KR100489193B1 - Floor structure of residential house - Google Patents

Abstract

The present invention in the floor structure of a multi-family house to construct the ondol layer, the bottom structure of the present invention to form a floating floor structure having an ondol layer on the floor slab 27, the cushioning material 26, the waterproof film 25, The cement mortar layer 22 and the finishing material 21, on which the hot-water heating pipe 24 for heating is installed, are sequentially stacked. The buffer material 26 has a density of 80 kg / m 3 to 200 kg / m 3 and a thickness of 35 mm. It is a rock wool series heat insulating material of -100 mm, It is characterized by the above-mentioned. The floor structure of the present invention has the effect of reducing the interlayer noise, such as floor impact sound and satisfying the vibration performance of the floor.

Description

Floor structure of residential house

The present invention relates to a floor structure of a multi-family house for constructing an ondol layer, and more particularly, to a floor structure for a multi-family house to reduce the noise between floors such as floor impact sound and to satisfy the vibration performance of the floor.

As a method for preventing interlayer noise, a method of increasing the structure, a method of improving the finishing material, a method of inserting a cushioning material into a floor structure, a method of designing a sound absorbing ceiling structure, and the like can be given. The thickness of the structure is mainly determined by the structural design, and the finishing material and ceiling structure are also determined by the architectural plan. Therefore, it is often difficult to change these parts only to improve the floor impact sound performance. Therefore, in some cases, the method of inserting the cushioning material inside the floor structure is often the only option, and the impact sound performance can be improved without changing the thickness of the floor structure, which is currently being actively researched and developed in Korea. It is part. Currently, dozens of specialized companies in Korea are developing and selling shock absorbers for inter-layer noise blocking, as summarized in Table 1 below.

Most domestic buffer manufacturers in Table 1 are small and small, and their life span is also short, so it is difficult to synthesize and accumulate related technologies. In addition, as can be seen from the noise blocking performance suggested by each company, the degree of performance improvement according to the construction of the buffer material for each product has not been clearly identified, and most of the buffer material is expensive, and in some products, high process density Is a problem, such as rising prices and defects.

Overseas noise reduction technology developed mainly in Japan and Europe. In the United States, the floor structure of a residential building, the type of floor impact sound, and the social perception of the floor impact sound are quite different from the domestic situation, and as a consideration for this, a finishing material (carpet) and a suspended ceiling are used. The related art related to the development of the floor structure in the direction of is rare.

In Japan, JIS 1419 was drafted in 1974 as a standard for evaluating the sound insulation performance of floor impact sound in apartments. Since the enactment of JIS in 1978, the JIS standard was developed in the form of "sound insulation performance standards and design guidelines" (Japan Institute of Architects) .The so-called "floating floor" structure using a cushioning material has a construction standard and a commentary (Japan Materials Association, 1978). It is prepared. Table 2 below summarizes the impact sound performance of floor structures measured for many years in Japan. Today, these data provide the basis for predicting the performance of floor structures. However, the floor structure of Japan does not use ondol heating as shown in Table 2, so the structure of the upper part of the cushioning material is different from that of Korea, and therefore, a unique "floating floor" structure is required in Korea.

European technology for reducing the noise between floors can be classified into a method of increasing the floor slab thickness and a method of constructing a "floating floor" structure using a cushioning material, and the application thereof is shown in Table 3 below.

In Germany, the floor impact sound reduction method has been applied to the floor of multi-unit houses for about 40 years ago.In 1963, the DIN standard for the structure of the floating floor was enacted, and the floor was used in single-family houses as well.

In the Netherlands, as in other countries in Europe, floating floor structures are applied to the concrete slab, which is a floor structure. The general floor structure of a Dutch residential building consists of 'slab (160 mm) + buffer layer (10-25 mm) + finish mortar (50 mm) + carpet', and there are not many cases where floor heating is applied like in Germany. .

In Europe, as in Japan, there are not many buildings that heat ondol, and in some cases, they are used in large space structures or walls, such as gymnasiums, which are non-residential buildings, and the upper structure of the buffer layer is different from that in Korea.

However, in Korea, more than 90% of all residential buildings are being built in the form of multi-family housing, and the lifestyle is also composed of sedentary life. In this regard, one of the biggest complaints of residents living in MDUs is the noise problem between neighboring households, and the floor shock sound problem caused by children playing in the upper class housing is also one of the challenges facing domestic MDUs.

As a basis for the solution, the institutional standard for floor impact sound is established, and the work of enactment and amendment is also carried out. These performance criteria for floor impact sound differ from one country to another according to cultural characteristics, lifestyle, residential method, construction technology, etc., and are different from neighboring neighboring Japan. The performance criteria for floor impact sound related to domestic life habits are currently 'Industrialized Housing Performance Standards', which are established under the Industrialized Housing Certification System as shown in Table 4 below.

Compared to Japan, which has a performance standard for heavy impact sound, similar to Korea, due to the difference in floor structure, the domestic standard has enhanced heavy impact sound performance and light impact sound performance compared to Japan. On the other hand, in 1989, the Korea Housing Corporation proposed the floor impact sound limit level similar to level 3 of the performance standard of industrialized houses.

The graph of Figure 1 is an example of measuring the floor impact sound performance of the actual construction apartment in Pohang Industrial Science Institute (1999). The horizontal axis of the graph shows light impact sound performance, the vertical axis shows heavy impact sound performance, and the shades by color are the performance criteria mentioned above.

Square points in the graph of FIG. 1 show measurement results, and most apartment houses did not meet the performance criteria. In the graph of FIG. 1, the case of second-class measurement is a hotel-type condominium, and the case of 'steel-frame' is a steel-framed apartment with a half-width space of more than 700 mm in the ceiling structure, and the sound absorption performance is excellent in this space. The impact sound performance was analyzed to be excellent.

As can be seen in the example of the graph of Fig. 1, the floor shock sound performance in the domestic reality is a technology that is quite difficult even to satisfy the lowest standard of grade 3, the performance of the grade 1 or more by inserting a cushioning material while maintaining the thickness of the existing floor structure As you can see, improving is a very difficult task.

In recent years, residents' demands for improving the quality of buildings have been increasing, and despite the high sale prices, the expectation that the general public would have improved the housing performance of the steel-framed apartments compared to the existing apartments, After the sound insulation performance, the most important research on the floor impact sound has attracted a lot of attention in some large companies. In particular, when the Ministry of Land, Infrastructure, and Transport has recently gathered opinions from all walks of life to establish the standards for cut-off performance for floor impact sound, it is meaningful to provide more reliable and economical measures for floor vibration and impact sound.

At present, some large corporations use floor insulation materials at a considerable cost, but do not use accurate understanding of the transmission path and transmission characteristics of the floor shock sound, and there are many cases where complaints arise because there is little performance improvement. Therefore, to grasp the performance of various soundproof materials developed by recent tenants and policy requirements, investigate the performance improvement when applied to domestic ondol components, and fundamentally predict the floor impact sound at the design stage. Theoretical research needs to be parallel to be applicable in the field.

In addition, due to the long span of the pillars of the building, including steel framed apartments, the use of floor vibrations has been a lot of problems. However, in the past, the floor vibration problem was limited only to the area of the building structure and examined at the design stage, and the vibration performance and the analysis value of the actual building showed much difference. Here, the ondol floor of a residential building can be considered as a factor affecting the floor vibration. The sound insulation material used to improve the floor impact sound performance has a significant effect on the floor vibration performance by changing the dynamic characteristics of the ondol floor. Therefore, the residential performance of the building floor must be considered at the same time, floor vibration and impact sound can be found.

Accordingly, the present invention has been made to solve the problems of the prior art as described above, and an object thereof is to provide a floor structure for a multi-family house to reduce the noise between the floors such as floor impact sound and to satisfy the vibration performance of the floor.

According to the present invention for achieving the above object, in order to form a floating floor structure having an ondol layer on the floor slab, a buffer material, a cement mortar layer installed with a hot water pipe for the heating on the floor and a finishing material are sequentially laminated on the floor structure of the apartment house In the buffer member, the density is 80 kg / m 3 to 200 kg / m 3, and the thickness is a rock wool series heat insulating material having a thickness of 35 mm to 100 mm.

In the following, with reference to the accompanying drawings a preferred embodiment of a floor structure of a multi-family house according to the present invention will be described in detail.

2 is a schematic diagram showing a floor structure of a multi-family house. As shown in Fig. 2, the floor structure is provided with a cushioning material 26 for forming a "floating floor" on the floor slab 27 which is a structure of the building, and the cement mortar 22 on the upper part of the buffer material 26. Install a waterproof film 25 for waterproofing. And, on the top of the waterproof film 25 is installed a cement mortar (22) layer and hot-water heating pipes 24 embedded therein in the same manner as the existing floor structure, immediately above the hot water pipes 24 The wire mesh 23 is installed, and the finishing material 21 is packed at the top of the floor structure. In addition, the lower half slab 27 is formed with a half-width space 28 and half-width 29 forming a ceiling structure.

As the shock absorbing material 26 for reducing the noise between floors, a high density product should be used so as not to be pressed by the worker's walking during construction, and it should be excluded that it is too heavy to facilitate transportation by the worker.

Thus, the present inventors performed vibration performance and impact sound performance for a plurality of shock absorbers, respectively, in order to select the most suitable shock absorbers for the floor structure.

 Figure 3 is a graph measuring the vibration performance for the floor structure using a variety of buffers. As can be seen in the graph of FIG. 3, when compared with a floor structure composed of a structure without an ondol layer (conc. 150), which is a criterion for evaluating the vibration performance of the floor structure, the glass surface (GW3250, GW9650) and other 1 Vibration performance is worsened in the existing products (ES), glass surface products (GW series) was excluded as a buffer of the floor structure of the present invention.

Figure 4 is a graph measuring the floor impact sound performance for the floor structure using a variety of cushioning materials. 4 represents various shock absorbing materials, and the vertical axis represents floor impact sound performance. The floor shock sound performance is an index indicating the transmission level of the impact sound generated in the upper layer, and the smaller the value, the better the performance. The red bar in the graph of FIG. 4 represents the heavy impact sound performance, and the blue bar represents the light impact sound performance.

As can be seen in the graph of Figure 4, the GW series and the MW series floor impact sound performance was found to be excellent. The GW series is a glass wool product, and the vibration performance is not excellent and the product excluded from the cushioning material of the present invention (see Fig. 3), the MW series is a rock wool product, excellent vibration performance and floor impact sound performance of the floor structure of the present invention It is used as a buffer material to comprise.

On the other hand, among the buffer material IL is a product that is released as a prototype to be used in the floor noise reduction floor structure, MW series and floor impact sound performance is equal, but as shown in the graph of Figure 3 is inferior vibration performance. In addition, IL is more than five times more expensive than the MW series and is a product that requires construction by professional personnel, it was excluded from the present invention.

Through the comparison of the floor impact sound of FIG. 4, it is possible to sufficiently predict that the buffer material of the rock wool series (MW series) constituting the floor structure of the present invention has an excellent interlayer noise reduction effect compared to other buffer materials, and reduces the equivalent interlayer noise. Construction is easier than other structures having an effect, and there is an advantage that can be cheaply constructed.

As can be seen from the above experimental results, the rock wool series has better vibration performance than the glass surface series, and it can be confirmed that the rock surface series is ideal as a buffer material constituting the floor structure.

Thus, in the present invention, the buffer material is used as a rock wool insulation material, but the density is 80kg / ㎥ ~ 200kg / ㎥, the thickness of the floor structure was developed using a rock wool insulation insulation having a thickness of 35mm ~ 100mm. Application of the rock wool insulation material having such a range to the present invention is based on the following reasons.

In the case of the density of the cushioning material, the product used as the insulation material in the existing construction work is mainly 30 ~ 60㎏ / ㎥ and excellent insulation performance, but when it is installed on the floor, the phenomenon occurs that is pressed according to the walking of the operator, so bridge), etc. There is a problem that occurs. Limiting the cushioning material used in the present invention to 80kg / ㎥ or more is considering the situation that the current product is produced, such as 80kg / ㎥, 96kg / ㎥, 100kg / ㎥, 150kg / ㎥. That is, in the present invention, the rock wool-based heat insulating material currently on the market is used as a cushioning material.

In addition, the buffer material constituting the floor structure of the present invention has a higher density, the workability is advantageous, but considering the cost and weight problems, it is preferable to use a product of 200kg / ㎥ or less.

In addition, according to the insulation standard for each building part revised in 2001, it is required that the insulation material of rock wool system should be installed more than 35mm when floor heating is performed as interlayer floor of MDU in the central region. Therefore, in the present invention, the thickness is limited to 35 mm or more in consideration of the insulation standard. In addition, there is a case in which the insulation used in the floating floor structure of advanced foreign countries such as Germany and France is designed to be 75mm or more, and it is known that the performance is improved as the thickness of the cushioning material increases. However, it is practically impossible to increase the thickness of the cushioning material to 100 mm or more in domestic conditions in which an ondol layer having a heat storage layer having a thickness of about 50 mm on the upper part of the buffer material is practically impossible, and the thickness is preferably 100 mm or less.

In addition, in constructing the floor structure of the present invention, a wire mesh 23 is disposed on the cement mortar layer 22 formed on the cushioning material 26 so that the cement mortar layer 22 is not damaged by the load of the building. It is preferable to construct.

In addition, in constructing the floor structure of the present invention, in order to omit the process of installing the waterproof film 25 on the upper portion of the shock absorbing material 26, the use of waterproof film-attached rockwool boards that are expected to be produced in accordance with future regulations You may.

That is, the present invention can be configured by using a rock wool-based heat insulating material that is integrally attached to the buffer film in the cushioning material without using a separate waterproof film. The rock wool series heat insulating material with such a waterproof film has a density of 80 kg / m 3 to 200 kg / m 3 and a thickness of 35 mm to 100 mm.

In addition, the floor structure of the present invention by using the rock wool series used in the existing building construction, it can omit the lightweight foam concrete process that was originally constructed in the cushioning material site is required for equipment such as mixers, pumps, etc. required for this process You can save money. In addition, the floor structure of the present invention is not particularly difficult construction process can be fully constructed by non-professional workers, there is an advantage that can be installed more than twice cheaper than the buffer material for the "floating floor" structure is currently released as a prototype.

In addition, according to the "Building Energy Conservation Design Standards" revised from June 2000, insulation performance is regulated even when floor heating is performed on the floors of multi-unit houses, and insulation materials of 30 mm or more are required to be installed. In constructing the floor structure of the present invention, by installing a rock surface of about 50 mm in the floor structure, it is possible to satisfy the revised insulation standard without additional insulation work.

As described in detail above, the floor structure of the multi-family house of the present invention not only can greatly reduce the noise between floors by using rock wool-based buffer material, but also has excellent vibration performance than existing products having equivalent performance, and is cheaply and quickly installed. This has a possible advantage.

In addition, the floor structure of the multi-family house of the present invention has the effect of satisfying the revised insulation standard without a separate insulation work.

The technical details of the floor structure of the multi-family house of the present invention have been described above with the accompanying drawings, but the exemplary embodiments of the present invention have been described by way of example and are not intended to limit the present invention.

In addition, it is obvious that any person skilled in the art can make various modifications and imitations without departing from the scope of the technical idea of the present invention.

1 is a graph showing a case of measuring the floor impact sound performance of the actual construction apartment,

Figure 2 is a schematic diagram showing a floor structure of another multi-unit house in one embodiment of the present invention,

3 is a graph measuring the vibration performance of the floor structure using a variety of shock absorbing material,

Figure 4 is a graph measuring the impact sound performance for the floor structure using a variety of cushioning materials.

  ♠ Explanation of symbols on the main parts of the drawing ♠

21: finish 22: cement mortar

23: wire mesh 24: hot water pipe

25: waterproof film 26: cushioning material

27 floor slab 28 half-width space

29: half-width characters

Claims (3)

In the floor structure of a multi-family house in which a buffer material, a cement mortar layer in which hot water pipes for heating on-heat is installed, and a finishing material are sequentially stacked to form a floating floor structure having an ondol layer on the floor slab, The cushioning material is a rock wool series heat insulating material having a density of 80 kg / m 3 to 200 kg / m 3 and a thickness of 35 mm to 100 mm, Floor structure of a multi-family house, characterized in that the wire mesh is installed on the upper portion of the hot water pipe. delete According to claim 1, wherein the cushioning material is a floor structure of a multi-family house, characterized in that the waterproof film is integrally attached.