KR20130114378A - The variable skylight system for collection and control of solar energy - Google Patents

Abstract

PURPOSE: A variable skylight system functioning as a sunlight collector and a sunlight intake controller is provided to improve sunlight collecting performance by rotating a sunlight collecting part based on the position of the sun and to seasonally control the intake of sunlight to an indoor space. CONSTITUTION: A variable skylight system functioning as a sunlight collector and a sunlight intake controller comprises a sunlight collecting part (100), an awning part (200), a skylight part (300), and a screen part (400). The sunlight collecting part includes a solar panel (102). The awning part includes an awning panel (201) to control the intake of sunlight to an indoor space. The skylight part is formed at the bottom of the sunlight collecting part and the awning part. The skylight part includes a transparent window (301) to accept sunlight into the indoor space. The screen part includes a screen panel (402) to block or reflect sunlight coming through the skylight part into a building.

Description

Variable Skylight System For Collection And Control Of Solar Energy

The present invention relates to a variable skylight system that functions to collect sunlight and control indoor inflow of sunlight. More specifically, the light collecting unit 100 including a solar panel and a selective blocking of solar light introduced into the room are provided. Shading part 200 to be formed in order to form the lower portion of the light collecting unit 100 and the shading unit 200 to form a sun so that sunlight can enter the room, and the skylight ( By including the screen unit 400 formed to reflect or block the sunlight flowing through the 300 into the interior of the building, one or more is installed on the roof or roof of the building, the light collecting unit 100 in the position of the sun Rotational movement along the reinforcement of the condensing performance and at the same time to control the sunlight flowing into the room through the skylight (300) through the shade portion 200 or the screen portion 400, the indirect light scattered light in the room When supplied to provide a variable skylight system of the sunlight condensing and sunlight indoor inflow control for reducing the air and light energy.

In the face of the depletion of fossil fuels, the efficient use of energy and active use of alternative energy are urgently urgent problems, and especially to the solar energy, the infinitely clean energy that is most likely to be used as an alternative to oil. Much research has been done on this.

 In buildings, the most common form of solar energy is to install solar panels on roofs or rooftops to produce solar power or hot water, but the installation of solar panels and the formation of openings for mining conflict with each other. There was a problem that the indoor inflow of sunlight was difficult, and the introduction of dye-sensitized BIPV type skylight to compensate for this also had the disadvantage of lowering the light collection efficiency and the selective control of sunlight.

Accordingly, the present invention is to solve the above problems and to effectively control the solar power generation and solar inflow through the upper portion of the building at the same time effectively.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems occurring in the prior art,

An object of the present invention is to install one or more on the roof or roof of the building to maximize the condensing performance of the solar panel by maximally concentrating the solar cell panel by moving the light up and down and left and right according to the altitude and direction of the sun. By forming the shade portion, it is possible to adjust the solar light flowing into the room through the skylight formed in the light collecting portion and the lower portion of the shade for each season, by forming a screen portion in contact with the skylight through the skylight to the room indoors The present invention provides a variable skylight system for controlling the concentration of sunlight and the inflow of sunlight, which can block or reflect incoming sunlight.

Another object of the present invention is the light collecting unit is a solar cell panel for photovoltaic power generation, a light collecting unit frame forming an overall frame and the frame of the solar panel, and the solar cell panel is formed as a central axis of the rotational movement A solar cell panel drive shaft, a light collecting unit gear unit for driving left and right rotational movement of the solar panel, a hydraulic press formed to drive the vertical rotation of the light collecting unit, and the light collecting unit is vertically driven by driving the hydraulic press. Condensing unit drive shaft formed as a central axis for rotational movement, Condensing unit drive shaft gear formed so as to be engaged with the shade portion at the end or the middle of the collecting unit drive shaft, the drive of the light collecting unit gear portion and the hydraulic press Condensing and sunlight chamber of sunlight, characterized in that it comprises a control unit for forming a control It provides a variable skylight system of the inflow control.

Another object of the present invention is a solar cell panel formed for photovoltaic power generation is a dye-sensitized solar cell (DSSC, Dye Sensitized Solar Cell) used to attach to crystalline silicon or thin film-type inorganic solar cells, glass, or organic solar At least one of the cells (OPV, Organic PV) can be used, and the solar panel formed as a heat collecting plate for the collection of solar energy is a flat plate, vacuum tube, Parabolic Trough Concentrator (PTC) type, Compound Parabolic Concentrator (CPC) Provided is a variable skylight system that functions to collect solar light and control the inflow of sunlight, characterized in that at least one of the types can be used.

Still another object of the present invention is to form the rack gear and one or more pinion gears inside the light collecting unit gear portion when the rack gear is horizontally moved by the driving of the electric motor as the pinion gear engaged with the teeth is rotated. At least one solar panel connected to the pinion gear rotates at the same time, and accordingly, the solar panel can change direction by following the azimuth angle of the sun. It provides a variable skylight system.

Still another object of the present invention is to form the upper part of the skylight through the skylight through the skylight to control the sunlight flowing into the interior of the building, by the size and angle of the sunshade, the solar light inflow in summer It provides a variable skylight system that functions to control solar inflow and solar indoor inflow, characterized in that the function of blocking the sun and inflowing sunlight as much as possible in winter but introducing scattered light at all times.

Still another object of the present invention is the sunshade to the sunshade to block the sun, sunshade drive shaft to form a central axis for promoting the rotation of the sunshade, and the sunshade so as to engage the drive shaft gear Provided is a variable skylight system having a sunshade drive shaft gear formed on the drive shaft and the indoor inflow control function of the solar light characterized in that it comprises a drive shaft gear.

Another object of the present invention by the sunshade is interlocked with the up and down rotational movement of the light-collecting unit, in the summer when the light-collecting unit is lowered to the horizontal, the sunshade also rotates to lower as the sunshade to block the inflow of sunlight indoors, In the winter when the condensing bag rises close to the vertical, the solar condensing and the indoor inflow control of solar light can be reduced by cooling the heating and cooling load by allowing the indoor inflow of sunlight to the maximum by allowing the sunshade to rise as well. It provides a variable skylight system that functions.

Another object of the present invention is that the sunshade plate is formed so that the lowest angle between the horizontal and the winter in winter, the solar altitude (29 degrees of Seoul standard) of the winter solstice does not block the sunlight flowing into the lower panel. It provides a variable skylight system that performs the function of condensing the sunlight and the indoor inflow control of sunlight.

Still another object of the present invention is to form a louver shape or to form one or more through holes in the awning plate to reduce the damage or deformation of the awning plate by the wind and to improve safety The present invention provides a variable skylight system that functions to collect solar light and control indoor flow of sunlight.

Still another object of the present invention is to open and close freely of the wind through the opening formed between the light collecting portion and the shade portion and the skylight portion formed in the lower portion, thereby reducing the temperature rise of the solar panel in the summer to reduce efficiency. Provided is a variable skylight system that can control the light condensing and indoor inflow control of sunlight, characterized in that it can be alleviated.

Still another object of the present invention is a transparent window, such as glass and plastic, the skylight frame frame that is the border of the transparent window, a fixing plate for forming and fixing the skylight on the roof or roof of the building, and the fixing plate A variable skylight having a solar condenser and a solar inflow control function, characterized in that it comprises a support portion formed to support the slab of the building at the lower portion of the building, and the support for forming the light collecting portion and the shade. Provide a system.

Still another object of the present invention is a variable type for controlling the light condensing and indoor inflow of sunlight, characterized in that the transparent window can use a material or film that can block at least one of ultraviolet, infrared, or visible light. Provide skylight system.

Still another object of the present invention is to screen at least one of the function of blocking the sunlight flowing through the skylight or reflecting into the room, the screen unit can be formed into a variable, such as folding, removable, etc. The present invention provides a variable skylight system that functions to collect solar light and control indoor flow of sunlight.

It is still another object of the present invention to form a screen unit for reflecting sunlight, and by using a material or film that can block at least one of ultraviolet rays, infrared rays, or visible light in the screen unit, it is possible to specify a specific spectrum of sunlight. The present invention provides a variable skylight system that functions to collect sunlight and control the inflow of sunlight.

Still another object of the present invention is to form a curved surface of the screen to reflect light scattering, or by processing the surface of the screen portion in the form of irregularities to reflect the scattering light, so that the light is evenly transmitted to each part of the room and the glare phenomenon Provided is a variable skylight system that can control the light condensing and indoor inflow control of sunlight, characterized in that it can be alleviated.

Another object of the present invention, when forming the screen portion to block the sunlight, the screen portion functions as a heat storage body by using a material having high heat storage performance or a color with high light absorption performance in the screen portion It provides a variable skylight system that can improve the heating performance of the solar condensing and the indoor inflow control of solar light.

Still another object of the present invention is to install the screen unit to be included in a part of the light steel ceiling or ceiling tex of the building, or a solar condensing and solar indoor inlet control function, characterized in that can be utilized as a separate design element It provides a variable skylight system.

The present invention includes the following embodiments in order to achieve the above object.

According to an embodiment of the present invention, by installing one or more on the roof or roof of the building, the light collecting unit rotates up and down and left and right according to the altitude and direction of the sun to maximize the condensing performance of the solar panel at the same time, By forming the sunshade interlocking with the light collecting unit, through the skylight formed in the lower portion of the light collecting unit and the sunshade can be adjusted seasonally, through the skylight by forming a screen portion in contact with the skylight It is characterized by being able to block or reflect sunlight entering the room in winter.

According to another embodiment of the present invention, the light collecting unit has a solar cell panel for photovoltaic power generation, a light collecting unit frame forming the frame and the overall frame of the solar panel, and the central axis of the solar cell panel rotates A solar cell panel drive shaft formed as a shaft; a condensing unit gear unit for driving left and right rotational movements of the solar panel; a hydraulic press formed to drive up and down rotation of the condensing unit; and condensing by driving the hydraulic press. A light collecting unit driving shaft formed as a central axis to allow a large unit to rotate vertically, a light collecting unit driving shaft gear formed to be engaged with the sunshade at an end or an intermediate portion of the light collecting unit driving shaft, and the light collecting unit gear unit and the hydraulic press. Characterized in that it comprises a control unit for controlling the driving of.

According to another embodiment of the present invention, the solar cell panel formed for photovoltaic power generation is a dye-sensitized solar cell (DSSC, Dye Sensitized Solar Cell) used to attach to crystalline silicon or thin-film inorganic solar cells, glass, etc., Alternatively, at least one of an organic solar cell (OPV, Organic PV) may be used, and the solar cell panel formed as a heat collecting plate for collecting solar energy may be a flat plate, a vacuum tube, a parabolic trough concentrator (PTC) type, or a CPC (Compound). Parabolic Concentrator) is characterized in that at least one can be used.

According to another embodiment of the present invention, the light collecting unit gear portion is formed by the rack gear and at least one pinion gear inside the rack gear is moved horizontally by the drive of the electric motor by the teeth of the pinion gear is engaged with the rotational movement As the at least one solar panel connected to the pinion gear is rotated at the same time, the solar panel is characterized in that the direction can be changed by chasing the azimuth of the sun.

According to another embodiment of the present invention, the sunshade is formed in the upper portion of the skylight to control the sunlight flowing into the room from the top of the building through the skylight, by the size and angle of the sunshade, the sun in summer Blocks the influx of light, and in winter, the function of introducing sunlight as much as possible, but scattered light is characterized in that it can be introduced at all times.

According to a further embodiment of the present invention, the sunshade is provided with a sunshade plate for blocking sunlight, a sunshade drive shaft which is formed as a central axis for promoting the rotation of the sunshade plate, and the focusing unit drive shaft gear to be engaged. And a shading drive shaft gear formed on the shading drive shaft.

According to another embodiment of the present invention, the sunshade by interlocking with the vertical rotation of the light-collecting unit, in the summer when the light-collecting unit descends to be horizontal, the sunshade also rotates so as to lower the sunshade as the indoor inflow of sunlight In winter, when the light collecting unit is raised to be close to the vertical, it is possible to reduce the heating and cooling load by allowing the indoor inflow of sunlight to the maximum by rotating the sunshade as well.

According to another embodiment of the present invention, the sunshade plate is formed so that the lowest angle to the horizontal in winter to be above the solar altitude (29 degrees of Seoul reference) of the winter solstice to block the sunlight entering the lower part of the sunshade in winter It is characterized by not.

According to another embodiment of the present invention, by forming the awning plate in the shape of a louver or by forming one or more through-holes in the awning plate can reduce the damage or deformation of the awning plate by the wind and can promote safety It is characterized by.

According to another embodiment of the present invention, the free passage of the wind is possible through the opening formed between the light collecting portion and the shade portion and the skylight portion formed on the lower portion, thereby reducing the temperature rise of the solar panel in the summer It is characterized by being capable of mitigating a decrease in efficiency.

According to another embodiment of the present invention, the skylight portion is a transparent window, such as glass, plastic, a skylight frame frame that is the border of the transparent window, and a fixing plate for forming and fixing the skylight portion on the roof or roof of the building; It is characterized in that it comprises a skylight case case formed to be in contact with the slab of the building in the lower portion of the fixing plate, and a support formed to support the light collecting unit and the shade.

According to another embodiment of the present invention, the transparent window may be a material or film that can block at least one of ultraviolet, infrared, or visible light.

According to another embodiment of the present invention, the screen unit blocks at least one of the sunlight flowing through the skylight or reflects into the room, but at least one of the two, can be formed in a variable form, such as folding, removable It features.

According to another embodiment of the present invention, in the case of forming the screen unit to reflect the sunlight, by using a material or film that can block at least one of ultraviolet, infrared, or visible light to the screen portion of the sunlight A particular region of the spectrum can be selected and reflected.

According to another embodiment of the present invention, by forming the screen portion curved surface to diffuse and reflect the light, or by processing the surface of the screen portion in the form of irregularities to reflect the light scattering, so that the light is evenly transmitted to each part of the room It is characterized in that the glare phenomenon can be alleviated.

According to another embodiment of the present invention, when the screen unit is formed to block sunlight, the screen unit functions as a heat accumulator by using a material having high heat storage performance or a color having high light absorption performance when the screen unit is formed to block sunlight. It is characterized in that to improve the heating performance of the building.

According to another embodiment of the present invention, the screen unit may be installed to be included in a part of a light steel ceiling or ceiling texture of a building, or may be utilized as a separate design element.

The present invention can achieve the following effects by the above configuration.

In the variable skylight system that functions to control the light condensation and indoor inflow of sunlight according to the present invention, by installing one or more on the roof or roof of the building, the light converging portion is rotated up and down and left and right according to the altitude and direction of the sun. By maximizing the condensing performance of the solar cell panel, and by forming a sunshade interlocking with the light collecting unit, it is possible to adjust the solar light introduced into the room seasonally through the skylight formed on the light collecting unit and the lower portion of the sunshade, By forming a screen portion in contact with the skylight portion, it is possible to achieve the effect of blocking or reflecting sunlight that enters the room during the winter season through the skylight portion.

In the variable skylight system that functions to collect the sunlight and the indoor inflow control of sunlight according to the present invention, the light collecting unit includes a light collecting unit gear unit for rotating the solar panel left and right, the light collecting unit gear unit inside At least one solar panel connected to the pinion gear is formed by forming a rack gear and at least one pinion gear so that when the rack gear is horizontally moved by driving the motor, the pinion gear engaged with the teeth is rotated. Rotating at the same time, it is possible to achieve the effect that the solar panel can change direction by chasing the azimuth angle of the sun.

In the variable skylight system that functions to control the light condensing and indoor inflow of sunlight according to the present invention, the shading portion is formed on the skylight portion to control the sunlight flowing into the room from the top of the building through the skylight portion By doing so, on the size and angle of the sunshade, it is possible to block the inflow of sunlight in the summer and to maximize the sunlight in winter, but the scattered light can be introduced at all times.

In the variable skylight system that functions to control the light condensing and indoor inflow of sunlight according to the present invention, the shade portion is interlocked with the vertical rotation of the light collecting portion, so that the light collecting portion is lowered horizontally in summer The sunshade also rotates to lower the sun's interior to block the inflow of sunlight. In winter, when the light-collecting section rises to the vertical, the sunshade also rotates to raise the sun to allow the indoor inflow of sunlight to the maximum, thereby reducing the heating and cooling load. The effect can be obtained.

In the variable skylight system for condensing sunlight and controlling the indoor inflow of sunlight according to the present invention, the sun visor by the wind by forming the awning plate in the form of louvers or by forming one or more through-holes in the awning plate The effect of reducing damage or deformation of the product and promoting safety can be obtained.

In the variable skylight system having the function of condensing the sunlight and controlling the indoor inflow of the sunlight according to the present invention, the free passage of wind is possible through the opening formed between the light collecting portion and the shade portion and the skylight portion formed in the lower portion. In summer, the effect of reducing the temperature rise of the solar panel can be reduced.

In the variable skylight system that functions to collect the sunlight and the indoor inflow control of sunlight according to the present invention, the screen portion can improve the energy performance of the building by blocking the sunlight flowing through the skylight or reflecting to the room. You can get the effect.

In the variable skylight system having the function of condensing sunlight and controlling indoor flow of sunlight according to the present invention, when the screen unit is formed to reflect sunlight, at least one of ultraviolet rays, infrared rays, or visible rays may be blocked. By using an existing material or film on the screen part, an effect of selecting and reflecting a specific region of the spectrum of sunlight can be obtained.

In the variable skylight system that functions to collect sunlight and control indoor flow of sunlight according to the present invention, the screen is curved to form a curved surface, or the light is scattered and reflected, or the surface of the screen is treated in an uneven form to scatter light. By doing so, light can be evenly distributed to each part of the room and the effect of alleviating glare can be obtained.

In the variable skylight system having the function of condensing the sunlight and controlling the indoor inflow of sunlight according to the present invention, when the screen portion is formed to block sunlight, the screen portion has high heat storage performance or light absorption. By using a color having high performance, the screen part functions as a heat storage body, thereby obtaining an effect of improving heating performance of a building.

1 is a perspective view of a skylight system according to an embodiment of the present invention
Figure 2 is a perspective view of the light collecting portion of the skylight system according to an embodiment of the present invention
Figure 3 is a perspective view of the shade of the skylight system according to an embodiment of the present invention
Figure 4 is a perspective view of the skylight portion of the skylight system according to an embodiment of the present invention
5 is a state diagram used for interlocking the light collecting unit and the shade of the skylight system according to an embodiment of the present invention.
Figure 6 is a detailed view of the light collecting unit gear portion of the skylight system according to an embodiment of the present invention
7a to 7c is a state diagram used for the rotation of the light collecting unit and the shade of the skylight system according to an embodiment of the present invention
8 is a state diagram used for the condensing loan of the skylight system according to an embodiment of the present invention.
9 is an installation example of a skylight system according to an embodiment of the present invention.

The present invention provides a light collecting unit 100 including a solar cell panel, the shade unit 200 formed to be in contact with the light collecting unit, and formed in the lower portion of the light collecting unit and the shade to inject sunlight into the room By including the skylight portion 300, one or more installed southward on the roof or roof of the building to move the light collecting unit 100 up, down, left, and right to enhance the condensing performance, and at the same time connected to the skylight 300 By forming the screen unit 400 to block or reflect the sunlight flowing into the winter, the sun flowing through the skylight 300 by the shade portion 200 and the screen unit 400 It is to provide a variable skylight system that functions to control the light condensing of sunlight and the indoor inflow of sunlight that can control light.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of a variable skylight system that performs the function of condensing the solar light and indoor inflow control of sunlight according to the present invention.

1 is a perspective view of a skylight system according to an embodiment of the present invention, FIG. 2 is a perspective view of a light collecting bag of a skylight system according to an embodiment of the present invention, and FIG. 3 is a shade portion of a skylight system according to an embodiment of the present invention. 4 is a perspective view of a skylight portion of a skylight system according to an embodiment of the present invention.

Referring to FIG. 1, a skylight system according to an embodiment of the present invention includes a light collecting unit 100 including a solar cell panel, a shading unit 200 connected to the light collecting unit 100, and the light collecting unit 100. And a skylight portion 300 formed under the sunshade portion, and a screen portion 400 formed under the skylight portion 300.

As shown in FIG. 1 or 2, the light collecting unit 100 according to the present embodiment is connected to the light collecting unit frame 101 having a predetermined thickness and forming a skeleton, and the light collecting unit frame 101. And a solar cell panel 102 for condensing sunlight, a solar panel drive shaft 103 formed as a central axis of left and right rotation of the solar panel 102, and left and right rotations of the solar panel 102. The solar cell is driven by the light collecting unit gear unit 104 formed to drive the hydraulic press, a hydraulic press 105 formed to drive the vertical rotation of the solar cell panel 102, and the hydraulic press 105. The light collecting unit drive shaft 106 formed by the center axis of the panel 102 rotating up and down, the light collecting unit driving shaft gear 107 formed at one or more end portions or the middle portion of the light collecting unit driving shaft 106, and the above aspect. Battery panel 102 vertical and horizontal rotation A control unit 108 for control.

Referring to FIG. 1 or FIG. 2, the light collecting unit frame 101 is a solar panel frame 1011 formed as an edge of the solar panel 102, and a light collecting unit is formed of a vertical frame of the light collecting unit 100. A vertical vertical frame 1012 and a horizontal frame 1013, which is formed of a horizontal frame of the light collecting unit 100, and includes a material such as stainless steel and a reinforced plastic having a predetermined thickness. 1012 and the horizontal frame 1013 intersect and bond to form an overall skeleton of the light collecting unit 100.

The solar panel 102 is formed in the form of a panel on the inside of the solar panel frame 1011, a device for collecting energy from the sun to convert into electricity, in some cases using a solar heat collecting plate heating or hot water Applicable to the production of

The solar cell panel formed for photovoltaic power generation is a dye-sensitized solar cell (DSSC, Dye Sensitized Solar Cell), or an organic solar cell (OPV, Organic PV) used by attaching to a crystalline silicon or thin film inorganic solar cell, glass, or the like. At least one of the solar cell panel formed as a heat collecting plate for the collection of solar energy can be used to use at least one of the plate type, vacuum tube type, Parabolic Trough Concentrator (PTC) type, Compound Parabolic Concentrator (CPC) type. do.

The solar panel driving shaft 103 is formed to be in contact with one surface of the solar panel frame 1011 to facilitate the rotation of the solar panel frame 1011 and the inner solar panel 102, one end is The light collecting unit gear unit 104 is connected.

The light collecting unit gear unit 104 is formed to rotate the solar panel driving shaft 103 by driving an inner pinion gear and a rack gear. For more details, refer to the description of FIG. do.

One or more hydraulic press 105 is formed on both sides or the center of the light collecting unit 100, the hydraulic press upper joint (1051) connects the light collecting unit 100 and the hydraulic press main body 1052, the lower hydraulic press The lower joint 1053 is connected to the support 305.

The hydraulic press upper joint 1051 and the hydraulic press lower joint 1053 may be formed of a material and a structure sufficiently durable to allow free rotational movement and to prevent deformation or breakage even after repeated rotation.

Both ends of the light collecting unit driving shaft 106 are supported by the support unit 305 and function as a central axis in which the light collecting unit 100 rotates up and down by the operation of the hydraulic press 105. Therefore, it is to be formed of a material and thickness to secure sufficient durability to support the load of the light collecting unit 100 and to prevent sagging due to its own weight.

At least one condensing unit driving shaft gear 107 is formed in the form of a pinion gear at an end portion or an intermediate portion of the condensing unit driving shaft 106 to be interlocked with the shading unit 200.

The control unit 108 is formed on one side of the light collecting unit gear unit 104, built-in a computer inside to convert the data of the solar altitude varying by region, date, time, by rotation spread value and transmitted to the electric motor According to the guide of the pinion and the rack gear of the light collecting unit gear unit 104 or the driving of the hydraulic press 105 to allow the solar panel 102 to rotate. In addition, in the present invention, a computer is built in the light collecting motor motor 104 to control the movement of the solar panel 102, but in another embodiment, a sensor is installed to track the altitude of the sun instead of the computer. It is possible to control the movement of the solar panel 102 in accordance with the value calculated from.

As shown in FIG. 1 or 3, the sunshade 200 according to the present embodiment has a sunshade 201 for blocking sunlight and a center for the rotation of the sunshade 201. A shading drive shaft 202 formed in a shaft, a shading drive shaft gear 203 formed in the shading drive shaft so as to engage with the light collecting unit drive shaft gear, a support connecting portion 204 for connecting with the skylight, and It includes a ventilation through hole 205 formed in the sunshade plate 201.

Referring to Figure 1 or 3, the awning plate 201 in the form of a flat plate made of a plastic, aluminum, wood, etc. on the upper portion of the skylight 300, but in the form of louver or one or more ventilation through By forming 205 at regular intervals, it is possible to prevent deformation or breakage due to wind.

On the other hand, the sunshade 201 is set so that the minimum angle between the horizontal and the winter in winter so as to be above the solar altitude (29 degrees of Seoul reference) of the winter sol so that the indoor inflow of sunlight is not blocked.

The sunshade drive shaft 202 is formed in the form of a rod rotatable so as to be in contact with one end of the sunshade plate 201, the sunshade drive shaft gear 203 is at the end or the middle portion of the sunshade drive shaft 202 One or more pinion gears may be formed in engagement with the light collecting unit driving shaft gear 107.

At both ends of the sunshade drive shaft 202, the sunshade drive shaft 202 forms a support connecting portion 204 which is a portion connected to the support 305 so as to rotate.

As illustrated in FIG. 1 or 4, the skylight 300 according to the present embodiment includes a transparent window 301 such as glass and plastic, and a skylight frame 302 which becomes a frame and an overall skeleton of the transparent window. And a fixing plate 303 which is formed to attach and fix the skylight to the roof or roof of the building, and a skylight case case 304 which is formed to be embedded in the slab of the building under the fixing plate, and the light collecting unit and And a support 305 formed to support the shade.

Referring to FIG. 1 or 4, the transparent window 301 is formed on the upper side or the side of the skylight part 300 by using a material such as glass or plastic having a high light transmittance, thereby entering the interior through the upper opening of the building. It functions to inject sunlight, and it is preferable to maintain a predetermined inclination so that dirt or dust can be easily washed off in rainwater and rainwater does not accumulate. On the other hand, the transparent window 301 may be a material or film that can block at least one of ultraviolet, infrared, or visible light in the transparent window.

The skylight frame 302 is formed of a metal such as aluminum having a predetermined thickness or a plastic material such as PVC to form the frame of the transparent window 301 and the entire skeleton of the skylight portion 300, between each member. Alternatively, the airtightness with the skylight frame 302 may be ensured so that leakage or thermal insulation problems do not occur.

The fixing plate 303 is formed to attach and fix the skylight part on the roof or roof of the building using a material such as metal, and forms a hole that can be fixed with an anchor, a bolt, or the like as necessary.

The skylight case case 304 is a part embedded in the slab of the building and is formed in the lower portion of the fixing plate 303 of a metal or plastic material, and a transparent window may be additionally installed in the lower portion as necessary.

The support 305 is formed on the fixing plate 303 to support the light collecting unit 100 and the shade 200, more specifically, the light collecting unit drive shaft 106 and the sunshade drive shaft ( Rotary shaft support 3031 formed to support 202, and the rotary shaft support hinge formed on the rotary shaft support 3051 as a hinge for promoting the rotation of the light collecting unit drive shaft 106 and the shade drive shaft 202 ( 3052, a hydraulic press support 3053 formed to support the hydraulic press 105, the hydraulic press support 3053 and the lower portion of the hydraulic press 105 is connected to the Hydraulic press connection portion 3054 is formed to facilitate the rotational movement.

The rotary shaft support 3051 may be the indirect sunlight passing through the lower portion and the ceiling 300 of the light collecting unit 100 and the shade 200 can be sufficiently delivered to the room and by the rotational movement of the sun plate 201 Due to the formation of a suitable height so that the control of solar inflow can be made.

On the other hand, by inducing the coming and going of the wind between the light collecting portion 100 and the shade portion 200 and the skylight portion 300 in the lower, by reducing the temperature rise of the solar panel in the summer efficiency Degradation can be mitigated, in particular, as the wind speed increases through the narrow space, the air pressure is lowered, and according to the Bernoulli principle of introducing more air, the effect can be further doubled.

The screen unit 400 according to the present exemplary embodiment includes a screen frame 401 and a screen plate 402, as shown in FIG. 1.

Referring to FIG. 1, the screen frame 401 is formed of a metal or plastic material having a predetermined thickness, wood, or the like to form an overall border, and the screen plate 402 is formed inside the screen frame 401. It may be formed of a plate-like body made of plastic or metal, or a material such as a fabric, but may be formed in a folding type that can be folded or unfolded or in a landfill type that can be put in or taken out.

The screen plate 402 is particularly formed in order to block the sunlight flowing through the skylight unit 300 in winter or to reflect the interior of the room.

When the screen plate 402 blocks sunlight, the screen plate 402 using a material that does not transmit light well to prevent the glare of the occupants and health problems and substances due to the influx of unnecessary harmful ultraviolet rays To prevent damage. In this case, by using a material having a high heat storage performance or a color having a high light absorption performance for the screen plate 402, it may be utilized as a heat storage body for storing thermal energy of solar light, thereby contributing to improving the heating performance of a building.

In addition, when the screen plate 402 reflects sunlight, the light energy or heat energy of the sun reflected using the material or color having high reflectance on the screen plate 402 may be transmitted to the inside of the building as much as possible. Make sure At this time, by using a UV blocking mirror or by attaching a UV blocking film to the screen plate 402, it is possible to exclude harmful ultraviolet rays as much as possible and reflect only visible light and infrared rays, and simultaneously block UV and visible light using an appropriate film. By doing so, it is possible to alleviate glare and to obtain thermal energy through infrared rays without harmful ultraviolet rays. In this case, the screen plate 402 is formed in a curved surface to diffuse and reflect light, or the surface of the screen plate 402 by scattering and reflecting light by processing the surface, so that the light is evenly transmitted to each part of the room. You can help relieve glare.

Factors that determine the function of the screen unit 400 among light reflection, blocking, dispersion, heat storage, and the like are the use and scale of the building, the preference of the occupants, the characteristics of the energy use, and the like. do.

On the other hand, the screen unit 400 may be installed or combined to be included in a structural material such as a light steel frame ceiling of a building or a ceiling material such as a ceiling tex, or may be utilized as a separate design element.

5 is a state diagram used for interlocking the light collecting unit and the shade of the skylight system according to an embodiment of the present invention.

As shown in FIG. 5, the light collecting unit drive shaft gear 107 is formed at the one end of the light collecting unit 100 in the form of a pinion gear, and the sunshade driving shaft gear 203 is the pinion at the one end of the sunshade 200. By forming in the form of gears, the light collection unit drive shaft gear 107 and the shade drive shaft gear 203 are formed so that the teeth interlock.

Therefore, in the summer when the light collecting unit 100 descends to be horizontal, the sun shade unit 200 also rotates downward to block the inflow of sunlight, and the light collecting unit 100 rises to be close to vertical. In winter, the sunshade 200 also rotates at an angle to allow indoor inflow of sunlight, and the light collecting unit 100 and the sunshade 200 are organically linked to derive an effect of increasing energy efficiency of a building. have.

At this time, the sunshade 200 has the advantage that the operation is interlocked by the light collecting unit 100 without a separate power or driving device, to reduce energy consumption and simplify the mechanical configuration.

On the other hand, if necessary, by separating the connection of the light collecting unit drive shaft gear 107 and the shading drive shaft gear 203, so that the light collection unit 200 in the fixed state to move the light collecting unit 100 independently. Can be set.

6 is a detailed view of the light collecting unit gear unit of the skylight system according to the embodiment of the present invention.

As shown in FIG. 6, the light collecting unit gear unit 104 has a predetermined width and length, and the gear case 1041 forms an outer edge thereof, and a rack gear is formed inside the gear case 1041. 1044 and one or more pinion gears 1043, wherein the rack gear 1044 is horizontally moved by driving the electric motor 1042 formed at one end of the light collecting unit gear unit 104. The pinion gear 1043, which is meshed with the size gear 1044, is rotated, so that the solar panel driving shaft 103 connected to the pinion gear 1043 can rotate at the same time.

7A to 7C are diagrams illustrating a state of use of rotation of the light collecting unit and the shading unit of the skylight system according to the embodiment of the present invention.

As shown in Figure 7a to 7c, to install the skylight system of the present invention on the roof or roof of the building, the lower portion of the skylight 300 is inserted into the room, the upper portion of the skylight 300 Allow it to protrude outwards. In addition, the light collecting unit 100 is rotated according to the altitude of the sun, which is operated by data values of the sun altitude varying by region, date, and time input to the embedded computer as described above.

Referring to FIG. 7A, when the altitude of the sun is low in winter corresponding to December, January, and February, the angle of the light collecting unit 100 is increased so that the solar light may be collected at right angles to the solar panel 102. It is used for power generation, etc., in conjunction with the sunshade 200 is rotated at an angle that does not block the sunlight flowing into the skylight part 300 directly contributes to the rise in the temperature of the room, causing the greenhouse effect to indoor heating It enhances the effect and increases the illuminance to make the room light effect. At this time, by blocking the sun light flowing into the skylight 300 through the screen unit 400 to prevent glare or to reflect the inside of the room it may be transmitted heat energy or light energy.

Referring to FIG. 7B, when the altitude of the sun is higher than winter, such as the spring and summer seasons (3, 4, 5, 9, 10, and November), the angle of the light collecting unit 100 is set lower than that of the winter solar panel (102). Increasing the effect of sunlight collected in the), but the sunshade 200 in conjunction with the moving to the angle to block the sunlight, thereby eliminating unnecessary direct sunlight, by inflowing only the scattered light indirect light into the room pleasant indoor illumination It is possible to obtain an effect that can be maintained.

At this time, if the size of the shade 200 is too small, the inflow of direct sunlight may occur in part, and if the size of the shade 200 is too large, waste of the member and mechanical overload can be caused, the use of the building It is necessary to appropriately form the size of the shading unit 200 according to the preference of the occupant, the mining demand, and the like.

Referring to FIG. 7C, in the summer (June, July and August), when the height of the sun is highest, the angle of the light collecting unit 100 is set lower than that of the spring and autumn seasons, so that the sunlight is collected on the solar panel 102. By increasing, but the shade 200 is moved further downward at an angle to block the sunlight, to prevent the increase of room temperature by maximizing the inflow of sunlight, only the scattered light, which is indirect light that does not contain thermal energy can be introduced into the room. So that you can maintain comfortable indoor lighting. Therefore, it is possible to derive the effect of reducing the lighting energy while reducing the cooling load in summer.

On the other hand, since some of the ultraviolet light may be included in the scattered light instead of direct sunlight, by using a sunscreen film or the like in the skylight portion 300, the scattered light without the harmful ultraviolet light can be introduced into the room.

8 is a state diagram used for the light concentrating loan of the skylight system according to an embodiment of the present invention.

As shown in FIG. 8, the solar panel 102 rotates about the solar panel driving shaft 103 to change the direction of the solar panel 102 according to the position of the sun by time, date, and region. The light condensing efficiency can be improved.

Actually, the effective time to effectively collect sunlight is from 10 am to 5 pm, so when the present invention is installed in the south facing direction, the solar panel 102 rotates about the solar panel drive shaft 103. It is preferable to set the angle within 90 degrees (less than 45 degrees east side, less than 45 degrees west side) normally. The reason is that the sun of the position outside the range of 90 degrees is the early morning or late afternoon sun, the light collection efficiency is reduced, and in the case of forming a plurality of solar panel 102, excessive rotation of the solar panel 102 is the angle This is because the shadow between each solar panel 102 can be made.

In addition, the distance between each solar panel 102 is set to allow a sufficient distance to avoid the mutual converging interference even at the maximum rotation angle of the solar panel 102, but direct sunlight passes between the solar panel 102 at any angle Do not allow indoor entry.

9 is an exemplary view of installation of a skylight system according to an embodiment of the present invention.

As shown in Figure 9, by installing the present invention at regular intervals so as not to interfere with each other on the roof or roof of the building, while efficiently condensing according to the position of the sun, the light through the upper surface of the building effectively according to the season It is possible to derive the effect of improving the energy efficiency of buildings.

At this time, it is advantageous to install the present invention in the south facing direction, but if unavoidably may be formed in the south-east or south-west direction, may be arranged in a row or in a zigzag to avoid mutual interference.

On the other hand, the present invention to be equally applicable to the inclined roof as well as the flat roof of the building.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Therefore, it is intended that the present invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents. Will be apparent to those of ordinary skill in the art.

100: condensing loan 101: condensing loan frame
1011: solar panel frame 1012: condensing portion vertical frame
1013: horizontal frame of condensing portion 102: solar panel
103: solar panel drive shaft 104: condensing portion gear unit
1041: gear case 1042: electric motor
1043: Pinion Gear 1044: Rack Gear
105: hydraulic press 1051: hydraulic press upper joint
1052: hydraulic press body 1053: hydraulic press lower joint
106: condensing portion driving shaft gear 107: condensing portion driving shaft gear
108: control unit 200: shading unit
201: sunshade 202: sunshade drive shaft
203: Shading drive shaft gear 204: Support connecting portion
205: ventilation through air 300: skylight
301: transparent window 302: skylight frame
303: fixing plate 304: skylight case
305: support 3051: rotation axis support
3052: hinge support shaft 3053: hydraulic press support
3054: hydraulic press connection portion 400: screen portion
401 screen frame 402 screen
500: the sun

Claims (14)

A solar cell panel formed to collect solar light, a light collecting unit gear unit formed to drive left and right rotation of the solar cell panel, a hydraulic press formed to drive a vertical rotational motion of the solar cell panel, A light collecting unit 100 including a solar panel driving axis formed as a center axis of left and right rotations of the solar cell panel, and a light collecting unit driving axis formed as a central axis of vertical movement of the solar cell panel;
It is formed in contact with the light collecting unit 100, and includes a sunshade to form to selectively block the sunlight flowing into the upper portion of the building, and a sunshade drive shaft to form a vertical axis of rotation of the sunshade plate Sunshade 200;
A skylight part 300 formed below the light collecting part 100 and the shade part 200 and including a transparent window for introducing sunlight into the room; And
The screen unit 400 is formed below the skylight unit 300 and includes a screen plate for blocking or reflecting sunlight introduced through the skylight unit 300 into the room. Variable skylight system that controls the inflow of solar light and sunlight.
The method of claim 1,
A light collecting unit drive shaft gear having a pinion gear shape and an pinion gear drive shaft gear having a pinion gear shape are formed at an end or an intermediate portion of the light collecting unit driving shaft, and the light collecting unit driving shaft gear and the sunshade are formed at an end or an intermediate portion of the light collecting unit driving shaft. Variable of the condensing of the solar light and the indoor inflow control of the solar light, characterized in that the teeth of the secondary drive shaft gear is engaged with each other, so that the rotational movement of the light collecting unit 100 and the shade 200 can be interlocked with each other. Type skylight system.
The method of claim 1,
The pinion gear part includes an electric motor, a rack gear, and a pinion gear inside, so that when the rack gear is horizontally moved by driving of the motor, the pinion gear engaged with the rack gear is rotated as the pinion gear rotates. The solar panel drive shaft connected to the gear is rotated, so that at least one of the solar panel can change the direction at the same time according to the position of the sun, the solar condensing and indoor inflow control function Variable skylight system.
The method of claim 1,
When the solar cell panel is formed for photovoltaic power generation, at least one of a dye-sensitized solar cell (DSSC) or an organic solar cell (OPV) used by being attached to crystalline silicon, a thin film-type inorganic solar cell, glass, or the like may be used. When the solar panel is formed for the collection of solar energy, the solar light condensing and indoor inflow control function of the solar light, characterized in that at least one of the type can be used, such as PTC, CPC type Variable skylight system.
The method of claim 1,
The sunshade 200 includes a sunshade formed on the upper portion of the skylight 300 to selectively block the indoor inflow of sunlight, the sunshade is a spring or summer season depending on the change in the altitude of the sun by the season Blocking the direct inflow of sunlight through the skylight 300 and forming the size and angle to allow the maximum sunlight in winter, scattered light through the bottom of the sunshade and the top of the skylight 300 A variable skylight system for condensing sunlight and controlling the inflow of sunlight indoors, which can be always supplied indoors.
6. The method according to claim 1 or 5,
The lowest angle between the awning plate and the horizontal in winter is formed so as to be equal to or higher than the solar altitude of the winter solstice (29 degrees in Seoul), so that the indoor inflow of sunlight is not blocked by the awning plate in winter. Variable skylight system to control indoor flow of sunlight.
6. The method according to claim 1 or 5,
By forming the sun visor plate in a louver form or by forming one or more through-holes in the sun visor plate, it is possible to prevent damage or deformation of the sun visor plate by wind and to promote safety. Variable skylight system with indoor inflow control.
The method of claim 1,
It is possible to reduce the temperature rise of the solar panel in the summer by creating an opening between the light collecting portion 100 and the shade portion 200 and the lower skylight portion 300 to induce the coming and going of the wind. A variable skylight system that functions to collect solar light and control indoor flow of sunlight.
The method of claim 1,
The skylight part 300 is buried and fixed in the opening of the roof or rooftop slab of the building, and includes a transparent window for introducing the light from the upper part of the building into the room, UV, infrared, or visible light in the transparent window A variable skylight system for controlling the concentration of sunlight and the inflow of sunlight indoors, characterized in that the material or film for blocking at least one can be used.
The method of claim 1,
The screen unit 400 includes a screen plate which functions at least one of the two, blocking the sunlight flowing through the skylight unit 300 or reflecting it into the room, and fixed or folding the screen plate. And a variable skylight system for controlling the concentration of sunlight and the inflow of sunlight indoors, which can be formed in a variable manner such as a moving type or a moving type.
11. The method according to claim 1 or 10,
In the case where the screen plate is formed to reflect sunlight into the room, a material or film for blocking at least one of ultraviolet rays, infrared rays, or visible light is used for the screen plate, thereby covering a specific region of the spectrum of sunlight. A variable skylight system that functions to control the focusing of sunlight and the indoor inflow of sunlight, characterized in that it can be selected and reflected.
11. The method according to claim 1 or 10,
When the screen plate is formed to block sunlight, the screen plate may function as a heat accumulator by using a material having high heat storage performance or a color having high light absorption performance in the screen plate. Variable skylight system that collects sunlight and controls the inflow of sunlight.
11. The method according to claim 1 or 10,
A variable skylight system for condensing sunlight and controlling the inflow of sunlight indoors, characterized in that the screen plate is formed into a curved surface to diffuse and reflect light or to scatter and reflect light by treating the surface in an uneven form. .
11. The method according to claim 1 or 10,
A variable skylight system for controlling the light inflow of solar light and indoor inflow of sunlight, characterized in that the screen unit 400 can be installed in conjunction with or coupled to the ceiling structure of the building or part of the ceiling material.

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