CN201730286U - Hydropower mixed wood-plastic heating floor - Google Patents

Abstract

The utility model provides a water-electricity hybrid wood-plastic heating floor, which includes a panel layer and a bottom layer arranged up and down, and is characterized in that: in the longitudinal direction between the bottom layer and the panel layer, there is also a The first cavity of the water pipeline and the second cavity leading to the electric heating pipeline are separated by a hollow support rib. The utility model passes the hot water pipeline and the electric heating pipeline through different cavities respectively, and at the same time of installing the floor, two heating lines of the hot water pipeline and the electric heating pipeline can be connected, and by using various types of electric energy, solar energy, natural gas, etc. Energy can be used to heat hot water and heat, reduce costs and save expenses. It can not only decorate and beautify the living room environment, but also save heating space and increase the utilization rate of the living room area, and there will be no adverse effects or harm between the heat sources. When the electric heating pipeline is used for heating, the water can also be heated indirectly, prolonging the heat release time of the entire heating system and improving the heating effect.

Description

A water-electric hybrid wood-plastic heating floor

technical field

The utility model relates to the field of floors in daily necessities for human beings, in particular to a heating floor.

Background technique

Traditional floor heating uses a single heat source of water or electricity for heating. The cost of water floor heating is low (natural gas and solar heating can be used for heating), but it is unstable. When natural gas is in short supply and solar resources are insufficient, it cannot meet the heating demand; while electric energy is used for heating. High consumption, high cost, power outage and heating.

Traditional underfloor heating cannot drill holes or nails in the ground, so as not to leak geothermal pipelines, resulting in problems of water leakage and electricity leakage in the geothermal system. Ordinary floors have poor thermal performance, slow speed, and large heat loss, so they cannot be used as special geothermal floors.

In the prior art, there is provided a heating panel integrated with water and electricity, which can realize heating by means of water and electricity. After the metal plate, another floor needs to be laid, and the surface of the metal plate is a flat surface, which cannot mark the paths of water and electricity pipelines, and cannot be drilled or nailed. It is very inconvenient to install.

Utility model content

The purpose of the utility model is to overcome the defects of complex structure, single heating mode and poor thermal conductivity of the existing floor heating, and provide a hydroelectric hybrid heating floor with simple structure and excellent performance.

The utility model is achieved in this way. A water-electric hybrid wood-plastic heating floor includes a panel layer and a bottom layer arranged up and down. In the longitudinal direction between the panel layer and the bottom layer, there is also a The first cavity of the pipeline and the second cavity leading into the electric heating pipeline are transparent in the transverse direction and separated and closed in the longitudinal direction by the hollow supporting ribs.

Preferably, the bottom layer, the panel layer and the hollow supporting ribs are integrally formed by wood-plastic materials added with metal wires.

Preferably, the thickness of the bottom layer is 1/3-1/2 of the thickness of the panel layer, and the thickness of the hollow support rib is 2-3 times of the thickness of the panel layer.

Specifically, the second cavity is arranged at the middle position in the longitudinal direction of the bottom layer and the panel layer, and two first cavities are respectively located at both ends of the bottom layer and the panel layer.

Further, a third cavity for installing fasteners or punching holes is further provided between the first cavity and the second cavity.

Furthermore, the panel layer corresponding to the third cavity is provided with a downward groove.

The utility model is provided with a first cavity that can be connected to a hot water pipeline and a second cavity that can be connected to an electric heating pipeline in the longitudinal direction between the panel layer and the bottom layer, so that hot water can be connected to the floor while the floor is installed. There are two kinds of heating lines, pipelines and electric heating pipelines, and by using various energy sources such as electric energy, solar energy, and natural gas to heat hot water and heat, reduce costs and save costs. It can not only decorate and beautify the living room environment, but also save heating space and increase The utilization rate of living room area.

The hot water pipeline and the electric heating pipeline of the utility model respectively pass through different cavities, and there is no adverse effect or harm on each other. Moreover, when the electric heating pipeline is used for heating, the water can also be heated indirectly, prolonging the heat release time of the entire heating system and improving the heating effect.

The utility model integrates radiation heating and ground decoration, has simple structure and is convenient to install.

Description of drawings

Fig. 1 is a structural schematic diagram of the utility model embodiment one;

Fig. 2 is the structural schematic diagram of the second embodiment of the utility model;

Fig. 3 is a schematic diagram of the distribution structure of water and electric heating pipelines in the utility model.

Detailed ways

In order to make the purpose, technical solution and advantages of the utility model clearer, the utility model will be further described in detail below in conjunction with the accompanying drawings and embodiments. It should be understood that the specific embodiments described here are only used to explain the utility model, and are not intended to limit the utility model.

The embodiment of the utility model provides two structures of water and electricity hybrid wood-plastic heating floor.

Embodiment one:

Referring to Fig. 1 and Fig. 3, the floor structure of Embodiment 1 provided by the utility model includes a panel layer 1 and a bottom panel layer 3 arranged up and down. A first cavity 5 and a second cavity 4 are provided, the first cavity 5 and the second cavity 4 are transparent in the transverse direction, and the longitudinal direction is separated by the hollow supporting rib 2, and at the same time, the panel layer 1 and the bottom plate The two sides of the layer 3 are also closed by two other longitudinally arranged hollow supporting ribs 2, wherein the first cavity 5 is used for passing through the hot water pipe A, and the second cavity 4 is used for entering the electric heating pipeline B. In this way, the hollow supporting ribs 2 can strengthen the strength of the floor and reduce deformation on the one hand, and can also serve as an isolation structure for the first cavity 5 and the second cavity 4 . In this embodiment, the hollow support ribs 2 on both sides are also provided with a tenon 7 and a slot 8 correspondingly, so that two adjacent floors can be fastened and connected side by side. Of course, the connection method of the floor is not limited to the structure shown in FIG. 1 , and other methods of fixing and splicing can also be used.

During installation, the floors are arranged in parallel and spliced longitudinally, and can be snapped into the adjacent floor slots 8 through the tenon 7, so that the first cavity 5 and the second cavity 4 are vertically connected, and the electric heating pipeline B and the heating The water pipes A respectively pass through the first cavity 5 and the second cavity 4 of each floor in sequence, and merge into respective buses/pipes at the edge of the ground. The utility model is provided with a first cavity 5 that can lead into the hot water pipeline A and a second cavity 4 that can lead into the electric heating pipeline B in the longitudinal direction between the panel layer 1 and the bottom layer 3, and can be installed on the floor. At the same time, two heating lines, the hot water pipeline and the electric heating pipeline, are connected, and the hot water pipeline A and the electric heating pipeline B can respectively pass through different cavities without any adverse effect or harm on each other.

The structure of the utility model can not only decorate and beautify the living room environment, but also save heating space and increase the utilization rate of the living room area. Through external connection, various energy sources such as electric energy, solar energy, and natural gas can also be used for heating. When resources are sufficient, solar energy, natural gas, and other low-cost energy sources are preferentially used to heat hot water for heating, reducing costs and saving costs. When one or two of the resources are insufficient, other methods of heating can be used to ensure heating supply under special conditions, which can overcome problems such as unstable solar energy supply, tight natural gas supply, expensive electricity costs, and inability to supply heat during power outages. In addition, the structure of the utility model can also indirectly heat the water in the hot water pipe A when using the electric heating pipeline B for heating, prolonging the heat release time of the entire heating system and further improving the heating effect.

In the specific processing of the embodiment of the utility model, the bottom layer 3, the panel layer 1 and the hollow supporting rib 2 are made of new wood-plastic materials, and metal wires are added in them, which can enhance the thermal conductivity and overcome the thermal performance of ordinary floors. Poor, slow speed, large heat loss, can not be used as the shortcomings of geothermal special floor. The whole structure is directly molded at one time, the process is simple, and it has outstanding advantages such as environmental protection, high strength, no discoloration, easy cleaning, good corrosion resistance, and elegant appearance. It has double the service life and anti-aging function compared with Finnish wood and other floor products.

In order to ensure that the utility model has a better strength, and to save processing materials, in the specific design and processing of the embodiment of the utility model, the thickness of the bottom layer 3 is selected as 1/3-1/2 times the thickness of the panel layer 1 , the thickness of the hollow supporting ribs 2 is 2-3 times the thickness of the panel layer 1 .

In order to further optimize the structural design, the embodiment of the utility model can also set the second cavity 4 at the longitudinal middle position between the floor layer 3 and the panel layer 1, and the first cavity 5 is divided into two, adjacent to the second cavity respectively. The cavity 4, the first cavity 5 and the second cavity 4 are separated by the hollow supporting ribs 2 in the transverse direction, and are located at both ends of the bottom layer 3 and the panel layer 1, and the other side of the first cavity 5 passes through The other two hollow supporting ribs 2 are closed.

Embodiment two:

Referring to Fig. 2, both the structure of the second embodiment of the utility model and the first embodiment include a panel layer 1 and a bottom layer 3 arranged up and down, and a first space is also provided in the longitudinal direction between the panel layer 1 and the bottom layer 3. Cavities 5 and second cavities 4, wherein the first cavity 5 is used for passing through the hot water pipe A, and the second cavity 4 is used for entering the electric heating pipeline B. The first cavity 5 and the second cavity 4 Between them, they are separated by hollow supporting ribs 2. The difference from Embodiment 1 is that the second cavity 4 in this embodiment 2 is located at the longitudinal middle position between the floor layer 3 and the panel layer 1, and the first cavity 5 is divided into two, adjacent to the second cavity respectively. The cavity 4 is separated by a hollow supporting rib 2 and is located at both ends of the bottom layer 3 and the panel layer 1 , and is closed by the other two hollow supporting ribs 2 in the transverse direction. At the same time, between the first cavity 5 and the second cavity 5, there is also a third cavity 6 for installing fasteners or punching holes, and the cavities are also separated by hollow supporting ribs 2 , On the panel layer 1 corresponding to the third cavity 7, a downward groove 11 is also provided. Like this, hot water pipeline A, electric heating pipeline B, fastener (not shown) can pass through different positions of floor respectively, and on panel layer 1 mark respective Through the position, the ribs 12 on both sides of the panel layer 1 correspond to the hot water channel, the ribs 13 in the middle of the panel layer 1 correspond to the electric heating pipeline channel, and the groove 11 in the middle of the panel layer 1 is used for fasteners (screws) nailing or Punch location. In this way, it is easy to judge whether there is water and electricity passing through the corresponding position in the floor only from the shape of the upper surface of the floor, and it can determine the reasonable nailing position when the floor is installed, and solve the problem that the traditional floor heating cannot be drilled or nailed on the ground to avoid leakage Geothermal pipelines lead to problems of water leakage and electricity leakage in the geothermal system.

At the same time, the second floor of this embodiment can be directly connected to the laying keel through screws and other fasteners during installation. Each floor is directly connected without mortise, tenon, etc., and is independent of each other. When damage occurs, only a single floor needs to be disassembled and replaced. , which solves the disadvantage of dismantling or even replacing a large number of surrounding floors for maintenance of the lock-type floor.

Embodiment 2 of the utility model provides floors with four different cavity structures, which are respectively placed in different positions according to the requirements for the arrangement of pipes and lines. It can use natural gas, solar energy or electric energy to realize low-power, arbitrary space heating. It can be used for water heating or electric heating, or both methods can be used in combination. It integrates indoor heating and floor decoration functions, and can be nailed and drilled , easy maintenance, small thickness, space-saving, multi-purpose board, wide range of heat sources, energy saving, and guaranteed heating.

Similarly, Embodiment 2 of the present utility model can use natural gas, solar energy or electric energy to realize low-power heating in any space, either by water heating or electric heating, or by combining the two methods, integrating indoor heating and ground heating. The decorative function is integrated, it can be nailed and drilled, it is easy to maintain, it is small in thickness, saves space, it can be used for multiple purposes, it has a wide range of heat sources, saves energy, and ensures heating.

The above descriptions are only two different embodiments of the utility model, and its structure is not limited to the shapes listed above. Any modifications, equivalent replacements and improvements made within the spirit and principles of the utility model should be Included within the protection scope of the present utility model.

Claims (6)

1. A water-electric hybrid wood-plastic heating floor, comprising a panel layer and a bottom layer arranged up and down, characterized in that: in the longitudinal direction between the bottom layer and the panel layer, there is also a pipe that can lead into hot water pipes The first cavity and the second cavity leading into the electric heating pipeline are transversely transparent and longitudinally separated and closed by hollow supporting ribs. 2. A water-electric hybrid wood-plastic heating floor as claimed in claim 1, characterized in that: the bottom layer, the panel layer and the hollow supporting ribs are integrally formed by wood-plastic materials added with metal wires. 3. A water-electric hybrid wood-plastic heating floor as claimed in claim 1, characterized in that: the thickness of the bottom layer is 1/3-1/2 of the thickness of the panel layer, and the thickness of the hollow supporting rib is 1/2 of that of the panel 2-3 times the layer thickness. 4. A water-electric hybrid wood-plastic heating floor as claimed in claim 1, characterized in that: the second cavity is set at the middle position in the longitudinal direction between the floor layer and the panel layer, and the first cavity is divided into two, They are respectively located at both ends of the bottom layer and the panel layer. 5. A water-electric hybrid wood-plastic heating floor according to any one of claims 1-4, characterized in that: between the first cavity and the second cavity, there is a fastener or Perforated third cavity. 6. The water-electric hybrid wood-plastic heating floor according to claim 5, characterized in that: the panel layer corresponding to the third cavity is provided with a downward groove.

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