CN220601673U - Temperature regulation and control mechanism based on underground energy taking - Google Patents

Abstract

The utility model relates to a temperature regulation and control mechanism based on underground energy taking, which comprises a temperature guide piece, a main gas pipeline and an underground heat preservation layer, wherein the underground heat preservation layer is positioned at 1.6-3.2 meters below the ground surface, the temperature guide piece extends into the main gas pipeline from the underground heat preservation layer, the number of the temperature guide pieces is more than ten, and the temperature guide piece comprises a first temperature guide pipe, a second temperature guide pipe, a third temperature guide pipe, a first heat insulation layer, a second heat insulation layer, a third heat insulation layer and a fourth heat insulation layer. This temperature regulation and control mechanism based on underground energy taking is based on the characteristics that soil transfer heat function is poor and heat preservation function is good, buries the heat preservation spare in the underground heat preservation for heat energy or cold energy conduction of underground heat preservation is to the house, and the out-of-season heat energy or the cold energy of make full use of underground heat preservation storage have reduced thermal pollution and energy consumption, have reduced the environmental burden.

Description

Temperature regulation and control mechanism based on underground energy taking

Technical Field

The utility model relates to the technical field of house room temperature regulation, in particular to a temperature regulation mechanism based on underground energy taking.

Background

With the improvement of the requirements of people on the quality of life, the air conditioner for regulating the room temperature of the house has very high popularization rate, and the air conditioner refrigerates the inside of the house when the ambient temperature is high.

The air conditioner has the following disadvantages in the use process, such as:

(1) A large amount of heat is discharged to the surrounding environment in the operation process, so that the environment is polluted by heat, and the regional natural environment heat balance is affected;

(2) The power assembly has high power consumption, high power consumption and high environmental burden.

Therefore, a temperature regulation mechanism and a temperature regulation method based on underground energy taking are provided to solve the above-mentioned problems.

Disclosure of Invention

Aiming at the defects of the prior art, the utility model provides a temperature regulation mechanism based on underground energy taking, which uses the natural heat preservation function of the underground to transfer the underground cold energy or heat energy into a house, reduces the heat pollution and the energy consumption in the use process, solves the problems that an air conditioner can discharge a large amount of heat into the surrounding environment in the use process, causes the heat pollution to the environment, affects the regional natural environment heat balance, and has large power consumption, large electric energy resource consumption and increased environmental burden required by the operation of a power component of the air conditioner.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the temperature regulation and control mechanism based on underground energy taking comprises a temperature guide piece, a main gas pipeline and an underground heat preservation layer, wherein the underground heat preservation layer is positioned at the position of 1.6-3.2 meters below the ground surface, and the temperature guide piece extends into the main gas pipeline from the underground heat preservation layer;

the number of the temperature guide pieces is more than ten, and the temperature guide pieces comprise a first temperature guide pipe, a second temperature guide pipe, a third temperature guide pipe, a first heat insulation layer, a second heat insulation layer, a third heat insulation layer and a fourth heat insulation layer.

Preferably, the innermost part of the heat conducting piece is a first heat insulation layer, a first heat conducting pipe is arranged outside the first heat insulation layer, a second heat insulation layer is arranged outside the first heat conducting pipe, a second heat conducting pipe is arranged outside the second heat insulation layer, a third heat insulation layer is arranged outside the second heat conducting pipe, a third heat conducting pipe is arranged outside the third heat insulation layer, and a fourth heat insulation layer is arranged outside the third heat conducting pipe.

Preferably, the gas transmission main pipeline is provided with gas transmission branch pipelines, the gas transmission branch pipelines extend into room areas needing to be subjected to temperature regulation, and the number of the gas transmission branch pipelines corresponds to the number of the room areas needing to be subjected to temperature regulation.

Preferably, a first filtering mechanism and a first air blowing mechanism are arranged in the main air transmission pipeline.

Preferably, a second filtering mechanism and a second air blowing mechanism are arranged in the air conveying branch pipeline.

Compared with the prior art, the technical scheme of the application has the following beneficial effects:

this temperature regulation and control mechanism based on underground energy taking is based on the characteristics that soil transfer heat function is poor and heat preservation function is good, buries the heat preservation spare in the underground heat preservation for heat energy or cold energy conduction of underground heat preservation is to the house, and the out-of-season heat energy or the cold energy of make full use of underground heat preservation storage have reduced thermal pollution and energy consumption, have reduced the environmental burden.

Drawings

FIG. 1 is a schematic view of a part of the construction of the present utility model for use in one embodiment;

FIG. 2 is a schematic view of a part of the construction of the present utility model for use in one embodiment;

FIG. 3 is a schematic diagram of a layered structure of a cross section of a temperature guide member according to the present utility model;

FIG. 4 is a schematic view of a part of the structure of the present utility model when used in the second embodiment;

FIG. 5 is a schematic view of a partial structure of the present utility model when used in the second embodiment;

FIG. 6 is a schematic view of a part of the present utility model when used in the third embodiment;

FIG. 7 is a schematic view of a part of the present utility model for use in a fourth embodiment;

fig. 8 is a schematic view of a partial structure of the present utility model when used in the third embodiment and the fourth embodiment.

In the figure: 1. a temperature guide member; 101. a first temperature guide tube; 102. a second temperature guide tube; 103. a third temperature guide tube; 104. a first heat insulating layer; 105. a second heat insulating layer; 106. a third heat insulating layer; 107. a fourth heat insulating layer; 2. a main gas transmission pipeline; 3. a gas transmission branch pipeline; 4. a first filtering mechanism; 5. a first air blowing mechanism; 6 a second filtering mechanism; 7, a second air blowing mechanism; 8. and an underground heat preservation layer.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-8, the temperature regulation mechanism based on underground energy taking provided by the utility model comprises a temperature guide member 1, a main gas pipeline 2 and an underground heat preservation layer 8, wherein the underground heat preservation layer 8 is positioned at the position 1.6-3.2 m below the ground surface, and the temperature guide member 1 extends from the inside of the underground heat preservation layer 8 to the inside of the main gas pipeline 2.

The number of the heat conducting pieces 1 is more than ten, and the heat conducting pieces 1 comprise a first heat conducting pipe 101, a second heat conducting pipe 102, a third heat conducting pipe 103, a first heat insulating layer 104, a second heat insulating layer 105, a third heat insulating layer 106 and a fourth heat insulating layer 107.

Further, based on the characteristics of poor heat transfer function and good heat preservation function of soil, the above-ground heat wave can not be transferred to the underground heat preservation layer 8 of soil quickly, can only be transferred downwards slowly, so that the underground heat preservation layer 8 forms a large contrast with the above-ground temperature, namely, when the above-ground heat is generated, the underground heat preservation layer 8 is cooled, when the above-ground heat is generated, the underground heat preservation layer 8 is internally warmed, the lower end of the heat conducting piece 1 is buried in the underground heat preservation layer 8, and the first heat conducting pipe 101, the second heat conducting pipe 102 and the third heat conducting pipe 103 are all composed of the existing heat conducting materials, so that the heat energy or cold energy stored in the underground heat preservation layer 8 is transferred to the corresponding area.

Further, the first heat insulation layer 104, the second heat insulation layer 105, the third heat insulation layer 106, the fourth heat insulation layer 107, the main gas pipeline 2 and the branch gas pipeline 3 are made of existing heat insulation materials, the first heat insulation layer 104 and the second heat insulation layer 105 are respectively located inside and outside the first heat conduction pipe 101, the first heat conduction pipe 101 is wrapped, loss of cold energy and heat energy on the first heat conduction pipe 101 is prevented, the effect of the first heat conduction pipe 101 on transferring the cold energy and the heat energy is guaranteed, the second heat insulation layer 105 and the third heat insulation layer 106 are respectively located inside and outside the second heat conduction pipe 102, the second heat conduction pipe 102 is wrapped, loss of cold energy and heat energy on the second heat conduction pipe 102 is prevented, the third heat insulation layer 106 and the fourth heat insulation layer 107 are respectively located inside and outside the third heat conduction pipe 103, loss of cold energy and heat energy on the third heat conduction pipe 103 is prevented.

Further, the first filtering mechanism 4 is located at the air inlet of the main air conveying pipeline 2, intercepts and filters impurities in air entering the main air conveying pipeline 2, improves the quality of air entering the main air conveying pipeline 2, intercepts and filters the indoor quality, and further improves the air quality.

Further, the first blower mechanism 5 pumps air into the main conduit 2, and the second blower mechanism 7 pumps air in the main conduit 2 from the branch conduit 3 into the corresponding space region.

Embodiment one:

as shown in fig. 1 and 2, the heat conducting member 1 transfers and distributes the cold energy or heat energy in the underground heat insulating layer 8 into the main gas pipeline 2, the heat conducting member 1 positioned in the main gas pipeline 2 is not provided with the first heat insulating layer 104, the second heat insulating layer 105, the third heat insulating layer 106 and the fourth heat insulating layer 107, so as to ensure the heat energy and cold energy transfer efficiency of the first heat conducting pipe 101, the second heat conducting pipe 102 and the third heat conducting pipe 103 in the main gas pipeline 2 and the air, the first heat insulating layer 104, the second heat insulating layer 105, the third heat insulating layer 106 and the fourth heat insulating layer 107 are arranged on the heat conducting member 1 positioned outside the main gas pipeline 2, so that the heat energy or cold energy transfer loss of the first heat conducting pipe 101, the second heat conducting pipe 102 and the third heat conducting pipe 103 is reduced, the first air blast mechanism 5 brings the cold energy or heat energy into the branch gas pipeline 3 through air flow, and the second air blast mechanism 7 brings the cold energy or heat energy into corresponding space areas through air flow.

Embodiment two:

as shown in fig. 4 and 5, the heat conducting member 1 penetrates through the main gas pipeline 2 and the branch gas pipeline 3 and extends into the corresponding space region, the heat conducting member 1 transfers and distributes the cold energy or heat energy in the underground heat insulation layer 8 into the space region, the heat conducting member 1 extending into the space region is not provided with the first heat insulation layer 104, the second heat insulation layer 105, the third heat insulation layer 106 and the fourth heat insulation layer 107, so that the heat energy and the cold energy transfer efficiency of the first heat conducting pipe 101, the second heat conducting pipe 102 and the third heat conducting pipe 103 in the space region are ensured, the heat energy and the cold energy transfer efficiency are outside the space region, namely, the heat conducting member 1 positioned in the main gas pipeline 2 and the branch gas pipeline 3 is provided with the first heat insulation layer 104, the second heat insulation layer 105, the third heat insulation layer 106 and the fourth heat insulation layer 107, so that the heat energy or heat energy transfer loss of the first heat conducting pipe 101, the second heat conducting pipe 102 and the third heat conducting pipe 103 in the main gas pipeline 2 and the branch gas pipeline 3 is reduced, and the heat energy transfer efficiency of the heat energy or heat energy is accelerated in the space region is accelerated by the fan or the heat energy transfer mechanism arranged in the heat conducting member 1, and the heat energy transfer mechanism is arranged in the space region, and the heat conducting member 1 is provided in the air conducting member 1.

Embodiment III:

as shown in fig. 6 and 8, unlike the first embodiment, the air delivery branch pipe 3 is not disposed on the main air delivery pipe 2, the heat conducting member 1 is disposed at the position of the original air delivery branch pipe 3, the heat conducting member 1 penetrates the outside of the main air delivery pipe 2 from the inside of the main air delivery pipe 2, and the heat conducting member 1 at the position of the original air delivery branch pipe 3 is not disposed with the first heat insulating layer 104, the second heat insulating layer 105, the third heat insulating layer 106 and the fourth heat insulating layer 107, so as to ensure the heat energy and cold energy transfer efficiency between the first heat conducting pipe 101, the second heat conducting pipe 102 and the third heat conducting pipe 103 and the inside and surrounding environment of the main air delivery pipe 2, and transfer the second air blowing mechanism 7 to the position near the air outlet of the main air delivery pipe 2, and the first air blowing mechanism 5 is matched with the second air blowing mechanism 7 to bring the cold energy on the heat conducting member 1 at the inlet of the main air delivery pipe 2 to the heat conducting member 1 at the position of the original air delivery branch pipe 3 through air flow, and since the heat conducting member 1 at the position of the original air delivery branch pipe 3 extends to the outside of the main air delivery pipe 2, and the heat conducting member 1 at the position of the original branch pipe 3 forms a plurality of net-shaped heat conducting members 1 to counteract the high temperature with the outside light energy.

Embodiment four:

as shown in fig. 7 and 8, unlike the second embodiment, the main gas pipe 2 is not provided with the branch gas pipe 3, the heat conducting member 1 extends in the main gas pipe 2 and penetrates from the inside of the main gas pipe 2 to the outside of the main gas pipe 2, the heat conducting member 1 located outside the main gas pipe 2 is not provided with the first heat insulating layer 104, the second heat insulating layer 105, the third heat insulating layer 106 and the fourth heat insulating layer 107, so as to ensure the heat energy and cold energy transfer efficiency between the first heat conducting pipe 101, the second heat conducting pipe 102 and the third heat conducting pipe 103 and the surrounding environment, the heat conducting member 1 located inside the main gas pipe 2 is provided with the first heat insulating layer 104, the second heat insulating layer 105, the third heat insulating layer 106 and the fourth heat insulating layer 107, so as to reduce the heat transfer loss of the heat energy or the cold energy by the first heat conducting pipe 101, the second heat conducting pipe 102 and the third heat conducting pipe 103, the cold energy transfer and store the cold energy in the underground layer 8, and the heat energy and cold energy transfer efficiency between the heat conducting member 1 and the heat insulating layer 1 are counteracted by the heat energy and the cold energy on the heat conducting member 1 formed by a plurality of net-shaped heat conducting members.

Further, the first and second embodiments are used for temperature regulation of the inside of the wall surface of the house, and the third and fourth embodiments are used for local temperature regulation of the outside of the wall surface of the house.

Further, the first and third embodiments use the first and second blower mechanisms 5 and 7 to assist the flow of air in the duct, and can be used for buildings with higher floors, and the second and fourth embodiments are used for buildings with lower floors.

In summary, this temperature regulation and control mechanism based on underground energy taking utilizes the nature heat preservation effect in underground, with cold energy or heat energy conduction to the house in the underground, has reduced thermal pollution and energy consumption in the use, has solved the air conditioner and can discharge a large amount of heat to the surrounding environment in the use, causes thermal pollution to the environment, influences regional natural environment heat balance, and the power component operation of air conditioner required power consumption is big, and the electric energy resource consumption is big, can increase the burden problem of environment.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (5)

1. Temperature regulation and control mechanism based on secret energy-taking, including heat conduction spare (1), gas transmission trunk line (2) and secret heat preservation (8), its characterized in that: the underground heat preservation layer (8) is positioned at the position of 1.6-3.2 meters below the ground surface, and the heat conduction piece (1) extends from the inside of the underground heat preservation layer (8) to the inside of the main gas transmission pipeline (2);

the number of the heat conducting pieces (1) is greater than ten, and the heat conducting pieces (1) comprise a first heat conducting pipe (101), a second heat conducting pipe (102), a third heat conducting pipe (103), a first heat insulating layer (104), a second heat insulating layer (105), a third heat insulating layer (106) and a fourth heat insulating layer (107).

2. The underground energy taking-based temperature regulation mechanism according to claim 1, wherein: the heat conducting device is characterized in that the innermost part of the heat conducting piece (1) is a first heat insulation layer (104), a first heat conducting pipe (101) is arranged outside the first heat insulation layer (104), a second heat insulation layer (105) is arranged outside the first heat conducting pipe (101), a second heat conducting pipe (102) is arranged outside the second heat insulation layer (105), a third heat insulation layer (106) is arranged outside the second heat conducting pipe (102), a third heat conducting pipe (103) is arranged outside the third heat insulation layer (106), and a fourth heat insulation layer (107) is arranged outside the third heat conducting pipe (103).

3. The underground energy taking-based temperature regulation mechanism according to claim 1, wherein: the air conveying main pipeline (2) is provided with air conveying branch pipelines (3), the air conveying branch pipelines (3) extend into room areas needing temperature regulation and control, and the number of the air conveying branch pipelines (3) corresponds to the number of the room areas needing temperature regulation and control.

4. The underground energy taking-based temperature regulation mechanism according to claim 1, wherein: the inside of the main gas transmission pipeline (2) is provided with a first filtering mechanism (4) and a first air blowing mechanism (5).

5. A temperature regulation mechanism based on underground energy extraction according to claim 3, wherein: the inside of the gas transmission branch pipeline (3) is provided with a second filtering mechanism (6) and a second air blowing mechanism (7).