KR101168493B1 - Double window system having asymmetry reflctor - Google Patents

Abstract

The double glazing system having an asymmetric reflective surface according to the present invention comprises a frame, an outdoor window and an indoor window which are installed to be opened and closed on both sides of the frame, and a slat formed with reflective surfaces having different reflectances, between the outdoor window and the indoor window. A double glazing system having an asymmetric reflecting surface including a sunshade installed in a window, comprising: an outdoor environmental measurement step for measuring outdoor temperature and insolation and an outdoor temperature and insolation measured in an outdoor environment measurement step with a reference value And a system driving step of driving at least one of an outdoor window, an indoor window, and a slat according to the result of comparison in the section setting step.
Double window system having an asymmetric reflective surface according to the present invention is divided into sections according to the outdoor temperature and the amount of solar radiation in the outside, and according to the divided section to control the outdoor window, indoor window or sunshade device more efficiently There is an effect that can be done.

Description

DOUBLE WINDOW SYSTEM HAVING ASYMMETRY REFLCTOR}

The technical field to which the present invention belongs is the field of double glazing systems. More specifically, the present invention relates to a double glazing system having an asymmetric reflecting surface provided with a slat 410 on which an asymmetric reflecting surface is formed.

The conventional double glazing system has a simple awning to play a basic role of controlling the solar inflow. In the prior art, when sunshade is applied to secure winter privacy, it may be difficult to utilize solar energy to reduce heating load by blocking solar energy inflow. In addition, there is room for improvement in the winter night like the thermal insulation material installed in the hollow inside the dual system, but it has not been actively utilized.

The double glazing system having an asymmetric reflective surface according to the present invention aims to solve the following problems.

First, the outdoor air conditioner, indoor window or sunshade device is driven in accordance with the outdoor temperature and the amount of solar radiation to efficiently heat and cool the room.

Second, when the amount of insolation introduced from the outdoors at the time of the cooling load occurs, it is to reflect in the slat to more efficiently cool the room.

Third, when the sunshade should be applied at the time of heating load to ensure privacy, the sunshade device solves a problem that may inhibit the influx of solar radiation, thereby inducing heating load reduction.

Fourth, when the outdoor temperature is low, it is intended to prevent the radiant heat of the indoors from flowing out to the outside more efficiently.

Fifth, it is intended to maintain the indoor temperature using the outdoor air.

The problem of the present invention is not limited to those mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

Double window system having an asymmetric reflective surface according to the present invention is composed of a frame, an outdoor window and an indoor window which are installed to be opened and closed on both sides of the frame, and a slat formed with reflective surfaces having different reflectances on one side and the other side. A double glazing system having an asymmetric reflective surface including a sunshade installed between an outdoor window and an indoor window.

Double window system having an asymmetric reflective surface according to the present invention includes an outdoor environmental measurement step (S1) for measuring the outdoor temperature (To) and solar radiation (I).

The double window system having an asymmetric reflective surface according to the present invention includes a section setting step (S2) for setting a section by comparing the outdoor temperature (To) and the solar radiation amount (I) measured in the outdoor environment measurement step with a reference value. .

The double window system having an asymmetric reflective surface according to the present invention includes a system driving step (S3) for driving at least one of an outdoor window, an indoor window, or a slat according to the result compared in the section setting step (S2).

In the double window system having the asymmetric reflective surface according to the present invention, the section set in the section setting step S2 includes a first section having a temperature greater than the first reference value T1 of the outdoor temperature To; , A second section in which the outdoor temperature To is less than or equal to the outdoor temperature first reference value T1 and greater than the outdoor temperature second reference value T2, and the outdoor temperature To is the outdoor temperature second reference value T2. The third section which is smaller than or equal to and larger than the outdoor temperature third reference value T3 and the fourth section smaller than the outdoor temperature third reference value T3 are preferable.

In the double window system having an asymmetric reflective surface according to the present invention, the section set in the section setting step (S2) is a section in which the outdoor solar radiation amount I is greater than the solar radiation reference value Is and the outdoor solar radiation amount I It is preferable that it consists of section b which is smaller than or equal to this solar radiation reference value Is.

In the double window system having an asymmetric reflective surface according to the present invention, when the section set in the section setting step (S2) is in the first section and the section a, the system driving step (S3) opens the outdoor window, It is preferable that the window is closed and the slats are driven to rotate the face of the slats with high reflectivity among the reflective surfaces of the slats toward the outdoor direction to open the sunshade, thereby preventing the outdoor solar S from entering the room. Do.

In the double window system having an asymmetric reflective surface according to the present invention, when the section set in the section setting step (S2) is in the first section and section b, the system driving step (S3) opens the outdoor window, By closing the window and rotating the slats, it is desirable to open the sunshade so that the surface of the slats with high reflectivity among the reflective surfaces of the slats faces the interior direction, so that the radiant heat R of the room can be discharged to the outside. .

In the double window system having an asymmetric reflective surface according to the present invention, when the section set in the section setting step (S2) is in the second section and section a, the system driving step (S3) opens the outdoor window and the indoor window and It is preferable that the sunshade is opened by rotating the slats so that the surface of the slats having a large reflectance in the reflection surface of the slats faces the outdoor direction, thereby preventing the outdoor radiation R from entering the room.

In the double window system having an asymmetric reflective surface according to the present invention, when the section set in the section setting step (S2) is in the second section and section b, the system driving step (S3) opens the outdoor window and the outdoor window It is preferable to rotate the slats so that the shading device is opened so that the surface of the slats having the large reflectance in the reflection surface of the slats faces the outdoor direction, so that the radiant heat R of the room can be discharged to the outside.

In the double window system having an asymmetric reflective surface according to the present invention, when the section set in the section setting step (S2) is in the third section and section a, the system driving step (S3) opens the outdoor window and the indoor window and Rotate the slat to open the sunshade so that the surface of the slat with the smallest reflectivity of the slat reflects the outdoor direction, and raise the temperature of the slat by insolation to bring the outdoor air (F) through the slat into the room. It is desirable to allow inflow.

In the double window system having an asymmetric reflective surface according to the present invention, when the section set in the section setting step (S2) is in the third section and section a, the system driving step (S3) opens the outdoor window and the indoor window and It is preferable to fold the slats so that outdoor solar radiation S and outdoor air F can be introduced into the interior.

In the double window system having an asymmetric reflective surface according to the present invention, when the section set in the section setting step (S2) is in the third section and section b, the system driving step (S3) closes the outdoor window and the indoor window In addition, it is preferable to rotate the surface of the slat having a small reflectance in the reflection surface of the slat toward the outdoor direction to open the shading device to block the radiant heat R of the room from flowing out to the outside.

In the double window system having an asymmetric reflective surface according to the present invention, when the section set in the section setting step (S2) is in the fourth section and section a, the system driving step (S3) closes the outdoor window and the indoor window and It is preferable to fold the slats to each other so that the outdoor solar radiation S can be introduced into the room.

In the double window system having the asymmetric reflective surface according to the present invention, when the section set in the section setting step (S2) is in the fourth section and section a, the system driving step (S3) closes the outdoor window, It is preferable to open the window, open the shading device by rotating the face of the slat with the smallest reflectance among the reflective surfaces of the slat toward the outdoor direction, and heat the slat by insolation.

In the double window system having an asymmetric reflective surface according to the present invention, when the section set in the section setting step (S2) is in the fourth section and section b, the system driving step (S3) closes the outdoor window and the indoor window It is preferable to block the radiant heat (R) of the room that flows out to the outside by rotating the sunshade device by rotating the face of the slat having a large reflectance toward the interior direction among the reflection surfaces of the slat.

In the double window system having an asymmetric reflective surface according to the present invention, when the section set in the section setting step (S2) is in the fourth section and section b, the system driving step (S3) closes the outdoor window and the indoor window , It is preferable to block the radiant heat (R) of the room to be released by closing the sunshade device by rotating the slat so that one surface of one slat and the other surface of the other slat abut each other.

In the double window system having an asymmetric reflective surface according to the present invention, it is preferable that the outdoor window opened in the system driving step S3 is opened at the top and bottom of the outdoor window in parallel with the frame.

In the double window system having the asymmetric reflective surface according to the present invention, the outdoor temperature first reference value T1 is 26 ° C, the outdoor temperature second reference value T2 is 15 ° C, and the third reference value T3 is It is preferable that it is 5 degreeC.

Double window system having an asymmetric reflective surface according to the present invention is divided into sections according to the outdoor temperature and the amount of solar radiation in the outside, and according to the divided section to control the outdoor window, indoor window or sunshade device more efficiently There is an effect that can be, in particular, when the amount of solar radiation flowing from the outdoor is large, there is an effect to block the solar radiation flowing from the outdoor using a different slat reflecting surface. In addition, when the outdoor temperature is low, there is an effect to control the indoor window, the outdoor window and the shading device so that the radiant heat of the room is not leaked to the outside to make the heating of the room more efficient.

The effects of the present invention are not limited to those mentioned above, and other effects that are not mentioned will be clearly understood by those skilled in the art from the following description.

1 is a flow chart of a double glazing system having an asymmetric reflective surface according to an embodiment of the present invention.
FIG. 2 is a flow chart of a double window system having an asymmetric reflective surface showing the section setting step and the system driving step shown in FIG. 1.
3 is a state diagram of Mode 1 of a double glazing system having an asymmetric reflective surface according to an embodiment of the present invention.
4 is a state diagram of Mode 2 of a double glazing system having an asymmetric reflective surface according to an embodiment of the present invention.
5 is a state diagram of Mode 3 of a double glazing system having an asymmetric reflective surface according to an embodiment of the present invention.
6 is a state diagram of Mode 4 of a double glazing system having an asymmetric reflective surface according to an embodiment of the present invention.
7 is a state diagram of Mode 5 of a double glazing system having an asymmetric reflective surface according to an embodiment of the present invention.
8 is a state diagram of another mode 5 according to an embodiment of the present invention.
9 is a state diagram of Mode 6 of a double glazing system having an asymmetric reflective surface according to an embodiment of the present invention.
10 is a state diagram of Mode 7 of a double glazing system having an asymmetric reflective surface according to an embodiment of the present invention.
FIG. 11 is a state diagram of Mode 8 of a double glazing system having an asymmetric reflective surface according to an embodiment of the present invention. FIG.
12 is a state diagram of Mode 9 of a double glazing system having an asymmetric reflective surface according to an embodiment of the present invention.
13 is a state diagram of Mode 10 of a double glazing system having an asymmetric reflective surface according to an embodiment of the present invention.

Hereinafter, a double glazing system having an asymmetric reflective surface according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a flow chart of a double glazing system having an asymmetric reflective surface according to an embodiment of the present invention, Figure 2 is a double glazing having an asymmetric reflective surface showing the section setting step and the system driving step shown in FIG. This is a flowchart of the system.

The double window system having an asymmetric reflective surface according to the present invention includes a frame 100, an outdoor window 200 and an indoor window 300 which are installed to be opened and closed on both sides of the frame 100, and the indoor window ( In the frame 100 between the 200 and the outdoor window 300, the shading device 400 made of a slat 410 is formed with a reflective surface having a different reflectance.

Here, the indoor window 200 and the outdoor window 300 may be combined with the frame 100 in a manner of being rotated and opened or slid and opened on the frame 100. In addition, it may be coupled to the frame 100 in a manner that protrudes from the frame 100 to open and close.

At this time, one side of the frame 100 or the outdoor window 300 is coupled to a temperature sensor and an insolation measurement sensor for measuring the outdoor temperature (To) and the external solar radiation (I).

In the present invention, the asymmetric reflective surface means that the surface reflectances of one surface and the other surface of the slat 410 are different from each other. When the reflectance is large, the light may absorb more light than the surface having the small reflectance.

As shown in FIG. 1, the double window system having the asymmetric reflective surface has an outdoor environment measuring step S1, a section setting step S2 for setting a section according to the measured outdoor environment, and an indoor window according to the section. 200), a system driving step (S3) for driving the outdoor window 300 and the sunshade device 400.

The outdoor environmental measurement step (S1) of measuring the outdoor temperature (To) and the solar radiation amount (I) according to the present invention is a step of measuring the outdoor temperature and the solar radiation amount of the outdoor, in the case of the present invention, the temperature sensor and the solar radiation measurement described above The sensor may measure the outdoor temperature (To) and the solar radiation amount (I), or install a separate temperature sensor and the solar radiation measurement sensor, and use the temperature value and the solar radiation value measured by the sensor.

When the outdoor temperature To and the solar radiation amount I are measured, in the section setting step S2, the section is set by comparing the outdoor temperature To and the solar radiation amount I with a reference value.

The reference value for setting such a section may be set in various ways, which will be described in more detail below.

In addition, the solar radiation reference value Is was set to 0 cal / m 2 / min so as to determine the presence or absence of solar radiation. The solar radiation reference value Is can be variously modified according to the environment in which the double glazing system having an asymmetric reflective surface is installed, and can be changed variably according to the choice of the occupants in the room.

The outdoor environment may be set for each section according to the reference value, and at least one of the outdoor window 200, the indoor window 300, or the awning device 400 may be driven in the system driving step S3 according to each section. have.

As shown in FIG. 2, the double glazing system having the asymmetric reflective surface according to the present invention has a temperature of which the outdoor temperature To is greater than the first outdoor reference temperature T1 based on the outdoor temperature To. The first section and the second section in which the outdoor temperature To is less than or equal to the outdoor temperature first reference value T1 and larger than the second outdoor reference temperature value T2, and the outdoor temperature To is the outdoor temperature second temperature The third section is smaller than or equal to the reference value T2 and larger than the third reference value T3, and the fourth section is smaller than the third reference value T3. Can be distinguished.

Sections according to the outdoor temperature (To) may be divided into less than four or more according to the embodiment, but in the present embodiment, it is classified into a total of four sections according to the outdoor temperature (To).

The outdoor temperature first reference value T1, the outdoor temperature second reference value T2, and the outdoor temperature third reference value T3, which are reference values of the section setting, may be set to various values. The reference value T1 was 26 ° C, the outdoor temperature second reference value T2 was 15 ° C, and the third reference value T3 was set to 5 ° C.

In addition, the section set in the section setting step (S2) according to the present invention may be set to a section a larger than the solar radiation amount I is greater than the above-mentioned solar radiation reference value Is and a b section smaller than or equal to the solar radiation reference value Is. In this case, the solar radiation reference value Is may be set to various values, as described above.

In the double window system having the asymmetric reflective surface according to the present invention, when the section set in the section setting step (S2) is in the first section and the section a, that is, the outdoor temperature (To) is greater than 26 ° C., the outdoor When the insolation amount I of is greater than 0 cal / m 2 / min, the insolation reference value Is, the system driving step S3 is shown in FIG. Likewise, the outdoor window 200 is opened, the indoor window 300 is closed, and the slat 410 is rotated so that the surface of the slat 410 having a large reflectance among the reflective surfaces of the slat 410 faces the outdoor direction. Open the sunshade.

At this time, the solar radiation introduced from the outside is in contact with the reflective surface having a large reflectance of the slat 410 is reflected outside.

In addition, the outdoor window 200 is open to allow outdoor air to flow between the outdoor window 200 and the indoor window 300 so that the temperature between the outdoor window 200 and the indoor window 300 increases. To prevent it from rising. Therefore, by lowering the temperature of the indoor window 300 in contact with the interior it is possible to perform the cooling of the room more efficiently.

In the double window system having an asymmetric reflective surface according to the present invention, when the section set in the section setting step S2 is in the first section and the section b, that is, the outdoor temperature To is greater than 26 ° C. When the solar radiation dose I of is less than or equal to 0 cal / m 2 / min, the solar radiation reference value Is, the system driving step S3 is shown in FIG. 4 which is a state diagram of the mode 2 of the double glazing system with an asymmetric reflective surface. As described above, the outdoor window 200 is opened, the indoor window 300 is closed, and the slat 410 is rotated so that the surface of the slat 410 having a large reflectance among the reflective surfaces of the slat 410 is in the indoor direction. Open the sunshade so as to face the, so that the radiant heat (R) in the room can be discharged to the outside.

In this case, since the amount of solar radiation introduced into the room from the outside is less than or equal to the solar radiation reference value Is, it does not have a great influence on the cooling of the room, and it is more preferable to discharge the radiant heat R generated in the room to the outside.

Therefore, it is preferable to rotate the surface of the slat 410 having a large reflectance among the reflection surfaces of the slat 410 to face the interior direction so as to open the sunshade device so that radiant heat R in the room can be discharged to the outside. At this time, outdoor solar radiation may flow into the space between the slat 410 and the slat 410, but as described above, the external solar radiation does not have a large influence on the efficiency of cooling the room because the amount of solar radiation is small.

In the double window system having the asymmetric reflective surface according to the present invention, when the section set in the section setting step S2 is in the second section and the section a, that is, the outdoor temperature To is the first outdoor reference temperature value. Is less than or equal to 26 ° C., greater than 15 ° C., the second outdoor temperature, and the solar radiation amount I is greater than the solar radiation reference value Is, the system driving step S3 is a double with an asymmetric reflective surface. As shown in FIG. 5, which is a state diagram of the mode 3 of the window system, the outdoor window 200 and the indoor window 300 are opened, and the slat 410 is driven to have a large reflectivity among the reflective surfaces of the slat 410. It is preferable to open the sunshade by rotating the surface of the 410 to face the outdoor direction, to block the outdoor solar S from entering the room.

When the outdoor temperature is between 15 ° C. and 26 ° C., it is more efficient to lower the indoor temperature by introducing outdoor air into the room than to cool the room.

Accordingly, when the outdoor temperature is between 15 ° C. and 26 ° C., as shown in FIG. 5, the outdoor window 200 and the indoor window 300 are opened to allow the outdoor air to flow into the room.

At this time, since the solar radiation amount I is larger than the solar radiation reference value Is, it is preferable to reflect it. Therefore, by rotating the slat 410 to open the sunshade device so that the surface of the slat 410 having a high reflectance among the reflection surface of the slat 410 toward the outdoor direction, the solar radiation (S) of the outdoor flow into the room Block it.

In the double window system having an asymmetric reflective surface according to the present invention, when the section set in the section setting step S2 is in the second section and the b section, that is, the outdoor temperature To is the first reference value of the outdoor temperature. Phosphorus is less than or equal to 26 ° C, greater than 15 ° C, which is the second outdoor temperature, and the outdoor solar radiation amount I is less than or equal to the solar radiation reference value Is, the system driving step S3 is performed in the outdoor window 200. And the indoor window 300 are opened, the slat 410 is rotated, and the sunshade device is opened so that the surface of the slat 410 having a high reflectance among the reflective surfaces of the slat 410 faces the room direction, and radiant heat in the room. It is desirable to allow (R) to flow out outdoors.

In this case, it is preferable to perform cooling through natural ventilation by introducing outdoor air into the room. Therefore, it is preferable to open the outdoor window 200 and the indoor window 300 as shown in FIG. 6, which is a state diagram of the mode 4 of the double window system having the asymmetric reflective surface, by rotating the slat 410, the slat. It is more preferable that the shading device is opened so that the surface of the slat 410 having a large reflectance among the reflective surfaces of the 410 faces the interior direction, so that the radiant heat R of the interior can be discharged to the outside.

In the double window system having the asymmetric reflective surface according to the present invention, when the section set in the section setting step S2 is in the third section and the a section, that is, the outdoor temperature To is the second reference value of the outdoor temperature. If the temperature is less than or equal to 15 ° C., greater than 5 ° C., which is the third outdoor temperature, and the solar radiation amount I is greater than the solar radiation reference value Is, the system driving step S3 may include the outdoor window 200 and the indoor window ( 300 is opened, and the slat 410 is rotated to open the sunshade device so that the surface of the slat 410 having the smallest reflectance among the reflection surfaces of the slat 410 faces the outdoor direction, so that the external solar S is slat. It is preferable to increase the temperature of 410 and to allow the outdoor air F heated by the slat 410 whose temperature is increased to be introduced into the room.

In such a section, the outdoor temperature is low, it is necessary to maximize the solar inflow into the room. However, if you must inevitably shed the sunshade can maximize the reflected sun and absorb most of the sun from the sunshade can be sent to the interior.

Therefore, the surface of the slat 410 having a small reflectance is rotated toward the outdoor direction by rotating the slat 410, thereby minimizing solar radiation reflected to the sunshade rotated at a predetermined angle to ensure privacy. Outdoor air (F) heated in the slat 410 may be introduced into the room.

At this time, the indoor window 300 is open to the top, one end of the slat 410 is located in a lower position than the other end of the slat 410 as shown in Figure 7, which is a state diagram of a double glazing system having an asymmetric reflective surface. It is desirable to arrange the outdoor air F more smoothly.

In this state, the slat 410 may be partially heated by solar radiation introduced from the outside, and the air introduced from the outside may be introduced into the room by convection while being heated in contact with the partially heated slat 410. It may be.

In addition, as shown in FIG. 8, the external solar radiation may be directly introduced into the room by adjusting the angle of the slat 410.

Further, according to the embodiment, when the section set in the section setting step (S2) is in the third section and section a, the system driving step (S3) is shown in Figure 9 which is a state diagram of a double window system having an asymmetric reflective surface As illustrated, the outdoor window 200 and the indoor window 300 may be opened, and the slats 410 may be folded to allow the outdoor solar S and the outdoor air F to enter the indoors.

In this case, the solar radiation in the outdoor can be directly introduced into the indoor to increase the temperature of the indoor.

In the double window system having the asymmetric reflective surface according to the present invention, when the section set in the section setting step S2 is in the third section and the b section, that is, the outdoor temperature To is the second reference value of the outdoor temperature. When the temperature is less than or equal to 15 ° C., is greater than 5 ° C., the third outdoor reference temperature, and the solar radiation amount I is less than or equal to the solar radiation reference value Is, the system driving step S3 is performed by the outdoor window 200 and the indoor location. It is preferable to open the sunshade by closing the window 300 and rotating the surface of the slat 410 having a high reflectance among the reflective surfaces of the slat 410 toward the outdoor direction.

In this state, the radiant heat (R) of the room is blocked by the indoor window (300) and the shade device (400), as shown in FIG. 10, which is a state diagram of a double window system having an asymmetric reflective surface, so that the heat of the room is outdoors. To prevent leakage.

In the double window system having the asymmetric reflective surface according to the present invention, when the section set in the section setting step S2 is in the fourth section and the section a, that is, the outdoor temperature To is less than or equal to 5 ° C. When the solar radiation amount I is larger than the solar radiation reference value Is, the system driving step S3 closes the outdoor window 200 and the indoor window 300 as shown in FIG. 11, and the slats 410. It is preferable to be able to fold each other so that the solar radiation (S) of the outdoor can be introduced into the room.

When the outdoor temperature To is less than or equal to 5 ° C., since indoor heating is required, it is preferable to close the outdoor window 200 and the indoor window 300 in the system driving step S3. In addition, in this section, it is necessary to increase the indoor temperature by introducing the solar radiation as much as possible.

Therefore, it is preferable to fold the slats 410 to open the sunshade so that the solar radiation amount I of the outdoor can be more smoothly introduced into the room.

In the double window system having the asymmetric reflective surface according to the present invention, when the section set in the section setting step S2 is in the fourth section and the section a, as shown in FIG. 12, the system driving step S3. May close the outdoor window 200, open the indoor window 300, and rotate the surface of the slat 410 having a small reflectance among the reflective surfaces of the slat 410 to face the outdoor direction to open the sunshade. have.

In this case, the sunshade device 400 may be raised in temperature by the solar radiation introduced from the outside, the outdoor air (F) in contact with the sunshade device 400 may be raised. Therefore, the outdoor air F heated up by the slat 410 may be introduced into the room by convection.

In the double window system having the asymmetric reflective surface according to the present invention, when the section set in the section setting step (S2) is in the fourth section and the section b, that is, the outdoor temperature (To) is less than or equal to 5 ℃ When the external solar radiation amount I is less than or equal to the solar radiation reference value Is, as shown in FIG. 10, the system driving step S3 closes the outdoor window 200 and the indoor window 300, and the slats ( Of the reflective surface of the 410, the surface of the slat 410 having a small reflectance is rotated to face the outdoor direction to open the sunshade device to block the radiant heat (R) of the room that flows out to the outside, so that heat flows out from the room to the outside. Can be blocked.

In addition, according to an embodiment, by rotating the slat 410 so that one surface of the one slat and the other surface of the other slat 410 abut each other to close the sunshade device, the radiant heat (R) of the room that flows out to the outside As shown in FIG. 13, it may be blocked.

The outdoor window 200 of the double window system having an asymmetric reflective surface according to the present invention may be opened and closed in various directions as described above, but the outdoor window 200 may allow more air to flow from the outdoor to the indoor direction. It is more preferable that the upper and lower ends of the windows are windows of the 'parallel' type in which the frame 100 is opened in parallel with the frame 100.

The embodiments and the accompanying drawings described in the present specification are merely illustrative of some of the technical ideas included in the present invention. Accordingly, the embodiments disclosed herein are for the purpose of describing rather than limiting the technical spirit of the present invention, and it is apparent that the scope of the technical idea of the present invention is not limited by these embodiments. Modifications and specific embodiments that can be easily inferred by those skilled in the art within the scope of the technical idea included in the specification and drawings of the present invention should be construed as being included in the scope of the present invention.

S1: outdoor environment measurement step S2: section setting step
S3: System operation stage
100: frame 200: outdoor window
300: indoor window 400: sunshade
410: slat To: outdoor temperature
T1: first reference value T2: second reference value
T3: Third reference value I: Insolation
Is: Insolation standard value S: Insolation
R: radiant heat F: outdoor air

Claims (16)

delete delete delete And a sunshade comprising a frame, an outdoor window and an indoor window installed on both sides of the frame so as to be opened and closed, and a slat having reflective surfaces having different reflectances on one side and the other side, the shade device being installed between the outdoor window and the indoor window. A double glazing system with an asymmetric reflective surface,
An outdoor environment measuring step S1 of measuring the outdoor temperature To and the solar radiation amount I; A section setting step (S2) of setting a section by comparing outdoor temperature (To) and solar radiation (I) measured in the outdoor environment measurement step with a reference value; And a system driving step (S3) of driving at least one of an outdoor window, an indoor window, and a slat according to the result compared in the section setting step (S2),
The section set in the section setting step S2 includes a first section having an outdoor temperature To greater than an outdoor temperature first reference value T1, and an outdoor temperature To having an outdoor temperature first reference value T1. ) The second section smaller than or equal to and greater than the second outdoor reference temperature T2, and the outdoor temperature To is less than or equal to the second outdoor reference temperature T2 and greater than the third outdoor reference temperature T3. The third section and a fourth section in which the outdoor temperature To is smaller than the third reference value T3 of the outdoor temperature,
The section set in the section setting step S2 is composed of a section in which the outdoor solar radiation amount I is greater than the solar radiation reference value Is, and the b section in which the outdoor solar radiation amount I is smaller than or equal to the solar radiation reference value Is. ,
When the section set in the section setting step (S2) is in the first section and section a,
The system driving step (S3) opens the outdoor window, closes the indoor window, and drives the slat to rotate the surface of the slat having the high reflectivity among the reflective surfaces of the slat toward the outdoor direction to open the sunshade device outdoors. Dual windows system with an asymmetric reflective surface, characterized in that the solar (S) of the inlet to block the entry.
And a sunshade comprising a frame, an outdoor window and an indoor window installed on both sides of the frame so as to be opened and closed, and a slat having reflective surfaces having different reflectances on one side and the other side, the shade device being installed between the outdoor window and the indoor window. A double glazing system with an asymmetric reflective surface,
An outdoor environment measuring step S1 of measuring the outdoor temperature To and the solar radiation amount I; A section setting step (S2) of setting a section by comparing outdoor temperature (To) and solar radiation (I) measured in the outdoor environment measurement step with a reference value; And a system driving step (S3) of driving at least one of an outdoor window, an indoor window, and a slat according to the result compared in the section setting step (S2),
The section set in the section setting step S2 includes a first section having an outdoor temperature To greater than an outdoor temperature first reference value T1, and an outdoor temperature To having an outdoor temperature first reference value T1. ) The second section smaller than or equal to and greater than the second outdoor reference temperature T2, and the outdoor temperature To is less than or equal to the second outdoor reference temperature T2 and greater than the third outdoor reference temperature T3. The third section and a fourth section in which the outdoor temperature To is smaller than the third reference value T3 of the outdoor temperature,
The section set in the section setting step S2 is composed of a section in which the outdoor solar radiation amount I is greater than the solar radiation reference value Is, and the b section in which the outdoor solar radiation amount I is smaller than or equal to the solar radiation reference value Is. ,
When the section set in the section setting step (S2) is in the first section and b section,
The system driving step (S3) opens the outdoor window, closes the indoor window, and rotates the slat to open the sunshade so that the surface of the slat having the high reflectivity among the reflective surfaces of the slat faces the indoor direction, A double glazing system having an asymmetric reflective surface, characterized in that it enables outflow of radiant heat (R) to the outdoors.
And a sunshade comprising a frame, an outdoor window and an indoor window installed on both sides of the frame so as to be opened and closed, and a slat having reflective surfaces having different reflectances on one side and the other side, the shade device being installed between the outdoor window and the indoor window. A double glazing system with an asymmetric reflective surface,
An outdoor environment measuring step S1 of measuring the outdoor temperature To and the solar radiation amount I; A section setting step (S2) of setting a section by comparing outdoor temperature (To) and solar radiation (I) measured in the outdoor environment measurement step with a reference value; And a system driving step (S3) of driving at least one of an outdoor window, an indoor window, and a slat according to the result compared in the section setting step (S2),
The section set in the section setting step S2 includes a first section having an outdoor temperature To greater than an outdoor temperature first reference value T1, and an outdoor temperature To having an outdoor temperature first reference value T1. ) The second section smaller than or equal to and greater than the second outdoor reference temperature T2, and the outdoor temperature To is less than or equal to the second outdoor reference temperature T2 and greater than the third outdoor reference temperature T3. The third section and a fourth section in which the outdoor temperature To is smaller than the third reference value T3 of the outdoor temperature,
The section set in the section setting step S2 is composed of a section in which the outdoor solar radiation amount I is greater than the solar radiation reference value Is, and the b section in which the outdoor solar radiation amount I is smaller than or equal to the solar radiation reference value Is. ,
When the section set in the section setting step (S2) is in the second section and section a,
The system driving step (S3) is to open the outdoor window and the indoor window, and rotate the slat to open the sunshade device so that the surface of the slat with a large reflectivity of the reflecting surface of the slat toward the outdoor direction, the outdoor radiation (R) is Double glazing system having an asymmetric reflecting surface, characterized in that to block the entry into the room.
And a sunshade comprising a frame, an outdoor window and an indoor window installed on both sides of the frame so as to be opened and closed, and a slat having reflective surfaces having different reflectances on one side and the other side, the shade device being installed between the outdoor window and the indoor window. A double glazing system with an asymmetric reflective surface,
An outdoor environment measuring step S1 of measuring the outdoor temperature To and the solar radiation amount I; A section setting step (S2) of setting a section by comparing outdoor temperature (To) and solar radiation (I) measured in the outdoor environment measurement step with a reference value; And a system driving step (S3) of driving at least one of an outdoor window, an indoor window, and a slat according to the result compared in the section setting step (S2),
The section set in the section setting step S2 includes a first section having an outdoor temperature To greater than an outdoor temperature first reference value T1, and an outdoor temperature To having an outdoor temperature first reference value T1. ) The second section smaller than or equal to and greater than the second outdoor reference temperature T2, and the outdoor temperature To is less than or equal to the second outdoor reference temperature T2 and greater than the third outdoor reference temperature T3. The third section and a fourth section in which the outdoor temperature To is smaller than the third reference value T3 of the outdoor temperature,
The section set in the section setting step S2 is composed of a section in which the outdoor solar radiation amount I is greater than the solar radiation reference value Is, and the b section in which the outdoor solar radiation amount I is smaller than or equal to the solar radiation reference value Is. ,
When the section set in the section setting step (S2) is in the second section and b section,
The system driving step (S3) opens the outdoor window and the outdoor window, rotates the slats, and opens the sunshade so that the surface of the slat having the high reflectivity among the reflective surfaces of the slats faces the outdoor direction, radiant heat (R) of the room. A double glazing system with an asymmetric reflective surface, characterized in that the outflow to the outside.
And a sunshade comprising a frame, an outdoor window and an indoor window installed on both sides of the frame so as to be opened and closed, and a slat having reflective surfaces having different reflectances on one side and the other side, the shade device being installed between the outdoor window and the indoor window. A double glazing system with an asymmetric reflective surface,
An outdoor environment measuring step S1 of measuring the outdoor temperature To and the solar radiation amount I; A section setting step (S2) of setting a section by comparing outdoor temperature (To) and solar radiation (I) measured in the outdoor environment measurement step with a reference value; And a system driving step (S3) of driving at least one of an outdoor window, an indoor window, and a slat according to the result compared in the section setting step (S2),
The section set in the section setting step S2 includes a first section having an outdoor temperature To greater than an outdoor temperature first reference value T1, and an outdoor temperature To having an outdoor temperature first reference value T1. ) The second section smaller than or equal to and greater than the second outdoor reference temperature T2, and the outdoor temperature To is less than or equal to the second outdoor reference temperature T2 and greater than the third outdoor reference temperature T3. The third section and a fourth section in which the outdoor temperature To is smaller than the third reference value T3 of the outdoor temperature,
The section set in the section setting step S2 is composed of a section in which the outdoor solar radiation amount I is greater than the solar radiation reference value Is, and the b section in which the outdoor solar radiation amount I is smaller than or equal to the solar radiation reference value Is. ,,
If the section set in the section setting step (S2) is in the third section and section a,
The system driving step (S3) is to open the outdoor window and the indoor window, and rotate the slat to open the sunshade so that the surface of the slat with a small reflectivity of the reflecting surface of the slat toward the outdoor direction, the temperature of the slat by the solar radiation A double glazing system with an asymmetric reflective surface, characterized in that to allow the outdoor air (F) passing through the slat to be introduced into the room by raising.
The method of claim 8,
If the section set in the section setting step (S2) is in the third section and section a,
The system driving step (S3) is provided with an asymmetric reflective surface, characterized in that to open the outdoor window and the indoor window, and to fold the slats to allow the outdoor solar (S) and the outdoor air (F) to enter the indoor. One double glazing system.
And a sunshade comprising a frame, an outdoor window and an indoor window installed on both sides of the frame so as to be opened and closed, and a slat having reflective surfaces having different reflectances on one side and the other side, the shade device being installed between the outdoor window and the indoor window. A double glazing system with an asymmetric reflective surface,
An outdoor environment measuring step S1 of measuring the outdoor temperature To and the solar radiation amount I; A section setting step (S2) of setting a section by comparing outdoor temperature (To) and solar radiation (I) measured in the outdoor environment measurement step with a reference value; And a system driving step (S3) of driving at least one of an outdoor window, an indoor window, and a slat according to the result compared in the section setting step (S2),
The section set in the section setting step S2 includes a first section having an outdoor temperature To greater than an outdoor temperature first reference value T1, and an outdoor temperature To having an outdoor temperature first reference value T1. ) The second section smaller than or equal to and greater than the second outdoor reference temperature T2, and the outdoor temperature To is less than or equal to the second outdoor reference temperature T2 and greater than the third outdoor reference temperature T3. The third section and a fourth section in which the outdoor temperature To is smaller than the third reference value T3 of the outdoor temperature,
The section set in the section setting step S2 is composed of a section in which the outdoor solar radiation amount I is greater than the solar radiation reference value Is, and the b section in which the outdoor solar radiation amount I is smaller than or equal to the solar radiation reference value Is. ,
When the section set in the section setting step S2 is in the third section and the b section,
The system driving step (S3) closes the outdoor window and the indoor window, rotates the surface of the slat with the small reflectivity among the reflective surfaces of the slat toward the outdoor direction to open the sunshade device, and radiant heat (R) of the room to the outside. A double glazing system having an asymmetric reflective surface, characterized by blocking leakage.
The method of claim 10,
When the section set in the section setting step (S2) is in the fourth section and section a,
The system driving step (S3) is a double glazing system having an asymmetric reflective surface, characterized in that to close the outdoor window and the indoor window, and to fold the slats mutually to allow the outdoor solar (S) to enter the room.
And a sunshade comprising a frame, an outdoor window and an indoor window installed on both sides of the frame so as to be opened and closed, and a slat having reflective surfaces having different reflectances on one side and the other side, the shade device being installed between the outdoor window and the indoor window. A double glazing system with an asymmetric reflective surface,
An outdoor environment measuring step S1 of measuring the outdoor temperature To and the solar radiation amount I; A section setting step (S2) of setting a section by comparing outdoor temperature (To) and solar radiation (I) measured in the outdoor environment measurement step with a reference value; And a system driving step (S3) of driving at least one of an outdoor window, an indoor window, and a slat according to the result compared in the section setting step (S2),
The section set in the section setting step S2 includes a first section having an outdoor temperature To greater than an outdoor temperature first reference value T1, and an outdoor temperature To having an outdoor temperature first reference value T1. ) The second section smaller than or equal to and greater than the second outdoor reference temperature T2, and the outdoor temperature To is less than or equal to the second outdoor reference temperature T2 and greater than the third outdoor reference temperature T3. The third section and a fourth section in which the outdoor temperature To is smaller than the third reference value T3 of the outdoor temperature,
The section set in the section setting step S2 is composed of a section in which the outdoor solar radiation amount I is greater than the solar radiation reference value Is, and the b section in which the outdoor solar radiation amount I is smaller than or equal to the solar radiation reference value Is. ,
When the section set in the section setting step (S2) is in the fourth section and section a,
The system driving step (S3) is to close the outdoor window, open the indoor window, open the sunshade by rotating the surface of the slat with a small reflectivity of the slat reflection surface toward the outdoor direction, the slat by the solar radiation A double glazing system having an asymmetric reflective surface, characterized in that for heating.
And a sunshade comprising a frame, an outdoor window and an indoor window installed on both sides of the frame so as to be opened and closed, and a slat having reflective surfaces having different reflectances on one side and the other side, the shade device being installed between the outdoor window and the indoor window. A double glazing system with an asymmetric reflective surface,
An outdoor environment measuring step S1 of measuring the outdoor temperature To and the solar radiation amount I; A section setting step (S2) of setting a section by comparing outdoor temperature (To) and solar radiation (I) measured in the outdoor environment measurement step with a reference value; And a system driving step (S3) of driving at least one of an outdoor window, an indoor window, and a slat according to the result compared in the section setting step (S2),
The section set in the section setting step S2 includes a first section having an outdoor temperature To greater than an outdoor temperature first reference value T1, and an outdoor temperature To having an outdoor temperature first reference value T1. ) The second section smaller than or equal to and greater than the second outdoor reference temperature T2, and the outdoor temperature To is less than or equal to the second outdoor reference temperature T2 and greater than the third outdoor reference temperature T3. The third section and a fourth section in which the outdoor temperature To is smaller than the third reference value T3 of the outdoor temperature,
The section set in the section setting step S2 is composed of a section in which the outdoor solar radiation amount I is greater than the solar radiation reference value Is, and the b section in which the outdoor solar radiation amount I is smaller than or equal to the solar radiation reference value Is. ,
When the section set in the section setting step (S2) is in the fourth section and section b,
The system driving step (S3) closes the outdoor window and the indoor window, rotates the surface of the slat having the large reflectance toward the indoor direction among the reflective surfaces of the slat to open the sunshade device, and radiates heat indoors (R) that flows out to the outside. Double glazing system having an asymmetric reflective surface, characterized in that for blocking).
The method of claim 13,
When the section set in the section setting step (S2) is in the fourth section and section b,
The system driving step (S3) closes the outdoor window and the indoor window, and rotates the slats so that one surface of the one slab and the other surface of the other slats abut each other to close the sunshade device to block the radiant heat (R) of the indoors Double glazing system having an asymmetric reflecting surface, characterized in that.
10. The method according to any one of claims 4 to 9,
The outdoor window opened in the system driving step (S3)
A double glazing system having an asymmetric reflective surface, characterized in that the top and bottom of the outdoor window is opened in parallel with the frame.
The method according to any one of claims 4 to 14,
Double temperature window with an asymmetric reflective surface, characterized in that the outdoor temperature first reference value (T1) is 26 ℃, the outdoor temperature second reference value (T2) is 15 ℃, the third reference value (T3) is 5 ℃. system.

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