KR101169886B1 - Window system for saving energy and method for controlling the same - Google Patents

Abstract

PURPOSE: An energy-saving multifunctional window system and a control method thereof are provided to reduce carbon exhaust by improving heating, cooling, and heat insulating efficiency. CONSTITUTION: An energy-saving multifunctional window system comprises first, second, third, and fourth heating laminated glass windows(C1,C2,C3,C4), a shading unit, a binder, and a frame(1). The second heating laminated glass window is separated from the first heating laminated glass window. The third heating laminated glass window is separated from the second heating laminated glass window. The fourth heating laminated glass window is separated from the third heating laminated glass window. The shading unit is formed between the second and third heating laminated glass windows and selectively shields sunlight. The binder seals the edges of the first, second, third, and fourth heating laminated glass windows. The frame supports the first, second, third, and fourth heating laminated glass windows separated from each other.

Description

Energy-saving multifunctional window system and its control method {window system for saving energy and method for controlling the same}

The present invention relates to a multi-functional wall combined window system (hereinafter, referred to as a 'window system') that produces an insulation effect and a light-shielding and shading effect by heat generation control, and more specifically, a window of a general house or apartment farm, When applied to walls, sloped roofs, etc., it is possible to effectively prevent snow removal, thawing, and dew condensation through heat generation control, and to improve the efficiency of solar energy utilization through control of solar transmittance. The present invention relates to a low-carbon, eco-friendly and high-efficiency multifunctional insulation window system that can reduce the amount of fossil fuel used and the carbon emissions.

In general, in the study of thermal management and energy efficiency analysis of standard residential buildings, windows are known to lose about 10% of the total wall area, but more than 25% of the total wall heat is lost through the windows. Since buildings with more than 50% of windows installed for commercial purposes or prospects can lose at least 45% of heat, insulation of windows is a major part of the total energy management of the building.

The heat loss caused by windows and doors can have a significant impact not only on ground structures, but also in large passenger ships or temporary housing.In particular, on large cruise ships with 5,000 or more passengers, one third of the total fuel is used for heating the passengers, In winter or polar routes, up to 1/2 is used. On the other hand, due to the convenience of passengers and skylight, the area ratio of windows is increasing and heat loss of windows is increasing.

Most of the transparent materials of building windows are amorphous sodium glass, but heat-treated crystalline glass or high-strength glass is used, but the average thermal conductivity is about 1W / mK and more than 10 times of heat loss occurs than general building materials.

On the other hand, the prior art Patent No. 10-0905803 discloses a window system that is installed on the balcony of the building is installed on the balcony of the building in the multi-storey glass windows to insulate while separating the interior and the exterior.

That is, the Patent No. 10-0905803 (hereinafter referred to as "prior art"), the outer window 60 is installed on the outer wall of the balcony; An inner window 50 formed on the balcony and spaced apart from the outer window 60 at predetermined intervals to form an insulation space 55 between the outer window 60 and the outer window 60; Is installed in the heat insulating space 55 of the inner window 50 is interposed between the outer window 60 and the inner window 50, overlapping or unfolding as the sunlight projected to the outer window 60 as needed Sunshade to selectively shield; And a ventilation member for opening and closing a portion of the outer window 60 and the inner window 50 to ventilate the outside air and the inside of the building, wherein the shading member is overlapped or developed in the insulation space 55. Remote control for controlling the operation of the awning member 72 having the awning blade 72a, the retractor 74 to automatically overlap or unfold the awning blade 72a of the awning member 72 and the retractor 74 It includes 76, the operation is controlled by the remote control 76, the heat generating blade 72a of the sunshade member 72 is expanded by the retractor 74 using a power applied from the outside Further comprising a heat generating member, wherein the heat generating member is integrally attached to the sunshade blade 72a, the planar heating element 78 and the terminal of the planar heating element 78 is provided with a terminal (T) through which power is introduced ( The power cord that supplies power through It includes, the ventilation member is formed through a portion of the outer window 60 and the inner window 50 through the outer window 60 and the inner window 50 to communicate the outside air and bet through the hole shape to enable ventilation One side of the ventilation unit 82, the outer window 60 and the inner window 50 is fixed to the hinge (H), the opening and closing plate for opening and closing the ventilation unit 82 while rotating around the hinge (H) ( 84) and a switch for opening and closing the opening and closing plate 84 by rotating the hinge (H), the switch is protruded to the hinge (H) is rotated by the hinge (H) and the opening and closing plate (84) Opening and closing projections (86) for opening and closing by pushing one side of the window and the balcony window comprising a motor (88) for operating the opening and closing projections 86 by rotating the hinge (H) is connected to the hinge (H) System is disclosed.

However, the above-described balcony window system of the Patent No. 10-0905803 has the following limitations and disadvantages of application.

First, the sunshade member structure applied in the prior art is a structure that is generally widely applied inside the residential window, the sunshade blade is a structure that overlaps or expands up and down. Accordingly, the window system according to the prior art is extremely difficult to install in an inclined structure rather than an upright structure.

That is, for example, when the window system of the prior art is applied to an inclined roof in an apartment farm with an inclined roof, the shading member sags in the direction of gravity, causing interference with the inner window, thereby causing the operation of the shading member to be abnormal. There is a problem.

In the abnormal operation of the sunshade member, there is a problem in the solar shielding action, such as shading and floodlight, which causes a loss of function or efficiency of the window system.

In short, the window system according to the prior art is a window system specially adapted to be installed in an upright state, such as a balcony, as the name of the invention, there is a limit to diversify its application.

In addition, the window system according to the prior art has a disadvantage that productivity is reduced due to the increase in the manufacturing process because the heating element is attached to the blade.

In particular, the existing windows and doors including the window system according to the prior art is used to move and rotate the blade in the use of the blade, a problem such as the shading member does not work due to the twist of the thread during use often occurs Can be.

When such a problem occurs in a window system of the prior art, if accessibility to the inside of the window is not good, it may not be possible to repair the problem that may need to replace the entire window.

In particular, the insulation technology applied to the existing windows and windows is to heat the space layer directly by heating the space between the glass and glass, but this takes a long time to heat up to the desired temperature, resulting in waste of electricity and deterioration of insulation efficiency. There is a problem.

The present invention is to solve the above problems, when applied to the building structure, such as apartment farms or general houses to increase the efficiency of heating and cooling insulation at low power to reduce the amount of fossil fuel and carbon emissions and solar power generation accordingly When applied to module cover or inclined roof of apartment farm, it is possible to effectively control snow removal, thawing and dew condensation by controlling heat generation at low power, and to improve efficiency of solar energy utilization through control of solar transmittance. Its purpose is to provide a highly efficient, multi-functional insulation window and door system.

On the other hand, another object of the present invention is to detect the temperature of the shade target (for example, photovoltaic power generation module) to be controlled through the window system, or to detect the indoor and outdoor and the window or the temperature of each heating laminated glass window, sensing Provides an intelligent window system that can independently generate heat and shade control based on the detected detection value, and provides a window system and its control method to remotely control a multifunctional window system based on ubiquitous and freely access the network. It is in

In order to achieve the above object, the present invention, the first heat-emitting laminated glass window; A second heat generating laminated glass window spaced apart from the first heat generating laminated glass window; A third heat generating laminated glass window spaced apart from the second heat generating laminated glass window; A fourth heat generating laminated glass window spaced apart from the third heat generating laminated glass window; A sunshade member provided for selective shielding of sunlight in a space spaced between the second heat generating laminated glass window and the third heat generating laminated glass window; A bonding agent sealing each edge of the first heat generating laminated glass window to the fourth heat generating laminated glass window; Provided is an energy-saving multifunctional window system comprising a; frame is installed so as to support spaced apart from the first heat generating laminated glass window to the fourth heat generating laminated glass window.

On the other hand, according to another aspect of the present invention for achieving the above object, in the energy-saving multi-functional window system control method, the temperature of any one or more of the laminated glass window of the first heat generating laminated glass window to the fourth heating laminated glass window Detecting; Detecting indoor and outdoor temperatures; Detecting a temperature of a space in which the shade member is installed; Sending to the control unit according to the temperature of at least one of the first heat generating laminated glass window and the fourth heat generating laminated glass window detected at each step, the indoor and outdoor temperatures, and the temperature of the space in which the shade member is installed; The heating element installed in the laminated glass window so as to maintain a set target value of the temperature of the laminated glass window to be controlled among the first to fourth heating glass windows according to a pre-programmed value by reading each temperature sensor received value from the controller. It provides a method for controlling energy-saving multifunctional windows and doors, characterized in that it comprises a step of controlling.

The effects of the present invention are as follows.

First, when applied to residential building structures, agricultural livestock and horticultural building structures, it is possible to reduce the amount of fossil fuel consumption and carbon emissions by increasing thermal management efficiency through effective thermal insulation.

That is, in order to insulate, the control temperature of the inner glass window (the first heat generating laminated glass window) is higher than the control temperature of the target room by a certain temperature (for example, 1 degree, which is changed according to the insulation condition of the building to be installed and installed). Direct input is possible by the operation of the integrated control panel such as a computer.

In particular, if the heat insulation conditions of the cold weather or the existing building is poor, and the indoor insulation is insufficient with only the first heat generating laminated glass window, the fourth heat generating glass window is heated to form the maximum heat insulating condition, and the temperature control generates the temperature signal of the temperature sensor itself. Received by the integrated control panel, the program in the control panel automatically controls whether the heating of each heating glass pane according to the use conditions and temperature most efficiently.

And, in winter, by controlling the opening angle of the sunshade member constituting the sunshade corresponding to the sun irradiation angle can maximize the amount of solar energy inflow, but can effectively prevent the internal heat from escaping to the outside.

In addition, it is possible to remove the winter frost and snow through the heat generation control.

On the other hand, in summer, the sun rise is basically minimized by solar heat in the room, but if necessary, by controlling the opening angle of the sunshade member corresponding to the irradiation angle of the sun can maximize the solar energy inflow.

In addition, through the selective control of the amount of light transmission in the summer, it is possible to increase the power generation efficiency of the photovoltaic module for using the green energy of sunlight as electrical energy.

In particular, the power generation of the solar power is reduced as the temperature rise of the module due to the characteristics of the solar cell. The decrease in output appears to decrease the efficiency of solar power generation. Therefore, in order to improve the output of the photovoltaic module to lower the temperature of the module, the present invention by blocking the direct sunlight in summer through the shading action of the shade member rather lower the temperature of the photovoltaic module to increase the power generation efficiency Can contribute to

The large amount of solar radiation does not mean that the output of the panel is maximized. The output drops as the module temperature rises. It is known that the output of 0.45 to 0.55% decreases when the temperature rises by 1 degree.

On the other hand, the present invention can solve the problem of lowering the efficiency of photovoltaic power generation by the winter snow through an effective heating system. That is, the snow accumulated in the outermost glass window can be melted by heat by the heating of the outermost glass window (fourth heat generating laminated glass window), and thus the power generation efficiency of the photovoltaic module can be improved even in winter.

In particular, the photovoltaic module is often installed in a high altitude area, so it can be quite dangerous, such as falling accidents during snow removal work, according to the present invention can solve the safety problems caused by snow removal work. .

In another big feature, the present invention is an intelligent window system, the solar cell module temperature, the external temperature, etc. by grasping the sensor, the summer sun is a large amount of solar radiation by remote control via an integrated control panel or RF (Radio Frequency) By changing the angle of the awning to prevent the rise of the temperature of the photovoltaic module, during the winter snowfall, the control panel and the RF remotely controlled through the RF to form an air heating layer through the heat generation The efficiency can be improved.

In addition, it is possible to detect the temperature of the shade object (for example, the photovoltaic power generation module) to be controlled through the window system or the indoor and window temperature, and to independently control the heating and shade based on the detected detection value. In particular, it is based on ubiquitous and can freely access the network to remotely control the window system.

In addition, it is also possible to control the operation of the window system using a smartphone.

 The present invention can provide a low-carbon eco-friendly and high-efficiency multi-functional insulation window system, increase the value of the building as an environmentally friendly element and can be applied to the construction of new construction or renovation of existing buildings and due to the winter heating load and summer cooling load Power peaks can be moderated.

1 is a perspective view showing a window system according to the prior art
2 is a front view showing the detailed configuration of the sunshade member shown in FIG.
3 is a perspective view showing an example of use of the window system shown in FIG.
Figure 4 is a perspective view showing the structure of the balcony window system according to the present invention
5A and 5B are side views of FIG. 4 for explaining shading,
Figure 5a is a partial cutaway side view for explaining the state of the sunshade member open
Figure 5b is a partial cutaway side view for explaining the shade state
6 is a cross-sectional view along the line I-I of FIG.
7 is a perspective view showing the structure of the heating laminated glass window of the present invention and the main cross-sectional view
8 and 9 show an application example of the window system of the present invention,
8 is a reference view showing a state in which the window system of the present invention is applied to the inclined roof
9 is a reference view showing a state in which the window system of the present invention is applied as a cover of the photovoltaic module
10 is a view showing a remote control system as another embodiment of the window system according to the present invention.
11a and 11b is a perspective view showing a rack / pinion structure as another embodiment of the power transmission means of the present invention

Hereinafter, a window system according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 11.

Prior to the description of each embodiment of the present invention, it is assumed that the window system of the present invention includes not only the concept of a window for a general house but also a concept as a cover for a wall of a building structure or a general structure or device. That is, it is assumed that the window system of the present invention having heat generation control, heat insulation effect, and light blocking control function is not limited to the concept of the existing simple house window system.

[Example 1]

Window system according to the present embodiment, the first heat generating laminated glass (C1); A second heat generating laminated glass (C2) spaced apart from the first heat generating laminated glass (C1); A third heat generating laminated glass (C3) spaced apart from the second heat generating laminated glass (C2); A fourth heat generating laminated glass (C4) spaced apart from the third heat generating laminated glass (C3); Shading means provided for selective shielding of sunlight in a space spaced between the second heat generating laminated glass window (C2) and the third heat generating laminated glass window (C3); A bonding agent (3) sealing each edge of the first heat generating laminated glass window (C1) to the fourth heat generating laminated glass window (C4); And a frame 1 installed to support the first heat generating laminated glass window C1 to the fourth heat generating laminated glass window C4 apart from each other.

In this case, each of the first heat generating laminated glass window C1 to the fourth heat generating laminated glass window C4 includes at least two laminated glass windows bonded to each other and a heating element provided between the laminated glass windows.

And, the sunshade means, a plurality of sunshade member 2 which is spaced apart at regular intervals in the vertical direction in the space between the third heat generating laminated glass (C3) spaced apart from the second heat generating laminated glass (C2), A sunshade member supporting means for rotatably supporting the sunshade member 2 to allow selective shielding of sunlight by the sunshade of the sunshade member 2, and the sunshade member (2) to rotate the sunshade member (2). It is configured to include a power transmission means for transmitting a rotational force to 2).

In addition, the sunshade member 2 has a column portion 200 is provided with a worm gear (5b) for receiving a driving force from the power transmission means.

And, the awning member support means, the column support hole is provided separately inside the frame (1) so as to support the awning member (2) without sag rotatable while determining the separation distance between the awning member (2) The formed spacing plate 10 (see FIG. 1).

On the other hand, unlike the present embodiment, the awning member support means, may be a column support groove (not shown) formed in the inner surface of the frame (1). That is, without forming a spacing plate, the column support groove which is inserted into the end of the column part 200 directly inserted into the inner surface of the frame 1 may be formed to support the rotatable member without any sag when the shading member 2 is assembled. to be.

The power transmission means includes a drive motor 4 as a drive source, in which the worm 5a and the worm gear 5b are coupled to each other. A worm 5a which receives the driving force from the driving motor 4 and rotates the worm 5a; And a worm gear 5b provided in the column part 200 of the sunshade member 2 so as to be engaged with the worm 5a. At this time, a reducer (not shown) is provided between the drive motor 4 and the worm 5a, and the power of the drive motor 4 is decelerated by the reducer and transmitted to the worm 5a.

On the other hand, the heat generating element provided inside the first heat generating laminated glass window C1 to the fourth heat generating laminated glass window C4 is arranged on the surface of the laminated glass window as a linear heating element or a planar heating element.

In the case of the linear heating element, a generally used heating wire is applied to the heating element, and a nichrome wire, a carbon heating wire, or a silicon heating wire coated with silicon may be used. The planar heating element may include carbon (CARBON) and graphite (GRAPHITE). ) May be applied.

On the other hand, a temperature sensor (not shown) is provided in each of the first heat generating laminated glass C1 to the fourth heat generating laminated glass C4, and a temperature sensor for measuring indoor and outdoor temperatures indoors and outdoors. Are omitted, respectively, and a temperature sensor (not shown) is also provided in the third space P2, which is a shading member installation space between the second heat generating glass pane and the third heat generating glass pane.

In addition, the sunshade member 2 is preferably attached to the reflective sheet 20 on the surface.

The operation of the window system according to the present embodiment configured as described above is as follows.

Referring to FIG. 1, when the left side of the first heat generating laminated glass C1 is indoor and the right side of the fourth heat generating laminated glass C4 is outdoor, the first heat generating laminated glass C1 maintains an indoor temperature. It is a heat generating laminated glass window, the second heating laminated glass window (C2) acts as an auxiliary heating window for reducing power when operating the first heating laminated glass window (C1) under the condition of maintaining the set room temperature.

For example, when only the first heat generating laminated glass window C1 is operated for 10 minutes in order to create a condition for maintaining the room temperature at 25 degrees in winter, the first heat generating laminated glass window C1 and the second heat generating laminated glass window are required. When you run (C2) at the same time, three minutes will have the same effect.

In addition, a space between the first heat generating laminated glass C1 and the second heat generating laminated glass C2 (hereinafter, the first space P1), the third heat generating laminated glass window C3, and the fourth heat generating laminated glass window C4 The space between the spaces (hereinafter, the second space P2) is to ensure the sustainability of the temperature of the first heat generating laminated glass C1 to the fourth heat generating laminated glass C4, and at the same time, the low power of the heat generating unit is realized. To help.

In addition, the space in which the shading member 2 is installed (hereinafter, the third space P3) also serves as a buffer for blocking a kind of heat exchange, thereby contributing to blocking the entry and exit of energy.

On the other hand, the sunshade member 2 is a sunshade for adjusting the amount of light of the way that only the angle of rotation of the sunshade member 2 is adjusted on the spot without lifting action, it is possible to adjust the amount of light according to the rotation angle regardless of the season, especially hot summer By eliminating the gap between the sunshade member 2 to the maximum rotation angle, it is possible to block the inflow of the radiant heat from the sun or infrared rays.

In addition, the third heat generating glass window (C3) and the fourth heating glass window (C4) is used for the thawing, snow melting and condensation removal in winter through the heating of the built-in heating wire (W), as described above In extreme cases, the first heat generating laminated glass C1 and the second heat generating laminated glass C2 work together to generate heat to effectively prevent the energy of the room from escaping to the outside.

That is, the second space P2 formed between the third heat generating glass window C3 and the fourth heat generating glass window C4 together with the heat generating action of the third heat generating glass window C3 is the fourth heating glass window C4. Helps keep the set temperature at low power.

For example, the set temperature of the fourth heat generating glass window (C4) to maintain the image 1 ~ 2 ℃ during cold weather or snow, so that the fourth heating glass window (C4) is thawed, thawed, condensation removal, the heat generated The third heat generating laminated glass C3 and the second space P2 forming the air layer help to maintain the set temperature of the fourth heat generating laminated glass C4 at low power.

In particular, since the reflective sheet 20 attached to the awning member 2 surface reflects sunlight to the outside, the sunlight reflected from the reflective sheet 20 freezes to the outside of the fourth heat generating laminated glass C4. It also helps relieve condensation from snow, snow, and dew.

Hereinafter, the specific action of the window system according to the season will be described with an example.

First, in winter, by maintaining the surface temperature of the first heat generating laminated glass window (C1) 1 ~ 2 ℃ higher than the room temperature to prevent the emission through the window of the room energy, the second heat generating laminated glass window (C2) is the first heat generation As an auxiliary laminated glass window for preserving the temperature of the laminated glass window C1, it serves as a supporting part for maintaining the temperature of the first heat generating laminated glass window C1 with minimum power.

In addition, the first space P1 traps the temperature formed by the heat generation of the heating wires W embedded in the first heat generating laminated glass window C1 and the second heat generating laminated glass window C2 in a closed space, thereby providing the first heat generating laminated glass. It plays a critical role in maintaining the temperature by the minimum power of the glass window (C1).

On the other hand, the set temperature of the fourth heat generating glass window (C4) in winter to maintain the image 1 ~ 2 ℃ in cold weather or snow so that the fourth heat generating glass window (C4) is thawed, thawing, condensation removal.

In addition, the second space (P2) is the fourth heating layer by trapping the heat energy formed by the heat generation of the heating wire (W) built in the third heat generating glass window (C3) and the fourth heating glass window (C4) in a closed space It plays a decisive role in achieving the temperature maintenance of the window C4 at the minimum power.

In addition, the third space P3 in which the shading member 2 is installed also acts as a thermal buffer to prevent heat exchange, thereby maintaining the temperature of the first and fourth heat generating glass panes C1 and C4. Helped.

That is, in order to insulate during winter, the control temperature of the inner glass window (the first heat generating glass window C1) is higher than the control temperature of the target room by a certain temperature (for example, 1 degree, which is changed according to the thermal insulation condition of the building to be installed). It can be directly input by the operation of integrated control panel such as PLC or computer during installation.) Actively blocks the heat emitted from the room to the outside, and the first heat insulation laminated glass window due to the poor heat insulation condition of the cold weather or the existing building. If the heat of (C1) alone is not enough to block the escape of the heat inside the room to the outside to generate the maximum heat insulating conditions by heating the fourth heat-emitting laminated glass window (C4).

The temperature control is a temperature sensor installed in the indoor and outdoor temperature sensor, the first heat generating laminated glass (C1) to the fourth heat generating laminated glass (C4), the second heat generating laminated glass (C2) and the third heat generating laminated glass (C3). Receives temperature signals such as temperature sensors in the awning member's installation space from its integrated control panel and automatically applies power to each heating glass pane by a program in the control panel to control the heat generation to be the most efficient temperature condition according to the usage conditions and temperature. do.

On the other hand, in the summer, the first heat generating laminated glass (C1) to the fourth heat generating laminated glass (C4) is not supplied with power, but structurally delays the outflow of the indoor cooling energy to the outdoor. That is, the air layer of the first space P1, the second space P2, and the third space P3 formed between the first heat generating laminated glass C1 to the fourth heat generating laminated glass C4 and the laminated glass windows. By the adiabatic action, the outdoor leakage of cooling energy is effectively reduced.

In addition, the heating element built in the first heat generating glass window (C1) to the fourth heat generating glass window (C4) has a power saving structure as much as possible by the automatic control method according to the application of electric power and electric power in an integrated control panel such as a computer or a PLC. Is achieved.

According to the present embodiment, the first space P1 and the second space P2 can reduce the amount of power required to keep the fourth heat generating laminated glass C4 warm, and the reflection attached to the sunshade member 2 is reduced. When the sheet 20 melts a part of the snow or ice accumulated on the surface of the fourth heat generating laminated glass C4 and the sunlight starts to flow into the reflective sheet 20, the sheet 20 melts by the reflective action of the reflective sheet 20. And the thawing effect can be accelerated.

On the other hand, with reference to Figures 5a and 5b will be described the solar shielding and opening action of the window system according to this embodiment.

First, referring to FIG. 5A, FIG. 5A is a state in which the sunshade member 2 of the window system is opened to allow sunlight to flow therein.

In this state, when the worm 5a is rotated by the drive of the drive motor 4, the driving force is transmitted to each worm gear 5b provided in the shading member 2 so as to be engaged with the worm 5a. The sunshade member 2 coupled to each worm gear 5b rotates at the same time.

Referring to FIG. 5B, FIG. 5B is a state in which the shade member 2 is closed to block sunlight.

At this time, according to the rotation angle of the sunshade member 2, the degree of shielding of sunlight through the window system is of course determined.

As described above, the window system of the present embodiment is used in winter and the like to increase the heat management efficiency by heat generation of the four laminated glass windows constituting the window system when applied to residential and horticultural buildings, and thus the insulation of the air layer between the laminated glass windows. It is possible to reduce the amount of fossil fuel used and carbon emissions, and to remove winter frost and snowfall through heat generation control.

That is, the present invention primarily blocks heat exchange with indoors or outdoors through direct heating of the heat generating laminated glass windows, and generates heat from the first heat generating laminated glass window C1 to the fourth heat generating laminated glass window C4. The spaces P1 and the second spaces P2 are heated to act as thermal buffers to form a so-called air heating layer so that the temperature of each of the heating laminated glass windows is continuously maintained.

Accordingly, it is possible to reduce the amount of fossil fuel used and the carbon emissions associated with heating such as winter.

In addition, the window system of the present embodiment, in the case of frost occurs in the winter window, it is effective to effectively remove the frost and the like through the heating temperature control of the heating element, in the summer sun blocking the sunlight with the shade member (2) It does not supply power to the heating laminated glass window (C1) to the fourth heating laminated glass (C4) and structurally delays the outflow of the indoor cooling energy to the outside, thereby acting to maintain indoor cooling at minimum power.

[Example 2]

The window system according to the present embodiment is an example applied to an inclined structure such as an inclined roof such as an apartment farm, and is basically composed of the same components as the window system of the first embodiment.

At this time, the sunshade member 2 of the present embodiment is a structure that can be rotated only without sag, even if the window system is installed in a state inclined to the roof or the like is stable. That is, the existing household awning member that is folded up by pulling the string has a deflection in the direction of gravity when installed on the inclined roof, on the contrary, the awning member 2 of the present invention is installed only inclined because the structure can not be rotated and deflection is possible It is especially stable if

That is, according to the present embodiment, the window system of the present invention may be installed as a window to an inclined roof, such as an apartment farm, in which case, as mentioned above in winter, freezing may occur on the surface of the window or snow may accumulate. However, even when thickly frozen or a lot of snow accumulates, it is possible to effectively remove the laminated glass window at a low power for a long time in removing not only freezing but also snowing through the heating temperature control of the heating element and the space between the windows.

In particular, due to the weight of snow falling during the snowfall, facilities collapse, etc. cause a lot of social and economic problems, the window system of the present embodiment by melting the snow on the window immediately by removing the heating window, on the slope roof of the apartment farm It will increase the safety of the facility by reducing the overall weight of snow.

This action is especially essential in preparation for heavy snowfall, which is related to the recent abnormal temperature, and is a very important factor in terms of energy saving and securing safety of various building structures.

[Example 3]

The window system according to the present embodiment is basically composed of the same components as the window system of the first embodiment, except that the solar cell is installed on the surface of the shade member 2.

In the window system of the present embodiment configured as described above, a solar cell is installed on the surface of the shade member 2 instead of a reflective sheet, thereby driving power and / or driving the shade member 2 through heat generation through self-generation. Can be used to supply or supplement its own power.

Therefore, according to the present embodiment, snow removal, thawing, and dew condensation prevention can be performed through heat generation control, and the use of solar energy can be achieved by improving the utilization efficiency of solar energy through control of solar transmittance, which is environmentally friendly energy.

Example 4

The window system according to the present embodiment is basically composed of the same components as the window system of the first embodiment, but the window system of the first embodiment is hypothesized to be spaced apart from the ground and positioned below the object. A stand device 7 is further provided to perform the sunshade for the user.

The window system configured as described above increases the operating efficiency of the photovoltaic module by increasing the operating time of the photovoltaic module by blocking the sunlight flowing into the photovoltaic module through the operation control of the sunshade member 2 in the summer, and freezing in the winter. It is possible to increase power generation efficiency by eliminating snowfall and increasing the operating time of the photovoltaic module.

First, when applied as a cover device of the photovoltaic module for using the green energy solar light as electrical energy through the selective control of the amount of light transmission in the summer, it is possible to increase the power generation efficiency of the photovoltaic module by lowering the temperature.

Photovoltaic power generation is reduced due to the temperature rise of the module due to the characteristics of the solar cell. The decrease in output appears to decrease the efficiency of solar power generation.

In other words, even if the amount of solar radiation is unconditionally high, the output of the panel does not increase to the maximum. The output drops as the module temperature rises. It is known that the output of 0.45 to 0.55% decreases when the temperature rises by 1 degree.

Therefore, in order to improve the output of the photovoltaic power generation to lower the temperature of the photovoltaic module, the present invention is to increase the efficiency of the photovoltaic module by blocking direct sunlight in summer through the shading action of the shade member (2) Can contribute to

On the other hand, the present invention provides a window system that can effectively solve the problem of efficiency degradation of the photovoltaic module due to winter snow and ice. That is, if it is assumed that the fourth heat generating glass window (C4) is located on the outermost side of the photovoltaic module, when the outermost fourth heating glass window (C4) is warmed by heat, the snow falling on the glass window by heat It will not melt immediately, thus increasing the power generation efficiency of the photovoltaic module even in winter.

In particular, the first space P1 and the second space P2 can reduce the amount of power required to keep the fourth heat generating laminated glass C4 warm, and the reflective sheet 20 attached to the sunshade member 2. Due to the melting of any part of the snow or ice accumulated on the surface of the fourth heat generating laminated glass (C4) due to the solar light is introduced into the reflective sheet 20 by the reflection action of the sunlight on the reflective sheet 20 Thawing and thawing are accelerated.

In addition, the photovoltaic module is often installed in a high altitude area, so that a safety accident such as a fall may occur during snow removal, which is quite dangerous. According to the present invention, safety problems caused by snow removal can be solved. .

[Example 5]

The window system according to the present embodiment is basically composed of the same components as the window system of the first embodiment, and further includes a window system operating device (8).

That is, the window system of the present embodiment includes a window system operating device 8, which includes: a receiving unit 81 for receiving an input signal, a storage unit 82 for storing an input signal, And a controller 83 controlling the driver based on the input signal analysis and the analysis result, and a driver mechanically driving the window system according to the control signal of the controller 83.

In this case, the operating device 8 may further include a transmitter 84 for transmitting a control result to the outside.

On the other hand, the window system according to the present embodiment is provided with a remote terminal (9), the remote terminal (9), an infrared terminal, a computer using the Internet network, a smart phone using the Internet or mobile communication network, power line using a power line Any one of a communication modem and a terminal connected thereto.

On the other hand, the operating device 8 of the present embodiment is of course applicable to the window system of the present invention applied as a cover device of the photovoltaic module as well as the control of the windows installed on the wall or roof of the building structure.

The operation of the window system of this embodiment configured as described above is as follows.

Since the present invention uses telecommunication, it is possible to remotely control or monitor the window system anytime and anywhere without limitation of time and place.

On the other hand, according to the temperature control process according to this embodiment, the temperature of any one or more of the laminated glass window of the first heat generating laminated glass (C1) to the fourth heat generating laminated glass (C4), the indoor and outdoor temperature, the shading member (2) ) Detects the temperature of the third space (P3) is installed and sent to the integrated control panel such as a computer or a PLC.

Accordingly, the control unit of the integrated control panel reads the value of each of the temperature sensor receivers and performs feedback control so that the user can set a desired value by a pre-programmed value.

That is, a third space P3 in which the temperature of at least one of the first heat generating laminated glass C1 to the fourth heat generating laminated glass C4, the indoor and outdoor temperatures, and the shade member 2 are installed. When sent to the control unit according to the temperature of the), the control unit reads each temperature sensor received value by the value programmed in advance to maintain the room temperature at the desired temperature, the first heat generating laminated glass (C1) to the fourth heat generating laminated In the glass window C4, the temperature of the laminated glass window to be controlled is controlled so as to maintain a set target temperature.

For example, the power of each heating unit may be applied to maintain the temperature of the first heat generating laminated glass C1 by 1 degree higher than the room temperature by a pre-programmed value.

This temperature control process of the present embodiment is of course applicable to all the window system of the present invention of the first to fourth embodiments described above.

On the other hand, in the control method of the window system, data for control such as seasonal solar irradiation angle or target temperature may be input, and the rotation angle of the sunshade member 2 may be adjusted according to the input data.

In addition, such control adjusts the rotation angle of the sunshade member 2 of the window system, thereby adjusting the incident amount of sunlight, and applying the window system of the present invention as a cover device of the photovoltaic module. It can be adopted in order not to reduce the generation efficiency of the module.

In addition, such a control method may be applied as a method for effective mining when applied to a vertical wall or inclined roof of a horticultural or residential building structure as a window.

[Example 6]

On the other hand, referring to Figures 11a and 11b, a power transmission means other than that shown in the first embodiment can be configured. That is, it may be due to the coupling structure (not shown) of the rack 5c and the pinion 5d or the link structure (not shown) of the link.

As another example of the power transmission means, referring to FIG. 11, the coupling structure of the rack 5c and the pinion 5d is coupled to the drive motor 4 and the shaft tip of the drive motor 4. And a pinion (5d) provided in the sunshade member (2) to be engaged with the teeth formed in the rack (5c) and the rack (5c) is installed to engage in a linear motion.

At this time, it is preferable that a guide is further provided to guide the accurate linear movement of the rack (5c).

On the other hand, the power transmission means may be configured as a link connection structure, although not shown. In this case, the power transmission means includes a drive motor, a link eccentrically coupled to the axis of the drive motor, and a plurality of connection links connecting the link and each shading member.

On the other hand, the present invention is not limited to the above embodiments, it is possible to change and modify in various forms without departing from the scope of the technical spirit of the present invention.

For example, in Example 1, the temperature sensor is one in four spaces of the first heat generating laminated glass C1 to the fourth heat generating laminated glass C4, two places in the indoor and outdoor sides, and a spaced space P3 including the shade device. Although the location is provided, the installation number and location of the temperature sensor may be changed in consideration of the temperature control target, control method, measurement efficiency, installation environment, and the like.

Accordingly, the present invention is, therefore, defined in the claims as defined and not limited to the embodiments described above, and may be variously modified within the scope of the claims by those of ordinary skill in the art. It is self-evident that we can transform and adapt

When the present invention is applied to building structures such as an apartment farm or a general house, the present invention is highly applicable to use because it reduces the amount of fossil fuel used and carbon emissions by increasing the insulation efficiency during heating and cooling with low power.

In addition, the present invention can effectively perform snow removal, thawing and condensation prevention through the low-power heating control when applied to cover the solar power module or applied as a window or the like to the inclined roof of the apartment-type farm, and control the solar transmittance control It is an invention that is highly applicable to the industry because it can improve the solar energy utilization efficiency.

That is, the present invention can provide a low-carbon eco-friendly and high-efficiency multi-functional insulation window system, increase the value of the building as an environmentally friendly element, and can be applied to the construction of new construction structures or renovation of existing buildings, as well as winter heating loads and summer cooling loads. Power peak due to the temperature can be alleviated, and the temperature of the shade object to be controlled (e.g., the temperature of the photovoltaic module) to be controlled through the window system can be detected, or the room and window temperature can be detected, and the detected value is Based on ubiquitous, it is possible to control the heating and shade independently, and in particular, it is possible to remotely control the window system by accessing the network freely based on ubiquitous, so it can be applied as a cover device of solar power generation module. It is a very high invention.

C1: first heat generating glass window C2: second heat generating glass window
C3: third heat generating glass window C4: fourth heat generating glass window
P1: first space P2: second space
P3: third space W: hot wire
1: frame 10: spacing plate
2: sunshade member 20: reflective sheet
3: binder 4: drive motor
5a: Worm 5b: Worm Gear
6: temperature sensor 7: stand unit
8: operating unit 81: receiving unit
82: storage unit 83: control unit
84: transmitter 9: remote terminal

Claims (21)

First heat generating laminated glass (C1) and;
A second heat generating laminated glass (C2) installed spaced apart from the first heat generating laminated glass (C1) to form a first space (P1) which is an indoor spaced space;
A third heat generating laminated glass (C3) spaced apart from the second heat generating laminated glass (C2) to form a third space (P3) which is a shading member installation space;
A fourth heat generating laminated glass (C4) spaced apart from the third heat generating laminated glass (C3) to form a second space (P2) which is an outdoor spaced space;
Shading means provided for selective shielding of sunlight in a space spaced between the second heat generating laminated glass window (C2) and the third heat generating laminated glass window (C3);
A bonding agent (3) sealing each edge of the first heat generating laminated glass window (C1) to the fourth heat generating laminated glass window (C4);
And a frame (1) installed to support the first heat generating laminated glass window (C1) to the fourth heat generating laminated glass window (C4) apart from each other.
The shading means,
A window system, characterized in that the plurality of sunshade members (2) are installed spaced apart at regular intervals in the vertical direction of the window and rotatably installed in place without sagging. The method of claim 1,
The first heat generating laminated glass (C1) to the fourth heat generating laminated glass (C4),
And at least two or more laminated glass windows, and a heating element provided between the laminated glass windows. The method of claim 1,
The shading means,
A sunshade member supporting means for rotatably supporting the sunshade member 2 without sagging;
Window system, characterized in that it further comprises a power transmission means for transmitting a rotational force to the sunshade member 2 so that the sunshade member (2) is rotated. The method of claim 3, wherein
The sunshade member 2,
The window system, characterized in that it further comprises a column 200 for receiving the rotational force from the power transmission means. The method of claim 3, wherein
The sunshade member supporting means,
Window system, characterized in that the column support groove provided on the frame (1). The method of claim 3, wherein
The sunshade member supporting means,
The window system, characterized in that the spacing plate (10) formed with column support holes so as to support the sunshade member (2) rotatably without determining the separation distance between the sunshade member (2). The method of claim 3, wherein
The power transmission means,
A drive motor 4;
A worm 5a which is directly connected to the motor shaft of the drive motor 4 and rotates;
And a worm gear (5b) provided in the sunshade member (2) to be engaged with the worm (5a). The method of claim 3, wherein
The power transmission means,
A drive motor 4;
A rack (5c) installed to engage in a linear motion by engaging a gear coupled to the shaft end of the drive motor (4);
And a pinion (5d) provided on the sunshade member (2) to engage the teeth formed in the rack (5c). The method of claim 1,
A drive motor 4;
A link eccentrically coupled to an axis of the drive motor 4 from an axis center;
And a plurality of connection links connecting the link and each sunshade member. The method of claim 2,
The heating element,
A window system comprising a linear heating element or a strip-like planar heating element. 11. The method of claim 10,
The heating element,
A window system comprising a composite of carbon (CARBON) and graphite (GRAPHITE) or a nichrome alloy. 11. The method of claim 10,
The heating element is a window system, characterized in that arranged on the surface of the laminated glass window to form a sand-shaped structure. The method of claim 1,
A temperature sensor provided in at least one heat generating laminated glass window among the first heat generating laminated glass window C1 to the fourth heating laminated glass window C4;
Space between the first heat generating laminated glass C1 and the second heat generating laminated glass C2, and the space between the third heat generating laminated glass C3 and the fourth heat generating laminated glass C4 Temperature measurement of at least one of the second space (P2) which is a space, or the third space (P3) which is a shading member installation space between the second heat generating laminated glass (C2) and the third heat generating laminated glass (C3) Window system, characterized in that further comprises a temperature sensor is installed for. The method of claim 3, wherein
Window system, characterized in that the reflective sheet 20 is attached to the sunshade member surface. The method of claim 3, wherein
Window system, characterized in that the solar cell is installed on the sunshade member surface. A window system according to claim 1, further comprising a stand device (7) which is constructed so that the window system of claim 1 is spaced from the ground to perform the sunshade on the object located below the window system. 17. The method according to any one of claims 1 to 16,
The window system further comprises an operating device (8),
The operating device 8,
A receiver 81 for receiving an input signal;
A storage unit 82 which stores an input signal,
And a control unit (83) for controlling the window system based on the input signal analysis and the analysis result. The method of claim 17,
The window system is provided with a remote terminal (9),
The remote terminal 9,
Window system, characterized in that any one of the infrared terminal, a computer using the Internet network, a smartphone using the Internet network or mobile communication network, a power line communication modem using a power line and a terminal connected thereto. In the control method of the window system according to any one of claims 1 to 16,
Detecting a temperature of at least one of the first heat generating laminated glass windows C1 to the fourth heat generating laminated glass window C4;
Detecting indoor and outdoor temperatures;
Detecting a temperature of the third space P3 in which the shading member 2 is installed;
The third space in which the temperature of any one or more of the laminated glass windows, the indoor and outdoor temperatures, and the sunshade member 2 are installed in the first heat generating laminated glass window C1 to the fourth heating laminated glass window C4 detected at each step. Sending to the control unit according to the temperature of P3;
The control unit reads the received values of each temperature sensor so as to maintain a set target value of the temperature of the laminated glass window to be controlled among the first and fourth heating glass windows C1 to C4 according to a pre-programmed value. Control the heating element installed in the laminated glass window; Window system control method characterized in that it comprises a. In the control method of the window system according to any one of claims 1 to 16,
Inputting data for control such as seasonal solar irradiation angle or target temperature;
Adjusting the rotation angle of the sunshade member (2) in accordance with the input data; Window system control method characterized in that it comprises a. delete

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