KR20090025724A - Manually slant adjustable typed photo voltaic module support structure - Google Patents

Abstract

A manually slant adjustable photovoltaic module support structure is provided to increase a fixing force and to reduce a construction time by fixing the support using a screw type support. A holder holds and fixes a photovoltaic module on a frame unit. A first step front support(4) distributes the load applied to the holder. An angle adjusting member(5) adjusts a tilt angle of the holder. The frame unit includes a plurality of frames(1) coupled in a transverse or longitudinal direction. The first step support is fixed in the front frame of the holder.

Description

 Manual Slant Adjustable Typed Photo Voltaic Module Support Structure}

The present invention relates to a passive inclination deformable solar cell support structure, in particular, by fixing the solar cell module on the top of the cradle consisting of a plurality of supports that can manually adjust the height and adjust the height of the support according to the solar altitude during the year It relates to a passive solar inclined deformable solar cell module support structure for injecting maximum sunlight into the battery module.

In general, indoor lighting mostly uses electrical energy, which is obtained by using so-called fossil fuels such as petroleum and coal. However, since fossil fuels have a limited amount of use, attention has been paid to systems using solar light as an alternative energy to replace such fossil fuels. In the solar system, a solar house, a photovoltaic generator, or a photovoltaic module is widely used as an alternative energy using the sun, and in recent years, an attempt to use the solar light as an indoor lighting system is also performed in parallel. It is becoming. In other words, the limited space is required to develop new living spaces compared to the rapidly increasing population, and in fact, the construction of buildings in underground or north directions where direct sunlight is impossible is impossible, and these spaces will continue to increase.

Then, referring to FIG. 1, one example of the conventional photovoltaic system as described above, a light collecting plate frame 71 mounted with a plurality of light collecting plates 70 for collecting incident sunlight;

A fixing unit 72 installed at a lower portion of the light collecting plate frame 71 to fix the light collecting plate frame 71;

It consists of an electrical circuit unit 73 for accumulating the solar energy collected through the light collecting plate 70 to supply a set load, for example, indoor lighting or other electrical facilities.

On the other hand, the operation of such a conventional photovoltaic system, when the sunlight is present, the sunlight is incident to the light collecting plate 70 attached to the light collecting plate frame 71 installed at a predetermined inclination angle. Then, the light collecting plate 70 collects the incident sunlight and converts the incident sunlight into electrical energy and outputs it to the electric circuit device 73. In addition, the electric circuit device 73 accumulates solar energy collected through the light collecting plate 70 and supplies it to a set load, for example, indoor lighting or other electric facilities.

However, the conventional solar light system as described above is a fixed support structure in which the support structure produces power while maintaining a constant inclination angle at all times, for example, the fixing device 72 is independent of the altitude angle of the sun. Since the solar cell module, for example, the structure for fixing the light collecting plate frame 71, which is equipped with a plurality of light collecting plate 70, the angle of incidence of the sunlight incident on the light collecting plate is not right angle as the altitude angle of the sun changes throughout the year. There was a limit to increasing power production,

In addition, when the support structure is installed to maintain the angle of inclination so that the angle of incidence is automatically close to the right angle according to the altitude angle of the sun, such a support structure has a problem that it is difficult to maintain a high cost of production.

Furthermore, the conventional solar light system as described above requires a heavy concrete foundation because the anchoring bolt is inserted into the concrete foundation for fixing the solar cell module support structure. Therefore, a lot of environmental pollution and concrete curing are required. There was a problem that time was needed.

Accordingly, the present invention has been invented to solve the above problems, and it is possible to manually vary the inclination of the cradle for placing the solar cell module to change the angle of incidence of the solar light into the solar cell module according to the change of the solar elevation angle. By being close to the right angle, the purpose is to provide a passive solar inclined solar cell module support structure to increase the power output.

Another object of the present invention is to distribute the load of the support structure to the front support and the rear support of the support of the solar cell module, it is easy to manufacture the support structure of the solar cell module having the necessary load, and do not use concrete foundation It is to provide a passive solar inclined solar cell module supporting structure that can shorten the construction period at low cost while minimizing environmental pollution.

The present invention for achieving the above object is a cradle for fixing a plurality of rod-shaped frame horizontally and vertically to each other to form a frame frame and then fixed to the solar cell module thereon; A first stage front supporter coupled to one side of the frames of the front end portion of the cradle to distribute the load applied to the cradle; It is installed on the rear end of the cradle provides a passive solar inclination deformable solar cell module support structure comprising a variable flow member for variablely adjusting the inclination angle of the cradle.

As described above, the present invention may increase the amount of photovoltaic power generated by the inclined cradle of the passive inclined deformable solar cell support structure, thereby concentrating more incident sunlight, and supporting structure with a screw-type support. By fixing the structure, the construction period is shortened and the fixing force of the ground is increased.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The bolt holes of the second stage rear support for connecting with the third stage rear support can be variously inclined so that the inclination of the solar cell module cradle can be varied. do.

When the third stage rear support is connected to the upper bolt of the second stage rear support, the second stage rear support may be in the form of a triangle in consideration of the sharing of load, but in the present invention, the second support is formed at right angles.

When the third stage rear support is connected to the upper bolt of the second stage rear support, the second stage rear support may have a constant inclination angle with the ground in consideration of the sharing of load, but in the present invention, the second support is perpendicular to the ground.

The front support and the three-stage rear support and the solar cell module holder of the support structure may be connected in a form other than a pin such as a bearing so as to be rotatable, but in the present invention, it is connected in the form of a pin.

The support structure of the present invention, as shown in Figures 2 to 4, for example, by combining a plurality of rod-shaped frame (1) horizontally and vertically with each other by welding or other attachment method to form a frame thereon A cradle (3) for fixing the battery module (2);

A first stage front support (4) coupled to one side of the front end frames (1) of the cradle (3) to distribute the load applied to the cradle (3);

It is installed to the rear end of the cradle 3 is configured to include a variable flow member (5) for variablely adjusting the inclination angle of the cradle (3).

In addition, the variable flow member (5) has a screw member (6) is formed at the end of the body and the first stage rear support (7) embedded in the ground;

It is firmly fixed through the first stage rear support 7 and the fixed coupling member 8 and the body is opened on only one side thereof to form an insertion space 9 therein (for example, when viewed in cross-section, approximately “c” shaped). ), A two-stage rear support (11) formed with screwing grooves (10a-c) at a predetermined interval in the longitudinal direction on the body;

Inserted into the insertion space (9) of the second stage rear support 11 is screwed into the screwing groove (10a-c) of the second stage rear support 11 through the screw fastening hole 12 formed in the end of the body The second pivot ring 13 and the coupling pin member 14 formed on the frame 1 of the cradle 3 at another end of the body are coupled to each other so that the cradle 3 rotates up and down when the cradle 3 flows. It is configured to include a three-stage rear support (16) provided with two swing storage unit (15).

In addition, the first stage support (4) is coupled to the upper end of the body through the first pivot ring 17 and the coupling pin member 18 formed on the frame (1) of the holder (3), the holder (3) flows In this case, the first pivotal storage unit 19 is installed to rotate up and down, and a screw member 20 is installed at the lower end of the body to bury a part of the body in the ground.

Here, the first stage With anterior supports (4)  1 stage Of rear support (7) At the end Screw members 6 and 20  Although described as being installed, other of the present invention As an example  In front of the first stage With support (4)  1 stage Of rear support (7) At the end Anchor bolt  Installed underground With concrete  Can be buried.

In other words, the first stage front support 4 is integrally divided into a portion inserted into the ground and a portion exposed to the ground, and the variable flow member 5 is inclined with the first stage rear support 7 inserted into the ground. Consists of a two-stage rear support 11 and a three-stage rear support 16 for the variable.

Here, the second stage rear support 11 is fastened with the third stage rear support 16 by varying the position of the screw fastening grooves 10a-c in order to vary the inclination of the solar cell module holder 3. At this time, the position of the screw fastening groove (10a-c) is determined according to the position of the length and the inclination angle of the three-stage rear support (16), the lower end of the screw fastening groove (10a) of the lower second support 11 Screw fastening hole 12 of the three-stage rear support 16 is fastened through the screw 21, and in the spring and autumn, three-stage rear support 16 is provided in the screw fastening groove 10b of the center of the two-stage rear support 11. Screw fastening hole (12) of the screw is fastened through the screw 21, the screw fastening hole (12) of the third stage rear support (16) in the screw fastening groove (10c) of the upper stage of the second stage rear support (11) This screw 21 is fastened.

That is, the three-stage rear support 16 is screwed into the screw fastening grooves 10a-n formed in plural with a predetermined interval in the insertion space 9 of the two-stage rear support 11, respectively. In the fastening manner, the inclination angle of the holder 3 is adjusted based on the eclipse of the changing sun, for example, the vernal equinox, the autumn equinox, the lower limb and the winter solstice.

Here, the material of the frame 1 of the holder 3 may be made of any one of steel or aluminum, plastic or urethane or wood.

On the other hand, when explaining the assembly state of the present invention as described above, as shown in Figures 1 to 4, the passive inclination-deformable solar cell module support structure of the present invention is fixedly installed in the ground. That is, the solar cell module 2 is mounted on the cradle (3). At this time, a plurality of first stage front supports (4) and one stage rear supports (7) are installed at a place where the solar cell module support structure is to be installed. The screw members 6 and 20 respectively formed at the end of the body are firmly embedded in the ground. Then, the first front support (4) is coupled to the first pivot ring (17) formed in the frame (1) of the cradle (3) the first pivot housing (19). In addition, the plurality of first stage rear supports 7 firmly fix the plurality of two stage rear supports 11 corresponding thereto through the fixing member 8.

Then, the plurality of fixed two-stage rear support (11) as described above slides the corresponding plurality of three-stage rear support (16) into the insertion space (9) and then screw the two-stage rear support (11) The grooves 10a-c and the screw fastening holes 12 of the third stage rear support 16 are matched with each other, and then the screws 21 are firmly fastened. At this time, the screwing height of the second stage rear support 11 and the third stage rear support 16 is set based on the inclination angle of the cradle 3, for example, the ecliptic, the autumn equinox, the lower limb and the winter solstice. do.

On the other hand, when the two-stage rear support 11 and the three-stage rear support 16 are combined through the above process, the plurality of three-stage rear support 16 is the second pivotal storage unit 15 formed at the upper end of the body. In combination with each of the second turning ring 13 corresponding to that formed in the frame (1) of the holder (3) in the groove of the inclined angle of the holder (3) is installed to be rotated up and down.

That is, the first and second pivot supports 16 and 16 are provided in the groove portions of the first and second pivotal receptacles 15 and 19, as shown in FIGS. Since the pivot pins 13 and 17 are inserted and then the coupling pin members 14 and 18 are inserted and fixed, the inclination angle of the holder 3 fixed to the first and second pivot rings 13 and 17 is changed. The first and second pivots 13 and 17 are rotated in the grooves of the first and second pivotal receivers 15 and 19 via the coupling pin members 14 and 18. Done.

Where3-stage Rear support (16) 2-stage Of rear support (11) When connected to the upper screw or bolt, two-stage considering load sharing The rear support (11) It may be in the form of a triangle, but in the present invention is a right angle.

In addition, the third stage Rear support (16)  2-stage Of rear support (11)  When connected to the upper bolt, two stages considering load sharing The rear support (11)  It can be installed to have a constant inclination angle with the ground, in the present invention to be perpendicular to the ground.

And, the first stage With anterior supports (4)  3-stage Of rear support (16)  When connecting the upper part with the solar cell module holder (3) of the support structure, To allow rotation Pin member  or Bearing member furnace  Can connect

Next will be described in more detail the operation of the embodiment of the present invention having the configuration as described above.

First, the manual inclined deformable solar cell module support structure of the present invention, as shown in Figures 5 to 7 to select the appropriate place to receive the most sunlight and then the first stage support (4) and the first stage rear support ( 7) is fixed to the ground through the screw members (6, 20) formed at its ends. Then, the second stage rear support 11 is coupled to the first stage rear support 7, and then the screw fastening groove 10a to vary the inclination of the solar cell module holder 3 to the coupled second stage rear support 11. -c) to combine the three stage rear support 16 by changing the position.

At this time, the position of the screw fastening groove (10a-c) of the second stage rear support 11 is determined according to the position of the length and the inclination angle of the three stage rear support 16, the lower stage of the second stage rear support (11) The screw fastening hole 12 of the three stage rear support 16 is fastened to the screw fastening groove 10a of the three stages, and the three stage rear support is fastened to the screw fastening groove 10b of the center of the two stage rear support 11 at the spring and autumn. The screw fastening hole 12 of (16) is fastened, and the screw fastening hole 12 of the third stage rear support 16 is screwed into the screw fastening groove 10c of the upper stage of the second stage rear support 11 through the screw. Tighten.

Accordingly, the first and second pivot rings 13 and 17 installed on the first stage front support 4 and the third stage rear support 16 are first and second as shown in FIGS. 5 to 6. The cradle (3) fixed to the first and second swing rings (13, 17) is inserted into the groove of the swing storage (15, 19) and then inserted and fixed through the coupling pin members (14,18). The first and second pivot rings 13 and 17 are formed by the first and second pivot hooks 15 and 19 through the coupling pin members 14 and 18. Will rotate within the groove of the.

Therefore, the position of the screw fastening grooves 10a-c of the two-stage rear support 11 is manually changed in accordance with the state in which sunlight is incident on the screw fastening hole 12 of the three-stage rear support 16 as described above. Since the inclination angle of the holder (3) in which the solar cell module (2) is placed is adjusted so as to condense more solar light incident on the solar cell module (2), the amount of photovoltaic power generation can be increased accordingly. Fixing the supporting structure with screw type supports shortens the construction period and increases the fixing force of the ground.

Meanwhile, of the present invention Other As an example  Installed in the front end of the cradle (3) by varying the inclination angle of the cradle (3) Fixed  A variable flow member 5;

Of the rear end frames 1 of the holder 3 On one side  At regular intervals Combined  holder( 3) to  It can be configured to include a first stage support (4) to distribute the load applied.

Thus, as described above of the present invention Other Example  When used, by adjusting the inclination angle of the front portion of the cradle (3) through the variable flow member (5) Solar  Angle of incidence Will be adjusted .

The passive tilting deformable solar cell module support structure of the present invention can be easily used as a variable fixing means in the field of photovoltaic power generation equipment that obtains electrical energy from sunlight.

1 is an explanatory diagram illustrating an example of a conventional photovoltaic power generation system.

Figure 2 is an explanatory view illustrating a passive slope modified solar cell module support structure of the present invention.

3 is an explanatory view illustrating a state schematically viewed from the side of the structure of the present invention.

4 is an explanatory view for explaining a state schematically viewed from the front of the structure of the present invention.

5 is an explanatory view illustrating the first stage support of the structure of the present invention.

Figure 6 is an explanatory diagram illustrating a three-stage rear support of the present invention structure.

Figure 7 is an explanatory view illustrating a state of adjusting the inclination angle of the cradle of the present invention structure.

*** Explanation of symbols for important parts of drawing ***

1 frame 2 solar cell module

3: cradle 4: 1 step front support

5 variable flow member 6 screw member

7: 1st stage rear support 8: Fixed coupling member

9: Insertion space 10a-c: Screw tightening groove

11: 2-stage rear support 12: Screw fastener

13: 1st pivot ring 14: coupling pin member

15: first turntable 16: three-stage rear support

17: second pivot ring 18: coupling pin member

19: second pivotal storage portion 20: screw member

21: screw

Claims (7)

A cradle for fixing a plurality of rod-shaped frames horizontally and vertically to form a frame and then fixedly mounting the solar cell module thereon; A first stage front supporter coupled to one side of the frames of the front end portion of the cradle to distribute the load applied to the cradle; Manual tilting deformable solar cell module supporting structure, characterized in that it comprises a variable flow member is installed on the rear end of the cradle variable to adjust the inclination angle of the cradle fixed. According to claim 1, wherein the first front support is provided with a first pivotal storage unit is coupled to the first pivot ring formed in the frame of the cradle at the upper end of the body to rotate up and down when the cradle flows, Manual tilting deformable solar cell module supporting structure, characterized in that the lower portion is provided with a screw member for fixing a part of the body buried in the ground. The variable flow member of claim 1, wherein the variable flow member has a screw member formed at the end of the body and includes a first stage rear support embedded in the ground; A two-stage rear support that is firmly fixed through the first stage rear support and the fixed coupling member, and has only one side of the body opened to form an insertion space therein, and a screw coupling groove is formed at a predetermined interval in the longitudinal direction on the body; Inserted into the insertion space of the second stage rear support is screwed into the screw fastening groove of the second stage rear support through a screw fastening hole formed in the end of the body, and the second pivot ring formed in the frame of the mount on the other end of the body and Manual tilting deformable solar cell module supporting structure, characterized in that it comprises a three-stage rear support is installed, the second pivotal storage unit to be rotated up and down when the cradle is coupled to flow. The method of claim 1, wherein the two-stage rear support is a manual slope deformable solar cell module supporting structure, characterized in that fastening with the three-stage rear support by varying the position of the screw fastening groove to vary the inclination of the solar cell module holder. The position of the screw fastening groove of the second stage rear support is to fasten the screw fastening holes of the third stage rear support to the screw fastening groove of the lower stage of the second stage rear support when the solar season is the lower season, In the case of spring and autumn, fasten the screw fastening hole of the three-stage rear support to the screw fastening groove in the middle of the two-stage rear support. If the solar season is winter, Manual tilting deformable solar cell module support structure, characterized in that for fastening the screw fastening. The structure of claim 1, wherein the frame of the cradle is made of steel. The structure of claim 1, wherein the frame of the cradle is made of plastic.

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