TWM592893U - Floating micro-floor floor structure for reducing floor impact noise - Google Patents

Abstract

This creation is a floating micro-floor floor structure that reduces the impact sound of a floor slab, including: a honeycomb-shaped sound-absorbing support structure layer, the honeycomb-shaped sound-absorbing support structure layer includes a plurality of hollow honeycomb frame bodies, the honeycomb frame body is provided with A porous sound-absorbing material, a frame is provided around the honeycomb-shaped sound-absorbing support structure layer; a surface decoration material is provided on the honeycomb-shaped sound absorption support structure layer; an elastic vibration isolation layer is provided on the honeycomb-shaped sound absorption structure Under the support structure layer; in this way, it can make the construction and assembly of the floor of the building modular and have excellent convenience, can greatly improve the sound absorption and sound insulation effect through the design of the structure, and have more comfortable and safe Practical use effect.

Description

Floating micro-floor floor structure to reduce impact sound of floor

This creation is about a floor masonry structure, especially a modular combination operation that facilitates on-site construction, and has a floating micro-floor floor structure with excellent safety, firmness and sound insulation effects to reduce the impact of floor slabs.

According to modern people’s requirements for home decoration in order to have a quiet and comfortable life, the general floor/floor is usually laid with a layer of floor tiles or floors to increase the appearance and comfort. It is usually RC solid structure. When people walk around (such as high-heeled shoes), move furniture and utensils (such as table and chair impact and scrape), various types of impact noises will be generated. In order to achieve a quiet environment to prevent noise interference, this is the first problem to be solved at home.

The conventional construction structure 90A for reducing the impact sound of the floor slab is shown in FIG. 1. It is provided with an elastic vibration isolation layer 91 on an RC floor 90, and then a cement mortar layer 92 is laid on the vibration isolation layer 91. On the cement mortar layer 92, surface decoration materials 93 such as tile, marble, etc. are pasted with cement paste and adhesive. In the conventional construction structure 90A, the cement mortar layer 92 on the elastic vibration isolation layer 91 cannot bear the bending moment force, so that the surface decoration material 93 may break.

As shown in FIG. 1a, another conventional construction 90B for reducing the impact sound of a floor slab is to provide an elastic vibration isolation layer 91 on the floor 90 of an RC building. A splint 94 is laid on the elastic vibration isolation layer 91. A layer of RC board 95 is poured on the plywood 94, and then a cement mortar layer 92 is laid on the RC board 95, and then the surface decoration material 93 such as tile, marble, etc. is pasted on the cement mortar layer 92 with cement mortar and adhesive . In this conventional construction structure 90B, the plywood 94 is first laid on the elastic vibration isolation layer 91, and then a layer of RC board 95 is poured, which will cause the overall floor slab to increase the static load of 200Kg per square meter. The weight and structural cost of the entire building increased.

The aforementioned constructions 90A and 90B for reducing the impact sound of floor slabs all have their deficiencies, which is obviously not an ideal design, and there is a need for improvement. Therefore, how to improve the defects in manufacturing, assembling and using the conventional constructions that reduce the impact sound of floor slabs should be a further issue that the industry should strive to solve and overcome.

For this reason, in view of the fact that the construction of conventional constructions to reduce the impact sound of the floor slab is lacking in manufacturing, assembly and use, and the structural design is not ideal, the creator of this case set out to develop its solution, hoping to develop A floating micro-floor floor structure that is more soundproof, convenient in construction, lightweight, safe and practical, and has excellent economic benefits to reduce the impact of floor slabs to serve the public and promote the development of this industry. The creation of the original creation.

The purpose of this creation is to provide a floating micro-floor floor structure, which can make the construction and assembly of floor floors have excellent modularity and convenience, and its sound absorption and sound insulation effects are greatly improved by the design of this structure, and Those who have a more comfortable, safe and practical use effect.

Another purpose of this creation is to provide a floating honeycomb masonry floor structure that can use the floating micro-floor floor structure concept to reduce the impact sound of the floor slab, so that under the trend of increasing shortage of construction workers, the construction method can be industrialized. 、Certainization, further convenience, simple construction and reduce manpower requirements.

The technical means adopted by this creation to achieve the above purposes include: a floating micro-floor floor structure, which includes an elastic vibration isolation layer, a honeycomb-shaped sound-absorbing supporting structure layer and surface decoration materials; wherein, the elasticity The vibration isolation layer is disposed under the honeycomb-shaped sound-absorbing support structure layer, and the surface decoration material is disposed above the honeycomb-shaped sound-absorbing support structure layer; the honeycomb-shaped sound-absorbing support structure layer includes a plurality of hollow honeycomb frame bodies, the honeycomb The frame body is provided with a porous sound-absorbing material, and the surrounding frame of the honeycomb-shaped sound-absorbing support structure layer is provided with a frame, which is integrated with the honeycomb-shaped sound-absorbing support structure layer to bind and consolidate the honeycomb Frame body.

In the embodiment of the present technology, the porous sound-absorbing material is a network structure formed by interpenetrating or closed pores, rather than a compact entity, which is used to achieve the effect of sound absorption and sound attenuation, and the material is not limited. .

In the embodiment of the present technology, at least one outer periphery of the sealing frame may also be coated with a polymer adhesive layer, so as to facilitate its use in combination with the adjacent honeycomb-shaped sound-absorbing supporting structure layer;

In the embodiment of the present technology, the adhesive layer is a double-sided adhesive layer.

In the embodiment of the present technology, the elastic vibration isolation layer is a plate layer with a thickness, which is composed of rubber, glass wool, polyester cotton, foam or cork.

In the embodiment of the present technology, a bottom plate is further provided under the honeycomb-shaped sound-absorbing support structure layer.

In the embodiment of the present technology, the surface decoration material is bonded to the honeycomb-shaped sound-absorbing supporting structure layer by a glue layer.

In the embodiment of the present technology, a thermal insulation and vibration isolation layer is further provided between the floating micro-floor floor structure and a wall, and the thermal insulation and vibration-isolation layer blocks heat exchange between the floating micro-floor floor structure and the wall.

In the embodiment of the present technology, the sealing frame outside the honeycomb-shaped sound-absorbing support structure layer and the surface decoration material are flush with each other in the longitudinal height direction.

In order to make your reviewing members have a better understanding and understanding of the technical characteristics and the achieved effects of this creation, I would like to use the preferred embodiment drawings and detailed descriptions, the explanations are as follows:

1‧‧‧Floating micro-floor floor structure

10‧‧‧Elastic vibration isolation layer

20‧‧‧Honeycomb-shaped sound-absorbing supporting structure layer

21A‧‧‧Top

22‧‧‧Honeycomb frame

23‧‧‧porous sound-absorbing material

24‧‧‧Seal frame

25‧‧‧seal bottom plate

26‧‧‧ Adhesive layer

27‧‧‧ Primer

30‧‧‧Surface decoration material

31‧‧‧adhesive layer

40‧‧‧ Wall

41‧‧‧Insulation and vibration isolation layer

100‧‧‧Slab

Figure 1 is a schematic diagram 1 of the structure of the conventional floor masonry.

Figure 1a is the second schematic diagram of the structure of the conventional floor masonry.

Figure 2 is a three-dimensional schematic diagram of this creation.

Figure 3 is an exploded view of this creation.

Fig. 4 is a schematic sectional view of a partial combination of this creation.

Figure 5 is a three-dimensional schematic diagram of the construction combination of this creation.

Figure 6 is a schematic sectional view of the three-dimensional combination of this creation.

Please refer to Figures 2 to 4 for a detailed description of this embodiment of the floating micro-floor floor structure that reduces the impact sound of the floor. The floating micro-floor floor structure 1 shown in this embodiment is a floor structure that is laid on the building floor Floor masonry, the floating micro-floor floor structure 1 includes an elastic vibration isolation layer 10, a honeycomb-shaped sound-absorbing support structure layer 20 and a surface decoration material 30; wherein, the elastic vibration isolation layer 10 is provided on the honeycomb-shaped sound-absorbing support structure Below the layer 20, the surface decoration material 30 is disposed above the honeycomb-shaped sound-absorbing supporting structure layer 20, and the whole combination forms this embodiment. The detailed structure and technical details of the floating micro-floor floor structure 1 are described below.

Wherein, the honeycomb-shaped sound-absorbing support structure layer 20 includes a plurality of hollow honeycomb frame bodies 22, so that the honeycomb-shaped sound-absorbing support structure layer 20 has very strong toughness and bearing capacity; the honeycomb frame body 22 is provided with porous The sound-absorbing material 23, the porous sound-absorbing material 23 is a light-weight sound-absorbing material composed of interpenetrating or closed holes, rather than a compact entity, used to achieve the effect of sound absorption and sound reduction, the material is not Restricted.

In addition, a frame 24 is further provided around the honeycomb-shaped sound-absorbing support structure layer 20, and the seal frame 24 is integrated with the honeycomb-shaped sound-absorbing support structure layer 20 to bind and fix the honeycomb frame body 22; the seal The outer periphery of the frame 24 can also be coated with a polymer adhesive layer 26 (as shown in Figure 5), which can be conveniently combined with the adjacent honeycomb-shaped sound-absorbing support structure layer 20 when used; the honeycomb-shaped sound-absorbing support structure layer A bottom plate 25 is also provided below the 20, for example: it is arranged in an adhesive manner to provide the tensile strength of the vertical load. In this way, the manufacturing and assembly of the honeycomb-shaped sound-absorbing support structure layer 20 are completed.

As shown in FIG. 4 again, in a suitable embodiment, the top end of the sealing frame 24 may be flush with the top surface 21A of the honeycomb-shaped sound-absorbing support structure layer 20. Thus, the sealing frame 24 and the bee A flat plane is formed at the top surface 21A of the nested sound-absorbing support structure layer 20 to facilitate subsequent assembly and placement of the surface decoration material 30.

The elastic vibration isolation layer 10 is a plate layer with a thickness. The elastic vibration isolation layer 10 can be made of rubber, glass wool, polyester cotton, foam, cork and other materials, so as to have appropriate elasticity. The elastic vibration isolation layer 10 is disposed (e.g., glued) under the honeycomb-shaped sound-absorbing support structure layer 20 (ie, the bottom plate 25), that is, the honeycomb-shaped sound-absorbing support structure layer 20 (the bottom plate 25) has a bottom The glue 27 is adhered to the elastic vibration isolation layer 10 (refer to FIG. 6), so that when the honeycomb-shaped sound-absorbing support structure layer 20 is placed on the elastic vibration isolation layer 10, it is like designing a raft type for buildings and buildings in weak strata The same principle as the foundation structure to bear the weight of the superstructure, the elastic vibration isolation layer 10 is like a weak formation, so that the honeycomb-shaped sound-absorbing support structure layer 20 is like a raft foundation structure.

The surface decoration material 30 is disposed on the honeycomb-shaped sound-absorbing supporting structure layer 20. The surface decoration material 30 includes a ceramic tile, marble, floor tile, vitrified brick, plastic floor tile or wooden brick, etc., but not Limited; the surface decoration material 30 is adhered to the honeycomb-shaped sound-absorbing support structure layer 20 with a glue layer 31, in this embodiment, the honeycomb-shaped sound-absorbing support structure layer 20 is pushed down by heavy pressure Compressive state, and increase its overall stability and aesthetics.

In a suitable embodiment, the floating micro-floor floor structure 1 for combination can be cut and customized at the factory, and is convenient for transportation to the construction site; thus, multiple floating micro-floor floors can be laid during construction The floor structure 1 is placed on the floor respectively, and then each floating micro-floor floor structure 1 is quickly connected into a large floating floor by the polymer adhesive layer 26 (or double-sided adhesive layer) coated on the outer periphery of the sealing frame 24. The sealing frame 24 on the outer side of the honeycomb-shaped sound-absorbing support structure layer 20 is preferably flush with the surface decoration material 30 in the longitudinal height direction.

Please refer to Figures 5 and 6 together. During the assembly and application of the floating micro-floor floor structure that reduces the impact sound of the floor, a plurality of floating micro-floor floor structures 1 are arranged and spliced on the first floor 100 (or floor). That is, the elastic vibration isolation layer 10 of the floating micro-floor floor structure 1 is provided on the floor 100 (or floor), and the bonding between two adjacent floating micro-floor floor structures 1 is between two adjacent sealing frames 24 The adhesive layer 26 is bonded together, so that the plurality of floating micro-floor floor structures 1 are firmly connected into a floor masonry paving layer (floating soundproof floor), that is, the construction combination on site is completed. When convenient. Since the surface decoration material 30 (surface decoration board) has been glued on the honeycomb-shaped sound-absorbing supporting structure layer 20, when the plurality of floating micro-floor floor structures 1 are completed, they can be used after the construction is completed. Quite convenient and fast.

As shown in FIG. 5 again, after the plurality of floating micro-floor floor structures 1 are connected into a floor masonry paving layer (floating soundproof floor), a heat insulation and vibration isolation layer 41 is further provided between the surroundings and the wall 40, The heat insulation and vibration isolation layer 41 is used to block the heat exchange and solid vibration sound conduction between the plurality of floating micro-floor floor structures 1 and the wall 40, so that the cold or heat of the wall 40 is not easily transmitted to the plurality of floating micro-floor floor structures 1.

When the floating micro-floor floor structure 1 which reduces the impact sound of the floor is used in this work, the floating micro-floor floor structure 1 can carry the concentrated load and movable load on the floor by the honeycomb-shaped sound-absorbing support structure layer 20, and then evenly distribute it to the entire elastic partition On the vibration layer 10, the elastic vibration isolation layer 10 transfers the bearing weight to the RC floor/floor, which has excellent support. Furthermore, the honeycomb-shaped sound-absorbing support structure layer 20 is filled with a porous sound-absorbing material 23 to form a considerable sound-absorbing force. In addition, because the drum surface effect is to compress the enclosed air when striking on the drum skin, the percussion sound is transmitted to the lower bone skin to radiate, so this design is so constructed that on the one hand, it can eliminate the impact of the hollow honeycomb structure when it is sealed. Drum surface effect; on the other hand, due to solid sound transmission when striking surface decoration materials 30 such as tiles and marbles, when the sound energy is radiated into the air in the honeycomb-shaped sound-absorbing supporting structure layer 20, the sound energy can be filled in The porous sound-absorbing material 23 in the honeycomb frame 22 absorbs; in three aspects, when striking the surface decoration materials 30 such as tiles and marbles, air transmission is generated behind it, and these air transmissions can also be filled in the honeycomb frame The porous sound-absorbing material 23 in 22 is absorbed. Therefore, this creation has excellent tranquility and comfort in use.

The floating micro-floor floor structure of this creation to reduce the impact sound of the floor slab is constructed with the above-mentioned structure, which can make the construction and assembly of the floor masonry have excellent modularity, convenience, and simplicity, and its sound and sound insulation effects are supported by The design of the sound absorption layer and its structural layer can be greatly improved, and it has a more comfortable, safe and practical use effect. At the same time, this creation can use the floating micro-floor floor structure concept to derive a floating honeycomb masonry floor structure that reduces the impact sound of the floor, so that under the trend of increasing shortage of construction workers, the construction method can be industrialized and implemented. To facilitate, Simple construction and reduce manpower requirements.

In summary, this creation has indeed met the requirements of the new type of patent, and the patent application has been filed in accordance with the law. However, the above are only the preferred embodiments of this creation, and are not used to limit the scope of the implementation of this creation. Therefore, all changes and modifications based on the shape, structure, characteristics and spirit described in the scope of the patent application for this creation are cited. , Should be included in the scope of patent applications for this creation.

1‧‧‧Floating micro-floor floor structure

10‧‧‧Elastic vibration isolation layer

20‧‧‧Honeycomb-shaped sound-absorbing supporting structure layer

24‧‧‧Seal frame

30‧‧‧Surface decoration material

Claims (8)

A floating micro-floor floor structure to reduce the impact sound of floor plates, including: A honeycomb-shaped sound-absorbing support structure layer includes a plurality of hollow honeycomb frame bodies, the honeycomb frame body is provided with a porous sound-absorbing material, and a border is provided around the honeycomb-shaped sound-absorbing support structure layer; A surface decoration material is provided on the honeycomb-shaped sound-absorbing supporting structure layer; An elastic vibration isolation layer is arranged under the honeycomb-shaped sound-absorbing support structure layer. The floating micro-floor floor structure for reducing the impact sound of the floor as described in item 1 of the scope of the patent application, wherein the elastic vibration isolation layer is a rubber, glass wool, polyester cotton, foam or cork. The floating micro-floor floor structure for reducing the impact sound of the floor as described in item 1 of the patent scope, wherein a bottom plate is further provided below the honeycomb-shaped sound-absorbing support structure layer. The floating micro-floor floor structure for reducing the impact sound of floor slabs as described in item 1 of the patent application scope, wherein at least one outer side of the sealing frame is provided with an adhesive layer. The floating micro-floor floor structure for reducing the impact sound of floor slabs as described in item 4 of the patent application scope, wherein the adhesive layer is a double-sided adhesive layer. The floating micro-floor floor structure for reducing the impact sound of a floor as described in item 1 of the scope of the patent application, wherein the surface decoration material is bonded to the honeycomb-shaped sound-absorbing supporting structure layer with a glue layer. The floating micro-floor floor structure for reducing the impact sound of floor slabs as described in item 1 of the scope of the patent application, wherein a thermal insulation layer is further provided between the floating micro-floor floor structure and a wall, the thermal insulation layer is Block heat exchange and solid vibration sound conduction between the floating micro-floor floor structure and the wall. The floating micro-floor floor structure for reducing the impact sound of a floor as described in item 1 of the patent application scope, wherein the sealing frame outside the honeycomb-shaped sound-absorbing support structure layer and the surface decoration material are flush with each other in the longitudinal height direction.

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