KR102297188B1 - Adhesive solar panel system - Google Patents

Abstract

The present invention provides a shoulder mounted solar panel system comprising: a solar panel; A solar panel communicating with the solar panel and transmitting a control signal for adjusting the angle of the solar panel to maximize the amount of sunlight irradiated to the solar panel according to the amount of sunlight irradiated to the solar panel server; A panel support formed in the shape of a square plate, a plurality of solar panels are spaced apart on the top; a central support located at the center of the lower end of the panel support, provided with a hydraulic cylinder capable of lifting or lowering therein, and ascending or descending according to the control signal transmitted from the solar panel server; and a lower support located at both lower ends of the panel support, provided with a hydraulic cylinder capable of lifting or lowering therein, and ascending or descending according to the control signal transmitted from the solar panel server.

Description

Adhesive solar panel system

The present invention relates to a shoulder mounted solar panel system.

In general, photovoltaic power generation using photovoltaic panels uses unlimited, pollution-free solar energy, so fuel costs are unnecessary, there is no air pollution or waste generation, and the power generation part is a semiconductor device, and the control unit is an electronic component, so There is no vibration and noise.

In addition, the solar panel has a long lifespan of at least 20 years, it is easy to automate the power generation system, and it has the advantages of minimizing the cost due to operation and maintenance.

The solar panel used for photovoltaic power generation serves to convert sunlight into electrical energy as described above, and generally silicon and composite materials are mainly used.

On the other hand, solar cells have a change in power generation efficiency according to the angle of sunlight, but since most solar panels are of a fixed type, they cannot cope with the angle of sunlight according to the four seasons, so there is a problem that the power generation efficiency is lowered.

An object of the present invention is to provide a shoulder-mounted solar panel system capable of adjusting the angle of the solar panel to maximize the amount of sunlight irradiated to the solar panel according to the amount of sunlight irradiated to the solar panel.

The technical problems of the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the following description.

The shoulder-mounted solar panel system according to an embodiment of the present invention may include a solar panel.

The shoulder-mounted solar panel system according to an embodiment of the present invention communicates with the solar panel and maximizes the amount of sunlight irradiated to the solar panel according to the amount of sunlight irradiated to the solar panel. A solar panel server that transmits a control signal for adjusting the angle of the solar panel; A panel support formed in the shape of a square plate, a plurality of solar panels are spaced apart on the top; a central support located at the center of the lower end of the panel support, provided with a hydraulic cylinder capable of lifting or lowering therein, and ascending or descending according to the control signal transmitted from the solar panel server; and a lower support located at both lower ends of the panel support and having a hydraulic cylinder capable of lifting or lowering therein, so that the lower support is raised or lowered by the control signal transmitted from the solar panel server.

According to an embodiment, the solar panel server includes: a second transceiver for transmitting the control signal for controlling the lifting or lowering of the hydraulic cylinder located inside the central support and the lower support, respectively; In accordance with the case of controlling the inclination angle of the panel support according to the amount of sunlight irradiated to the solar panel, the elevation angle of the panel support by differentiating the elevation or descending height of the central support and the elevation or descending height of the lower support. an inclination angle control unit generating a signal to control the ; In accordance with the case of controlling the height of the panel support according to the amount of sunlight irradiated to the solar panel, the elevation or descending height of the central support and the ascending or descending height of the lower support are equal to the height of the panel support. a height control unit for generating a signal for controlling the height; and a signal for controlling the height generated by the height control unit controlling the elevation or lowering of the panel support according to the amount of sunlight irradiated to the solar panel for each season or time zone, and the inclination angle control unit for adjusting the inclination angle of the panel support Controls the inclination angle control unit and the height control unit to accumulate and store signals for controlling the inclination angle generated in and a second data management unit.

According to an embodiment, the central support may be raised or lowered by the control signal transmitted from the solar panel server to change the inclination angle of the panel support or to change the height of the panel support.

According to an embodiment, the lower support may be raised or lowered by the control signal transmitted from the solar panel server to change the inclination angle of the panel support or to change the height of the panel support.

According to an embodiment, the lower support may include an outer forming part that is installed from the ground and is installed with a variable overall length.

According to one embodiment, the outer forming portion, a cross section is formed vertically long while forming the shape of a rectangular bar (BAR), the outer surface is formed in a round shape, the central support bar is formed with an inner space in the longitudinal direction; a length forming part inserted and coupled to the center of the central support bar from the upper part of the central support bar; and a length forming part frame that is fitted to the upper part of the central support bar so as to be lifted and lowered.

According to an embodiment, the length forming part may be fitted into the inner space of the length forming part frame.

According to an embodiment, the length forming part may be inserted so that a part of it can be lifted up and down in an inner space formed in the center of the central support bar.

According to an embodiment, the length forming part is inserted into the inner space formed in the center of the central support bar and includes a second helical part having a screw thread formed along the outer surface, and rotates in a state inserted into the inner space. Thus, the screw thread of the second helical part may be lifted and lowered by the force fitted to the inner circumferential surface of the inner space.

According to an embodiment, the central support bar may be formed with a first helical part symmetrical to the thread of the second helical part on the inner circumferential surface of the inner space.

According to an embodiment, the length forming part may include a rotating part which is formed on the upper side of the second spiral part and is inserted into the inner space of the central support bar to rotate.

According to an embodiment, the length forming part is further formed with a fastening protrusion rotatably fitted into a fastening groove formed in the center of the length forming part frame on the upper side of the rotating part, and the fastening protrusion is the length forming part When it is fitted into the fastening groove formed in the center of the frame, a height at which the length forming part frame is coupled to the upper portion of the central support bar may be determined.

The photovoltaic system installed in the blind according to an embodiment of the present invention may include a photovoltaic panel.

In the solar system installed in the blind according to an embodiment of the present invention, the solar panel is provided at the upper end, and the inclination angle and the direction of the inclination are adjusted. blind part; and a manager terminal for controlling the elevating or lowering of the blind unit.

According to an embodiment, the manager terminal includes: a blind server for controlling the elevating line to adjust the elevating, lowering, inclination angle and the inclination direction of the blind unit; and a solar panel server.

According to an embodiment, the blind server includes: a first transceiver for transmitting a signal for controlling the lifting line located at both ends of the blind unit; a first signal generator for generating a first signal for adjusting the elevation or descent of the blind unit to correspond to the position of the sun according to the amount of sunlight irradiated to the solar panel; a second signal generator for generating a second signal for adjusting the inclination angle or direction of the inclination of the blind unit to correspond to the position of the sun according to the amount of sunlight irradiated to the solar panel; And by accumulating the first signal for adjusting the elevation or lowering of the blind unit according to the amount of sunlight irradiated to the solar panel for each season or time zone and the second signal for adjusting the inclination angle or inclination direction of the blind unit First data for controlling the first signal generating unit and the second signal generating unit to generate a signal for controlling the rising, falling, tilting angle or tilting direction of the blind unit according to a season or a time zone according to the stored data management unit; may include.

According to an embodiment, the solar panel is arranged in a plurality of spaced apart at the upper end of the panel support formed in the shape of a square plate, located at the lower ends of both sides of the panel support, there is a hydraulic cylinder capable of lifting or lowering therein It is provided and may include a lower support for lifting or lowering according to the control signal transmitted from the solar panel server.

According to an embodiment, the lower support may include an outer forming part that is installed from the ground and is installed with a variable overall length.

According to one embodiment, the outer forming portion, a cross section is formed vertically long while forming the shape of a rectangular bar (BAR), the outer surface is formed in a round shape, the central support bar is formed with an inner space in the longitudinal direction; a length forming part inserted and coupled to the center of the central support bar from the upper part of the central support bar; and a length forming part frame that is fitted to the upper part of the central support bar so as to be lifted and lowered.

According to an embodiment, the length forming part may be fitted into the inner space of the length forming part frame.

According to an embodiment, the length forming part may be inserted so that a part of it can be lifted up and down in an inner space formed in the center of the central support bar.

According to an embodiment, the length forming part is inserted into the inner space formed in the center of the central support bar and includes a second helical part having a screw thread formed along the outer surface, and rotates in a state inserted into the inner space. Thus, the screw thread of the second helical part may be lifted and lowered by the force fitted to the inner circumferential surface of the inner space.

According to an embodiment, the central support bar may be formed with a first helical part symmetrical to the thread of the second helical part on the inner circumferential surface of the inner space.

According to an embodiment, the length forming part may include a rotating part which is formed on the upper side of the second spiral part and is inserted into the inner space of the central support bar to rotate.

According to an embodiment, the length forming part is further formed with a fastening protrusion rotatably fitted into a fastening groove formed in the center of the length forming part frame on the upper side of the rotating part, and the fastening protrusion is the length forming part When it is fitted into the fastening groove formed in the center of the frame, a height at which the length forming part frame is coupled to the upper portion of the central support bar may be determined.

According to one aspect of the present invention described above, the shoulder mounted solar panel system proposed by the present invention is the angle of the solar panel to maximize the amount of sunlight irradiated to the solar panel according to the amount of sunlight irradiated to the solar panel can be adjusted.

The effects of the present invention are not limited to the above-mentioned effects, and various effects may be included within the range apparent to those skilled in the art from the description below.

1 is a view showing a schematic configuration of a solar system installed in a blind according to an embodiment of the present invention.
2 to 6 is a view showing a specific configuration of the solar system installed in the blind according to an embodiment of the present invention.
7 to 10 are views showing the configuration of a solar system installed in a blind according to another embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0010] DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0010] DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0023] Reference is made to the accompanying drawings, which show by way of illustration specific embodiments in which the present invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the present invention. It should be understood that the various embodiments of the present invention are different but need not be mutually exclusive. For example, certain shapes, structures, and characteristics described herein with respect to one embodiment may be implemented in other embodiments without departing from the spirit and scope of the invention.

When a component is referred to as being “connected” or “fastened” to another component, it may be directly connected or engaged with the other component, but it is understood that other components may exist in between. it should be On the other hand, when it is mentioned that a certain element is "directly connected" or "directly fastened" to another element, it should be understood that the other element does not exist in the middle.

In addition, it should be understood that the location or arrangement of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the present invention. Accordingly, the detailed description set forth below is not intended to be taken in a limiting sense, and the scope of the invention, if properly described, is limited only by the appended claims, along with all scope equivalents to those claimed. Like reference numerals in the drawings refer to the same or similar functions throughout the various aspects.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the drawings.

1 is a view showing a schematic configuration of a solar system installed in a blind according to an embodiment of the present invention.

Referring to FIG. 1 , a solar system 10 installed in a blind according to an embodiment of the present invention may include a solar panel 150 , a blind unit 100 , and a manager terminal 300 .

The blind unit 100 may be provided with a solar panel 150 at an upper end, and may be raised or lowered by the elevating line 110 provided penetrating at both ends, or the angle of inclination and the direction of inclination may be adjusted.

The manager terminal 300 may control the raising or lowering of the blind unit 100 , thereby maximizing the amount of sunlight irradiated to the solar panel 150 located at the upper end of the blind unit 100 .

2 to 6 , the solar system 10 installed in the blind according to an embodiment of the present invention is a lifting line 110 to adjust the lifting, lowering, inclination angle and direction of the inclination of the blind unit 100 . ) may include a blind server 310 and a solar panel server 390 to control.

A plurality of solar panels 550 may be spaced apart from each other at the top of the panel support 510 formed in the shape of a square plate.

It is located at the lower ends of both sides of the panel support 510, and is provided with a hydraulic cylinder capable of lifting or lowering inside, so that the lower supports 530 and 570 that are raised or lowered by the control signal transmitted from the solar panel server 390 are provided. may be available.

In addition, it is located in the center of the lower end of the panel support 510, and is provided with a hydraulic cylinder capable of lifting or lowering therein. may be available.

The central support 590 is raised or lowered by a control signal transmitted from the solar panel server 390 , and the inclination angle of the panel support 510 may be changed or the height of the panel support 510 may be changed.

The lower supports 530 and 570 may be raised or lowered by a control signal transmitted from the solar panel server 390 to change the inclination angle of the panel support 510 or to change the height of the panel support 510 .

The blind server 310 may include a first transceiver 311 , a first signal generator 313 , a second signal generator 315 , and a first data manager 317 .

The first transceiver 311 may transmit a signal for controlling the lifting line 110 located at both ends of the blind unit 100 .

The first signal generating unit 313 generates a first signal for controlling the elevation or descent of the blind unit 100 so as to correspond to the position of the sun according to the amount of sunlight irradiated to the solar panel 150, so that the blind unit ( 100), it is possible to maximize the amount of sunlight irradiated to the solar panel 150 located on the top.

The second signal generating unit 315 generates a second signal for adjusting the inclination angle or direction of the inclination of the blind unit 100 to correspond to the position of the sun according to the amount of sunlight irradiated to the solar panel 150, The amount of sunlight irradiated to the solar panel 150 located on the upper end of the blind unit 100 can be maximized.

The first data management unit 317 includes a first signal that adjusts the elevation or descent of the blind unit 100 according to the amount of sunlight irradiated to the solar panel 150 for each season or time zone, and an angle or direction of inclination of the blind unit. It is possible to accumulate and store the second signal adjusted by .

In addition, the first data management unit 317 is a first signal generating unit 313 to generate a signal for controlling the raising/lowering, tilting angle or tilting direction of the blind unit 100 according to the season or time zone according to the stored data. and the second signal generator 315 may be controlled.

Accordingly, the first data management unit 317 controls the lifting line 110 located at both ends of the blind unit 100 according to the season and time even if the amount of sunlight irradiated to the solar panel 150 is not directly transmitted. The first signal generator 313 and the second signal generator 315 may be controlled to generate a signal.

The solar panel server 390 communicates with the solar panel and transmits a control signal for adjusting the angle of the solar panel to maximize the amount of sunlight irradiated to the solar panel according to the amount of sunlight irradiated to the solar panel can do.

The solar panel server 390 may include a second transceiver 391 , an inclination angle control unit 393 , a height control unit 395 , and a second data management unit 397 .

The second transceiver 391 may transmit a control signal for controlling the lifting or lowering of the hydraulic cylinders respectively located inside the central support 590 and the lower support 530 and 570 .

The inclination angle control unit 393 adjusts the elevation or descending height of the central support 590 and the lower support 530 in accordance with the case of controlling the inclination angle of the panel support 510 according to the amount of sunlight irradiated to the solar panel 550. A signal for controlling the inclination angle of the panel support 510 may be generated by varying the height of the 570 ).

The height control unit 395 adjusts the height of the central support 590 to ascend or descend according to the case of controlling the height of the panel support 510 according to the amount of sunlight irradiated to the solar panel 550 and the lower support 530, A signal for controlling the height of the panel support 510 may be generated by making the height of the 570) the same as the ascending or descending height.

The second data management unit 397 controls the height generated by the height control unit 395 that adjusts the elevation or descent of the panel support 510 according to the amount of sunlight irradiated to the solar panel 550 for each season or time zone. Signals and signals for controlling the inclination angle generated by the inclination angle control unit 393 that have adjusted the inclination angle of the panel support 510 may be accumulated and stored.

In addition, the second data management unit 397 generates a signal for controlling the elevation, descent, and inclination angles of the panel support 510 according to the season or time according to the stored signal data, the inclination angle control unit 393 and the height control unit 395 ) can be controlled.

A blind server and a solar panel server are not mediums that store data for a short period of time, such as registers, caches, and memories, but semi-permanently store data, and mean a medium that can be read by a device. Specifically, examples of the storage medium include, but are not limited to, ROM, RAM, CD-ROM, magnetic tape, floppy disk, optical data storage device, and the like. That is, the blind server and the solar panel server may be stored in various recording media on various servers that the computer can access or in various recording media on the user's computer. In addition, the medium may be distributed in a network-connected computer system, and computer-readable codes may be stored in a distributed manner.

The steps of a method or algorithm described in relation to an embodiment of the present invention may be implemented directly in hardware, as a software module executed by hardware, or by a combination thereof. A software module may contain random access memory (RAM), read only memory (ROM), erasable programmable ROM (EPROM), electrically erasable programmable ROM (EEPROM), flash memory, hard disk, removable disk, CD-ROM, or It may reside in any type of computer-readable recording medium well known in the art to which the present invention pertains.

7 to 10 are views showing the configuration of the solar system installed in the blind according to another embodiment of the present invention.

Referring to FIGS. 7 and 8 , it can be seen that the installation state diagrams of the lower supports 530 and 570 having an outer forming part capable of length adjustment according to another embodiment of the present invention are shown.

The lower supports 530 and 570 having an outer forming part that can be adjusted in length according to another embodiment of the present invention may be installed to support the panel support 550 and the like for supporting the solar panel located at the upper end.

These lower supports 530 and 570 may be provided with a panel support 550 at the upper end of the outer forming parts 532 that are typically installed from the ground.

The outer forming part 532 is installed with a variable overall length between the floor and the ceiling. 536) may be included.

The outer forming portion 532 of the lower supports 530 and 570 having an outer forming portion 532 capable of length adjustment according to another embodiment of the present invention includes the central support bar 534 and the length forming portion 535 and the length. The forming part frame 536 may be a basic configuration (

The lower portion of the length forming portion 535 may be inserted into and coupled to the center of the central support bar 534 from the upper portion of the central support bar 534 , and the combined length forming portion 535 is inserted into the center of the central support bar 534 . may be fitted in the inner space of the length forming part frame 536 , and the length forming part frame 536 may be fitted to the upper part of the central support bar 534 so as to be liftable.

The specific configuration and coupling relationship of the central support bar 534 , the length forming part 535 , and the length forming part frame 536 may be described later in detail.

First, the central support bar 534 may be formed to be vertically long while forming an approximate cross-section of a rectangular bar (BAR), and each outer surface 5341 is preferably formed in a round shape, and in the center of the upper part An inner space (A) may be formed in the longitudinal direction.

The length forming part 535 is inserted so as to be elevating in the inner space (A) formed in the center of the central support bar (534), and the height of the central support bar (534) protruding upward can be adjusted. It consists of a spiral part (535a) and a rotating part (535b).

The second helical portion 535a is a portion to be inserted into the inner space A formed in the center of the central support bar 534, and a thread is formed on the outer periphery to insert the second helical portion 535a into the inner space (A). When the length forming part 535 is rotated in one state, the length forming part 535 can be raised and lowered along the screw thread by the force of the screw thread of the second helical part 535a being fitted to the inner circumferential surface of the inner space (A). have.

On the other hand, the inner peripheral surface of the inner space (A) of the central support bar (534) can also form a first spiral portion (534a) symmetrical with the thread of the second spiral portion (535a).

That is, if the first helical portion 534a is formed on the inner circumferential surface of the inner space A, when the length forming portion 535 is inserted and rotated inside the inner space A, the first of the inner space A The screw threads of the helical part 534a and the second helical part 535a can be engaged, so when the length forming part 535 is inserted into the inner space (A) of the central support bar 534, the central support bar 534. The combination of the length forming part 535 and the length forming part 535 becomes solid, and when the length forming part 535 is rotated to elevate, it may be guided by the first spiral forming part 534a of the inner space (A).

The rotating part 535b is formed on the upper side of the second helical part 535a and is a part for rotating the length forming part 535 inserted into the inner space A of the central support bar 534, and various shapes may be used. , as an example, if the hexagonal bolt head is formed, the rotating unit 535b can be easily rotated using a rotating tool such as a spanner or a grip unit (not shown).

On the other hand, the length forming part 535 has a fastening protrusion 537a to be rotatably fitted in the fastening groove 538 formed in the center of the length forming part frame 536 on the upper side of the rotating part 535b. When the fastening protrusion 537a is fitted into the fastening groove 538 formed in the center of the length forming part frame 536 , the length forming part frame 536 is coupled to the upper part of the central support bar 534 . can be determined.

In addition, the length forming part 535 may further form a fitting part 537 between the rotating part 535b and the fastening protrusion 537a, and the fitting part 537 is the fastening protrusion 537a in the length forming part frame ( When it is rotatably fitted into the fastening groove 538 formed in the center of the 536 , it is possible to prevent the upper surface of the length forming part frame 536 from coming into direct contact with the rotating part 535b.

The length forming part frame 536 is in the form of a cover having an upper surface and a side part, so that a part of the length forming part 535 is exposed when combined with the length forming part 535 on one side of the side part 539) may be formed.

Therefore, when the length forming unit frame 536 is coupled to the upper portion of the length forming unit 535 in a state in which the length forming unit 535 is screwed to the upper surface of the central support bar 534, the rotation confirmation unit 539 of one side is The rotating part 535b of the length forming unit 535 can be seen through, and a rotating tool for rotating the rotating unit 535b is put into the inside through the rotation confirmation unit 539 of the length forming unit frame 536 and the rotating unit (535b) can be operated.

On the other hand, when the rotation confirmation unit 539 is formed on both sides of the length forming unit frame 536, the length forming unit 535 is formed on both sides of the length forming unit frame 536 through the rotation confirmation units 539 on both sides. The rotating part 535b is exposed and can be seen, and the rotating part 535b can be operated by putting a rotating tool for rotating the rotating part 535b into the inside through the rotation confirmation part 539 of an arbitrary position. .

In addition, in the length forming part frame 536, when the fastening protrusion 537a is formed in the length forming part 535, a fastening groove 538 into which the fastening protrusion 537a can be fitted may be formed on the upper part. When the fastening protrusion 537a is fitted into the groove 538, when the length forming part 535 is rotated, the fastening protrusion 537a is inserted into the fastening groove 538, so the length forming part 535 is supported and not shaken. It can be rotated without

Hereinafter, a method of adjusting the length of the outer forming portion 532 in the lower supports 530 and 570 having the adjustable outer forming portion 532 of the present invention having the structure as described above can be described. have.

In addition, the length forming part frame 536 constituting the outer forming part 532 in the lower supports 530 and 570 having the outer forming part 532 that can be adjusted in length according to another embodiment of the present invention is a central support bar. It may remain lowered downward to abut the top surface of 534 .

In this state, if you want to make the length of the outer forming part 532 longer, insert a rotating tool such as a finger or a spanner through the rotation check part 539 of the length forming part frame 536 to make a hexagonal bolt head shape. The length forming part frame 536 is raised by holding and rotating the rotating part 535b.

That is, when the rotating part 535b is rotated using a rotating tool such as a finger or a spanner, the length forming part 535 is raised by the second helical part 535a inserted into the inner space A of the central support bar 534. Accordingly, the length forming unit frame 536 coupled thereto also rises, and the length of the outer forming unit 532 is increased as much as the length of the length forming unit frame 536 is increased.

In addition, when the length of the outer forming part 532 is increased and it is desired to decrease the length again, the rotating part 535b of the length forming part 535 is rotated in the opposite direction using a rotating tool such as a finger or a spanner to rotate the length forming part. By lowering 535 , the length forming part frame 536 also descends and the length of the outer forming part 532 may be reduced by the descending distance.

9 and 10, the length adjustment body 5351 according to another embodiment of the present invention is raised or lowered in a state inserted into the inner diameter of the lower supports (530, 570) of the lower supports (530, 570). As a configuration for adjusting the height, a length checking unit 53511 may be formed in the outer diameter in the longitudinal direction so that the user can visually adjust the height of the panel support 550 while checking the height.

Therefore, the user can adjust the height of the length adjustment body 5351 while checking the length check unit 53511 according to the height or topography of the surrounding buildings.

At this time, a protective pad made of rubber or synthetic resin for preventing friction and abrasion with the bottom surface was formed on the lower portion of the length adjustment body 5351 .

In particular, since the length adjustment body 5351 is inserted from the inner diameter of the lower supports 530 and 570 to rotate, it will be natural that the diameter is smaller than the inner diameter of the lower supports 530 and 570.

In addition, the first fixing part 5352 is configured to expand the second fixing part 5353 in contact with the close contact forming part 53532, and for this purpose, it is in contact with the inner diameter of the close contact forming part 53532 while ascending or descending. It is preferable to manufacture to have a conical shape so that the second fixing part 5353 can be expanded or reduced.

In addition, the first fixing part 5352 usually supports the length adjustment body 5351 by the elastic force of the elastic part 5354 in order to alleviate the shock generated in using the lower supports 530 and 570 to rise or fall. It may be, and the panel support 550 may have a buffer action.

To this end, it will be natural that the first fixing part 5352 must maintain a loose coupling so that it can move in the upper and lower directions of the length adjustment body 5351 .

On the other hand, the spiral formed on the outer diameter of the first screw thread 53521 is an important configuration for smoothly moving the second fixing part 5353 in the upper and lower directions through spiral rotation, in particular, the first fixing part ( 5352 and the close contact forming part 53532 are induced to come into contact with each other, and as a result, the lower end of the second fixing part 5353 may gradually expand (widen) outward.

At this time, it is preferable that the shape and pitch of the first screw thread 53521 and the second screw thread 53531 (the distance the screw is rotated by one rotation) can be efficiently adjusted in consideration of the moving distance of the length adjustment body 5351 .

In particular, a separation prevention part ( 53522 and 53523) may be formed, respectively.

The second fixing part 5353 is in close contact with the inner diameter of the lower supports 530 and 570 so that the user can move only when the user holds the length adjustment body 5351 and applies force, and the user holds the length adjustment body 5351 and rotates When this is done, the inner diameter of the close contact forming part 53532 comes into contact with the first fixing part 5352 and gradually expands outwardly, so that it can be firmly compressed and fixed to the inner diameter of the lower supports 530 and 570 .

At this time, a plurality of extension guide portions 53533 are formed in the longitudinal direction to have a predetermined length at the lower portion of the second fixing portion 5353 so that when the first fixing portion 5352 and the close contact forming portion 53532 come into contact with each other, efficiently outward direction may lead to expansion.

In particular, the second fixing part 5353 should have restoring force and flexibility so that it can be expanded and contracted according to the contact state between the first fixing part 5352 and the close contact forming part 53532, as well as the lower supports 530 and 570. Since it is in direct contact, durability and abrasion resistance must be maintained. For this purpose, it is preferable to be made of a material such as silicone, urethane, synthetic resin, engineering plastic, or the like.

In another embodiment of the present invention having the above configuration, the height adjustment operation of the panel support 550 is as follows.

First, the user can select the height by inserting the length adjustment body 5351 into the inner diameter of the lower support (530, 570).

Next, the user holds the length adjustment body 5351 and rotates it in one direction. At this time, the first screw thread 53521 is in a state of being helically coupled with the second screw thread 53531 in the rotation direction of the length adjustment body 5351. Accordingly, the second fixing part 5353 may be gradually lowered.

At this time, since the elastic part 5354 generates an elastic force between the length adjustment body 5351 and the first fixing part 5352, the rotational force of the body 110 is transmitted to the first fixing part 5352 so that it can be rotated. can be

For this purpose, it is preferable to use a known compression spring for the elastic part 5354 .

That is, when the length adjustment body 5351 is continuously rotated in a state where the close contact forming part 53532 and the first fixing part 5352 of the second fixing part 5353 descending in a spiral rotation are in contact with each other, the second fixing part ( 5353) may be gradually spread outward to be firmly fixed to the inner diameter of the lower supports (530, 570).

At this time, since the outer diameter of the second fixing part 5353 is in close contact with the inner diameter of the lower supports 530 and 570 and is in a fixed state without spinning, when the length adjustment body 5351 is rotated, only the lower end of the second fixing part 5353 It can be firmly fixed by being compressed with the inner diameter of the lower supports (530, 570) while gradually spreading outward.

Conversely, in order to adjust the height of the lower supports (530, 570) again, the fixed state between the second fixing part (5353) and the lower supports (530, 570) is canceled by rotating the length adjustment body (5351) in the opposite direction. It may be able to move up and down.

The above-described embodiments are for illustration, and those of ordinary skill in the art to which the above-described embodiments pertain can easily transform into other specific forms without changing the technical idea or essential features of the above-described embodiments. You will understand. Therefore, it should be understood that the above-described embodiments are illustrative in all respects and not restrictive. For example, each component described as a single type may be implemented in a dispersed form, and likewise components described as distributed may be implemented in a combined form.

The scope to be protected through the present specification is indicated by the following claims rather than the detailed description, and should be construed to include all changes or modifications derived from the meaning and scope of the claims and their equivalents.

10: Solar system installed in the blinds

Claims (2)

In a shoulder-mounted solar panel system comprising; a solar panel,
A solar panel communicating with the solar panel and transmitting a control signal for adjusting the angle of the solar panel to maximize the amount of sunlight irradiated to the solar panel according to the amount of sunlight irradiated to the solar panel server;
Doedoe formed in the shape of a square plate, a plurality of solar panels are spaced apart from the top panel support;
a central support located at the center of the lower end of the panel support, provided with a hydraulic cylinder capable of lifting or lowering therein, and ascending or descending according to the control signal transmitted from the solar panel server; and
It is located at the lower ends of both sides of the panel support, and has a hydraulic cylinder capable of lifting or lowering therein, so that the lower support is raised or lowered by the control signal transmitted from the solar panel server;
The solar panel server,
a second transceiver for transmitting the control signal for controlling the lifting or lowering of the hydraulic cylinders respectively located inside the central support and the lower support;
In accordance with the case of controlling the inclination angle of the panel support according to the amount of sunlight irradiated to the solar panel, the elevation angle of the panel support by differentiating the elevation or descending height of the central support and the elevation or descending height of the lower support. an inclination angle control unit generating a signal to control the ;
In accordance with the case of controlling the height of the panel support according to the amount of sunlight irradiated to the solar panel, the elevation or descending height of the central support and the ascending or descending height of the lower support are equal to the height of the panel support. a height control unit for generating a signal for controlling the height; and
A signal for controlling the height generated by the height control unit that adjusts the elevation or descent of the panel support according to the amount of sunlight irradiated to the solar panel for each season or time zone, and the inclination angle control unit that adjusts the inclination angle of the panel support The signal for controlling the generated inclination angle is accumulated and stored, and the inclination angle control unit and the height control unit control the inclination angle control unit and the height control unit to generate a signal for controlling the elevation, descent, and inclination angles of the panel support according to the season or time according to the data of the stored signal Including; a second data management unit;
The central support is
Lifting or lowering by the control signal transmitted from the solar panel server to change the inclination angle of the panel support or to change the height of the panel support,
The lower support is
Lifting or lowering by the control signal transmitted from the solar panel server to change the inclination angle of the panel support or to change the height of the panel support,
The lower support is
It is installed from the ground and includes an outer forming part to be installed with a variable overall length,
The outer forming part,
a central support bar whose cross section is vertically long while forming the shape of a rectangular bar, the outer surface is formed in a round shape, and an inner space is formed in the longitudinal direction;
a length forming part inserted and coupled to the center of the central support bar from the upper part of the central support bar; and
Including; and a length forming part frame that is fitted to the upper part of the central support bar so as to be lifted and lowered.
The length forming part,
Fitted into the inner space of the length forming part frame,
The length forming part,
A part is inserted so as to be elevating in the inner space formed in the center of the central support bar,
The length forming part,
It is inserted into the inner space formed in the center of the central support bar and includes a second helical part having a thread formed along the outer surface, and rotates while being inserted into the internal space so that the thread of the second helical part is inserted into the inner space. It is possible to ascend and descend by the force that is inserted into the inner circumferential surface of the space,
The central support bar,
A first helical part symmetrical with the thread of the second helical part is formed on the inner circumferential surface of the inner space,
The length forming part,
It is formed on the upper side of the second helical part, and includes a rotating part inserted into the inner space of the central support bar to rotate,
The length forming part,
A fastening protrusion rotatably fitted into a fastening groove formed in the center of the length forming part frame is further formed on the upper side of the rotating part, and the fastening protrusion is fitted into the fastening groove formed in the center of the length forming part frame. When it loses, the height at which the length forming part frame is coupled from the upper part of the central support bar is determined, a shoulder-mounted solar panel system.

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