KR102053693B1 - Multifunctional bipv double skin facade system - Google Patents

Abstract

The present invention relates to a multi-functional BIPV double skin system, for this purpose a PV (Photovoltaic) frame that is opened and closed in the non-window area between the building exterior wall layer and the floor, the double skin portion is installed in the window area of the building exterior wall; And a control unit for controlling the PV frame and the sun visor by a light sensor installed in the building and a GPS module installed outside the building, and dimming the LED lighting according to the amount of light incident on the window area of the building; And an ESS distribution unit for storing the photovoltaic energy generated in the PV frame and supplying power to each unit, and surplus power supplied to the KEPCO switchboard. Ventilation, and the PV frame can be tilted according to the altitude and azimuth and the external wind direction of the sun as well as opening and closing, it is characterized in that the power generation amount and the ventilation efficiency can be increased.

Description

Multifunctional BIPV Double Skin System {MULTIFUNCTIONAL BIPV DOUBLE SKIN FACADE SYSTEM}

The present invention relates to a multi-functional BIPV double-shell system, more specifically to produce power in-house through photovoltaic, and to efficiently distribute energy through the BEMS (Bulding Energy Management System) and ESS (Energy Storage System) distribution unit The present invention relates to a multi-functional BIPV double envelope system that can quickly ventilate efficient photovoltaic power and external air through PV frames that open and close in four axes.

In general, windows of buildings provide natural light and vistas, but they can also cause visual discomfort due to excessive heating and heating loads, thermal discomfort due to solar radiation, and glare.

In order to overcome this problem, a double facade has been introduced that doubles the windows of a building, which is generally a hollow layer formed between the outdoor windows and the indoor windows and between them. It is composed.

Recently, as the demand for quality improvement of building space is increasing day by day due to the improvement of the cultural environment and the perception of the building environment, the concept of a multi-layer that adds one envelope to the existing facade. A double skinned window is used.

The double skin may be installed only with solar panels, but in general, since the outer skin of a building is constructed by a glass curtain wall method, the part corresponding to the glass is composed of windows or panels for light, and the like. The portion of is usually formed by solar panels.

However, in the conventional double skin system of a building provided with a solar cell module, the window frame frame is not automatically controlled manually, and since the solar panel is fixed, the angle of the solar panel may be changed according to the height or position of the sun according to the change of the season. There is a problem that power generation is not efficient because it is not adjustable.

Republic of Korea Patent Registration No. 1586208

The present invention has been made in view of the above problems, the first object of the present invention is to produce the power itself through photovoltaic power, energy through the BEMS (Bulding Energy Management System) and ESS (Energy Storage System) distribution unit To provide a multifunctional BIPV double skin system that can efficiently distribute the

It is a second object of the present invention to provide a multifunctional BIPV double envelope system capable of quickly venting efficient photovoltaic power and external air through a PV frame opened and closed in four axes.

According to a feature for achieving the above object, the first invention relates to a multifunctional BIPV double skin system, for this purpose, PV (Photovoltaic) frame is installed in the non-window area between the building's outer wall layer and the floor In the window area of the outer wall of the building, the double skin part is installed with a sunshade; and the PV frame and the sunshade are controlled by the illumination sensor installed in the building and the GPS module installed outside the building, and according to the amount of light incident to the window area of the building A controller dimming the LED lighting; And an ESS distribution unit for storing the photovoltaic energy generated in the PV frame and supplying power to each unit, and surplus power supplied to the KEPCO switchboard. In addition to the ventilation, the PV frame can be tilted according to the altitude and azimuth and the external wind direction of the sun, as well as opening and closing, it is characterized in that the power generation amount and the ventilation efficiency can be increased.

According to a second invention, in the first invention, the double skin part is installed to protrude over the wall of the building, a plurality of PV frames hinged via a hinge frame on the outside of the frame, and each of the PV frames A plurality of screw shafts coupled to the inside of the frame to open and close, a servo motor connected to a worm gear box coupled to each of the screw shafts, and one side is connected to a universal joint coupled to both sides of the PV frames, The other side is composed of a pair of operating bars which are linked to the screw nut is elevated by the rotation of the respective screw shaft, the hinge frame is connected to the upper or lower center of the PV frame and the PV frame left / Characterized in that configured to be able to tilt to the right.

According to a third invention, in the first or second invention, the double skin portion is characterized in that the PV frame disposed in the upper and lower portions of the window area around the window area is opened and closed to face each other.

In a fourth invention, in the first invention, the control unit is supplied with wind direction information by a wind vane installed in a building.

The fifth invention, in the first invention, the control unit is connected to the building energy management system (BEMS) of the building to receive the space information, power load information, HVAC (Heating, Ventilation, Air Conditioning System) information It is connected to the ESS distribution unit and receives the charging information of the battery, characterized in that for controlling the opening and closing angle of the PV frame.

According to a sixth invention, in the fourth or fifth invention, the control unit controls the PV frame by determining the weather vane, spatial information in the building of the BEMS, and HVAC (Heating, Ventilation, Air Conditioning System) information. .

According to the multi-function BIPV double skin system of the present invention, the power is produced by the photovoltaic itself, and energy can be efficiently distributed through the BEMS (Bulding Energy Management System) and the ESS (Energy Storage System) distribution unit.

In addition, through the angle control of the PV frame opening and closing in the four-axis direction can be efficiently ventilated photovoltaic power and external air in a short time has the effect of increasing the heating and cooling efficiency.

1 is a block diagram of a multifunctional BIPV double skin system according to the present invention,
2 is a front view showing the screw shaft and the operation bar fixed to the frame in FIG.
Figure 3 is a side cross-sectional view of a multifunctional BIPV double envelope system installed in an existing building according to the present invention,
4 is an operation diagram showing the opening and closing of the PV frame and the sunshade in Figure 3,
5 is an operation diagram showing the left / right tilt angle of the PV frame extracted from FIG.
6 is a block diagram of a multifunction BIPV double skin system according to the present invention;

The following objects, other objects, features and advantages of the present invention will be readily understood through the following preferred embodiments associated with the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms.

Rather, the embodiments introduced herein are provided so that the disclosure may be made thorough and complete, and to fully convey the spirit of the present invention to those skilled in the art.

The embodiments described and illustrated herein also include complementary embodiments thereof.

In this specification, the singular also includes the plural unless specifically stated otherwise in the phrase. As used herein, the words 'comprise' and / or 'comprising' do not exclude the presence or addition of one or more other components.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. In describing the specific embodiments below, various specific details are set forth in order to explain and understand the invention in more detail. However, one of ordinary skill in the art can understand that the present invention can be used without these various specific contents. In some cases, it is mentioned in advance that parts of the invention which are commonly known in the description of the invention and which are not highly related to the invention are not described in order to avoid confusion in describing the invention.

1 is a block diagram of a multifunctional BIPV double skin system according to the present invention, Figure 2 is a front view showing the screw shaft and the operation bar fixed to the frame in Figure 1, Figure 3 is a multifunctional BIPV double skin system according to the present invention It is a side cross-sectional view installed in an existing building, Figure 4 is an operation diagram showing the opening and closing of the PV frame and the sunshade in Figure 3, Figure 5 is an operation diagram showing the left / right tilting angle of the PV frame extracted in Figure 4, 6 is a block diagram of a multifunction BIPV double skin system in accordance with the present invention.

As shown in Figures 1 to 6, the present invention not only produces power itself through photovoltaic power generation, but also efficiently distributes energy through the BEMS (Bulding Energy Management System) and ESS (Energy Storage System) distribution unit, 4 The present invention relates to a multifunctional BIPV double skin system that can efficiently ventilate external air with efficient photovoltaic power through an axially open PV frame.

Multifunctional BIPV double skin system 100 of the present invention is composed of three parts, which is composed of a double skin 10, the control unit 20 and the ESS distribution unit 30.

The double skin 10 is to be remodeled on the outer wall of the existing building, it is installed on the wall of the window area 210 and the non-winding area 220 between the floor and the floor of the existing building is installed in duplicate.

At this time, the double skin 10 is a PV (Photovoltaic) frame 11 that is opened and closed to the non-window area between the building outer wall layer and the floor is installed, the sunshade film 112 is installed in the window area of the building outer wall. .

The double skin 10 is formed in the hollow layer 111 therein, the hollow layer 111 is made to be ventilated by the opening and closing degree of the PV frame 12.

In addition, the hollow layer 111 is provided with a awning film 112 connected to a plurality of awning film plate 113, the awning film 112 is opened and closed by a servo motor (M), the servo motor (M) is a control unit ( 20) is a configuration controlled by.

The ESS distribution unit 30 includes a storage battery 31 to store energy photovoltaic in the PV frame 12, and supplies the power stored in the storage battery 31 to each part, the surplus power is KEPCO switchboard Function to supply

The ESS power distribution unit 30 stores power at a maximum daily use time (Peak time), and then utilizes (discharges) at a desired time period, thereby enabling stable and efficient energy consumption of the power system, and operating time of the PV module ( It is possible to utilize 100% of irregularly produced power by charging the battery produced by solar light in the battery and discharging it during non-operation time (power non-occurring time) at 10 ~ 16 o'clock. do.

The controller 20 controls the PV frame 12 and the sunshade 112 by the illumination sensor 50 installed in the building and the GPS module 51 installed outside the building, and the window area 210 of the building 200. Dimming the LED light 60 according to the amount of light incident on the).

In addition, the control unit 20 is supplied with building space information, power load information, HVAC (Heating, Ventilation, Air Conditioning System) information through the Building Energy Management System (BEMS) 40, It is connected with the ESS distribution unit 30 receives the charging information of the battery.

On the other hand, the PV frame 12 coupled to the double skin 10 is made so that the PV module 121 is installed so that the photovoltaic power, at this time, the PV frame 12 is not only open and close, but also the altitude of the sun And it can be tilted according to the azimuth and the outside wind direction is configured to increase the amount of power generation and ventilation efficiency.

In this case, the double skin 10 is configured to increase and decrease the ventilation efficiency by opening and closing the PV frame 12 facing each other around the window area 210.

The detailed configuration of the above-described double skin is as follows.

The double skin 10 includes a frame 11, a PV frame 12, a screw shaft 14, a servo motor M, an operation bar 16, and a hinge frame 13.

The frame 11 is formed of an inner hollow layer 111 and consists of a pentagonal body so as to protrude at a predetermined distance from the wall surface of the building.

In this case, the PV frame 12 is hinged to the outside of the frame 11, which is a non-window area 220 of the building via a hinge frame 13 to be opened and closed.

In addition, each screw shaft 14 is coupled to the worm gear box 15 for deceleration, the worm gear box 15 is engaged with the worm shaft 152 rotated by the servo motor (M) in the horizontal direction.

More specifically, the worm gear box 15 is provided with a worm wheel 151 arranged on the screw shaft 14, and the worm wheel 151 is engaged with the worm shaft 152 connected to the servo motor M. .

And the operation bar 16 is to open and close the PV frame 12, one side is linked to the universal joint 122 coupled to the PV frame 12, the other side of each of the screw shaft 14 Linked to the screw nut 141 is elevated by rotation.

At this time, the operation bar 16 is connected to both sides of the PV frame 12, as shown in Figure 5, is configured to be tilted according to the horizontal length of each operation bar (16). In more detail, each of the operation bars 16 is linked to both upper and lower sides of the PV frame 12, and the hinge frame 13 is connected to the PV frame via the ball 131 and the socket 132. 12) is connected to the upper or lower center is configured to tilt the PV frame 12 to the left / right.

Therefore, the PV frame 12 is rotated left / right through the ball 131 and the socket 132 so that the tilting angle can be freely changed according to the altitude and azimuth of the sun.

In addition, the PV frame 12 disposed in the non-window area 220, which is the upper portion of the window area 210, has a lower portion of the hinge frame 13 hinged to the frame 11 to open and close an upper part of the window area 210. The PV frame 12 disposed in the non-window area 220 that is the lower portion of the hinge frame 13 is hinged to the frame 11 is configured to open and close the bottom.

As a result, the PV frame 12 is opened and closed to face each other around the window area 210 so as to increase the ventilation efficiency.

Hereinafter, the overall operation of the multifunctional BIPV double skin system will be briefly described.

The function of the control unit 20 is as follows.

As shown in FIG. 6, the control unit 20 is the color of the LED lighting 60 in the building according to the amount of light incident on the window area 210 of the building 200 by the illumination sensor 50 installed inside the building 200. And dimming the brightness and control the sunshade (112).

In addition, the controller 20 controls the servomotor M by receiving the solar altitude and azimuth information by the illumination module 50 installed outside the building 200 and by the GPS module 51. Then, the opening and closing and tilting angles of the PV frame 12 are controlled by the controlled servomotor (M).

In addition, the controller 20 is connected to the BEMS 40 of the building 200 receives the space information, power load information, HVAC information in the building, and is connected to the ESS distribution unit 30 of the storage battery 31 The charging information is supplied to control the opening and closing angle of the PV frame 12.

Accordingly, whether or not photovoltaic power generation is determined by whether the illuminance sensor 50 is incident to sunlight, the power load information of the BEMS 40, and the charge state of the battery 31 of the ESS power distribution unit 30. The frame 12 is controlled.

In addition, whether the ventilation is determined by the wind vane 52, the space information and the HVAC information in the building of the BEMS 40, the control unit 20 controls the PV frame 12. At this time, the controller 20 determines the upward wind, the downward wind, and the side wind flowing along the wall of the building 200 to adjust the opening and closing degree and the tilting angle of the PV frame 12 so that ventilation can be performed more quickly. do.

The operation of the PV frame is as follows.

2, 5 and 6, when the servo motor M controlled by the control unit 20 rotates, the worm wheel 151 slows down the rotation speed, and the worm wheel 151 is screwed according to the rotation direction. Rotate the shaft 14 forward / reverse.

The screw nut 141 moves up and down according to the forward / reverse rotation of the screw shaft 14, and the operating bar 16 linked to the screw nut 141 has a different horizontal length to open and close the PV frame 12. .

At this time, since the two operation bars 16 are connected to the PV frame 12 together with the opening / closing operation of the PV frame 12, the PV frame 12 is ball (depending on the horizontal length of each operation bar 16). The tilting angle is variable through the 131 and the socket 132.

Configurations shown in the embodiments and drawings described herein are only one of the most preferred embodiments of the present invention and do not represent all of the technical spirit of the present invention, various equivalents that may be substituted for them at the time of the present application It should be understood that there may be variations and examples.

10: double skin 11: frame 111 hollow layer
112: sunshade 113: sunshade
12: PV frame 121: PV module
122: universal joint 13: hinge frame
131: ball 132: socket
14: screw shaft 141: screw nut
15: worm gearbox 151: worm wheel
152: Worm shaft 16: operation bar
20: control unit
30: ESS power distribution unit 31: storage battery
40: BEMS
50: Ambient light sensor 51: GPS module 52: Weather vane
60: LED lighting
100: Multifunction BIPV Double Jacketed System
200: building 210: window area 220: non-wind area
M: Servo Motor

Claims (6)

Photovoltaic (PV) frames 11 that are opened and closed are installed in the non-window area 220 between the outer wall layer and the floor of the building 200, and the sunscreen 112 is installed in the window area 210 of the outer wall of the building 200. Double skin 10;
Control the PV frame 12 and sunshade 112 by the illumination sensor 50 installed in the building 200 and the GPS module 51 installed outside the building, and enters the window area 210 of the building 200. A control unit 20 dimming the LED light 60 according to the amount of light to be; And
The ESS distribution unit 30 stores the energy photovoltaic generated in the PV frame 12 and supplies power to each unit, and the surplus power is supplied to the KEPCO switchboard,
The double skin 10 is ventilated by the opening and closing degree of the PV frame 12,
The PV frame 12 can be tilted according to the altitude and azimuth and the external wind direction of the sun as well as opening and closing, thereby increasing power generation and ventilation efficiency,
The double skin 10 is,
Frame 11 is installed to protrude to the wall of the building 200,
A plurality of PV frames 12 hinged to the outside of the frame 11 via a hinge frame 13,
A plurality of screw shafts 14 coupled to the inside of the frame 11 to open and close the respective PV frames 12;
Servo motor (M) connected to the worm gear box (15) coupled to each of the screw shaft (14),
One side is linked to the universal joint 122 coupled to both sides of the PV frame 12, the other side is a pair of link connected to the screw nut 141 is elevated by the rotation of the respective screw shaft 14 Consisting of an operating bar (16),
The hinge frame 13 is connected to the upper or lower center of the PV frame 12 through the ball 131 and the socket 132 is configured to tilt the PV frame 12 to the left / right Multifunction BIPV double skin system.
delete The method of claim 1,
The double skin 10 is a multi-functional BIPV double skin system, characterized in that the PV frame 12 disposed on the upper and lower portions of the window area 210 around the window area 210 is opened and closed to face each other.
The method of claim 1,
The control unit 20 is a multi-function BIPV double envelope system, characterized in that the wind direction information is supplied by the wind vane (52) installed in the building.
The method of claim 1,
The control unit 20 is connected to the building energy management system (BEMS) 40 of the building is supplied with space information, power load information, HVAC (Heating, Ventilation, Air Conditioning System) information, ESS distribution unit Multi-function BIPV double skin system, characterized in that the control of the opening and closing and tilting angle of the PV frame 12 by receiving the charging information of the storage battery 31 in association with (30).
The method according to claim 4 or 5,
The control unit 20 controls the PV frame 12 by determining the weather vane 52, the space information in the building of the BEMS 40, and the HVAC (Heating, Ventilation, Air Conditioning System) information. Double skin system.

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