CN210947561U - Heating floor system - Google Patents

Abstract

The utility model provides a heating floor system, which is provided with a floor component, a power supply part and a control part, wherein a plurality of heating floors of the floor component are detachably spliced in sequence, and the heating layers of two adjacent heating floors are electrically connected; the floor system comprises a plurality of floor components, a plurality of heating units and a plurality of control units, wherein the floor components are arranged side by side and are divided into a plurality of heating groups, and each heating group is provided with at least one floor component; a plurality of parallel power supply circuits of the power supply part are electrically connected with the plurality of heating groups in a one-to-one correspondence manner so as to independently supply power to each heating group through the power supply part; each power supply circuit is electrically connected with the control part so as to independently control the on-off and temperature of the circuit of each heating group through the control part. This scheme accessible control division independent control every generates heat the circuit break-make and the temperature of group to according to the condition of generating heat of every group that generates heat of indoor environment and user hobby independent control, thereby can realize diversified control, satisfy different users' user demand, improve user experience.

Description

Heating floor system

Technical Field

The utility model relates to a floor technical field particularly, relates to a floor system generates heat.

Background

In winter heating, floor heating is the main choice for pursuing home comfort in colder areas in winter. The ground heating is realized by uniformly heating the whole ground and conducting heat from bottom to top by utilizing the self heat storage and heat upward radiation rule of the ground so as to achieve the aim of heating. From the heat medium, generally warm up divide into water ground heating and electric ground heating. No matter the water floor heating or the electric floor heating, heating media need to be laid firstly, and then the floor is laid.

At present, a floor capable of self-heating after being electrified appears, and the floor has the function of heating. However, the structure of a plurality of heating floors in the prior art is arranged, so that the heating floor can be controlled integrally only during heating, and therefore, the control mode is single, and the diversified use requirements of users cannot be met.

SUMMERY OF THE UTILITY MODEL

The utility model provides a heating floor system to solve the single problem of the floor control mode that generates heat among the prior art.

In order to solve the above problem, the utility model provides a floor system generates heat, include: the floor component comprises a heating floor, the heating floor comprises a solid wood layer and a heating layer, the heating layer is made of a conductive material, the heating layer can generate heat under the condition of being electrified so as to heat the indoor environment, the heating floor is multiple, the heating floors are sequentially detachably spliced, and the heating layers of two adjacent heating floors are electrically connected; the floor board assembly comprises a plurality of floor board assemblies, the floor board assemblies are arranged side by side, the floor board assemblies are divided into a plurality of heating groups, and at least one floor board assembly is arranged in each heating group; the power supply part is provided with a plurality of power supply circuits which are arranged in parallel, and the power supply circuits are electrically connected with the heating groups in a one-to-one correspondence manner so as to independently supply power to each heating group through the power supply part; and each power supply circuit is electrically connected with the control part so as to independently control the on-off and temperature of the circuit of each heating group through the control part.

Further, each heating group comprises at least two floor assemblies, and the at least two floor assemblies in each heating group are arranged in parallel; the plurality of floor assemblies in the at least two heating groups are arranged alternately.

Further, the heat generating floor system further includes: the first temperature sensor is electrically connected with the control part and is used for measuring the temperature of the indoor environment; the plurality of second temperature sensors are electrically connected with the control part and are arranged corresponding to the plurality of heating groups in a one-to-one correspondence manner so as to respectively measure the temperature of each heating group; and the network module is electrically connected with the control part to transmit information.

Further, the heating floor further comprises a decorative surface layer, a first fiber reinforced layer, a second fiber reinforced layer, a heat preservation layer and a metal heat reflection layer, wherein the decorative surface layer, the second fiber reinforced layer, the solid wood layer, the first fiber reinforced layer, the heating layer, the heat preservation layer and the metal heat reflection layer are sequentially attached to each other, the heat preservation layer is made of heat preservation materials, and the metal heat reflection layer is used for reflecting electromagnetic waves radiated by the heating layer towards the metal heat reflection layer.

Further, the heating layer is made of a carbon fiber material or a graphene material, and the first fiber reinforced layer and the second fiber reinforced layer are made of glass fibers with an insulating effect.

Furthermore, the heating floor also comprises a conductive part, one end of the conductive part is connected with the heating layer, and the other end of the conductive part is positioned outside the side surface of the solid wood layer; in each of the floor panel assemblies, the two conductive portions of adjacent two heat emitting floor panels are connected to each other to achieve electrical connection of the two heat emitting floor panels.

Furthermore, the conductive part comprises a first conductive layer and a second conductive layer which are connected with each other, an included angle is formed between the first conductive layer and the second conductive layer, the first conductive layer is connected with the heating layer, the second conductive layer is positioned outside the side face of the solid wood layer, and in each floor component, the two second conductive layers of two adjacent heating floors are connected with each other.

Furthermore, two ends of the solid wood layer along the length direction of the solid wood layer are respectively provided with a first buckle structure and a second buckle structure, each heating floor comprises two conductive parts, and second ends of the two conductive parts are respectively positioned outside the side surface of the first buckle structure and outside the side surface of the second buckle structure; in two adjacent heating floors of each floor assembly, the first buckle structure of one heating floor is clamped with the second buckle structure of the other heating floor, and the second end of the conductive part of one heating floor is abutted against the second end of the conductive part of the other heating floor, so that the two heating floors are electrically connected.

Further, the floor assembly further comprises two conductive structures, the heating floors at the two ends of the floor assembly are divided into a first heating floor and a second heating floor, one conductive structure of the two conductive structures is arranged at the end part of the first heating floor and is electrically connected with the heating layer of the first heating floor, the other conductive structure of the two conductive structures is arranged at the end part of the second heating floor and is electrically connected with the heating layer of the second heating floor, and the two conductive structures are respectively connected with the positive pole and the negative pole of the power supply circuit corresponding to the floor assembly.

Further, the conductive structure comprises a plate-shaped part and a connecting part which are connected in sequence, the length direction of the connecting part is perpendicular to the surface of the plate-shaped part, the plate-shaped part is arranged on the installation bottom surface of the heating floor and is electrically connected with the heating layer of the heating floor, the connecting part is located at the end part of the heating floor, and the connecting part is used for being connected with a power supply circuit.

The technical scheme of the utility model is applied, a heating floor system is provided, a floor component, a power supply part and a control part are arranged in the heating floor system, wherein the floor component comprises a plurality of heating floors which are detachably spliced in sequence, and the heating layers of two adjacent heating floors are electrically connected; the floor board assembly comprises a plurality of floor board assemblies, wherein the floor board assemblies are arranged side by side, the floor board assemblies are divided into a plurality of heating groups, and each heating group is provided with at least one floor board assembly; the power supply part is provided with a plurality of power supply circuits which are arranged in parallel, and the power supply circuits are electrically connected with the heating groups in a one-to-one correspondence manner so as to independently supply power to each heating group through the power supply part; each power supply circuit is electrically connected with the control part so as to independently control the on-off and temperature of the circuit of each heating group through the control part. By adopting the technical scheme, the control part can independently control the on-off and the temperature of the circuit of each heating group, so that the heating condition of each heating group can be independently controlled according to the indoor environment and the user preference, thereby realizing diversified control, meeting the use requirements of different users and improving the user experience.

Drawings

The accompanying drawings, which form a part of the present application, are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the invention and not to limit the invention. In the drawings:

fig. 1 shows a schematic structural diagram of a heat-generating floor system provided by an embodiment of the present invention;

FIG. 2 shows a schematic structural view of the flooring assembly of FIG. 1;

FIG. 3 shows a schematic diagram of the conductive structure of FIG. 2;

FIG. 4 shows a schematic structural view of the heat generating floor of FIG. 2;

fig. 5 shows a partially enlarged view of the heat generating floor in fig. 4.

Wherein the figures include the following reference numerals:

100. a floor assembly; 10. a heating floor; 11. decorating the surface layer; 12. a second fiber-reinforced layer; 13. a solid wood layer; 131. a first snap structure; 132. a second snap structure; 133. a groove; 14. a first fiber-reinforced layer; 15. a heat generating layer; 16. a heat-insulating layer; 17. a metal heat reflective layer; 18. a conductive portion; 181. a second conductive layer; 182. a first conductive layer; 20. a conductive structure; 21. a plate-like member; 22. a connecting member; 221. a connecting plate; 222. a tubular member; 200. a power supply unit; 210. a power supply circuit; 300. a control unit; 400. a first temperature sensor; 500. and a network module.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention. It is to be understood that the embodiments described are only some embodiments of the invention, and not all embodiments. The following description of at least one exemplary embodiment is merely illustrative in nature and is in no way intended to limit the invention, its application, or uses. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

As shown in fig. 1 to 5, an embodiment of the present invention provides a heating floor system, including: the floor assembly 100 comprises a heating floor 10, the heating floor 10 comprises a solid wood layer 13 and a heating layer 15, the heating layer 15 is made of a conductive material, the heating layer 15 can generate heat under the condition of being electrified so as to heat the indoor environment, the heating floor 10 is provided with a plurality of heating floors 10, the heating floors 10 are detachably spliced in sequence, and the heating layers 15 of two adjacent heating floors 10 are electrically connected; the number of the floor assemblies 100 is multiple, the floor assemblies 100 are arranged side by side, the floor assemblies 100 are divided into a plurality of heating groups, and at least one floor assembly 100 is arranged in each heating group; a power supply unit 200, the power supply unit 200 having a plurality of power supply circuits 210 arranged in parallel, the plurality of power supply circuits 210 being electrically connected to the plurality of heat generating groups in a one-to-one correspondence, so that each heat generating group is independently supplied with power through the power supply unit 200; and a control part 300, wherein each power supply circuit 210 is electrically connected with the control part 300, so that the circuit on-off and the temperature of each heating group are independently controlled through the control part 300.

The technical scheme of the utility model is applied, a heating floor system is provided, a floor component 100, a power supply part 200 and a control part 300 are arranged in the heating floor system, wherein the floor component 100 comprises a plurality of heating floors 10, the heating floors 10 are detachably spliced in sequence, and the heating layers 15 of two adjacent heating floors 10 are electrically connected; the number of the floor assemblies 100 is multiple, the floor assemblies 100 are arranged side by side, the floor assemblies 100 are divided into a plurality of heating groups, and at least one floor assembly 100 is arranged in each heating group; the power supply part 200 has a plurality of power supply circuits 210 arranged in parallel, and the plurality of power supply circuits 210 are electrically connected with the plurality of heat generating groups in a one-to-one correspondence manner so as to independently supply power to each heat generating group through the power supply part 200; each power supply circuit 210 is electrically connected to the control unit 300 to independently control the on/off and temperature of each heat generating set through the control unit 300. By adopting the technical scheme, the circuit on-off and the temperature of each heating group can be independently controlled through the control part 300, so that the heating condition of each heating group can be independently controlled according to the indoor environment and the user preference, diversified control can be realized, the use requirements of different users can be met, and the user experience can be improved.

For example, the position with a bed or other furniture barriers can be kept without heating, and the heating temperature can be increased in the position where a user moves for a long time, so that the heating can be fully realized, and the energy can be saved.

In the present embodiment, each heat generating set includes at least two floor assemblies 100, and at least two floor assemblies 100 in each heat generating set are arranged in parallel; the plurality of floor modules 100 in at least two heat generating sets are arranged alternately. The arrangement can realize the effect of alternately arranging the plurality of floor assemblies 100 in the plurality of heating groups. Therefore, under the condition that the indoor environment temperature is not very low and large-area and large-scale heat supply is not needed, only a part of heating groups can be powered and heated, and other heating groups are not powered, and because the heating floor assemblies 100 are arranged at intervals, different areas of the indoor environment can be uniformly heated, and energy is saved. Therefore, diversified control can be realized, the use requirements of different environments are met, the user experience is improved, and the energy is saved while good heating is realized.

In this embodiment, the heat generating floor system further includes: a first temperature sensor 400, the first temperature sensor 400 being electrically connected to the control unit 300, the first temperature sensor 400 being used for measuring the temperature of the indoor environment; a plurality of second temperature sensors electrically connected to the control part 300, the plurality of second temperature sensors being disposed in one-to-one correspondence with the plurality of heat generating groups to measure a temperature of each heat generating group, respectively; and a network module 500, wherein the network module 500 is electrically connected with the control part 300 to transmit information. The temperature of the indoor environment can be measured by the first temperature sensor 400, the temperature of each heating group can be measured by the second temperature sensors, and the temperature can be known in time, so that the control and adjustment are convenient. Moreover, the network module 500 can be connected with other terminal devices, so that control is facilitated and convenience is improved. For example, the network module 500 is connected to a mobile phone, so that remote operation can be realized through the mobile phone, and user experience is improved.

In this embodiment, the heating floor 10 further includes a decorative surface layer 11, a first fiber reinforced layer 14, a second fiber reinforced layer 12, a heat insulation layer 16 and a metal heat reflection layer 17, wherein the decorative surface layer 11, the second fiber reinforced layer 12, the solid wood layer 13, the first fiber reinforced layer 14, the heating layer 15, the heat insulation layer 16 and the metal heat reflection layer 17 are sequentially attached to each other, the heat insulation layer 16 is made of a heat insulation material, and the metal heat reflection layer 17 is used for reflecting electromagnetic waves radiated from the heating layer 15 toward the metal heat reflection layer 17. By adopting the scheme, the strength of the heating floor 10 can be improved through the first fiber reinforced layer 14 and the second fiber reinforced layer 12, and moreover, the heat insulation layer 16 and the metal heat reflection layer 17 are arranged, so that the heat transfer to the lower part of the heating floor can be weakened, most of the heat is transferred to the upper part of the floor for indoor heating, the heat utilization rate is improved, and the energy is saved. The heating floor 10 in the scheme does not distinguish the positive electrode and the negative electrode, and after the two ends of the heating floor 10 are connected with an external circuit, the two ends respectively become the positive electrode and the negative electrode, so that the heating floor is convenient to be connected with the circuit.

Alternatively, the first fiber-reinforced layer 14 is made of glass fibers having an insulating effect, and the second fiber-reinforced layer 12 is made of glass fibers having an insulating effect. The glass fiber has good toughness and strength, so that the strength and the long-term use stability of the heating floor 10 can be improved. Moreover, the materials have an insulating effect, so that the safety of the heating floor 10 is improved. Moreover, after the floor is reinforced, the lower floor with the same strength can be thinner, and the heat conduction effect is better.

Alternatively, the heat generating layer 15 is made of a carbon fiber material or a graphene material. The materials have high strength and good electrical conductivity, and can improve the heat productivity of the heating layer 15, thereby improving the energy utilization rate and the performance of the heating floor.

In the present embodiment, the resistance of the heat generating layer 15 ranges from 15 Ω to 60 Ω. Through the arrangement, the heating layer 15 can be used for heating the floor more reasonably when the floor normally works, and the body feeling comfort of a user is improved.

In this embodiment, the insulating layer 16 is made of cork or foam. The materials have good heat preservation effect and low cost.

In this embodiment, the decorative face layer 11 is made of a solid wood skin and the metallic heat reflective layer 17 is made of an aluminum film. The decorative surface layer 11 is made of solid wood skin, so that the texture and the aesthetic degree of the heating floor can be improved. The metal heat reflecting layer 17 is made of an aluminum film, which can achieve a good effect of reflecting heat radiation.

In the present embodiment, the heat generation floor 10 further includes a conductive portion 18, one end of the conductive portion 18 is connected to the heat generation layer 15, and the other end of the conductive portion 18 is located outside the side surface of the solid wood layer 13; in each floor panel assembly 100, the two conductive portions 18 of the adjacent two heat generation floor panels 10 are connected to each other to achieve electrical connection of the two heat generation floor panels 10. In this way, the plurality of heating floors 10 can be spliced in the same way as the existing common floor, and the electric connection of different heating floors 10 can be realized without additional operation while splicing. Therefore, the installation is simple.

Specifically, the conductive portion 18 includes a first conductive layer 182 and a second conductive layer 181 which are connected to each other, and an included angle is formed between the first conductive layer 182 and the second conductive layer 181, wherein the first conductive layer 182 is connected to the heat generating layer 15, the second conductive layer 181 is located outside the side surface of the solid wood layer 13, and in each floor board assembly 100, two second conductive layers 181 of two adjacent heat generating floor boards 10 are connected to each other. Thus, the first conductive layer 182 can be electrically connected with the heat generating layer 15, and then the second conductive layer 181 can be electrically connected with other heat generating floors 10. In this way, the plurality of heating floors 10 can be spliced in the same way as the existing common floor, and the electric connection of different heating floors 10 can be realized without additional operation while splicing.

Optionally, an elastic structure is disposed between the side surface of the solid wood layer 13 of the heating floor 10 and the second conductive layer 181, so that when the second conductive layers 181 of the two heating floors 10 are in contact, the two second conductive layers 181 can be pressed against each other by the elastic force of the elastic structure, thereby improving the reliability of connection and avoiding the problem of poor contact. The elastic structure can be made of metal or rubber.

In this embodiment, the two ends of the solid wood layer 13 along the length direction thereof are respectively provided with a first buckling structure 131 and a second buckling structure 132, each heating floor 10 includes two conductive parts 18, and the second ends of the two conductive parts 18 are respectively located outside the side surface of the first buckling structure 131 and outside the side surface of the second buckling structure 132; in two adjacent heating floor boards 10 of each floor board assembly 100, the first snap structure 131 of one heating floor board 10 is snapped with the second snap structure 132 of the other heating floor board 10, and the second end of the conductive part 18 of one heating floor board 10 abuts against the second end of the conductive part 18 of the other heating floor board 10, so as to realize the electrical connection of the two heating floor boards 10. By adopting the arrangement, the sequential connection of the heating floors 10 can be realized by a buckle connection mode, the connection is reliable, and the installation is convenient. Moreover, the connection is realized while the different heating floors 10 are electrically connected, and the connection is simple and convenient.

In this embodiment, the floor panel assembly 100 further includes two conductive structures 20, the heating floor panels 10 at two ends of the floor panel assembly 100 are divided into a first heating floor panel 10 and a second heating floor panel 10, one conductive structure 20 of the two conductive structures 20 is disposed at an end of the first heating floor panel 10 and electrically connected to the heating layer 15 of the first heating floor panel 10, the other conductive structure 20 of the two conductive structures 20 is disposed at an end of the second heating floor panel 10 and electrically connected to the heating layer 15 of the second heating floor panel 10, and the two conductive structures 20 are respectively connected to a positive electrode and a negative electrode of the power supply circuit 210 corresponding to the floor panel assembly 100. Like this a plurality of heating floor 10 can realize the electricity of the layer that generates heat in a plurality of heating floor 10 through the concatenation in order and connect, then through two conducting structure 20 respectively with external circuit's positive pole and negative pole be connected, alright realize the equipment and the circuit connection of a plurality of heating floor 10, simplified installation operation.

Specifically, the conductive structure 20 includes a plate-shaped member 21 and a connecting member 22 connected in sequence, the connecting member 22 is disposed in a length direction perpendicular to a surface of the plate-shaped member 21, the plate-shaped member 21 is disposed on an installation bottom surface of the heating floor 10, the plate-shaped member 21 is electrically connected to the heat generating layer 15 of the heating floor 10, the connecting member 22 is located at an end portion of the heating floor 10, and the connecting member 22 is used for connecting to the power supply circuit 210. Due to the arrangement, the floor assembly 100 can be conveniently connected with a circuit, and the conductive structure 20 occupies a small space after being installed, so that the appearance is not influenced.

Alternatively, the plate member 21 has a connection hole, the floor panel assembly 100 further includes a fastening member which passes through the connection hole to be connected with the heat generating floor 10, and the plate member 21 is electrically connected with the heat generating layer 15 by the fastening member; the connecting member 22 includes a connecting plate 221 and a cylindrical member 222, the connecting plate 221 is connected with the plate-shaped member 21, the length direction of the connecting plate 221 is perpendicular to the surface of the plate-shaped member 21, the cylindrical member 222 is disposed on the connecting plate 221, a notch is disposed on the side wall of the cylindrical member 222 along the axial direction, the cylindrical member 222 is used for being sleeved on the electric wire of the external circuit to be electrically connected with the external circuit, and the opening of the notch is adjustably set so that the side wall of the cylindrical member 222 clamps the electric wire. In this way, the plate-like member 21 is fixed to the heat generation floor 10 by the fastening member, and the plate-like member 21 is electrically connected to the heat generation layer 15 of the heat generation floor 10. Further, by adjusting the size of the opening of the notch of the cylindrical member 222, the side wall of the cylindrical member 222 can be made to clamp the electric wire, thereby improving the reliability of connection.

Optionally, the solid wood layer 13 has a plurality of grooves 133, the plurality of grooves 133 are spaced apart along the length of the solid wood layer 13, the notches of a part of the plurality of grooves 133 are disposed toward the first fiber reinforced layer 14, and the notches of another part of the plurality of grooves 133 are disposed toward the second fiber reinforced layer 12. Through setting up a plurality of recesses 133 can play stress release's effect when the inside emergence of wood layer 13 is out of shape to the stability of leveling and long-term use of wood layer and the floor that generates heat has been guaranteed.

In order to facilitate understanding of the present embodiment, a flow of a manufacturing process of the heat generating floor panel 10 in the floor panel assembly will be described.

1. The front and back surfaces of the dried (moisture is controlled within 10%) wood core material are cut off part of wood fiber by the integrated saw blade to reduce the deformation risk;

2. the method comprises the steps that (1) a wooden core material is coated with environment-friendly melamine modified hot-pressing glue on two sides through a roller coater, then glass fiber felts are pasted on the two sides of the wooden core material, then air is discharged through cold pressing for 30 minutes to enable the glue to be fully bonded, and then the wooden core material is placed into a hot press (with the temperature of 120 MPa and the pressure of 15MPa) to be hot-pressed for 15 minutes to form a high-strength glass fiber deformation-resistant;

3. the high-strength glass fiber anti-deformation base material is coated with environment-friendly melamine modified hot-pressing glue on two sides by a roller coater, the front surface of the base material is pasted with a decorative surface layer (the thickness of a solid wood veneer used in the case is 0.3-5 mm), the back surface of the base material is pasted with a carbon fiber chopped felt heating layer (the resistance is 30 +/-3 omega is optimized), then the base material is cold-pressed for 30 minutes to discharge air so that the glue is fully adhered, and then the base material is placed into a hot press (the temperature is 120 MPa and the pressure is 15MPa) to be hot-pressed for 15 minutes to form;

4. milling two ends (commonly called short sides) of an electric heating floor blank into the shape of a conductive lock catch by using a double-end milling machine tool, and then covering graphene conductive paper at a folded angle at the bottom of the conductive lock catch and a heating layer of carbon fiber chopped felt by using a film covering machine, so that the individual and the individual can be spliced and electrically conducted (the internal gap of the lock catch after splicing the two ends is controlled within 20 filaments);

5. milling two sides (commonly called long sides) of the electric heating floor blank into lock catches, namely, semi-finished products of the electric heating floor by using a four-side planer machine tool for molding;

6. covering the back surface (the heating layer surface of the carbon fiber chopped strand felt) of the semi-finished product of the electric heating floor with a heat-insulating layer (an XPE foaming film or a cork thin skin is used in the scheme), sealing the heating layer, using the graphene conductive paper with the empty end part as a conductive piece, covering an aluminum foil with a film covering machine as a reflecting layer, reflecting the heat to the front surface, and further preventing the heat loss;

7. the painting machine assembly line is used for finishing the painting of a decorative surface layer (the painting surface has a waterproof function) of a semi-finished product of the electric heating floor, the sealing of paint and wax on two long sides and the finishing of the high-strength solid wood (multilayer solid wood) low-temperature electric heating floor.

Through the process flow, the automatic assembly line production of the heating floor can be realized, the labor consumption is reduced, the production efficiency is greatly improved, and the quality uniformity is ensured.

The process flow applied to the solid wood floor, the reinforced floor, the pvc, spc and wpc floor is as follows:

(for example, the flow of ' solid wood flooring ', reinforced flooring ' and ' pvc, spc, wpc flooring ' can omit finish paint process).

1. Milling the dried and water-balanced (the water content is controlled within 10%) floor blank into the shape of conductive lock catches at two ends by using a double-end milling machine (the internal clearance of the lock catches after the two ends are spliced is controlled within 20 filaments), and milling the lock catches at two sides of the floor blank into a semi-finished floor by using a four-side milling machine;

2. the method comprises the following steps of (1) rolling environmental-friendly melamine modified hot-pressing glue on the back surface of a semi-finished floor product by using a roller coater (because the glue coating amount of two materials pressed and pasted at the same time is slightly large), cold pressing for 30 minutes after a first layer of glass fiber felt and a second layer of carbon fiber chopped strand felt heating layer (the resistance is 30 omega) to discharge air so as to enable the glue to be fully bonded, and then putting the glue into a hot press (the temperature is 120 and the pressure is 15Mpa) for hot pressing for 15 minutes;

3. then covering graphene conductive paper at the folded angle at the bottom of the conductive lock catch and the carbon fiber chopped felt heating layer by a film covering machine, so that the individual can be spliced and electrically conducted;

4. covering the back surface (the heating layer surface of the carbon fiber chopped felt) of the semi-finished product of the electric heating solid wood floor with a heat-insulating layer (XPE foaming film or cork thin skin is used in the scheme), sealing the heating layer, using the hollow end part of the graphene conductive paper as a conductive piece, covering an aluminum foil with a film covering machine as a reflecting layer, reflecting the heat to the front surface, and further preventing the heat loss;

5. the painting machine assembly line is used for finishing the painting of a decorative surface layer (the painting surface has a waterproof function) of a semi-finished product of the electric heating floor, the sealing of the two long sides with paint and sealing wax, and the production of the solid wood low-temperature electric heating floor.

In this embodiment, the decorative surface layer may be replaced by "technical wood artificial veneer 0.3-5 mm", "melamine decorative paper", "polyvinyl chloride decorative paper", "wood fiber decorative paper", "cork veneer", "artificial leather", "animal leather", "marble sheet", "ceramic tile sheet", or the like.

The first fiber reinforced layer or the second fiber reinforced layer of the scheme can be replaced by glass fiber woven cloth, polyester woven cloth, aramid woven cloth, cotton woven cloth, melamine paper, polyvinyl chloride resin film, polyethylene resin film, polypropylene resin film, polystyrene resin film and the like.

The heating layer of the scheme can be replaced by carbon fiber woven cloth, carbon fiber non-woven paper, graphene conductive paper, nickel-chromium foil, nickel-chromium wire, carbon fiber wire, silicon crystal coating, graphite coating and the like.

The conductive part in the scheme can be replaced by copper foil, aluminum foil, carbon fiber non-woven paper, carbon fiber woven cloth and the like.

The melamine modified glue in the scheme can replace formaldehyde-free formaldehyde glue and benzene glue such as epoxy soybean glue and deodorized epoxy soybean glue.

The scheme is a decorative floor heating product integrating diversified styles, decoration, stable performance, overall heating, heat reflection and heat preservation, ① is provided with a conductive interface (namely a conductive part) special for a floor, so that the number of leads is greatly reduced, the safety risk is reduced, the mounting mode is almost the same as that of a common floor, floor heating and floor mounting are completed in one step, the construction procedure is simplified, the construction period is shortened, and the cost is saved, ② is high in heating speed, the floor is integrally heated to 20 ℃ in 10-15 minutes, namely, the floor is heated in multiple gears, and the heating in the specified region can be coded during mounting, so that the purposes of high efficiency, timeliness and energy saving are achieved, the use cost is reduced, ③ is used for solving the problems that a solid wood core material is easy to deform and crack after long-time heating, the internal stress of wood is reduced by cutting off wood fibers in sections, high-strength glass fibers are respectively pressed on the front side and the back side to reinforce the stability and the strength of a felt core material.

The utility model discloses cover conducting material and connect the layer that generates heat in the conductive part bottom at the floor both ends that generate heat, the floor itself that generates heat does not distinguish positive negative pole, and top-down roughly can divide into: decorative surface layer, glass fiber reinforced layer, wooden core, glass fiber insulating layer, low temperature layer, heat preservation, heat reflection layer.

The utility model discloses cooperate dedicated "T shape binding post" in the installation and go into the electrically conductive work that the electrically conductive portion can accomplish whole vertical retort at the head and the tail both ends card of whole vertical retort (be floor subassembly promptly). When the conductive part is installed, sealing glue is coated on the upper part of the conductive part to prevent water and electric leakage. When the floor is laid, a plurality of vertical strip-shaped floor components are arranged, each floor component can be numbered and separately powered, the specified area is heated or opened at intervals in a heat preservation state through software, unnecessary heating areas under furniture such as beds and wardrobes can be omitted, and the purpose of energy conservation is achieved.

The utility model discloses applied glass fiber strengthening resistance to deformation and with the layer of generating heat insulation in wood (multilayer wood). The utility model discloses improve into electrically conductive hasp and can use on the knot type of any kind of hasp at ordinary hasp on the floor. The utility model discloses a design collection is decorated, is generated heat, heat reflection, heat preservation and stable performance in product of an organic whole. The utility model discloses a "graphite alkene conducting paper" is at this kind of design of "carbon fiber felt layer that generates heat" as electrically conductive tectorial membrane, and production is simple and convenient, and volume production efficiency is high.

The utility model discloses different according to the specification of product thickness, the earth's surface speed of generating heat is about 3 ~ 15 minutes can reach more than 25 degrees, and the core is thinner the more fast with the architectural surface layer speed of generating heat. The hot-pressing glue used in the utility model has the advantages of water resistance, insulation, high curing speed, long-term heat supply stability, no degumming and the like.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. A heat generating flooring system, comprising:

the floor assembly (100), the floor assembly (100) includes the floor (10) that generates heat, the floor (10) that generates heat includes solid wood layer (13) and layer (15) that generates heat, the layer (15) that generates heat is made by conducting material, the layer (15) that generates heat can produce heat in order to heat the indoor environment under the circumstances of circular telegram, the floor (10) that generates heat is a plurality of, a plurality of the floor (10) that generates heat detachably splice in proper order, and two adjacent floor (10) that generate heat layer (15) electricity are connected;

the number of the floor assemblies (100) is multiple, the floor assemblies (100) are arranged side by side, the floor assemblies (100) are divided into multiple heating groups, and at least one floor assembly (100) is arranged in each heating group;

a power supply unit (200), wherein the power supply unit (200) has a plurality of power supply circuits (210) arranged in parallel, and the plurality of power supply circuits (210) are electrically connected with the plurality of heat generating groups in a one-to-one correspondence manner so as to independently supply power to each heat generating group through the power supply unit (200);

the control part (300), each power supply circuit (210) is electrically connected with the control part (300) so as to independently control the circuit on-off and the temperature of each heating group through the control part (300).

2. The heat generating flooring system of claim 1,

each heating group comprises at least two floor assemblies (100), and the at least two floor assemblies (100) in each heating group are arranged in parallel;

the floor components (100) in at least two heating groups are arranged alternately.

3. The heat generating flooring system as recited in claim 2, further comprising:

a first temperature sensor (400), the first temperature sensor (400) being electrically connected to the control unit (300), the first temperature sensor (400) being configured to measure a temperature of an indoor environment;

a plurality of second temperature sensors electrically connected to the control unit (300), the plurality of second temperature sensors being disposed in one-to-one correspondence with the plurality of heat generating groups to measure the temperature of each of the heat generating groups, respectively;

a network module (500), the network module (500) being electrically connected with the control part (300) to transmit information.

4. The heating floor system according to claim 1, wherein the heating floor (10) further comprises a decorative surface layer (11), a first fiber reinforced layer (14), a second fiber reinforced layer (12), a heat insulating layer (16) and a metal heat reflecting layer (17), the decorative surface layer (11), the second fiber reinforced layer (12), the solid wood layer (13), the first fiber reinforced layer (14), the heating layer (15), the heat insulating layer (16) and the metal heat reflecting layer (17) are sequentially laminated, the heat insulating layer (16) is made of a heat insulating material, and the metal heat reflecting layer (17) is used for reflecting electromagnetic waves radiated from the heating layer (15) toward the metal heat reflecting layer (17).

5. The heat generating flooring system as recited in claim 4, wherein the heat generating layer (15) is made of a carbon fiber material or a graphene material, and the first fiber-reinforced layer (14) and the second fiber-reinforced layer (12) are each made of glass fiber having an insulating effect.

6. The heat generating floor system according to claim 1, wherein the heat generating floor (10) further comprises a conductive portion (18), one end of the conductive portion (18) is connected to the heat generating layer (15), and the other end of the conductive portion (18) is located outside a side surface of the solid wood layer (13); in each floor assembly (100), two conductive parts (18) of two adjacent heating floors (10) are connected with each other to realize the electric connection of the two heating floors (10).

7. The heat generating flooring system according to claim 6, wherein said conductive portion (18) comprises a first conductive layer (182) and a second conductive layer (181) connected to each other, said first conductive layer (182) and said second conductive layer (181) having an angle therebetween, wherein said first conductive layer (182) is connected to said heat generating layer (15), said second conductive layer (181) is located outside of the side of said solid wood layer (13), and in each of said flooring assemblies (100), two second conductive layers (181) of adjacent two of said heat generating floorings (10) are connected to each other.

8. The heat generating flooring system of claim 6,

a first buckling structure (131) and a second buckling structure (132) are respectively arranged at two ends of the solid wood layer (13) along the length direction of the solid wood layer, each heating floor (10) comprises two conductive parts (18), and second ends of the two conductive parts (18) are respectively positioned outside the side surface of the first buckling structure (131) and outside the side surface of the second buckling structure (132);

every two adjacent of floor subassembly (100) in heating floor (10), one first buckle structure (131) and another of heating floor (10) second buckle structure (132) joint of heating floor (10), and one the second end of the conductive part (18) on heating floor (10) and another the second end butt of the conductive part (18) on heating floor (10) to realize two the electricity of heating floor (10) is connected.

9. The heat generating flooring system as recited in claim 1, wherein said flooring assembly (100) further comprises two conductive structures (20), heating floor (10) at the both ends of floor subassembly (100) divide into first heating floor (10) and second heating floor (10), two a conducting structure (20) in conducting structure (20) sets up the tip on first heating floor (10) and with the layer (15) electricity that generates heat on first heating floor (10) is connected, two another conducting structure (20) in conducting structure (20) set up the tip on second heating floor (10) and with the layer (15) electricity that generates heat on second heating floor (10) is connected, two conducting structure (20) respectively with floor subassembly (100) corresponds the positive pole and the negative pole of supply circuit (210) are connected.

10. A heat generation floor system according to claim 9, characterized in that the conductive structure (20) comprises a plate-like member (21) and a connecting member (22) connected in series, the length direction of the connecting member (22) is arranged perpendicularly with respect to the surface of the plate-like member (21), the plate-like member (21) is arranged on the installation bottom surface of the heat generation floor (10), and the plate-like member (21) is electrically connected with the heat generation layer (15) of the heat generation floor (10), the connecting member (22) is arranged at the end of the heat generation floor (10), and the connecting member (22) is used for connecting with the power supply circuit (210).

Images