KR102050764B1 - Insulation structure for rooftop slab of building - Google Patents

Abstract

The present invention provides an internal insulation structure for a rooftop slab of a building which facilitates replacement of an insulator. The internal insulation structure for a rooftop slab of a building comprises: a rooftop unit including a slab layer and a concrete layer formed on the slab layer; an installation unit arranged on the slab layer and provided with installation grooves having a grid arrangement; first insulation units arranged on the installation grooves, arranged to be able to protrude to the outside, and provided with a first insulation member formed therein; a cylinder unit allowing the first insulation units to protrude from the installation grooves; second insulation units installed on the first insulation units to be able to protrude and rotate, and provided with a second insulation member arranged therein; a rotating unit allowing the second insulation units to protrude and rotate; and a monitoring unit measuring a different between outside and indoor temperatures at positions of the installation grooves, and allowing a second insulation unit with a temperature difference higher than or equal to a preset temperature difference among the second insulation units to protrude to the outside and rotate by using the rotating unit if the temperature difference is higher than or equal to the preset temperature difference.

Description

Insulation structure of roof top slab of building {INSULATION STRUCTURE FOR ROOFTOP SLAB OF BUILDING}

The present invention relates to an insulation structure of a rooftop slab of a building, and more particularly, is installed in a ceiling part of a rooftop slab of a building, and monitors the state of insulation in real time to facilitate replacement of the insulation when the replacement time is reached. The present invention relates to an insulation structure of a rooftop slab of a building that can achieve environmentally friendly insulation using geothermal or solar heat.

Usually, the roof of a building is slabed with concrete, etc., and waterproofed on it with a waterproofing layer such as asphalt waterproofing or sheet waterproofing, and then thermally insulated with a heat insulating material, and then a protective concrete construction as a rooftop floor thereon.

In the case of building roofs, the insulation is mainly made of foam insulation such as styrofoam.

Since the heat insulating material has its own life span, there is a problem that it becomes difficult to achieve normal heat insulation by deteriorating the heat insulation performance determined due to moisture absorption, dew condensation, change of chemical composition, etc. when the predetermined life is more than a predetermined number of years.

In addition, the bar is attached to the rooftop concrete slab, there is a problem that can not be easily replaced when the thermal insulation performance of the heat insulating material is degraded with age.

In addition, the rooftop is exposed to the outside environment as it is, and if the heat insulation layer is deteriorated, there is a problem that the heat insulation of the room below the slab layer is not normally achieved.

The technology related to the present invention is domestic application No. 10-2016-0003010 (2016.01.11).

An object of the present invention is installed on the ceiling in the roof of the building slab, monitoring the insulation state in real time to facilitate the replacement of the insulation when the replacement time, and also to use the geothermal or solar heat to make an environmentally friendly insulation It is to provide a heat insulation structure of the roof slab of the building that can be achieved.

In order to achieve the above object, the present invention provides a rooftop slab insulation structure of the building.

The rooftop slab insulation structure of the building includes a rooftop portion including a slab layer and a concrete layer formed on the slab layer; An installation part provided on the slab layer and having installation grooves having a lattice arrangement; First insulation parts disposed in each of the installation grooves, protruding outwardly, and having a first insulation member formed therein; A cylinder portion protruding the first insulation portion from the installation grooves; Second insulation portions protruding from the first insulation portion, rotatably installed, and a second insulation member disposed therein; A rotating part protruding and rotating the second heat insulating part; And measuring a temperature difference between the outside and the room at the positions of the installation grooves, and when the temperature difference is a predetermined abnormal temperature difference, among the second heat insulating parts, a second heat insulating part which forms the predetermined abnormal temperature difference. And a monitoring unit configured to protrude and rotate outwardly using the rotating unit.

Wherein the monitoring unit,

First temperature sensors installed in the second heat insulation parts to measure external temperature at the positions of the installation grooves;

Second temperature sensors measuring an indoor temperature of an indoor side at positions of the installation grooves;

Comprising a calculated temperature difference between the measured external temperature and the room temperature, the predetermined abnormal temperature difference is set, the controller for controlling the driving of the rotating unit,

The rotating part,

A pair of rotary shafts installed at both ends of the second thermal insulation portion, a rotary motor connected to the rotary shaft in an axial manner, and a first shaft having one end connected to the rotation shaft and protruding from the rotary shaft; With a first cylinder,

The pair of first cylinders are installed in the second insulation portion,

The second insulation portion is in contact with or spaced apart from one surface of the first insulation portion according to the expansion and contraction of the first axis.

And the second insulation portion,

A second heat insulating part body having a receiving groove for receiving the second heat insulating member;

A door connected to the second insulation body in a hinged manner and opening and closing the accommodation groove;

Is connected to the hinge in an axial manner, and has a motor for rotating and opening and closing the door under the control of the controller.

In addition, the first insulation member,

A cooling coil embedded in the first insulation portion;

A heating coil embedded in the first insulation portion;

A first terminal installed at a rear part of the first heat insulating part and connected to the cooling coil;

A second terminal installed at a rear part of the second heat insulating part and connected to the heating coil;

A first current provider installed inside the installation groove and providing a current for cooling;

Is installed inside the installation groove, provided with a second current provider for providing a current for heating,

On the inner side of the installation groove,

A first terminal groove connected to the first current provider and into which the first terminal is inserted is formed,

A second terminal groove connected to the second current provider and into which the second terminal is inserted is formed;

By the driving of the cylinder part, the coupling between the first terminal and the first terminal groove and the coupling between the second terminal and the second terminal groove are determined.

In particular, the auxiliary insulation is installed in the area between the installation grooves,

The auxiliary heat insulating part,

A cooling line embedded between the installation grooves and cooled to a predetermined temperature;

A heating line buried between the installation grooves and heated to a predetermined temperature;

And an auxiliary current provider for providing current to the cooling line or the heating line under control of the controller.

In addition, the first insulation portion and the second insulation portion,

Be accommodated in each of the installation grooves,

In each of the installation grooves,

A sliding door for opening and closing the installation grooves is installed according to the driving of the linear motor,

Each of the installation grooves,

It is connected to the vacuum lines connected to the inner space of each of the installation grooves,

The vacuum lines are connected with a vacuum provider,

In each of the mounting grooves, vacuum sensors for measuring the degree of vacuum of each of the mounting grooves are installed,

The controller,

In the state where the sliding door closes the installation groove, the driving of the vacuum provider is controlled in real time such that the vacuum degree measured using the vacuum provider reaches a preset reference vacuum degree.

In addition, the first insulation portion and the second insulation portion form a wave-shaped bond with each other. Alternatively, the first insulation portion and the second insulation portion may form a concave-convex shape.

The outer surface of the first insulation portion in contact with the outer surface of the second insulation portion is further provided with a vacuum plate to form a vacuum therein to a certain thickness,

It is preferable that an elastic layer having a predetermined thickness is further formed on the outer surface of the vacuum plate.

By the above solution means, the present invention is installed to form a lattice arrangement on the outer wall of the building, grasp the heat insulation performance at the location in real time, and when the heat insulation performance is below a certain level, it is easy to insulate the material at the location. It has an effect that can be replaced.

1 is a view showing a roof-top slab insulation structure of the building according to the invention.
2 is a cross-sectional view along the line AA of FIG. 2.
3 is a view showing an arrangement state of the first and second heat insulating parts according to the present invention.
4 and 5 are views showing a state in which the second insulation unit is projected and rotated to the outside according to the present invention.
6 and 7 are other views showing a state accommodated into the installation groove in the state in which the second insulation is protruding.
8 is a view illustrating an example in which a sliding door and a vacuum line are installed in an installation groove according to the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention.

As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention.

In order to clearly describe the present invention, parts irrelevant to the description are omitted, and like reference numerals designate like elements throughout the specification.

Hereinafter, any configuration is provided or disposed on the "top (or bottom)" of the substrate or "top (or bottom)" of the substrate, that any configuration is provided or disposed in contact with the top (or bottom) of the substrate Means that.

In addition, it is not limited to not including another structure between the said base material and any structure provided or arrange | positioned on (or under) the base material.

Hereinafter, with reference to the accompanying drawings, it will be described the rooftop slab inner insulation structure of the building according to the invention.

1 is a view showing a roof-top slab insulation structure of the building according to the invention. 2 is a cross-sectional view along the line A-A of FIG. 3 is a view showing an arrangement state of the first and second heat insulating parts according to the present invention. 4 and 5 are views showing a state in which the second insulation unit is projected and rotated to the outside according to the present invention. 6 and 7 are other views showing a state accommodated into the installation groove in a state in which the second insulation is protruding according to the present invention. 8 is a view illustrating an example in which a sliding door and a vacuum line are installed in an installation groove according to the present invention.

1 to 8, the roof top slab insulation structure of the building of the present invention is a roof top including a slab layer and a concrete layer formed on the slab layer, and a ceiling formed at the bottom of the slab layer ( It is provided in the 100, the installation portion 100 is formed in the installation grooves 110 having a lattice arrangement, disposed in each of the installation grooves 110, is disposed to protrude outward, the first inside First insulating parts 200 in which a heat insulating member is formed, a cylinder part 300 which protrudes the first insulating part 200 from the installation grooves 110, and protrude into the first insulating part 200. And a second heat insulating part 400 having a second heat insulating member disposed therein, a rotatable part 500 protruding and rotating the second heat insulating part 400, and the installation grooves. The temperature difference between the outside and the room is measured at the position of 110, and the temperature difference is preset. When the difference in phase temperature is achieved, the monitoring unit for protruding and rotating the second insulation unit 400, which forms the predetermined abnormal temperature difference, outwardly using the rotating unit 500, of the second insulation units 400 ( 600).

Here, the monitoring unit 600 is installed in the second insulation units 400 and the first temperature sensors 610 for measuring the external temperature at the location of the installation grooves 110 and the installation grooves Second temperature sensors 620 for measuring the indoor temperature of the indoor side at the position of 110 and calculating a temperature difference between the measured external temperature and the indoor temperature, and the predetermined abnormal temperature difference is set, The controller 630 controls the driving of the rotating part 500.

The rotary part 500 is connected to the rotary shaft 510 installed at both ends of the second heat insulating part 400 and the rotary shaft 510 in an axial manner, and rotates the second heat insulating part 400 to rotate. And a pair of first cylinders 530 having a motor 520 and one end connected to the rotation shaft 510 and having a first shaft 531 protruding therefrom.

The pair of first cylinders 530 are installed in the second heat insulating part 400.

The second insulation unit 400 is in contact with or spaced apart from one surface of the first insulation unit 200 according to the expansion and contraction of the first shaft 531.

The second heat insulating part 400 includes a second heat insulating body 410 and a second heat insulating body 410 in which an accommodation groove 412 in which the second heat insulating member 411 is accommodated is formed. Is connected in a hinged manner, the door 420 to open and close the receiving groove 412, the shaft is connected to the hinge, the motor for rotating and opening and closing the door 420 under the control of the controller 630 ( 430.

The first insulation member may include a cooling coil 210 embedded in the first insulation portion 100, a heating coil 220 embedded in the first insulation portion 200, and the first insulation member. It is installed on the rear portion of the first insulation unit 200, the first terminal 230 is connected to the cooling coil 210, is installed on the rear portion of the second insulation unit 200, and the heating coil 220 Is connected to the second terminal 240 and the installation groove 110, the first current provider 250 for providing a current for cooling and the installation groove 110 is connected to And a second current provider 260 which provides a current for heating.

On the inner surface of the installation groove 110, a first terminal groove 111 is formed, which is connected to the first current provider 250, into which the first terminal 230 is inserted, and the second current provider. It is connected to the 260, the second terminal groove 112 into which the second terminal 240 is inserted is formed.

The first terminal 230 and the first terminal groove 111 are coupled to each other by the cylinder unit 300, and the second terminal 240 and the second terminal groove 112 are coupled to each other. This is determined.

In particular, although not shown in the figure, an auxiliary heat insulating part is installed in an area between the installation grooves 110.

The auxiliary heat insulating part includes a cooling line embedded between the installation grooves 110 and cooled to a predetermined temperature, a heating line embedded between the installation grooves and heated to a predetermined temperature, and the control of the controller 630. According to the present invention may be provided with an auxiliary current provider for providing a current to the cooling line or the heating line.

Here, the angular intervals of the installation grooves 110 form a minute gap to form a distance of 1% of the horizontal or vertical of the installation groove 110.

As described above, there is an advantage in that a heat bridge or a cold bridge phenomenon formed at this interval may be effectively prevented through a cooling or heating line formed between the installation grooves forming the fine interval.

10 is a view showing an example in which the sliding door and the vacuum line is installed in the installation groove according to the present invention.

Referring to FIG. 10, the first heat insulating part 200 and the second heat insulating part 400 are accommodated in each of the installation grooves 110.

Each of the installation grooves 110 is provided with a sliding door 700 that opens and closes the installation grooves 110 according to the driving of the linear motor 710.

Each of the installation grooves 110 is connected to vacuum lines 720 connected to an inner space of each of the installation grooves 110.

The vacuum lines 720 are connected with a vacuum provider 730.

In each of the installation grooves 110, vacuum sensors 740 for measuring the degree of vacuum of each of the installation grooves 110 are installed.

The controller 630 provides the vacuum such that the vacuum degree measured using the vacuum provider 730 achieves a predetermined reference vacuum degree while the sliding door 700 closes the installation groove 110. The driving of the machine 730 is controlled in real time.

And although not shown in the figure, a light collecting plate is installed on the roof. The light energy collected by the light collecting plate is converted into electrical energy and charged in the charging unit.

The charging unit always provides power required for driving the first and second current providers and the vacuum provider according to the present invention.

In addition, although not shown in the drawings, the first and second insulation units form a wave-shaped bond with each other. Alternatively, the first insulation portion and the second insulation portion may form a concave-convex shape.

The outer surface of the first insulation portion in contact with the outer surface of the second insulation portion is further provided with a vacuum plate to form a vacuum therein to a certain thickness,

It is preferable that an elastic layer having a predetermined thickness is further formed on the outer surface of the vacuum plate.

Therefore, the present invention may be able to easily determine the heat insulating performance at the corresponding position of the ceiling in real time, and when the heat insulating performance is below a certain level, it is possible to easily replace the heat insulating material at the corresponding position.

As mentioned above, although the specific Example which concerns on this invention was described, it is obvious that various implementation deformation is possible without the deviating from the range of this invention.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the claims below and equivalents thereof.

In other words, the foregoing embodiments are to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the following claims rather than the detailed description, the meaning and scope of the claims and their equivalents All changes or modifications derived from the concept should be construed as being included in the scope of the present invention.

100: installation
200: first insulation
300: cylinder part
400: second insulation
500: rotating part
600: monitoring unit

Claims (4)

A rooftop portion comprising a slab layer and a concrete layer formed on the slab layer;
An installation part provided on the slab layer and having installation grooves having a lattice arrangement;
First insulation parts disposed in each of the installation grooves, protruding outwardly, and having a first insulation member formed therein;
A cylinder portion protruding the first insulation portion from the installation grooves;
Second insulation portions protruding from the first insulation portion, rotatably installed, and a second insulation member disposed therein;
A rotating part protruding and rotating the second heat insulating part; And,
Measuring the temperature difference between the outside and the room at the location of the installation grooves, and when the temperature difference is a predetermined abnormal temperature difference, the second heat insulating portion of the second heat insulating portion, which makes the predetermined abnormal temperature difference of the rotating unit Including; monitoring unit for protruding and rotating outwards,
The monitoring unit,
First temperature sensors installed in the second heat insulation parts to measure external temperature at the positions of the installation grooves;
Second temperature sensors measuring an indoor temperature of an indoor side at positions of the installation grooves;
Comprising a calculated temperature difference between the measured external temperature and the room temperature, the predetermined abnormal temperature difference is set, and having a controller for controlling the driving of the rotating unit,
The rotating part,
A pair of rotating shafts provided at both ends of the second insulating portion, a rotating motor connected to the rotating shaft in an axial manner, and having a first shaft having one end connected to the rotating shaft and protruding from the rotating shaft; 1 cylinder
The pair of first cylinders are installed in the second insulation portion,
The second insulating portion is in contact with, or spaced apart from one surface of the first insulating portion in accordance with the expansion and contraction of the first shaft rooftop slab internal insulation structure of the building.
delete Claim 3 has been abandoned upon payment of a set-up fee. The method of claim 1,
The second insulation portion,
A second heat insulating part body having a receiving groove for receiving the second heat insulating member;
A door connected to the second insulation body in a hinged manner and opening and closing the accommodation groove;
And a motor connected to the hinge in an axial manner and including a motor for rotating and opening and closing the door according to the control of the controller.
The method of claim 1,
The first insulation member,
A cooling coil embedded in the first insulation portion;
A heating coil embedded in the first insulation portion;
A first terminal installed at a rear part of the first heat insulating part and connected to the cooling coil;
A second terminal installed at a rear part of the second heat insulating part and connected to the heating coil;
A first current provider installed inside the installation groove and providing a current for cooling;
Is installed inside the installation groove, provided with a second current provider for providing a current for heating,
On the inner side of the installation groove,
A first terminal groove connected to the first current provider and into which the first terminal is inserted is formed,
A second terminal groove connected to the second current provider and into which the second terminal is inserted is formed;
By the driving of the cylinder portion, the coupling between the first terminal and the first terminal groove and the coupling between the second terminal and the second terminal groove is determined, the roof slab internal insulation structure of a building.

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