CN219942712U - Thermal insulation hopper structure of homogenizer - Google Patents
Thermal insulation hopper structure of homogenizer Download PDFInfo
- Publication number
- CN219942712U CN219942712U CN202320868178.2U CN202320868178U CN219942712U CN 219942712 U CN219942712 U CN 219942712U CN 202320868178 U CN202320868178 U CN 202320868178U CN 219942712 U CN219942712 U CN 219942712U
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- China
- Prior art keywords
- heat preservation
- heat
- hopper
- pipeline
- hopper body
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- 238000009413 insulation Methods 0.000 title description 6
- 238000004321 preservation Methods 0.000 claims abstract description 82
- 239000000463 material Substances 0.000 claims abstract description 52
- 238000000034 method Methods 0.000 claims description 9
- 239000011810 insulating material Substances 0.000 description 10
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 description 9
- 230000009286 beneficial effect Effects 0.000 description 2
- 239000012774 insulation material Substances 0.000 description 2
- 230000000903 blocking effect Effects 0.000 description 1
- 230000000694 effects Effects 0.000 description 1
- 238000000265 homogenisation Methods 0.000 description 1
- 238000012986 modification Methods 0.000 description 1
- 230000004048 modification Effects 0.000 description 1
- 238000006467 substitution reaction Methods 0.000 description 1
- 238000003466 welding Methods 0.000 description 1
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- Thermal Insulation (AREA)
Abstract
The utility model discloses a heat-insulating hopper structure of a homogenizer, which comprises a hopper joint (1), a cone (2), a hopper body (3) and a clamp joint (4); the heat-insulating sleeve (5) and the pipeline joint (6) are also included; the heat-insulating jacket (5) is sleeved outside the hopper body (3), and a heat-insulating cavity (501) is formed between the heat-insulating jacket (5) and the hopper body (3); two circulation connectors (502) are formed on the heat preservation jacket (5), one ends of two pipeline connectors (6) are respectively communicated with the heat preservation chamber (501) through the circulation connectors (502), and the other ends of the two pipeline connectors (6) are externally connected with a heat preservation material supply source through a pipeline, so that heat preservation materials are filled in the heat preservation chamber (501) through the external pipeline, the pipeline connectors (6) and the circulation connectors (502). The utility model can solve the problem that the material smoothness and the material feeding temperature in the prior art can not meet the use requirement.
Description
Technical Field
The utility model relates to a hopper of a homogenizer, in particular to a heat-insulating hopper structure of the homogenizer.
Background
Referring to fig. 1, the hopper structure of the homogenizer of the prior art comprises a hopper body 3, a cone 2 connected to one end of the hopper body 3, a hopper joint 1 connected to the cone 2, and a clamp joint 4 connected to the other end of the hopper body 3. When the homogenizer works, materials are input into the hopper body 3, and are continuously sucked from the hopper body 3 and conveyed to the one-way valve of the homogenizer through the reciprocating motion of the plunger of the homogenizer, so that the process of homogenizing the materials is completed.
In the working process of the homogenizer, if the viscosity of the material is higher, the material is easy to bond in the hopper body, so that the feeding fluency of the material is reduced, and the normal operation of the homogenizer cannot be ensured. Meanwhile, the hopper body in the prior art does not have a heat preservation function, and cannot meet the material feeding requirement with strict requirement on feeding temperature. Therefore, it is necessary to provide a heat-preserving hopper structure of a homogenizer, which can solve the problem that the smoothness of materials and the feeding temperature of materials in the prior art cannot meet the use requirement.
Disclosure of Invention
The utility model aims to provide a heat-insulating hopper structure of a homogenizer, which can solve the problem that the smoothness of materials and the feeding temperature of the materials in the prior art cannot meet the use requirement.
The utility model is realized in the following way:
a heat-insulating hopper structure of a homogenizer comprises a hopper joint, a cone, a hopper body and a clamp joint; one end of the cone is coaxially connected with one end of the hopper body, the hopper joint is coaxially arranged at the other end of the cone, and the clamp joint is coaxially connected with the other end of the hopper body;
the homogenizer heat-insulating hopper structure also comprises a heat-insulating jacket and a pipeline joint; the heat-insulating jacket is sleeved outside the hopper body, and a heat-insulating cavity is formed between the heat-insulating jacket and the hopper body; two circulating connectors are formed on the heat-insulating jacket, one ends of the two pipeline connectors are respectively communicated with the heat-insulating cavity through the circulating connectors, and the other ends of the two pipeline connectors are externally connected with a heat-insulating material supply source through a pipeline, so that heat-insulating materials are filled in the heat-insulating cavity through the external pipeline, the pipeline connectors and the circulating connectors.
The heat preservation overcoat be both ends open-ended cavity tubular structure, the internal diameter of heat preservation overcoat is greater than the external diameter at the hopper body, and the both ends open-ended diameter of heat preservation overcoat is unanimous with the external diameter of hopper body, makes the heat preservation overcoat cup joint in the outside of hopper body and forms annular confined heat preservation cavity.
The heat preservation jacket and the hopper body are coaxially arranged.
The two circulation connectors comprise a first circulation connector and a second circulation connector, the first circulation connector is positioned at the bottom of one end of the heat preservation chamber, and the second circulation connector is positioned at the top of the other end of the heat preservation chamber.
The axial direction of the first circulating connecting port and the axial direction of the second circulating connecting port are perpendicular to the axial direction of the hopper body.
One end of the heat preservation chamber extends to the outside of the cone, and the other end of the heat preservation chamber extends to the outside of the clamp joint, so that the heat preservation chamber can wrap the whole hopper body.
The other end of the pipeline joint is provided with a pagoda connecting part, and the pipeline is sleeved on the pipeline joint through the pagoda connecting part and is communicated with the heat preservation chamber.
Compared with the prior art, the utility model has the following beneficial effects:
1. the heat-insulating jacket covers the outside of the hopper body, and the heat-insulating cavity filled with heat-insulating materials is formed between the heat-insulating jacket and the hopper body, so that the materials in the hopper body reach the specified feeding temperature to meet the feeding requirement, the materials in the hopper body can also keep good fluidity, the materials can smoothly flow to the one-way valve, the plunger suction is facilitated, and the problem that the smoothness of the materials and the feeding temperature of the materials in the prior art cannot meet the use requirement is solved.
2. The utility model is provided with the pipeline joint, and forms a circulating flow path between the heat insulation material supply source and the heat insulation chamber through the pipelines such as the quick and reliable connecting hose of the pagoda connecting part, thereby being used for circulating and conveying the heat insulation material, ensuring continuous and uniform heat insulation of the material in the hopper body, and being convenient and quick to disassemble and assemble.
Drawings
FIG. 1 is a cross-sectional view of a prior art homogenizer heat preservation hopper structure;
FIG. 2 is a cross-sectional view of the heat preservation hopper structure of the homogenizer of the present utility model.
In the figure, 1 hopper joint, 2 cones, 3 hopper bodies, 4 clamp joints, 5 heat preservation jackets, 501 heat preservation chambers, 502 circulation connectors, 6 pipeline joints and 601 pagoda connection parts.
Detailed Description
The utility model will be further described with reference to the drawings and the specific examples.
Referring to fig. 2, a heat-insulating hopper structure of a homogenizer comprises a hopper joint 1, a cone 2, a hopper body 3 and a clamp joint 4; one end of the cone 2 is coaxially connected with one end of the hopper body 3, the hopper joint 1 is coaxially arranged at the other end of the cone 2, and the clamp joint 4 is coaxially connected with the other end of the hopper body 3.
The heat-insulating hopper structure of the homogenizer also comprises a heat-insulating jacket 5 and a pipeline joint 6; the heat-insulating jacket 5 is sleeved outside the hopper body 3, and a heat-insulating cavity 501 is formed between the heat-insulating jacket 5 and the hopper body 3; two circulating connectors 502 are formed on the heat-insulating jacket 5, one ends of two pipeline connectors 6 are respectively communicated with the heat-insulating cavity 501 through the circulating connectors 502, and the other ends of the two pipeline connectors 6 are externally connected with a heat-insulating material supply source through a pipeline, so that heat-insulating materials are filled in the heat-insulating cavity 501 through the externally connected pipeline, the pipeline connectors 6 and the circulating connectors 502.
The heat preservation jacket 5 is sleeved outside the hopper body 3 to form a heat preservation chamber 501, and a heat preservation material supply source injects heat preservation material into the heat preservation chamber 501 through a pipeline via a pipeline joint 6. The heat preservation material enters and flows out of the heat preservation chamber 501 through the two circulation connectors, circularly flows outside the hopper body 3 and exchanges heat with the material in the hopper body 3, so that the material in the hopper body 3 meets the requirement of feeding temperature, or the temperature and the fluidity of the material in the hopper body 3 are improved, and the material smoothly flows to the one-way valve of the homogenizer, thereby being beneficial to plunger suction.
Preferably, the heat-insulating jacket 5 can be fixed on the hopper body 3 by adopting a welding mode and the like, the heat-insulating material can be hot water or hot steam and the like, and the temperature and the texture of the heat-insulating material can be selected according to actual requirements.
The heat preservation overcoat 5 be both ends open-ended cavity tubular structure, the internal diameter of heat preservation overcoat 5 is greater than the external diameter at hopper body 3, and the both ends open diameter of heat preservation overcoat 5 is unanimous with the external diameter of hopper body 3, makes heat preservation overcoat 5 cup joint in the outside of hopper body 3 and forms annular confined heat preservation cavity 501.
The size of the heat preservation jacket 5 can be determined according to the filling amount and flow requirements of the heat preservation material in the heat preservation chamber 501, so that the heat preservation material in the heat preservation chamber 501 can heat and preserve the material in the hopper body 3 to a specified temperature and ensure the fluidity of the material.
The heat preservation jacket 5 and the hopper body 3 are coaxially arranged, so that the sizes of all positions of the heat preservation chamber 501 are consistent, and materials in the hopper body 3 are uniformly heated and preserved.
The two circulation connection ports 502 include a first circulation connection port and a second circulation connection port, the first circulation connection port is located at the bottom of one end of the heat insulation chamber 501, and the second circulation connection port is located at the top of the other end of the heat insulation chamber 501.
The first circulation connector and the second circulation connector are respectively located at two ends of the heat preservation cavity 501 and located at the top and the bottom, so that heat preservation materials such as hot water or hot steam can be guaranteed to fill the whole heat preservation cavity 501 and completely wrap the outside of the hopper body 3 in the circulation flowing process, and therefore materials in the hopper body 3 are fully heated and preserved, heat exchange efficiency is high, and the heat preservation materials reach the designated temperature and fluidity.
One end of the heat preservation chamber 501 extends to the outside of the cone 2, and the other end of the heat preservation chamber 501 extends to the outside of the clamp joint 4, so that the heat preservation chamber 501 can wrap the whole hopper body 3.
The length of the heat-preserving chamber 501 can be adjusted according to actual requirements, so that the material can flow in the hopper structure of the homogenizer to the whole flow track of the one-way valve of the homogenizer, and the homogenized material can reach the designated feeding temperature or the flow smoothness of the high-viscosity material can be ensured.
The axial direction of the first circulating connecting port and the axial direction of the second circulating connecting port are perpendicular to the axial direction of the hopper body 3.
The heat preservation material such as hot water or hot steam gets into in the heat preservation cavity 501 from the second circulation connector, flows out heat preservation cavity 501 from the second circulation connector again, and whole process flows along the axial of hopper body 3 and effectively wraps up the outside of hopper body 3, has guaranteed the abundant heat exchange between heat preservation material and the inside material of hopper body 3, improves the heat preservation effect.
The other end of the pipeline joint 6 is provided with a pagoda connection part 601, and the pipeline is sleeved on the pipeline joint 6 through the pagoda connection part 601 and is communicated with the heat preservation chamber 501.
By the arrangement of the pagoda connection part 601, the connection firmness of the pipeline joint 6 and the pipelines such as the hose can be improved, and the pipelines can be prevented from falling off.
Referring to fig. 2, the application method of the present utility model is as follows:
in the working process of the homogenizer, if the feeding temperature of the material is required, or the viscosity of the material is high, caking, blocking and other conditions are easy to occur, the pipeline joint 6 is externally connected with a heat-insulating material supply source through a hose through the pagoda connecting part 601, and the heat-insulating material can be hot water or hot steam, so that the hot water or the hot steam circularly flows between the heat-insulating material supply source and the heat-insulating chamber 501 through the hose.
Hot water or hot steam enters the heat preservation chamber 501 from the second circulation connection port, flows out of the heat preservation chamber 501 from the first circulation connection port after flowing through the whole heat preservation chamber 501, returns to the heat preservation material supply source, can heat the hot water or the hot steam again in the heat preservation material supply source, and then flows in the next circulation.
In the continuous circulation flow process of the hot water or the hot steam, the hot water or the hot steam and the materials in the hopper body 3 perform sufficient heat exchange, so that the materials reach the specified feeding temperature, and the high-viscosity materials can also keep good fluency, so that the materials smoothly flow to the one-way valve, the plunger suction of the homogenizer is facilitated, and the homogenization process of the materials is completed.
The above embodiments are merely preferred embodiments of the present utility model and are not intended to limit the scope of the present utility model, therefore, any modifications, equivalent substitutions, improvements, etc. made within the spirit and principle of the present utility model should be included in the scope of the present utility model.
Claims (7)
1. The heat-insulating hopper structure of the homogenizer comprises a hopper joint (1), a cone (2), a hopper body (3) and a clamp joint (4); one end of the cone (2) is coaxially connected with one end of the hopper body (3), the hopper joint (1) is coaxially arranged at the other end of the cone (2), and the clamp joint (4) is coaxially connected with the other end of the hopper body (3);
the method is characterized in that: the heat-insulating hopper structure of the homogenizer also comprises a heat-insulating jacket (5) and a pipeline joint (6); the heat-insulating jacket (5) is sleeved outside the hopper body (3), and a heat-insulating cavity (501) is formed between the heat-insulating jacket (5) and the hopper body (3); two circulation connectors (502) are formed on the heat preservation jacket (5), one ends of two pipeline connectors (6) are respectively communicated with the heat preservation chamber (501) through the circulation connectors (502), and the other ends of the two pipeline connectors (6) are externally connected with a heat preservation material supply source through a pipeline, so that heat preservation materials are filled in the heat preservation chamber (501) through the external pipeline, the pipeline connectors (6) and the circulation connectors (502).
2. The homogenizer heat preservation hopper structure of claim 1, wherein: the heat preservation overcoat (5) be both ends open-ended cavity tubular structure, the internal diameter of heat preservation overcoat (5) is greater than the external diameter at hopper body (3), and the both ends open-ended diameter of heat preservation overcoat (5) is unanimous with the external diameter of hopper body (3), makes heat preservation overcoat (5) cup joint in the outside of hopper body (3) and forms annular confined heat preservation cavity (501).
3. The homogenizer heat preservation hopper structure according to claim 1 or 2, characterized in that: the heat preservation coat (5) and the hopper body (3) are coaxially arranged.
4. The homogenizer heat preservation hopper structure of claim 1, wherein: the two circulation connectors (502) comprise a first circulation connector and a second circulation connector, the first circulation connector is positioned at the bottom of one end of the heat preservation chamber (501), and the second circulation connector is positioned at the top of the other end of the heat preservation chamber (501).
5. The homogenizer heat preservation hopper structure of claim 4, wherein: the axial direction of the first circulating connecting port and the axial direction of the second circulating connecting port are perpendicular to the axial direction of the hopper body (3).
6. The homogenizer heat preservation hopper structure of claim 1, wherein: one end of the heat preservation chamber (501) extends to the outside of the cone (2), and the other end of the heat preservation chamber (501) extends to the outside of the clamp joint (4), so that the heat preservation chamber (501) can wrap the whole hopper body (3).
7. The homogenizer heat preservation hopper structure of claim 1, wherein: the other end of the pipeline joint (6) is provided with a pagoda connecting part (601), and the pipeline is sleeved on the pipeline joint (6) through the pagoda connecting part (601) and is communicated with the heat preservation chamber (501).
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202320868178.2U CN219942712U (en) | 2023-04-18 | 2023-04-18 | Thermal insulation hopper structure of homogenizer |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202320868178.2U CN219942712U (en) | 2023-04-18 | 2023-04-18 | Thermal insulation hopper structure of homogenizer |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CN219942712U true CN219942712U (en) | 2023-11-03 |
Family
ID=88554062
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN202320868178.2U Active CN219942712U (en) | 2023-04-18 | 2023-04-18 | Thermal insulation hopper structure of homogenizer |
Country Status (1)
| Country | Link |
|---|---|
| CN (1) | CN219942712U (en) |
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2023
- 2023-04-18 CN CN202320868178.2U patent/CN219942712U/en active Active
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