CN111678188B - Graphite alkene navigation cold and hot part and graphite alkene changes in temperature and draws - Google Patents

Abstract

The invention relates to a graphene navigation heat-conducting component and a graphene cold-warm picture. The graphene navigation cold and hot part comprises a ceramic plate and a resin plate which are sealed together in a joint mode, wherein one side of the ceramic plate is coated with a first mixture, one side of the resin plate is coated with a second mixture, and wires are arranged on the ceramic plate and the resin plate respectively, wherein the two sides coated with the first mixture and the second mixture face inwards, and then the wires are arranged on the two sides facing inwards. The graphene navigation cold and heat component provided by the invention achieves the refrigeration and heating effects by adopting an autonomous formula and technology, can heat and refrigerate indoors by adopting electric energy under the condition of not using Freon and an indoor unit of a compressor, can reduce the temperature by 7 ℃ in 20 minutes and improve the temperature by 10 ℃ in 35 minutes for a standard building room of 15 square meters by testing 1000w at present. And can generate 8-14um far infrared rays at the same time of heating and refrigerating, and is beneficial to health.

Description

Graphite alkene navigation cold and hot part and graphite alkene changes in temperature and draws

Technical Field

The invention relates to the field of graphene, in particular to a graphene navigation heat and cold component and a graphene cold and warm picture.

Background

In the prior art, air conditioning refrigeration and heating are mostly adopted in the overall indoor heating and warming. Or the electric heater and other heating modes are adopted in winter, and the electric fan or the water adding and fan and other modes are adopted in summer. Although the air conditioner heating and refrigerating are wide in users, the heating effect in the north is not obvious. The ideal heating temperature cannot be achieved, and although the temperature is guaranteed in the south, the temperature gradient effect is not ideal, and particularly, the situations of dryness, discomfort and the like are easily caused. When the refrigerator is used for refrigeration in summer, forced air blowing is adopted, so that air conditioning diseases are easily caused to people or the people feel uncomfortable when forced air blowing is carried out on the human body, and particularly, the problems of arthralgia and the like are caused. The noise of the outdoor unit affects the sleeping and has high cost, high maintenance cost and the like. The fan can only blow air but cannot solve the problems of heating and refrigeration in winter. The electric heater used in winter is dry and can not solve the problem of refrigeration in summer.

The existing refrigerating air-conditioning and heating equipment has been used for many years. In general, from the aspect of refrigeration, freon is used as a medium, is compressed by a compressor to be liquefied, and is then transmitted to the indoor to be gasified to absorb heat, and then is circulated to the outdoor unit to be released. Heating equipment mostly adopts heating wire carbon crystals or carbon fiber heating wires and adopts a blowing or convection radiation mode.

Disclosure of Invention

In view of the above problems, the present invention is proposed to provide a graphene navigation cooling and heating component and a graphene cooling and heating picture which overcome the above problems or at least partially solve the above problems.

According to a first aspect, a graphene navigation cooling and heating component is provided, which comprises a ceramic plate and a resin plate which are sealed together, wherein one side of the ceramic plate is coated with a first mixture, one side of the resin plate is coated with a second mixture, and wires are respectively arranged on the ceramic plate and the resin plate, wherein two sides coated with the first mixture and the second mixture face inwards, and then the wires are arranged on the two sides facing inwards.

Wherein the first mixture comprises the following components in parts by mass:

the mixture II comprises the following components in parts by mass:

according to one possible design, the mixture consists of the following components: 6-7 parts of water and 1-1.2 parts of ethanol.

According to one possible design, the first diluent consists of: 2-3 parts of dimethylbenzene, 1-2 parts of methylbenzene and 4-6 parts of butyl acetate.

According to the second aspect, a graphene cold and warm painting is provided, which comprises a frame, a shell composed of a front panel and a rear panel, wherein a picture is arranged on the outer surface of the front panel, a single-layer graphene and titanium material mixed coating is arranged on the inner surface of the front panel, the single-layer graphene and titanium material mixed coating is next to a cold and hot superconducting transmission layer and a graphene navigation heat and cold component, a heat dissipation and cold dissipation device and a gas circulation device are arranged on the inner side of the graphene navigation heat and cold component, an exhaust duct is arranged on the frame, the front panel and the rear panel are buckled together through buckling parts all around to form a combined plate, and air holes are formed in the buckling parts.

According to one possible design, the housing is also provided with a direct current power supply, a temperature control device and a power socket.

According to one possible design, a silent fan is provided in the gas flow device.

According to one possible design, the working voltage of the direct current power supply is 12V, and the power is supplied to the graphene navigation cold and hot parts.

According to one possible design, the heat and cold dissipating device is in the form of a closed conduit comprising the following components:

according to one possible design, the second diluent consists of:

3-5 parts of dimethylbenzene, 1-3 parts of methylbenzene and 4-8 parts of butyl acetate.

According to one possible design, the frame is provided with air outlets.

The graphene navigation cold and heat component provided by the invention achieves the refrigeration and heating effects by adopting an autonomous formula and technology, can heat and refrigerate indoors by adopting electric energy under the condition of not using Freon and an indoor unit of a compressor, can reduce the temperature by 7 ℃ in 20 minutes and improve the temperature by 10 ℃ in 35 minutes for a standard building room of 15 square meters by testing 1000w at present. And can generate 8-14um far infrared rays at the same time of heating and refrigerating, and is beneficial to health.

The foregoing description is only an overview of the technical solutions of the present invention, and the embodiments of the present invention are described below in order to make the technical means of the present invention more clearly understood and to make the above and other objects, features, and advantages of the present invention more clearly understandable.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a graphene navigation heat and cold component;

fig. 2 is a schematic structural diagram of a graphene cold-warm painting;

description of reference numerals:

1-frame, 2-air outlet, 3-front panel, 4-cold and hot superconducting transfer layer, 5-graphene navigation heat-cooling component, 6-heat dissipation and cold dissipation device, 7-gas circulation device, 8-silent fan, 9-direct current power supply, 10-temperature control device, 11-power supply socket, 12-rear panel, 13-exhaust duct, 51-ceramic plate, 52-resin plate.

Detailed Description

Exemplary embodiments of the present disclosure will be described in more detail below with reference to the accompanying drawings. While exemplary embodiments of the present disclosure are shown in the drawings, it should be understood that the present disclosure may be embodied in various forms and should not be limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the disclosure to those skilled in the art.

The terms "comprises" and "comprising," and any variations thereof, in the present description and claims and drawings are intended to cover a non-exclusive inclusion, such as a list of steps or elements.

The technical solution of the present invention is further described in detail with reference to the accompanying drawings and embodiments.

Example 1

Referring to fig. 1, an embodiment of the present invention provides a graphene navigation cooling and heating component, which includes a ceramic plate 51 and a resin plate 52 that are bonded and sealed together, wherein the ceramic plate 51 is coated with a first mixture on one side, the resin plate 52 is coated with a second mixture on one side, and wires are respectively disposed on the ceramic plate and the resin plate, wherein two sides coated with the first mixture and the second mixture face inward, and then wires are disposed on the two inward sides.

The first mixture consists of the following components in parts by mass:

wherein the mixture consists of the following components:

6-7 parts of water and 1-1.2 parts of ethanol.

The first diluent consists of the following components:

2-3 parts of dimethylbenzene, 1-2 parts of methylbenzene and 4-6 parts of butyl acetate.

The second mixture consists of the following components in parts by mass:

the electronic sequence of the graphene material can be changed after the graphene material is electrified, when the graphene material is electrified in the forward direction, the graphene material is heated, and when the graphene material is electrified in the reverse direction, the graphene material is electrified and refrigerated in the reverse direction, and the technology is called graphene navigation technology. The positive connection here means that the mixture I is connected with the positive electrode, and the mixture II is connected with the negative electrode to be regarded as positive connection.

Example one, the mixture one consists of the following components in parts by mass:

wherein the mixture consists of the following components:

6 parts of water and 1 part of ethanol.

The first diluent consists of the following components:

2 parts of dimethylbenzene, 1 part of methylbenzene and 4 parts of butyl acetate.

The second mixture consists of the following components in parts by mass:

example two, the first mixture consists of the following ingredients in parts by mass:

wherein the mixture consists of the following components:

6.5 parts of water and 1.1 parts of ethanol.

The first diluent consists of the following components:

2.5 parts of dimethylbenzene, 1.5 parts of methylbenzene and 5 parts of butyl acetate. The second mixture consists of the following components in parts by mass:

example three, the first mixture consists of the following ingredients in parts by mass:

wherein the mixture consists of the following components:

7 parts of water and 1.2 parts of ethanol.

The first diluent consists of the following components:

3 parts of dimethylbenzene, 2 parts of methylbenzene and 6 parts of butyl acetate.

The second mixture consists of the following components in parts by mass:

example 2

As shown in fig. 2, a graphene cooling and heating picture comprises a frame 1, a front panel 3 and a back panel 12, wherein the front surface (i.e., the outer surface) of the front panel 3 has a picture, the back surface (i.e., the inner surface) has a single-layer graphene and titanium material mixed coating, a cooling and heating superconducting transfer layer 4 and a graphene navigation heat and cooling component 5 are placed close to the single-layer graphene and titanium material mixed coating on the back surface of the front panel 3, an exhaust duct 13 is arranged on the frame 1, the front panel 3 and the back panel 12 are fastened together through fasteners to form a combined plate, and air holes are formed in the fasteners. The graphene navigation cooling and heating component 5 herein is the graphene navigation cooling and heating component provided in example 1. The front surface of the front panel 1 is provided with a laser and jet printing combined picture which is manufactured by a halation process, so that the picture is attractive, and can be customized. The inner side of the graphene navigation cold and hot part 5 is provided with a heat dissipation and cold dissipation device 6 and a gas circulation device 7.

In a specific embodiment, the heat dissipation and cold dissipation device 6 is a closed conduit made of a graphene material mixture, and can rapidly dissipate heat or cold generated by a component, and the device is tightly combined with a graphene navigation heat dissipation component.

In a particular embodiment, the housing is provided with a dc power supply 9, a temperature control device 10 and a power outlet 11. Graphite alkene navigation cold and hot part 5 passes through DC power supply 9 and power socket 11 and connects external power source, temperature control device 10 can control the temperature of graphite alkene navigation cold and hot part 5.

The single-layer graphene and titanium material mixed coating comprises the following components:

the second diluent consists of the following components: 3-5 parts of dimethylbenzene, 1-3 parts of methylbenzene and 4-8 parts of butyl acetate.

Example one:

the mixed coating of the single-layer graphene and the titanium material comprises the following components:

the second diluent consists of the following components: 3 parts of dimethylbenzene, 1 part of methylbenzene and 4 parts of butyl acetate.

Example two:

the mixed coating of the single-layer graphene and the titanium material comprises the following components:

the second diluent consists of the following components: 4 parts of dimethylbenzene, 2 parts of methylbenzene and 6 parts of butyl acetate.

Example three:

the mixed coating of the single-layer graphene and the titanium material comprises the following components:

the second diluent consists of the following components: 5 parts of dimethylbenzene, 3 parts of methylbenzene and 8 parts of butyl acetate.

In one embodiment, the heat dissipating and cooling device 6 is a closed conduit, and comprises the following components:

wherein the second diluent consists of the following components:

3-5 parts of dimethylbenzene, 1-3 parts of methylbenzene and 4-8 parts of butyl acetate.

The gas circulation device 7 is in a form of an air duct formed by a silent fan 8 and heat dissipation and cold dissipation fins made of a graphene mixture coating, and is connected with an exhaust duct 13 to transmit cold or heat outdoors. The device is tightly combined with a heat dissipation and cold dissipation device.

In a specific embodiment, the operating voltage of the direct current power supply 9 is 12V, and the graphene navigation heat and cold component is powered by the direct current power supply.

In a specific embodiment, the cold/hot superconducting transfer layer 4 is a graphene superconducting sheet, and is tightly bonded to the back surface of the front panel 3.

In one embodiment, the temperature control device 10 with a Wi fi module can be remotely controlled. Meanwhile, the automatic temperature control device is provided with the functions of controlling startup and shutdown heating and temperature reduction, controlling temperature at regular time and the like by the keys.

In a specific embodiment, the front panel 3 and the rear panel 12 are made of alloy material, and the rear panel 12 is tightly combined with the gas circulation device 7.

Because the graphene material has a super-conduction effect, the cold and heat superconducting transfer layer 4 can rapidly release cold and heat generated by the refrigerating and heating component and rapidly conduct the cold and heat to the front panel 3.

The graphene navigation cold and heat component provided by the invention achieves the refrigeration and heating effects by adopting an autonomous formula and technology, can heat and refrigerate indoors by adopting electric energy under the condition of not using Freon and an indoor unit of a compressor, can reduce the temperature by 7 ℃ in 20 minutes and improve the temperature by 10 ℃ in 35 minutes for a standard building room of 15 square meters by testing 1000w at present. And can generate 8-14um far infrared rays at the same time of heating and refrigerating, and is beneficial to health.

The heat dissipation and cold dissipation device 6 provided by the invention can quickly dissipate the heat or cold generated by the components, which is 1.3 times faster than the traditional heat dissipation mode.

The air circulation device provided by the invention is combined with the silent fan and the exhaust duct 13 to form an air channel. It is possible to maximize the outdoor transmission of the surplus heat or cold generated from the components.

The invention is provided with the exhaust duct 13, which can lead the redundant heat and cold to pass and be released outdoors.

In a specific embodiment, the frame 1 is provided with an air outlet 2.

The above embodiments are provided to further explain the objects, technical solutions and advantages of the present invention in detail, it should be understood that the above embodiments are merely exemplary embodiments of the present invention and are not intended to limit the scope of the present invention, and any modifications, equivalents, improvements and the like made within the spirit and principle of the present invention should be included in the scope of the present invention.

Claims (7)

1. A graphene navigation cold and hot component is characterized by comprising a ceramic plate (51) and a resin plate (52) which are attached and packaged together, wherein one side of the ceramic plate (51) is coated with a first mixture, one side of the resin plate (52) is coated with a second mixture, and wires are respectively arranged on the ceramic plate and the resin plate, wherein two sides coated with the first mixture and the second mixture face inwards, and then the wires are arranged on the two inwards facing sides;

the first mixture consists of the following components in parts by mass:

the second mixture consists of the following components in parts by mass:

the mixture consists of the following components:

6-7 parts of water and 1-1.2 parts of ethanol.

2. The graphene navigation cold and hot part of claim 1, wherein the first diluent consists of:

2-3 parts of dimethylbenzene, 1-2 parts of methylbenzene and 4-6 parts of butyl acetate.

3. A graphene cold and warm painting is characterized by comprising a shell consisting of a frame (1), a front panel (3) and a rear panel (12), the outer surface of the front panel (3) is provided with a picture, the inner surface of the front panel (3) is provided with a single-layer graphene and titanium material mixed coating, the single-layer graphene and titanium material mixed coating is closely provided with a cold and hot superconducting transfer layer (4) and a graphene navigation heat and cold component (5), the inner side of the graphene navigation heat and cold component (5) is provided with a heat dissipation and cold dissipation device (6) and a gas circulation device (7), an exhaust duct (13) is arranged on the frame (1), the front panel (3) and the rear panel (12) are buckled together by buckling parts to form a combined plate, the buckling parts are provided with air holes, wherein the graphene navigation cooling and heating component (5) is the graphene navigation cooling and heating component of any one of claims 1-2;

the heat dissipation and cold dissipation device (6) is in the form of a closed conduit and comprises the following components:

the second diluent consists of the following components:

3-5 parts of dimethylbenzene, 1-3 parts of methylbenzene and 4-8 parts of butyl acetate.

4. The graphene cold-warm drawing according to claim 3, wherein the casing is further provided with a direct current power supply (9), a temperature control device (10) and a power socket (11).

5. The graphene cold-warm drawing according to claim 3, wherein a mute fan (8) is arranged in the gas circulation device (7).

6. The graphene cold-warm drawing according to claim 4, wherein the operating voltage of the direct current power supply (9) is 12V, and the graphene navigation cold-heat component is powered.

7. The graphene cold-warm drawing according to claim 3, wherein an air outlet (2) is formed in the frame (1).

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