KR101944930B1 - Piloti slab insulation structure of apartment - Google Patents

Abstract

The present invention relates to a piloti slab insulation structure of an apartment house. The piloti slab insulation structure of an apartment house comprises: a piloti layer spaced from the ground, and having a predetermined floor area; a support column supporting the piloti layer to be spaced from the ground surface at a predetermined height; a coupling unit installed in a lower end of the piloti layer; an insulation unit coupled through the coupling unit, and having an upper surface that is in contact with a lower end surface of the piloti layer; and an auxiliary insulation material injected between a lower end surface of the piloti layer and an upper surface of the insulation unit.

Description

[0001] PILOTI SLAB INSULATION STRUCTURE OF APARTMENT [0002]

The present invention relates to a pyrotechnic insulation structure for a residential building, and more particularly, to a heat insulation structure detachable from a lower portion of the pyrotechnic layer to enable application at the time of construction or after construction of a building, The present invention relates to a pyrotechnic insulation structure for a building, and more particularly, to a pyrotechnic insulation structure for a building.

Generally, a plurality of buildings including apartment houses are constructed to have a structure having a fatigue layer.

Such a pyrotechnic layer has a structure that is spaced upward from the ground at a certain height. Thus, the lower portion of the pyrotechnic layer forms an empty space.

The pyrotechnic layer is fixed and supported on the ground by pillars of the building. The column serves only as a support, and rather has a problem of transferring geothermal heat generated from the ground to the bottom of the pyrotechnic layer as it is, thereby lowering the heat insulation efficiency.

According to this structure, the indoor floor of the furniture which is located in the conventional fatigue layer is vulnerable to heat insulation.

Conventionally, only the pyrotechnic layer is provided with a separate heating and cooling system. However, this is difficult from the point of view of additional purchase per household.

In the literature related to the present invention, there is Korean Patent Laid-open Publication No. 10-2007-0029943 (Mar. 15, 2007), which has proposed a technique relating to floor heating.

A first object of the present invention is to provide a heat insulation structure detachable at the lower part of a pyrotechnic layer, and to provide a pyrotechnic insulation structure for a pyramid structure applicable at the time of construction or after construction.

It is a second object of the present invention to provide a pyrotechnic insulation structure for a pyramidal tile slab which can variably control the heat insulation efficiency in the bottom region of the pyrotechnic layer and actively control the insulation efficiency according to the external temperature.

In order to achieve the above object, the present invention provides a multi-housing pyrotechnic slab insulation structure.

The apartment house pyrotechnic slab insulation structure includes a pyrotechnic layer spaced from the ground and having a set floor area; A support column supporting the fatigue layer so as to be spaced apart from the ground at a predetermined height; A fastening portion provided at a lower end of the fatigue layer; A heat insulating portion fastened through the fastening portion and having an upper surface in close contact with a lower end surface of the fatigue layer; And an auxiliary insulating material injected between a bottom surface of the pyrotechnic layer and an upper surface of the heat insulating portion.

Wherein the bottom region is provided with a first temperature sensor for measuring a first temperature of the bottom region,

The heat insulating portion includes a heat insulating body formed of a metal and having an inner space formed therein, a partition plate disposed to be able to move up and down in the inner space, and an outer circumference of the inner space of the inner space and the outer circumference of the partition plate, A sealing member for dividing the inner space into an upper space and a lower space with the partition plate as a boundary, a lifting unit for lifting and lowering the partition plate, and a vacuum member for forming a predetermined vacuum in each of the upper space and the lower space, A second temperature sensor installed at a lower end of the heat insulating body for measuring a second temperature which is an external temperature and a control unit for controlling driving of the elevating unit and the vacuum providing unit,

The controller controls the lifting and lowering of the partition plate by controlling the driving of the lifting unit so that the first temperature and the second temperature have a predetermined temperature difference and adjusts the vacuum volume of the upper space and the lower space to be variable .

The elevator includes a plurality of motors having motor shafts, and a plurality of ball screws,

Wherein the plurality of ball screws are installed upright to be connected and screwed at a plurality of positions of the partition plate,

The upper ends of the plurality of ball screws are rotatably supported on the upper end of the heat insulating member body,

The lower ends of the plurality of ball screws are connected to shafts of the plurality of motors,

Wherein the partition plate is lifted and lowered in accordance with a rotation direction of the plurality of ball screws,

Preferably, the plurality of motors are disposed at the lower end of the heat insulating body so as to be exposed to the outside.

Wherein the fastening portions are fastening grooves formed at a plurality of positions of the fatigue layer,

And a fastening member for fastening the fastening recesses to the upper end of the heat insulating body,

The lower end of the fatigue layer and the upper end of the heat insulating body are convex-concave,

The auxiliary insulating material is preferably filled in a space between a lower end of the fatigue layer and an upper end of the heat insulating body.

Particularly, a cooling coil and a heating coil are buried in the heat insulating body,

Wherein the cooling coil forms a first wave path inside the heat insulating body,

The heating coil forms a second wave path inside the heat insulating body,

Wherein the first wave path and the second wave path form a path that does not intersect with each other,

The cooling coil is cooled to a predetermined temperature by receiving a current from the first current supplier,

The heating coil is heated to a predetermined temperature by receiving a current from the second current supplier,

The first and second current supply units are preferably driven under the control of the control unit.

A moisture removing layer having a solid moisture-removing material embedded therein is formed in the heat-

It is preferable that the moisture removal layer is exposed to the inner space through a plurality of through holes formed in an inner wall of the heat insulation body.

The column is provided with a geothermal accumulator for accumulating heat generated in the ground,

The geothermal heat accumulator includes a heat transfer conduit and a pump,

Wherein the heat transfer pipe is embedded in the inside of the support column and the fatigue layer,

One end and the other end of the heat transfer pipe are connected to the geothermal heat accumulator to form a circulation flow path,

Preferably, the pump is installed on the heat transfer pipe and moves the accumulated heat along the heat transfer pipe under the control of the control unit.

First embossing protrusions are formed on the inner wall of the inner space of the heat insulating body,

Second embossing protrusions are formed on the upper and lower ends of the bulge liner, and a heat insulating material is filled in the first and second embossing protrusions.

An outer heat insulating layer having a predetermined thickness is further formed around the heat insulating body,

Preferably, the outer heat insulating layer and the outer surface of the heat insulating body form a wave-like connection.

According to the above-mentioned solution, the present invention provides a heat-insulating structure detachable from the bottom of the pyrotechnic layer and has an effect applicable at the time of construction or after construction of the building.

In addition, the present invention has the effect of varying the heat insulating volume in the bottom region of the pyrotechnic layer and actively controlling the heat insulating efficiency according to the external temperature.

FIG. 1 is a view showing a pyrotechnic insulation slab insulation structure according to the present invention. FIG.
2 is a view showing an insulating part according to the present invention.
3 is a view showing a state in which the partition plate is moved in the heat insulating unit according to the present invention.
4 is a cross-sectional view showing an insulating part according to the present invention.
5 is a view showing a state in which the heat insulating portion according to the present invention is installed at the lower end of the fatigue layer.
FIG. 6 is a view illustrating a state in which the insulating portion and the bottom of the fatigue layer according to the present invention are coupled with each other in a concave-convex manner.
7 is a view showing an example in which a geothermal heat accumulator is installed on a supporting column 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.

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.

Hereinafter, the structure of the apartment house fatigue slab insulation according to the present invention will be described.

FIG. 1 is a view showing a pyrotechnic insulation slab insulation structure according to the present invention. FIG. 2 is a view showing an insulating part according to the present invention. 3 is a view showing a state in which the partition plate is moved in the heat insulating unit according to the present invention. 4 is a cross-sectional view showing an insulating part according to the present invention. 5 is a view showing a state in which the heat insulating portion according to the present invention is installed at the lower end of the fatigue layer. FIG. 6 is a view illustrating a state in which the insulating portion and the bottom of the fatigue layer according to the present invention are coupled with each other in a concave-convex manner.

Referring to FIGS. 1 to 6, the apartment house pyrotechnic slab insulation structure of the present invention includes a pyrotechnic layer 100 spaced from the ground and having a predetermined bottom area 110, (300) which is installed at a lower end of the fatigue layer (100), and a fixing part (300) fastened through the fastening part (300) And an auxiliary insulating material 500 injected between a bottom surface of the fatigue layer 100 and an upper surface of the heat insulating part.

In the bottom region 110, a first temperature sensor 120 for measuring a first temperature of the bottom region 110 is provided.

The heat insulating part 400 includes a heat insulating body 410 formed of a metal and having an inner space formed therein, a partition plate 420 disposed to be able to move up and down in the inner space, A sealing member 430 elastically connecting the outer periphery of the plate 420 to partition the inner space into an upper space and a lower space with the partition plate 420 as a boundary, (450) for forming a vacuum in each of the upper space and the lower space, and a second temperature sensor (450) installed at a lower end of the heat insulating body (410) And a control unit 470 for controlling the driving of the elevating unit 440 and the vacuum supply unit 450. The second temperature sensor 460 measures the temperature of the vacuum chamber 450,

The control unit 470 controls the driving of the elevating unit 440 to control the elevating and lowering positions of the partitioning plate 420 so that the first temperature and the second temperature have a predetermined temperature difference, And the vacuum volume of the lower space can be variably controlled.

The elevating unit 440 includes a plurality of motors 441 having motor shafts and a plurality of ball screws 442.

The plurality of ball screws 442 are vertically installed to penetrate and screw at a plurality of positions of the partition plate 420.

The upper ends of the plurality of ball screws 442 are rotatably supported on the upper end of the heat insulating body 410.

The lower ends of the plurality of ball screws 442 are connected to shafts of the motors 441, respectively.

The partition plate 420 is lifted and lowered in accordance with the rotation direction of the plurality of ball screws 442.

The plurality of motors 441 are disposed at the lower end of the heat insulating body 410 so as to be exposed to the outside.

The coupling portion 300 is a coupling groove formed at a plurality of positions of the fatigue layer 100.

At the upper end of the heat insulating body 410, fastening members 411 to be fastened to the fastening grooves are provided.

The lower end of the fatigue layer 100 and the upper end of the heat insulating body 410 may be concavo-convex coupled to each other.

The auxiliary insulating material 500 may be filled in a space between the lower end of the fatigue layer 100 and the upper end of the heat insulating body 410.

Particularly, although not shown in the drawings, the cooling coil and the heating coil are buried in the heat insulating body 410.

The cooling coil forms a first wave path inside the heat insulating body 410.

The heating coil forms a second wave path inside the heat insulating body.

The first wave path and the second wave path form a path that does not intersect with each other.

The cooling coil is cooled to a predetermined temperature by receiving a current from the first current provider, and the heating coil is heated to a predetermined temperature by receiving a current from the second current provider.

The first and second current sources may be driven under the control of the controller 470.

In addition, the heat insulating body 410 is formed with a moisture removing layer in which a solid moisture removing material is embedded.

The moisture removal layer may be exposed to the inner space through a plurality of through holes formed in the inner wall of the heat insulation body 410.

7 is a view showing an example in which a geothermal heat accumulator is installed on a supporting column according to the present invention.

Referring to FIG. 7, the column 200 is provided with a geothermal accumulator 210 for accumulating heat generated in the ground.

The geothermal heat accumulator 210 includes a heat transfer pipe 211 and a pump 212.

The heat transfer pipe 211 is embedded in the inside of the support column 200 and the fatigue layer 100.

One end and the other end of the heat transfer pipe 211 are connected to the geothermal heat accumulator 210 to form a circulation flow path.

The pump 212 is installed on the heat transfer pipe 211 and forcibly moves the accumulated heat along the heat transfer pipe 211 under the control of the controller 470 to circulate the heat.

Here, a geothermal collecting part 213 for directly collecting geothermal heat is buried in the ground. The geothermal heat collecting unit 213 is embedded with a geothermal heat transfer pipe 214 embedded in the ground. In the geothermal heat transfer pipe 214, geothermal collecting protrusions 215 having sharp ends are formed.

The first embossing protrusions are formed on the inner wall of the inner space of the heat insulating body 410.

Second embossing protrusions are formed on the upper and lower ends of the partition plate 420. The first and second embossing projections are filled with a heat insulating material.

In addition, an external heat insulating layer having a predetermined thickness is further formed around the heat insulating body 410.

The outer heat insulating layer and the outer surface of the heat insulating body 410 may have a wave-like connection.

According to the above-described structure and operation, the embodiment according to the present invention has a heat insulating structure detachable from the bottom of the pyrotechnic layer, and has an effect applicable at the time of construction or after construction of a building.

In addition, the embodiment according to the present invention has an effect that the heat insulating efficiency can be actively controlled according to the external temperature by implementing the heat insulating volume in the bottom region of the pyrotechnic layer variably.

As described above, the concrete housing fatigue-slab heat insulation structure of the present invention has been described. However, it is apparent that various modifications are possible within the scope of the present invention.

Therefore, the scope of the present invention should not be limited to the above-described embodiments, but should be determined by the scope of the appended claims and equivalents thereof.

It is to be understood that the foregoing embodiments are illustrative and not restrictive in all respects and that the scope of the present invention is indicated by the appended claims rather than the foregoing description, It is intended that all changes and modifications derived from the equivalent concept be included within the scope of the present invention.

100: pyrochlore layer
200: support column
300: fastening part
400:
410: Heat insulating body
420: partition plate
430: sealing member
440:
450: vacuum supply
460: second temperature sensor
470:
500: Auxiliary insulation

Claims (4)

A fatigue layer spaced from the ground and having a set bottom area;
A support column supporting the fatigue layer so as to be spaced apart from the ground at a predetermined height;
A fastening portion provided at a lower end of the fatigue layer;
A heat insulating portion fastened through the fastening portion and having an upper surface in close contact with a lower end surface of the fatigue layer; And
And an auxiliary insulating material injected between a bottom surface of the pyrotechnic layer and an upper surface of the heat insulating portion,
Wherein the bottom region is provided with a first temperature sensor for measuring a first temperature of the bottom region,
The heat-
A heat insulating body formed of a metal and having an internal space,
A partition plate that is vertically movable in the inner space,
A sealing member elastically connecting the inner wall of the inner space and the outer periphery of the partition plate to divide the inner space into an upper space and a lower space with the partition plate as a boundary,
A lifting portion for lifting the partition plate;
A vacuum supplier for forming a predetermined vacuum in each of the upper space and the lower space,
A second temperature sensor installed at the lower end of the heat insulating body for measuring a second temperature which is an external temperature,
And a control unit for controlling driving of the elevating unit and the vacuum supply unit,
Wherein,
Controlling the elevation position of the partition plate by controlling the driving of the elevation unit so that the first temperature and the second temperature have a predetermined temperature difference and variably controlling the vacuum volume of the upper space and the lower space,
Thermal insulation structure of apartment house.
delete The method according to claim 1,
The elevating unit includes:
A plurality of motors having motor shafts, and a plurality of ball screws,
The plurality of ball screws may include:
And is installed upright and connected to the partition plate at a plurality of positions,
The upper ends of the plurality of ball screws are rotatably supported on the upper end of the heat insulating member body,
The lower ends of the plurality of ball screws are connected to shafts of the plurality of motors,
The partition plate
Wherein the plurality of ball screws are lifted and lowered in accordance with rotation directions of the plurality of ball screws,
The plurality of motors include:
And a heat insulating member disposed at a lower end of the heat insulating member so as to be exposed to the outside,
Thermal insulation structure of apartment house.
◈ Claim 4 is abandoned due to the registration fee. The method of claim 3,
The fastening portion
A plurality of fastening grooves formed at a plurality of positions of the fatigue layer,
At the upper end of the heat insulating body,
Wherein the fastening members are fastened to the fastening grooves,
The lower end of the fatigue layer and the upper end of the heat insulating body are convex-concave,
Wherein the auxiliary insulating material is filled in a space between a lower end of the fatigue layer and an upper end of the heat insulating body,
Thermal insulation structure of apartment house.

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