CN109822984B - Graphene far-infrared foreign magnetic plate - Google Patents

Abstract

The invention discloses a graphene far infrared ferromagnetic slab, and relates to the technical field of slabs; the floor comprises a floor body, a graphene far infrared heating core plate, a wire leading-out end and a wire; the upper surface of graphite alkene far infrared core that generates heat has been pegged graft and has been had the electric wire to draw forth the end, and the electric wire is drawn forth and is served and be connected with the electric wire, has seted up logical groove in the floor body, and graphite alkene far infrared core that generates heat inserts and establishes in this logical groove. It generates heat the split type setting in layer with floor and graphite alkene, is favorable to the later stage to the inside graphite alkene in floor generate heat the layer and change and maintain, practices thrift panel cost, and the practicality is stronger.

Description

Graphene far-infrared foreign magnetic plate

Technical Field

The invention relates to the technical field of plates, in particular to a graphene far infrared geomagnetic plate.

Background

The graphene heating film is a semitransparent polyester film capable of heating after being electrified, and is prepared by hot-pressing conductive special carbon paste ink, a mixture of dozens of rare metal elements (containing graphene components) and a metal current carrying strip into a core graphene heating layer through various processes, and wrapping an imported epoxy resin waterproof layer, an electrostatic absorption protective layer, an electromagnetic shielding protective layer, an anti-creeping protective layer and the like from top to bottom. The heat exchanger can send most of heat into a room in a radiation mode, not only heats air, but also heats floor and wall plates in the room firstly, and then radiates the radiation heat by the objects, so that the indoor temperature is naturally and uniformly raised, the heat conversion efficiency can reach more than 99 percent, and the service life is 20 ten thousand hours.

The graphene heating film is applied to the floor or the wallboard, and can heat the floor and the wallboard for improving the environment temperature. Graphite alkene membrane in the floor that generates heat at present and floor formula structure as an organic whole, add man-hour at the floor, with graphite alkene heating film pressfitting to floor sheet layer in, after the floor is used for a long time, can have graphite alkene heating layer to appear because of heating the phenomenon that factors such as too much appear damaging, just need to change the monoblock floor this moment, extravagant panel undoubtedly causes the wasting of resources, awaits urgently and improves.

Disclosure of Invention

The invention aims to overcome the defects and shortcomings of the prior art, and provides the graphene far infrared external magnetic plate which is simple in structure, reasonable in design and convenient to use.

In order to achieve the purpose, the invention adopts the technical scheme that: the floor comprises a floor body, a graphene far infrared heating core plate, a wire leading-out end and a wire; a wire leading-out end is inserted in the upper surface of the graphene far infrared heating core plate, a wire is connected to the wire leading-out end, a through groove is formed in the floor body, and the graphene far infrared heating core plate is inserted in the through groove;

the graphene far infrared heating core plate is composed of a graphene heating film, a far infrared generating layer, heat reflecting glass, a heat insulating layer and a heat conducting silica gel layer; the lower surface of the graphene heating film is provided with a far infrared ray generation layer, the lower surface of the far infrared ray generation layer is provided with heat reflection glass, and the lower surface of the heat reflection glass is provided with a heat insulation layer; the upper surface of the graphene heating film is provided with a heat-conducting silica gel layer, and the upper surface of the heat-conducting silica gel layer is in contact with the floor body at the upper part of the through groove; lead-out end through holes are formed in the heat-conducting silicon adhesive layer, the electric wire lead-out ends are arranged in the lead-out end through holes in a penetrating mode, and the lower ends of the electric wire lead-out ends are connected with the graphene heating film in a contact mode.

Further, the upper surface on heat conduction silica gel layer seted up the bar groove, the electric wire is laid in the bar inslot, and inlay in the bar groove and be equipped with the silica gel strip of paper used for sealing.

Further, both ends all are equipped with the shrouding around the floor body, set up the through wires hole that the power supply line wore to establish on the shrouding.

Furthermore, a detection opening is formed in the floor body on the upper portion of the through groove, and a plugging plate is embedded in the detection opening.

Furthermore, the upper surface of the heat-conducting silica gel layer positioned between the lead-out ends of the wires at the left side and the right side is set as the upper surface of the sawtooth; the lower surface of the floor body on the upper part of the through groove is provided with a sawtooth lower surface which is matched and embedded with the upper surface of the sawtooth.

Further, graphite alkene far infrared core that generates heat's one end lower surface seted up the arc recess, lead to the upper surface of the floor body of groove lower part and seted up the caulking groove, the caulking groove internal fixation has the spring, the upper end of spring is connected with the arc arch of establishing with arc recess cooperation card, this arc arch activity sets up in the caulking groove.

Furthermore, the heat insulation layer is a heat insulation coating which is coated on the lower surface of the heat reflection glass.

The processing steps of the invention are as follows:

1. a through groove is arranged in the floor body;

2. spraying heat-insulating paint on the lower surface of the heat reflection glass by adopting a spraying process to form a heat-insulating layer;

3. placing heat reflection glass, a far infrared ray generation layer, a graphene heating film and a heat conduction silicon adhesive layer from bottom to top, coating adhesives between adjacent layers, and pressing and molding the layers by adopting a pressing process to form the graphene far infrared heating core plate;

4. punching a hole in the press-molded heat-conducting silica gel layer, namely punching a leading-out end, inserting the wire leading-out end into the hole until the lower end of the wire leading-out end is contacted with the graphene heating film, and finally coating adhesive on the contact position of the upper end of the wire leading-out end and the upper surface of the heat-conducting silica gel layer to fix the wire leading-out end in the leading-out end hole;

5. connecting positive and negative wires to the wire leading-out ends of the positive and negative electrodes respectively, connecting two wires in parallel to one wire leading-out end, leading out the wires to the front and rear ends of the graphene far infrared heating core plate, and placing the wires outside the floor body;

6. finally, inserting the graphene far infrared heating core plate connected with the electric wire into the floor body;

7. when the floor is laid, positive and negative wires in the adjacent floor bodies from head to tail are connected with each other, and parallel connection among the graphene far infrared heating core plates in the plurality of floor bodies is completed; and finally, connecting positive and negative electric wires on the graphene far infrared heating core plate at the edge with a power supply and a controller to form an electric loop.

After adopting the structure, the invention has the beneficial effects that: according to the graphene far infrared outer magnetic plate, the floor and the graphene heating layer are arranged in a split mode, the replacement and maintenance of the graphene heating layer in the floor in the later period are facilitated, the cost of plates is saved, the practicability is higher, and the graphene far infrared outer magnetic plate has the advantages of being simple in structure, reasonable in arrangement, low in manufacturing cost and the like.

Drawings

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

Fig. 1 is an exploded view of the present invention.

Fig. 2 is an exploded view of the graphene far infrared heating core plate according to the present invention.

FIG. 3 is a cross-sectional view of the connection between the heat conductive silicone layer and the floor body according to the present invention.

Fig. 4 is a schematic illustration of the graphene far infrared heating core plate and the floor body in the invention.

Description of reference numerals:

the floor comprises a floor body 1, a detection opening 1-1, a sawtooth lower surface 1-2, a through groove 1-3, an embedded groove 1-4, a graphene far infrared heating core plate 2, a graphene heating film 2-1, a far infrared generating layer 2-2, heat reflection glass 2-3, a heat insulation layer 2-4, an arc-shaped groove 2-4-1, a heat conduction silica gel layer 2-5, a strip-shaped groove 2-5-1, a leading-out end through hole 2-5-2, a sawtooth upper surface 2-5-3, a silica gel seal 2-6, an electric wire leading-out end 3, an electric wire 4, an arc-shaped bulge 5, a spring 6, a seal plate 7, a threading hole 7-1 and a blocking plate 8.

Detailed Description

The invention will be further described with reference to the accompanying drawings.

Referring to fig. 1 to 4, the technical solution adopted by the present embodiment is: the floor comprises a floor body 1, a graphene far infrared heating core plate 2, a wire leading-out end 3 and a wire 4; an electric wire leading-out end 3 is inserted into the upper surface of the graphene far infrared heating core plate 2, an electric wire 4 is connected onto the electric wire leading-out end 3, a through groove 1-3 is formed in the floor body 1, a detection opening 1-1 is formed in the floor body 1 at the upper part of the through groove 1-3, and a plugging plate 8 is embedded in the detection opening 1-1;

the graphene far infrared heating core plate 2 is composed of a graphene heating film 2-1, a far infrared ray generating layer 2-2, heat reflecting glass 2-3, a heat insulating layer 2-4 and a heat conducting silica gel layer 2-5; the lower surface of the graphene heating film 2-1 is provided with a far infrared ray generation layer 2-2, the lower surface of the far infrared ray generation layer 2-2 is provided with heat reflection glass 2-3, the heat reflection glass 2-3, and the lower surface of the heat reflection glass 2-3 is sprayed with heat preservation and insulation paint to form a heat preservation and insulation layer 2-4; the upper surface of the graphene heating film 2-1 is provided with a heat-conducting silica gel layer 2-5, the upper surface of the heat-conducting silica gel layer 2-5 is provided with a strip-shaped groove 2-5-1, the electric wire 4 is arranged in the strip-shaped groove 2-5-1, and a silica gel seal 2-6 is embedded in the strip-shaped groove 2-5-1; the upper surface of the heat-conducting silica gel layer 2-5 is in contact with the floor body 1 at the upper part of the through groove 1-3 (the heat-conducting silica gel layer 2-5 has certain elasticity and is in a compressed state in the inserting process, and after the heat-conducting silica gel layer is completely arranged, the whole heat-conducting silica gel layer 2-5 is completely attached to the floor body 1 by the elasticity of the heat-conducting silica gel layer); a leading-out end through hole 2-5-2 is formed in the heat-conducting silicon adhesive layer 2-5, the wire leading-out end 3 is arranged in the leading-out end through hole 2-5-2 in a penetrating mode, and the lower end of the wire leading-out end is connected with the graphene heating film 2-1 in a contact mode; the lower surface of one end of the heat reflection glass 2-3 is provided with an arc-shaped groove 2-4-1, the upper surface of the floor body 1 at the lower part of the through groove 1-3 is provided with an embedded groove 1-4, a spring 6 is fixed in the embedded groove 1-4, the upper end of the spring 6 is connected with an arc-shaped bulge 5 (made of steel balls) matched and clamped with the arc-shaped groove 2-4-1, the arc-shaped bulge 5 is movably arranged in the embedded groove 1-4, the graphene far infrared heating core plate 2 is inserted in the through groove 1-3, and the arc-shaped groove 2-4-1 is matched with the arc-shaped bulge 5 to be clamped and fixed.

Furthermore, the front end and the rear end of the floor body 1 are respectively provided with a sealing plate 7, and the sealing plates 7 are provided with threading holes 7-1 through which the power supply lines 4 penetrate.

Furthermore, the upper surface of the heat-conducting silica gel layer 2-5 positioned between the wire leading-out ends 3 at the left side and the right side is set as a sawtooth upper surface 2-5-3; the lower surface of the floor body 1 at the upper part of the through groove 1-3 is provided with a sawtooth lower surface 1-2 which is matched and embedded with the sawtooth upper surface 2-5-3, so that the heat transfer area is increased.

The processing steps of the embodiment are as follows:

1. the floor board body 1 is provided with through grooves 1-3, holes are formed in the floor board body 1 at the upper parts of the through grooves 1-3, namely detection openings 1-1 are formed, one end of the upper surface of the floor board body 1 at the lower parts of the through grooves 1-3 is provided with an embedded groove 1-4, a spring 6 with an arc-shaped bulge 5 is embedded in the embedded groove 1-4, the lower end of the spring 6 is fixedly connected with the embedded groove 1-4 through an adhesive, and the upper half section of the arc-shaped bulge 5 is exposed above the embedded groove 1-4 under the premise that the spring 6 is not compressed;

2. spraying heat-insulating coating on the lower surface of the heat reflection glass 2-3 by adopting a spraying process to form a heat-insulating layer 2-4, and forming an arc-shaped groove 2-4-1 on the lower surface of one end of the heat reflection glass 2-3;

3. placing heat reflection glass 2-3, a far infrared ray generation layer 2-2 (a metal oxide film, namely a copper oxide film or a silver oxide film and the like), a graphene heating film 2-1 and a heat conduction silica gel layer 2-5 from bottom to top, coating adhesives among adjacent layers, and performing lamination molding on the layers by adopting a lamination process to form a graphene far infrared heating core plate 2;

4. punching a hole in the pressed and molded heat-conducting silica gel layer 2-5, namely a leading-out end punching hole 2-5-2, inserting the wire leading-out end 3 into the punching hole until the lower end of the wire leading-out end 3 is contacted with the graphene heating film 2-1, finally coating adhesive on the contact part of the upper end of the wire leading-out end 3 and the upper surface of the heat-conducting silica gel layer 2-5, and fixing the wire leading-out end 3 in the leading-out end punching hole 2-5-2;

5. the left side and the right side of the upper surface of the heat-conducting silica gel layer 2-5 are provided with strip-shaped grooves 2-5-1, electric wires 4 are arranged in the strip-shaped grooves 2-5-1, positive and negative electric wires 4 are respectively connected to positive and negative electric wire leading-out ends 3, one electric wire leading-out end 3 is connected with two electric wires 4 in parallel, and the electric wires 4 are led out to the front end and the rear end of the graphene far infrared heating core plate 2 and are arranged outside the floor body 1;

6. finally, inserting the graphene far infrared heating core plate 2 connected with the electric wire 4 into the floor body 1, connecting upper sealing plates 7 at the front end and the rear end of the floor body 1 by using embedded screws, and embedding a plugging plate 8 in the detection opening 1-1;

7. when the floor boards are laid, the positive and negative electric wires 4 in the adjacent floor boards 1 from head to tail are connected with each other, and the parallel connection among the graphene far infrared heating core boards 2 in the plurality of floor boards 1 is completed; and finally, connecting positive and negative electric wires 4 on one graphene far infrared heating core plate 2 at the edge with a power supply and a controller to form an electric loop, wherein the controller has the same working principle as a controller of an electric blanket in the prior art, can adjust the heating temperature, the heating state and other operations of the whole floor, a temperature detector is embedded in a detection opening 1-1 in each floor body 1, and a probe of the temperature detector is arranged in contact with the graphene heating film 2-1 to detect whether the floor body 1 generates heat in real time, so that fault troubleshooting can be conveniently, quickly and accurately carried out.

The working principle of the specific embodiment is as follows: the power supply of the whole floor is started to supply power, the graphene heating film 2-1 is heated to generate heat and simultaneously generate far infrared light waves, meanwhile, the heat is conducted to the heat-conducting silica gel layer 2-5 and the far infrared ray generation layer 2-2 which are adjacent to the heat-conducting silica gel layer, the far infrared ray generation layer 2-2 further generates far infrared light waves, the heat-conducting silica gel layer 2-5 transmits the generated heat to the upper surface of the floor body 1 to radiate the heat, meanwhile, heat reflection glass 2-3 arranged below the far infrared ray generation layer 2-2 reflects heat generated by the graphene heating film 2-1 and far infrared light waves generated by the graphene heating film 2-1 and the far infrared ray generation layer 2-2 to the upper surface of the floor body 1, and a heat insulation layer 2-4 arranged above the heat reflection glass 2-3 accumulates heat; when the graphene heating film 2-1 is conductive, a magnetic field can be generated, the graphene heating film utilizes the characteristics of the graphene heating film, so that the temperature of the floor is uniformly increased, and the generated magnetic field and the far infrared light wave of 6-14 microns can generate a health care function on a human body; when breaking down, take out the floor body 1 that has damaged to take out graphite alkene far infrared heating core 2 in it, change new graphite alkene far infrared heating core 2 can.

After adopting the structure, the invention has the beneficial effects that:

1. the controller controls the temperature of the whole circuit, so that the effect of randomly adjusting the temperature is achieved;

2. the system can be started or closed randomly according to the needs of users, the operation is very economical, the power consumption is about 0.33 degrees/square meter/day, the energy consumption per month of 100 square meters is less than 700 yuan, and the installation cost, the use cost and the maintenance cost are greatly reduced compared with the centralized heating and water and ground heating;

3. the heating plate and the pipeline are not needed, so the space thickness is small (18 MM), the temperature rise is fast, the floor can obviously feel warm within half an hour, the floor is the thinnest electric floor heating at present, and the whole system has long service life, is free from maintenance and maintenance;

4. the formaldehyde is zero, smoke dust and dust are not generated, noise and floating dust caused by indoor air convection are avoided, the urban planning requirement is met, and the environment-friendly indoor air purifying agent is suitable for the green and environment-friendly requirement of the modern society;

5. because the radiation mode is adopted for heating, the human body feels hot but not dry in the room heated by the product, and the whole body is warm and fresh, like the feeling of bathing under natural sunlight;

6. when the system works, the surface of the product keeps low-temperature operation, and the highest temperature does not exceed 40 ℃. Therefore, accidents such as scalding, explosion, fire and the like cannot happen, and the whole system is connected in a parallel mode.

The above description is only for the purpose of illustrating the technical solutions of the present invention and not for the purpose of limiting the same, and other modifications or equivalent substitutions made by those skilled in the art to the technical solutions of the present invention should be covered within the scope of the claims of the present invention without departing from the spirit and scope of the technical solutions of the present invention.

Claims (2)

1. The utility model provides a graphite alkene far infrared magnetic plate which characterized in that: the floor comprises a floor body (1), a graphene far infrared heating core plate (2), a wire leading-out end (3) and a wire (4); an electric wire leading-out end (3) is inserted into the upper surface of the graphene far infrared heating core plate (2), an electric wire (4) is connected onto the electric wire leading-out end (3), a through groove (1-3) is formed in the floor body (1), and the graphene far infrared heating core plate (2) is inserted into the through groove (1-3);

the graphene far infrared heating core plate (2) is composed of a graphene heating film (2-1), a far infrared generating layer (2-2), heat reflecting glass (2-3), a heat insulating layer (2-4) and a heat conducting silica gel layer (2-5); the lower surface of the graphene heating film (2-1) is provided with a far infrared ray generation layer (2-2), the lower surface of the far infrared ray generation layer (2-2) is provided with heat reflection glass (2-3), the heat reflection glass (2-3) and the lower surface of the heat reflection glass (2-3) is provided with a heat insulation layer (2-4); the upper surface of the graphene heating film (2-1) is provided with a heat-conducting silica gel layer (2-5), and the upper surface of the heat-conducting silica gel layer (2-5) is in contact with the floor body (1) at the upper part of the through groove (1-3); a leading-out end through hole (2-5-2) is formed in the heat conduction silica gel layer (2-5), the wire leading-out end (3) is arranged in the leading-out end through hole (2-5-2) in a penetrating mode, and the lower end of the wire leading-out end is in contact connection with the graphene heating film (2-1); the upper surface of the heat-conducting silica gel layer (2-5) is provided with a strip-shaped groove (2-5-1), the electric wire (4) is arranged in the strip-shaped groove (2-5-1), and a silica gel seal (2-6) is embedded in the strip-shaped groove (2-5-1); sealing plates (7) are arranged at the front end and the rear end of the floor body (1), and threading holes (7-1) through which the power supply lines (4) penetrate are formed in the sealing plates (7); a detection opening (1-1) is formed in the floor body (1) at the upper part of the through groove (1-3), and a plugging plate (8) is embedded in the detection opening (1-1); the upper surface of the heat-conducting silica gel layer (2-5) positioned between the wire leading-out ends (3) at the left side and the right side is set as a sawtooth upper surface (2-5-3); the lower surface of the floor body (1) at the upper part of the through groove (1-3) is provided with a sawtooth lower surface (1-2) which is matched and embedded with the sawtooth upper surface (2-5-3); an arc-shaped groove (2-4-1) is formed in the lower surface of one end of the graphene far infrared heating core plate (2), an embedding groove (1-4) is formed in the upper surface of the floor body (1) at the lower portion of the through groove (1-3), a spring (6) is fixed in the embedding groove (1-4), an arc-shaped protrusion (5) matched and clamped with the arc-shaped groove (2-4-1) is connected to the upper end of the spring (6), and the arc-shaped protrusion (5) is movably arranged in the embedding groove (1-4); the heat preservation and insulation layer (2-4) is a heat preservation and insulation coating which is coated on the lower surface of the heat reflection glass (2-3).

2. The utility model provides a graphite alkene far infrared magnetic plate which characterized in that: the processing steps are as follows:

(1) a through groove is formed in the floor body;

(2) spraying heat-insulating paint on the lower surface of the heat reflection glass by adopting a spraying process to form a heat-insulating layer;

(3) placing heat reflection glass, a far infrared ray generation layer, a graphene heating film and a heat conduction silicon rubber layer from bottom to top, coating adhesives between adjacent layers, and pressing and molding the layers by adopting a pressing process to form the graphene far infrared heating core plate;

(4) punching a hole in the heat-conducting silica gel layer after press molding, namely punching a leading-out end, inserting the wire leading-out end into the hole until the lower end of the wire leading-out end is contacted with the graphene heating film, and finally coating adhesive on the contact position of the upper end of the wire leading-out end and the upper surface of the heat-conducting silica gel layer to fix the wire leading-out end in the leading-out end hole;

(5) connecting positive and negative wires to the wire leading-out ends of the positive and negative wires respectively, connecting two wires in parallel on one wire leading-out end, leading out the wires to the front and rear ends of the graphene far infrared heating core plate, and placing the wires outside the floor body;

(6) finally, inserting the graphene far infrared heating core plate connected with the electric wire into the floor body;

(7) when the floor is laid, positive and negative wires in the adjacent floor bodies from head to tail are connected with each other, and parallel connection among the graphene far infrared heating core plates in the plurality of floor bodies is completed; and finally, connecting positive and negative electric wires on the graphene far infrared heating core plate at the edge with a power supply and a controller to form an electric loop.

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