KR101390515B1 - Solar streetlamp - Google Patents

Abstract

According to an embodiment of the present invention, a solar street lamp includes: a street lamp pillar; a solar cell module; a fixing post crossed over the street lamp pillar; a hinge attached to the backside of the solar cell module and rotated using the fixing post as a support axis; and a torsion spring rotated using the fixing post as the support axis and a torsion spring controls a rotation radius of a hinge to be limited within a selected range.

Description

SOLAR STREETLAMP

More particularly, the present invention relates to a solar streetlight, which uses natural energy such as sunlight, solar heat, and wind power to convert it into electric energy and stores it in a battery, The present invention relates to a solar streetlight capable of efficiently and flexibly preventing a street light from blinking, a solar storm, and a strong wind from damaging the solar module and the streetlight column.

Most of the street lamps that are generally used are lighted by electric energy, and street lights using solar light suitable for alternative energy and eco-friendly structure are being used in small scale. The street lighting structure using electric energy can maintain a constant brightness without frequent flashing of the lamp, but when it is used in a place with little humanity, the economic cost for piping and wiring is considerably burdensome and the current energy Considering the won, it is a very serious level.

In addition, although the streetlight structure using solar light is not only environmentally friendly but also a substitute for electric energy, it is difficult to secure electric power when the amount of sunshine is insufficient due to the use of pure sunlight. And the installation volume is increased, and improvement is necessary. Also, because the accumulated energy in the battery is limited, the streetlight lamp fails to maintain brightness until dawn, and is turned off or frequently flickers.

In addition, there is a disadvantage that the photovoltaic module is damaged by typhoon and strong wind or the support of the streetlight supporting the photovoltaic module is bent, which increases the maintenance cost of the solar streetlight.

The present invention was conceived to improve the above-mentioned conventional arts. The present invention uses natural energy such as sunlight, solar heat, and wind power to convert it into electric energy and stores it in a battery, And it is an object of the present invention to provide a solar streetlight capable of efficiently and flexibly flickering a street light irrespective of a change of a wind direction, and preventing a sun, a module, and a streetlight column from being damaged by a typhoon and a strong wind.

According to an aspect of the present invention, there is provided a solar streetlight including: a street lamp; Solar modules; A stationary post installed to be crossed at an upper end of the streetlight post; A hinge attached to a rear surface of the solar module, the hinge being configured to rotate about the fixing post as a supporting shaft; And a torsion spring that rotates about the fixing post as a support shaft and controls the rotation radius of the hinge to be limited to a predetermined range.

Further, a solar streetlight according to an embodiment of the present invention includes: a streetlight support; A spindle which is installed at the upper end of the street lamp post and rotates in a predetermined turning radius range; One or more photovoltaic modules attached to the spindle and rotating with the spindle in the radius of rotation; And a center-of-gravity module attached to a rear surface of the solar module to form a center of gravity of the solar module at a lower end of the solar module.

In addition, in the solar street light according to an embodiment of the present invention, the spindle may include an inner stationary shaft fixed to the streetlight pillar in a cross-coupled manner and having a stationary block formed at an end thereof; And an external rotary shaft to which the at least one solar module is attached, the at least one solar module being formed such that the internal fixed shaft is accommodated therein and the terminal is slotted by a predetermined radius of rotation corresponding to the fixed block.

Further, in the solar streetlight according to an embodiment of the present invention, the center-of-gravity forming module may include an arc bar attached to a rear surface of the solar module to pass through the spindle; And a weight center weight attached to the lower end of the arc bar.

Further, in the solar street lamp according to an embodiment of the present invention, the center-of-gravity forming module may include at least one center-weighted weight installed at the bottom of the rear surface of the solar module. And a center-of-gravity accommodating portion capable of accommodating the at least one gravity center additionally.

According to the solar street lamp of the present invention, natural energy such as sunlight, solar heat, and wind power is used for conversion into electric energy and stored in a battery for night lighting and advertisement promotion, It is possible to obtain an effect that the street light is flicker resiliently and the sun, the module and the street lamp are damaged by the typhoon and the strong wind.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a diagram showing the overall configuration of a solar streetlight according to the present invention; FIG.
2 is a view showing a portion where a solar module is installed in a solar streetlight according to a first embodiment of the present invention.
3 is a view showing a portion where a solar module is installed in a solar streetlight according to a second embodiment of the present invention.
4 is a view showing a cross section of a front surface c and a side surface d of a spindle in a solar streetlight according to a second embodiment of the present invention.
5 is a view showing a range of rotation of a solar module installed in a solar streetlight according to the second embodiment of the present invention.
6 is a view showing a part where a solar module is installed in a solar streetlight according to a second embodiment of the present invention.

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

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a diagram showing the overall configuration of a solar streetlight according to the present invention; FIG.

The solar street lamp 300 according to the present invention includes a rotary vane 100, a vertical vane 110, a solar module 120, a solar module support 130, a fixing post 140, a street lamp 150, A CCTV 160, a motion detection sensor 170, a streetlight support 180, a control panel 190, and a pedestal 200.

First, in the solar streetlight of the present invention, a streetlight support 180 formed of a beam of 'H' type and an 'I' type is formed in a basic skeleton, and a lower end of the streetlight support 180 is embedded in a ground And may be formed as a pedestal 200. A wind power generator may be installed at the top of the street lamp post 180. The wind power generator includes a rotary vane 100 and a vertical vane 110. The rotary vane 100 may be formed by crossing one or more posts.

At the end of the rotary vane 100, one or more vertical vanes 110 formed as an airfoil may be installed. The vertical vane 110 is rotated by wind blowing from the outside, and the rotary motion is transmitted to the rotary vane 100 and is transmitted as kinetic energy to the wind power generator installed at the lower end of the rotary vane 100 And can be generated by electric energy. The electric energy may be supplied to the control panel 190 to operate the street lamp 150, the CCTV 160, and the motion detection sensor 170.

The wind power generator is a wind power generator having a vertical axis that improves a weak point of a wind power generator formed on a horizontal axis and has excellent ability to cope with wind direction and wind speed, Which is capable of safely receiving rotational motion in any wind, such as a hurricane, a hurricane (tornado), etc., thereby enhancing power generation efficiency. At the lower end of the wind power generator, at least one solar module 120, at least one solar module support 130, and at least one stationary post 140 may be installed.

The solar module 120 may be formed in a rectangular shape and the solar module support 130 may be installed on the rear surface. One surface of the solar module support 130 may be formed as an 'L' grid to allow the solar module 120 to be inserted, and a rotation control unit may be formed on the other surface. The rotation control means can be described in various embodiments in Fig. 2, Fig. 3, and Fig. In FIG. 2, one or more hinges 131 may be coupled, and one or more holes may be formed on both sides of the hinge 131. The torsion spring 132 may be inserted in correspondence with the at least one hole. The fixing post 140 may be inserted into the torsion spring 132 and the at least one hole. The stationary posts 140 may be installed crosswise with the streetlight post 180. 3 and 6, a center-of-gravity forming module is installed on the lower surface of the hinge 131 so that the solar module 120 can be rotated at a predetermined angle.

A street lamp 150 may be installed on the lower end of the solar module 120. One or more LEDs may be installed within the streetlight 150. A CCTV 160 may be installed at a lower end of the streetlight 150. The CCTV 160 can be used for crime prevention and traffic information. At least one motion detection sensor 170 may be installed at the lower end of the CCTV 160. The at least one motion detection sensor 170 may operate the recording function of the CCTV 160 in response to a nearby human body or object. A control panel 190 may be installed at the lower end of the at least one motion detection sensor 170. The control panel 190 may be formed in the form of a rectangular parallelepiped, and may have a door opening on one side thereof.

2 is a view showing a portion where a solar module is installed in a solar streetlight according to a first embodiment of the present invention.

A portion where the solar module 120 is installed in the solar streetlight 300 according to the first embodiment of the present invention may include at least one solar module 120, a solar module support 130, a hinge 131, (132), and a fixing post (140).

Can be controlled and operated as shown in Figs. 2 (a) and 2 (b). As shown in (a), one or more solar modules 120 may be formed in a rectangular shape, and a solar module support 130 may be installed on a rear surface thereof. One side of the solar module support 130 is formed as an L-shaped grid so that the solar module 120 can be inserted and the hinge 131 is coupled to the other side of the solar module support 130. On both sides of the hinge 131, A hole may be formed. The torsion spring 132 may be inserted in correspondence with the at least one hole. The fixing post 140 may be inserted into the torsion spring 132 and the at least one hole. Referring to the partially enlarged view of FIG. 2 (a), a protective cover may be provided on the outer surface of the torsion spring 132. The protective cover may receive the torsion spring 132 and block the inflow of foreign matter that may enter from the external environment. The stationary posts 140 may be installed crosswise with the streetlight post 180.

The inclination degree of the solar module 120 can be changed according to the strength of the wind 135 blowing from the outside as shown in (b). The inclination may vary depending on the strength and angle of the torsion spring 132 inserted into the hinge 131. The first leg 133 and the second leg 134 of the torsion spring 132 can be installed while maintaining an inclination at a predetermined angle. The solar module 120 can be rotated and returned to its original position by the inclination.

For example, when the first leg 133 and the second leg 134 maintain the inclination at an angle of 0 ° to 60 °, the angle of inclination The solar module 120 can be rotated and moved.

The first leg 133 may be inserted into a hole formed in one surface of the fixing post 140 and the second leg 134 may be installed on a lower surface of the solar module 120. The inclination of the solar module 120 is changed according to the intensity of the wind 135, and the damage and loss of the solar module 120 can be reduced, so that the maintenance cost can be reduced.

3 is a view showing a portion where a solar module is installed in a solar streetlight according to a second embodiment of the present invention.

The portion where the solar module 120 is installed in the solar streetlight 300 according to the second embodiment of the present invention may include at least one solar module 120, a solar module support 130, a hinge 131, And a spindle 143.

At least one solar module 120 may be formed in a rectangular shape and a solar module support 130 may be installed at the rear. One side of the solar module support 130 is formed as an L-shaped grid so that the solar module 120 can be inserted and the hinge 131 is coupled to the other side of the solar module support 130. On both sides of the hinge 131, A hole may be formed. On the rear surface of the hinge 131, a center-of-gravity forming module may be installed.

The center-of-gravity forming module includes an arc bar 141, and a first weight-centered weight 142. The arc bar 141 is formed in the shape of half shell and arc and supports the first center of gravity 142. When the solar module 120 is rotated at an angle of 0 to 60 degrees by the wind, And more stable rotational motion can be realized. The weight of the first weight center weight 142 may be varied depending on the size of the solar module 120.

The spindle 143 includes an inner fixed shaft 144, a fixed block 145, and an outer rotary shaft 146. One side of the inner fixed shaft 144 is cross-coupled to the street lamp post 180 and the other end of the one side is provided with a fixing block 145. The fixed block 145 can control the range of rotation of the external rotation shaft 146 at an angle of 0 to 60 degrees. The inner hole formed in the outer rotary shaft 146 can receive the outer portion of the inner fixed shaft 144. And may be slotted to one side of the external rotation shaft 146 at an angle of 0 to 60 degrees and a length of 70 to 80 mm.

The center-of-gravity forming module and the spindle 143 reduce the internal stress on the wind direction and wind velocity exerted on the solar module 120 from the outside, It is possible to reduce maintenance and repair costs by reducing damage and loss.

4 is a view showing a cross section of a front surface c and a side surface d of a spindle in a solar streetlight according to a second embodiment of the present invention.

Can be controlled and operated as shown in the front view (c) and the side view (d) of Fig. And a cross-sectional view of the spindle 143 as shown in the front view (c). One or more bearings are provided on both sides of the inner fixed shaft 144 and the outer rotating shaft 146 which are in contact with each other and friction and shaking can be corrected when the inclination of the solar module 120 is changed.

(D) is a cross-sectional view of the spindle 143. FIG. The spindle 143 includes an inner fixed shaft 144, a fixed block 145, and an outer rotary shaft 146. The inner hole formed in the outer rotary shaft 146 can receive the outer portion of the inner fixed shaft 144. The fixed block 145 is installed at the end of the inner fixed shaft 144 and can control the rotational motion of the outer rotary shaft 146. [ For example, if one side of the external rotation shaft 146 is slotted at an angle of 0 ° to 60 °, the range of rotation of the solar module 120 can be controlled in the range of 0 ° to 60 ° .

5 is a view showing a range of rotation of a solar module installed in a solar streetlight according to the second embodiment of the present invention.

The solar street lamp 300 according to the present invention includes a rotary vane 100, a vertical vane 110, a solar module 120, a solar module support 130, a fixing post 140, a street lamp 150, A CCTV 160, a motion detection sensor 170, a streetlight support 180, a control panel 190, and a pedestal 200.

First, in the solar streetlight of the present invention, a streetlight support 180 formed of a beam of 'H' type and an 'I' type is formed in a basic skeleton, and a lower end of the streetlight support 180 is embedded in a ground And may be formed as a pedestal 200. A wind power generator may be installed at the top of the street lamp post 180. The wind power generator includes a rotary vane 100 and a vertical vane 110. The rotary vane 100 may be formed by crossing one or more posts.

At the end of the rotary vane 100, one or more vertical vanes 110 formed as an airfoil may be installed. The vertical vane 110 is rotated by wind blowing from the outside, and the rotary motion is transmitted to the rotary vane 100 and is transmitted as kinetic energy to the wind power generator installed at the lower end of the rotary vane 100 And can be generated by electric energy. The electric energy may be supplied to the control panel 190 to operate the street lamp 150, the CCTV 160, and the motion detection sensor 170.

At the lower end of the wind power generator, at least one solar module 120, at least one solar module support 130, and at least one stationary post 140 may be installed. At least one solar module 120 may be formed in a rectangular shape and a solar module support 130 may be installed at the rear. One side of the solar module support 130 is formed as an 'L' type grid so that the solar module 120 can be inserted therein. One or more hinges 131 are coupled to the other side, At least one hole may be formed. On the rear surface of the hinge 131, a center-of-gravity forming module may be installed.

The center-of-gravity forming module includes an arc bar 141, and a first weight-centered weight 142. The arc bar 141 is formed in the shape of half shell and arc and supports the first center of gravity 142. When the solar module 120 is rotated at an angle of 0 to 60 degrees by the wind, And more stable rotational motion can be realized. The weight of the first weight center weight 142 may be varied depending on the size of the solar module 120.

A street lamp 150 may be installed on the lower end of the solar module 120. The solar module 120 can be controlled at an angle selected by the wind. For example, when the solar module 120 is rotated at an angle of 0 to 60 degrees, stable rotation can be realized by correcting the shaking. The weight of the weight center weight 142 may be varied depending on the size of the solar module 120. One or more LEDs may be installed within the streetlight 150. A CCTV 160 may be installed at a lower end of the streetlight 150.

The CCTV 160 can be used for crime prevention and traffic information. At least one motion detection sensor 170 may be installed at the lower end of the CCTV 160. The at least one motion detection sensor 170 may operate the recording function of the CCTV 160 in response to a nearby human body or object. A control panel 190 may be installed at the lower end of the at least one motion detection sensor 170. The control panel 190 may be formed in the form of a rectangular parallelepiped, and may have a door opening on one side thereof.

6 is a view showing a part where a solar module is installed in a solar streetlight according to a second embodiment of the present invention.

A portion where the solar module 120 is installed in the solar streetlight 300 according to the embodiment 2-2 of the present invention may include at least one solar module 120, a solar module support 130, a hinge 131, A spindle 143, and a weight centering portion.

At least one solar module 120 may be formed in a rectangular shape and a solar module support 130 may be installed at the rear. One side of the solar module support 130 is formed as an 'L' type grid so that the solar module 120 can be inserted therein, the hinge 131 is coupled to the other side, A hole may be formed. The weight centering weight receiving part may be installed at the lower end of the solar module 120.

The weight-centered weight receiving part may be provided with a bag 147 formed in a bag-shaped form. A Velcro 148 may be attached to the upper surface of the bag 147 formed in a bag shape. The Velcro 148 may be attached with one or more second center-of-gravity weights 149. For example, when the solar module 120 is rotated according to the wind direction and the wind speed by an angle of 0 to 60 degrees by the at least one second center of gravity 149, the shaking can be corrected, Can be implemented. The weight of the second center of gravity weight 149 may vary depending on the size of the solar module 120.

The spindle 143 includes an inner fixed shaft 144, a fixed block 145, and an outer rotary shaft 146. One side of the inner fixed shaft 144 is cross-coupled to the street lamp post 180 and the other end of the one side is provided with a fixing block 145. The inner hole formed in the outer rotary shaft 146 can receive the outer portion of the inner fixed shaft 144. The fixed block 145 can control the range of rotation of the external rotation shaft 146 at a predetermined angle. For example, after slotting at an angle of 0 to 60 degrees and a length of 70 to 80 mm on one side of the external rotation shaft 146, the wind 135 is blown from the outside by the wind direction and the wind speed to the solar module 120 may be rotated in the range of 0 to 60 degrees.

The center-of-gravity forming module and the spindle 143 reduce the internal stress on the wind direction and wind velocity exerted on the solar module 120 from the outside, It is possible to reduce maintenance and repair costs by reducing damage and loss.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. This is possible.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by the equivalents of the claims, as well as the claims.

100: rotary blade 110: vertical blade
120: solar module 130: solar module support
131: Hinge 132: Torsion spring
133: first leg 134: second leg
135: wind 140: stationary post
141: arc bar 142: 1st center of gravity weight
143: spindle 144: inner fixed shaft
145: fixed block 146: outer rotating shaft
147: bag 148: Velcro
149: second center-weighted weight 150: streetlight
160: CCTV 170: motion detection sensor
180: Street lamp 190: Control panel
200: Stand

Claims (5)

delete Street light holding;
An inner fixed shaft which is installed at an upper end of the street lamp support and which is rotated in a predetermined turning radius range and which is fixed in a cross-coupled manner with the street lamp support and has a fixed block at its end; A spindle including an outer rotation axis to which an axis is received and which is configured to slotting the end by a predetermined radius of rotation corresponding to the fixed block and to which at least one solar module is attached;
One or more photovoltaic modules attached to the spindle and rotating with the spindle in the radius of rotation; And
A center-of-gravity forming module attached to a rear surface of the solar module to form a center of gravity of the solar module at a lower end of the solar module;
And a plurality of light emitting diodes (LEDs). delete 3. The method of claim 2,
The center-of-
An arc bar attached to a rear surface of the solar module to pass through the spindle; And
A center-of-gravity weight attached to the lower end of the arc bar
And a plurality of light emitting diodes (LEDs). 3. The method of claim 2,
The center-of-
At least one center-weighted weight installed at the bottom of the rear surface of the solar module; And
The weighted center weight receiving portion
And a plurality of light emitting diodes (LEDs).

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