CN211282245U - Material cooling device - Google Patents

Abstract

The utility model relates to a food processing field, concretely relates to material cooling device, be equipped with the feed inlet on the hollow jar body, this feed inlet is worn to locate by the conveying pipeline, and the discharge end of conveying pipeline extends towards the inside of the jar body, with the splash phenomenon of reduction conveying pipeline discharge material, the sleeve pipe cup joints on the conveying pipeline, and be equipped with the space between the lateral wall of sheathed tube inside wall and conveying pipeline, the heat-proof effect between sleeve pipe and the conveying pipeline can be promoted in the space, prevent the heat transfer to the sleeve pipe of conveying pipeline, avoid sleeve pipe high temperature, a small amount of material because of splashing and adhesion at the sheathed tube lateral wall is difficult to form dry scale layer under the condition that does not have high temperature drying, and then make sheathed tube lateral wall easily clean, avoid bacterial growing.

Description

Material cooling device

Technical Field

The utility model relates to a food processing field especially relates to a material cooling device.

Background

Treat that refrigerated high temperature material gets into and cools down in the storage tank through the inlet pipe, the discharge end of inlet pipe is located the storage tank, and along with the material increase in the storage tank, the lateral wall of inlet pipe exhaust material inevitably can splash to the inlet pipe. However, when the high-temperature material flows through the feeding pipe, heat is transferred to the feeding pipe, so that the temperature of the feeding pipe is increased, the material adhered to the outer side wall of the feeding pipe is baked by the high temperature of the feeding pipe to become dry, and finally a dry scale layer is formed, and the dry scale layer is difficult to clean and is easy to breed bacteria.

SUMMERY OF THE UTILITY MODEL

In order to solve the problems, the utility model aims to provide a material cooling device to solve the problem that the inlet pipe of the existing material cooling device is easy to generate a dry scale layer.

Based on the above, the utility model provides a material cooling device, which comprises a sleeve, a material conveying pipe and a tank body, wherein the tank body is provided with a feed inlet which communicates the interior of the tank body with the outside, the material conveying pipe is arranged at the feed inlet in a penetrating way, and the discharge end of the material conveying pipe extends towards the interior of the tank body; the sleeve is sleeved with the conveying pipe, and a heat insulation gap is formed between the inner side wall of the sleeve and the outer side wall of the conveying pipe.

Preferably, one end of the sleeve is connected to the outer side wall of the discharge end of the feed delivery pipe, so that the inner side wall of the sleeve and the outer side wall of the feed delivery pipe form a cavity.

Preferably, the feeding device further comprises a cover body covering the feeding hole, a through hole is formed in the cover body, the sleeve penetrates through the through hole, and the outer side wall of the sleeve is attached to the inner side wall of the through hole.

Preferably, the sleeve is made of a metal material.

Preferably, the tank body is provided with a negative pressure port, and the negative pressure port is communicated with a negative pressure device.

Preferably, the material conveying device further comprises a conical pipe, the large end of the conical pipe is connected to the sleeve, and the pipe orifice of the small end of the conical pipe is connected to the outer side wall of the discharge end of the material conveying pipe.

Preferably, the sleeve is located within the canister body.

Preferably, the material conveying pipe is made of metal materials or plastic materials.

The utility model discloses a material cooling device, be equipped with the feed inlet on the jar body, this feed inlet is worn to locate by the conveying pipeline, and the discharge end of conveying pipeline extends towards the inside of the jar body, with the splash phenomenon that reduces conveying pipeline discharge material, the sleeve pipe cup joints on the conveying pipeline, and form thermal-insulated clearance between the lateral wall of sheathed tube inside wall and conveying pipeline, thermal-insulated effect between sleeve pipe and the conveying pipeline can be promoted in thermal-insulated clearance, prevent the heat transfer to the sleeve pipe of conveying pipeline, avoid sleeve pipe high temperature, a small amount of material because of splashing and adhesion at the sheathed tube lateral wall is difficult to form dry scale layer under the condition that does not have high temperature to dry, and then make sheathed tube lateral wall easily clean, avoid bacterial growing.

Drawings

Fig. 1 is a schematic overall structure diagram of a material cooling device according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of a cover body of the material cooling device according to the embodiment of the present invention;

FIG. 3 is a schematic view of a prior art accumulator tank.

Wherein, 1, a sleeve; 11. a tapered tube; 2. a delivery pipe; 3. a tank body; 31. a feed inlet; 4. a thermally insulating gap; 5. a cover body; 51. and a through hole.

Detailed Description

The following detailed description of the embodiments of the present invention is provided with reference to the accompanying drawings and examples. The following examples are intended to illustrate the invention, but are not intended to limit the scope of the invention.

With reference to fig. 1 and 2, schematically showing the utility model discloses a material cooling device, including sleeve pipe 1, conveying pipeline 2 and hollow jar body 3, jar internal chamber that holds that has for holding the material, sleeve pipe 1 preferably adopts the metal material to make, and conveying pipeline 2 can adopt metal material or plastics material to make.

The tank body 3 is provided with a feed inlet 31 for communicating the inside with the outside, and the feed inlet 31 is positioned at the top of the tank body 3. Feed inlet 31 is worn to locate by conveying pipeline 2, and the discharge end of conveying pipeline 2 extends to the inside of jar body 3, because the discharge end of conveying pipeline 2 is close to more in the bottom that holds the chamber or the liquid level of material, consequently can effectively reduce the splash phenomenon of material.

As shown in fig. 2, the inner diameter of the sleeve 1 is larger than the outer diameter of the feeding pipe 2, the sleeve 1 is sleeved with the feeding pipe 2, a heat insulation gap 4 is arranged between the inner side wall of the sleeve 1 and the outer side wall of the feeding pipe 2, the heat insulation gap 4 can be filled with air or a vacuum environment can be manufactured in the heat insulation gap 4, the feeding pipe 2 is made of metal, and the heat conductivity of the air is far lower than that of the feeding pipe 2 made of metal, so the heat insulation gap 4 has a heat insulation function. This thermal-insulated clearance 4 can promote the thermal-insulated effect between sleeve pipe 1 and the conveying pipeline 2, prevents conveying pipeline 2's heat transfer to sleeve pipe 1, avoids sleeve pipe 1 high temperature, and a small amount of material because of splashing and adhesion at sleeve pipe 1's lateral wall is difficult to form dry scale layer under the condition that does not have high temperature to dry, and then makes sleeve pipe 1's lateral wall easily clean, avoids bacterial growing.

One end of the sleeve 1 is connected with the outer side wall of the discharge end of the conveying pipe 2, so that the inner side wall of the sleeve 1 and the outer side wall of the conveying pipe 2 form a cavity, and the cavity is isolated from the accommodating cavity. Specifically, the device also comprises a conical pipe 11, the large end of the conical pipe 11 is connected to the sleeve 1, and the nozzle of the small end of the conical pipe 11 is connected to the outer side wall of the discharge end of the conveying pipe 2.

Further, the material cooling device further comprises a cover body 5 covering the feed inlet 31, a through hole 51 is formed in the cover body 5, the sleeve 1 penetrates through the through hole 51, and the outer side wall of the sleeve 1 is attached to the inner side wall of the through hole 51 so as to isolate the external environment and the accommodating cavity of the tank body 3. The tank body 3 is provided with a negative pressure port which is communicated with a negative pressure device, so that the accommodating cavity of the tank body 3 is maintained in a negative pressure environment, and the discharge end of the conveying pipe 2 extends towards the inside of the tank body 3 to prevent splashed materials from being accidentally discharged from the negative pressure port.

In certain alternative embodiments, the sleeve 1 is located only within the tank 3.

To sum up, the utility model discloses a material cooling device, be equipped with feed inlet 31 on the hollow jar body 3, this feed inlet 31 is worn to locate by conveying pipeline 2, and the discharge end of conveying pipeline 2 extends towards jar inside of body 3, in order to reduce the splash phenomenon of 2 discharge material of conveying pipeline, sleeve pipe 1 cup joints on conveying pipeline 2, and be equipped with thermal-insulated clearance 4 between the inside wall of sleeve pipe 1 and the lateral wall of conveying pipeline 2, thermal-insulated clearance 4 can promote the thermal-insulated effect between sleeve pipe 1 and the conveying pipeline 2, prevent heat transfer to sleeve pipe 1 of conveying pipeline 2, avoid sleeve pipe 1 high temperature, a small amount of material because of splashing and adhesion at sleeve pipe 1's lateral wall is difficult to form dry scale layer under the condition that does not have high temperature drying, and then make sleeve pipe 1's lateral wall easily clean, avoid bacterial growing.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of modifications and replacements can be made without departing from the technical principle of the present invention, and these modifications and replacements should also be regarded as the protection scope of the present invention.

Claims (8)

1. A material cooling device is characterized by comprising a sleeve, a material conveying pipe and a tank body, wherein a feed port for communicating the interior of the tank body with the outside is formed in the tank body; the sleeve is sleeved with the conveying pipe, and a heat insulation gap is formed between the inner side wall of the sleeve and the outer side wall of the conveying pipe.

2. The material cooling apparatus as claimed in claim 1, wherein one end of said sleeve is connected to an outer side wall of a discharge end of said feed conveyor pipe, such that said inner side wall of said sleeve and said outer side wall of said feed conveyor pipe form a cavity.

3. The material cooling device according to claim 1, further comprising a cover body covering the feed port, wherein a through hole is formed in the cover body, the sleeve penetrates through the through hole, and the outer side wall of the sleeve is attached to the inner side wall of the through hole.

4. The material cooling device of claim 1, wherein the sleeve is made of a metal material.

5. The material cooling device as claimed in claim 1, wherein the tank body is provided with a negative pressure port, and the negative pressure port is communicated with a negative pressure device.

6. The material cooling device as claimed in claim 2, further comprising a tapered pipe, wherein the large end of the tapered pipe is connected to the sleeve, and the orifice of the small end of the tapered pipe is connected to the outer side wall of the discharge end of the conveying pipe.

7. The material cooling device of claim 1 wherein the sleeve is located within the tank.

8. The material cooling device as claimed in claim 1, wherein said feed pipe is made of metal or plastic.

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