KR100418277B1 - construction of ground for plural storey building and construction method there of - Google Patents

Abstract

The present invention relates to a floor structure of a multi-storey building and a construction method thereof to reduce noise between each layer and heat loss of the hot water pipes disposed in the multi-storey building. A sound insulation unit on which the sawdust and the additive are respectively formed in the state of particles in a thickness of a predetermined volume ratio on the slab surface of each space divided by the wall and the slab; A watertight portion provided on an upper portion of the sound insulation portion to prevent penetration of moisture from the upper portion of the space with respect to the sound insulation portion; And a finishing mortar disposed in a predetermined thickness on an upper portion of the watertight portion. According to this, the granular sawdust having a low thermal conductivity and mechanical rigidity is arranged in a rigid bonding structure of mutual cell structure (scale arrangement or wood grain arrangement), so that sufficient mechanical stability for the composition such as finishing mortar on the upper part thereof is achieved. At the same time has the effect of having improved sound insulation and heat insulation and insulation.

Description

Floor structure of multi-storey building and construction method thereof {construction of ground for plural storey building and construction method there of}

The present invention relates to a floor structure of a multi-story building and a construction method thereof, and more particularly, in the construction of a multi-story building, the floor structure of the multi-story building to reduce noise and heat loss of the hot water pipes disposed between the floors and the same. It is about a construction method.

The general buildings of the present society are constructed in a multi-layered structure in which a plurality of spaces are separated to maximize land utilization. Each space divided in this way is shared between the slabs and walls between each space. As a result, each slab and the wall have a function of blocking a specific environmental factor of each space, that is, internal temperature and various noises, from being transferred to another neighboring space. In particular, the floor structure including the slab is required to have a function to limit the temperature from the hot water pipe to the target space without heat loss, as in a Korean residential environment that heats the internal space through the hot water pipe disposed on the floor of the space. The construction of a floor structure including a slab is increasingly emphasized in the construction of a multi-layered structure, such as a function of preventing the floor impact sound generated inside the space from being transmitted to the lower floor space.

In this relationship, reference is made to the accompanying drawings for the construction of the floor structure of a multilayered building according to the prior art which functions to reduce the floor impact sound for the lower floor space and to prevent the internal temperature from transferring to the lower floor. This will be described.

As shown in FIG. 1 or 2, a floor structure of a conventional multi-story building is formed by partitioning a wall having a predetermined size into layers by a wall 10 and a slab 12, and forming a slab 12. On the upper surface, the expanded ceramic mortar 14 having porosity is widely installed and hardened to a predetermined thickness. The hot water pipe 16 is arranged on the upper surface of the foamed ceramic mortar 14 installed and hardened in this way, and the hot water pipe 16 is commonly used in concrete nails 18, etc., projected to a predetermined height on the foamed ceramic mortar 14. It is tied with wire or string and fixed. Then, the finishing mortar 20 for forming the bottom of the space more flat to the upper side of the foamed ceramic mortar 14 in which the hot water pipe 16 is disposed is widely installed and hardened to a predetermined thickness to finish the floor construction.

However, in the floor structure of such a structure, the foamed ceramic mortar 14 has a porosity, it can be seen to reduce the temperature transition and the floor impact sound to some extent compared to the general concrete mortar, but firmly in a rigid structure of a monolith with high thermal conductivity As the temperature is transferred and the impact sound is transmitted in each direction from the impact position P, the effect is insufficient. In addition, it is relatively lighter than concrete mortar in response to the high rise of the building, but because of its high weight, the effect was also insufficient to cope with the high rise. In addition, even in the above-described hot water pipe 16, the foamed ceramic mortar 14 is formed in the process of hardening and the surface of the non-uniform irregularities of the pipe support plate for installing the hot water pipe 16, etc. The panel (omitted for the sake of simplicity) is difficult to fix such as lifting from the surface, which not only causes cracking of the finishing mortar 20 to be laid later but also has a lot of difficulty in forming the flat surface. Will be. Accordingly, the excavation of the hot water pipe 16, hitting the concrete nail 18 to the foamed ceramic mortar 14 one by one, and fixed the hot water pipe 16 by using a wire or a string here, a lot of work Time and labor of the worker is required, there was an inefficient problem such as requiring a high degree of skill to form a flat surface of the finishing mortar (20). In addition, cracks may occur due to shrinkage of the foamed ceramic mortar 14 and the finishing mortar 20, and thus, the wire mesh may be formed when the foamed ceramic mortar 14 or the finishing mortar 20 is laid. (For the sake of simplicity), use of such a member is required, such as difficulty in work and an uneconomical problem.

On the other hand, in the prior art for the floor structure, concrete composition for thermal insulation and sound insulation in which waste tire pulverization disclosed in the Republic of Korea Patent Publication No. 96-17568 is mixed, but can be useful in terms of utilizing waste resources, As a hard structure is achieved, the sound insulation performance is very poor, and the uneven portion of the surface is severe, and thus the panel and the like are difficult to be fixed.

In addition, the sound absorbing damping material disclosed in Korean Patent Publication No. 97-27190 has a problem in that it is difficult to secure satisfactory mechanical stability in the supporting structure including the finishing mortar 20 due to the use of fibers.

In addition, the floor soundproofing (soundproofing) material disclosed in Korean Patent Publication No. 97-69939 had a difficult relationship at the same time including the thickness relationship of the floor structure in securing mechanical safety and expressing impact reduction performance. .

To summarize the problems of the prior art for such a floor structure, the structure for the impact sound reduction effect is generally to use a member having a sheet shape, these sheet-shaped members are formed so as to have a mechanical stability It is difficult to fix on the slab 12 of the non-uniform surface, the relatively flexible sheet is difficult to secure mechanical stability, and also difficult to form a light weight and high thickness of the floor structure stably for high layer In addition, there is a problem such as a high cost due to the difficulty of the installation work and the cost according to the production formation.

In addition to this problem, the finishing mortar 20 which is installed to form a flat surface of the floor structure is difficult to set the reference height, and requires a high level of skill, and includes a wire mesh in response to cracking caused by the contraction. A separate member is required, and in the bottom structure, there is a further problem that does not solve the impact acting on the finishing mortar 20 is transmitted through the wall 10.

An object of the present invention is to meet the above-mentioned problems and requirements of the prior art, so that the sawdust of the granular structure having low thermal conductivity and mechanical rigidity is laid on the surface of the slab at a predetermined thickness so that these sawdusts are mutually organized. The multi-layered building, which is arranged in a rigid coupling structure (scale arrangement structure or wood grain arrangement structure), has sufficient mechanical stability for the construction of the finishing mortar, etc. at the top thereof, and further improves sound insulation, insulation, and heat insulation. To provide a floor structure and its construction method.

In addition, the thickness of each floor can be adjusted appropriately, and the weight is reduced according to the thickness to facilitate the multi-layered building, the economics through the reduction of the material cost, and the work including the panel installation regardless of the unevenness of the slab surface. To facilitate this, to reduce the working time and labor of the worker, and to provide a floor structure of the multi-storey building and its construction method so that the surface by the following finish mortar is uniform.

In addition, the floor structure of the multilayered building and its construction method to prevent cracking due to shrinkage of the finishing mortar without using a member such as a wire mesh, and to prevent the impact sound acting on the finishing mortar from being transmitted through the wall. In providing it.

1 is a partial cross-sectional perspective view schematically showing the structure of the interlayer floor structure of the conventional multi-storey building and the coupling relationship between these components.

2 is a cross-sectional view showing a coupling relationship of the floor structure shown in FIG.

3 is a partial cross-sectional perspective view schematically showing the floor structure of the multi-storey building according to an embodiment of the present invention and the coupling relationship between these configurations.

4 is a cross-sectional view schematically showing the coupling relationship of the floor structure shown in FIG.

FIG. 5 is a perspective view illustrating a plane configuration of the panel illustrated in FIG. 3.

FIG. 6 is a perspective view illustrating a bottom structure of the panel illustrated in FIG. 3.

*** Explanation of symbols for the main parts of the drawing ***

10: wall 12: slab

14: foamed ceramic mortar 16: hot water piping

18: Concrete nail 20: Finish mortar

30: sound insulation foam pad 32: sound insulation

34 panel 36: partition

38: sealing member 40: seat groove

42a, 42b: Rib 44: Upper protrusion

46: lower protrusion 48: protrusion

50: fastening groove 52: support member

54: reference bar

Floor structure configuration of a multi-storey building according to the present invention for achieving the above object, by adding a sawdust and an additive in a predetermined volume ratio to each of the slab surface of each space partitioned by at least one or more walls and slabs, each of which is a particulate state A sound insulation portion which is formed in a layer having a predetermined thickness while maintaining the same; A watertight portion provided on an upper portion of the sound insulation portion to prevent penetration of the sound insulation portion from an upper portion of the space; And a finishing mortar disposed in a predetermined thickness on the upper portion of the watertight portion. In addition, the sound insulation foam pad formed in a predetermined width, thickness and length to set the thickness of the sound insulation portion, the watertight portion and the finishing mortar; may be further provided in close contact with the adjacent portions of the wall and the slab. The sawdust forming the sound insulation may have a volume ratio of 70 to 95, and the additive may have a volume ratio of 5 to 30. On the other hand, the watertight portion, a plurality of panels having a predetermined thickness, area and shape can be made to be coupled to maintain the airtight with respect to the upper and lower parts. In addition, the panel is partitioned to form a honeycomb shape on the upper surface and protrudes a predetermined height; Seat grooves formed on the partitions so that the side portions of the hot water pipes are fitted from above; A rib formed to protrude to have a support force between the partitions; A support part protruding downward from a lower surface in a honeycomb shape to prevent the sawdust and additives from flowing; Upper and lower protrusions forming a shape protruding in a shape intersecting with another side portion adjacent to the side portion; A protrusion forming a shape protruding downward with a predetermined interval on a lower surface of the upper protrusion; And a fastening groove formed to correspond to the protrusion on the upper surface of the lower protrusion. And, in installing the respective panels, the excess portion of each panel with respect to the space may be configured to seal using a separate sealing member and an auxiliary panel of a predetermined shape.

On the other hand, the floor structure construction method of the multi-sided building according to the present invention for achieving the above object, by adding a sawdust and an additive in a predetermined volume ratio on the surface of the slab of each space divided by the wall and the slab in a predetermined volume state Forming a sound insulation of thickness; Forming a watertight portion on an upper surface of the sound insulation portion to prevent penetration from an upper portion thereof; And arranging a finishing mortar at a predetermined thickness on an upper portion of the watertight portion. And, before the sound insulation portion forming step, to install a sound insulation foam pad having a predetermined thickness, width and length in the edge portion adjacent to the wall and the slab to set the thickness position of the sound insulation portion, the watertight portion and the finishing mortar Step; may be further provided.

Hereinafter, with reference to the accompanying drawings, the present invention for the construction of the floor structure and the construction method of the multi-layered building will be described in more detail.

FIG. 3 is a perspective view partially cut out to explain the construction of a floor structure of a multi-story building according to an embodiment of the present invention, a coupling relationship between the components, and a construction method thereof, and FIG. 4 is a bottom view of FIG. 3. 5 and 6 are a perspective view and a bottom view showing the planar configuration of the panel shown in FIG. 3, and the same reference numerals are given to the same parts as in the prior art, and thus detailed The description will be omitted.

As shown in FIG. 3, the floor structure of the multi-layered building according to the present invention is formed by partitioning a space having a predetermined size into each layer by the wall 10 and the slab 12, and the slab of each space ( On the upper surface of 12) sawdust having a predetermined particle size and the additive is covered with a thickness of a predetermined volume ratio to form a sound insulation (32). In the construction of the sound insulation part 32, the above-mentioned sawdust makes up a volume ratio of about 70 to 95, and the above-mentioned additives are mixed to form a volume ratio of about 5 to 30, and the surface of the slab 12 is maintained to maintain its particle state. By covering it. At this time, the additive is added to the sawdust for the insect repellent and preservation quicklime and charcoal powder is added in a volume ratio of about 3 to 7, in addition to other preservatives, insect repellent chemicals may be added. In addition, waste tire chips or rubber chips are added to the additive to form a volume ratio of about 2 to 27 and mixed uniformly. The sound insulation part 32 is chopped by the worker in a state covered on the surface of the slab 12, wherein the sawdust and additive particles are mixed with each other to form a cell structure (scale arrangement or wood grain shape) to act from the upper side Sufficient mechanical rigidity structure is achieved with respect to force. In addition, as described above, prior to forming the sound insulation portion 32 composed of sawdust and additives, vibration sound is provided at the edge portion of the wall 10 and the slab 12 adjacent to the wall 10. 10) it is preferable to install the sound-proof foam pad 30 of the soft synthetic resin material that can absorb the vibration sound so as not to be transmitted through first. In addition, the soundproof foam pad 30 installed in this way is to determine the height of the total thickness of the floor structure after.

Meanwhile, as described above, as illustrated in FIG. 3 or 4, sawdust and additives are firmly bonded to each other from the upper side to the upper portion of the sound insulation part 32 covered with the predetermined thickness of the slab 12. Watertight portion is formed to block to some extent the liquid material containing water to penetrate. The watertight portion is formed by connecting the plurality of panels 34 having a predetermined area and thickness in close contact with each other in the process of compacting the sound insulation portion 32 described above.

In addition, in the configuration of the panel 34 described above, as shown in FIG. 5, the partition 36 has a honeycomb shape and protrudes a predetermined height on an upper surface thereof, and the hot water pipe 16 of each of the partitions 36 is formed on the partition 36. The seat groove 40 is formed to be supported by the side portion from the upper side. In addition, ribs 42a are formed to protrude between the partitions 36 adjacent to each other so as to more firmly maintain the protruding shape in addition to the mutual supporting force. And the rib 42b of the shape which protrudes downward from the lower surface also is formed in the lower surface of the panel 34 mentioned above in the honeycomb shape so that the sawdust and the additive of the particle state corresponding to the lower side may be prevented. In addition, on the side of the panel 34, the upper protrusion 44 and the lower protrusion 46 are formed to protrude in a predetermined shape so as to form a shape overlapping with the side of the other panel 34 adjacent to each other, wherein, A plurality of protrusions 48 having a predetermined thickness formed to protrude downward are formed on the lower surface of the upper protrusion 44, and each protrusion 48 is inserted into the upper surface of the lower protrusion 46 corresponding to the protrusions 48. A fastening hole or a fastening groove 50 is formed, and the adjacent panels 34 are coupled to each other by combining the protrusions 48 and the fastening grooves 50 with each other. The configuration of the panel 34 having such a shape may be integrally formed in the manufacturing process, or may be formed in a configuration in which each configuration is assembled. And in installing each of these panels 34, the upper part of the space | part, ie, the excess site | part by the coupling | bonding of the panel 34 with respect to the corresponding site | part of the above-mentioned soundproof foam pad 30, of the upper and lower sides through the site | part The separate sealing member 38, such as a separate auxiliary panel (to simplify the drawing, is omitted) to prevent the penetration of liquid substances such as moisture, is cut and connected to each other, or the aforementioned panel 34 is required. It can also be configured to cut to size to be connected. In addition, when the area of the slab 12 in the space in which the plurality of panels 34 described above are formed is an area of a predetermined range or more, the load to the upper side of each panel 34 is coupled to a predetermined position of the center portion thereof. A separate support member 52 may be further provided to prevent the panel 34 of the portion including the sound insulation unit 32 from being settled, and the support member 52 may be settled by the panel 34. It is preferable to use one capable of providing sufficient support in response to the above and at the same time cushioning or mitigating vibration or noise against an impact from the upper side thereof.

As described above, when the above-described panels 34 are installed together with the auxiliary panel or the sealing member 38 to prevent penetration of the sound insulation 32 above, the seat grooves 40 formed in the partitions 36 on the upper side thereof. ) Will be installed in the form of fitting the hot water pipe (16). In addition, at a predetermined position of each partition 36, the reference rod 54 for setting the reference position so that the height of the finishing mortar 20 disposed thereon is the same as that of the soundproof foam pad 30 and is made uniform overall. One or more are provided. In this state, the finishing mortar 20 is installed above the watertight part, and the finishing mortar 20 to be installed penetrates between the partition 36 and the ribs 42a and the hot water pipe 16 described above. From the soundproof foam pad 30 and the reference bar 54 to form a layer of uniform thickness from. Here, as described above, the finishing mortar 20 is laid and contracted is subjected to a force that is firmly supported so that no crack is generated by the honeycomb-shaped partitions 36, ribs 42a, and the like.

According to this configuration, the operator installs and installs the sound-proof foam pad 30 in a conventional manner in a portion where the wall 10 and the slab 12 of the space partitioned to a predetermined size are adjacent to each other, and the slab 12 partitioned in this manner. The sound insulation part 32 which mixed a predetermined additive with the sawdust as a main raw material on the surface is installed in predetermined thickness. In this case, the sound insulation portion 32 to be installed is covered with a thickness of about 40 to 80 mm, that is, the thickness reaching the intermediate position of the soundproof foam pad 30 described above, thereby compacting the upper portion thereof. The plurality of panels 34 having a predetermined area are adjacent to the upper surface of the sound insulating portion 32 thus compacted, and the upper and lower protrusions 44 and 46 are positioned to connect with each other so as to be connected to each other. 32) to form a watertight portion to prevent penetration. In addition to the connection configuration of the plurality of panels 34 installed in this way, an auxiliary panel or a sealing member for preventing penetration thereof is separately provided at an edge portion or a corner portion of the space, and at least one support is provided at the center portion of the space. The member 52 may be provided so as to cope with the settlement of the sound insulation 32 by the load from the upper side. And the honeycomb rib 42b formed in the lower part of the panel 34 mentioned above receives a support force so that there may be no flow by inserting the granular sawdust or additive which forms the lower sound insulation part 32, and from the upper side By uniformly distributing the load action to the sound insulating portion 32 is to make a stable force distribution.

On the other hand, in the upper portion formed with the water-tight portion, the hot water pipe 16 is easily installed in the seat groove 40 formed in the partition 36 of the panel 34 to be easily installed, and formed on the upper part of the panel 34. On the partition 36 or the rib 42a, as shown in FIG. 4, the reference | standard rod 54 which sets the reference position of the same height as the height of the soundproof foam pad 30 is provided. Finishing mortar 20 is installed on the upper side of the water-tight part in this state, the operator overall plastering the height of the upper surface by the finishing mortar 20 on the basis of the height of the soundproof foam pad 30 and the reference rod 54. As a result, a flat bottom surface is formed.

When the finishing mortar 20 is sufficiently hardened through this process, the bottom impact acting on the upper part of the finishing mortar 20 is dispersed through each panel 34 in the finishing mortar 20 and is applied to these panels 34. The vibrations or impact sounds of the dispersed shocks are absorbed by the sound insulation unit 32 disposed below the bottom, thereby effectively blocking the noise transmission to the lower space. In addition, the sound insulation part 32 mentioned above becomes high in heat insulation efficiency because the main component consists of sawdust, and it becomes sufficient to limit the temperature from the hot water piping 16 arrange | positioned on the panel 34 to the upper space. In addition, the vibration or noise due to the impact acting on the finishing mortar 20 is blocked again by the soundproof foam pad 30 installed adjacent to the wall 10 so that the floor impact sound or vibration to the neighboring space is transmitted. It is prevented enough.

Therefore, according to the present invention, the sawdust of the granular structure having a low thermal conductivity and mechanical rigidity is arranged in a rigid bonding structure of mutual cell structure (scale arrangement or wood grain arrangement) to form a finishing mortar or the like at the upper portion thereof. At the same time it has a sufficient mechanical stability against the effect of having more improved sound insulation and heat insulation and insulation.

In addition, the thickness of each floor can be adjusted appropriately, and the weight is reduced according to the thickness to facilitate the multi-layered building, the economics through the reduction of the material cost, and the work including the panel installation regardless of the unevenness of the slab surface. To facilitate this, to reduce the working time and labor of the worker, and to provide a floor structure of the multi-storey building and its construction method so that the surface by the following finish mortar is uniform.

In addition, the present invention provides a floor structure and a construction method of the multilayered building to prevent cracking of the finishing mortar, etc. without using a member such as a wire mesh, and to prevent the impact sound acting on the finishing mortar from being transmitted through the wall. Is in.

Although the present invention has been described in detail only with respect to the described embodiments, it will be apparent to those skilled in the art that various modifications and variations are possible within the technical scope of the present invention, and such modifications and modifications are within the scope of the appended claims.

Claims (9)

(Correction) in a floor structure of a multi-storey building bordered by at least one space divided into upper and lower parts, A slab for dividing the space into upper and lower parts; The sound-absorbing portion is formed in a layer having a predetermined thickness to keep the sawdust and the additive of a predetermined particle size on the slab in a particle state and to mix at a predetermined volume ratio and to form a cellular structure with a minimum gap between particles. Floor structure of a multi-story building, characterized in that configured by. (Correction) Sawdust and additives of a predetermined particle size are maintained in the state of particles on the surface of the slab of each space divided by at least one wall and the slab, and mixed at a predetermined volume ratio, and the gap between the particles is minimized. A sound insulation portion formed by laying down a layer having a predetermined thickness to form a cellular structure; A watertight portion provided on an upper portion of the sound insulation portion to prevent liquid material from penetrating from the upper portion of the space with respect to the sound insulation portion; And The bottom structure of the multi-story building, characterized in that it comprises a finishing mortar which is installed in the upper portion of the watertight portion to a predetermined thickness to be firm. The method of claim 2, The multi-layered sound insulation foam pad further includes a soundproof foam pad formed at a predetermined width, thickness, and length to set the thickness of the sound insulation part, the watertight part, and the finishing mortar to the edge portion adjacent to the wall and the slab. Floor structure of the building. The method of claim 2, The sawdust forming the sound insulation comprises a volume ratio of 70 to 95, the additive is a floor structure of the multi-story building, characterized in that consisting of a volume ratio of 5 to 30. The method of claim 2, The watertight portion is a floor structure of the multi-story building, characterized in that a plurality of panels having a predetermined thickness, area and shape are combined to be kept airtight with respect to each other. The method of claim 5, The panel may include: a partition having a honeycomb shape on an upper surface thereof and protruding a predetermined height; Seat grooves formed on the partitions so that the side portions of the hot water pipes are fitted from above; A rib formed to protrude to have a support force between the partitions; A support part protruding downward from a lower surface in a honeycomb shape to prevent the sawdust and additives from flowing; Upper and lower protrusions forming a shape protruding in a shape intersecting with another side portion adjacent to the side portion; A protrusion forming a shape protruding downward at a predetermined interval on a lower surface of the upper protrusion; And A fastening groove formed to correspond to the protrusion on an upper surface of the lower protrusion; Floor structure of the multi-story building, characterized in that comprises a. (Correction) The method according to claim 6, In installing the respective panels, the floor structure of the multi-story building, characterized in that the surplus portion of each panel to the space is configured to seal using a separate sealing member and the auxiliary panel of a predetermined shape. Adding a sawdust having a predetermined particle size and an additive in a predetermined volume ratio to the slab surface of each space partitioned by the wall and the slab to form a sound insulating part having a predetermined thickness in a particle state; Forming a watertight portion on an upper surface of the sound insulation portion to prevent penetration from an upper portion thereof; And Laying a finishing mortar at a predetermined thickness on an upper portion of the watertight portion; Floor structure construction method of a multi-storey building, characterized in that consisting of. The method of claim 8, Before the sound insulation portion forming step, installing a sound insulation foam pad having a predetermined thickness, width, and length at an edge portion adjacent to the wall and the slab to set a thickness position of the sound insulation portion, the watertight portion, and the finishing mortar; Floor structure construction method of the multi-storey building, characterized in that further comprises.