CN115218553A - Energy charging system of portable cold and heat storage device and heat conduction structure thereof - Google Patents

Abstract

The invention relates to an energy charging system of a portable cold and heat storage device and a heat conduction structure thereof. Each heat conducting structure is provided with two heat conducting plates connected with the temperature adjusting device. One side surface of each cold and heat storage box is recessed to form two heat conduction grooves. The two heat conduction grooves of the cold and heat accumulation box can be separately sleeved outside the two heat conduction plates of the heat conduction structure, and the two opposite side surfaces of the heat conduction plates are respectively attached to the two opposite groove walls of the heat conduction grooves. Compared with the cooling or heating from the outer side surface of the cold and heat accumulation box, the invention inserts the heat conduction plate into the heat conduction groove of the cold and heat accumulation box, so that the cold energy or the heat energy can be quickly transferred to all the cold and heat accumulation agents in the cold and heat accumulation box through the heat conduction plate, and the time required by the cold and heat accumulation box to be cooled and solidified or heated to a specific temperature can be greatly shortened.

Description

Energy charging system of portable cold and heat storage device and heat conduction structure thereof

Technical Field

The invention relates to a freezing or heating insulation system with a portable cold and heat accumulation device, in particular to a low-temperature insulation system matched with a low-temperature distribution box of vehicles such as automobiles, motorcycles or electric bicycles and the like.

Background

In recent years, the rise of catering and low-temperature fresh delivery platforms enables the logistics business of delivery by using automobiles, motorcycles, electric bicycles or bicycles to be developed vigorously. Wherein, the low temperature fresh food must keep the temperature in the whole course in the distribution process to avoid deterioration, and the portable cold accumulation ice box which is frozen in advance is arranged in the low temperature distribution box to carry out the low temperature distribution.

The existing method for freezing the cold-storage ice boxes is to stack the cold-storage ice boxes on the market and then place the stacked cold-storage ice boxes into a freezer/box, and then take out the cold-storage ice boxes for distribution after the cold-storage ice boxes are completely frozen in the freezer/box. However, the convection heat transfer coefficient of the freezer/refrigerator and the heat transfer coefficient of the cold-storage ice box in the state of liquid state to solid state are both low, so that the existing cold-storage ice box can be completely cooled, solidified and frozen after at least 3 to 7 days, the freezing efficiency is very poor, personnel cannot be rapidly replaced, and the use is inconvenient.

Therefore, the freezing system of the prior art cold storage device is in need of improvement.

Disclosure of Invention

In view of the above-mentioned shortcomings and drawbacks of the prior art, the present invention provides a charging system for portable cold and heat storage device and a heat conducting structure thereof, which can increase the cooling and solidification speed.

The invention provides an energy charging system of a portable cold and heat accumulation device, which can separately penetrate a heat conduction structure into a cold and heat accumulation ice box, thereby improving the cooling and solidification speed.

In order to achieve the above object, the present invention provides a charging system for a portable cold and heat storage device, comprising:

a temperature adjusting device;

at least one heat conducting structure having:

at least one heat conducting plate connected to the temperature regulator;

at least one cold and heat accumulation box, which is filled with cold and heat accumulation agent; one side surface of the cold and heat storage box is recessed to form at least one heat conduction groove; at least one heat conduction groove of the cold and heat accumulation box can be separately sleeved outside at least one heat conduction plate of the heat conduction structure; the two opposite side surfaces of the heat conducting plate are respectively attached to the two opposite groove walls of the corresponding heat conducting grooves;

the temperature adjusting device cools or heats the cold and heat storage box through the heat conduction structure.

Further, the heat conducting plate of the heat conducting structure comprises a fixing part and a penetrating part which are bent oppositely; one side surface of the fixing part is tightly propped against the temperature adjusting device; the penetrating parts can penetrate through the corresponding heat conducting grooves separately.

Further, the heat conducting plate of the heat conducting structure is provided with at least one heat pipe.

Further, the heat conducting plate of the heat conducting structure is provided with at least one heat pipe, and the at least one heat pipe extends from the fixing portion of the heat conducting plate to the penetrating portion.

Further, the heat conducting plate of the heat conducting structure is concavely provided with at least one heat pipe mounting groove;

the heat pipe is arranged in the heat pipe mounting groove; the heat pipe is attached to one of the groove walls of the heat conduction grooves of the temperature adjusting device and the cold and heat accumulation box.

Further, at least one heat pipe installation groove is concavely formed on the heat conduction plate of the heat conduction structure, and the at least one heat pipe installation groove tightly abuts against one side surface of the temperature adjusting device from the fixing part of the heat conduction plate and extends to the penetrating part;

the heat pipe is arranged in the heat pipe mounting groove; the heat pipe is attached to one of the groove walls of the heat conduction grooves of the temperature adjusting device and the cold and heat accumulation box.

Further, the heat pipe is a flat pipe, and two opposite side surfaces of the heat pipe are respectively attached to one of the walls of the heat conducting plate and the heat conducting groove.

To achieve the above object, the present invention further provides a heat conduction structure of an energy charging system of a portable cold and heat storage device, the heat conduction structure of the energy charging system of the portable cold and heat storage device comprising: the heat conduction structure is used for connecting the temperature adjusting device and the cold and heat storage box so as to cool or heat the cold and heat storage box through the temperature adjusting device; at least one heat conduction groove is formed on one side surface of at least one cold and heat storage box in a concave way; the heat conducting structure comprises:

at least one heat conducting plate for connecting the temperature regulating device; the heat conducting plate is used for separately penetrating and arranging in the heat conducting groove of the cold and heat accumulation box; the two opposite side surfaces of the heat conducting plate are respectively attached to the two opposite groove walls of the heat conducting groove.

Further, the heat conducting plate of the heat conducting structure comprises a fixing part and a penetrating part which are bent oppositely; one side surface of the fixing part is tightly propped against the temperature adjusting device; the penetrating parts can penetrate through the corresponding heat conducting grooves separately.

Further, the heat conducting plate of the heat conducting structure is provided with at least one heat pipe.

Further, the heat conducting plate of the heat conducting structure is provided with at least one heat pipe, and the at least one heat pipe extends from the fixing portion of the heat conducting plate to the penetrating portion.

Furthermore, the heat conducting plate of the heat conducting structure is concavely provided with at least one heat pipe installation groove;

at least one heat pipe is arranged in the heat pipe mounting groove; the heat pipe is used for being attached to one of the groove walls of the heat conduction grooves of the temperature adjusting device and the cold and heat storage box.

Further, at least one heat pipe installation groove is concavely formed on the heat conduction plate of the heat conduction structure, and the at least one heat pipe installation groove tightly abuts against one side surface of the temperature adjusting device from the fixing part of the heat conduction plate and extends to the penetrating part;

the heat pipe is arranged in the heat pipe mounting groove; the heat pipe is used for being attached to one of the groove walls of the heat conduction grooves of the temperature adjusting device and the cold and heat storage box.

Further, the heat pipe is a flat pipe, and two opposite side surfaces of the heat pipe are respectively attached to one of the walls of the heat conducting plate and the heat conducting groove.

The invention has the characteristics and advantages that:

the cold and heat storage box is provided with a heat conduction groove which is sleeved with the heat conduction groove of the cold and heat storage box, and two opposite groove walls of the heat conduction groove are respectively attached to two opposite side surfaces of the heat conduction plate. Therefore, the average distance between the heat conduction plate and the cold and heat storage agent at each position in the cold and heat storage box is smaller than the average distance between any outer side surface of the cold and heat storage box and the cold and heat storage agent at each position in the cold and heat storage box; that is, compared with the cooling or heating from the outer side surface of the cold and heat storage box, the invention inserts the heat conducting plate into the heat conducting groove of the cold and heat storage box, so that the cold energy or the heat energy can be quickly transferred to all the cold and heat storage agents in the cold and heat storage box through the heat conducting plate, and the time required by the energy charging (namely, the cooling solidification or the heating to a specific temperature) of the cold and heat storage box can be greatly shortened, and the use is more convenient.

Drawings

The drawings described herein are for illustration purposes only and are not intended to limit the scope of the present disclosure in any way. In addition, the shapes, the proportional sizes, and the like of the respective members in the drawings are merely schematic for facilitating the understanding of the present invention, and do not specifically limit the shapes, the proportional sizes, and the like of the respective members of the present invention. Those skilled in the art, having the benefit of the teachings of this invention, may effect this invention by selecting various possible shapes and proportional dimensions as appropriate.

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings required to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the description below are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic perspective view of a charging system of a portable cold and heat storage device according to a first embodiment of the present invention.

Fig. 2 is a schematic partial top view of a charging system of a portable cold and thermal storage device according to a first embodiment of the present invention.

Fig. 3 is a perspective external view of the heat-conducting plate of the first embodiment of the charging system of the portable cold and heat storage device of the present invention.

Fig. 4 is a schematic sectional view of the charging system of the first embodiment of the portable cold and heat storage device of the present invention.

Fig. 5 is a perspective external view of the heat-conducting plate of the second embodiment of the charging system of the portable cold and heat storage device of the present invention.

Detailed Description

The details of the invention will become more apparent in the light of the following description of specific embodiments thereof, as illustrated in the accompanying drawing. However, the specific embodiments of the present invention described herein are for the purpose of illustration only and are not to be construed as limiting the invention in any way. Any possible variations based on the present invention may be conceived by the skilled person in the light of the teachings of the present invention, and these should be considered as falling within the scope of the present invention.

It will be understood that when an element is referred to as being "secured to" or "disposed" on another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or intervening elements may be present.

The technical means adopted by the invention to achieve the predetermined object of the invention are further described below with reference to the drawings and the preferred embodiments of the invention.

Referring to fig. 1, 2 and 4, the charging system of the portable cold and heat storage device of the present invention comprises a temperature adjusting device 10, a plurality of heat conducting structures 20 and a plurality of cold and heat storage boxes 30.

The thermostat 10 is a device that can continuously absorb heat energy (i.e. cool the other object) or generate heat energy (i.e. heat the other object). In the present embodiment, the temperature control device 10 is a refrigerant evaporator of a refrigeration equipment, and performs cooling by absorbing heat through refrigerant evaporation, but the present invention is not limited thereto, and the temperature control device 10 may be a large amount of cryogenic fluid or an electric heater, for example.

The heat-conducting structures 20 each have two heat-conducting plates 21 arranged at a distance from each other, and each heat-conducting plate 21 is connected to the temperature-regulating device 10. In other preferred embodiments, each heat conducting structure 20 may have only one heat conducting plate 21, and the present invention may have only one heat conducting structure 20.

In the present embodiment, each heat conducting plate 21 includes a fixing portion 211 and a penetrating portion 212 bent relatively. One side of the fixing portion 211 abuts against the temperature adjustment device 10 to ensure that heat energy can be rapidly transferred between the fixing portion 211 and the temperature adjustment device 10. The penetrating portion 212 extends in a direction away from the temperature adjustment device 10. The two through portions 212 of the two heat conductive plates 21 of each heat conductive structure 20 are parallel to each other. The heat conducting plate 21 is preferably made of a material having good thermal conductivity, such as copper, aluminum, or graphite.

Referring to fig. 2 to 4, further, a plurality of heat pipe installation grooves 213 are formed on each heat conduction plate 21, and a plurality of heat pipes 22 are disposed on each heat conduction plate 21. The heat pipe installation groove 213 extends from one side surface of the fixing portion 211 of the heat conduction plate 21 abutting against the temperature adjustment device 10 to the penetration portion 212. Each heat pipe 22 is disposed in a corresponding heat pipe mounting groove 213, and the heat pipe 22 extends from the fixing portion 211 to the penetrating portion 212 of the heat conducting plate 21, and one end of the heat pipe 22 located at the fixing portion 211 directly abuts against the temperature adjusting device 10 to improve the heat conducting effect. More specifically, the heat pipe 22 is a flat pipe, one of the two opposite side surfaces thereof abuts against the bottom of the heat pipe installation groove 213, and the other side surface thereof abuts against the temperature adjustment device 10, but the heat pipe 22 is not limited to be flat. In addition, the heat pipe 22 is not limited to be disposed in the groove of the heat conducting plate 21, and only the heat pipe 22 contacts the heat conducting plate 21 to increase the transmission speed of the heat energy between the fixing portion 211 and the penetrating portion 212. In other preferred embodiments, each heat-conducting plate 21 can be provided with only one heat pipe 22. In addition, referring to fig. 5, in the second embodiment of the charging system of the portable cold and heat storage device of the present invention, the heat conducting plate 21A may be a plate body made of a material with good thermal conductivity without the heat pipe 22.

Referring to fig. 1 and 4, the cold and heat storage box 30 is filled with a cold and heat storage agent, one side of each cold and heat storage box 30 is recessed to form two heat conduction grooves 31, the two heat conduction grooves 31 are respectively detachably sleeved outside the two penetrating portions 212 of the two heat conduction plates 21 of the corresponding heat conduction structure 20, and the two opposite groove walls of each heat conduction groove 31 respectively abut against the two opposite side surfaces of the corresponding penetrating portion 212, so as to increase the contact area and increase the heat conduction speed. In this embodiment, one of the walls of the heat-conducting grooves 31 is more directly against one side of the heat pipe 22.

When the invention is used, the cold and heat storage box 30 to be cooled is sleeved into the heat conduction plate 21 of any heat conduction structure 20 by aligning the heat conduction groove 31. Through practical tests, the cold and heat storage box 30 which is 2 kilograms in weight and has the solidification temperature of minus 23 ℃ can be completely cooled and solidified after about 2 hours. The cooled and solidified cold and heat storage box 30 can be drawn out and placed in the insulation box for low-temperature distribution.

In summary, the present invention forms the heat conduction groove 31 in the cold-and-heat-accumulating box 30, and inserts the heat conduction plate 21 into the heat conduction groove 31 of the cold-and-heat-accumulating box 30, so that the cold energy or the heat energy can be quickly transferred to the cold-and-heat-accumulating agent in the cold-and-heat-accumulating box 30 via the heat conduction plate 21, and the time required for charging the cold-and-heat-accumulating box can be greatly shortened, and the use is more convenient.

Although the present invention has been described with reference to the preferred embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but is intended to cover various modifications, equivalents and alternatives falling within the spirit and scope of the invention.

Claims (14)

1. An energy charging system for a portable cold and heat storage device, comprising:

a temperature adjusting device;

at least one heat conducting structure having:

at least one heat conducting plate connected with the temperature adjusting device;

at least one cold and heat accumulation box, which is filled with cold and heat accumulation agent; at least one heat conduction groove is formed on one side surface of the cold and heat accumulation box in a concave mode; at least one heat conduction groove of the cold and heat accumulation box can be separately sleeved outside at least one heat conduction plate of the heat conduction structure; the two opposite side surfaces of the heat conducting plate are respectively attached to the two opposite groove walls of the corresponding heat conducting grooves;

the temperature adjusting device cools or heats the cold and heat storage box through the heat conducting structure.

2. The charging system for portable cold-and heat-storage device as claimed in claim 1, wherein the heat-conducting plate of the heat-conducting structure comprises a fixing portion and a penetrating portion bent oppositely; one side surface of the fixing part tightly abuts against the temperature adjusting device; the penetrating parts can penetrate through the corresponding heat conducting grooves separately.

3. The charging system for portable cold and thermal storage devices of claim 1, wherein said thermally conductive plate of said thermally conductive structure is provided with at least one heat pipe.

4. The charging system for portable cold and heat storage devices according to claim 2, wherein the heat-conducting plate of the heat-conducting structure is provided with at least one heat pipe, at least one heat pipe extending from the fixing portion of the heat-conducting plate to the penetrating portion.

5. The charging system for portable cold-and heat-storage device as defined in claim 3,

the heat conducting plate of the heat conducting structure is concavely provided with at least one heat pipe mounting groove;

the heat pipe is arranged in the heat pipe mounting groove; the heat pipe is attached to one of the temperature adjusting device and the heat conducting groove of the cold and heat storage box.

6. The portable cold and heat storage device charging system according to claim 4,

the heat conducting plate of the heat conducting structure is concavely provided with at least one heat pipe installation groove, and the at least one heat pipe installation groove tightly abuts against one side surface of the temperature adjusting device from the fixing part of the heat conducting plate and extends to the penetrating part;

the heat pipe is arranged in the heat pipe mounting groove; the heat pipe is attached to one of the groove walls of the heat conduction grooves of the temperature adjusting device and the cold and heat accumulation box.

7. The charging system for portable cold and heat storage devices according to any one of claims 3 to 6, wherein the heat pipe is a flat pipe body, and opposite sides of the heat pipe respectively abut against one of the walls of the heat-conducting plate and the heat-conducting groove.

8. A heat conduction structure of an energy charging system of a portable cold and heat storage device, characterized in that the heat conduction structure of the energy charging system of the portable cold and heat storage device comprises:

the heat conduction structure is used for connecting the temperature adjusting device and the cold and heat storage box so as to enable the temperature adjusting device to cool or heat the cold and heat storage box through the heat conduction structure; at least one heat conduction groove is formed on one side surface of at least one cold and heat storage box in a concave way; the heat conductive structure includes:

at least one heat conducting plate for connecting the temperature regulating device; the heat conducting plate is detachably arranged in the heat conducting groove of the cold and heat storage box in a penetrating manner; the two opposite side surfaces of the heat conducting plate are respectively attached to the two opposite groove walls of the heat conducting groove.

9. The heat conducting structure of the charging system for portable cold and heat storage device according to claim 8, wherein the heat conducting plate of the heat conducting structure comprises a fixing portion and a penetrating portion bent oppositely; one side surface of the fixing part tightly abuts against the temperature adjusting device; the penetrating parts can penetrate through the corresponding heat conducting grooves separately.

10. The heat conducting structure of the charging system for portable cold and thermal storage devices of claim 8, wherein the heat conducting plate of the heat conducting structure is provided with at least one heat pipe.

11. The heat conducting structure of the charging system for portable cold and thermal storage device according to claim 9, wherein the heat conducting plate of the heat conducting structure is provided with at least one heat pipe, at least one heat pipe extending from the fixing portion of the heat conducting plate to the penetrating portion.

12. The heat conduction structure of the charging system for portable cold-and heat-storage device as claimed in claim 10,

the heat conducting plate of the heat conducting structure is concavely provided with at least one heat pipe mounting groove;

at least one heat pipe is arranged in the heat pipe mounting groove; the heat pipe is used for being attached to one of the groove walls of the heat conduction grooves of the temperature adjusting device and the cold and heat storage box.

13. The heat conducting structure of the charging system for portable cold and thermal storage device according to claim 11,

the heat conducting plate of the heat conducting structure is concavely provided with at least one heat pipe installation groove, and the at least one heat pipe installation groove tightly abuts against one side surface of the temperature adjusting device from the fixing part of the heat conducting plate and extends to the penetrating part;

the heat pipe is arranged in the heat pipe mounting groove; the heat pipe is used for being attached to one of the groove walls of the heat conduction grooves of the temperature adjusting device and the cold and heat storage box.

14. The heat conduction structure of the charging system for portable cold-and heat-storage device according to any one of claims 10 to 13, wherein the heat pipe is a flat pipe body, and opposite side surfaces of the heat pipe respectively abut against one of the walls of the heat-conducting plate and the heat-conducting groove.

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