body is provided with a secondary liquid inlet pipe communicated with the secondary cooling chamber, and the top of the other end of the tank body is provided with a secondary liquid outlet pipe communicated with the secondary cooling chamber.

In the aforementioned rapid cooling device for silicone adhesive production, one side of each of the flow distribution plates is connected to the side wall of the end of the tank body by a plurality of connecting rods.

In the quick cooling device for producing the silicone adhesive, the middle part below the tank body is provided with the sewage discharge pipe which is connected with the secondary cooling chamber in a penetrating way; the diapire of jar internal portion is equipped with the slope towards blow off pipe department slope.

In the quick cooling device for silicone adhesive production, the top of the base is provided with a plurality of hydraulic telescopic columns connected with the bottom of the tank body; a plurality of liftable electric rollers are uniformly arranged at the bottom of the base; a plurality of liftable support columns are uniformly distributed at four corners of the bottom of the base.

In the aforementioned rapid cooling device for silicone adhesive production, the isolation sleeve, the splitter plate, the spiral tube and the straight-through tube are all made of heat conductive materials.

In the rapid cooling device for silicone adhesive production, the outer wall of the isolation sleeve is provided with the guide plate spirally wound outside the isolation sleeve; the guide plate can make the cooling liquid flow spirally around the isolation sleeve after entering from the secondary liquid inlet pipe and finally flow out from the secondary liquid outlet pipe.

In the quick cooling device for producing the silicone adhesive, the spherical bodies are uniformly distributed on each spiral pipe, so that the contact area between the spiral pipe and the silicone adhesive is enlarged, and the cooling efficiency is improved.

Compared with the prior art, the tank body is divided into the main cooling chamber and the secondary cooling chamber by additionally arranging the isolation sleeve, the cooling unit is arranged in the main cooling chamber, the silicone adhesive flows in the isolation sleeve from the material conveying interface, and the cooling unit and the secondary cooling chamber perform heat dissipation and cooling on the silicone adhesive from the inner side and the outer side, so that the heat dissipation of the silicone adhesive is more uniform; the cooling unit is formed by a plurality of uniformly distributed spiral pipes and a straight-through pipe, so that the effective contact area between the silicone adhesive and the cooling unit is greatly increased, the heat exchange efficiency is higher, and the cooling efficiency is relatively higher.

Therefore, the utility model has the advantages that the heat dissipation of the silicone adhesive is relatively more uniform and the cooling efficiency is relatively higher.

Furthermore, the base and the tank body are connected through the hydraulic telescopic column, so that the height of the tank body can be adjusted through the hydraulic telescopic column, and the requirements of different working heights are met;

the lifting electric idler wheels and the supporting columns are additionally arranged on the base, the electric idler wheels can facilitate the movement of the device, and the supporting columns ensure that the device is placed stably when in use;

the supporting column can be adjusted in a lifting way, and the level of the device can be ensured no matter whether the ground is flat or not;

through adding and establishing the guide plate for coolant liquid in the time cooling chamber can the heliciform flow on the isolation sleeve wall, and its cooling effect is better.

FIG. 1 is a schematic diagram of the present invention.

The labels in the figures are: 1-tank body, 11-secondary cooling chamber, 12-primary cooling chamber, 13-isolation sleeve, 14-slope, 15-blow-off pipe, 2-base, 21-hydraulic telescopic column, 22-electric roller, 23-support column, 31-secondary liquid inlet pipe, 32-secondary liquid outlet pipe, 41-primary liquid inlet pipe, 42-primary liquid outlet pipe, 5-splitter plate, 51-spiral pipe, 52-straight-through pipe and 6-material conveying interface.

Detailed Description

The utility model is further described with reference to the following figures and examples, which are not to be construed as limiting the utility model.

Examples are given. A rapid cooling device for silicone adhesive production is shown in figure 1 and comprises a tank body 1, a base 2 arranged at the bottom of the tank body 1 and a cooling unit arranged in the tank body 1; an isolation sleeve 13 is horizontally arranged in the tank body 1, the tank body 1 is divided into an inner part and an outer part by the isolation sleeve 13, the inner part is a main cooling chamber 12, and the outer part is a secondary cooling chamber 11; the cooling unit is arranged in the main cooling chamber 12; two ends of the tank body 1 are respectively provided with a material conveying interface 6 which is in penetrating connection with a main cooling chamber 12, and the material conveying interfaces 6 are detachably connected with material conveying pipes; the cooling unit comprises two vertically arranged splitter plates 5, a plurality of spiral pipes 51 uniformly distributed between the two splitter plates 5, and a main liquid inlet pipe 41 and a main liquid outlet pipe 42 which are respectively connected with the corresponding splitter plates 5; the main liquid inlet pipe 41 and the main liquid outlet pipe 42 sequentially penetrate through the isolation sleeve 13 and the tank body 1 and are detachably connected with a refrigerant conveying device through a connecting seat, and the refrigerant conveying device is used for conveying a refrigerant; a straight-through pipe 52 horizontally positioned in the middle of the spiral pipes 51 is arranged between the two flow distribution plates 5; the bottom of one end of the tank body 1 is provided with a secondary liquid inlet pipe 31 communicated with the secondary cooling chamber 11, and the top of the other end of the tank body 1 is provided with a secondary liquid outlet pipe 32 communicated with the secondary cooling chamber 11.

Each 5 one sides of flow distribution plate link to each other with 1 tip lateral wall of jar body through many connecting rods.

A sewage discharge pipe 15 which is connected with the secondary cooling chamber 11 in a penetrating way is arranged in the middle of the lower part of the tank body 1; the bottom wall of the interior of the tank body 1 is provided with a slope 14 which inclines towards the sewage discharge pipe 15.

The top of the base 2 is provided with a plurality of hydraulic telescopic columns 21 connected with the bottom of the tank body 1; a plurality of liftable electric rollers 22 are uniformly arranged at the bottom of the base 2; a plurality of liftable support columns 23 are uniformly distributed at four corners of the bottom of the base 2.

The isolation sleeve 13, the splitter plate 5, the spiral tube 51 and the straight-through tube 52 are all made of heat conducting materials.

And a guide plate spirally wound outside the isolation sleeve 13 is arranged on the outer wall of the isolation sleeve 13.

A plurality of spheroids are uniformly distributed on each spiral tube 51.

Claims (6)

1. A quick cooling device for production of silicone adhesive which characterized in that: comprises a tank body (1), a base (2) arranged at the bottom of the tank body (1) and a cooling unit arranged in the tank body (1); an isolation sleeve (13) is horizontally arranged in the tank body (1), the tank body (1) is divided into an inner part and an outer part by the isolation sleeve (13), the inner part is a main cooling chamber (12), and the outer part is a secondary cooling chamber (11); the cooling unit is arranged in the main cooling chamber (12); both ends of the tank body (1) are provided with material conveying interfaces (6) which are in penetrating connection with the main cooling chamber (12), and the material conveying interfaces (6) are detachably connected with material conveying pipes; the cooling unit comprises two vertically arranged splitter plates (5), a plurality of spiral pipes (51) which are uniformly distributed between the two splitter plates (5), and a main liquid inlet pipe (41) and a main liquid outlet pipe (42) which are respectively connected with the corresponding splitter plates (5); the main liquid inlet pipe (41) and the main liquid outlet pipe (42) sequentially penetrate through the isolation sleeve (13) and the tank body (1) and are detachably connected with the refrigerant conveying device through the connecting seat, and the refrigerant conveying device is used for conveying refrigerants; a straight-through pipe (52) horizontally positioned in the middle of the spiral pipes (51) is arranged between the two flow distribution plates (5); the bottom of one end of the tank body (1) is provided with a secondary liquid inlet pipe (31) communicated with the secondary cooling chamber (11), and the top of the other end of the tank body (1) is provided with a secondary liquid outlet pipe (32) communicated with the secondary cooling chamber (11).

2. A rapid cooling device for silicone adhesive production according to claim 1, characterized in that: one side of each flow distribution plate (5) is connected with the side wall of the end part of the tank body (1) through a plurality of connecting rods.

3. A rapid cooling device for silicone adhesive production according to claim 1, characterized in that: a sewage discharge pipe (15) which is connected with the secondary cooling chamber (11) in a penetrating way is arranged in the middle part below the tank body (1); the bottom wall in the tank body (1) is provided with a slope (14) which inclines towards the sewage discharge pipe (15).

4. A rapid cooling device for silicone adhesive production according to claim 1, characterized in that: the top of the base (2) is provided with a plurality of hydraulic telescopic columns (21) connected with the bottom of the tank body (1); a plurality of liftable electric rollers (22) are uniformly arranged at the bottom of the base (2); a plurality of liftable support columns (23) are uniformly distributed at four corners of the bottom of the base (2).

5. A rapid cooling device for silicone adhesive production according to claim 1, characterized in that: the isolation sleeve (13), the flow distribution plate (5), the spiral pipe (51) and the straight-through pipe (52) are all made of heat conducting materials.

6. A rapid cooling device for silicone adhesive production according to claim 1, characterized in that: and a guide plate spirally wound outside the isolation sleeve (13) is arranged on the outer wall of the isolation sleeve (13).

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