CN215446619U - Steel fiber graphite conductive self-heating floor structure - Google Patents

Abstract

The utility model discloses a steel fiber graphite conductive self-heating floor structure, and belongs to the technical field of building floors. This electrically conductive self-heating floor structure of steel fibre graphite includes: the steel fiber graphite layer is arranged on the concrete base layer and electrically connected with a current controller, the current controller is electrically connected with a master controller, and the master controller is electrically connected with a power supply device; the heat conduction water pipe is laid on the steel fiber graphite layer, the heat conduction water pipe is a closed self-circulation heat conduction water pipe, one end of the heat conduction water pipe is communicated with a water inlet of the water pump, a water outlet of the water pump is communicated with the other end of the heat conduction water pipe, liquid is arranged in the heat conduction water pipe, and the water pump is electrically connected with the master controller; the decorative plate is arranged on the heat conduction water pipe. The steel fiber graphite conductive self-heating floor structure provided by the utility model can not only heat the indoor through self-heating, but also improve the phenomenon of uneven floor heating, thereby improving the comfort of the indoor environment.

Description

Steel fiber graphite conductive self-heating floor structure

Technical Field

The utility model relates to the technical field of building floors, in particular to a steel fiber graphite conductive self-heating floor structure.

Background

In the field of buildings, some buildings need to consider heating in winter, wherein floor heating is often applied to household indoor heating due to uniform heat release. The steel fiber graphite is a material which has excellent electrical conductivity, can self-heat after receiving electricity and has higher compressive strength, and therefore, the steel fiber graphite is often used as a floor heating material.

The existing steel fiber graphite conductive self-heating floor is easy to generate heat unevenly, and further influences the comfort of the indoor environment.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the problems in the prior art, and provides a steel fiber graphite conductive self-heating floor structure which can not only heat the indoor space through self-heating, but also improve the phenomenon of uneven floor heating, thereby improving the comfort of the indoor environment.

The utility model provides a steel fiber graphite conductive self-heating floor structure, which comprises:

the steel fiber graphite layer is arranged on the concrete base layer and electrically connected with a current controller, the current controller is electrically connected with a master controller, and the master controller is electrically connected with a power supply device;

the heat conduction water pipe is laid on the steel fiber graphite layer, the heat conduction water pipe is a closed self-circulation heat conduction water pipe, one end of the heat conduction water pipe is communicated with a water inlet of the water pump, a water outlet of the water pump is communicated with the other end of the heat conduction water pipe, liquid is arranged in the heat conduction water pipe, and the water pump is electrically connected with the master controller;

the decorative plate is arranged on the heat conduction water pipe.

Preferably, a heat insulation material layer is further arranged between the heat conduction water pipe and the decorative plate, a pipe groove is formed in the bottom of the heat insulation material layer, the heat conduction water pipe is arranged in the pipe groove, the bottom of the heat insulation material layer is fixedly connected with the top of the steel fiber graphite layer, and the top of the heat insulation material layer is fixedly connected with the bottom of the decorative plate.

Preferably, a plurality of temperature sensors which are arranged at intervals are further arranged between the heat-insulating material layer and the decorative plate, each temperature sensor is electrically connected with the master controller, the temperature sensors are used for detecting temperature values of different parts of the heat-insulating material layer in real time and transmitting the real-time temperature values to the master controller, and the master controller controls the water pump and the current controller to work according to the real-time temperature values.

Preferably, the heat insulation film is arranged between the concrete base layer and the steel fiber graphite layer.

Preferably, the liquid in the heat conducting water pipe is pure water.

Preferably, a filtering device is further arranged between the heat-conducting water pipe and the water inlet of the water pump.

Compared with the prior art, the utility model has the beneficial effects that: the steel fiber graphite conductive self-heating floor structure provided by the utility model can not only heat the indoor through self-heating, but also improve the phenomenon of uneven floor heating, thereby improving the comfort of the indoor environment. Through setting up insulation material layer, not only can prevent that the heat that steel fibre graphite produced from scattering and disappearing too fast, can also be through insulation material layer's conduction, heat distribution is more even. The heat preservation material layer can prevent the direct atress of heat conduction water pipe, consequently can effectively prevent the heat conduction water pipe deformation to prevent that the liquid circulation is not smooth in the heat conduction water pipe. Through setting up the temperature sensor of a plurality of interval arrangements, can be when the floor generates heat uneven the automatic water pump that opens to and when the floor temperature was too high, the automatic shutdown was for steel fibre graphite layer circular telegram. Through setting up thermal-insulated membrane, the produced heat conduction of steel fibre graphite layer to the volume of concrete basic unit that can greatly reduced to greatly reduced heat runs off. Pure water has high specific heat capacity and is not easy to generate precipitate. Through setting up filter equipment, can in time get rid of the impurity in the heat conduction water pipe, prevent that the heat conduction water pipe from blockking up.

Drawings

FIG. 1 is a schematic structural view of the present invention;

fig. 2 is a circuit block diagram of the present invention.

Description of reference numerals:

101. the heat insulation structure comprises a steel fiber graphite layer, 102 a concrete base layer, 103 a heat conduction water pipe, 104 a decorative plate, 201 a heat insulation material layer, 202 a pipe groove, 3 a temperature sensor and 4 a heat insulation film.

Detailed Description

The following detailed description of the present invention is provided in conjunction with the accompanying fig. 1 and 2, but it should be understood that the scope of the present invention is not limited to the specific embodiments. All other embodiments, which can be obtained by a person skilled in the art without any inventive step based on the embodiments of the present invention, are within the scope of the present invention.

Example 1:

as shown in fig. 1 and 2, the present invention provides a steel fiber graphite conductive self-heating floor structure, comprising: the concrete base layer comprises a steel fiber graphite layer 101, a heat conduction water pipe 103 and a decorative plate 104, wherein the steel fiber graphite layer 101 is arranged on a concrete base layer 102, the steel fiber graphite layer 101 is electrically connected with a current controller, the current controller is electrically connected with a master controller, and the master controller is electrically connected with a power supply device; the heat conduction water pipe 103 is laid on the steel fiber graphite layer 101, the heat conduction water pipe 103 is a closed self-circulation heat conduction water pipe 103, one end of the heat conduction water pipe 103 is communicated with a water inlet of the water pump, a water outlet of the water pump is communicated with the other end of the heat conduction water pipe 103, liquid is arranged in the heat conduction water pipe 103, and the water pump is electrically connected with the master controller; the decorative plate 104 is arranged on the heat conduction water pipe 103.

The working principle of example 1 is now briefly described:

when floor heating is needed, the current controller and the water pump are turned on through the master controller, the current controller controls the current to be led into the steel fiber graphite layer 101, and the water pump starts to work. At this time, the steel fiber graphite layer 101 starts to generate heat, and the liquid in the heat conductive water pipe 103 starts to flow. When steel fiber graphite layer 101 generates heat unevenly, the high position heat of heat passes through heat conduction water pipe 103 and transmits to the liquid in heat conduction water pipe 103, and under the promotion of water pump, liquid flows in heat conduction water pipe 103, takes away some heat at high heat position, and decorative board 104 of remaining heat transmission to this department to for indoor heating. At the low heat part, the heat in the liquid is transferred to the decorative plate 104 at the part through the pipe wall of the heat conduction pipe to heat the room.

The steel fiber graphite conductive self-heating floor structure provided by the utility model can not only heat the indoor through self-heating, but also improve the phenomenon of uneven floor heating, thereby improving the comfort of the indoor environment.

Example 2:

on the basis of embodiment 1, in order to prevent the heat loss from being too fast, and prevent the phenomenon that the heat conduction water pipe 103 is stressed and deformed due to the direct stress of the heat conduction water pipe 103 when people walk on the floor.

As shown in fig. 1, a heat insulating material layer 201 is further disposed between the heat conducting water pipe 103 and the decorative plate 104, a pipe groove 202 is disposed at the bottom of the heat insulating material layer 201, the heat conducting water pipe 103 is disposed in the pipe groove 202, the bottom of the heat insulating material layer 201 is fixedly connected to the top of the steel fiber graphite layer 101, and the top of the heat insulating material layer 201 is fixedly connected to the bottom of the decorative plate 104.

Through setting up insulation material layer 201, not only can prevent that the heat that steel fibre graphite produced from scattering and disappearing too fast, can also be through insulation material layer 201's conduction, heat distribution is more even. Furthermore, since the heat conduction water pipe 103 is disposed in the pipe groove 202 at the bottom of the thermal insulation material layer 201, when a person walks on the decorative board 104, the heat conduction water pipe 103 can be prevented from being directly stressed due to the supporting function of the thermal insulation material layer 201, and therefore the heat conduction water pipe 103 can be effectively prevented from being deformed, and the liquid in the heat conduction water pipe 103 is prevented from flowing unsmoothly.

Example 3:

in addition to example 2, the energization of the steel fiber graphite layer 101 was automatically stopped so that the water pump could be automatically turned on when the floor heating was uneven and when the floor temperature was too high.

As shown in fig. 1 and 2, a plurality of temperature sensors 3 arranged at intervals are further arranged between the heat insulating material layer 201 and the decorative plate 104, each temperature sensor 3 is electrically connected with the master controller, the temperature sensors 3 are used for detecting temperature values of different parts of the heat insulating material layer 201 in real time and transmitting the real-time temperature values to the master controller, and the master controller controls the water pump and the current controller to work according to the real-time temperature values.

Through setting up the temperature sensor 3 of a plurality of interval arrangements, a plurality of temperature sensor 3 detect the real-time temperature value at the different positions of heat preservation, and the total controller is with the real-time temperature value at these positions contrast, and when the range of the real-time temperature value at these positions was greater than and predetermines the temperature range value, the total controller control water pump was opened, and then utilized the liquid in the heat conduction water pipe 103 even with the heat conduction that steel fibre graphite layer 101 produced. When the mean value of the real-time temperature values of the monitored parts is larger than the preset temperature mean value, the master controller controls the current controller to be closed, so that the steel fiber graphite layer 101 stops heating, and the temperature of the whole floor is prevented from being too high.

As shown in fig. 1, the heat insulating film 4 is preferably provided between a concrete base layer 102 and a steel fiber graphite layer 101. Through setting up thermal-insulated membrane 4, the volume that can greatly reduced steel fibre graphite layer 101 produced heat conduction to concrete substrate 102 to greatly reduced heat loss.

Preferably, the liquid in the heat conduction water pipe 103 is pure water. Pure water has high specific heat capacity and is not easy to generate precipitate.

Preferably, a filtering device is further disposed between the heat conduction water pipe 103 and the water inlet of the water pump. Through setting up filter equipment, can in time dispel the impurity in the heat conduction water pipe 103, prevent that heat conduction water pipe 103 from blockking up.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. A steel fiber graphite conductive self-heating floor structure is characterized by comprising:

the steel fiber graphite layer (101) is arranged on the concrete base layer (102), the steel fiber graphite layer (101) is electrically connected with a current controller, the current controller is electrically connected with a master controller, and the master controller is electrically connected with a power supply device;

the heat conduction water pipe (103) is laid on the steel fiber graphite layer (101), the heat conduction water pipe (103) is a closed self-circulation heat conduction water pipe (103), one end of the heat conduction water pipe (103) is communicated with a water inlet of the water pump, a water outlet of the water pump is communicated with the other end of the heat conduction water pipe (103), liquid is arranged in the heat conduction water pipe (103), and the water pump is electrically connected with the master controller;

and the decorative plate (104) is arranged on the heat conduction water pipe (103).

2. The steel fiber graphite conductive self-heating floor structure according to claim 1, wherein an insulation material layer (201) is further arranged between the heat conduction water pipe (103) and the decorative plate (104), a pipe groove (202) is formed in the bottom of the insulation material layer (201), the heat conduction water pipe (103) is arranged in the pipe groove (202), the bottom of the insulation material layer (201) is fixedly connected with the top of the steel fiber graphite layer (101), and the top of the insulation material layer (201) is fixedly connected with the bottom of the decorative plate (104).

3. The steel fiber graphite conductive self-heating floor structure as claimed in claim 2, wherein a plurality of temperature sensors (3) are arranged between the heat insulating material layer (201) and the decorative plate (104), each temperature sensor (3) is electrically connected with the master controller, the temperature sensors (3) are used for detecting temperature values of different parts of the heat insulating material layer (201) in real time and transmitting the real-time temperature values to the master controller, and the master controller controls the water pump and the current controller to work according to the real-time temperature values.

4. A steel fiber graphite conductive self-heating floor structure according to claim 1, wherein a heat insulating film (4) is provided between the concrete base layer (102) and the steel fiber graphite layer (101).

5. A steel fiber graphite conductive self-heating floor structure as claimed in claim 1, wherein the liquid in the heat conductive water pipe (103) is pure water.

6. The steel fiber graphite conductive self-heating floor structure as claimed in claim 5, wherein a filtering device is further provided between the heat conducting water pipe (103) and the water inlet of the water pump.

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