KR101301946B1 - Prefab module ceiling system - Google Patents

Abstract

PURPOSE: A prefabricated module ceiling system is provided to omit a task to hang a hanging member by forming a ceiling plate on the upper part of a lower flange on a ceiling beam. CONSTITUTION: A prefabricated module ceiling system comprises a beam (100), a heating bottom plate (200), and a ceiling plate (300). A beam includes a ceiling beam (120) of a lower layer and a bottom beam (110) of an upper layer laminated on the upper part of the ceiling beam. The ceiling plate includes a glass wool panel and a gypsum board fixed to the lower part of the glass wool panel. The glass wool panel is laminated on the upper part of a lower flange on the ceiling beam and supports a ceiling without an additional hanging member. The heating bottom plate includes a reinforcing panel, a heat insulating panel, a moisture proof paper, a magnesium board, a hot water panel, and a finishing material.

Description

Prefab Module Ceiling System

The present invention relates to a prefabricated module ceiling system, and more particularly, to form a ceiling without using a stratum on the lower floor, to use a reinforced panel without using concrete to reduce the weight of the floor of the upper floor, It relates to a dry floor system for reducing the floor impact sound by forming an air layer between the bottom of the top layer.

The prefabrication method has excellent construction properties in that the process is simpler and the construction work is minimized than the existing construction method. Most of the work is done in factories, such as frame construction, interior construction, facility construction, and electrical construction, which take up a considerable amount of work from the existing construction methods. , Is reduced.

Since most of the processes performed in the factory are not affected by the change in weather, it can be said that it is very advantageous compared to the existing methods in which field construction is limited by rain or cold.

However, the conventional modular unit has a problem that the self-weight of the unit increases by using excessive amount of material due to unclear stress transmission.

In addition, there is no technology related to the floor impact sound reduction in the prefabrication method. Recently, in order to construct a multi-family house with a modular construction method among prefabrication methods, it is trying to reduce the floor impact sound by pouring 210mm concrete.

However, as the weight of the module increases rapidly due to the slab of 210mm, the manufacturing process is complicated and the construction period is long.

In addition, when forming the ceiling of the prefabricated module, a moon stand was installed to meet the ceiling level and finish the ceiling. There is a problem.

The present invention has been made to solve the above problems, it is an object of the present invention to provide a prefabricated module ceiling system that can form a ceiling without using the moon.

Another object of the present invention is to provide a dry floor system for reducing the weight of the bottom plate except the concrete slab.

Another object of the present invention is to provide a dry floor system for reducing the floor impact sound.

Prefabricated module ceiling system according to an aspect of the present invention for achieving the above object is a beam having a ceiling beam of the lower layer, the bottom beam of the upper layer to be loaded on the ceiling beam, and the ceiling beam lower flange on the top A glass wool panel supporting a ceiling without using a separate stand, a ceiling plate having a gypsum board fixed to the lower part of the glass wool panel, a reinforcing panel loaded on the top of the floor beam to reduce floor load, An insulation panel for loading on top of the reinforcement panel to improve insulation and sound insulation performance, a moistureproof paper for loading on the insulation panel and preventing moisture from penetrating into the insulation panel, a magnesium board for loading on the moistureproof paper, and The hot water panel of plastic series for heating by loading on the magnesium board and the upper part of the hot water panel Having a finish material which may comprise a heated bottom plate.

The prefabricated module ceiling system may further include a shock absorber having a plurality of studs to absorb the impact of the upper portion at the bottom of the heating bottom plate, and an elastic piece that cushions the studs when they move downward.

The shock absorber may be coupled to the beam and the reinforcement panel to prevent deflection of the heating bottom plate.

The bottom of the beam may be reduced, and an air layer may be formed between the glass wool panel and the bottom plate for thermal insulation.

Structural members fixed to the ceiling beams may be fixed to arrange the wires on the upper portion of the glass wool panel and to prevent the glass wool panel from sagging downward.

The ceiling plate may be provided with a moisture-permeable paper for absorbing moisture between the glass wool panel and the gypsum board.

The insulation panel may be used to overlap the elastic modulus to increase the buffering effect.

In addition, the prefabricated module ceiling system according to another aspect of the present invention for achieving the above object is a beam having a ceiling beam of the lower layer, the bottom beam of the upper layer to be stacked on the ceiling beam, and the ceiling beam lower flange Glass wool panel mounted on the top to support the ceiling without using a separate stand, a ceiling plate having a gypsum board fixed to the lower portion of the glass wool panel, and a reinforced panel to be loaded on the floor beam to reduce the floor load And a reinforcing glass wool panel formed on the reinforcing panel, a reinforcing moisture paper which is loaded on the reinforcing glass wool panel and absorbs moisture, and a reinforcing reinforcement which is loaded on the reinforcing moisture paper and doublely secures the bottom structural performance. A panel, a heat insulation panel mounted on an upper portion of the reinforcement reinforced panel to improve insulation and sound insulation performance, and A moisture-proof paper that is loaded on the panel and prevents moisture from penetrating into the insulating panel, a magnesium board loaded on the moisture-proof paper, a plastic-based hot water panel loaded on the magnesium board, and heated on the hot water panel. It may include a reinforced heating bottom plate having a finishing material for loading.

The prefabricated module ceiling system may further include a shock absorber having a plurality of studs to absorb the impact of the upper portion from the lower portion of the reinforced heating bottom plate, and an elastic piece that cushions the studs when moving downward. .

The shock absorber may be coupled to the beam and the reinforcement panel to prevent sagging from the reinforced heating bottom plate.

The bottom of the beam may be reduced, and an air layer may be formed between the glass wool panel and the bottom plate for thermal insulation.

Structural members fixed to the ceiling beams may be fixed to arrange the wires on the upper portion of the glass wool panel and to prevent the glass wool panel from sagging downward.

The ceiling plate may be provided with a moisture-permeable paper for absorbing moisture between the glass wool panel and the gypsum board.

The insulation panel may be used to overlap the elastic modulus to increase the buffering effect.

In addition, the prefabricated module ceiling system according to another aspect of the present invention for achieving the above object is a beam having a ceiling beam of the lower layer, the bottom beam of the upper layer to be stacked on the ceiling beam, and the ceiling beam lower An aluminum panel extending from a flange, an aluminum angle member coupled to the upper part of the aluminum panel, a ceiling plate having a glass wool panel provided on the aluminum upper part, a reinforcing panel mounted on the upper beam and reducing a floor load; An insulation panel for loading on top of the reinforcement panel to improve insulation and sound insulation performance, a moistureproof paper for loading on the insulation panel and preventing moisture from penetrating into the insulation panel, a magnesium board for loading on the moistureproof paper, and The hot water panel of plastic series for heating by loading on the magnesium board, and the hot water It may include a heating bottom plate having a finish for loading on the panel.

The aluminum shell may have a fixing protrusion for fixing to the aluminum panel.

The aluminum panel may include a fixing hole into which the fixing protrusion is inserted.

A gypsum board and a moisture-permeable paper for absorbing moisture between the gypsum board and the aluminum panel may be fixed to the lower part of the aluminum panel.

The prefabricated module ceiling system may further include a shock absorber having a plurality of studs to absorb the impact of the upper portion from the lower portion of the reinforced heating bottom plate, and an elastic piece that cushions the studs when moving downward. .

The insulation panel may be used to overlap the elastic modulus to increase the buffering effect.

According to the prefabricated module ceiling system according to the present invention, since the ceiling plate is formed on the lower flange of the ceiling beam, it is possible to omit the step of attaching the moon.

And, with the exception of the concrete slab, it is possible to reduce the overall module weight by securing the floor structural performance with the reinforced panel of 19mm.

In addition, an air layer is formed between the ceiling beams and the floor beams, and studs are overlapped with the upper and lower parts of the bottom plate, and elastic pieces are installed between the respective studs, thereby reducing floor impact sound, thereby reducing noise. .

1 is a cross-sectional view showing a stacked state prefabricated module according to an embodiment of the present invention.
Figure 2 is a cross-sectional view showing a prefabricated module ceiling system according to an embodiment of the present invention.
Figure 3 is a cross-sectional view showing a state in which the heating base plate installed on the top of the floor beam according to an embodiment of the present invention.
4 is a cross-sectional view showing the heating bottom plate shown in FIG.
5 is a cross-sectional view showing a ceiling beam and the ceiling plate of the prefabricated module ceiling system according to an embodiment of the present invention.
6 is a cross-sectional view showing a state in which a structural member is installed on the ceiling plate shown in FIG.
Figure 7 is a cross-sectional view showing a state in which the reinforced heating base plate installed on the top of the floor beam according to another embodiment of the present invention.
8 is a cross-sectional view of the reinforced heating sole plate shown in FIG.
Figure 9 is a cross-sectional view showing a shock absorber of the prefabricated module ceiling system according to an embodiment of the present invention.
10 is a plan view showing a state in which the aluminum shell is installed in the prefabricated module ceiling system according to another embodiment of the present invention.
FIG. 11 is a cross-sectional view illustrating a ceiling beam provided with an aluminum panel and an aluminum panel shown in FIG. 10; FIG.

Hereinafter, with reference to the accompanying drawings will be described in detail a prefabricated module ceiling system according to an embodiment of the present invention.

1 is a cross-sectional view showing a stack of prefabricated module according to an embodiment of the present invention, Figure 2 is a cross-sectional view showing a prefabricated module ceiling system according to an embodiment of the present invention.

1 to 2, the prefabricated module ceiling system according to an exemplary embodiment of the present invention may include a beam 100 installed on a floor and a ceiling, and a wall 20.

The prefabricated module 10 may be provided with beams 100 on the top and bottom of the wall (20).

The beam 100 may be provided with a bottom beam 110 and a ceiling beam 120 at the bottom, the beam 100 may be formed of U-shaped steel. The beam 100 may be formed at upper and lower edges of the wall 20.

The prefabricated module 10 may be stacked on top to form a multi-layer. When the prefabricated module 10 is stacked, the bottom beam 110 of the upper layer is positioned at a position corresponding to the ceiling beam 120 of the lower layer. It may be provided to overlap.

A heating bottom plate 200 may be provided on the bottom beam 110, and a ceiling plate 300 of the lower layer may be provided on an upper portion of the lower flange 121 of the ceiling beam 120.

An air layer is formed between the heating sole plate 200 of the upper beam 110 and the ceiling plate 300 of the lower layer to prevent the heat generated from the heating sole plate 200 of the upper layer from being transferred downward. And, it is possible to prevent the bottom shock generated in the upper layer to be transmitted to the bottom.

In addition, the lower portion of the heating bottom plate 200 may be provided with a shock absorber 400 to reduce the floor impact sound.

Since the ceiling plate 300 is provided on the lower flange 121 of the ceiling beam 120 to maintain the ceiling without providing a separate moon stand, manpower and time for hanging the moon stand can be saved.

In addition, since the ceiling plate 300 is provided on the lower flange 121 of the ceiling beam 120 without using a moon stand to maintain the ceiling of the lower layer, it is possible to set the level of the ceiling accurately without a separate process.

3 is a cross-sectional view showing a heating bottom plate installed on the top of the floor beam according to an embodiment of the present invention, Figure 4 is a cross-sectional view showing a heating bottom plate shown in FIG.

3 to 4, the heating bottom plate 200 according to an embodiment of the present invention is formed on the upper portion of the beam 100, the reinforcement panel 210 to secure the bottom structural performance, and the reinforcement Insulation panel 220 to be stacked on the panel 210 to improve the insulation and sound insulation performance, and moisture-proof paper 230 to be loaded on the insulation panel 220 and prevent the moisture from penetrating into the insulation panel 220 And, the magnesium board 240 to be loaded on the top of the moisture-proof paper 230, the dry hot water panel 250 of the plastic series for heating by loading on the magnesium board 240, and the top of the dry hot water panel 250 It may be provided with a finishing material 260 to be loaded on.

The reinforcement panel 210 may use an OSB (Oriented Strand Board) and may be formed to a thickness of 19 mm. Since the reinforcement panel 210 is used, it is possible to secure the floor structure performance except the concrete slab. In general, the prefabricated building uses a method in which the beam 100 and the floor are integrated to increase workability. When the prefabricated building is manufactured in a factory, the beam 100 is used as a formwork to cure concrete on the floor to construct the floor. Curing the floor with the concrete ensures flooring performance, but increases weight. You cannot increase the height of prefabricated buildings. In addition, even if the prefabricated building is constructed with a plurality of floors, it is possible to secure the floor structure performance, but there is a disadvantage that the structure and material thickness of the upper and lower floors need to be changed because the load of the entire building increases. Therefore, since the reinforced panel 210 is used except for the concrete, the floor structure performance can be secured, and the fixed load occurring in the entire building can be reduced.

For example, in a 3m x 6m module, the weight of a 100mm slab is 4.32ton, and when the 3m * 6m modules are stacked five at the top, the load generated at the top is 21.6ton. However, when using the reinforcement panel 210 can reduce the load generated in the upper portion can reduce the fixed load of the entire building can increase the structural performance of the building.

The thermal insulation panel 220 loaded on the reinforcement panel 210 may use EPS (Expanded Polystyrene), and the EPS is white and light as the polystyrene is expanded by the action of a blowing agent, and is water-resistant, heat-insulating, soundproofing, and buffering. It is excellent in heat insulating material and the like, and is loaded on top of the buffer material. In addition, the insulation panel 220 may be used to overlap the elastic modulus to increase the buffering effect.

The thermal insulation panel 220 mounted on the reinforcement panel 210 may have a dynamic modulus of 10 MN / m 3, and the vibration and noise transmitted to the bottom of the bottom plate are alleviated by alleviating the impact transmitted to the heating bottom plate 200. To alleviate

In addition, an insulating panel 220 having a dynamic modulus of 20 MN / m 3 may be loaded on the upper portion of the dynamic modulus of 10 MN / m 3. The upper insulation panel 220 may alleviate the vibration and noise primarily transmitted before the vibration and noise to the lower insulation panel 220 to reduce the vibration and noise transmitted to the lower.

In addition, the heat insulation panel 220 may prevent the transfer of heat of the upper portion to the lower portion or the transfer of the heat of the lower portion to the upper portion.

The moisture proof paper 230 may be stacked on the insulation panel 220 to prevent moisture from penetrating into the insulation panel 220.

For example, when the moistureproof paper 230 is not loaded on the heat insulation panel 220, moisture generated by condensation due to moisture or heating generated from the heat insulation panel 220 is transferred to the heat insulation panel 220. The moisture may be transferred to the heat insulation panel 220 and the reinforcement panel 210.

The magnesium board 240 is loaded on the moisture-proof paper 230, it can be used to overlap a plurality of thickness of 7.5mm. The magnesium board 240 may be provided to apply the effects of heat insulation, soundproofing, electromagnetic shielding, etc. to the floor. By increasing the effect of the magnesium board 240 can prevent heat, noise, electromagnetic waves flowing from the upper layer or the lower layer and can prevent the heat of the room is not emitted to the outside.

The dry hot water panel 250 may use the plastic series and the thickness may be 10 mm or more. The dry hot water panel 250 is for floor heating, using a ready-made product, can be very easy to shorten the construction period.

The reinforcement floor is loaded on top of the dry hot water panel 250 as a finishing material 260 of the heating bottom plate 200, so that the impact to the dry hot water panel 250 to be more than 10mm thick.

The shock absorber 400 may be used to overlap the stud 410 of the lip C-shaped steel, and to the deflection of the heating bottom plate 200 to the beam 100 and the reinforcement panel 210 Can be fixed in combination.

5 is a cross-sectional view showing a ceiling beam and a ceiling plate of a prefabricated module ceiling system according to an embodiment of the present invention, Figure 6 is a cross-sectional view showing a structural member installed on the top of the ceiling plate shown in FIG.

5 to 6, the prefabricated module ceiling system according to an embodiment of the present invention may include a ceiling beam 120 and a ceiling plate 300.

The ceiling plate 300 may be provided with a gypsum board 320 fixed to the glass wool panel 310 on the upper flange 120, the lower flange 121, and fixed to the lower glass wool panel 310.

The glass wool panel 310 may be mounted on the ceiling beam 120, the lower flange 121, and may be used to have a thickness of 100 mm. Since the insulation of the glass wool panel 310 is increased by using 100 mm, it is possible to prevent the transfer of the heat of the upper part to the lower part or the transfer of the heat of the lower part to the upper part.

In addition, by using the density of the glass wool panel 310 or more than 45K it can be prevented from transmitting the noise of the upper or lower to another layer.

Since the glass wool panel 310 is mounted on the ceiling beam 120 and the lower flange 121 without fixing to the moon stand, manpower and work for installing the moon stand can be reduced, and the bottom impact sound of the upper part is lowered through the moon stand. Can be prevented.

The bottom of the glass wool panel 310 may be provided with a gypsum board 320 to form a ceiling of the lower layer, the gypsum board 320 may be used 15mm. The gypsum board 320 may be used by overlapping two sheets. Since the gypsum board 320 is used by overlapping two sheets, a more solid ceiling can be formed.

Between the glass wool panel 310 and the gypsum board 320 is provided with a moisture-permeable paper 330 for absorbing moisture to prevent the moisture of the upper or lower portion is transferred.

In addition, as shown in FIG. 6, the structural member 340 may be fixed to an upper portion of the glass wool panel 310 to arrange wirings and various pipes disposed on the ceiling. The structural member 340 is fixed to the beam 100 at equal intervals and supports the glass wool panel 310 to prevent the glass wool panel 310 from sagging downward.

The structural member 340 may be formed in the glass wool panel 310 in the shape of a grid, and may evenly support the glass wool panel 310.

Hereinafter, in describing the reinforced heating bottom plate 500 of the prefabricated module ceiling system according to another embodiment of the present invention, the same configuration as the heating bottom plate 200 of the prefabricated module ceiling system according to the above-described embodiment will be described. The same reference numerals are used, and detailed description thereof will be omitted.

FIG. 7 is a cross-sectional view illustrating a reinforcement heating sole plate installed on an upper floor beam according to another embodiment of the present invention, and FIG. 8 is a cross-sectional view illustrating the reinforced heating sole plate illustrated in FIG. 7.

As shown in FIGS. 7 to 8, the reinforcement heating sole plate 500 according to the embodiment of the present invention is formed on the upper beam 110 and the reinforcement panel 210 to secure the floor structure performance. The reinforcing glass wool panel 510 formed on the reinforcing panel 210, the reinforcing breathing paper 520 that is mounted on the reinforcing glass wool panel 510 and absorbs moisture, and on the reinforcing breathing paper 520 Reinforcement reinforcement panel 530 for stacking and securing the bottom structural performance in a double, the insulation panel 220 for improving the insulation and sound insulation performance by loading on the reinforcement reinforcement panel 530, and the insulation panel 220 ) Is placed on top of the moisture-proof paper 230 to prevent moisture from penetrating into the insulation panel 220, the magnesium board 240 to be loaded on the moisture-proof paper 230 and the magnesium board 240 to be loaded on the top Plastic hot water panel (250) for heating , The dry hot panel 250 may be provided with a sealer (260) for loading thereon.

The reinforcement panel 210 may be stacked on the top of the bottom beam 110 and formed to a thickness of 19 mm. Since the reinforcement panel 210 is used, it is possible to secure the floor structure performance except the concrete slab.

The reinforcement glass wool panel 510 may be stacked on the reinforcement panel 210 and may be used to have a thickness of 100 mm. By using the reinforcing glass wool panel 510 to increase the heat insulation, it is possible to prevent the transfer of the heat of the upper portion to the lower portion or to transfer the heat of the lower portion to the upper portion.

In addition, the density of the reinforcing glass wool panel 510 may be prevented from transmitting noise of the upper or lower portion to another layer by using the same 45K or more as the glass wool panel 310.

The reinforcing moisture-permeable paper 520 is loaded on the reinforcing glass wool panel 510 and the reinforcing glass-wool panel 510 or the reinforcing reinforced panel 530 or the heat-insulating panel that is loaded on the upper part of the reinforcing moisture-proof paper 520. Absorb moisture delivered to 220.

The reinforcing reinforcement panel 530 loaded on the reinforcing moisture-permeable paper 520 is to reinforce the reinforcing panel 210 loaded on the upper portion of the beam 100 to secure floor structure performance. As in 210, the thickness of the reinforced dry sole may be properly maintained using 19 mm.

The insulation panel 220 (Expanded Polystyrene) to be loaded on the reinforcement reinforced panel 530 is expanded and whitened by the action of the blowing agent polystyrene is light and lightweight, and excellent in water resistance, insulation, sound insulation, cushioning, etc. Load on top of cushioning material. In addition, the insulation panel 220 may be used to overlap the elastic modulus to increase the buffering effect.

The moisture proof paper 230 may be stacked on the insulation panel 220 to prevent moisture from penetrating into the insulation panel 220.

The magnesium board 240 is loaded on the moisture-proof paper 230, it can be used to overlap a plurality of thickness of 7.5mm. The magnesium board 240 may be applied to the floor, such as heat insulation, soundproofing, electromagnetic shielding. .

The dry hot water panel 250 may use the plastic heat and have a thickness of 10 mm or more. The dry hot water panel 250 is for floor heating, using a ready-made product, can be very easy to shorten the construction period.

The reinforced floor is loaded on top of the dry hot water panel 250 as a finishing material 260 of the dry heating bottom plate 200, the thickness is 10mm or more to allow the impact to the dry hot water panel 250 to be alleviated.

The shock absorber 400 may be used to overlap the stud 410 of the lip C-shaped steel, and to the deflection of the heating bottom plate 200 to the beam 100 and the reinforcement panel 210 Can be fixed in combination.

9 is a cross-sectional view showing a shock absorber of the prefabricated module ceiling system according to an embodiment of the present invention.

As illustrated in FIG. 9, the shock absorber 400 of the prefabricated module ceiling system according to an embodiment of the present invention has an impact of an upper portion of the dry heating soleplate 200 or the lower portion of the reinforced heating soleplate 500. It may be provided with a plurality of studs 410, and an elastic piece 420 that buffers when the stud 410 moves downward.

The stud 410 may use a lip C-shaped steel, and the beam 100 and the reinforcing panel (100) to prevent sagging in the dry heating bottom plate 200 or the reinforced heating bottom plate 500. 210 may be fixed in combination.

In addition, the stud 410 may be used to overlap a plurality of buffers so that a buffer may be provided in a damper type.

As shown in (a) of FIG. 9, the two studs 410 may be provided to overlap the upper and lower portions. An end portion of the lower surface of the upper stud 410 formed of the lip C-shaped steel is faced downward, and an end portion of the lower surface of the upper stud 410 is upward, and an end portion of the lower surface of the upper stud 410 and the lower stud ( After the end of the upper surface meets 410 may be provided with an elastic piece 420 having elasticity between the upper stud 410 and the lower stud 410. When an end portion of the lower surface of the upper stud 410 and an end portion of the upper surface of the lower stud 410 meet each other, elasticity is generated between the studs 410 to prevent vibration caused by the dry heating sole plate 200. Can be.

In addition, as shown in (b) of FIG. 9, the two studs 410 of the rib C-shaped steel overlap the upper and lower portions, and the elastic piece 420 is disposed between the upper stud 410 and the lower stud 410. It can be provided to prevent the transmission of the vibration of the dry heating floor plate 200 or the reinforced heating floor plate 500 to the lower layer.

The elastic piece 420 may be formed of an elastic material such as rubber, and the elastic piece 420 has an upper stud 410 with the dry heating bottom plate 200 or the reinforced heating bottom plate 500. When vibrating up and down by the vibration generated in the vibration may have a dust-proof effect so that the vibration is not transmitted to the lower stud 410.

10 is a plan view showing the installation of the aluminum shell in the prefabricated module ceiling system according to another embodiment of the present invention, Figure 11 is a cross-sectional view showing a ceiling beam with an aluminum panel and the aluminum panel shown in FIG.

10 to 11, the prefabricated module ceiling system according to an embodiment of the present invention may include a ceiling beam 120 and a ceiling plate 300.

The ceiling plate 300 may be provided with an aluminum panel 700 extending from the lower flange 121 of the ceiling beam 120. The ceiling beam 120 may be formed of aluminum.

The aluminum panel 700 may extend from the ceiling beam 120, and may be combined with the ceiling beam 120.

An aluminum square material 600 may be provided on an upper portion of the aluminum panel 700, and sag may be prevented by the aluminum square material 600.

The aluminum lumber 600 may be fixed to the beam 100 at equal intervals or fixed to the beam in a grid shape as shown in FIG. The aluminum shell 600 may be used as a C-shaped steel, the upper portion of the aluminum shell 600 may be used as a space to organize the wiring and the like. In addition, the aluminum shell 600 may be installed to grab the level of the ceiling plate (300).

For example, when the ceiling is formed, the moon is installed to set the level of the ceiling. When the moon is installed, the work process is not only increased, but the exact level is not obtained. Therefore, since the aluminum beams 600 are fixed to the ceiling beams 120 to the level without installing the moon stand, the ceiling is formed, and thus the process of catching a separate level can be omitted.

In addition, the aluminum lumber 600 may be provided with a fixing protrusion 610 to be fixed to the aluminum panel 700. The fixing protrusion 610 may be a protrusion protruding from the aluminum shell 600 as shown in FIG.

As shown in FIG. 11, the aluminum panel 700 and the aluminum square material 600 are coupled to the fixing hole 710 into which the fixing protrusion 610 provided in the aluminum panel 700 is inserted. There is a method of fixing the fixing protrusion 610. In addition, although not shown in the drawings, the fixing protrusion 610 is provided on the aluminum panel 700 so that the fixing hole 710 is provided on the aluminum square material 600 to fix the aluminum square material 600. The end of the fixing protrusion 610 extends from the vertical to the horizontal, is inserted into the fixing hole 710, and then moves horizontally to couple the aluminum angle member 600 and the aluminum panel 700 to each other.

In addition, when the fixing protrusion 610 is inserted into the fixing hole 710 in a shape that is separated into a plurality of points at one point, the collected fixing protrusions 610 are collected and opened when the fixing protrusion 610 is inserted into the fixing hole 710. ) And the aluminum panel 700 may be fixed.

The glass wool panel 310 may be stacked on the aluminum lumber 600.

The glass wool panel 310 may be used to a thickness of 100 mm. Since the insulation of the glass wool panel 310 is increased by using 100 mm, it is possible to prevent the transfer of the heat of the upper part to the lower part or the transfer of the heat of the lower part to the upper part.

In addition, by using the density of the glass wool panel 310 or more than 45K it can be prevented from transmitting the noise of the upper or lower to another layer.

Since the glass wool panel 310 is mounted on the aluminum square beam 600 without being fixed to the moon stand, manpower and work for installing the moon stand can be reduced, and the bottom impact sound of the upper part is prevented from being transferred to the bottom through the moon stand. Can be.

The lower end of the aluminum panel 700 may be provided with a gypsum board 320 to form a ceiling of the lower layer, the gypsum board 320 may be used 15mm. The gypsum board 320 may be used by overlapping two sheets. Since the gypsum board 320 is used by overlapping two sheets, a more solid ceiling can be formed.

Between the aluminum panel 700 and the gypsum board 320 is provided with a moisture-permeable paper 330 for absorbing moisture to prevent the moisture of the upper or lower portion is transferred.

In the above described the prefabricated module ceiling system according to an embodiment of the present invention, the spirit of the present invention is not limited to the embodiments presented herein. Those skilled in the art, who understands the spirit of the present invention, can readily suggest other embodiments by adding, changing, deleting, adding, or the like of components within the scope of the same idea, I would say.

10: prefabricated module 20: wall
100: beam 110: floorcloth
120: ceiling beam 200: heating bottom plate
300: ceiling panel 330: breathable paper
400: shock absorber 500: reinforced heating bottom plate

Claims (20)

A beam having a ceiling beam of a lower layer and a floor beam of an upper layer stacked on the ceiling beam;
A glass wool panel mounted on the upper flange lower flange to support the ceiling without using a separate moon stand, and a ceiling plate having a gypsum board fixed to the lower portion of the glass wool panel;
Reinforcement panel mounted on the floor beam and reducing the floor load, Insulation panel loaded on the reinforcement panel to improve insulation and soundproofing performance, Loaded on top of the insulation panel and the moisture penetrates into the insulation panel And a heating bottom plate provided with a moisture proof paper for preventing the water, a magnesium board loaded on the top of the moisture proof paper, a plastic series hot water panel loaded on the magnesium board, and a finishing material loaded on the hot water panel. Prefabricated modular ceiling system.
The method of claim 1,
The prefabricated module ceiling system further includes a shock absorber having a plurality of studs to absorb the impact of the upper part from the bottom of the heating base plate, and an elastic piece that cushions the studs when they move downward. Prefabricated modular ceiling system.
The method of claim 2,
The buffer device is a prefabricated module ceiling system, characterized in that coupled to the beam and the reinforcement panel to prevent the deflection of the heating base plate.
The method of claim 1,
Prefabricated module ceiling system, characterized in that to reduce the impact floor sound, forming an air layer between the glass wool panel and the bottom plate for insulation.
The method of claim 1,
Prefabricated module ceiling system, characterized in that the structural member fixed to the ceiling beam is fixed to the top of the glass wool panel to arrange the wiring and to prevent the glass wool panel from sagging downward.
The method of claim 1,
The ceiling panel is a prefabricated module ceiling system, characterized in that provided between the glass wool panel and the gypsum board moisture-permeable paper for absorbing moisture.
The method of claim 1,
The insulation panel is a prefabricated module ceiling system, characterized in that to use a different elastic modulus to increase the cushioning effect.
A beam having a ceiling beam of a lower layer and a floor beam of an upper layer stacked on the ceiling beam;
A glass wool panel mounted on the upper flange lower flange to support the ceiling without using a separate moon stand, and a ceiling plate having a gypsum board fixed to the lower portion of the glass wool panel;
Reinforced panel to be loaded on the top of the beam and to reduce the floor load, reinforcing glass wool panel formed on the reinforcement panel, reinforcing breathing paper to absorb the moisture and load on the reinforcing glass wool panel, the reinforcing breathing paper Reinforcement reinforcement panel to be loaded on the top and double bottom to secure the performance of the structure, Insulation panel for loading on the reinforcement reinforcement panel to improve insulation and sound insulation performance, Loaded on top of the insulation panel and the moisture into the insulation panel Reinforced heating bottom plate having a moisture-proof paper to prevent the infiltration, magnesium board to be loaded on the top of the moisture-proof paper, a plastic-based hot water panel for heating by loading on the magnesium board, and a finishing material for loading on the hot water panel Prefabricated module ceiling system comprising a.
The method of claim 8,
The prefabricated module ceiling system further includes a shock absorber having a plurality of studs to absorb the impact of the upper portion from the lower portion of the reinforced heating sole plate, and an elastic piece that cushions the studs when moving downward. Prefabricated modular ceiling system.
The method of claim 9,
The buffer device is a prefabricated module ceiling system, characterized in that coupled to the beam and the reinforcement panel to prevent the deflection of the reinforced heating base plate.
The method of claim 8,
Prefabricated module ceiling system, characterized in that to reduce the impact floor sound, forming an air layer between the glass wool panel and the bottom plate for insulation.
The method of claim 8,
Prefabricated module ceiling system, characterized in that the structural member fixed to the ceiling beam is fixed to the top of the glass wool panel to arrange the wiring and to prevent the glass wool panel from sagging downward.
The method of claim 8,
The ceiling panel is a prefabricated module ceiling system, characterized in that provided between the glass wool panel and the gypsum board moisture-permeable paper for absorbing moisture.
The method of claim 8,
The insulation panel is a prefabricated module ceiling system, characterized in that to use a different elastic modulus to increase the cushioning effect.
A beam having a ceiling beam of a lower layer and a floor beam of an upper layer stacked on the ceiling beam;
An aluminum panel extending from the lower flange of the ceiling beam, an aluminum angle member coupled to the upper part of the aluminum panel, a ceiling plate including a glass wool panel provided on the aluminum upper part;
Reinforcement panel mounted on the floor beam and reducing the floor load, Insulation panel loaded on the reinforcement panel to improve insulation and soundproofing performance, Loaded on top of the insulation panel and the moisture penetrates into the insulation panel And a heating bottom plate provided with a moisture proof paper for preventing the water, a magnesium board loaded on the top of the moisture proof paper, a plastic series hot water panel loaded on the magnesium board, and a finishing material loaded on the hot water panel. Prefabricated modular ceiling system.
16. The method of claim 15,
The aluminum shell is a prefabricated module ceiling system, characterized in that it comprises a fixing projection for fixing to the aluminum panel.
17. The method of claim 16,
The aluminum panel is a prefabricated module ceiling system, characterized in that it has a fixing hole into which the fixing projection is inserted.
16. The method of claim 15,
Prefabricated module ceiling system, characterized in that the gypsum board and the moisture-permeable paper absorbing moisture between the gypsum board and the aluminum panel is fixed to the lower part of the aluminum panel.
16. The method of claim 15,
The prefabricated module ceiling system further includes a shock absorber having a plurality of studs to absorb the impact of the upper portion from the lower portion of the reinforced heating sole plate, and an elastic piece that cushions the studs when moving downward. Prefabricated modular ceiling system.
16. The method of claim 15,
The insulation panel is a prefabricated module ceiling system, characterized in that to use a different elastic modulus to increase the cushioning effect.

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