KR101941697B1 - Insulation structure for rooftop slab of apartment - Google Patents

Abstract

The present invention provides an insulation structure for a rooftop slab for an apartment house. The insulation structure for a rooftop slab for an apartment house comprises: a rooftop layer of an apartment house having a floor region and a banister wall extended upward from an edge of the floor region; a first insulation part formed to be stepped inside the floor region; a temperature measurement part for measuring temperatures at multiple positions of the upper and lower ends of the first insulation part; a heating part installed inside the floor region to be arranged at positions corresponding to the positions above and below the first insulation part, and heated to a predetermined temperature; a cooling part installed inside the floor region to be arranged at positions corresponding to the positions above and below the first insulation part, and cooled to a predetermined temperature; a control part for calculating a difference value between temperatures measured at each of the positions, checking a position where a difference value deviates from a predetermined reference temperature difference value range, and controlling driving of the heating part and the cooling part such that a difference value between temperatures at the checked position is included in the predetermined reference temperature difference value range; and a display part electrically connected to the control part and displaying a position deviated from the preset reference temperature difference value range at the outside.

Description

{INSULATION STRUCTURE FOR ROOFTOP SLAB OF APARTMENT}

More particularly, the present invention relates to a roof-slab insulation structure for a roof-top slab of a residential house, and more particularly, to a roof-slab insulation structure for a roof- The present invention relates to a roof-slab insulation structure for a residential-use apartment building.

Generally, a heat insulation structure applied to a building requires an insulation function that keeps the interior space cool in the summer and warm in the winter.

As part of the government 's policy, building insulation is expected to save energy by not only reducing energy consumption, but also building more parts for low - carbon emissions and applying construction methods that expect energy effects to design. However, there is still a need to address the most effective and innovative insulation problems in all home construction and insulation materials.

In particular, the rooftops of high-rise buildings such as apartment houses are exposed to the outside environment.

Generally, the rooftop forms a flat floor area and includes a barrier wall formed at the edge of the floor area.

Conventionally, a heat insulating layer having a certain thickness is formed in a bottom region of a roof of a apartment house. The heat insulating layer is formed as a layer at the time of construction of the building. Therefore, since the conventional heat insulating layer is constructed to be joined to the lower part of the slab sphere at the time of constructing the roof slab, there is a problem that it is difficult to immediately check if the heat insulating performance deteriorates after a certain period of time.

In addition, conventionally, there is a problem that it is difficult to confirm which part of a heat insulating layer included in a bottom region of a roof having a certain area degrades the heat insulating performance.

Further, conventionally, there is a problem that it is difficult to replace a heat insulating layer bonded to a roof slab at the time of construction with a new heat insulating layer.

Further, in the case where a region forming a step is formed other than a region where the shape of the support region on the roof top is flat, conventionally, a region in which the heat insulation is not performed remains because no separate heat treatment is performed on the step region. That is, heat flow is generated along the non-adherent sphere and a heat bridge or a cold bridge is generated.

In addition, since there is no separate heat insulating layer at the edge portions of the step difference region and the bottom region as described above, there is a problem that the heat insulating performance is lowered in the above-mentioned edge region.

Thermal insulation structure of roof slab (Patent Application No. 10-2011-0041011)

In order to solve the above-mentioned problems, an object of the present invention is to provide a heat insulating layer included in a floor area of a roof having a certain area so as to immediately check if the heat insulating performance deteriorates after a predetermined time elapses, The roof slab heat insulation structure of the roof structure of the apartment house.

Another object of the present invention is to provide a roof-slab insulation structure for a residential house which can easily replace a heat insulation layer on a roof with a new insulation layer.

It is still another object of the present invention to provide a heat insulating layer in a corner portion of a stepped region and a bottom region in a case where a region having a step difference other than a flat region of a shape of a roof support region is formed, It is an object of the present invention to provide a rooftop slab insulation structure for a residential house which can solve the problem of deterioration of the heat insulating performance in the above-mentioned corner area.

In order to solve the above problems, the present invention provides a rooftop slab insulation structure for apartment houses.

Wherein the roof slab heat insulation structure of the apartment house comprises a floor area and a roof layer of the apartment building having a barrier wall extending upwardly from the edge of the floor area; A first heat insulating portion formed as a layer inside the bottom region; A temperature measuring unit for measuring temperatures at a plurality of positions of the upper and lower ends of the first adiabatic unit; A heating unit installed in the bottom region to be disposed at positions corresponding to the plurality of positions above and below the first adiabatic unit and heated to a predetermined temperature; A cooling unit installed inside the bottom region so as to be disposed at positions corresponding to the plurality of positions above and below the first adiabatic unit and cooled to a predetermined temperature; Calculating a difference value of the measured temperatures at each of the plurality of positions, confirming a position where the difference value is out of a predetermined reference temperature difference value range, and comparing the difference value of the temperatures at the identified position with the predetermined reference temperature difference value And a display unit electrically connected to the control unit and displaying a position outside the preset reference temperature difference value range on the outside.

An inlet for exposing one end of the first adiabatic portion mounting groove to the outside of the first bottom portion, and an inlet for exposing one end of the first adiabatic portion mounting groove to the outside of the first bottom portion, And a winder,

Wherein the winder forcibly moves and positions the first heat insulating portion to the inside of the first heat insulating portion mounting groove through the inlet under the control of the controller while the first heat insulating portion is wound,

A cover for hinging the inlet and opening and closing the inlet is provided at the inlet,

When the inlet is closed, air is sealed between the cover and the inlet through a sealing member,

The first heat insulating portion is preferably flexible.

The first adiabatic portion includes a flexible tubular body formed in a rectangular tube shape, an upper vacuum member formed at an upper end of the tubular body and having upper vacuum spaces formed therein in a lattice shape, A first heat insulating member disposed inside the tube body, and a control unit for controlling the degree of vacuum of the upper vacuum spaces and the lower vacuum spaces by independently controlling the degree of vacuum of the upper vacuum spaces and the lower vacuum spaces, It is preferable to provide a vacuum device.

It is preferable that the first heat insulating member is formed in a circular rod shape and is screwed into the tube body.

A space is formed between the inner circumference of the tube body and the inner circumference of the installation groove,

At one side of the bottom region, inlets are formed,

Outlets on the other side of the bottom region are formed,

Wherein the inlets and the outlets are in the spaced-

The air outlet is provided with a ventilation means,

Preferably, the ventilation means is driven under the control of the control unit, forcibly introduces outside air from the inlets, and allows the introduced outside air to flow out through the outlets.

In particular, the air inlets and the air outlets are each provided with airtight covers that can be opened and closed,

The spacing space is connected to another vacuum through a vacuum line,

The other vacuum unit,

And receives a control signal from the control unit to provide a vacuum to the spaced space so as to achieve a predetermined degree of vacuum.

It is preferable that a moisture removal layer having moisture removing materials is further formed on the outer periphery of the tube body.

A second installation groove is formed in the wall,

A groove cover for opening and closing the second installation groove is provided at an upper end of the wall,

Wherein the second installation groove is provided with a second heat insulating portion interposed therebetween,

The second adiabatic portion and the second installation groove may be formed in a wave shape so as to be coupled to each other in a wave shape.

An edge structure forming an edge is formed between the bottom region and the wall,

A third installation hole in which a lattice-shaped flow path is formed is formed in the edge structure,

Wherein the second installation hole is filled with a third insulation part in a liquid or gel state,

The third installation hole is connected to a supply pipe and a discharge pipe,

The feed pipe and the discharge pipe are connected to a feeder for feeding the third heat insulating part,

Preferably, the control unit controls the driving of the air to circulate the third adiabatic unit at a predetermined cycle.

Roller members are installed at the upper and lower ends of the tube body,

Each of the roller members includes a support having one end hinged to a plurality of upper and lower ends of the tube body, a roller installed at the other end of the support and rolling along the inner circumference of the first installation groove, And an elastic member elastically guiding to unfold,

Preferably, on the periphery of the tube body, a seating groove on which the support base and the roller are seated is formed.

The present invention has the effect of confirming which of a part of the heat insulating layer included in the bottom region of the roof having a certain area is deteriorated in the heat insulating performance so that if the heat insulating performance deteriorates after a predetermined time, .

Further, the present invention has the effect of facilitating replacement of the heat insulating layer on the roof with a new heat insulating layer.

Further, in the present invention, in the case where a region having a step difference is formed in a region other than the flat region of the shape of the support region on the roof, a separate heat insulating layer is provided at the corner portion of the step region and the bottom region, It is possible to solve the problem that deterioration of the heat insulating performance due to heat bridges or cold bridges occurs.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a rooftop slab insulation structure of a joint housing of the present invention. FIG.
2 is a view showing an example in which a winder is installed in a floor area according to the present invention.
Fig. 3 is a view showing the state in which the sealing member of Fig. 2 is opened. Fig.
4 is a view showing a configuration of a first adiabatic portion according to the present invention.
5 is a view showing an example in which an inlet and an outlet are formed in a bottom region according to the present invention.
6 is a view showing an example in which the spacing space according to the present invention is connected to another vacuum chamber.
7 is a view showing an example in which the second heat insulating part according to the present invention is inserted into a barrier wall.
8 is a front view showing a barrier wall according to the present invention.
9 is a view showing an example in which a third insulating part is filled in an edge structure according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings so that those skilled in the art can easily carry out the present invention.

The present invention may be embodied in many different forms and is not limited to the embodiments described herein. That is, it can be carried out on the lower part or the upper part of the roof slab frame, and in some cases, it can be carried out in the middle of the double slab

In order to clearly illustrate the present invention, parts not related to the description are omitted, and the same or similar components are denoted by the same reference numerals throughout the specification.

Hereinafter, the term "an upper (or lower)" or a "top (or lower)" of the substrate means that any structure is disposed or arranged in any manner, as long as any structure is provided or disposed in contact with the upper surface .

Furthermore, the present invention is not limited to a configuration that does not include any other configuration between the substrate and any configuration provided or disposed on (or under) the substrate.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a rooftop slab insulation structure according to the present invention will be described with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a rooftop slab insulation structure of a joint housing of the present invention. FIG.

1, the roof-top slab insulation structure of the present invention comprises a floor area 110 and a roof top floor of a multi-storey house having a railing wall 120 extending upwardly from the rim of the floor area 110 A first heat insulating part 200 formed on the bottom of the bottom part 110 and formed as a layer inside the bottom part 110 and a temperature measuring part 120 for measuring temperatures at a plurality of positions of the upper and lower ends of the first heat insulating part 200 A heating unit 300 installed in the bottom region 110 and disposed at a position corresponding to the plurality of positions above and below the first adiabatic unit 200, And a cooling unit 500 installed in the bottom region 110 to be disposed at positions corresponding to the plurality of positions above and below the first adiabatic unit 200 and cooled to a predetermined temperature, And calculating a difference value of the temperatures measured at each of the plurality of positions, (600) for controlling the driving of the heating unit and the cooling unit such that a position outside the predetermined reference temperature difference value range is confirmed and a difference value of the temperatures at the identified position is included in the predetermined reference temperature difference value range, And a display unit 700 electrically connected to the controller 600 and displaying a position outside the predetermined reference temperature difference value range on the outside.

The heating unit 400 includes a heating coil 410 and a first current supplier 420. The heating coil 410 is disposed inside the bottom region 110 so as to be disposed at an upper portion of the first heat insulating portion mounting groove 111. The first current supplier 420 generates current to the heating coil 410 under the control of the controller 600 to generate heat.

The cooling unit 500 includes a cooling coil 510 and a second current supplier 520. The cooling coil 510 is disposed inside the bottom region 110 so as to be disposed at an upper portion of the first heat insulating portion mounting groove 111. The second current supplier 520 provides a current to the cooling coil 510 under the control of the controller 600 to cool it.

The heating coil 410 and the cooling coil 510 are disposed to intersect with each other. A heat transfer prevention member (not shown) may be disposed between the heating coil 410 and the cooling coil 520.

2 is a view showing an example in which a winder is installed in a floor area according to the present invention. Fig. 3 is a view showing the state in which the sealing member of Fig. 2 is opened. Fig.

2 and 3, a floor area 110 according to the present invention includes a first heat insulating part installation groove 111 located in the first heat insulating part 200, An inlet 112 for exposing one end of the bottom portion 111 to the outside of the bottom region 110 and a winder 130 disposed near the inlet 112 are installed.

In the bottom region 110, a winder receiving groove 131 is formed, which is connected to the inlet 112. The winder receiving groove 131 is connected to the first heat insulating portion mounting groove 111.

The winder 130 is configured to wind the first heat insulating part 200 to the first heat insulating part 200 through the inlet under the control of the controller 600 in a state where the first heat insulating part 200 is wound, Forcibly moved and positioned inside the groove (111).

The inlet 112 is provided with a cover 113 hinged to the inlet 112 to open and close the inlet 112. The hinge is connected to the shaft of the motor. The motor rotates the shaft under the control of the control unit 600, and the cover 113 connected to the hinge is rotated up and down.

When the inlet 112 is closed, the space between the cover 113 and the inlet 112 is sealed through a sealing member (not shown). The first heat insulating portion 200 is formed to be flexible.

Thereby, there is an advantage that the first heat insulating part 200 can be replaced in a certain period by replacing only the winder 130.

4 is a view showing a configuration of a first adiabatic portion according to the present invention.

Referring to FIG. 4, the first adiabatic part 200 according to the present invention includes a flexible tube body 210 formed in a square pipe shape, a flexible tube body 210 formed at an upper end of the tube body 210, A lower vacuum member 230 formed at the lower end of the tube body 210 and having lower lattice vacuum spaces formed therein and a lower vacuum member 230 disposed inside the tube body 210. [ And a purge air 250 for independently controlling the degree of vacuum of the upper vacuum spaces and the lower vacuum spaces in response to a control signal from the control unit 600.

The first heat insulating member 240 may be formed in a circular bar shape and may be screwed into the tube body.

5 is a view showing an example in which an inlet and an outlet are formed in a bottom region according to the present invention.

Referring to FIG. 5, a spacing space is formed between the inner circumference of the tube body 210 and the inner circumference of the first heat insulating portion mounting groove 111 according to the present invention.

At one side of the bottom region 110, inlets 110a are formed.

On the other side of the bottom region 110, outflow holes 110b are formed.

The inlets 110a and the outlets 110b communicate with each other in the space.

The outlet (110b) is provided with a ventilation means (150).

The ventilation means 150 may be driven under the control of the controller 600 to force the outside air from the inlets 110a and to allow the outside air to flow out through the outlets 110b.

Here, it is preferable that rolling members 111a for guiding the movement of the bottom of the first heat insulating part 200 are installed on the bottom of the first heat insulating part mounting groove 111.

6 is a view showing an example in which the spacing space according to the present invention is connected to another vacuum chamber.

Referring to FIG. 6, hermetic covers (not shown) capable of rotating and opening are installed in the respective inlets 110a and outlets 110b, respectively.

The spacing space is connected to the other purge air (260) through a vacuum line (261).

The other purge air (260) may receive a control signal from the controller (600) and provide a vacuum to the spacing space to achieve a predetermined degree of vacuum.

A moisture removing layer (not shown) including moisture removing materials is further formed on the outer circumference of the tube body 210. This makes it possible to suppress the generation of moisture in the spacing space.

7 is a view showing an example in which the second heat insulating part according to the present invention is inserted into a barrier wall. 8 is a front view showing a barrier wall according to the present invention.

Referring to FIGS. 7 and 8, a second installation groove 121 is formed in the interior of the barrier wall 120 according to the present invention.

At the upper end of the barrier wall body 120, a groove cover 122 for opening and closing the second installation groove 121 is provided. The groove cover 122 has a structure in which a hinge is connected to a shaft of the motor in a hinge manner so that the groove is vertically opened and closed.

The second installation space (121) is fitted with a second insulation unit (800).

The second adiabatic part 800 and the second installation groove 121 are formed in a wave shape so as to be coupled to each other in a wave shape.

9 is a view showing an example in which a third insulating part is filled in an edge structure according to the present invention.

Referring to FIG. 9, an edge structure 180 forming an edge is formed between the floor area 110 and the barrier wall body 120 according to the present invention.

In the inside of the edge structure 180, a third installation hole 181 in which a lattice-shaped flow path is formed is formed.

The third installation hole 181 is filled with a third heat insulation part 900 in a liquid or gel state.

The third installation hole 181 is connected to a supply pipe and a discharge pipe,

The supply pipe and the discharge pipe are connected to a feeder 910 for supplying the third heat insulating part 900.

The control unit 600 may control the driving of the feeder 910 to circulate the third adiabatic unit according to a predetermined period.

Although not shown in the drawing, roller members are installed at the upper and lower ends of the tube body 210 according to the present invention.

Each of the roller members includes a support hinge having one end hinged to the upper and lower ends of the tube body 210, a roller installed at the other end of the support and rolling along the inner circumference of the first installation groove, And an elastic member for elastically guiding the elastic member to expand outward.

At the periphery of the tube body 210, a seating groove on which the support base and the roller are seated is formed.

In addition, each of the upper and lower vacuum spaces according to the present invention may be formed in a wave shape.

According to the above-described structure and operation, in the heat insulating layer included in the bottom region of the roof having a certain area so that the heat insulating performance deteriorates after aging after a predetermined time, It is possible to confirm whether or not it is possible.

Further, the present invention has the effect of facilitating replacement of the heat insulating layer on the roof with a new heat insulating layer.

Further, in the present invention, in the case where a region having a step difference is formed in a region other than the flat region of the shape of the support region on the roof, a separate heat insulating layer is provided at the corner portion of the step region and the bottom region, It is possible to solve the problem that the heat insulating performance due to the thermal bridges or the cold bridges is lowered.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined by the appended claims. The present invention is not limited to the drawings.

100: rooftop
110: floor area
120: barrier wall
200: first insulating portion
300: Temperature measuring unit
400: heating section
500: cooling section
600:
700:

Claims (4)

A roof top floor of a multi-storey building having a floor area and a railing wall extending upwardly from a rim of the floor area;
A first heat insulating portion formed as a layer inside the bottom region;
A temperature measuring unit for measuring temperatures at a plurality of positions of the upper and lower ends of the first adiabatic unit;
A heating unit installed in the bottom region to be disposed at positions corresponding to the plurality of positions above and below the first adiabatic unit and heated to a predetermined temperature;
A cooling unit installed inside the bottom region so as to be disposed at positions corresponding to the plurality of positions above and below the first adiabatic unit and cooled to a predetermined temperature;
Calculating a difference value of the measured temperatures at each of the plurality of positions, confirming a position where the difference value is out of a predetermined reference temperature difference value range, and comparing the difference value of the temperatures at the identified position with the predetermined reference temperature difference value A control unit for controlling driving of the heating unit and the cooling unit so as to be included in the range; And.
And a display unit electrically connected to the control unit and displaying a position outside the predetermined reference temperature difference value range,
In the bottom region,
An inlet for exposing one end of the first adiabatic portion mounting groove to the outside of the first bottom portion and a winder disposed in the vicinity of the inlet,
Wherein the winder forcibly moves and positions the first heat insulating portion to the inside of the first heat insulating portion mounting groove through the inlet under the control of the controller while the first heat insulating portion is wound,
A cover for hinging the inlet and opening and closing the inlet is provided at the inlet,
When the inlet is closed, air is sealed between the cover and the inlet through a sealing member,
The first heat insulating portion is flexible,
The first heat insulating portion may include:
A flexible tube body formed in a square tube shape,
An upper vacuum member formed at an upper end of the tube body and having upper vacuum spaces formed therein,
A lower vacuum member formed at the upper end of the tube body and having upper vacuum spaces formed therein,
A first heat insulating member disposed inside the tube body,
And a vacuum unit for receiving the control signal from the control unit and independently controlling the degree of vacuum of the upper vacuum spaces and the lower vacuum spaces.
delete delete The method according to claim 1,
A space is formed between the inner circumference of the tube body and the inner circumference of the installation groove,
At one side of the bottom region, inlets are formed,
Outlets on the other side of the bottom region are formed,
Wherein the inlets and the outlets are in the spaced-
In the outlet,
A ventilation means is provided,
The air-
Wherein the outdoor unit is driven under the control of the control unit to forcibly inflow outdoor air from the inflow openings and to discharge the inflow outdoor air through the outflow openings.

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