CN112696751A

CN112696751A - Air conditioning device based on 3D temperature-uniforming plate module

Info

Publication number: CN112696751A
Application number: CN202110093662.8A
Authority: CN
Inventors: 张明; 石俊; 江菊生; 胡明敏
Original assignee: Dongguan Wanwei Heat Transfer Technology Co ltd
Current assignee: Dongguan Wanwei Heat Transfer Technology Co ltd
Priority date: 2021-01-22
Filing date: 2021-01-22
Publication date: 2021-04-23

Abstract

The invention relates to an air conditioning device based on a 3D temperature-uniforming plate module, which comprises a shell, and a refrigerating module and a heating module which are arranged in the shell, wherein one side surface of the shell is provided with an air inlet, the other side surface corresponding to the air inlet is provided with an air outlet, a main fan is arranged at the air inlet, the 3D temperature-uniforming plate module is arranged between the refrigerating module and the heating module, the lower part of the 3D temperature-uniforming plate module is contacted with the heating module, and the upper part of the 3D temperature-uniforming plate module is contacted with the refrigerating. According to the invention, concentrated cold and heat are quickly and uniformly diffused by utilizing the high thermal conductivity of the 3D temperature-equalizing plate module, and the cold and heat are exchanged by the fan to realize quick cooling and heating, so that the air-conditioning device can be used for cooling in summer, can blow natural wind in spring and autumn, and can be used for heating in winter, therefore, the air-conditioning device is energy-saving, environment-friendly, safe, reliable, small in volume, and flexible, light and portable, and the whole air-conditioning device can be moved at will.

Description

Air conditioning device based on 3D temperature-uniforming plate module

Technical Field

The invention relates to the technical field of air conditioners, in particular to an air conditioner device based on a 3D temperature-uniforming plate module.

Background

Air conditioner fan of market low side carries out the heat transfer mode through water shower on the cascade and reaches the cooling purpose, and this mode cooling effect is poor, breeds the bacterium easily, and the electrical apparatus short circuit that ages easily, and the potential safety hazard is big. The product after the upgrading adds and is equipped with semiconductor refrigeration chip, through the pure water of semiconductor refrigeration pre-installation, the water shower after the refrigeration is on cascade or filter, and the cooling effect has the promotion after the heat transfer, but also breeds the bacterium easily equally, and the potential safety hazard is big, needs continuous water of interpolation again, and the refrigeration time is slow. Therefore, it is urgently needed to develop a cold and hot air conditioning device capable of rapidly heating or rapidly cooling.

Disclosure of Invention

Based on the technical scheme, the air conditioning device based on the 3D temperature-equalizing plate module is good in isothermal property, small in thermal resistance, small in cold loss and high in speed, and the temperature is cooled fastest and the body feeling is optimal under the same refrigerating power.

Air conditioning equipment based on 3D temperature-uniforming plate module, including the casing, install the refrigeration module and the module of heating in the casing, a side of casing is equipped with the air intake, and another side that corresponds with it is equipped with the air outlet, and the air intake goes out to be equipped with main fan, its characterized in that: the heating module is characterized in that a 3D temperature equalizing plate module is arranged between the refrigerating module and the heating module, the lower portion of the 3D temperature equalizing plate module is in contact with the heating module, and the upper portion of the 3D temperature equalizing plate module is in contact with the refrigerating module.

In a further technical scheme, the 3D temperature-uniforming plate module comprises an upper temperature-uniforming plate, a lower temperature-uniforming plate, a frame temperature-uniforming plate and a temperature-uniforming plate heat exchanger, wherein the upper temperature-uniforming plate is fixedly connected with the lower surface of the refrigeration module, the lower temperature-uniforming plate is fixedly connected with the upper surface of the heating module, the frame temperature-uniforming plate is bent to form an installation space, and the temperature-uniforming plate heat exchanger is arranged in the installation space and is in contact with the frame temperature-uniforming plate.

In a further technical scheme, the frame temperature-uniforming plate is bent for four times to form a frame body with a rectangular cross section, and the bent parts are all subjected to rounding treatment.

In a further technical scheme, the temperature-equalizing plate heat exchanger is provided with a plurality of ventilation grooves.

In another technical scheme, the 3D temperature-uniforming plate module comprises an upper temperature-uniforming plate, a lower temperature-uniforming plate, a temperature-uniforming plate heat exchanger and a plurality of vertical temperature-uniforming plates, wherein the upper temperature-uniforming plate is fixedly connected with the lower surface of the refrigeration module, the lower temperature-uniforming plate is fixedly connected with the upper surface of the heating module, the temperature-uniforming plate heat exchanger is provided with a plurality of clamping grooves, the vertical temperature-uniforming plates are correspondingly arranged in the clamping grooves one by one, and ventilation grooves are reserved between the adjacent vertical temperature-uniforming plates.

In a further technical scheme, the ventilating device further comprises a radiating fin, and the radiating fin is embedded in the ventilating groove.

In a further technical scheme, the cooling fin is bent for multiple times to form a snake-shaped cooling fin with a plurality of groove structures.

In another technical scheme, the 3D temperature-uniforming plate module comprises an upper temperature-uniforming plate, a lower temperature-uniforming plate, a frame temperature-uniforming plate and a heat sink, the upper temperature-uniforming plate is fixedly connected to the lower surface of the refrigeration module, the lower temperature-uniforming plate is fixedly connected to the upper surface of the heating module, and the frame temperature-uniforming plate is respectively in contact with the upper temperature-uniforming plate and the lower temperature-uniforming plate.

In a further technical scheme, the frame temperature-uniforming plate is bent for multiple times to form a plurality of supporting bodies, the upper parts of the plurality of supporting bodies are in contact with the upper temperature-uniforming plate, and the lower parts of the plurality of supporting bodies are in contact with the lower temperature-uniforming plate; the radiating fins are embedded in the supporting body.

In a further technical scheme, a radiator in contact with the refrigerating module is arranged at the upper part of the refrigerating module, and a radiating fan is arranged above the radiator; a water storage cavity is further arranged in the shell, and pure water for atomization is stored in the water storage cavity; an atomizing filter screen is arranged at the air outlet of the shell.

The invention provides a desktop air conditioner with dual purposes of cooling and heating, which can be used for cooling in summer and blowing natural wind fans in spring and autumn, can be used for heating in winter, is energy-saving, environment-friendly, safe, reliable and small in volume, and can be moved freely as a whole, thereby being flexible and light. The characteristics that the heat conduction speed is fast, the effect is even through utilizing 3D temperature-uniforming plate module mainly, through setting 3D temperature-uniforming plate module to have the structure that the surface area is big and whole light in weight to improve the effect that air conditioning equipment refrigerates or heated.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the internal structure of embodiment 1 of the present invention;

FIG. 3 is a schematic view of the internal structure of embodiment 2 of the present invention;

FIG. 4 is a schematic diagram of three configurations of the heat sink of the present invention;

FIG. 5 is a schematic view of the internal structure of embodiment 3 of the present invention;

FIG. 6 is a schematic view of the overall structure of embodiment 4 of the present invention;

FIG. 7 is a schematic structural view of a frame vapor chamber according to example 4;

FIG. 8 is a schematic view of the refrigeration operation of FIG. 1;

fig. 9 is a view of the refrigerating operation principle of the present invention fig. 2.

The heat dissipation device comprises a shell-100, an electric control area-110, a heat exchange area-120, an atomization area-130, a semiconductor heat dissipation area-140, an air outlet-101, an air inlet-102, an atomization filter screen-103, an air deflector-104, a radiator-105, a heat dissipation fan-106, a main fan-107, a refrigeration module-200, a heating module-300, a 3D temperature equalization plate module-400, an upper temperature equalization plate-401, a lower temperature equalization plate-402, a temperature equalization plate heat exchanger-403, a clamping groove-403 a, a vertical temperature equalization plate-404, a frame temperature equalization plate-410, an installation space-411, a support body-412, a heat dissipation plate-500, a folding heat dissipation plate-510, an aluminum extruded heat dissipation plate 520 and a harmonica type heat dissipation plate-530.

Detailed Description

To facilitate an understanding of the invention, the invention will now be described more fully with reference to the accompanying drawings. Preferred embodiments of the present invention are shown in the drawings. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "secured to" 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 also be present.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention.

Example 1:

the invention discloses an air conditioner capable of refrigerating and heating, which comprises a shell 100, a refrigerating module 200 and a heating module 300, wherein the refrigerating module 200 and the heating module 300 are installed in the shell 100, a 3D temperature equalizing plate module 400 is arranged between the refrigerating module 200 and the heating module 300, the lower part of the 3D temperature equalizing plate module 400 is in contact with the heating module 300, and the upper part of the 3D temperature equalizing plate module 400 is in contact with the refrigerating module 200, as shown in figures 1 and 2.

An air inlet 102 is arranged on one side surface of the shell 100, an air outlet 101 is arranged on the other side surface corresponding to the air inlet 102, a main fan 107 is arranged at the air inlet 102, and an atomizing filter screen 103 and an air deflector 104 are arranged at the air outlet 101. The interior of the housing 100 is divided into an electric control area 110, a heat exchange area 120, an atomization area 130 and a semiconductor heat dissipation area 140. The electronic control section 110 is used for mounting an electronic control module and is located at the lowermost portion of the housing 100. The heat exchange area 120 is located above the electric control area 110 and used for installing the 3D temperature equalization plate module 400, the 3D temperature equalization plate module 400 comprises an upper temperature equalization plate 401, a lower temperature equalization plate 402, a frame temperature equalization plate 410 and a temperature equalization plate heat exchanger 403, the upper temperature equalization plate 401 is fixedly connected with the lower surface of the refrigeration module 200, the lower temperature equalization plate 402 is fixedly connected with the upper surface of the heating module 300, the frame temperature equalization plate 410 forms an installation space 411 after being bent, and the temperature equalization plate heat exchanger 403 is arranged in the installation space 411 and is in contact with the frame temperature equalization plate 410. The frame vapor chamber 410 is bent and does not contact end to end. Specifically, the frame temperature equalization plate 410 is bent four times to form a frame body with a rectangular cross section, and the bent portions are all rounded.

The atomization region 130 is used for storing purified water for atomization, and is located at both sides of the heat exchange region 120. The semiconductor heat dissipation area 140 is located above the heat exchange area 120 and the atomization area 130, and is provided with a heat sink 105, and a heat dissipation fan 106 is further disposed above the heat sink 105.

In this embodiment, the refrigeration module 200 is made of a TEC semiconductor chip, a refrigeration surface of the TEC semiconductor chip is in contact with the upper temperature-uniforming plate 401, and a heating surface of the TEC semiconductor chip is in contact with the heat sink 105.

When the air conditioner of the embodiment is in refrigeration operation, the principle is as shown in fig. 8 and fig. 9, the refrigeration module 200 works and the heating module 300 does not work, the refrigeration module 200 conducts low temperature to the upper temperature equalizing plate 401, the frame temperature equalizing plate 410, the temperature equalizing plate heat exchanger 403 and the lower temperature equalizing plate 402, and diffuses to the whole 3D temperature equalizing plate module 400, natural wind is sucked into the shell 100 under the action of the main fan 107, and performs heat exchange through the 3D temperature equalizing plate module 400, and after penetrating through the ventilation groove and performing sufficient heat exchange with the temperature equalizing plate heat exchanger 403, the natural wind leaves the air conditioner from the air outlet 101, so that the cold energy is radiated to the air flowing circularly through the module.

Specifically, in the heat conduction process inside the air conditioning device, the refrigeration surface of the TEC semiconductor chip radiates the refrigeration to the upper temperature equalizing plate 401, the upper temperature equalizing plate 401 conducts the temperature uniformly in the transverse direction, and then the refrigeration radiates to the frame temperature equalizing plate 410 and the temperature equalizing plate heat exchanger 403, and when natural wind enters the inside of the casing 100 along with the main fan 107, the natural wind is fully contacted with the temperature equalizing plate heat exchanger 403 through the ventilation groove to become cold wind, and then the cold wind is conveyed to the environment through the air outlet 101.

The invention fully utilizes the characteristics of good isothermal property, small thermal resistance, small cold loss and high speed of the 3D module, and compared with the traditional air conditioning device, the invention has the advantages of fastest temperature reduction and optimal body feeling under the same refrigeration power.

In this embodiment, the inside vacuum of 3D temperature-uniforming plate module 400 is filled with the environmental protection organic liquid, the temperature application range: the temperature is 40 ℃ below zero to 180 ℃, so that the 3D temperature equalizing plate module 400 can realize rapid cold and heat transfer and temperature equalization during refrigeration and heating.

During heating, the refrigeration module 200 does not work, the heating module works and transfers heat to the lower temperature equalizing plate 402, the lower temperature equalizing plate 402 quickly and uniformly diffuses the heat in the transverse direction and transfers the heat to the frame temperature equalizing plate 410 and the temperature equalizing plate heat exchanger 403, meanwhile, the main fan 107 sucks natural wind into the shell 100, performs heat exchange with the temperature equalizing plate heat exchanger 403 through the ventilation groove to form hot wind, and returns to the environment along with the air outlet 101. In the heat exchange process, the invention makes full use of the characteristic of excellent isothermal performance of the temperature equalizing plate to ensure that the outlet air temperature is always kept constant. Still be equipped with the atomizer in addition, atomize the pure water in the atomizing area 130, guarantee the humidity of environment, keep best body to feel.

Example 2:

as shown in fig. 3, in this embodiment, a 3D temperature-uniforming plate module 400 with another structure is adopted, where the 3D temperature-uniforming plate module 400 includes an upper temperature-uniforming plate 401, a lower temperature-uniforming plate 402, a temperature-uniforming plate heat exchanger 403, and a plurality of vertical temperature-uniforming plates 404, the upper temperature-uniforming plate 401 is fixedly connected to the lower surface of the refrigeration module 200, the lower temperature-uniforming plate 402 is fixedly connected to the upper surface of the heating module 300, the temperature-uniforming plate heat exchanger 403 is provided with a plurality of slots 403a, the vertical temperature-uniforming plates 404 are installed in the slots 403a in a one-to-one correspondence manner, and a ventilation slot is left between the adjacent vertical temperature.

The speed is faster when heat transfer is performed, for example, when refrigeration is performed, the refrigeration module 200 firstly radiates cold to the upper temperature-uniforming plate 401, the cold is uniformly diffused along the transverse direction by using the upper temperature-uniforming plate 401, the vertical temperature-uniforming plate 404 embedded in the clamping groove 403a simultaneously performs heat exchange with the upper temperature-uniforming plate 401, and the cold is uniformly diffused along the vertical direction. The natural wind passes through the gap between the vertical temperature equalizing plates 404, exchanges heat with the gap, turns into cold wind, and is discharged to the environment from the air outlet 101. The advantages of high cooling speed and good isothermal property of the uniform temperature plate are fully utilized, rapid refrigeration and uniform refrigeration are realized, and the optimal feeling is provided for users.

Example 3:

as shown in fig. 5, in example 2, heat dissipation fins 500 are further embedded between the vertical temperature uniforming plates 404. As shown in fig. 4, the heat sink 500 may be provided with three forms including a folded heat sink 510, an extruded aluminum heat sink 520, and a tubular harmonica heat sink 530, and as shown in a of fig. 4, the folded heat sink 510 is bent several times to form a serpentine heat sink 500 having a plurality of groove structures. As shown in fig. 4 b, the aluminum extruded fin 520 includes a body having a large surface area with a plurality of partition portions arranged in parallel. As shown in the drawing c in fig. 4, the harmonica tube cooling fin 530 includes a body, a hollow cavity is formed inside the body, and a plurality of partition plates are arranged in the cavity to partition the cavity into a plurality of independent channels.

In the present embodiment, the heat sink 500 employs a folded heat sink 510. The heat sink 500 can increase the heat exchange area between the natural wind and the 3D temperature equalization plate module 400 during the heat exchange process, thereby improving the heat exchange efficiency.

Example 4:

as shown in fig. 6, the 3D temperature-uniforming plate module 400 of this embodiment adopts a lighter structure, and specifically, the 3D temperature-uniforming plate module 400 includes an upper temperature-uniforming plate 401, a lower temperature-uniforming plate 402, a frame temperature-uniforming plate 410 and heat dissipation fins 500, where the upper temperature-uniforming plate 401 is fixedly connected to the lower surface of the refrigeration module 200, the lower temperature-uniforming plate 402 is fixedly connected to the upper surface of the heating module 300, and the frame temperature-uniforming plate 410 is in contact with the upper temperature-uniforming plate 401 and the lower temperature-uniforming plate 402, respectively.

As shown in fig. 7, the frame vapor chamber 410 is bent for multiple times to form a plurality of support bodies 412, wherein the upper portions of the plurality of support bodies 412 are in contact with the upper vapor chamber 401, and the lower portions are in contact with the lower vapor chamber 402; the heat sink 500 is embedded in the support 412.

The frame vapor chamber 410 of this embodiment is an integral vapor chamber, and is bent several times to form a serpentine structure with upper and lower portions contacting the upper vapor chamber 401 and the lower vapor chamber 402, and has a plurality of peak-shaped support bodies 412, and heat dissipation fins 500 for increasing the heat exchange area are provided between the support bodies 412.

When heat exchange is performed, taking the working principle of refrigeration as an example, the upper temperature-uniforming plate 401 radiates the cold energy to the upper part of the supporting body 412, the supporting body 412 evenly transmits the cold energy to the whole frame temperature-uniforming plate 410, and the cold energy of the frame temperature-uniforming plate 410 is radiated by all the radiating fins 500 at the same time to rapidly cool down, so that the light-weight design of the whole 3D temperature-uniforming plate module 400 is realized, and the cooling speed and the cooling effect are not influenced.

The technical features of the above embodiments can be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the above embodiments are not described, but should be considered as the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above examples only express preferred embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims

1. Air conditioning equipment based on 3D temperature-uniforming plate module, including the casing, install the refrigeration module and the module of heating in the casing, a side of casing is equipped with the air intake, and another side that corresponds with it is equipped with the air outlet, and the air intake goes out to be equipped with main fan, its characterized in that: the heating module is characterized in that a 3D temperature equalizing plate module is arranged between the refrigerating module and the heating module, the lower portion of the 3D temperature equalizing plate module is in contact with the heating module, and the upper portion of the 3D temperature equalizing plate module is in contact with the refrigerating module.

2. The air conditioning device based on the 3D temperature equalization plate module as claimed in claim 1, wherein: the 3D temperature-uniforming plate module comprises an upper temperature-uniforming plate, a lower temperature-uniforming plate, a frame temperature-uniforming plate and a temperature-uniforming plate heat exchanger, wherein the upper temperature-uniforming plate is fixedly connected with the lower surface of the refrigeration module, the lower temperature-uniforming plate is fixedly connected with the upper surface of the heating module, the frame temperature-uniforming plate forms an installation space after being bent, and the temperature-uniforming plate heat exchanger is arranged in the installation space and is in contact with the frame temperature-uniforming plate.

3. The air conditioning device based on the 3D temperature equalization plate module set as claimed in claim 2, wherein: the frame temperature equalizing plate is bent for four times to form a frame body with a rectangular cross section, and the bent parts are rounded.

4. The air conditioning device based on the 3D temperature equalization plate module set according to any one of claim 3, wherein: the temperature-equalizing plate heat exchanger is provided with a plurality of ventilation grooves.

5. The air conditioning device based on the 3D temperature equalization plate module as claimed in claim 1, wherein: the 3D temperature-uniforming plate module comprises a temperature-uniforming plate, a lower temperature-uniforming plate, a temperature-uniforming plate heat exchanger and a plurality of vertical temperature-uniforming plates, wherein the upper temperature-uniforming plate is fixedly connected with the lower surface of the refrigeration module, the lower temperature-uniforming plate is fixedly connected with the upper surface of the heating module, the temperature-uniforming plate heat exchanger is provided with a plurality of clamping grooves, and the vertical temperature-uniforming plates are installed in the clamping grooves in a one-to-one correspondence manner and are adjacent to each other, and ventilation grooves are reserved between the vertical temperature-uniforming.

6. The air conditioning device based on the 3D temperature equalization plate module set as claimed in claim 5, wherein: the ventilating structure also comprises a radiating fin which is embedded in the ventilating groove.

7. The air conditioning device based on the 3D temperature equalization plate module as claimed in claim 6, wherein: the cooling fin is bent for multiple times to form the serpentine cooling fin with the multiple groove structures.

8. The air conditioning device based on the 3D temperature equalization plate module as claimed in claim 1, wherein: the 3D temperature-uniforming plate module comprises an upper temperature-uniforming plate, a lower temperature-uniforming plate, a frame temperature-uniforming plate and radiating fins, wherein the upper temperature-uniforming plate is fixedly connected with the lower surface of the refrigeration module, the lower temperature-uniforming plate is fixedly connected with the upper surface of the heating module, and the frame temperature-uniforming plate is respectively contacted with the upper temperature-uniforming plate and the lower temperature-uniforming plate.

9. The air conditioning device based on the 3D temperature equalization plate module set as claimed in claim 8, wherein: the frame temperature-equalizing plate is bent for multiple times to form a plurality of supporting bodies, the upper parts of the supporting bodies are in contact with the upper temperature-equalizing plate, and the lower parts of the supporting bodies are in contact with the lower temperature-equalizing plate; the radiating fins are embedded in the supporting body.

10. The 3D vapor panel module-based air conditioning device according to any one of claims 1-9, wherein: the upper part of the refrigeration module is provided with a radiator which is contacted with the refrigeration module, and a radiating fan is arranged above the radiator; a water storage cavity is further arranged in the shell, and pure water for atomization is stored in the water storage cavity; an atomizing filter screen is arranged at the air outlet of the shell.