CN201909408U - Energy storage type refrigerating device - Google Patents

Abstract

The utility model discloses an energy storage type refrigerating device, which is characterized in that: the energy storage type refrigerating device comprises an energy storage box, a plurality of heat insulation walls and at least one thermal conduction wall, wherein energy storage medium is stored in the energy storage box, and a thermal insulation door is arranged on the thermal conduction wall. With the adoption of the energy storage type refrigerating device, heat absorption speed of the energy storage medium can be controlled, thereby stable cooling and dehumidifying effects can be provided.

Description

The energy storage type refrigerating plant

Technical field

The utility model relates to a kind of energy storage type refrigerating plant.

Background technology

When the people when stopping in the narrow space (for example, indoor, compartment, cabin etc.), because the heat of various device radiation in the heat of human body radiation and the space can make the temperature in the space constantly rise.In addition, along with the respiratory activity of human body, water loading of the air also can raise gradually.Because human body is difficult to adapt to the environment of high temperature, high humidity, therefore when the people stops, need take cooling, dehumidifying measure in narrow space to this environment.

Usually, people adopt air-conditioner to reduce temperature and humidity in the environment, promptly, utilize cold-producing medium to take to indoor heat outdoor in the circulation between evaporimeter and condenser under the driving of compressor, utilize the low temperature of evaporator surface to make airborne moisture simultaneously, thereby reduce indoor humidity in the evaporator surface condensation.

Yet, the running that the running of air-conditioner needs consumed power to come the drive compression machine is under the situation of the supply that is being difficult to guarantee electric energy, for example, in compartment that breaks down or the colliery down-hole survival capsule that has an accident, then need to adopt other mode to reduce temperature and humidity in the environment.

Used energy-accumulating medium such as ice cube as the means that make the environment temperature reduction dehumidifying; yet; directly use the problem of ice cube to be that uncontrollable ice cube absorbs the speed of heat; thereby the temperature and humidity that is difficult to control environment accurately; and, therefore be difficult to the refrigeration that provides lasting because energy-accumulating mediums such as ice cube can melt usually apace.

The utility model content

Therefore, the purpose of this utility model is to provide a kind of heat absorption speed that can control energy-accumulating medium, thereby the energy storage type refrigerating plant of lasting cool-down dehumidification effect can be provided.

One side of the present utility model provides a kind of energy storage type refrigerating plant, and refrigerating plant comprises during described energy storage: the energy storage case, have a plurality of thermal wall and at least one heat conducting wall, and storage has energy-accumulating medium in the energy storage case; Insulated door is arranged on the described heat conducting wall.

According to one side of the present utility model, described insulated door is made up of a plurality of sub-insulated doors, and described a plurality of sub-insulated doors can independent opening and closing.

According to one side of the present utility model, described sub-insulated door is along the direction setting parallel with the bottom of energy storage case.

According to one side of the present utility model, described heat conducting wall comprises a plurality of ventilation slot and cooling fins that vertically extend.

According to one side of the present utility model, the bottom of described heat conducting wall is provided with hot well.

According to one side of the present utility model, described energy-accumulating medium is a drinking water.

According to one side of the present utility model, described energy-accumulating medium is a nutrient solution.

According to one side of the present utility model, described insulated door top is provided with circulating fan.

According to one side of the present utility model, be provided with refrigerating plant in the described energy storage case.

Description of drawings

By the description of carrying out below in conjunction with accompanying drawing to the utility model exemplary embodiment, feature of the present utility model and/or advantage will become clearer, in the accompanying drawings:

Fig. 1 is the cutaway view according to the energy storage type refrigerating plant of the utility model embodiment;

Fig. 2 is the schematic diagram of the insulated door of the energy storage type refrigerating plant of Fig. 1 when partially opening;

Fig. 3 is the cutaway view along the line III-III ' intercepting of Fig. 1.

The specific embodiment

Describing illustrative examples of the present utility model below with reference to accompanying drawings, only is in order to make those skilled in the art can be well understood to principle of the present utility model yet these drawings and Examples are provided, rather than for the restriction the purpose of this utility model.

Fig. 1 is the cutaway view according to the energy storage type refrigerating plant of the utility model embodiment, and Fig. 2 is the schematic diagram of the insulated door of the energy storage type refrigerating plant of Fig. 1 when partially opening.

See figures.1.and.2, energy storage type refrigerating plant 100 of the present utility model comprises: energy storage case 110, have a plurality of thermal wall 111 and at least one heat conducting wall 112, and storage has energy-accumulating medium in energy storage case 110; Insulated door 120 is arranged on the described heat conducting wall 112.

Thermal wall 111 can form bottom and a part of sidewall of energy storage case 110, and heat conducting wall 112 can form other sidewall of energy storage case 110.Wherein, thermal wall 111 can be formed by heat-barrier material, to prevent between energy storage case inside and outside heat exchange taking place.Yet the utility model is not limited thereto, and thermal wall 111 also can be formed by the sandwich construction that comprises thermal insulation layer.Heat conducting wall 112 can be formed by the thermal conductivity excellent material, and for example, heat conducting wall 112 can be formed by heat conduction nonmetallic materials such as thermal conductive metallic materials such as copper, aluminium, thermal conductive ceramic or conducting polymer materials etc.

Insulated door 120 is arranged on each heat conducting wall 112, and covers the whole surface of heat conducting wall 112.Insulated door and having and thermal wall 111 same or analogous structure or materials.When insulated door 120 was closed, heat exchanges took place with outside by heat conducting wall 112 in the inside that can prevent energy storage case 110, thereby can prevent between the inside of energy storage case 110 and the outside heat exchange to take place.Therefore, when needs freeze, open insulated door 120, when not needing to freeze, close insulated door 120

According to an embodiment of the present utility model, insulated door 120 also can comprise a plurality of sub-insulated doors 125.Wherein, sub-insulated door 125 can be opened or close independently, and each sub-insulated door 125 includes heat-barrier material or heat insulation structural.When group insulated door 125 is closed, combine closely between the sub-insulated door 125, thereby utilize insulated door 120 to prevent that heat from passing through heat conducting wall 112 and transmitting.According to this embodiment, when the bigger refrigerating capacity of needs, can open more sub-insulated door 125, to increase heat transfer area, accelerate heat transfer rate; When the less refrigerating capacity of needs, can open less sub-insulated door 125, thereby dwindle heat transfer area, slow down heat transfer rate.Therefore, utilize a plurality of sub-insulated doors 125, can control rate of heat transfer more accurately.

When insulated door 120 was opened, the air that contact with heat conducting wall 112 was cooled, thereby made these atmospheric density become big and move downward, and indoor air was had to plant and moved downward the negative pressure of generation and be attracted to heat conducting wall 112 this moment.Simultaneously, the cold air that moves downward is discharged energy storage type refrigerating plant 100 from the below.Thereby form the circulating current shown in the direction of arrow among Fig. 2.When air-flow at heat conducting wall 112 place's circulation times, the temperature of air reduces, steam condenses on the surface of heat conducting wall 112 and becomes condensed water simultaneously.Condensed water flows down to the hot well 115 that is arranged on heat conducting wall 112 bottoms along heat conducting wall 112.

Preferably, sub-insulated door 125 can utilize such structure along the direction setting parallel with the bottom of energy storage case, when opening less sub-insulated door 125, can make only circulation between the sub-insulated door of opening 125 of air, thereby can avoid the energy-accumulating medium of energy storage case 110 inside to consume too quickly.Utilize this horizontal sub-insulated door 125 parallel with the bottom, can easier formation circulating current.

Fig. 3 is the cutaway view along the line III-III ' intercepting among Fig. 1.With reference to Fig. 3, also can comprise a plurality of ventilation slot 118 and cooling fins 119 that vertically extend according to heat conducting wall 112 of the present utility model.Ventilation slot 118 can make air more easily move downward along heat conducting wall 112, thereby helps the room air circulation.Simultaneously, cooling fin 119 can increase the area that air contacts with heat conducting wall 112, thereby can accelerate radiating rate, thereby improves radiating efficiency.

According to an embodiment of the present utility model,, also circulating fan 130 can be set above insulated door in order further to improve radiating efficiency.But circulating fan 130 electrifications drive or artificial mechanism drives, and circulating fan can make air vertically move downward, thereby accelerate the speed that room air flows through heat conducting wall 112, improve radiating efficiency.

Energy storage type refrigerating plant of the present utility model also can comprise the refrigerating plant (not shown), and refrigerating plant can be arranged on energy storage case inside, and when electric power was provided, refrigerating plant can produce cold energy, thereby energy is stored in the energy-accumulating medium.

According to an embodiment of the present utility model, energy-accumulating medium can be a drinking water, when utilizing after refrigerating plant makes water freezing, can absorb a large amount of heat in the melting process of ice, and in addition, the personnel that the water of thawing also can be in the space supply drinking water.This has great importance being used for deliverance apparatus (for example mine rescue capsule) time when refrigerating plant.In addition, also can in drinking water, add various nutriments, thereby be configured to nutrient solution, so not only can solve the problem of drinking water, can also provide existence required energy for the personnel in the space.

Described with reference to the accompanying drawings according to embodiment of the present utility model, yet those skilled in the art should understand that, under the situation that does not break away from spirit and scope of the present utility model, can carry out various modifications and change to disclosed embodiment, scope of the present utility model is limited by claim and equivalent thereof.

Claims (9)

1. energy storage type refrigerating plant is characterized in that described energy storage type refrigerating plant comprises:

The energy storage case has a plurality of thermal wall and at least one heat conducting wall, and storage has energy-accumulating medium in the energy storage case;

Insulated door is arranged on the described heat conducting wall.

2. energy storage type refrigerating plant as claimed in claim 1 is characterized in that described insulated door is made up of a plurality of sub-insulated doors, and described a plurality of sub-insulated doors can independent opening and closing.

3. energy storage type refrigerating plant as claimed in claim 2 is characterized in that described sub-insulated door is along the direction setting parallel with the bottom of energy storage case.

4. energy storage type refrigerating plant as claimed in claim 1 is characterized in that described heat conducting wall comprises a plurality of ventilation slot and cooling fins that vertically extend.

5. energy storage type refrigerating plant as claimed in claim 1 is characterized in that the bottom of described heat conducting wall is provided with hot well.

6. energy storage type refrigerating plant as claimed in claim 1 is characterized in that described energy-accumulating medium is a drinking water.

7. energy storage type refrigerating plant as claimed in claim 1 is characterized in that described energy-accumulating medium is a nutrient solution.

8. as claim 2 or 4 described energy storage type refrigerating plants, it is characterized in that described insulated door top is provided with circulating fan.

9. energy storage type refrigerating plant as claimed in claim 1 is characterized in that being provided with refrigerating plant in the described energy storage case.

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