CN220336329U - Integrated sound-insulation heat-preservation energy-storage floor - Google Patents

Abstract

The utility model relates to an integrated sound-insulation heat-preservation energy-storage floor which comprises a sound-absorbing plate, an energy-storage plate and a flow guide pipe, wherein the sound-absorbing plate, the energy-storage plate and the flow guide pipe are adhered into a whole, the bottom surface of the sound-absorbing plate is in a wavy shape, the top surface of the sound-absorbing plate is provided with a concave accommodating groove, the flow guide pipe is embedded in the accommodating groove, and the energy-storage plate is in a flat plate shape and is positioned on the sound-absorbing plate. The utility model aims to solve or at least reduce the problems of poor sound insulation effect and poor heat insulation effect of the existing floor, and provides an integrated sound insulation heat insulation energy storage floor.

Description

Integrated sound-insulation heat-preservation energy-storage floor

Technical Field

The utility model belongs to the technical field of energy conservation and heat preservation of buildings, and particularly relates to an integrated sound-insulation heat-preservation energy-storage floor.

Background

Floors, i.e. the surface layers of floors or floors of houses, are made of wood or other materials, and are classified into a number of categories, by structure: solid wood floors, reinforced composite wood floors, three-layer solid wood composite floors, bamboo wood floors, corrosion-resistant floors, cork floors, the most popular multi-layer solid wood composite floors, and the like are classified according to purposes: household, commercial, antistatic floor, outdoor floor, stage dance special floor, gymnasium floor, track special floor, etc., classified according to environmental protection level: e0 grade floor, E1 grade floor, F4 grade floor, JAS star standard F4 star floor, etc. The composite floor is generally formed by compounding four layers of materials, and comprises a wear-resistant layer, a decorative layer, a high-density base material layer and a balance (moisture-proof) layer. The log is crushed, and then added with glue, preservative and additive, and is pressed at high temperature and high pressure by a hot press, so that the physical structure of the log is broken, and the defect of poor log stability is overcome. The composite floor has high strength, uniform specification, high wear resistance, corrosion resistance, moth resistance and good decorative effect, and overcomes the problems of scab, worm eye and chromatic aberration on the surface of log.

But the existing floor has poor sound insulation effect, the upstairs and downstairs neighbors can easily hear the sounds of the rooms, the heat insulation effect is also not good enough, the phenomenon of stuffiness or coldness frequently occurs in the rooms, and the existing floor has no energy storage and self-temperature adjustment effects.

Disclosure of Invention

The utility model aims to overcome the defects in the prior art, solve or at least alleviate the problems of poor sound insulation effect and poor heat insulation effect of the existing floor, and provide an integrated sound insulation heat insulation energy storage floor.

The utility model is realized by the following technical scheme:

the utility model provides an integral type sound insulation heat preservation energy storage floor, includes abatvoix, energy storage board and the honeycomb duct that bonds as an organic wholely, the abatvoix bottom is the wave form, and the abatvoix top surface is provided with the holding tank of indent, the honeycomb duct gomphosis in the holding tank, the energy storage board is dull and stereotyped form and is located the abatvoix upside.

In order to further realize the utility model, the following technical scheme can be preferably selected:

preferably, the top surface of the accommodating groove is communicated with the top surface of the sound absorbing plate, and the depth value of the accommodating groove is not smaller than the diameter value of the flow guiding pipe.

Preferably, the two end surfaces of the guide pipe are respectively flush with the two side surfaces of the sound absorbing plate.

Preferably, the head end and the tail end of the honeycomb duct of the two adjacent integrated sound-insulation heat-preservation energy-storage floors are mutually communicated.

Preferably, the top surface of the sound absorbing plate, the bottom surface of the accommodating groove and the side surface of the accommodating groove are all provided with heat reflecting films.

Preferably, a non-woven fabric layer is arranged between the heat reflection film and the sound absorbing plate.

Preferably, the sound absorbing plate is made of graphite polyphenyl materials, and the phase change materials are poured into the energy storage plate.

Preferably, a decorative plate is adhered to the upper side of the energy storage plate.

Through the technical scheme, the utility model has the beneficial effects that:

the utility model is bonded into a whole, and is convenient for assembly type construction. A plurality of independent cavities are formed between the wavy bottom surface of the sound-absorbing plate and the ground, so that the sound-insulating and heat-insulating effects are achieved. The utility model is embedded with the guide pipe, the phase change material is arranged on the outer side of the guide pipe, the guide pipe is wrapped by the phase change material, the guide pipe is internally filled with fluid, and the indoor temperature is regulated by the temperature difference between the fluid and the room temperature.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a cross-sectional view of the structure of the present utility model;

FIG. 3 is a schematic view of the sound absorbing panel of the present utility model;

FIG. 4 is a schematic view of a flow guide tube according to the present utility model;

wherein: 1-a sound absorbing board; 2-an energy storage plate; 3-a flow guiding pipe; 4-a heat reflective film; 5-a decorative layer.

Detailed Description

In the description of the present utility model, it should also be noted that, unless explicitly specified and limited otherwise, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

The following description of the embodiments of the present utility model will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Examples

As shown in fig. 1-4, an integrated sound insulation heat insulation energy storage floor comprises a sound absorption plate 1, an energy storage plate 2 and a flow guide pipe 3 which are bonded into a whole, wherein the bottom surface of the sound absorption plate 1 is wavy, the top surface of the sound absorption plate 1 is provided with a concave accommodating groove, the flow guide pipe 3 is embedded in the accommodating groove, and the energy storage plate 2 is flat and is positioned on the upper side of the sound absorption plate 1.

The utility model is bonded into a whole, and is convenient for construction. A plurality of independent cavities are formed between the wavy bottom surface of the sound-absorbing plate 1 and the ground, so that the sound-insulating and heat-insulating effects are achieved. The utility model is embedded with the flow guide pipe 3, the flow guide pipe 3 is internally filled with fluid, and the indoor temperature is regulated by the temperature difference between the fluid and the room temperature.

In order to optimize the product structure, the assembly of the product of being convenient for, the holding tank top surface communicates to abatvoix 1 top surface, and the degree of depth value of holding tank is not less than the diameter value of honeycomb duct 3.

For the convenience of transportation and assembly, two end faces of the honeycomb duct 3 are respectively flush with two side faces of the acoustic panel 1, and the head ends and the tail ends of the honeycomb ducts 3 of two adjacent integrated sound-insulation heat-preservation energy-storage floors are mutually communicated.

In order to ensure the heat preservation effect, the heat energy in the room is prevented from being conducted outdoors, the top surface of the sound absorbing plate 1, the bottom surface of the accommodating groove and the side surface of the accommodating groove are all provided with heat reflection films 4, and the heat reflection films 4 are aluminum foil heat insulation films.

In order to ensure the formability of the heat reflection film 4 and the sound absorbing plate 1 and improve the overall tensile property, a non-woven fabric layer is arranged between the heat reflection film 4 and the sound absorbing plate 1.

The upper side of the energy storage plate 2 is adhered with a decorative layer 5, and the decorative layer 5 is made of hard wear-resistant materials.

In this embodiment, the acoustic panel 1 is made of a thermal insulation board material, and the phase change material is poured into the energy storage plate 2.

The heat-insulating board material can be selected from graphite foam board, extruded board, foam board, graphite extruded board, foaming glass board, foaming cement board, perlite board, polyphenyl particle mixture board, penetration board, rock wool board and polyurethane board, and the heat-insulating board belongs to green environment-friendly materials, has extremely low sound propagation speed and certain compressive strength, can effectively prevent heat transfer by the structure, and is a solid material with low heat conductivity at present.

Phase change materials refer to substances that change state of a substance and can provide latent heat under the condition of constant temperature. The process of transforming physical properties is known as the phase change process, where the phase change material will absorb or release a significant amount of latent heat. Phase change materials have the ability to change their physical state over a range of temperatures. Taking solid-liquid phase transformation as an example, when the solid-liquid phase transformation is heated to a melting temperature, the phase transformation material absorbs and stores a large amount of latent heat in the melting process, and when the phase transformation material is cooled, the stored heat is emitted to the environment within a certain temperature range to carry out the reverse phase transformation from the liquid state to the solid state. In both phase-change processes, the stored or released energy is referred to as latent heat of phase change. When the physical state changes, the temperature of the material itself is almost unchanged before the phase change is completed, so that a wide temperature platform is formed, and although the temperature is unchanged, the absorbed or released latent heat is quite large. The phase-change energy storage building material is applied to a novel building material, namely a solid-liquid eutectic phase-change material, and the phase-change material is poured into a wallboard floor board, a floor board or a lightweight concrete precast slab, so that the indoor temperature can be kept to be proper.

Finally, it should be noted that: the foregoing description of the preferred embodiments of the present utility model is not intended to be limiting, but rather, it will be apparent to those skilled in the art that the foregoing description of the preferred embodiments of the present utility model can be modified or equivalents can be substituted for some of the features thereof, and any modification, equivalent substitution, improvement or the like that is within the spirit and principles of the present utility model should be included in the scope of the present utility model.

Claims (8)

1. The utility model provides an integral type sound insulation heat preservation energy storage floor, its characterized in that, including abatvoix (1), energy storage board (2) and honeycomb duct (3) that bond as an organic whole, abatvoix (1) bottom surface is the wavy, and abatvoix (1) top surface is provided with the holding tank of indent, honeycomb duct (3) gomphosis in the holding tank, energy storage board (2) are dull and stereotyped form and are located abatvoix (1) upside.

2. The integrated sound-insulation heat-preservation energy-storage floor according to claim 1, wherein the top surface of the accommodating groove is communicated to the top surface of the sound-absorbing plate (1), and the depth value of the accommodating groove is not smaller than the diameter value of the flow guide pipe (3).

3. The integrated sound-insulation heat-preservation energy-storage floor according to claim 1, wherein two end faces of the flow guide pipe (3) are respectively flush with two side faces of the sound-absorbing plate (1).

4. An integrated sound-insulating heat-insulating energy-storing floor according to claim 3, characterized in that the head and tail ends of the honeycomb ducts (3) of two adjacent integrated sound-insulating heat-storing floors are mutually communicated.

5. The integrated sound-insulation heat-preservation energy-storage floor according to claim 1, wherein the top surface of the sound-absorbing plate (1), the bottom surface of the containing groove and the side surface of the containing groove are all provided with heat reflection films (4).

6. The integrated sound-insulation heat-preservation energy-storage floor according to claim 5, wherein a non-woven fabric layer is arranged between the heat reflection film (4) and the sound absorption plate (1).

7. The integrated sound-insulation heat-preservation energy-storage floor according to claim 1, wherein the sound-absorbing plate (1) is made of heat-preservation plate materials, and phase-change materials are poured in the energy-storage plate (2).

8. The integrated sound-insulation heat-preservation energy-storage floor according to claim 1, wherein a decorative layer (5) is adhered to the upper side of the energy-storage plate (2).