CN214034557U - Heating floor - Google Patents

Abstract

A heating floor comprises a surface layer, an alloy layer and a heating layer. The alloy layer is sandwiched between the surface layer and the heat generating layer to diffuse heat. The heating layer comprises a base body, a heating component and a joggle structure. The heating component comprises an electrifying heating layer, a conductive terminal and an electrifying connecting piece, and the conductive terminal has attraction. The energizing connection includes two energizing terminals. The energizing terminals have an absorption force. And the two joggle structures are respectively provided with a through hole. The conductive terminal is arranged in the through hole. One of the two electrified terminals is inserted in the through hole and connected with the corresponding conductive terminal under the action of attractive force. When the heating floor is assembled, the power-on connecting pieces are only required to be inserted into the two through holes respectively, the conductive terminals and the power-on terminals are attracted together under the action of the mutual absorption force to complete conduction, and therefore the heating floor is very convenient to assemble and favorable for popularization and use.

Description

Heating floor

Technical Field

The utility model belongs to the technical field of the floor, especially a floor generates heat.

Background

The heating floor is a floor capable of heating as the name implies, and can provide heat for a house. The floor board as one kind of functional floor board has no difference in appearance from common floor board, and has one built-in electric heating layer.

According to the current patent CN201679208U, the heating floor comprises a floor shell, a floor, electric heating pieces, a power input connecting line, a power output connecting line, a heat preservation cotton layer and the like, wherein a heat preservation layer and the electric heating pieces are laid in the floor, and the heating floor consisting of the power input connecting line and the power output connecting line is arranged on the electric heating pieces. Heat generation occurs after energization. However, after the existing heating floors are spliced, the joints connected by the two heating floors are poor in waterproofness and unstable in structure.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model provides a can solve current problem heating floor to satisfy above-mentioned demand.

A heating floor comprises a surface layer, an alloy layer connected with the surface layer, and a heating layer connected with the alloy layer. The alloy layer is sandwiched between the surface layer and the heat generating layer to diffuse heat. The heating layer comprises a base body, a heating component embedded in the base body and two joggle structures respectively arranged on two sides of the base body. The heating component comprises an electrified heating layer, two conductive terminals which are respectively arranged at two sides of the electrified heating layer and are electrically connected with the electrified heating layer, and an electrified connecting piece which is electrically connected with the conductive terminals, wherein the conductive terminals have attraction. The energizing connection includes two energizing terminals. The energizing terminals have an absorption force. And the two joggle structures are respectively provided with a through hole. The conductive terminal is arranged in the through hole. One of the two electrified terminals is inserted in the through hole and connected with the corresponding conductive terminal under the action of attractive force.

Further, the heating floor also comprises a bottom layer connected with the heating layer, and the bottom layer is arranged on the other side, opposite to the alloy layer, of the heating layer.

Further, the bottom layer comprises a heat insulation layer, and the heat insulation layer is directly connected with the heating layer.

Furthermore, the bottom layer also comprises a silencing layer, and the silencing layer is directly connected with the heat insulation layer.

Further, the sound-deadening layer is made of a fiber web.

Further, the area of the electrified heating layer is smaller than that of the surface layer.

Furthermore, the electrified heating layer contains one or two of carbon fiber, graphene and resistance wire.

Further, the area of the alloy layer is equivalent to the area of the surface layer.

Furthermore, the conductive terminal and the power-on terminal are both conductive suckers.

Compared with the prior art, the utility model provides a floor generates heat is through setting up the heating element on the layer that generates heat to when providing electric power for it, circular telegram among the heating element generate heat the layer alright with produce heat, and then can provide the heat for this floor generates heat. Meanwhile, as the tenon joint structure of the heating layer is provided with the through hole, when the two heating floors are combined together, the conductive terminal and the power-on terminal are accommodated in the through hole, so that water cannot reach the conductive terminal and the power-on terminal immediately when leaking, and the waterproof grade can be improved. In addition, due to the structural design, only two through holes need to be formed in the base body of the heating layer during manufacturing, the power-on connecting pieces only need to be inserted into the two through holes respectively during assembly, then the corresponding joggle joint structures are connected together, and the conductive terminals and the power-on terminals are attracted together under the action of mutual absorption force to complete conduction.

Drawings

Fig. 1 is a schematic view of an exploded cross-sectional structure of the heating floor provided by the present invention.

Fig. 2 is a partially enlarged view of the heat emitting floor of fig. 1 at a.

Detailed Description

Specific examples of the present invention will be described in further detail below. It should be understood that the description herein of embodiments of the invention is not intended to limit the scope of the invention.

As shown in fig. 1 and fig. 2, it is a schematic structural diagram of a heating floor provided by the present invention. The heating floor comprises a surface layer 10, an alloy layer 20 connected with the surface layer 10, a heating layer 30 connected with the alloy layer 20, and a bottom layer 40 connected with the heating layer 30. It is contemplated that the heat-generating floor may further include other functional layers, such as paint layers, etc., which are well known to those skilled in the art and will not be described in detail herein.

The surface layer 10 is a use surface, i.e. a side facing indoors when laid on the ground. The surface layer 10 may be made of solid wood material, or may be made of composite material such as stone plastic material or PVC material, which may be selected according to actual needs. The thickness of the surface layer 10 is generally small, such as 10 to 15 mm. It is of course conceivable that the surface layer 10 can be provided with various patterns. At the same time, a paint layer should be provided on the surface layer 10.

The alloy layer 20 may be made of an aluminum alloy for diffusing heat, and therefore, the area of the alloy layer 20 should be equivalent to that of the surface layer 10 so that heat can be obtained at all portions of the surface layer 10. The alloy layer 20 and the surface layer 10 are glued together by a low temperature glue. The low-temperature glue is used for gluing the alloy layer 20 and the surface layer 10, so that the influence of high temperature on the surface layer 10 can be avoided.

The heat-generating layer 30 includes a base 31, a heat-generating component 32 embedded in the base 31, and two joggle structures 33 respectively disposed on two sides of the base 31. The substrate 31 is sandwiched between the alloy layer 20 and the bottom layer 40, and may be made of solid wood or composite material, and the area of the substrate 31 is equivalent to the area of the surface 10. The base 31 is provided with a cavity. The heating assembly 32 includes an electric heating layer 321 disposed in the cavity of the base 31, two conductive terminals 322 disposed on two sides of the electric heating layer 321 and electrically connected to the electric heating layer 321, and an electric connecting member 323 electrically connected to the conductive terminals 322. The electrified heating layer 321 may be rectangular or square, and the shape of the electrified heating layer 321 should be the same as the shape of the heating floor, however, the area of the electrified heating layer 321 is smaller than the area of the surface 10, and four sides of the electrified heating layer 321 are spaced from four sides of the base 30, so as to prevent the two electrified heating layers 321 from being damaged due to the communication of water when water enters between the two heating floors. The electrified heating layer 321 contains one or two of carbon fiber, graphene and resistance wire, and can heat when electrified. The conductive terminal 322 is electrically connected to the conductive heating layer 321 through a conductive wire. The conductive terminal 322 has an attractive force, and specifically, the conductive terminal 322 may be a conductive chuck. The conductive suction cup is per se prior art, which has suction. The energizing connector 323 includes two energizing terminals 324 and a wire 325 connecting the two energizing terminals 324. The power-on terminal 324 has the same structure and operation principle as the conductive terminal 322, and is also a conductive chuck, i.e. has an absorption force. The conductive terminals 322 and the energizing terminals 324 may be attracted together to conduct electricity. The wire 325 is connected between the two energizing terminals 324 to make electrical connection. It is contemplated that the length of the wire 325 should be consistent with the length requirement, i.e., it is avoided that the wire 325 does not get folded when two heat emitting floors are combined together, thereby avoiding affecting the combination between the heat emitting floors. The mortise structure 33 includes a tenon provided at one side of the base 31 and a mortise provided at the other side of the base 31, but is prior art in itself and thus will not be described in detail herein. A through hole 331 is formed on each of the two tenon structures 33. The conductive terminal 322 is accommodated in the through hole 331 while one of the two energizing terminals 324 is accommodated in the through hole 331, and the conductive terminal 322 and the energizing terminal 324 are connected together by an attractive force. When two heat generating floors are combined, the other of the two energizing terminals 324 is inserted into the through hole 331 of the mortise structure 33 of the other heat generating floor, so that the two heat generating floors can be electrically connected together.

The base layer 40 is disposed on the other side of the heat generating layer with respect to the alloy layer. The bottom layer 40 includes an insulating layer 41 and a silencing layer 42 connected to the insulating layer 41. The insulating layer 41 is directly connected to the heat generating layer 30, and may be made of a hard material to provide strength to the heat generating floor. The insulating layer 41 is disposed between the heat generating layer 30 and the silencing layer 42. The sound-deadening layer 42 is directly connected to the heat-insulating layer 41 and is made of a fiber net for contacting the ground or a keel to prevent a sound from being generated when a person walks thereon.

Compared with the prior art, the utility model provides a floor generates heat is through setting up heating element 32 on the layer that generates heat to when for it provides electric power, circular telegram among the heating element 32 generates heat layer 321 alright with producing heat, and then can provide the heat for this floor generates heat. Meanwhile, as the tenon structure 33 of the heating layer 30 is provided with the through hole 331, when the two heating floors are combined together, the conductive terminal 322 and the power-on terminal 324 are both accommodated in the through hole 331, so that water cannot reach the conductive terminal 322 and the power-on terminal 324 immediately when leaking, and the waterproof grade can be improved. In addition, due to the structural design, only two through holes 331 need to be formed in the base 31 of the heating layer 30 during manufacturing, the power-on connecting pieces 33 only need to be inserted into the two through holes 331 respectively during assembly, then the corresponding joggle structures 33 are connected together, and at the moment, the conductive terminals 322 and the power-on terminals 324 are attracted together under the action of mutual absorption force to complete conduction, so that the heating floor is very convenient to assemble and is beneficial to popularization and use.

The above description is only for the preferred embodiment of the present invention and should not be construed as limiting the scope of the present invention, and any modification, equivalent replacement or improvement within the spirit of the present invention is encompassed by the claims of the present invention.

Claims (8)

1. A heating floor is characterized in that: the heating floor comprises a surface layer, an alloy layer connected with the surface layer and a heating layer connected with the alloy layer, wherein the alloy layer is clamped between the surface layer and the heating layer to diffuse heat, the heating layer comprises a base body, a heating component embedded in the base body and two tenon structures respectively arranged at two sides of the base body, the heating component comprises an electrified heating layer, two conductive terminals respectively arranged at two sides of the electrified heating layer and electrically connected with the electrified heating layer and an electrified connecting piece electrically connected with the conductive terminals, the conductive terminals have attraction, the electrified connecting piece comprises two electrified terminals, the electrified terminals have absorption force, a through hole is respectively arranged on each of the two tenon structures, and the conductive terminals are arranged in the through holes, one of the two electrified terminals is inserted in the through hole and connected with the corresponding conductive terminal under the action of attractive force.

2. The heat-generating floor as claimed in claim 1, wherein: the heating floor further comprises a bottom layer connected with the heating layer, and the bottom layer is arranged on the other side, opposite to the alloy layer, of the heating layer.

3. A heat generating floor as claimed in claim 2, wherein: the bottom layer comprises a heat-insulating layer, and the heat-insulating layer is directly connected with the heating layer.

4. A heat generating floor as claimed in claim 3, wherein: the bottom layer also comprises a mute layer, and the mute layer is directly connected with the heat-insulating layer.

5. The heat-generating floor as claimed in claim 4, wherein: the mute layer is made of a fiber web.

6. The heat-generating floor as claimed in claim 1, wherein: the area of the electrified heating layer is smaller than that of the surface layer.

7. The heat-generating floor as claimed in claim 1, wherein: the area of the alloy layer is equivalent to the area of the surface layer.

8. The heat-generating floor as claimed in claim 1, wherein: the conductive terminals and the power-on terminals are conductive suckers.

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