CN112900785A

CN112900785A - Open graphite alkene ceramic tile underfloor heating system that generates heat promptly and can control temperature promptly

Info

Publication number: CN112900785A
Application number: CN202110037222.0A
Authority: CN
Inventors: 张琪阳
Original assignee: Guangzhou Ene Health New Material Technology Co ltd
Current assignee: Guangzhou Ene Health New Material Technology Co ltd
Priority date: 2021-01-12
Filing date: 2021-01-12
Publication date: 2021-06-04
Anticipated expiration: 2041-01-12
Also published as: CN112900785B

Abstract

The invention discloses an instant heating temperature-controllable graphene heating ceramic tile floor heating system, which comprises a ceramic tile body, a heating strip, a graphene interlayer, a heating inner plate, an inserting end, a heat transfer plate, a heat transfer end point and a butt end, wherein a heating resistor upwards transfers heat to an upper heating transfer plate, the heating transfer plate transfers the heat between two connected ceramic tile bodies through a heating transfer column to accelerate the rapid heating of the heating transfer plate, simultaneously, after the heating transfer plate transfers the heat to the interlayer body, the heat transfer column transfers the heat to the top of the ceramic tile body, the interlayer body further transfers the heat to the heating strip through a heat transfer thin rod, so that the upper surface of the ceramic tile body and the heating strip are rapidly heated, meanwhile, a temperature storage hole can retain the heat, and the heating time required by secondary heating in a short period is saved, the temperature control and regulation can be realized, and heat can be rapidly transferred.

Description

Open graphite alkene ceramic tile underfloor heating system that generates heat promptly and can control temperature promptly

Technical Field

The invention relates to the technical field of ceramic tile floor heating, in particular to a graphene heating ceramic tile floor heating system capable of being opened and heated instantly and controlling temperature.

Background

The current heating modes in China mainly comprise: central heating, radiator heating, geothermal floor heating, central air-conditioning heating, household wall-hanging gas heating, electric heating film heating and the like. The central heating, the radiator heating and the geothermal floor heating are heating modes which are massively adopted in cities, and have the advantages of mature technology, safe and convenient use, all-weather heating and relatively low cost.

Just can adopt warm ceramic tile of electricity to heat when geothermal floor heating, warm ceramic tile of electricity is by becoming the ceramic tile that generates heat again, the ceramic tile that generates heat is that traditional ceramic tile can oneself send heat through using certain technique, generally is used for ground heating, discovery in the use that the ceramic tile warms up generates heat, the heat has a large amount of losses at the in-process of transmission, consequently after beginning to generate heat, need one section time could feel thermal existence, can't satisfy people's heating demand.

Disclosure of Invention

The invention aims to provide an instant heating temperature-controllable graphene heating ceramic tile floor heating system, wherein connecting wires inside two connected ceramic tile bodies are electrified, after the connecting wires are electrified, a heating resistor starts to generate heat, the heating resistor upwards transfers the heat to an upper heating transfer plate, the heating transfer plate transfers the heat between the two connected ceramic tile bodies through a heating transfer column to accelerate the rapid heating of the heating transfer plate, meanwhile, after the heating transfer plate transfers the heat to an interlayer body, the heat transfer column transfers the heat to the top of the ceramic tile body, the interlayer body further transfers the heat to a heating strip through a heat transfer thin rod, so that the upper surface of the ceramic tile body and the heating strip are rapidly heated, meanwhile, a temperature storage hole can retain the heat, the heating time required by reheating in a short period is saved, and the temperature can be controlled and adjusted, and rapidly transfer heat to solve the problems suggested in the background art.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides an open graphite alkene ceramic tile underfloor heating system that heats promptly controllable temperature soon, includes ceramic tile body, heating strip, graphite alkene intermediate layer, heating inner panel, ann inserts end, heat transfer plate, heat transfer terminal point and butt joint end, ceramic tile body's top is equipped with the heating strip, fixed connection between heating strip and the ceramic tile body, graphite alkene intermediate layer has been seted up to ceramic tile body's inside, graphite alkene intermediate layer's below is equipped with the heating inner panel, ann inserts the end has been seted up to one side of heating inner panel, one side that the ann inserts the end was kept away from to the heating inner panel has been seted up the butt joint end, the top of butt joint end is equipped with the heat transfer plate, the outside of.

Preferably, the graphene interlayer comprises an interlayer body, a temperature storage hole, heat transfer columns and heat transfer thin rods, the temperature storage hole is formed in the interlayer body, the heat transfer columns are fixedly mounted at the top end of the interlayer body, the top ends of the heat transfer columns are in contact with the tile body, the heat transfer thin rods are arranged between the heat transfer columns, the bottom ends of the heat transfer thin rods are fixedly connected with the interlayer body, and the top ends of the heat transfer thin rods are fixedly connected with the heating strips.

Preferably, the heating inner plate includes heating resistor, heating transfer board, heating transfer post and power connection line, heating resistor's top fixed connection is on the heating transfer board, one side fixedly connected with heating transfer post of heating transfer board, one side fixedly connected with heat transfer plate that heating transfer post was kept away from to the heating transfer board, be equipped with the power connection line between the heating resistor.

Preferably, the inserting end comprises a plug body, a bearing rotating shaft and a positioning seat, the bottom end of the plug body is penetrated by the bearing rotating shaft, two ends of the bearing rotating shaft are movably arranged on the positioning seat, and the positioning seat is fixedly arranged on the tile body.

Preferably, the plug body is electrically connected with the power connection wire, the plug body is movably mounted on the positioning seat through a bearing rotating shaft, and the plug board at the front end of the plug body is matched with the slot at the butt joint end.

Preferably, the top of heating strip and the top of ceramic tile body are parallel and level each other, and the bottom of heating strip is connected through between heat transfer pin and the intermediate layer body.

Compared with the prior art, the invention has the beneficial effects that: the invention provides an instant heating temperature-controllable graphene heating ceramic tile floor heating system, wherein a plug body is pushed downwards, the plug body rotates on a positioning seat through a bearing rotating shaft, so that the plug body leaves the inside of a ceramic tile body and is kept horizontal, an inserting plate at the front end of the plug body is inserted into a butt joint end on the other ceramic tile body, the electric connection between the plug body and the butt joint end is kept, meanwhile, a heating transfer column at one side of a heating transfer plate is mutually butted with a heat transfer end point in a heat transfer plate on the other ceramic tile body, after a butt electric wire is electrified, an electric wire is mutually butted between the plug body and the butt joint end, the electric wire in the two connected ceramic tile bodies is electrified, after the electric wire is electrified, a heating resistor starts to generate heat, and the heating resistor upwards transfers heat to the heating transfer plate above, the heating transfer board transmits the heat between two ceramic tile bodies that link to each other through the heating transfer post each other, heat the rapid intensification of transfer board with higher speed, the while heats the transfer board and transmits the heat for intermediate layer body after, the top of ceramic tile body is transmitted with the heat to the heat transfer post, the intermediate layer body further transmits the heat to the heating strip through the heat transfer pin, make the upper surface and the heating strip of ceramic tile body heat up rapidly, deposit the warm hole simultaneously and can preserve the heat, required heating time when saving in short-term intensification once more, this structure can realize the control regulation to the temperature, and the quick transmits the heat.

Drawings

FIG. 1 is a perspective view of the present invention;

FIG. 2 is a cross-sectional view of the present invention;

fig. 3 is a top view of a graphene interlayer of the present invention;

FIG. 4 is an enlarged view taken at A of FIG. 2 in accordance with the present invention;

FIG. 5 is a schematic structural view of the insertion end of the present invention;

fig. 6 is a schematic diagram of the butt joint of the insertion end of the present invention.

In the figure: 1. a tile body; 2. heating the strip; 3. a graphene interlayer; 31. an interlayer body; 32. a temperature storage hole; 33. a heat transfer column; 34. a heat transfer pin; 4. heating the inner plate; 41. a heating resistor; 42. a heat transfer plate; 43. heating the transfer column; 44. connecting a wire; 5. inserting the end; 51. a plug body; 52. a bearing rotating shaft; 53. positioning seats; 6. a heat transfer plate; 7. a heat transfer endpoint; 8. and (4) butting ends.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-4, an instant heating and temperature-controllable graphene heating tile floor heating system comprises a tile body 1, a heating strip 2, a graphene interlayer 3, a heating inner plate 4, an inserting end 5, a heat transfer plate 6, a heat transfer end point 7 and a butt end 8, wherein the heating strip 2 is arranged at the top end of the tile body 1, the top of the heating strip 2 is flush with the top of the tile body 1, the bottom end of the heating strip 2 is connected with an interlayer body 31 through a heat transfer thin rod 34, the heating strip 2 is fixedly connected with the tile body 1, the graphene interlayer 3 is arranged inside the tile body 1, the heating inner plate 4 is arranged below the graphene interlayer 3, the inserting end 5 is arranged at one side of the heating inner plate 4, the butt end 8 is arranged at one side of the heating inner plate 4 far away from the inserting end 5, the heat transfer plate 6 is arranged above the butt end 8, the heat transfer end point 7 is arranged at the outer, the graphene interlayer 3 comprises an interlayer body 31, a temperature storage hole 32, heat transfer columns 33 and heat transfer thin rods 34, the temperature storage hole 32 is formed in the interlayer body 31, the heat transfer columns 33 are fixedly mounted at the top end of the interlayer body 31, the top ends of the heat transfer columns 33 are in contact with the tile body 1, the heat transfer thin rods 34 are arranged between the heat transfer columns 33, the bottom ends of the heat transfer thin rods 34 are fixedly connected with the interlayer body 31, the top ends of the heat transfer thin rods 34 are fixedly connected with the heating strip 2, the heating inner plate 4 comprises heating resistors 41, heating transfer plates 42, heating transfer columns 43 and electric wires 44, the top ends of the heating resistors 41 are fixedly connected onto the heating transfer plates 42, the heating transfer columns 43 are fixedly connected onto one side of the heating transfer plates 42, the heat transfer plates 6 are fixedly connected onto one side of the heating transfer plates 42, the electric wires 44 are arranged between the heating resistors 41, the heating transfer columns 43 on one side of the heating transfer plates 42 and the heat transfer end points 7 in the heat transfer Butt joint, when the butt joint electric wire 44 is electrified, the electric wire 44 is in butt joint with the butt joint end 8 through the plug body 51, the electric wire 44 inside the two connected ceramic tile bodies 1 is electrified, after the electric wire 44 is electrified, the heating resistor 41 starts to generate heat, the heating resistor 41 upwards transfers the heat to the heating transfer plate 42 above, the heating transfer plate 42 transfers the heat between the two connected ceramic tile bodies 1 through the heating transfer column 43 to accelerate the rapid temperature rise of the heating transfer plate 42, meanwhile, after the heating transfer plate 42 transfers the heat to the interlayer body 31, the heat transfer column 33 transfers the heat to the top of the ceramic tile body 1, the interlayer body 31 further transfers the heat to the heating strip 2 through the heat transfer thin rod 34, so that the upper surface of the ceramic tile body 1 and the heating strip 2 are rapidly heated, and the heat storage hole 32 can retain the heat, the heating time required for reheating in a short period is saved.

Referring to fig. 5-6, the inserting end 5 includes a plug body 51, a receiving shaft 52 and a positioning seat 53, the bottom end of the plug body 51 is penetrated by the receiving shaft 52, two ends of the receiving shaft 52 are movably mounted on the positioning seat 53, the positioning seat 53 is fixedly mounted on the tile body 1, the plug body 51 is electrically connected with the power connection wire 44, the plug body 51 is movably mounted on the positioning seat 53 through the receiving shaft 52, an inserting plate at the front end of the plug body 51 is matched with an inserting groove of the butt end 8, the plug body 51 is shifted downwards, the plug body 51 rotates on the positioning seat 53 through the receiving shaft 52, so that the plug body 51 leaves the interior of the tile body 1, and keeping the plug body 51 horizontal, inserting the insert plate at the front end of the plug body 51 into the butt end 8 on the other tile body 1, and keeping the electrical connection between the plug body 51 and the butt end 8.

The working principle of the invention is as follows: the plug body 51 is pulled downwards, the plug body 51 rotates on the positioning seat 53 through the bearing rotating shaft 52, the plug body 51 is separated from the inside of the tile body 1, the plug body 51 is kept horizontal, the plug board at the front end of the plug body 51 is inserted into the butt joint end 8 on the other tile body 1, the plug body 51 is kept electrically connected with the butt joint end 8, meanwhile, the heating transmission column 43 at one side of the heating transmission plate 42 is mutually butted with the heat transmission endpoint 7 in the heat transmission plate 6 on the other tile body 1, after the butt joint electric wire 44 is electrified, the electric wire 44 is mutually butted between the plug body 51 and the butt joint end 8, the electric wire 44 in the two connected tile bodies 1 is electrified, after the butt joint electric wire 44 is electrified, the heating resistor 41 starts to generate heat, the heating resistor 41 upwards transmits the heat to the heating transmission plate 42 above, heating transfer plate 42 transmits the heat each other between two ceramic tile bodies 1 that link to each other through heating transfer post 43, heat transfer plate 42's rapid heating up with higher speed, simultaneously heating transfer plate 42 gives intermediate layer body 31 with heat transfer after, heat transfer post 33 is with heat transfer to ceramic tile body 1's top, intermediate layer body 31 further with heat transfer to heating strip 2 through heat transfer pin 34 on, the upper surface that makes ceramic tile body 1 and heating strip 2 heat up rapidly, deposit warm hole 32 simultaneously and can remain the heat, save required heating time when heating up once more in the short-term.

In summary, the following steps: the invention provides an instant heating temperature-controllable graphene heating tile floor heating system, wherein a plug body 51 is pushed downwards, the plug body 51 rotates on a positioning seat 53 through a bearing rotating shaft 52, the plug body 51 is separated from the inside of a tile body 1, the plug body 51 is kept horizontal, an inserting plate at the front end of the plug body 51 is inserted into a butt joint end 8 on another tile body 1, the plug body 51 is kept to be electrically connected with the butt joint end 8, a heating transmission column 43 at one side of a heating transmission plate 42 is mutually butted with a heat transmission endpoint 7 in a heat transmission plate 6 on another tile body 1, after a butting wire 44 is electrified, the connecting wire 44 is mutually butted between the plug body 51 and the butt joint end 8, a connecting wire 44 in the two connected tile bodies 1 is electrified, and after the butting wire 44 is electrified, a heating resistor 41 starts to generate heat, heating resistor 41 upwards transmits the heat to the heating transfer plate 42 of top in, heating transfer plate 42 transmits the heat between two ceramic tile bodies 1 that link to each other through heating transfer post 43, heat transfer plate 42's rapid heating up with higher speed, simultaneously heating transfer plate 42 transmits heat behind the intermediate layer body 31, heat transfer post 33 is with heat transfer to ceramic tile body 1's top, intermediate layer body 31 further transmits the heat to heating strip 2 through heat transfer thin pole 34, make ceramic tile body 1's upper surface and heating strip 2 heat up rapidly, it can remain the heat to deposit warm hole 32 simultaneously, save required heating time when heating up once more in the short-term, this structure can realize the control regulation to the temperature, and the quick heat with the transmission.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be able to cover the technical solutions and the inventive concepts of the present invention within the technical scope of the present invention.

Claims

1. An instant-heating and temperature-controllable graphene heating ceramic tile floor heating system comprises a ceramic tile body (1), heating strips (2), a graphene interlayer (3), a heating inner plate (4), an insertion end (5), a heat transfer plate (6), a heat transfer end point (7) and a butt joint end (8), it is characterized in that the top end of the tile body (1) is provided with a heating strip (2), the heating strip (2) is fixedly connected with the tile body (1), a graphene interlayer (3) is arranged inside the tile body (1), a heating inner plate (4) is arranged below the graphene interlayer (3), an inserting end (5) is arranged on one side of the heating inner plate (4), one side of the heating inner plate (4) far away from the inserting end (5) is provided with a butt joint end (8), a heat transfer plate (6) is arranged above the butt joint end (8), and a heat transfer end point (7) is arranged on the outer side of the heat transfer plate (6).

2. The graphene heating tile floor heating system capable of controlling temperature instantly after opening and heating as claimed in claim 1, wherein the graphene interlayer (3) comprises an interlayer body (31), temperature storage holes (32), heat transfer columns (33) and heat transfer thin rods (34), the temperature storage holes (32) are formed in the interlayer body (31), the heat transfer columns (33) are fixedly mounted at the top end of the interlayer body (31), the top ends of the heat transfer columns (33) are in contact with the tile body (1), the heat transfer thin rods (34) are arranged between the heat transfer columns (33), the bottom ends of the heat transfer thin rods (34) are fixedly connected with the interlayer body (31), and the top ends of the heat transfer thin rods (34) are fixedly connected with the heating strips (2).

3. The graphene heating tile floor heating system capable of controlling temperature instantly when being turned on as claimed in claim 1, wherein the heating inner plate (4) comprises a heating resistor (41), a heating transfer plate (42), a heating transfer column (43) and a power connection wire (44), the top end of the heating resistor (41) is fixedly connected to the heating transfer plate (42), the heating transfer column (43) is fixedly connected to one side of the heating transfer plate (42), the heat transfer plate (6) is fixedly connected to one side of the heating transfer plate (42) far away from the heating transfer column (43), and the power connection wire (44) is arranged between the heating resistors (41).

4. The system of claim 1, wherein the insertion end (5) comprises a plug body (51), a receiving rotating shaft (52) and a positioning seat (53), the bottom end of the plug body (51) is penetrated by the receiving rotating shaft (52), two ends of the receiving rotating shaft (52) are movably mounted on the positioning seat (53), and the positioning seat (53) is fixedly mounted on the tile body (1).

5. The graphene heating tile floor heating system capable of controlling temperature instantly when being turned on as claimed in claim 4, wherein the plug body (51) is electrically connected with the power connection wire (44), the plug body (51) is movably mounted on the positioning seat (53) through the bearing rotating shaft (52), and a plug board at the front end of the plug body (51) is matched with a slot of the butt joint end (8).

6. The graphene heating tile floor heating system capable of controlling temperature instantly after being opened as claimed in claim 1, wherein the top of the heating strip (2) is flush with the top of the tile body (1), and the bottom end of the heating strip (2) is connected with the interlayer body (31) through a heat transfer thin rod (34).