KR101000293B1 - Pairglass windows solar system - Google Patents

Abstract

PURPOSE: A solar light dual-layered glass system is provided to automatically or manually regulate the amount of incident light by rotatably installing a blind-type slat to the inside of the system. CONSTITUTION: A motor(10) is fixed in a case(7) in order to rotate a motor shaft(11). A decelerator(20) regulates the torque and the revolutions per minute of the motor. A driving gear(30) transfers the torque to a lower part. A plurality of pinion gears(40) is installed to the lower part of the driving gear. A pair of rack gears(50) is engaged with the pinion gears. A solar cell(70) is attached to the upper side of a slat(60) in order to generate electricity.

Description

Solar glass windows system {Pairglass windows solar system}

The present invention relates to a multi-layer glass system, in particular, the outdoor transmission is naturally maintained in the room, and also the blind-type slat in order to control the incident amount of sunlight, shading effect, noise blocking, invasion of privacy and energy saving The present invention relates to a solar laminated glass system that can be used in a system and attaches a solar cell to a slat to produce electricity in an eco-friendly manner.

In general, BIPV system (Building Integrated Photovoltaic System) is a commercially available technology for photovoltaic power generation by attaching a solar cell to the outer glass surface of laminated glass. When installed in the interior, there is a problem that the interior cannot be seen from the inside because it is not transmitted from the inside to the outside. There was a problem in that the efficiency is lowered.

On the other hand, the existing double-glazed glass built-in blinds are composed of squares on two glass plates, and the circular rollers are arranged at regular intervals in the upper box, and the aluminum slats listed below the upper box are fixed or fixed by the ladder chamber. It is connected and operated by the driving of the motor, reducer, etc. located on the side of the upper box. However, this method has a problem of efficiency in generating solar electricity since the shadow of the ladder room covers the solar cell surface attached to the blind.

The present invention has been invented to solve the problems of the prior art as described above, it is possible to implement the design according to the interior concept without the ladder room, tape straps, etc. used in the installation of the existing blinds and the external transmission is naturally maintained in the room. It is an object of the present invention to provide a new concept solar multilayer glass system that can generate solar energy, which is renewable energy, by automatically placing the solar cell attached to the slat at the most efficient position at a certain time.

In order to realize the above object, the present invention is a solar laminated glass system in which a pair of glass plate is fixedly fixed to the inner side of the window frame, the upper side of the base frame that each inner side of the pair of glass plate is in close contact A motor provided to rotate the rotating shaft of the motor, a reducer connected to the front of the motor to adjust the rotational force and the rotational speed of the motor, and fixed to an end of the rotating shaft of the motor protruding forward of the reducer to transmit the rotating force to the lower portion. A drive gear, a pinion gear installed at a lower portion of the drive gear and rotatably engaged with the gear teeth of the drive gear, the plurality of pinion gears being spaced apart from each other, and a support bracket in both vertical directions of the plurality of pinion gears, respectively. Rack gears which are supported and engaged with the gear teeth of the pinion gear so that both sides operate in the opposite vertical direction. And a slat coupled to the pinion gear on a slat rotation shaft axially coupled to the inside of the base frame to rotate forward and backward, and a solar cell attached to an upper surface of the slat to generate electricity. Provide a system.

Solar laminated glass system according to the present invention has a shade effect according to the time zone and the user's preference by allowing the blind slat to be rotatably installed therein so as to automatically or manually adjust the incident amount of sunlight, to block the noise The effect of the multi-layer glass system having an effect can be further increased, and as a blind, there is an advantage of preventing privacy invasion by preventing the interior from being viewed from the outside.

In addition, the solar cell is attached to the slat to generate electricity through the solar cell, so that it can be used as a power source for driving the slat and a power system including the surrounding electric and electronic devices, thereby having an energy saving effect. It automatically absorbs sunlight by automatically positioning it in the most efficient location at any given time. In addition, since a power supply wiring, a sensor, or a signal receiving unit is embedded in the multilayer glass system, there is an advantage that a multilayer glass system having a beautiful design can be realized.

In addition, the slats can be configured manually or semi-automatically, such as remote control, but the controller is provided with a built-in program in the controller to program the optimal angle of the solar cell at a certain time zone, season, and installation area. There is an advantage that can control the rotation of the solar cell by controlling.

In addition, since solar cells are installed between a pair of glass plates, solar cell efficiency can be prevented only by maintenance such as external cleaning of the glass plate, which makes maintenance easy and all components are installed inside the multilayer glass system. There is an advantage that there is no fear of corrosion, breakage and theft easily.
In addition, by installing the motor and the reducer in the case and fixing the case on a fixed base fixedly fixed to the upper surface of the base frame, attenuation and suppression of transmission of the vibration of the motor to the base frame can be performed to perform a stable operation of the multilayer glass system. There is an advantage to that.

1 is an overall perspective view of a solar laminated glass system according to the present invention,
2 is a partially cutaway perspective view of the main part according to the present invention;
Figure 3 is a side cross-sectional configuration according to the present invention,
4a and 4b is an operating state diagram of the solar laminated glass system according to the present invention,
5 and 6 is a front cross-sectional view showing another example according to the present invention,
7 to 8b is a perspective view and an operational state diagram showing still another example according to the present invention,
9 is a configuration diagram showing still another example according to the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is an overall perspective view of a solar laminated glass system according to the present invention, Figure 2 is a partial cutaway perspective view of the main portion of an embodiment according to the present invention, Figure 3 is a side cross-sectional configuration of FIG.

1 to 3, in the solar multilayer glass system according to the present invention, in the solar multilayer glass system, in which a pair of glass plates 3 are fixedly spaced apart and fixed inside the base frame 2, The motor 10 is provided on the upper side of the base frame 2 to rotate the motor rotating shaft 11, the reducer 20 connected to the motor 10, and is provided at the end of the motor rotating shaft 11 Drive gear 30, the pinion gear 40 is rotated in engagement with the drive gear 30, the rack gear 50 coupled to both sides of the horizontal direction of the pinion gear 40 vertically operated, and the pinion gear It comprises a slat 60 coupled to the slat rotation shaft 61 coupled to the shaft 40, and a solar cell 70 attached to the upper surface of the slat 60.

In the solar multilayer glass system according to the present invention, the solar cell 70 is attached to the slat 60 which is rotated as described above, and receives solar light, thereby forming electricity, and sensing the electricity of the solar cell 70. It includes a photovoltaic device provided with a measuring sensor (72).

As shown in FIGS. 2 and 3, the pair of glass plates 3 are tightly fixed to the inside of the rectangular frame-shaped base frame 2, and the window frame 5 has the outside of the edge of the glass plate 3 and the base frame 2. Wrapped in a multi-layer glass system is made, all the above components are installed inside the multi-layer glass system.

Among the above components, the motor 10 is fixedly installed on the upper side of the base frame 2, and in front thereof, a speed reducer 20 for adjusting the rotational force and the rotation speed of the motor 10 is installed. The motor 10 and the reducer 20 are fixedly positioned inside the case 7 having the upper and front portions open as shown in FIGS. 2 and 3, and the case 7 is the center of the base frame 2. It is supported and fixed by a fixing support 8 formed in the longitudinal direction of the base frame 2 on the side upper surface. The case 7 having the motor 10 and the reducer 20 is supported and fixed by the fixing support 8 to attenuate and suppress transmission of vibration by the motor 10 to the base frame 2. Therefore, the operation of the multilayer glass system can be maintained stably.

In front of the reducer 20, the motor shaft 11 is formed to protrude, and the driving gear 30 is provided at the end of the motor shaft 11 to transmit the rotational force to the bottom, the lower portion of the drive gear 30 A plurality of pinion gears 40 rotated in engagement with teeth are provided to be spaced apart. The drive gear 30 and the pinion gear 40 are a combined configuration for transmitting the amount of rotation through the reducer 20.

On both sides of the plurality of pinion gears 40 in the horizontal direction, a pair of rack gears 50 are installed in the vertical direction to operate vertically by the rotation of the pinion gear 40. Rack gear 50 is installed in the longitudinal direction along one side portion of the base frame 2, as shown in Figure 2, respectively supported by a plurality of spaced apart support brackets 51 are engaged with the gear teeth of the pinion gear 40, both sides This works in opposite directions.

The slat rotation shaft 61 is coupled to the inner side of the base frame 2 to the plurality of spaced lower side pinion gears 40, and the slat 60 is axially coupled to the slat rotation shaft 61, so that Rotating forward and backward in accordance with the rotation. At this time, since the pinion gear 40 and the rack gear 50 should be rotated to support the slat rotation shaft 61 also in the other side portion is not installed, it is obvious that a rotary support or a bearing having the same function should be installed.

In addition, as shown in the drawings, since the slats 60 are installed in each of the slat rotation shafts 61 connected to the plurality of pinion gears 40, the slats 60 are arranged in a plurality of vertical rows.

Thus, the rack gear 50 is connected to both sides of the plurality of pinion gears 40 spaced apart in the vertical direction, and the rack gear 50 is rotated as shown in FIG. 4A according to the rotation of the pinion gear 40 connected to the drive gear 30. One side (left side in FIG. 3) is raised and the other side (right side in FIG. 3) is lowered and the lower side pinion gear 40 engaged inwardly of the rack gear 50 is rotated in the clockwise direction so that the slat 60 is upward. Direction, and on the contrary, as shown in FIG. 4B, one side (left side in FIG. 3) is lowered and the other side (right side in FIG. 3) is raised and the lower side pinion gear 40 meshed with the inner side of the rack gear 50 is rotated. It rotates counterclockwise while rotating downward. As a result, both rack gears 50 operate in the vertical direction opposite to each other to open and close the slats 60.

Of course, the lower pinion gear 40 is rotated in the clockwise direction while the slat 60 is rotated downward, and may be configured to be rotated upward while being rotated counterclockwise.

As the slat 60 is rotated, the incident amount of sunlight from the outside can be controlled and controlled. As a result, it is possible to obtain noise blocking, shading effects, and privacy intrusion prevention.

The solar multilayer glass system according to the present invention can be configured by installing a drive structure interlocked on both sides of the motor 10 as shown in FIG. If only one side is installed, of course, there is no great force to rotate the slat 60 can be installed on both sides to drive a more stable structure.

In addition, the solar multilayer glass system according to the present invention is composed of one slat 60 in the transverse direction inside the base frame 2, but may be divided into a plurality of slats 60 as shown in FIG. .

Meanwhile, FIGS. 7 to 8B are perspective views and operational state diagrams showing still another example according to the present invention. Looking at the configuration of another embodiment of the solar laminated glass system according to the present invention with reference to the drawings, the worm gear 140 in place of the pinion gear 40 in the lower portion of the drive gear 30 driven by the motor 10 Install and install the worm 150 instead of the rack gear 50 can be configured to be coupled in a worm gear method.

The worm gear method is the same as the driving method of the pinion gear 40 and the rack gear 50. However, in the worm gear system, since the worm 150 connected to both sides in the horizontal direction of the worm gear 140 rotates vertically on the worm shaft 153, the rotation speed is slower than that of the pinion gear 40 and the rack gear 50. . This enables more precise and accurate control.

The upper surface of the slat 60 is attached to form a solar cell 70 for converting sunlight into electricity. The electricity generated through the solar cell 70 is detected by the power generation measurement sensor 72 and transmitted to the motor 10 through the controller 13. That is, it becomes an electric supply source of the motor 13.

Although not shown, the solar cell 70 may be connected to each other in series, in parallel, or in a serial-parallel mixed manner. The connection is configured to be made on both sides or one side of the slat 60 to which the solar cell 70 is attached.

In addition, the electricity generated through the solar cell 70 may be configured to be supplied to a power system such as other electric and electronic devices installed indoors or outdoors around the multilayer glass system. In this case, since the current electrical and electronic equipment and the power system is mainly operated by the alternating current, the inverter 74 for converting the direct current (DC) produced by the solar cell 70 to the alternating current (AC) should be provided.

On the other hand, the rear of the motor 10 provided on the upper side of the base frame 2 is connected to the controller 13 which controls the motor 10 and finally adjusts the angle of the slat 60.

The controller 13 is connected to the motor 10 to receive a signal from the power generation measuring sensor 72 for sensing electricity of the solar cell 70 to control the motor 10 to adjust the rotation angle of the slat 60. .

At this time, the controller 13 receives the signal of the power generation measuring sensor 72, calculates the maximum amount of power generation, and controls the motor 10 in real time to adjust the angle of the slat 60, and also the power generation measuring sensor 72 The angle of the slat 60 may be adjusted by controlling the motor 10 for each time zone by calculating the amount of generation of the maximum value for each time zone in response to the signal.

Continuously operating the motor 10 by the controller 13 can shorten the life of the motor 10, so that the controller 13 calculates the attitude of the solar cell 70 attached to the slat 60 at regular time intervals. Since the motor 10 can be controlled according to time zones with the data, a program is built in the controller 13 so that the solar cell 70 programs the optimal angle for each time zone, season, and installation region. By controlling the angle of the solar cell 70 may be adjusted. In this case, the controller 13 may control the motor 10 without the generation amount measuring sensor 72.

Since the controller 13 and the amount of power generation sensor 72 are configured in a small size, the controller 13 and the power generation sensor 72 may be installed inside the box or the like, but may be installed inside the window frame 5, but if necessary, the window frame 5 including the ground. It can also be installed outside.

In the present invention, the plurality of solar cells 70 is configured to generate electricity by sunlight passing through the glass plate 3, the solar cell 70 only by the management of cleaning the dust and the like on the outside of the glass plate 3 Can easily maintain the power generation efficiency.

On the other hand, the slat 60 of the multilayer glass system according to the present invention has been described to be simultaneously rotationally driven in a batch, it is possible to modify the design so that each of the individual drive through the controller (13). In this case, as an example of the modified design, a plurality of motors 10 may be installed and used, and the connecting means connected to the motor 10 may be modified to be independently driven.

Operation of the solar multilayer glass system according to the present invention having the configuration described above is as follows.

First, as shown in FIGS. 1 and 2, a plurality of slats 60 to which the solar cell 70 is attached to the inside of the base frame 2 are arranged in a constant manner. When the slat 60 is positioned in the vertical direction as shown in the drawings, sunlight does not penetrate into the interior, so that sunlight is absorbed by the solar cell 70 attached to the slat 60 while acting as a shade. Thus, the solar cell 70 converts the absorbed sunlight into electricity to generate electricity, and the generated electricity is sensed by the power generation measuring sensor 72 to operate the slat 60 and the peripheral electrical and electronic equipment. Supply electricity to the power system, including.

The slat 60 is rotated by a program suited to the installation conditions and the user's preferences built in the controller 13 to adjust the amount of incident sunlight, shade function, and also act as a noise blocker. At this time, the program can be selectively used by the user by inputting various numbers desired by the user, and may be set to automatically operate according to the weather or time even if the user does not select any of them.

The slat 60 may be configured to be operated in a manner of manually adjusting the drive gear 30 in addition to a program embedded in the controller 13, and may be operated by a user through a remote control (not shown). It can be configured to adjust the behavior directly semi-automatically.

2: base frame 3: glass plate
5: window frame 10: motor
11: motor shaft 13: controller
20: reducer 30: drive gear
40: pinion gear 50: rack gear
51: support bracket 60: slat
61: slat rotation axis 70: solar cell
72: power generation sensor 74: inverter

Claims (10)

In the solar multilayer glass system provided with a pair of glass plates hermetically spaced apart inside the base frame,
A motor (10) fixed inside the case (7) fixedly installed on the upper side of the base frame (2) to rotate the motor rotating shaft (11);
A reducer 20 fixed inside the case 7 and connected to the front of the motor 10 to adjust the rotational force and the rotational speed of the motor 10;
A drive gear (30) installed at an end of the motor rotating shaft (11) protruding forward of the reducer (20) to transmit a rotational force to the bottom;
A pinion gear 40 installed below the drive gear 30 and rotatably engaged with the gear teeth of the drive gear 30 and spaced apart from each other;
A pair of rack gears 50 which are respectively supported and supported by the support brackets 51 in both vertical directions of the plurality of pinion gears 40, are engaged with gear teeth of the pinion gear 40, and both sides operate vertically in opposite directions. Wow;
A slat (60) coupled to the pinion gear (40) on the slat rotation shaft (61) axially coupled to the inside of the base frame (2) and rotating forward and backward;
A solar cell 70 attached to an upper surface of the slat 60 to generate electricity;
A generation amount measuring sensor 72 installed outside the window frame 5 so as to sense electricity of the solar cell 70;
A controller 13 connected to the rear of the motor 10 to control the motor 10 to adjust the angle of the slat 60;
And an inverter (74) for supplying electricity to a power system installed in the periphery of the multilayer glass system by converting a direct current generated in the solar cell into an alternating current. The method of claim 1,
Solar pinned glass system, characterized in that by installing the worm gear 140 in place of the pinion gear (40), and install a worm (150) instead of the rack gear (50). The method of claim 1,
Solar motor laminated glass system, characterized in that the drive structure of the motor (10) and the slat (60) driven by the motor (10) is installed on both sides of the base frame (2). The method according to claim 1 or 3,
The slat (60) is arranged in a plurality of vertical columns, each of which is independently driven by the controller 13, solar multi-layer glass system. The method according to claim 1 or 3,
The slat (60) is divided into a plurality of lateral direction, the solar laminated glass system, characterized in that each drive independently through the controller (13). delete The method of claim 1,
The controller (13) receives a signal from the power generation measuring sensor (72) to calculate the maximum amount of power generation by controlling the motor (10) in real time to adjust the angle of the slat (60), characterized in that the solar glass system. The method of claim 1,
The controller 13 receives a signal from the power generation measuring sensor 72 and calculates the maximum amount of power generated at each time zone to control the motor 10 at each time zone to adjust the angle of the slat 60. system. The method of claim 1,
The controller 13 is configured to adjust the angle of the solar cell 70 by individually or globally controlling the motor 10 by programming the optimum angle of the solar cell 70 at predetermined time slots, seasons, and installation regions. Photovoltaic multilayer glass system, characterized in that. delete

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