KR200389162Y1 - Solar Powered Brick Light - Google Patents

Abstract

The present invention relates to a floor block, etc., produce electricity from the solar cell module using natural solar light during the day, stored in the storage battery, the road display solar light that is automatically turned on by the light sensor at night or cloudy days It is about floor block. The housing 11 to which the glass cover 113 is coupled to the upper portion of the glass case 111 having a receiving space, is installed in the glass case 111, the plurality of solar cell module 122 and the transmission window 123 ) Is installed using a body structure 12 in which the fault panel 121 coupled to the upper portion is integrally formed, and a reflector 132 in which a light emitting lamp 131 is inserted in a downward direction of the body structure 12. Control panel 13 and the storage battery 14 is fixed to the support plate 142 coupled to the lower plate of the body structure 12. Therefore, the present invention produces electricity from sunlight during the day using a solar cell and stores it in a storage battery, and is automatically turned on by an illuminance sensor at night, thus eliminating the need for constant electricity supply. . In addition, the construction cost is not necessary, such as electrical wiring, and the construction is easy, because it is generated by the solar energy, which is natural energy, can save energy, there is an effect that can be used semi-permanently when using the battery as an ultracapacitor (Ultracapacitor).

Description

Solar Powered Brick Light for Road Marking {Solar Powered Brick Light}

The present invention relates to a floor block, and more specifically, to produce electricity from the solar cell module using the natural energy of sunlight during the day, stored in the storage battery, the road that is automatically turned on by the light sensor at night or cloudy days It relates to a solar floor block for display.

In a conventional road sign bottle, a main body, a solar cell, a light emitting unit, and the like are mounted inside a case, and a cylinder fixing means is inserted into the road at the bottom thereof.

However, the configuration according to the prior art as described above has a problem that it takes a long time during the maintenance, such as assembly or coupling because each component is mounted inside the integrated case, in the case of road sign bottle powered by There is a problem that a separate transformer and rectifier, a constant voltage, and a capacitor should be further provided.

In order to solve the problems as described above, the present invention produces electricity in the solar cell module using the sunlight as the natural energy during the day, stored in the storage battery, automatically lights up by the illumination sensor at night or cloudy days, the body The purpose of the present invention is to provide a solar floor block for road marking that can be shortened in maintenance time by being separated into a case and a cover.

In the structure to achieve the purpose,

A housing to which a glass cover is coupled to an upper portion of the glass case having a receiving space;

A body structure installed inside the glass case and having a fixed panel in which a plurality of solar cell modules and a transmission window are coupled to an upper portion thereof;

A control panel installed using a reflector in which a light emitting lamp is inserted in a downward direction of the body structure;

It consists of a storage battery fixed to the support plate coupled to the lower plate of the body structure.

As another feature of the present invention, the glass cover is formed in the center convex to guide rainwater to the outside in the rain or the like.

As another feature of the present invention, the control panel inside is composed of a microprocessor, a memory and an illumination sensor.

As another feature of the present invention, the storage battery is composed of an ultracapacitor.

As another feature of the present invention, the storage battery is made of nickel hydrogen (Ni-Mh).

1 is a perspective view of a solar floor block light for road marking according to the present invention, Figure 2 is a side cross-sectional view of a solar floor block light for road marking according to the present invention, Figure 3 is a road marking sun according to the present invention 4 is a bottom view of the solar floor block for road marking according to the present invention, and FIG. 5 is an embodiment of the solar floor block for road marking according to the present invention, and FIG. Is a block diagram showing the configuration of a solar floor block for road marking according to the present invention, Figure 7 is a control flow diagram of a solar floor block for road marking according to the present invention.

Hereinafter, the components will be described with reference to the drawings.

1 and 2 show a perspective view and a side cross-sectional view of a solar floor block light for road marking according to the present invention, the block light 10 is the body structure 12 and the control panel 13 and the storage battery in the housing 11; It consists of (14).

The housing 11 forms an outer portion of the block lamp 10, and an insertion groove 112 is formed in the upper portion of the glass case 111, and a glass cover having a protrusion 114 inserted into the insertion groove 112. 113 is coupled to the upper glass case 111. The inside of the glass case 111 is composed of a space narrowing from the top to the bottom in the same shape as the outer portion, the handle groove 115 is provided on the left and right sides of the glass cover 113.

Body structure 12 is coupled to the glass case 111, the top is provided with a fixed panel 121 is formed integrally a plurality of solar cell module 122 is coupled, the inside of the solar cell module 122 The furnace is coupled to the circular transmission window 123. The body structure 12 is configured to gradually narrow from the top to the bottom, such as the glass case 111.

The control panel 13 is installed with a conventional coupling device such as a coupling screw on the vertical surface of the body structure 12, and a U-shaped reflector 132 having a light emitting lamp 131 inserted thereon is installed. The inside of the 13 is composed of a microprocessor 135, a memory 136 and the illumination sensor 137.

The storage battery 14 is provided in the lower space of the control panel 13, and charges the electricity produced by the solar cell module 122 during the day, and supplies the electricity required for lighting at night. The battery 14 is fixed to the support plate 142 coupled to the coupling screw 141 on one side of the bottom surface of the body structure 12, in Figure 2 by omitting a socket (not shown) for fixing the battery 14 Shown.

The solar cell module 122 is composed of a polycrystalline silicon solar cell, the storage battery 14 may selectively use an ultracapacitor and nickel hydrogen (Ni-Mh), in order to emit light at night The charging time of the battery 14 to be charged takes 5 hours when directly absorbing sunlight, and 8 hours when indirectly absorbing it. The lighting time is continuously turned on for about 30 hours, the operating temperature is operated at -25 ℃ ~ 65 ℃, the lighting method is automatically controlled by the illumination sensor 137 to detect the sunset and sunrise.

3 shows a plan view of the block lamp 10 in which the glass cover 113 is omitted, the insertion groove 112 is provided on the left and right sides of the glass case 1110, and the upper structure of the body structure 12 is provided inside. The solar cell module 122 and the transmission window 123 is shown, Figure 4 shows a bottom view of the block lamp 10, the lower surface of the glass case 111, the body structure 12 is coupled The support plate 142 fixed to the coupling screw 141 is coupled to one side of the bottom surface of the body structure 12.

The light emitting form of the block lamp 10 is classified into two types. First, continuous light emitting products continuously emit light at night light, and second blinking light emitting products blink at night light. It can be used selectively from the two types of light emitting products.

Table 1 is a specification when the ultracapacitor (Ultracapacitor) is used as the storage battery 14 as follows.

Table 1 Ultracapacitor

product color LED number Solar cell power Capacitor Life Capacitor Spec Voltage Capacitance Continuous Type R / G / B / W / Y / O each color 8 0.912 W 10 years 2.3V 720F Blinking Type R / G / B / W / Y / O each color 8 0.912 W 10 years 2.3V 720F

In the Table 1, when the ultracapacitor is used as the battery 14, the continuous light and the blinking light products are red (R) / green (G) / blue (B) / white ( W) / Yellow (Y) / Orange (O) can be selected and 8 LEDs are installed. The two products have the same specifications as 0.912W of solar cell power, 10 years of life, 2.3V of voltage, and 720F of capacitance.

The brightness of the LED light is red (R) 3,000 mcd / green (G) 4,000 mcd / blue (B) 1,500 mcd / white (W) 3,000 mcd / yellow (Y) 6,000 mcd / orange (O) 6,000 mcd The charging and discharging of the ultracapacitor is 100,000 cycles, which has a lifespan of about 54 years at 25 ° C, about 27 years at 60 ° C and about 7.3 years at 70 ° C.

Table 2 is a specification when using a nickel hydrogen (Ni-Mh) battery (14) as follows.

[Table 2] Nickel hydrogen (Ni-Mh)

product color LED number Solar cell power Battery life Nickel Hydrogen Spec Voltage Capacitance Continuous Type R / G / B / W / Y / O each color 8 0.912 W 3-5 years 1.2 V 4,000 mAh Blinking Type R / G / B / W / Y / O each color 8 0.912 W 3-5 years 1.2 V 4,000 mAh

In Table 2, when nickel-hydrogen (Ni-Mh) is used as the storage battery 14, continuous light products and blinking light products are red (R) / green (G) / blue (B) / White (W) / Yellow (Y) / Orange (O) can be selected and 8 LEDs are installed. The two products have the same specifications as 0.912W of solar cell power, 3 ~ 5 years lifespan, 1.2V voltage and 4,000mAh capacitance.

The brightness of the LED light is red (R) 3,000 mcd / green (G) 4,000 mcd / blue (B) 1,500 mcd / white (W) 3,000 mcd / yellow (Y) 6,000 mcd / orange (O) 6,000 mcd The charge and discharge of nickel-hydrogen (Ni-Mh) is 2,000 cycles, and when the temperature is 25 ℃ has a life of about 3 to 5 years.

5 shows an embodiment of a block light, the block light 10 is inserted into the central lane of the road 200, the vehicle sensor 210 is installed at regular intervals. The vehicle detection sensor 210 is turned on by skipping the block light 10 by one space when there is no vehicle traveling on the road at night and a signal to turn off the skipped block light 10 microprocessor of each block light 10 It will be sent to (135), and if the vehicle detects all the block lights (10) will be turned on.

In addition, the block light 10 may be used as a floor landscape lighting, such as a plaza, a park, and an apartment complex, in addition to the road 200 as described above.

6 shows a block diagram of a floor block, which generates electricity from the solar cell module 122 using sunlight and stores it as a storage battery 14 to emit light to the light emitting lamp 131. The charge and discharge as described above is controlled by the control panel 13, the control panel 13 is composed of a microprocessor 135, a memory 136 and the illumination sensor 137. The microprocessor 135 may include a memory 136 in which sunrise and sunset time information is input according to seasons, and light emitting lamps according to setting values of sunrise and sunset time information and illumination values according to weather changes in the memory 136. And an illuminance sensor 137 that operates 131. In addition, the vehicle detection sensor 210 installed on the road 200 detects whether the vehicle is traveling and sends a signal to the microprocessor 135.

7 shows a control flow chart of the floor block and the like as follows.

Step S10 of inputting seasonal sunrise and sunset time information into the memory 136;

If the illumination sensor 137 detects the sunrise, if the illuminance is more than the set value to the next step, if the set value is less than the step S20 to return to the previous step,

In step S20, when the illuminance is greater than or equal to a set value, that is, when the sunrise starts, step S30 of turning off the light-emitting lamp 131 lit at night;

When the light emitting lamp 131 in the step S30 is turned off (OFF), step S40 for detecting electricity from the solar cell module 121 to produce electricity,

S50 step of charging the battery 14 to the electricity produced in the step S40,

As described above, when the electricity generation and charging using solar light are repeated and the illuminance is lower than the set value, the next step is performed.

S70 to determine whether or not the vehicle passes when the illuminance is less than the set value in the step S60, that is, when the sunset starts or the weather is cloudy;

When the vehicle is detected in step S70, step S80 of turning on the entire light emitting lamp 131,

When the vehicle is not sensed in step S70, the partial light emitting lamp 131 is turned on.

The block lamp 10 continues the return operation as described above (S10 ~ S90).

As described above, the present invention produces electricity from sunlight during the day using a solar cell and stores it in a storage battery, and is automatically turned on by an illuminance sensor at night, thus eliminating the need for constant electricity supply. There is no at all. In addition, the construction cost is not necessary, such as electrical wiring, and the construction is easy, because it is generated by the solar energy, which is natural energy, can save energy, there is an effect that can be used semi-permanently when using the battery as an ultracapacitor (Ultracapacitor).

1 is a perspective view of a solar floor block for road marking according to the present invention.

Figure 2 is a side cross-sectional view of a solar floor block light for road marking according to the present invention.

Figure 3 is a plan view of a solar floor block light for road marking according to the present invention.

Figure 4 is a bottom view of a solar floor block light for road marking according to the present invention.

5 is an embodiment of a solar floor block for road marking according to the present invention.

Figure 6 is a block diagram showing the configuration of a solar floor block for road marking according to the present invention.

7 is a control flow chart of a solar floor block for road marking according to the present invention.

<Description of the symbols for the main parts of the drawings>

10: block light 11: housing

12 body structure 13 control panel

14: storage battery

Claims (5)

In the floor lighting for the indication and guidance of various roads, A housing 11 to which a glass cover 113 is coupled to an upper portion of the glass case 111 having a receiving space; A body structure 12 installed inside the glass case 111 and having a fixed panel 121 in which a plurality of solar cell modules 122 and a transmission window 123 are coupled to an upper portion thereof; A control panel 13 installed using a reflector 132 in which a light emitting lamp 131 is inserted in a downward direction of the body structure 12; Solar floor block for road marking, characterized in that consisting of a storage battery 14 is fixed to the support plate 142 is coupled to the lower plate of the body structure (12). The method of claim 1, The glass cover 113 is a solar floor block light for road marking, characterized in that the central portion is formed convex to guide the rain water in the rain in the block 10. The method of claim 1, The inside of the control panel 13 is a microprocessor 135, a memory 136, and a road floor solar floor light, characterized in that consisting of a light sensor (137). The method of claim 1, The storage battery 14 is a road floor solar floor light, characterized in that consisting of ultracapacitors (Ultracapacitor). The method of claim 1, The storage battery 14 is a road floor solar floor block lamp, characterized in that consisting of nickel-hydrogen (Ni-Mh).