KR20130014757A - The wall and roof of water -conditioning or water-heating function - Google Patents

Abstract

PURPOSE: Walls and a roof of a building for executing a cooling and heating function are provided to maintain a pleasant indoor environment by removing air directly discharged from indoor cooling or heating devices. CONSTITUTION: Walls and a roof of a building for executing a cooling and heating function comprises an integral wall, a spraying unit, a cooling and heating unit, a collecting well(80), and a mounting unit. Finishing materials are air tightly adhered to the front and rear sides of a frame(10) of the wall so that the integral wall is formed. A pipe(50) and a nozzle are installed in an inner top of the integral wall so that the spraying unit sprays cooling and heating water to the inside the frame. The collecting well and a boiler are installed at a specific position of the building. The pipe connects the collecting well and cooling and heating devices(86,87). The mounting unit connects cooling and heating water supply pipes installed on the top of the wall and the collecting well and installs a pump(92) between the pipes. [Reference numerals] (20) Front; (21) Rear; (87) Heating device

Description

{The Wall and Roof of water -conditioning or water-heating function}

Since the present invention enables the building walls and roofs to perform cooling and heating functions, it is intended to minimize the energy excessively used for existing cooling and heating, and to create an eco-friendly building without CO ² emission using solar heat and solar light.

Until now, centralized installation of cold and heating equipment for cooling and heating of buildings has been solved by installing them through pipes or by installing cold and heating equipment in each floor and each room. It is intended to make functional walls and roofs with heating functions.

The present invention should have a function of compensating the temperature in addition to the function of the wall or the roof of the existing building and also to utilize the structural characteristics for producing environmentally friendly energy.

In the present invention, to solve the problems as described above, to make a double wall or a roof body having a watertight function, and to create a unitary wall and roof bonded the finishing material in front and rear of the frame and the frame A pipe is installed in the upper part (building) to inject cold and heating water, and the lower part (lower part of the building) has a drainage path where cold and heating water is collected. Allow the function to repeat the process automatically.

The present invention can significantly reduce the total amount of energy required for cooling and heating by efficiently using energy because the walls of the building performs the cooling and heating functions.

Therefore, there is no need for existing cooling and heating equipment or limited use, and there is no need for air conditioning piping for cooling and heating.

In particular, since there is no air from the direct cold and heating equipment in the room, a comfortable indoor environment can be maintained.

It is a structure that is easy to produce energy for cooling and heating with environmentally friendly energy using solar heat and sunlight.

This construction method can be used not only for new buildings, but also has the advantage that it can be applied as an additional construction to existing buildings.

In addition, there are many examples of finishing the exterior wall with glass for the aesthetics of the building, but it has been raised as a problem due to the effect of raising the indoor temperature by the glass greenhouse effect. In this case, applying this method has the advantage of solving the problem of cooling and heating without compromising the original design of the building.

1 is a side, side view of the integral skeleton forming a frame
Figure 2 is a cross-sectional view of the front and rear finishing material construction
3 is a perspective view of a heat sink
4 is a cross-sectional view of the construction of the skeleton in the basic frame of the building
5 is a cooling and heating system diagram of the building constructed with the present frame
6 is a cross-sectional view of a solar heat collector
7 is a cross-sectional view of the solar cell installed on the back of the windshield of the frame
Description of the Related Art [0002]
10; Skeleton 13; Weld
20; Front glass 21; Back glass
40; Heat sink 40-1; live
50; Piping 45; Building basic framing
60; Drain pipe 80; Collection
81; Temperature sensor 85 in the sump well; Central controller
86; Air conditioning apparatus 87; Heater
92; Pump
100; Heat-Fired Solar Collectors
150; Flat solar collector
200; Solar cell
210; Protective resin
220; Wiring

In the present invention, the wall (including the roof) of the building is to join the integral frame and the finishing material before and after the structure to support the structure in order to perform the cooling and heating function in a watertight structure.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily implement the embodiments. 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.

1 is a side, side view of the integral skeleton constituting the skeleton.

Referring to FIG. 1, the material and the thickness of the frame are determined based on the structural calculation considering the load of the wall, and based on this, a hat shape having each of the wings 10a and 10b is formed in the shape of FIG. The other one is arranged symmetrically to each other and between the groove bar between the round bar 12 of the thickness at 90 degrees and then welded to each other (13, 13a, 13b ...). Frame material 10 thus made is a frame of trust type made of a minimum of material considering the structural strength.

In some cases, this framing material can be used in the form of I-Beam to produce the same effect.

Watertight bonding of the finishing material 20a between the wings 10b and 10c of the frame 10 and watertight bonding of the finishing material 21b between the wings 11b and the wings 11c are integral walls with front and back blocked. Is formed.

2 is a cross-sectional view of the finish before and after the present frame.

In this case, moisture or water may come into contact with the finishing materials 20a and 21b attached to the front and back of the frame 10, such as deformation or corrosion. Glass or the like, which may or may not touch water, may directly touch water or water.

3 is a perspective view of a heat sink.

When the finishing materials 20a and 21b are materials having problems such as deformation or corrosion due to moisture or water, the heat sink 40 is installed inside the frame 10.

The heat sink 40 is made of a metal (aluminum or copper plate) having a good thermal conductivity or a flat pipe 40 made of a heat-conductive plastic material and gives a rib 40-1 to improve the heat dissipation effect on the inner and outer surfaces. The rib 40-1 increases the structural strength of the heat sink, and the rib 40-2 inside serves to evenly cool the cooling water or the heating water.

Figure 4 is a cross-sectional view of the construction of the present bone in the building basic frame.

Referring to an example in which the main frame 10 is installed in the basic frame 45 of the building, the frame 10 is installed from the upper part to the lower part of the building basic wall (including the roofing body) 45 and the frame 10 is minimized. A pipe 50 for spraying cooling or heating water is installed at the upper center, and the pipe 50 and the heat sink 40 are integrally attached to each other.

Cooling or heating water flows by discharging cooling or heating water between the heat sinks 40 to solve the watertightness problem. Also, the cooling and heating water flows along the heat sink 40 to the lower portion of the framework material 10 to reduce the temperature inside the building. Adjust to the set temperature.

In consideration of aesthetics, when constructing walls with the front and rear finishing materials (20, 21) of the frame (10), the room temperature is controlled by spraying cooling or heating water directly on the glass surface without using the heat sink (40). At this time, the watertight problem should be watertightly the part where the glass and the glass meet and the part where the glass and the frame meet.

And if the building is curved in design, in order to make the heat sink 40 in a flexible form, it may be made in the form of a tube made of aluminum foil or the like.

In addition, if the design of the building is not possible to use the frame (10) can be constructed only by the heat sink (40).

5 is a heating and cooling system diagram of a building constructed with the present frame.

The water collecting well (80) for storing cooling water or heating water is installed on any one of the roof or basement of the building, the first floor, and the like, and a temperature sensing sensor (81) for measuring the water temperature is always installed therein. Sends the water temperature to the central controller (85).

In addition, the air conditioner 86 and the heater 87 is installed next to the sump, and each of the pipes 86a and 87a is connected to the sump 80.

The cooling device 86 and the heating device 87 operate in accordance with the set temperature displayed on the central controller 85 to maintain the water temperature of the sump 80 at the set temperature.

In addition, one side of the cold, heating water pipe 40 installed in the top of the building, that is, the frame 10, the sump well 80 and the connection pipe 50, and the pump 92 is installed in the middle.

Then, the indoor temperature sensor 90 is placed inside the building, and the indoor temperature is always detected, and the pump 92 is operated according to the set temperature displayed on the indoor temperature setting controller.

When the pump 92 is operated, cooling water or heating water of the sump 80 is sprayed into the heat sink 40 through the pipe 50. The sprayed cold and heated water flows on the wall to make the room temperature at the set temperature, and when the set temperature reaches the set temperature, the pump 92 stops operation and repeatedly operates the room temperature to maintain the room temperature.

Cold and heating water collected in the drain pipe 60 installed in the lower part of the building, that is, the frame 10 is sent back to the sump 80.

This series of repetitive operations are made automatically and cooling and heating is made in a water collecting well (80), but there is actually a difference between winter and summer depending on the time difference.

And the sump (80) can be installed in one or more plural or capacity according to the need and can be installed separately the sump (80) of cooling water and heating water.

As shown in FIG. 5, the roof surface is constructed with a heat sink 40, and a finishing material is used for the roof, and the front surface is a glass 20, 21.

In case of wall construction with glass (20, 21), if cooling and heating are solved by spraying cold and heating water directly on glass (20, 21) without heat sink (40), it can be installed without harming the original appearance of glass. have.

In the case of a large building or a high-rise building, when the cooling and heating water flows and the efficiency decreases, a plurality of systems may be installed to compensate for this.

6 is a cross-sectional view of a solar collector installed on a building.

In order to obtain heating energy using solar heat, a solar collector (heat pipe type (100) or flat type (150)) is installed between the front glass 20 and the rear glass 21 inside the frame 10 and the pipe ( Pipe 110 and 160 in conjunction with the sump (80).

In case of heating, the water warmed by solar heat during the day is stored in the sump 80, and when the room temperature is below the set temperature, it is sprayed on the wall or the roof to maintain the set temperature.

The existing heater 87 is used as an auxiliary heat source when there is no sun (cloudy day, snowy, rainy day, etc.) or when the heat source is insufficient.

Since the collector (100,150) is installed inside the frame (10), it is not directly in contact with the outside air, thereby increasing the efficiency of collection and

In addition, the winter problem, which is a problem of the existing collector, is installed inside the frame 10 so that it always maintains a constant temperature, thereby solving the problem of freezing.

7 is a cross-sectional view of the solar cell installed on the back of the windshield of the aggregate.

In order to produce the electrical energy required to operate the building, the solar cell 200 is installed on the back of the glass 20 of the frame 10 of the wall (including the roof), and the moisture protection and the solar cell protection resin 210 are covered. To close. At this time, each of the wiring 220 of the solar cell is located inside the frame (10).

Since it is directly installed on the windshield 20 forming the wall (including the roof), the conventional solar cell panel has a much more economical and clean appearance than the method of constructing a double on the building roof or in front of the wall.

In addition, since the solar cell 200 is placed inside the frame 10 in order to reduce the power generation efficiency caused by the increase of the solar cell temperature, which is a problem of the existing panel method, the power generation efficiency can be kept constant at a constant temperature.

In addition, when the solar cell 200 is constructed as a transparent solar cell for the inherent transparency of the glass considering the aesthetics of the wall, the transparency of the glass can be maintained.

Claims (9)

The wall (including the roof) of the building itself is to perform the heating and cooling function,
An integral wall (including a roof) which is watertightly bonded to the finishing materials 20a, 20b ... in front of and behind the frame 10 constituting the wall (including the roof);
Means for injecting cold and heating water into the frame 10 by installing a pipe 50 and a nozzle for supplying cooling and heating water at the top of the integrated wall (including the roof):
A means for making the drain pipe 60 at the bottom of the wall and collecting the cold and heating water collected therein to send the cold and heating water flowing down the wall to the sump 80;
Means for spraying cold and heating water directly onto the glass when the building walls are constructed with glass to see the cold and heating effect;
Means for installing a heat sink (40) inside the frame for watertightness when the finishing material (20a, 20b ...) of the building wall is finished with a material weak against moisture or water;
Install a sump well (80), a heating device (boiler) 87 for making heating water, and an air conditioner (86) for making cooling water in a predetermined position of the building (place where the underground is most effective), ) Pipes (86,87) in conjunction with the cold, heating (86,87);
In addition, the water pipe (80) and the cold, heating water supply pipe 50 in the upper wall in conjunction with the pipe and the means for installing a pump 92 therebetween;
To operate the above system automatically
It has a room temperature sensor 90 and a temperature controller 91 inside the building and a water temperature sensor 81 for detecting the water temperature inside the sump 80 and a central controller 85 in an easy place;
When the indoor temperature is set to the temperature controller 91, the sensor 90 which senses the indoor temperature sends the signal to the central controller 85, and the central controller 85 receiving the signal is below the set temperature (heating) or abnormal ( Cooling) operates the pump 92 installed in the sump 80 to inject cooling and heating water into the wall.
In addition, the sensor 81 that senses the temperature of the cooling and heating water inside the sump 80 sends the signal to the central controller 85, and the central controller 85 receives the signal according to the set temperature. The heater 87 is operated to maintain the water temperature of the cold and heated water in the sump 80 at the set temperature.
Walls of buildings (including roofs) that perform cooling and heating functions, consisting of means for automatically operating all of these series of operations. The method of claim 1, further comprising:
The frame 10 is made in the form of a hat with both wings (10a, 10b) and another one arranged symmetrically with each other between the grooves of the thickness of the round bar (12) at a 90 ° angle and then contact each other A structure of a trust type in which the places 13, 13a, 13b ... are welded; 3. The method of claim 2,
When the round bar 12 is replaced by a non-round iron plate, the partition wall is made of structural material made by designing holes and the like on the iron plate. (I-beam type frame). The method of claim 1, further comprising:
A means for flowing cold and heating water into the heat sink 40 by heat-producing metal or plastic for watertightness on the roof or wall; The method of claim 4
Means for improving the heat dissipation effect of the heat dissipation plate 40, equalizing heat dissipation, and improving the directionality of the sprayed water (anti-tension), and at the same time, for strengthening the structure; 5. The method of claim 4,
Means for making the heat sink 40 in the form of a tube with aluminum foil or the like in order to give flexibility to the heat sink 40 because the heat sink 40 is not suitable for construction in a straight shape when the building has a curved shape; The method of claim 1, wherein
Means for performing cooling and heating functions while maintaining transparency of the glass by spraying cold and heating water directly on the glass when the outer wall considering the aesthetics is constructed of glass in front of and behind the frame in the glass building; The method of claim 1, wherein
Means for installing a solar collector (heat pipe type or flat plate type) inside the present aggregate to make the environment-friendly heating energy; The method of claim 1, wherein
A means of installing solar cells on the back of the windshield of this frame to produce electrical energy for building operations.

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