KR20210017118A - Solar module system with improved angle control - Google Patents

Abstract

The present invention relates to a solar module system with an improved angle control function. More particularly, the present invention relates to a solar module system with an improved angle control function which is installed on a roof or outer wall of a building to convert sunlight into electrical energy, but, depending on ventilation of air inside the building or a position of the sun, is provided with an angle control means to control an angle of a solar panel, but minimizes the risk of malfunction and damage during use by improving a structure.

Description

Solar module system with improved angle control}

The present invention relates to a solar module system having an improved angle adjustment function, and more specifically, it is installed on a roof or an outer wall of a building to convert sunlight into electric energy, but the solar energy depends on ventilation of the air inside the building or the location of the sun. The present invention relates to a solar module system with an improved angle adjustment function provided with an angle adjustment means to adjust the angle of the optical panel, but minimizes the risk of malfunction and damage during use by improving the structure.

Solar light is easier to use than other energy sources and can obtain high-efficiency and abundant energy, and power generation devices using the same have been disclosed.

This solar power generation device measures the altitude or azimuth of the sun or tracks sunlight according to a pre-programmed method according to the time the sun moves, collects solar thermal energy through a heat collecting panel, and converts it into electricity. It includes.

Here, the heat collecting panel is for collecting heat energy from sunlight, and a flat plate-shaped panel is used to collect a large amount of heat energy, and is arranged to have a predetermined inclination angle toward the direction of the sun.

Conventional solar power generation devices are installed on the roof or roof of a building or a flat area without topography or a building that generates a shadow around the building. In a photovoltaic power generation device installed on the roof of a building, the solar heat collecting panel is separate on the roof surface. It is integrally fixed and installed through the frame.

Since such a conventional photovoltaic device is integrally fixed to a separate frame, it is difficult to adjust the angle according to the position of the sun.

In addition, the solar heat collecting panel needs to cool the movable heat generated during operation, because the heat collecting efficiency decreases as the temperature of the heat collecting panel increases.

However, there is a problem in that it is difficult to provide a separate cooling means because the space between the heat collecting panel constituting the conventional photovoltaic device and the roof surface is not large.

On the other hand, the conventional solar power generation device is installed on the roof of an existing building, but there is a problem that it is difficult to install in a building where crops are grown, such as a green house, not a general building.

In other words, in the case of a building for growing agricultural crops, it is necessary to open a door or window provided in the building to control the indoor temperature or to ventilate the air.If a solar power generation device is installed on the roof, the roof cannot be opened. There is a disadvantage that the efficiency of control and ventilation is lowered.

In addition, when a large amount of snow falls in winter and accumulates in the photovoltaic device, the weight increases and the roof is damaged.

Korean Patent Registration No. 10-1762795 Korean Patent Registration No. 10-1883757 Korean Patent Registration No. 10-1854452 Republic of Korea Utility Model Registration No. 20-0467825

The present invention has been proposed to solve the above problems, and is installed on the roof of a building for houses or crops, and allows the angle of the solar panel to be adjusted for indoor temperature control or ventilation, and at this time, the solar panel It is an object to provide a solar module system with an improved angle adjustment function that minimizes the risk of malfunction and damage during use by improving the structure of the angle adjustment means for adjusting the angle of the unit.

In order to achieve the above object, the present invention,

A frame that forms a roof frame of a building, and forms a plurality of arrangement spaces by combining a plurality of square pipes to form a grid;

A plurality of photovoltaic panels disposed in the arrangement space of the frame;

Including an angle adjusting means for adjusting the angle of the solar panel,

The angle adjustment means,

A driving motor disposed on the frame and operated by the applied power and signals,

A driving shaft coupled with the driving motor to transmit a driving force and arranged in a direction symmetrical to each other;

A pair of rotation gears respectively disposed at the longitudinal ends of the drive shaft,

A bottom body in which a pair of the photovoltaic panel is disposed at a mutually symmetrical position, has a semicircular shape with an open one side, and has a gear portion engaged with the rotational gear along an inner circumferential surface;

A relay rod disposed on one side of the bottom body and extending in a length direction and having an end coupled to the solar panel;

It characterized in that it comprises a rail rod disposed in a direction opposite to the bottom body with the rotation gear interposed therebetween, and moving in a horizontal direction by rotation of the rotation gear, and one end in the longitudinal direction coupled to the solar panel. do.

In addition, in the bottom body,

It is characterized in that a pair of stoppers protruding from the outer surface toward the outside to limit the rotation angle of the bottom body is further provided.

In addition, in the frame,

With a winding drum,

A wire that is unwound or wound on the winding drum,

It is characterized in that it is provided at the front end of the wire, including a coupling portion detachably coupled to the relay rod or the support bar, and further comprising a level maintaining means for maintaining the position of the angle-adjusted solar panel.

In addition, the solar panel,

It is characterized in that a shielding module is further provided to prevent foreign matters, insects, etc. from entering the interior while the angle is adjusted to a position separated from the frame.

At this time, the shielding module,

The upper end is coupled to the rear edge of the solar panel, and the lower end is characterized by including a porous net coupled to the frame.

The present invention made as described above,

It is installed on the roof of a building for houses or crops, but allows the angle of the solar panel to be adjusted for indoor temperature control or ventilation,

By improving the structure of the angle adjusting means for adjusting the angle of the solar panel, there is an effect of reducing the fear of malfunction and damage during use, extending the service life, thereby reducing the cost required for maintenance.

1 is an exemplary view showing a solar module system with an improved angle adjustment function according to the present invention.
Figure 2 is an exemplary view showing an angle adjustment means according to the present invention.
3 to 5 are exemplary views showing a change in the angle of the solar panel according to the operating state of the angle adjusting means according to the present invention.
Figure 6 is an exemplary view showing a level maintaining means according to the present invention.
Figure 7 is an exemplary view showing a shielding module according to the present invention.

Hereinafter, other objects and features of the present invention in addition to the above objects will be clearly revealed through the description of the embodiments with reference to the accompanying drawings.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related technology, and should not be interpreted as an ideal or excessively formal meaning unless explicitly defined in this application. Does not.

Hereinafter, a preferred embodiment of a solar module system having an improved angle adjustment function according to the present invention will be described with reference to the accompanying drawings.

1 and 2, the solar module system 1 with an improved angle adjustment function according to the present invention includes a frame 10, a solar panel 20, and an angle adjustment means 30 And, it includes a level maintaining means 40 and a shielding module 50.

The frame 10 is formed by interconnecting a plurality of angle pipes, and constitutes a roof frame of a building or is disposed above the roof frame. At this time, when it is disposed on the top of the pre-configured roof frame, it is integrally fixed through a coupling means such as a bolt.

The frame 10 is composed of a metal or synthetic resin material to form a plurality of arrangement spaces 13 so that the solar panel 20 is arranged, and to prevent corrosion due to moisture while supporting the load of the arranged solar panel. It may be, and preferably, it is formed of stainless steel or stainless alloy, which is excellent in durability and heat resistance and does not have a concern for corrosion.

In addition, the frame 10 is composed of a main body 11 constituting a grid-shaped square frame, and a sub-bar 12 disposed to protrude from the main body 11 to one side, the main body 11 Is configured by combining a plurality of angle pipes in a grid shape to form the arrangement space 13, and the sub-bar 12 is disposed to protrude from the main body 11 to one side. The sub-bar 12 is combined with an angle adjusting means 30 to be described later and a battery for storing energy collected from the solar panel 20. Here, the arrangement position and number of the subbars 12 are deformable and are not limited to the illustrated shape.

The solar panel 20 is disposed on the frame 10 to collect sunlight, and a plurality of the solar panels 20 are disposed in the arrangement space 13 formed in the frame 10.

Such a solar panel 20 is known, and is made in the form of a flat plate in order to increase the collection efficiency of sunlight, a plurality of cells are arranged, a cable for transferring the energy collected in each cell, and the cell or panel And a control box equipped with a bypass circuit for checking the operating state of the device.

The angle adjusting means 30 is for adjusting the angle of the solar panel 20, and looking at with reference to the accompanying FIGS. 2 to 5,

A driving motor 31 disposed on the frame 10 and operated by an applied power and a signal,

A driving shaft 32 coupled with the driving motor 31 to transmit a driving force and arranged in a direction symmetrical to each other,

A pair of rotation gears 33 respectively disposed at ends of the drive shaft 32 in the longitudinal direction,

A bottom body 34 in which a pair of the solar panel 20 is disposed at a mutually symmetrical position, has a semicircular shape with one side open, and has a gear unit 341 meshing with the rotation gear 33 along an inner circumferential surface Wow,

A relay rod 35 disposed on one side of the bottom body 34 and extending in the longitudinal direction and having an end coupled to the solar panel 20;

It is disposed in a direction opposite to the bottom body 34 with the rotation gear 33 interposed therebetween, and moves in a horizontal direction by rotation of the rotation gear 33, and one end in the length direction is the solar panel ( It includes a rail rod 36 coupled to 20).

The driving motor 31 is operated by an applied power source and a signal, and is coupled to the frame 10 through a separate bracket (not shown in the drawing). At this time, the driving motor 31 is preferably provided as a two-way motor capable of rotating in a clockwise or counterclockwise direction, but is not limited thereto.

That is, it may be composed of a pair of motors rotating in opposite directions, or may be configured in a form in which a drive shaft of the driving motor is coupled to a gearbox in which a plurality of gears for adjusting the rotation direction are disposed therein.

The drive shaft 32 is for transmitting the rotational force of the drive motor 31, and is made in the form of a rod extending in the longitudinal direction, but the shape and length of the cross-section is adjusted by an installed position or angle adjusting means. It can be changed according to the number of solar panels.

That is, it is preferable that the number of solar panels whose angle is adjusted through one angle adjustment means is one, but it is not necessary to arrange the angle adjustment means for each solar panel and control it after the installation cost and frame 10 Since the load on the photovoltaic panel increases, it is desirable to adjust the angle of a plurality of solar panels through one angle adjustment means, and most preferably, when the length of the solar panel is 1 to 1.2 m, three solar panels It is configured to control the panel through one angle adjusting means.

This, as the number of solar panels increases, the rotational force to be supplied by the angle adjusting means increases, and thus the capacity of the driving motor must be increased, which has disadvantages such as an increase in weight of the driving motor and an increase in power use.

In addition, as described above, when one angle adjusting means is disposed on one solar panel, the capacity of the drive motor is reduced and the weight of the individual drive motor can be reduced, but the angle adjusting means according to the arrangement of the solar panel Since the number of the motors is also increased, there is a problem in that the total load increases, and the power used to drive a plurality of drive motors is also increased.

Meanwhile, an auxiliary cap 321 for maintaining the horizontality of the driving shaft 32 may be further disposed on the driving shaft 32 at regular intervals, and the auxiliary cap 321 is disposed through a separate bracket, and the bracket Is arranged to be movable with one end abutting against a rail rod to be described later.

The rotation gear 33 is disposed at the longitudinal end of the drive shaft 32 and rotates by the rotational force of the drive shaft 32, and a gear part is formed on the outer circumferential surface and a coupling hole in which the drive shaft 32 is coupled Is formed.

The bottom body 34 has a pair of gear units 341 disposed at mutually symmetrical positions on the solar panel 20 and meshing with the rotation gear 33, and has an overall rectangular enclosure shape. It is formed in a semicircular shape opened to the outside on one side of the support, and the gear part 341 is provided on an inner circumferential surface formed in a semicircular shape.

Through this, the bottom body 34 engages with the rotation gear 33 and is inclined according to the rotation of the rotation gear 33.

On the other hand, the outer surface of the bottom body 34 is further provided with a stopper 342 for limiting the inclined angle, the stopper 342 is formed to protrude outward from the outer surface in the direction in which the bottom body 34 is inclined. It is in contact with one surface of the rail rod 36 to be described later to limit the rotation angle of the bottom body 34.

Here, the stopper 342 may be made of a soft synthetic resin material, rubber, or urethane so as not to damage the gear mountain formed on the rail rod 36.

The relay rod 35 is disposed on one side of the bottom body 34 and extends in the longitudinal direction, and its ends are coupled to the solar panel 20, preferably a pair of 90 It is disposed in a position that is spread by ° and both ends are coupled to the solar panel 20, respectively, so that the solar panel can be stably supported. At this time, a support bar 351 connecting the pair of relay rods 35 is further provided to distribute and support the load pressure of the bottom body 34 to prevent damage to the relay rod 35.

The rail rod 36 is disposed so as to be engaged with the rotation gear 33 and is disposed in a direction opposite to the bottom body 34 with the rotation gear 33 interposed therebetween to reduce the rotation of the rotation gear 33 And at the same time move in the horizontal direction when the rotation gear 33 rotates.

The rail rod 36 is formed in the shape of a rectangular parallelepiped extending in the longitudinal direction, and a corresponding gear mountain that meshes with a gear mountain formed in the rotary gear is formed on one surface in contact with the rotary gear 33. At this time, the rail rod 36 is disposed on the upper surface of the sub-bar 12 constituting the frame 10, and is coupled to the surface abutting the sub-bar 12 through a coupling means such as bolting, and is preferably One surface of the rail rod 36 is formed to extend outwardly and wraps the outer surface of the sub-bar 12, and then a caster or a ball bearing is disposed on the inner side of the expanded one surface to ensure stability when moving in the horizontal direction.

On the other hand, a control unit (not shown) for controlling the driving motor 31 of the angle adjusting means 30 is further provided, and the control unit controls the rotational force and rotation direction of the driving motor 31 according to a preset time. And, it is configured to control the rotational force and rotation direction of the drive motor 31 according to the manager's operation by being connected to the manager terminal and the communication module (not shown) by either wired or wireless.

The angle adjusting means 30 made as described above rotates the rotation gear 33 by the drive of the driving motor 31, the angle of the bottom body 34 engaged with the rotation gear 33 is changed, and at the same time the bottom body ( As the angle of the relay rod 35 connecting 34) and the solar panel 20 is changed, the angle of the solar panel 20 is adjusted.

Since the angle adjustment means 30 can adjust the angle of the solar panel 20 according to the spacing formed on the gear mountain where the rotation gear 33 and the bottom body 34 are meshed, the minimum range of the adjustable angle is small. There is an advantage of enabling precise angle adjustment of the optical panel 20. That is, there is an advantage of maintaining high heat collection efficiency by adjusting the angle of the solar panel 20 in real time in a direction that directly looks at the sun according to the movement of the sun.

In addition, indoor air can be ventilated by opening or closing the roof of a building by adjusting the angle of the solar panel 20 through the angle adjusting means 30, and the load increases due to snow accumulation on the surface of the solar panel in winter. In this case, it is possible to prevent damage to the solar panel or frame by weight by adjusting the angle of the solar panel so that the snow moves downward.

On the other hand, the level maintaining means 40 is for maintaining the position of the solar panel 20 at which the angle is adjusted, a winding drum 41 and a wire 42 that is unwound or wound from the winding drum 41 And, it is provided at the front end of the wire 42 and includes a coupling unit 43 that is detachably coupled to the relay rod 35 or the support bar 351.

The winding drum 41 has a wire 42 wound on an outer surface thereof, and is rotatably disposed on the main body 11 or the sub bar 12 of the frame 10.

At this time, the winding drum 41 may be configured to be rotated by a motor (not shown), where the winding drum 41 is freely rotated during the process of unwinding the wire, and rotated by the driving force of the motor when winding. While it can be configured to wind the wire.

The wire 42 is formed by twisting a plurality of steel wires, and is unwound or wound in the winding drum 41.

The coupler 43 is coupled to the front end of the wire 42 and is detachably coupled to the relay rod 35 or the support bar 351.

Such a coupler 43 has an opening 431 with one side open so that it can be coupled while surrounding the outer surface of the relay rod 35 or the support bar 351, and the opening 431 is formed in a direction facing each other to the opening 431. A pair of elastic plates 432 are provided.

That is, after the elastic plate 432 comes into contact with the relay rod 35 or the support bar 351, the opening 431 opens, and then returns to the original position through the elastic restoring force, and the relay rod or It is fixed in contact with the outer surface of the support bar.

At this time, the elastic plate 432 prevents the coupling hole 43 from being separated from the relay rod or the support bar, and a pair is disposed in a direction facing each other in the opening 431, and the front ends face each other. It is formed protruding toward.

The level maintaining means 40 made as described above has a problem in that the solar panel 20 is tilted more than the angle set by the weight when the solar panel 20 is adjusted at an angle that is inclined to the outside of the frame 10. This may occur, and there is an advantage of increasing the stability by maintaining the position of the solar panel 20 through the level maintaining means 40.

In addition, in the present invention, a shielding module 50 for preventing foreign substances, dust, etc. from entering the room from the outside in a state where the solar panel 20 is angled to a position spaced from the frame 10 is further provided. It is equipped.

The shielding module 50 includes a porous net 51 having an upper end coupled to the edge of the solar panel 20 and a lower end coupled to the frame 10.

Here, the porous net 51 is preferably made of a flexible material that can be deformed rather than metal, which is a porous net 51 in a state in which the solar panel 20 is in contact with the frame 10. It is designed to reduce the volume by allowing it to wait in open state.

In addition, the porous net 51 may be connected to the edge of the solar panel 20 by an adhesive or the like, and as another embodiment, a separate finishing material is provided at the upper and lower ends of the porous net 51, and the finishing material is It may be attached to and detached from the solar panel 20 by allowing it to be fastened. This will facilitate replacement of the old or damaged porous net 51.

When the solar panel 20 is angle-adjusted through the porous net 51 made as described above, it is possible to block foreign substances, insects, etc. from entering the interior when the interior and exterior are communicated.

On the other hand, the porous net 51 is another embodiment, consisting of a hollow cylindrical shape extending downward along the circumference of the lower surface of the solar panel 20, disposed along the outer circumferential surface, and formed through a plurality of ventilation It may be configured as a hole (not shown).

As described above, in the present invention, specific matters such as specific components, etc., and limited embodiments and drawings have been described, but this is provided only to help a more general understanding of the present invention, and the present invention is not limited to the above embodiments. , If a person of ordinary skill in the field to which the present invention belongs, various modifications and variations are possible from these descriptions.

Therefore, the spirit of the present invention is limited to the described embodiments and should not be defined, and all things equivalent or equivalent to the claims as well as the claims to be described later belong to the scope of the spirit of the present invention. .

1: Solar module system with improved angle adjustment function
10: frame
11: main body 12: sub bar
13: arrangement space
20: panel
30: angle adjustment means
31: drive motor 32: drive shaft
33: rotating gear 34: bottom body
35: relay rod 36: rail rod
40: level maintenance means
41: winding drum 42: wire
43: coupling
50: shielding module
51: porous net

Claims (1)

A frame (10) forming a roof frame of a building, forming a plurality of arrangement spaces (13) by combining a plurality of square pipes to form a grid;
A plurality of solar panels 20 disposed in the arrangement space 13 of the frame 10;
Including an angle adjusting means 30 for adjusting the angle of the solar panel 20,
The angle adjustment means 30,
A driving motor 31 disposed on the frame 10 and operated by an applied power and a signal,
A driving shaft 32 coupled with the driving motor 31 to transmit a driving force and arranged in a symmetrical direction,
A pair of rotation gears 33 respectively disposed at ends of the drive shaft 32 in the longitudinal direction,
A pair of the photovoltaic panel 20 is arranged in a mutually symmetrical position, one side is made of an open semicircle, and a gear portion 341 is formed along the inner circumferential surface to mesh with the rotating gear 33
The bottom body 34 provided with a pair of stoppers 342 that protrudes from the outer surface toward the outside to limit the rotation angle of the bottom body 34,
A relay rod 35 disposed on one side of the bottom body 34 and extending in the longitudinal direction and having an end coupled to the solar panel 20;
It is disposed in a direction opposite to the bottom body 34 with the rotation gear 33 interposed therebetween, and moves in a horizontal direction by rotation of the rotation gear 33, and one end in the length direction is the solar panel ( Including a rail rod 36 coupled to 20),
In the frame 10,
A winding drum 41,
A wire 42 that is unwound or wound in the winding drum 41,
Maintains the position of the solar panel 20 at which the angle is adjusted, including a fitting 43 provided at the tip of the wire 42 and detachably coupled to the relay rod 35 or the support bar 351 A solar module system with improved angle adjustment function, characterized in that the level maintaining means 40 is further provided.

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