KR20200048175A - Structure for decreasing noise between building floors and ONDOL comprising the same - Google Patents

Abstract

The present invention relates to a structure for preventing a noise between floors and a Korean floor heater including the same. The structure for preventing a noise between floors includes a three-dimensional mesh mat and a sound absorbing structure. The three-dimensional mesh mat is configured in a shape of being divided by partition walls so that through holes individually vertically penetrate into a transverse section. The sound absorbing structure is stacked on the three-dimensional mesh mat. Protruding parts protruding from an upper surface of a base part are vertically and horizontally spaced apart based on a horizontal surface so that an air hole dented from a lower surface of the base part is provided. An installation groove is vertically and horizontally connected between the protruding parts.

Description

Structure for decreasing noise between building floors and ONDOL comprising the same}

The present invention relates to a technology that can improve the noise problem between floors in an apartment.

Apartments make residential life convenient. However, in the residential life of apartments, the problem of inter-floor noise between the lower and upper floors has caused many people to suffer health problems due to stress, the relationship between neighbors is also damaged, and even murders occur, resulting in social problems.

In order to prevent such an inter-floor noise problem, residents purchase and lay flooring and mats. According to a survey result, it is reported that there is an average reduction effect of 21% for lightweight shock noise, but no reduction effect for heavy shock noise. . Most of the causes of inter-layer noise conflict are heavy shock sounds, such as children jumping, but most existing products show a problem that there is no reduction effect on the heavy shock sounds.

Also, in order to improve the serious floor noise problem of the apartment, a policy to regulate the floor thickness to be significantly strengthened was introduced.However, if the floor thickness of the apartment is thick, the floor noise can be definitely reduced, but 100% of the floor noise is eliminated. It is not only difficult, but also has the disadvantage that the presale price increases due to the increase in the load on the apartment building.

Registered Patent Publication No. 10-1145878 (published Mar. 02, 2011)

An object of the present invention is to provide an interlayer noise prevention structure and an ondol including the same, which can improve the floor noise problem in an apartment and the like, and improve floor insulation efficiency to reduce heating costs.

The interlayer noise prevention structure according to the present invention for achieving the above object includes a three-dimensional mesh mat and a sound absorbing structure. The three-dimensional mesh mat is formed in a form partitioned by partitions so that the through holes penetrate each up and down in a regular hexagonal cross section. The sound absorbing structure is stacked on the three-dimensional mesh mat, and the protrusions protruding from the upper surface of the base part are arranged to be spaced apart from each other horizontally and horizontally relative to the horizontal surface so as to have air grooves recessed from the lower surface of the base part, and the installation grooves are connected horizontally and horizontally between the protrusions. It is made in the form.

The ondol according to the present invention has the above-described interlayer noise prevention structure, a heat insulating mat disposed on the floor slab to stack the 3D mesh mat, heat sinks installed in the installation groove of the sound absorbing structure, and to cover the sound absorbing structure. It includes a floor finishing material made of any one of a mortar layer and a finishing plate.

According to the present invention, it is possible to improve the inter-floor noise problem in an apartment and the like, and increase the efficiency of floor insulation to reduce heating costs. In addition, according to the present invention, when finishing with a mortar layer on the ondol, it is possible to save the amount of the mortar and to reduce the load of the building accordingly, compared to when the mortar is finished on the entire floor.

1 is a perspective view of an interlayer noise prevention structure according to an embodiment of the present invention.
FIG. 2 is a longitudinal sectional view of FIG. 1.
3 is a plan view of the 3D mesh mat in FIG. 1.
4 is a cross-sectional view of FIG. 3.
5 is a plan view of the sound absorbing structure in FIG. 1.
6 is a perspective view showing a lower side of the sound absorbing structure in FIG. 1.
7 is a longitudinal sectional view of an ondol according to an embodiment of the present invention.
8 is a perspective view illustrating a state in which heat radiation tubes are installed in the sound absorbing structure in FIG. 7.
FIG. 9 is a longitudinal cross-sectional view of FIG. 7 showing an example in which the floor finishing material is made of a finishing plate.
FIG. 10 is a perspective view of FIG. 8 showing an example of an ondol equipped with a PTC heater instead of a hot water circulation pipe.
11 is a perspective view showing another example of the heat sink in FIG. 8.

If described in detail with reference to the accompanying drawings for the present invention. Here, the same reference numerals are used for the same components, and repeated descriptions and detailed descriptions of well-known functions and components that may unnecessarily obscure the subject matter of the present invention are omitted. Embodiments of the present invention are provided to more fully describe the present invention to those skilled in the art. Therefore, the shape and size of elements in the drawings may be exaggerated for a more clear description.

1 is a perspective view of an interlayer noise prevention structure according to an embodiment of the present invention. FIG. 2 is a longitudinal sectional view of FIG. 1. 3 is a plan view of the 3D mesh mat in FIG. 1. 4 is a cross-sectional view of FIG. 3. 5 is a plan view of the sound absorbing structure in FIG. 1. 6 is a perspective view showing the lower side of the sound absorbing structure in FIG. 1.

1 to 6, the inter-layer noise prevention structure 100 according to an embodiment of the present invention includes a three-dimensional mesh mat 110 and a sound absorbing structure 120.

The three-dimensional mesh mat 110 is formed in a form partitioned by the partition walls 112 so that the through holes 111 penetrate each up and down in a regular hexagonal cross section. The partition wall 112 is formed of a micro-pillar structure having a hexagonal columnar shape having a hexagonal cross-section through-hole therein, and the micro-pillar structures are arranged in a vertical and horizontal fashion to form a honeycomb-like structure.

The micro-pillar structure is densely formed like a spider web, and may have relatively strong and robust characteristics. That is, since each micro-pillar structure is formed like a cobweb in a large amount with a thin but dense density, it acts as a pillar, so the force withstanding the load per unit area is strong, and it can sufficiently support the weight transmitted by furniture or people applied on the floor. . This is the same principle that heavy tanks do not fall out of wetlands because the weight per unit area is dispersed due to the cross-sectional area of the wheel.

The vertical height of the 3D mesh mat 110 is formed by the vertical height of the micropillar tissue. Two three-dimensional mesh mats 110 may be provided in a thickness of 5 mm and stacked in two layers, or may be composed of a single layer in a thickness of 10 mm. Of course, the thickness of the 3D mesh mat 110 is not limited to the illustrated bar, and may be variously set according to application conditions.

The 3D mesh mat 110 is formed with a space formed by the partition wall 112, that is, the internal through hole 111 of the micro-pillar structure, so that air is filled in the space, which causes the height of the micro-pillar structure between the top and bottom surfaces. As much as the air layer is formed, the air layer absorbs the light and heavy impact sound generated from the upper surface, so that the light and heavy impact sound generated from the upper surface is not transmitted to the floor surface. This is the same as the principle that the impact sound that strikes the floor with the palm of your hand is transmitted to the lower floor, but if you clap your hands to the left or right in a space of at least 1 cm above the floor, the sound is transmitted only to the inside of the room, but not to the floor.

The 3D mesh mat 110 may be made of a fabric called double raschel 3D mesh fabric, DNB 3D mesh fabric, and DNB spacer fabric. The 3D mesh mat 110 may be made of synthetic fibers that are harmless to the human body. For example, the three-dimensional mesh mat 110 may be made of at least one material selected from the group consisting of nylon fiber, polyvinyl chloride fiber, polyolefin fiber, and polyacrylic fiber.

The sound absorbing structure 120 is stacked on the three-dimensional mesh mat 110. In the sound absorbing structure 120, the protrusions 123 formed to protrude from the upper surface of the base part 121 are arranged to be spaced apart from each other horizontally and horizontally relative to the horizontal surface so as to have the air grooves 122 recessed from the lower surface of the base part 121, and the protrusions ( Between the 123), the installation groove 124 is formed in a vertical and horizontal connection.

In the sound absorbing structure 120, air grooves 122 are formed in each lower portion of the protrusions 123, and air is filled in the air grooves 122, which is similar to an air cushion held by a support. The protruding portion 123 may be formed to protrude from the upper surface of the base portion 121 as the air groove 122 is recessed from the lower surface of the base portion 121.

The protrusion 123 may be set to a certain thickness. The protrusion 123 may be set to the same thickness as the base portion 121, but is not limited thereto. The protrusions 123 all have the same shape and may be arranged vertically and horizontally at regular intervals. The protrusion 123 may protrude so that the outer circumference forms a rectangle. The protrusion 123 may be protruded such that the outer circumference forms a square. The protruding portion 123 may be rounded at the top four corner portions. The base portion 121 may be formed to have a rectangular outer circumference.

The installation groove 124 allows heat sinks 150 and 150 'to be selectively inserted and installed. The installation groove 124 is filled with only the mortar in the portion where the heat dissipation pipes 150 and 150 'are not installed, so that the sound absorbing structure 120 is sturdy and strong, so that the load transmitted on the floor can be distributed.

The installation groove 124 is defined by the top surfaces of the base portion 121 and the side surfaces of the protruding portions 123 adjacent to each other. Therefore, the bottom surface of the installation groove 124 corresponds to the upper surface of the base portion 121, and both inner walls of the installation groove 124 correspond to the side surfaces of the adjacent protrusions 123. The installation groove 124 is configured in a form in which the longitudinal installation grooves 124a and the lateral installation grooves 124b are cross-connected.

Both inner walls of the installation groove 124 may be formed to become narrower from the top to the bottom. That is, the side surface of the protruding portion 123 is inclined in a form in which the outer width is widened from the top to the bottom, so that the installation grooves 124 between the adjacent protruding portions 123 can be made narrower from the top to the bottom. have. Therefore, the installation groove 124 can smoothly flow in mortar along both inclined inner walls.

The sound absorbing structure 120 may include a reinforcement groove 125 recessed from the upper surface of the protrusion 123. The reinforcement groove 125 enables the protrusion 123 to be reinforced. When the mortar layer of the floor finishing material 160 covers the sound absorbing structure 120, the reinforcing groove 125 is introduced into the mortar inside, so that the mortar is better applied to the upper surface of the protrusion 123. The reinforcing groove 125 may be recessed from the upper surface of the protruding portion 123 and protruded to the lower surface of the protruding portion 123.

The reinforcing groove 125 may be formed in a form in which the longitudinal reinforcing groove 125a and the transverse reinforcing groove 125b cross each other. The longitudinal reinforcement groove 125a has a predetermined width and may be extended such that both ends open to both sides of the protrusion 123. The lateral reinforcement groove 125b also has a certain width and may be extended such that both ends open to both sides of the protruding portion 123. Here, although one longitudinal reinforcement groove 125a and two transverse reinforcement grooves 125b are illustrated as being connected, one longitudinal reinforcement groove 125a and one transverse reinforcement groove 125b are cross-shaped. It is also possible to be connected to, it can be configured in a variety of forms.

The sound absorbing structure 120 may include horizontal alignment protrusions 126 protruding from the upper surface of the base portion 121 to a predetermined height in the installation groove 124, respectively. The horizontal alignment protrusions 126 allow the heat pipes 150 and 150 'installed in the installation groove 124 to be horizontally aligned and aligned. Each of the horizontal alignment protrusions 126 may protrude to the same height from the bottom surface of the installation groove 124 in the form of a cylinder. The horizontal alignment protrusion 126 may be disposed at the intersection of the longitudinal installation groove 124a and the transverse installation groove 124b. Ribs connected to peripheral protrusions may be formed on the side surface of the horizontal alignment protrusion 126.

The sound absorbing structure 120 may have fastening protrusions 127 formed on two adjacent edges, and fastening pieces 128 having fastening holes 128a on the other two edges. Therefore, the sound absorbing structure 120 can be fastened to other sound absorbing structures by a fastening protrusion 127 and a fastening hole 128a. The sound absorbing structure 120 may be made of a plastic-based material such as high density resin, and may be manufactured by a method such as injection molding.

A gravity dispersion plate 130 may be disposed between the 3D mesh mat 110 and the sound absorbing structure 120. The gravity dispersion plate 130 distributes the weight transmitted from the top to the bottom surface, thereby reducing the pressure applied per unit area. The weight distribution plate 130 may be made of a cellulose reinforced cement board or the like. The top surface of the weight distribution plate 130 may be integrated with one panel by mutually adhering to the bottom surface of the 3D mesh mat 110.

According to the interlayer noise prevention structure 100, the sound absorbing structure 120 may exhibit a sound insulation effect due to the sound absorbing action of the air filled in the air grooves 122. In addition, when the sound absorbing structure 120 is applied with a mortar layer of the floor finishing material 160 to the ondol, the amount of finishing mortar is reduced by about the volume of the air grooves 122 when the mortar is applied to the entire floor, saving about half. It can be, and the load on the building can be reduced in proportion to the reduction in the amount of finishing mortar.

Since the installation groove 124 of the sound absorbing structure 120 is filled with mortar and acts as a waist post, it can sufficiently support a heavy furniture such as a piano or a bed or a person's load. In addition, the air contained in the air groove 122 of the sound absorbing structure 120 increases the insulation effect together with the air contained in the air layer of the three-dimensional mesh mat to reduce heat loss radiated to the floor by at least half.

7 is a longitudinal sectional view of an ondol according to an embodiment of the present invention. 8 is a perspective view illustrating a state in which heat radiation tubes are installed in the sound absorbing structure in FIG. 7.

7 and 8, the ondol according to an embodiment of the present invention is the above-described inter-layer noise prevention structure 100, the insulating mat 140, the heat dissipation tubes 150, and the floor finishing material 160 It includes.

The insulating mat 140 is disposed on the floor slab to stack the three-dimensional mesh mat 110. The insulating mat 140 is spread over the floor of the foam concrete floor slab to maintain a constant temperature. The heat insulating mat 140 may be made of a heat reflective heat insulating material such as a silver foil heat insulating material, or may be made of a material such as high density foamed polystyrene.

The heat dissipation tubes 150 are installed in the installation groove 124 of the sound absorbing structure 120. The heat dissipation pipe 150 may be installed by skipping one line at a time to the installation grooves 124 parallel to each other. In this case, only the mortar is filled in the installation groove 124 in which the heat dissipation pipe 150 is not installed, so that the sound absorbing structure 120 is sturdy and strong, so that the load transmitted on the floor of the room can be distributed.

The heat dissipation tubes 150 may be formed of heat pipes, respectively. A heat pipe is a mechanism in which an appropriate amount of liquid is enclosed in a vacuum tube, and when one side is heated, the liquid becomes steam and flows to the other side, and when the heat dissipates there, the liquid returns to the heating part by capillary action. . Therefore, the heat dissipation tube 150 made of a heat pipe is heated while dissipating heat at the evaporation site. The working liquid of the heat pipe may be made of distilled water or acetone.

The evaporation portion of the heat dissipation pipe 150 may be heated by the hot water circulation pipe 170. The hot water circulation pipe 170 is connected to the heat radiation pipe 150 to heat the evaporation portion of the heat radiation pipe 150 by the heat of hot water circulating inside. The hot water circulation pipe 170 may be connected to the heat dissipation pipe 150 by a coupling socket 171. The hot water circulation pipe 170 may be inserted into the installation groove 124 and installed. Therefore, the ondol can be made of a hot water heating structure.

The floor finishing material 160 covers the sound absorbing structure 120. The floor finishing material 160 may be formed of a mortar layer to form a warm type of ondol. The mortar layer covers the sound absorbing structure 120 with a mortar to the mortar finish line, thereby finishing and plastering the top surface at a horizontal level. At this time, the mortar is filled in the reinforcement groove 125 and the installation grooves 124, and accordingly, the heat dissipation pipe 150 and the hot water circulation pipe 170 in the installation groove 124 may be filled by the mortar layer. In addition, the level of the mortar finish line is the same as the upper surface of the sound absorbing structure 120 or is set higher than the upper surface of the sound absorbing structure 120 to cover the protrusions 123 as a whole. Here, by making the upper surface of the mortar layer to be a horizontal level, it is possible to facilitate the construction of a floor such as ondol floor, monolium, or the like.

As another example, as illustrated in FIG. 9, the floor finishing material 160 ′ may be composed of a finishing plate to configure ondol as a dry type. In the state in which the closing plate covers the sound absorbing structure 120, the reinforcing groove 125 remains as an empty space, and the installation groove 124 inserts the heat dissipation tube 150 and the hot water circulation tube 170 or remains empty. do. The empty spaces of the reinforcing grooves 125 and the installation grooves 124 allow the sound insulation effect and the insulation effect to be further increased. The finishing plate may be made of a fiber reinforced cement board or the like.

On the other hand, as shown in Figure 10, the ondol may be provided with a PTC heater (positive temperature coefficient heater, 170 ') instead of the hot water circulation pipe 170. That is, the ondol includes a PTC heater 170 ′ connected to the heat dissipation tube 150 to heat the evaporation portion of the heat dissipation tube 150 by heat generated by current supply. In this way, by connecting the heat dissipation tube 150 made of a heat pipe and the PTC heater 170 'that generates electricity, it is possible to configure and heat an electric heater pipe. The PTC heater 170 may be inserted into and installed in the installation groove 124 while being connected to the heat dissipation pipe 150. Therefore, the ondol can be made of an electric heating structure.

As another example, as illustrated in FIG. 11, the heat dissipation tubes 150 ′ may receive heat from outside and radiate heat. In this case, the heat dissipation pipe 150 'may correspond to an XL pipe used in the heating pipe of the hot water boiler.

A method of constructing an ondol having the above-described configuration will be described, for example, as follows.

When the ondol is a hot water heating structure, first, a heat insulating mat 140 is laid on the floor slab to be disposed. Then, the three-dimensional mesh mat 110 and the weight distribution plate 130 are stacked on the insulating mat 140. At this time, the three-dimensional mesh mat 110 and the weight distribution plate 130 may be laminated on the insulating mat 140 in an integral state by previously bonding them. Then, the sound absorbing structure 120 is stacked on the weight distribution plate 130.

Next, the heat dissipation pipe 150 is connected to the hot water circulation pipe 170 by the coupling socket 171 and then is skipped one by one in the installation groove 124 of the sound absorbing structure 120. Then, check for leaks by water pressure. Subsequently, the sound absorbing structure 120 is covered with floor finishing materials 160 and 160 '. At this time, the sound absorbing structure 120 is applied to the horizontal level with a finishing mortar to form a mortar layer, or a wet type construction is applied, or instead of the finishing mortar, the sound absorbing structure 120 is covered with a finishing plate to form a dry type, and then ondol Finish with floors or floors.

On the other hand, when the ondol is made of an electric heating structure, first, the insulating mat 140 is laid on the floor slab and placed. Then, the three-dimensional mesh mat 110 and the weight distribution plate 130 are stacked on the insulating mat 140. At this time, the three-dimensional mesh mat 110 and the weight distribution plate 130 may be laminated on the insulating mat 140 in an integral state by previously bonding them. Then, the sound absorbing structure 120 is stacked on the weight distribution plate 130.

Thereafter, the electric heat pipe having the PTC heater 170 'connected to the heat dissipation pipe 150 is skipped one line at a time in the installation groove 124 of the sound absorbing structure 120, wired, and whether it is connected and operated through commissioning. To confirm. Subsequently, the sound absorbing structure 120 is covered with floor finishing materials 160 and 160 '. At this time, the sound absorbing structure 120 is applied to the horizontal level with a finishing mortar to form a mortar layer, or a wet type construction is applied, or instead of a finishing mortar to cover the sound absorbing structure 120 with a dry type, followed by a dry type, ondol Finish with floors or floors.

The present invention has been described with reference to one embodiment shown in the accompanying drawings, but this is only exemplary, and those skilled in the art can understand that various modifications and other equivalent embodiments are possible therefrom. Will be able to. Therefore, the true protection scope of the present invention should be defined only by the appended claims.

110..3D mesh mat
120..Sound absorption structure
122..Air home
123..Protrusion
124..Installation home
125..Reinforcement Home
126..Horizontal alignment
130..Gravity dispersion
140..Insulating mat
150, 150 '.. heat pipe
160, 160 '.. Floor finish
170..Hot water circulation pipe
170 '.. PTC heater

Claims (8)

A three-dimensional mesh mat formed in a form partitioned by partitions so that the through holes penetrate each up and down in a regular hexagonal cross section; And
As being stacked on the three-dimensional mesh mat, the protrusions protruding from the upper surface of the base part are arranged to be spaced apart from each other horizontally and horizontally relative to the horizontal surface so as to have air grooves recessed from the lower surface of the base part, and the installation grooves are connected horizontally and horizontally between the protrusions. Sound absorbing structure made of a shape;
Interlayer noise prevention structure comprising a. According to claim 1,
The sound absorbing structure,
An interlayer noise prevention structure comprising a reinforcing groove recessed from the upper surface of the protrusion. According to claim 1,
The sound absorbing structure,
Interlayer noise prevention structure, characterized in that it comprises horizontal alignment projections respectively protruding from the upper surface of the base portion at a certain height in the installation groove. According to claim 1,
And a gravitational dispersion plate disposed between the 3D mesh mat and the sound absorbing structure. The interlayer noise prevention structure according to any one of claims 1 to 4;
A heat insulating mat disposed on the floor slab to stack the 3D mesh mat;
Heat dissipation tubes installed in the installation groove of the sound absorbing structure; And
A floor finishing material made of any one selected from a mortar layer and a finishing plate to cover the sound absorbing structure;
Ondol containing. The method of claim 5,
The heat dissipation tubes are each made of a heat pipe;
And a hot water circulation pipe connected to the heat radiation pipe to heat the evaporation portion of the heat radiation pipe by the heat of the hot water circulating inside. The method of claim 5,
The heat dissipation tubes are each made of a heat pipe;
Ondol, characterized in that it comprises a PTC heater (positive temperature coefficient heater) connected to the heat sink to heat the evaporation portion of the heat sink by the heat generated by the current supply. The method of claim 5,
The heat pipes are ondol, characterized by receiving heat from the outside and dissipating heat.

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