KR101776481B1 - Eco-friendly Window systems for saving Energy - Google Patents

Abstract

The present invention relates to an environmentally friendly window system to save energy, comprising: a glass panel (10); a window frame comprising: an indoor frame (22) which includes a vertical member and a horizontal member, which fixate the glass panel, and a common unit placed on an indoor side; and an outdoor frame (24) placed on an outdoor side; a thermoelectric generator means (30) placed on the common unit of the indoor frame (22) of the window frame (20) to be attached to an internal surface on an indoor side; a cooler means (40) attached to the thermoelectric generator means (30) to cool a heat radiation unit; and an air blower means (50) which circulates air in the window frame (20) to settle the issues of local heat radiation and local cooling of the window frame (20). According to the present invention, the environmentally friendly window system to save energy, in a curtain wall and window system using much energy, is able to be cooled in summer and to radiate heat in winter, to prevent cooling/heating energy indoors from passing outdoors, to reduce the indoor cooling/heating load taken to the external air, to reduce energy loss due to a difference in temperature between indoors and outdoors in summer and winter, to ultimately reduce indoor energy consumption, and to reduce carbon emissions, thereby contributing to the prevention of global warming and national energy saving.

Description

Eco-friendly window systems for saving energy

The present invention relates to an energy saving type eco-friendly window system, and more particularly, to an energy saving type eco-friendly window system in which cooling and heating are performed using a Peltier effect and a Seebeck effect of a thermoelectric element, (PCM) into the window system to double the effect of the environmentally friendly window system.

Generally, according to the analysis of thermal management and energy efficiency of standard residential buildings, windows account for an average of 10% of the total wall surface, but at least 25% of the total heat emitted from the wall is lost through the window It is known. In addition, in the case of a building in which more than 50% of the walls are placed in a window for the convenience of the commercial building or the customer, and the mining and the prospect of the customer, the heat of the window may be lost by 45% And it takes a large portion in energy management.

Also, recently, the wall is acting as a curtain which separates the space from the load supporting structure. Such a wall is called a curtain wall and functions as an external function in addition to the blocking function, and is widely used in buildings. The curtain wall is made of a material such as a metal plate, a glass, a block, and a precast concrete. In recent years, an aluminum chassis and a glass panel have been widely used.

As described above, the glass or glass panel used for the window or the curtain wall of the building has an average thermal conductivity of about 1 W / mK, which is about 10 times more heat loss than the general building material, and the material of the flesh of the window or the chassis Aluminum, which has high thermal conductivity, has been used as a passive heat insulation system to block heat transfer, and a technique using polyamide and a method using polyurethane have been used.

However, due to the material properties, the aluminum window with such a conventional heat insulation system not only causes condensation due to the temperature difference outside the room, but also has a limited heat insulation performance. Therefore, the aluminum window is insulated rather than PVC material or wood material window There is a weak problem.

Accordingly, in order to overcome the energy loss of the conventional window system, Korean Patent Laid-Open Publication No. 10-2010-0106081 discloses a window system in which an awning member is installed between glass windows. However, As a constitution considered to solve this problem, the purpose of the space separation is purely a damage prevention of a low-emissivity (Low-E) coating, there is no concept of heat generation in a window system, and a heat generation and cooling function can not be achieved.

Japanese Unexamined Patent Application Publication No. 2001-193364 discloses that a heating element is provided between two-layered glass to warm a space by directly heating a large space between the glasses. However, There is a problem that it takes much time because the space must be directly heated to raise the temperature to a desired temperature.

Japanese Unexamined Patent Application Publication No. 2002-089154 discloses a double-layered glass having blinds. However, this is merely that the glass and the glass are formed in a multi-layered structure, and energy loss due to the difference in temperature between indoor and outdoor is large. And the like.

Korean Patent Publication No. 10-2010-0106081 Japanese Patent Application Laid-Open No. 2001-193364 Japanese Patent Application Laid-Open No. 2002-089154

An object of the present invention is to solve the above-mentioned problems and to reduce energy, and it is an object of the present invention to apply an active heat source system capable of maximally utilizing the thermal conductivity of aluminum itself, , And an aluminum window system to efficiently implement cooling and heating effects.

It is also an object of the present invention to provide an energy saving type eco-friendly window system that can reduce the indoor cooling and heating load taken by the outside air in curtain wall and window systems with high energy consumption.

In order to solve the above-mentioned problems, an energy saving type environmentally friendly window system according to the present invention,

A window system comprising a glass panel (10) and a window frame (20)

And a thermoelectric generator 30 provided in the window frame 20 to generate electricity and realize a cooling and heating effect.

Further, in the energy saving type environmentally friendly window system according to the present invention,

And air blowing means (50) for circulating air in the window frame (20) so as to eliminate local heat and local cooling of the window frame (20).

Further, in the energy saving type environmentally friendly window system according to the present invention,

The electricity generated by the thermoelectric generator 30 is supplied to the thermoelectric generator 30 or the blower 50 so that the energy is circulated.

Further, in the energy saving type environmentally friendly window system according to the present invention,

The blowing means (50) is constituted by a blowing fan and a damper type bracket, and air is circulated for each compartment of the window frame.

Further, in the energy saving type environmentally friendly window system according to the present invention,

The energy saving window system further includes a phase change member (60) in the window frame (20) to cool and heat the window frame (20) through heat accumulation or cooling operation, In the case of the present invention.

Further, an energy saving type environmentally friendly window system according to the present invention is characterized in that,

A glass panel 10;

A window frame (20) formed by vertical and horizontal members for fixing the glass panel, the window frame (20) comprising an indoor frame (22) having a cavity disposed on the indoor side and an outdoor frame (24) arranged on the outdoor side;

A thermoelectric generating unit 30 disposed in a cavity of the indoor frame 22 of the window frame 20 and attached to the inner surface of the room;

A cooler means 40 attached to the thermoelectric generating means 30 to cool the heat generating portion; And

And blowing means (50) for circulating air in the window frame (20) so as to eliminate local heat and local cooling of the window frame (20).

Further, in the energy saving type environmentally friendly window system according to the present invention,

The window frame 20 further includes a connecting rod 26 which is engaged with the indoor frame 22 and the outdoor frame 24 to be fastened.

Further, in the energy saving type environmentally friendly window system according to the present invention,

The thermoelectric generator 30 is made of a thermoelectric element and the heat absorbing part 32 and the heat generating part 34 of the thermoelectric element are selected in accordance with the relative direction of the element or a direction of the applied electric current .

Further, in the energy saving type environmentally friendly window system according to the present invention,

The thermoelectric generator 30 is characterized in that the thermoelectric generator 30 generates electricity through the thermoelectric generator while cooling and generating heat using the Peltier effect and the Seebeck effect of the thermoelectric element.

Further, in the energy saving type environmentally friendly window system according to the present invention,

The energy saving window system may further include a solar cell module as an electric energy source.

Further, in the energy saving type environmentally friendly window system according to the present invention,

The cooler means 40 is constituted by a heat dissipating fan for dissipating the heat of the heat generating portion 34 of the thermoelectric generator 30.

Further, in the energy saving type environmentally friendly window system according to the present invention,

And a ceramic member (45) is further provided between the cooler means (40) and the thermoelectric generating means (30).

Further, in the energy saving type environmentally friendly window system according to the present invention,

The ceramic member 45 is any one selected from fine ceramic materials made of alumina, aluminum nitride, and silicon carbide.

Further, in the energy saving type environmentally friendly window system according to the present invention,

The air blowing means (50) is provided with a blowing fan in an inner cavity of the indoor frame (22) of the window frame (20), and air is circulated for each compartment formed by the vertical member and the horizontal member of the window frame Or a ventilation fan is provided for each of the grafting portions to which the vertical member and the horizontal member are connected or a flow path branched to the straight air passage and the horizontal air passage so that the air flow is linear and horizontal In the direction of the arrow.

Further, in the energy saving type environmentally friendly window system according to the present invention,

The energy saving window system further includes a phase change member (60) in a cavity portion of the indoor frame of the window frame (20) to emit heat or cool air stored in the window frame And the cooling effect and the heat generation effect of the heat exchanger are increased.

Further, in the energy saving type environmentally friendly window system according to the present invention,

The phase change member 60 is coated on the inner surface of the hollow portion of the indoor frame 22, coated or sponge-shaped.

The energy saving type environmentally friendly window system according to the present invention has an effect that the aluminum window system can efficiently realize the effect of cooling and heat generation by the thermal storage material combined with the thermal conductivity of aluminum itself.

In addition, the energy-saving environmentally friendly window system according to the present invention is characterized in that, in a curtain wall and window system having a large energy consumption, a window frame is cooled in summer and a window frame is heated in winter, It is possible to reduce the indoor cooling and heating load which is taken away by the outside air.

In addition, the energy-saving environmentally friendly window system according to the present invention reduces the energy loss due to the indoor and outdoor temperature difference during summer and winter, so that the indoor energy consumption is ultimately reduced and the carbon emission is reduced, There is an eco-friendly effect that contributes to national energy saving.

FIG. 1 is a schematic view showing a state in which an energy-saving environmentally friendly window system according to a preferred embodiment of the present invention is installed on a window frame of a grid shape;
Fig. 2 is an enlarged view of a portion M in Fig. 1,
Fig. 3 is a plan view of Fig. 2,
4 is a view schematically showing a state in which the phase change member is coated on an indoor frame and an example in which the air blowing means is provided in an indoor frame,
5 is a schematic view showing that an energy saving type environmentally friendly window system according to another preferred embodiment of the present invention can be installed in a single type of window frames and window frames.

Hereinafter, a preferred embodiment of an energy saving environmentally friendly window system according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a schematic view showing a state in which an energy saving type environmentally friendly window system according to a preferred embodiment of the present invention is installed in a latticed window frame. FIG. 2 is an enlarged view of a portion M in FIG. FIG. 4 is a schematic view illustrating a state in which a phase change member is coated on an indoor frame in an energy saving environmentally friendly window system according to the present invention and an example in which an air blowing means is provided in an indoor frame. Is a schematic view showing that an energy saving type environmentally friendly window system according to an example can be installed in a single type of window frames and window frames.

1 to 5, an energy-saving environmentally friendly window system 1 according to the present invention includes a glass panel 10, a glass panel 10, A thermoelectric generator 30 mounted on the inner surface of the cabinet frame, the thermoelectric generator 30 being installed in the cavity of the window frame, and a thermoelectric generator 30 mounted on the thermoelectric generator, A cooler means 40 for cooling the heat generating portion, and a blowing means 50 for circulating air in the window frame so as to eliminate local heat and local cooling.

The glass panel 10 is preferably made of a heat insulating glass material, but may be replaced with a reinforced plastic material having transparency or other glass material.

The window frame 20 has a bracket shape having a cavity portion, and includes an indoor frame 22 disposed on the indoor side, an outdoor frame 24 disposed on the outdoor side, and an outdoor frame 24 interlocked with the indoor frame and the outdoor frame to connect them. And a connecting rod 26. The glass panel 10 such as a window or a door is fixed. Here, a plurality of protrusions are formed at the connection portions of the indoor frame 22 and the outdoor frame 24, which are connected to each other, so as not to be engaged with the connection rod 26.

The window frame 20 is composed of a vertical member 20a and a horizontal member 20b and a plurality of vertical members 20a and horizontal members 20b are arranged in a lattice form to form a lattice, It is also possible to provide only the upper, lower, right, and outer rims of the window fastened adjacent thereto. Further, the window frame is preferably made of a highly conductive aluminum material so as to enhance the durability and increase the cooling and heating effect.

A sealing member 15 such as a sealant is provided at a contact portion between the window frame 10 and the window frame 10 to prevent indoor and outdoor air flow through the contact portion to reduce the cooling and adiabatic effect, In order to prevent the glass panel from being broken or scratching on the glass panel in the process of being pressed onto the glass panel.

The thermoelectric generating means 30 is formed by using a thermoelectric module having a pair of P-type and N-type semiconductor device pairs fixed between two ceramic substrates. And is attached to the inner surface of the room. At this time, the heat absorbing portion 32 and the heat generating portion 34 of the thermoelectric element 30 may be selected in accordance with the relative electric element or the opposite direction of the applied electric current.

The thermoelectric generating unit 30 uses the Peltier effect and the Seebeck effect of the thermoelectric element to cool and generate heat while at the same time discharging the electricity generated through the thermoelectromotive force to the blower fan Or to supply energy to the thermoelectric element so that the energy can be circulated.

Here, the Peltier effect refers to a phenomenon in which a direct current voltage is applied to both ends of two different elements to absorb heat on one side and generate heat on the other side depending on the direction of current. The energy required for electrons to move between two metals The opposite effect of the Peltier effect is the phenomenon in which a potential difference occurs on the closed circuit due to the difference in temperature between two different devices, which causes current to flow. Free electrons gain energy and this energy is used to generate electromotive force.

In the present invention, a system capable of performing an energy circulation cycle by eco-friendly means by buffering the temperature difference between the indoor and the outdoor by heat absorption and heat generation by the thermoelectric generating means 30 and driving the generated electric heat dissipating fan or blowing fan or re- .

It goes without saying that the electric energy required in the present invention can be supplied from the sunlight, which is environmentally friendly renewable energy. At this time, the solar cell module can be attached along the outer surface of the outdoor frame 24 or directly placed on the window using a transparent material, thereby preventing the view through the window from being obscured and connected to other components through the electric wire to be.

The cooler means 40 is attached to the thermoelectric generating means 30 to cool the heat generating portion 34. The heat absorbing portion 32 absorbs heat from the heat absorbing portion 32 of the thermoelectric generating means 30, And a heat-dissipating fan for dissipating heat of the heat-generating portion 34 during the diverging process. At this time, the cooler means may be formed integrally with the thermoelectric generator or may be separately attached to form one unit.

The cooler means is preferably provided to be attached to the heat generating portion 34 of the thermoelectric generator 30 or to absorb the heat of the heat generating portion and a heat conduction between the heat generating portion 34 and the cooler means 40 The ceramic member 45 having a high thermal conductivity can be further provided. Here, the ceramic member 45 is preferably selected from fine ceramic materials such as alumina, aluminum nitride, and silicon carbide. The thickness of the ceramic member is preferably as thin as possible in order to minimize the heat transfer path. However, Mu m is preferable. Such a thin ceramic member improves the heat radiation characteristic.

The blowing means 50 circulates the air in the window frame so as to eliminate local heat and local cooling by the thermoelectric generating means 30, and may be constituted by a blowing fan and a damper type bracket (not shown). Here, the damper type bracket is an apparatus that allows the flow of air to flow in one direction or in different directions, and is formed by branching at least two flow paths, and it is of course possible to selectively block any one flow path .

The blowing means 50 according to the present invention has a structure in which a vertical member 20a and a horizontal member 20b forming a plurality of compartments in a lattice form each air circulation system for each compartment or an entire air circulation system A damper bracket provided so as to allow the flow direction of the air to branch forward and a blowing fan provided for each knotted portion where the vertical member and the horizontal member are connected or a flow path structure branched to the straight air passage and the horizontal air passage, So that the air flow can be moved up and down straight and easily moved in the horizontal direction.

It is preferable that the blowing means is provided at a joint portion (J or A) provided in the inner cavity of the indoor frame (22) of the window frame, to which the vertical member and the horizontal member are connected.

In addition, the window system according to the present invention may be provided in a window frame of a single window frame as shown in FIG. 4 or in an interior frame or a window frame of both window frames.

In addition, the present invention improves the cooling and heating effect of a window frame through heat accumulation or cooling action and dissipates heat or cold stored in the room, and uniform heat generation and cooling are generated to maintain the heating effect and cooling effect The phase change member 60 may further be provided in the cavity of the window frame so as to reduce the electrical consumption of the thermoelectric element. At this time, the phase change member 60 may be coated on the inner surface of the hollow portion of the indoor frame 22, coated or sponge-shaped.

The phase change member 60 is solid at room temperature. When the ambient temperature is increased, the phase change member 60 absorbs heat and is converted into a liquid state. When the ambient temperature is lowered, ; Phase Change Material), which absorbs heat or cold air from a heat frame or window frame made of thermoelectric elements and emits heat and cold when the temperature difference occurs after heat storage and cooling.

The arrangement of the solar cell module and the electrical connection line are well known in the art, and detailed drawings are omitted in the present invention.

Further, in the present invention, the thermoelectric generating elements or the phase change member, that is, the width and the length of the thermoelectric generating element or the phase change member are contacted with the entire inner side of the inner side of the indoor frame So that the heat generating efficiency or the cooling efficiency can be increased.

Hereinafter, the energy saving method in the energy saving type eco-friendly window system (1) according to the present invention will be described as summer and winter.

<In case of summer season>

In summer, the outdoor air, the glass panel 10, and the window frame 20 made of aluminum are heated by solar heat and high temperature outside the room.

At this time, the heat absorbing portion 32 of the thermoelectric element provided in contact with the indoor frame 22 of the heated window frame 20 absorbs heat from the window frame and emits heat toward the heat generating portion 34, Cool down the temperature.

At the same time, the free electrons in the thermoelectric element take energy and generate electricity.

The generated electricity is applied to the heat radiating fan of the cooler means 40 connected to the heating line or the blowing fan of the blowing means 50 to operate the fan. By the operation of the fan, the air is supplied to the damper- So that the temperature of the window frame 20 is lowered because the temperature of the heat emitted by the circulating air is lowered.

The cold air from the window frame 20 having a lower temperature cools the adjacent glass panel and circulates around the glass panel to prevent the outdoor heat from entering the room through the glass panel and preventing the cold air from escaping outdoors .

Further, when the phase change member 60 is provided in the cavity portion of the indoor frame, the phase-converted member that absorbs heat and is cooled by the air circulating in the liquid state to the solid state, It becomes possible to absorb heat from the frame.

<Winter season>

In winter, the outdoor air, the glass panel 10, and the aluminum frame 20 are cooled by low altitude and low temperature outside.

At this time, it is preferable that the thermoelectric element located at the cavity of the indoor frame 22 of the cooled window frame 20 is attached to the inner surface of the indoor frame. At this time, heat is absorbed from the air in the cavity or heat generated by a power source applied from the installed solar cell is discharged to the heat generating part (34) in contact with the window frame to raise the temperature of the window frame .

Similarly, in addition to the electricity applied from the solar cell module, the thermoelectric element generates electricity by allowing free electrons to move within the thermoelectric element.

The generated electricity is applied to the heat radiating fan of the cooler means 40 connected to the heating line or the blowing fan of the blowing means 50 to operate the fan. By the operation of the fan, the air is supplied to the damper- The heat generated by the circulation air circulates through the window frame 20 to increase the temperature of the window frame as a whole.

The heat from the window frame 20 having a high temperature heats the adjacent glass panel and circulates around the glass panel and prevents the cold air from entering the room through the glass panel and preventing the warmth of the room from escaping outdoors .

When the phase change member 60 is provided in the cavity portion of the indoor frame, the heat generated by the heat generating portion is absorbed and supplied to the contacting indoor frame to be reduced to a solid state, So that the cold air can be shut off.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

1: Energy saving window system 10: Glass panel
15: sealing member 20: window frame
20a, 20b: a vertical member and a horizontal member 22: an indoor frame
24: outdoor frame 26: connecting rod
30: thermoelectric generating means 32:
34: heat generating unit 40: cooler means
50: blower means 60: phase change member

Claims (16)

A window system comprising a glass panel (10) and a window frame (20)
A thermoelectric generator 30 provided in the window frame 20 to generate electricity and to realize a cooling and heating effect,
And a blowing means (50) for circulating air in the window frame (20) so as to eliminate local heat and local cooling of the window frame (20)
The damper-type bracket is configured to be branched into at least two flow paths that can be selectively blocked. The damper-type bracket is configured to be divided into at least two flow paths by the air flow that is vertically advanced and horizontally moved, Air is circulated for each section of the frame,
The window frame 20 is provided with the phase-change member 60 in contact with the entire inner surface of the inner side of the inner frame so that the heat is transferred to the window frame 20 through the surface heat- Wherein the window frame (20) is configured to raise the cooling and heating effect of the window frame (20).
delete The method according to claim 1,
Wherein the electricity generated by the thermoelectric generator (30) is supplied to the thermoelectric generator (30) or the blower (50) so that energy is circulated. Eco friendly window system.
delete delete A glass panel 10;
A window frame (20) formed by vertical and horizontal members for fixing the glass panel, the window frame (20) comprising an indoor frame (22) having a cavity disposed on the indoor side and an outdoor frame (24) arranged on the outdoor side;
A thermoelectric generating unit 30 disposed in a cavity of the indoor frame 22 of the window frame 20 and attached to the inner surface of the room;
A cooler means 40 attached to the thermoelectric generating means 30 to cool the heat generating portion; And
And blowing means (50) for circulating air in the window frame (20) so as to eliminate local heat and local cooling of the window frame (20)
The damper-type bracket is configured to be branched into at least two flow paths that can be selectively blocked. The damper-type bracket is configured to be divided into at least two flow paths by the air flow that is vertically advanced and horizontally moved, Air is circulated for each section of the frame,
The window frame 20 is provided with the phase-change member 60 so as to be in contact with the entire inner surface of the inside of the cavity of the indoor frame so as to emit heat or cool air reserved in the surface heat- Is configured to increase the cooling and heating effect of the window frame (20) through the window (20).
The method according to claim 6,
The energy saving type eco-friendly window system according to claim 1, wherein the window frame (20) further comprises a connecting rod (26) which is engaged with the indoor frame (22) and the outdoor frame (24).
The method according to claim 6,
The thermoelectric generating means 30 is made of a thermoelectric element and the heat absorbing portion 32 and the heat generating portion 34 of the thermoelectric element are selected in accordance with the relative direction of the element or the direction of the applied electric current, Energy saving environment friendly window system.
The method according to claim 6,
Wherein the thermoelectric generating means (30) generates electricity through the thermoelectric power generation while cooling and generating heat using the Peltier effect and the Seebeck effect of the thermoelectric element.
The method according to claim 6,
Wherein the energy saving window system further comprises a solar cell module as an electric energy supply source.
The method according to claim 6,
Wherein the cooler means (40) comprises a heat dissipating fan for dissipating the heat of the heat generating portion (34) of the thermoelectric generating means (30).
The method according to claim 6,
Further comprising a ceramic member (45) between the cooler means (40) and the thermoelectric generating means (30).
13. The method of claim 12,
Wherein the ceramic member (45) is any one selected from fine ceramic materials made of alumina, aluminum nitride, and silicon carbide.
delete delete The method according to claim 6,
Wherein the phase change member (60) is applied to the inner surface of the hollow portion of the indoor frame (22), coated, or formed in the form of a sponge, and attached.

Images