CN214065386U - Cylindrical cold bottle capable of directionally guiding cold energy - Google Patents

Abstract

A cylindrical cold bottle capable of directionally guiding cold energy comprises: a cup housing including at least a closed bottom, a sidewall connecting the bottom; the side wall is parallel to or unparallel to the surface of the first inner wall to form a temperature-resistant vacuum layer; a cold accumulation release cavity is formed between the second inner wall and the first inner wall, and a cold accumulation agent is arranged in the cold accumulation release cavity; the cold accumulation release cavity is blocked by the temperature-resistant vacuum layer in the direction of the side wall, and the cold accumulation release cavity conveys cold energy to the placing cavity from the second inner wall so as to directionally guide the flow, so that the temperature is changed. The cold energy storage device has the advantages of simple and compact structure, long service life, uniform cold energy transmission, small temperature difference, lasting cold insulation and the like; therefore, the device has excellent performance in the aspects of technical performance, practicability and economical efficiency.

Description

Cylindrical cold bottle capable of directionally guiding cold energy

Technical Field

The utility model belongs to the technical field of the cold-stored technique of medicine and specifically relates to a tube-shape cold bottle of directional water conservancy diversion cold energy.

Background

The diabetes patient needs to carry insulin when going out, the insulin can be stably stored for a long time only at the temperature of 2-8 ℃, people invent a refrigeration cup, the refrigeration cup on the market generally adopts a cylindrical cold bottle filled with directional flow guiding cold energy of a phase change cold storage agent and placed in a vacuum heat preservation cup, and the cylindrical cold bottle filled with the directional flow guiding cold energy of the phase change cold storage agent needs to be placed in a refrigerator for precooling for several hours before use, so that the phase change cold storage agent can be completely precooled. Generally, the temperature of the cylindrical cold bottle with the fully pre-cooled directional flow guiding cold energy in the freezing chamber of the refrigerator is lower than the lower limit temperature for storing insulin, even the freezing of the insulin can be caused, so that the insulin loses the biological activity, therefore, the cylindrical cold bottle with the fully pre-cooled directional flow guiding cold energy needs to be placed in a room temperature environment to adjust the temperature, the temperature in the bottle body is increased to be more than +2 ℃, then the medicine is placed in the bottle for storage, and the low temperature environment for storing the insulin is continuously kept.

According to market research and patent retrieval: the cup body in the refrigeration cup in the prior art is usually a vacuum cup, and the cold accumulation bottle needs to be additionally arranged in the vacuum cup for use, and because the conduction area is poor when the cold accumulation bottle needs to absorb cold energy, cold cannot be quickly conducted to the cold accumulation agent; the cold storage bottle occupies the placing space in the bottle, and has small cold release surface and uneven cold energy transmission during cold release; therefore, the cup body has large volume, high material cost and manufacturing cost, and resource waste.

In order to overcome the defects, a cylindrical cold bottle capable of directionally guiding cold energy is developed.

SUMMERY OF THE UTILITY MODEL

The technical problem to be solved by the utility model is to provide a cylindrical cold bottle with directional flow guiding cold energy, which has the advantages of simple and compact structure, long service life, uniform cold energy transmission, small temperature difference, long cold insulation and the like; therefore, the device has excellent performance in the aspects of technical performance, practicability and economical efficiency.

In order to realize the above purpose, the utility model adopts the technical scheme that a tube-shape cold bottle of directional water conservancy diversion cold energy is provided, it includes:

a cup housing including at least a closed bottom, a sidewall connecting the bottom; the side wall is parallel to or unparallel to the surface of the first inner wall to form a temperature-resistant vacuum layer;

a cold accumulation release cavity is formed between the second inner wall and the first inner wall, and a cold accumulation agent is arranged in the cold accumulation release cavity;

the cold accumulation release cavity is blocked by the temperature-resistant vacuum layer in the direction of the side wall, and the cold accumulation release cavity conveys cold energy to the placing cavity from the second inner wall so as to directionally guide the flow, so that the temperature is changed.

In one or more embodiments of the present invention, the heat exchanger includes a heat transfer member, at least a portion of which is in contact with the second inner wall to receive the heat transferred from the heat exchanger.

In one or more embodiments of the present invention, the cold conduction and transfer member is connected to the cold energy generator.

In one or more embodiments of the present invention, the cold energy generator includes a cold energy output portion contacting the cold conducting and transmitting member, a semiconductor cooling plate connected to the cold energy output portion, a heat dissipating fin portion connected to the semiconductor cooling plate, and a heat dissipating fan.

In one or more embodiments of the present invention, the cold conducting and transferring member has a cylindrical receiving cavity at the bottom; the semiconductor refrigerating sheet generates cold energy to be transmitted to the cold energy output part, and the cold energy is transmitted to the cold storage agent by the cold conduction transmission component.

In one or more embodiments of the present invention, the cup shell provides a screw portion, a clamping portion, or a screwing portion for the cooperation of the cover.

In one or more embodiments of the present invention, the cold energy output portion and the cold conduction transmission member are detachable via the thermal insulating pad to prevent the cold energy from being released to the outside or not to be in contact with each other directly to be conducted between the cold energy output portion and the cold conduction transmission member.

In one or more embodiments of the present invention, the coolant is a phase-change coolant; the cooling fan and the semiconductor refrigeration piece are connected with the direct current socket.

In one or more embodiments of the present invention, the cover further comprises a controller, and the controller is disposed on the side wall of the cover.

In one or more embodiments of the present invention, the cover further comprises a controller, the controller is disposed outside the cover body, and the controller comprises a control connection line, an insertion connector connected to the control connection line, a power plug connected to the power line, a display screen, and a control key; the built-in joint is connected with the direct current socket.

In one or more embodiments of the present invention, the cover further comprises a controller, the controller is disposed outside the cover body, and the controller comprises a control connection line, an insertion connector connected to the control connection line, a power plug connected to the power line, a display screen, and a control key; the built-in joint is connected with the direct current socket.

Compared with the prior art, the utility model the effect that exists is:

by adopting the scheme, the utility model has the advantages of simple and compact structure, long service life, uniform cold energy transmission, small temperature difference, long cold insulation and the like; therefore, the device has excellent performance in the aspects of technical performance, practicability and economical efficiency.

Drawings

Fig. 1 is a schematic structural view of a cylindrical cold bottle for directionally guiding cold energy in an embodiment of the present invention in a cold transfer state;

fig. 2 is a schematic structural diagram of a cylindrical cold bottle for directionally guiding cold energy in an embodiment of the present invention in a cold insulation state;

fig. 3 is a schematic perspective view of a cylindrical cold bottle for directionally guiding cold energy according to an embodiment of the present invention;

FIG. 4 is a schematic view of the expanded structure of the cylindrical cooling bottle for directionally guiding the cooling energy in FIG. 3;

FIG. 5 is a schematic view of the expanded structure of the cylindrical cooling bottle for directional diversion of cooling energy in FIG. 3 from another view angle;

FIG. 6 is a schematic view of the cylindrical cooling bottle with directional flow guiding of cooling energy in FIG. 5 in a further expanded configuration;

fig. 7 is a schematic structural view of a cylindrical cold bottle for directionally guiding cold energy according to an embodiment of the present invention in a use state;

those skilled in the art can appreciate that the shapes, configurations and arrangements of the various elements shown in the drawings are not necessarily to scale, and that the dimensions of the various elements and components of the drawings may be exaggerated or minimized to more clearly illustrate the embodiments of the present invention described herein.

Detailed Description

Reference will now be made in detail to the embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar functions throughout.

The orientation shown in the drawings is not to be considered as limiting the scope of the invention, but merely as providing a reference to the preferred embodiments, changes in position or addition of numbers or structural simplifications may be made to the product parts shown in the drawings.

The relation of "connected" between the components shown in the drawings and described in the specification can be understood as fixedly connected or detachably connected or integrally connected; the connecting elements can be directly connected or connected through an intermediate medium, and persons skilled in the art can understand the connecting relation according to specific conditions, and can use the connecting elements in a screwed connection or riveting connection or welding connection or clamping connection or embedding connection mode to replace different embodiments in a proper mode.

The terms of orientation such as up, down, left, right, top, bottom, and the like in the description and the orientation shown in the drawings, may be used for direct contact or contact with each other through another feature therebetween; above may be directly above and obliquely above, or it simply means above the other; other orientations may be understood by analogy. The technical solution and the advantages of the present invention will be more clear and clear by further describing the embodiments of the present invention with reference to the drawings of the specification.

Detailed description of the preferred embodimentsreference is made below to the specific embodiments illustrated in fig. 1-7, however, those skilled in the art will readily appreciate that the detailed description given herein with respect to these figures is for illustrative purposes only and should not be construed as limiting, as the present invention provides that the preferred embodiment is a directional flow directing cold energy cylinder cold bottle comprising a cup housing 1, a cold storage agent 2, and a cold conduction transfer member 3; the cup housing 1 comprises a closed bottom 11 and a side wall 12 connecting the bottom 11; the side wall 12 and the surface of the first inner wall 13 are arranged in parallel or in nonparallel to form a temperature-resistant vacuum layer 14; and a second inner wall 15 forming a cold accumulation release cavity 16 with the first inner wall 13, wherein the cold accumulation release cavity 16 is internally provided with the cold accumulation agent 2. During cold insulation, the cold accumulation release cavity 16 is blocked by the temperature-resistant vacuum layer 14 in the direction of the side wall, and the cold energy is conveyed to the placing cavity from the second inner wall 15 to directionally guide the flow of cold energy, so that the temperature is changed.

Further, the efficiency of the transmitted cold energy is enhanced, and the device comprises a cold conduction and transmission member 3 which is at least partially contacted with the second inner wall 15 and receives the transmitted cold energy. The cold conduction and transmission component 3 is connected with a cold energy generator 4.

The cold energy generator 4 includes a cold energy output portion 41 contacting the cold conduction transfer member 3, a semiconductor cooling fin portion 42 connected to the cold energy output portion 41, a heat radiation fin portion 43 connected to the semiconductor cooling fin portion 42, and a heat radiation fan 44. The cold conduction and transmission component 3 is provided with a cylindrical accommodating cavity at the bottom; the semiconductor cooling fins 42 generate cold energy and transmit the cold energy to the cold energy output portion 41, and the cold energy is transmitted to the coolant 2 through the cold conduction transmission member 3.

The cup shell 1 provides a detachable connection structure mode such as a screw connection part 17, a clamping part or a screwing part for the matching of the cover body 5. The cover 5 may be formed as a single body or as separate bodies.

The cold energy output part 41 and the cold conduction and transmission member 3 are detachably arranged between the cold energy output part and the cold conduction and transmission member by the thermal insulation pad 6, and the cold insulation state of preventing cold conduction from releasing outwards or the cold conduction state of not arranging between the cold energy output part and the cold conduction and transmission member so as to make the cold energy output part 41 directly contact and conduct with the cold conduction and transmission member 3 is converted. The thermal insulating pad 6 provides a matching groove 61 or a protrusion for the cold energy output portion 4 to facilitate connection sealing. The cold storage agent 2 is a phase-change cold storage agent, and the phase-change cold storage agent preferably has a phase-change temperature of 5 ℃ or 18 ℃ so as to meet the requirements of users on short-term or long-term medicine storage; the heat dissipation fan 44 and the semiconductor refrigeration sheet 42 are connected with the direct current socket 7. The thermal insulation pad 6 is made of elastic material.

Further, the device also comprises a controller 8, wherein the controller 8 is provided with the side wall of the cover body 5, and can also be arranged outside the cover body 5; the controller 8 comprises a control connecting wire 81, an embedded connector 82 connected with the control connecting wire 81, a power plug 84 connected with a power line 83, a display screen 85 and a control key 86; the built-in joint is connected with the direct current socket.

When in cold transmission use, the heat insulation pad 6 is arranged on the outer bottom surface of the cold conduction and transmission component 3, and the rebound force of the heat insulation pad 6 enables the cold conduction and transmission component 3 to be tightly contacted with the cold energy output part 41; to ensure good energy transfer. The cold energy generator 4 is electrified to generate cold energy, and simultaneously drives the radiating fan 44 to discharge the heat of the radiating fin part 43; the semiconductor refrigerating sheet 42 generates cold energy to be transmitted to the cold energy output part 41, and transmits the cold energy to the cold storage agent 2 by the cold conduction transmission component 3; the cold energy output part 41 is directly contacted with the cold conduction and transmission component 3 to conduct and transmit cold, thereby effectively improving the conduction efficiency and enlarging the conduction surface.

When the cold insulation device is used for cold insulation, the cold accumulation release cavity 16 is blocked by the temperature-resistant vacuum layer 14 in the direction of the side wall and is conveyed to the placing cavity from the second inner wall 15 to directionally guide cold energy, so that the temperature is changed. The cold energy output part 41 and the cold conduction and transmission member 3 are detachably inserted between them by the thermal insulation pad 6 to prevent the cold energy from being released outwards. The warm pad 6 is engaged with the mouth of the cold energy output part 41 to prevent the energy transmission between the cold conduction and transmission member 3 and the cold energy output part 41, thereby prolonging the cold insulation time. Therefore, the structure is simple and compact, the service life is long, the cold energy is conveyed uniformly, the temperature difference is small, and the cold insulation is lasting.

The foregoing description, for purposes of explanation, used specific nomenclature to provide a thorough understanding of the embodiments. However, it will be apparent to one skilled in the art that the specific details are not required in order to practice the embodiments. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and modifications and substitutions based on the known art are intended to fall within the scope of the present invention, which is defined by the claims.

Claims (10)

1. The utility model provides a cold bottle of tube-shape of directional water conservancy diversion cold energy which characterized in that, it includes:

a cup housing including at least a closed bottom, a sidewall connecting the bottom; the side wall is parallel to or unparallel to the surface of the first inner wall to form a temperature-resistant vacuum layer;

a cold accumulation release cavity is formed between the second inner wall and the first inner wall, and a cold accumulation agent is arranged in the cold accumulation release cavity;

the cold accumulation release cavity is blocked by the temperature-resistant vacuum layer in the direction of the side wall, and the cold accumulation release cavity conveys cold energy to the placing cavity from the second inner wall so as to directionally guide the flow, so that the temperature is changed.

2. The cylindrical cold bottle for directionally guiding cold energy according to claim 1, wherein: it includes at least one part contacting with the second inner wall to receive the cold conducting and transmitting component.

3. The cylindrical cold bottle for directional diversion of cold energy according to claim 2, wherein: the cold conduction and transmission component is connected with the cold energy generator.

4. The cylindrical cold bottle for directionally guiding cold energy according to claim 3, wherein: the cold energy generator comprises a cold energy output part contacting with the cold guide transmission component, a semiconductor refrigeration piece connected with the cold energy output part, a radiating fin part connected with the semiconductor refrigeration piece and a radiating fan.

5. The cylindrical cold bottle for directionally guiding cold energy according to claim 4, wherein: the cold conduction and transmission component is provided with a cylindrical accommodating cavity at the bottom; the semiconductor refrigerating sheet generates cold energy to be transmitted to the cold energy output part, and the cold energy is transmitted to the cold storage agent by the cold conduction transmission component.

6. The cylindrical cold bottle for directional diversion of cold energy according to claim 5, wherein: the cup shell is matched with the cover body to provide a screw connection part, a clamping part or a screwing part.

7. The cylindrical cold bottle for directionally guiding cold energy according to claim 6, wherein: the cold energy output part and the cold conduction transmission member are detachably arranged between the cold energy output part and the cold conduction transmission member through the thermal insulation pad, so that cold energy is prevented from being released outwards, or the cold conduction state which is not arranged between the cold energy output part and the cold conduction transmission member is changed between the cold insulation state and the cold conduction state and is directly contacted and conducted with the cold conduction transmission member.

8. The cylindrical cold bottle for directional diversion of cold energy according to claim 7, wherein: the cold storage agent is a phase change cold storage agent; the cooling fan and the semiconductor refrigeration piece are connected with the direct current socket.

9. The cylindrical cold bottle for directional diversion of cold energy according to claim 7, wherein: it still includes the controller, the controller is located the lid lateral wall.

10. The cylindrical cold bottle of directional diversion cold energy of claim 8, wherein: the controller is arranged outside the cover body and comprises a control connecting wire, an embedded joint connected with the control connecting wire, a power plug connected with a power line, a display screen and a control key; the built-in joint is connected with the direct current socket.

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