KR101004285B1 - The lighting system installed on bus stop using solar cell - Google Patents

Abstract

PURPOSE: A sunlight illuminating system is provided to save electric energy by turning on or off a light emitting device according to external illumination. CONSTITUTION: A solar panel(1) generates electricity using sunlight. A chargeable battery stores electricity produced by a solar panel. A charging controller supplies electricity produced by the solar panel to the chargeable battery. A light emitting device(7) lights a bus stop(2) using electricity stored in the chargeable battery. An illumination sensor is arranged at the bus stop. A first controller turns on or off the light emitting device according to the external illumination sensed by the illumination sensor.

Description

The lighting system installed on bus stop using solar cell}

The present invention relates to a solar lighting system installed in a bus platform, and more particularly, a solar installed in a bus platform that directly supplies electricity generated by a solar panel installed in a bus platform to a lighting facility installed in the bus platform. A light illumination system.

At present, roads in our country are equipped with bus stands for passengers to get on and off the bus.

At this time, the bus platform is provided with a lighting system to inform the bus driver or pedestrians who want to board the bus at the evening or dawn time when the sun is low, the lighting system is typically provided by Korea Electric Power. It is the situation that is using the transferred AC power as it is or converts AC power to DC power.

Therefore, in order to supply electricity to the lighting facility provided in the bus platform, the electric track installed in the power pole is directly drawn to the lighting facility provided in the bus platform, or the electric tracks drawn from the outside are placed on the asphalt floor or concrete installed around the bus platform. It is used to bury the floor.

However, the above-described power supply system not only makes it difficult to move pedestrians due to the track laying work at the time of initial construction, but also has a problem in that it is impossible to install in a mountain area where electricity supply is not smooth.

In addition, the lighting system applied to the bus platform has a problem that the replacement work should be performed when a predetermined time has elapsed since most of the fluorescent lights.

Therefore, the present invention is to solve the problem of the conventional electricity supply system for supplying electricity in the bus platform, while being able to be smoothly supplied electricity even in the bus platform that is not far from the power supply is far from the city, lighting facilities in the bus platform The purpose is to provide a solar lighting system installed in a bus platform that can be installed simply to prevent the pedestrian's movement during construction, and to reduce the number of replacement of the lighting facility, thereby reducing maintenance costs and waste of manpower.

The solar lighting system installed in the bus platform according to the present invention for achieving the above object is a solar panel that receives electricity from the solar light in the state installed in the bus platform and accumulates electricity generated from the solar panel A charging battery for controlling the voltage output from the solar panel and then supplying the charging battery to the charging battery, and a light emitting device that illuminates the inside of the bus platform using electricity stored in the charging battery in a state where the battery is installed in the bus platform. It may be made of a first illumination controller for turning on, off the light emitting device according to the illumination sensor mounted on the, and the external illumination sensed by the illumination sensor.

The solar lighting system installed in the bus platform according to the present invention having such a structure can operate the light emitting device using electricity produced by itself from the solar panel, and thus does not need to use an external electric line.

In addition, by using a long life LED as the light emitting device, it is possible to overcome the problem of a fluorescent lamp that must be replaced periodically.

In addition, the light emitting device may be turned on or off according to the external illuminance sensed by the illuminance sensor, thereby saving electric energy and preventing the lighting facility from being lit during the day.

In addition, the present invention has an advantage that can be equipped with an additional exercise equipment that can produce electricity by the reciprocating motion of the person, the passengers can charge the charge battery at the same time while exercising.

1 is a schematic diagram of the present invention;
2 is a control block diagram of an illuminance detection unit according to the present invention;
3 is a longitudinal sectional view of a solar panel provided in the present invention;
4A is a control block diagram of a charge controller according to the present invention;
4b is an electronic circuit diagram of a charge controller according to the present invention;
5 is a control block diagram of a lighting controller according to the present invention;
6 is a control block diagram of a human body sensing unit according to the present invention;
7 is a view for explaining a state in which the exercise device is added to the present invention,
8 is a front view of a rotating means according to the present invention;
9A to 9B are views for explaining a process in which the solar panel is always faced with the sun by a motor provided in the rotating means.

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

The solar lighting system installed in the bus platform according to the present invention, as shown in Figures 1 to 4a, the solar panel (1) for generating electricity by receiving solar light in the state installed in the bus platform (2), and A rechargeable battery 3 accumulating electricity generated from the solar panel 1, a charge controller 5 for attenuating the voltage output from the solar panel 1 and supplying it to the rechargeable battery 3, a bus platform The light emitting device 7 illuminating the inside of the bus stand 2 by using the electricity stored in the rechargeable battery 3 in the state installed in the (2), the illumination intensity sensing unit 9 mounted on the bus stand 2, and the The first controller 11 may be configured to turn on and off the light emitting device 7 according to the external illuminance detected by the illuminance sensor 9.

In addition, as shown in FIG. 2, the illuminance detecting unit 9 typically has a CDS sensor 13 having an output terminal connected to a ground terminal and changing its resistance value according to external illuminance, and an output terminal having the CDS sensor ( 13 is connected to the input terminal, the input terminal may be made of a fixed resistor (15) connected to the power supply terminal.

The illuminance sensing unit 9 having the above structure changes the output voltage between the CDS sensor 13 and the fixed resistor 15 whenever the self-resistance value of the CDS sensor 13 changes according to the external illuminance.

In this case, the first controller 11 may convert the analog voltage output between the fixed resistor 15 and the CDS sensor 13 into a digital value by using an A / D converter.

Next, when the illuminance value converted into a digital value is equal to or less than a predetermined value, the first control unit 11 turns on the light emitting element 7 installed in the bus platform 2.

Meanwhile, as shown in FIG. 3, the solar panel 1 includes a front electrode 21 bonded to the N-type semiconductor 19 provided in the solar panel 1, and the solar panel 1. EVA surrounding the combination of the back electrode 23 bonded to the P-type semiconductor 22, the N-type semiconductor 19, and the P-type semiconductor 22, the front electrode 21, and the back electrode 23 ( 25) Ethylene Vinyl Acetate (PV) or PolyVinyl Butyral (PVB), and a connection member connecting the two or more front electrodes 21 or two or more rear electrodes 23 or the front electrodes 21 and the rear electrodes 23. It may be made of.

In addition, as shown in FIG. 4A, the charge controller 5 includes a first constant voltage unit 27 which fixes and attenuates the voltage output from the solar panel 1 to a voltage suitable for charging the rechargeable battery 3. A reverse voltage prevention unit 29 mounted between the first constant voltage unit 27 and the rechargeable battery 3 to prevent the voltage of the rechargeable battery 3 from flowing back toward the solar panel 1; A switching unit 31 connected between the unit 29 and the rechargeable battery 3 to supply or not supply electricity of the solar panel 1 to the rechargeable battery 3 according to an external control signal, and the solar panel 1. The second constant voltage unit 33 for attenuating and fixing the output voltage of the rechargeable battery 3 to the maximum charging voltage of the rechargeable battery 3, and comparing the voltage output from the second constant voltage unit 33 with the charged voltage of the rechargeable battery 3. If the voltage of the rechargeable battery 3 is output from the second constant voltage unit 33 It is higher than the voltage that is provided with a voltage comparator (35) which passes a control signal to the switching unit 31 is cut off the electricity supplied to the rechargeable battery (3) from a solar panel (1).

In this case, as shown in FIG. 4B, the first constant voltage unit 27 and the second constant voltage unit 33 may be configured as a zener diode, and the reverse voltage preventing unit 29 may be configured as a diode. .

In addition, the voltage comparison unit 35 may be configured as an op-amp, as shown in FIG. 4B, and the switching unit 31 may be configured using a transistor, a thyristor, or the like.

Meanwhile, the light emitting device 7 may be formed of an LED module or an LED light guide plate, and the LED 41 may be used as a light emitting source in the LED module or the LED light guide plate.

In addition, the light emitting device 7 may be equipped with an illumination controller 17 that adjusts the brightness of the light emitting device 7 or turns the light emitting device 7 on or off.

In this case, the first control unit 11 provided in the lighting controller 17 adjusts the brightness of the LED 41 provided in the light emitting element 7 or adjusts the LED 41 as shown in FIG. 5. The control signal may be transmitted to the second control unit 37 to turn on and off.

In addition, as shown in FIG. 5, the lighting controller 17 includes two or more LEDs 41 connected in series or in parallel, and a cathode terminal of the LEDs 41 disposed at the rearmost end of the LEDs 41. And a current sensing unit 43 connected to each other to measure a current supplied to the LED 41 in real time, and the second control unit 37 includes brightness data of the LED 41 transmitted from the first control unit 11. Current value) and the comparison unit 45 for comparing the current value transmitted from the current sensing unit 43 and the LED 41 brightness data (current) transmitted from the first control unit 11 by the comparison unit 45. Value) and the current value transmitted from the current sensing unit 43, if the LED 41 brightness data (current value) transmitted from the first control unit 11 is the current value transmitted from the current sensing unit 43 If it is larger, the pulse width of the high level included in the pulse signal of one cycle is increased to the switching unit 31 and transmitted to the switching unit 31. When the LED 41 brightness data transmitted from the first control unit 11 is smaller than the current value transmitted from the current sensing unit 43, the pulse width of the high level included in the pulse signal of one cycle in the switching unit 31 is determined. It is provided with a pulse width control unit 47 to reduce the and transfer to the switching unit (31).

In addition, the lighting controller 17 has an input terminal connected to the rechargeable battery 3 to supply electricity transmitted from the rechargeable battery 3 to the filter unit 51 according to a pulse signal transmitted from the pulse width controller 47. And a filter unit 51 connected to the switching unit 49 and an output terminal of the switching unit 49 and converting the square wave voltage output through the switching unit 49 into a fixed voltage.

In addition, as shown in Figure 6, the bus landing 2, the human body detecting unit 53 for detecting the presence of the human body in the bus landing 2, and a radio may be mounted.

In addition, the first control unit 11 may operate the radio when a control signal indicating that the human body is detected from the human body detecting unit 53 is input.

At this time, the human body detection unit 53, as shown in Figure 6, the human body sensor 57 for detecting the movement of a person in the bus platform (2), and the output terminal of the human body sensor 57 The low pass filter 59 connected to remove high frequency noise output from the human body sensor 57, and amplify the signal output from the low pass filter 59 to a predetermined level, and then to the first control unit 11. It may be made of an amplifier 61 for transmitting.

In addition, in the present invention, as shown in Fig. 7, an exercise mechanism 63 capable of rotating the gears by a rotational movement of a person may be additionally mounted, and the exercise mechanism 63 may be configured to provide electrical energy for rotation of the gears. A generator capable of converting to

At this time, the electricity generated by the generator may be stored in the rechargeable battery 3, the bus platform (2) is equipped with a bus fare charger 66 that can be driven by the power of the rechargeable battery (3) Can be.

On the other hand, between the solar panel 1 and the bus platform 2, as shown in Figure 8, the rotation means 67 to the solar panel 1 to face the sun at all times can be mounted, An embodiment of the rotation means 67 will be described with reference to FIG.

The rotating means 67 comprises at least two active brackets 69 extending straight from the lower surface of the solar panel 1 toward the lower side of the solar panel 1 and the bus platform from the upper surface of the bus platform 2. And two or more driven brackets 71 extending straight in the upper direction of (2).

In this case, the active bracket 69 may be engaged with the driven bracket 71.

In addition, the rotation means (67) has a rotation shaft (73) penetrating the active bracket (69) and the driven bracket (71) engaged with each other, and the active bracket (69) is penetrated by the rotation shaft (73); In addition, it may be fixed to the rotation shaft 73 and rotated along the rotation shaft 73.

In addition, the rotation means 67 further includes a motor 75 that can be rotated a predetermined number of times at predetermined time intervals, and a power transmission means 77 is connected between the motor 75 and the rotation shaft 73. The rotation shaft 73 may be rotated by the rotation of the motor 75.

In this case, a chain, a wire, or a gear may be used as the power transmission means 77.

In addition, the rotation shaft 73 of the motor 75 may be equipped with a decoder 79 for generating an electric control signal different in the total number of pulses or the pulse width in accordance with the rotation angle or rotation speed of the motor 75, The first control unit 11 may rotate and rotate the motor 75 a predetermined number of time intervals by counting and analyzing the pulse width and the number of pulses transmitted from the decoder 79.

Therefore, the solar panel 1 may be rotated to face the sun at all times, as shown in FIGS. 9A and 9B.

In addition, a wind generator may be installed in the bus platform 2, and the rechargeable battery 3 may simultaneously charge electricity generated from the solar panel 1 and the wind generator, or the solar panel 1 or the wind generator. It is also possible to accumulate electricity generated from either.

The operation of the solar lighting system installed in the bus platform according to the present invention having the above structure will be described with reference to FIGS. 1 to 9b as follows.

First, the solar lighting system installed in the bus platform according to the present invention can accumulate electricity in the rechargeable battery 3 using the solar panel 1.

Next, the present invention detects the external illuminance using the illuminance sensor 9 which can be driven by electricity stored in the rechargeable battery 3, and then if the measured external illuminance is below a predetermined value, the lighting controller 17 Can be driven to light the light emitting element 7.

In addition, when the human body is detected in the bus platform 2 by the human body sensing unit 53, the present invention may drive a radio to people waiting for the bus at the bus platform 2.

The solar panel 1 provided in the present invention can always face the sun by the rotation means 67.

The solar lighting system installed in the bus platform according to the present invention having such a structure can operate the light emitting element 7 using electricity produced by the solar panel 1 itself.

In addition, the light emitting element 7 may be turned on or off according to the external illuminance sensed by the illuminance sensor.

In addition, the present invention can generate and then store electricity when operating the exercise mechanism 63 provided in the bus platform 2.

1. solar panel 3. rechargeable battery
5. Charge controller 7. Light emitting device
9. Illumination detection unit 11. First control unit
13. CDS sensor 15. Fixed resistor
17. Lighting controller 19. N-type semiconductor
21.Front Electrode 23.Rear Electrode
25.EVA 27.First constant voltage section
29. Reverse voltage protection unit 31. Switching unit
33. Second constant voltage section 35. Voltage comparison section
37. Second Control Unit 41.LED
43. Current sensing unit 45. Comparison unit
47. Pulse width control unit 49. Switching unit
51. Filter unit 53. Human body detecting unit
57. Human Body Detection Sensor 59. Low Pass Filter
61. Amplifying unit 63. Exercise equipment
67. Rotation means 69. Active bracket
71. Driven bracket 73. Shaft
75. Motor 77. Power transmission means

Claims (5)

A solar panel 1 configured to generate electricity by receiving solar light in a state installed at the bus platform 2;
A rechargeable battery (3) for accumulating electricity generated from the solar panel (1);
A charge controller 5 which attenuates the voltage output from the solar panel 1 and supplies it to the rechargeable battery 3;
A light emitting element 7 which illuminates the inside of the bus stand 2 using electricity stored in the rechargeable battery 3 in a state in which the bus stand 2 is installed;
An illumination intensity sensing unit 9 mounted on the bus platform 2;
And a first controller 11 for turning on and off the light emitting device 7 according to the external illuminance sensed by the illuminance sensor 9.
The solar panel 1 includes a front electrode 21 bonded to an N-type semiconductor 19 provided in the solar panel 1;
A back electrode 23 bonded to the P-type semiconductor 22 provided on the solar panel 1;
An EVA 25 or PVB surrounding the combination of the N-type semiconductor 19, the P-type semiconductor 22, the front electrode 21, and the rear electrode 23;
And a connecting member for conducting the at least two front electrodes 21 or at least two rear electrodes 23 or the front electrodes 21 and the rear electrodes 23.
The charging controller 5 includes a first constant voltage unit 27 for fixing and attenuating a voltage output from the solar panel 1 to a voltage suitable for charging the rechargeable battery 3;
A reverse voltage prevention unit (29) mounted between the first constant voltage unit (27) and the rechargeable battery (3) to prevent the voltage of the rechargeable battery (3) from flowing back toward the solar panel (1);
A switching unit 31 connected between the reverse voltage preventing unit 29 and the rechargeable battery 3 to supply or not supply electricity of the solar panel 1 to the rechargeable battery 3 according to an external control signal;
A second constant voltage unit 33 which attenuates and fixes the output voltage of the solar panel 1 to the maximum charging voltage of the rechargeable battery 3;
The voltage output from the second constant voltage unit 33 is compared with the charging voltage of the rechargeable battery 3, and the switching is performed when the voltage of the rechargeable battery 3 is higher than the voltage output from the second constant voltage unit 33. It is made of a voltage comparison unit 35 for transmitting a control signal to the unit 31 to cut off the electricity supplied from the solar panel 1 to the rechargeable battery 3,
The bus landing 2 is equipped with a human body detecting unit 53 for detecting the presence or absence of the human body in the bus landing (2),
The first control unit 11 drives a radio mounted on the bus platform 2 when a control signal indicating that a human body is detected from the human body sensing unit 53 is input.
Between the solar panel 1 and the bus platform 2 is provided with a rotation means 67 to face the solar panel 1 at all times,
The illuminance detecting unit 9 has an output terminal connected to the ground terminal, the CDS sensor 13 whose resistance is changed according to external illuminance, and an output terminal connected to the input terminal of the CDS sensor 13, and the input terminal is a power terminal. It consists of a fixed resistor (15) connected to
The first controller 11 converts the analog voltage output between the fixed resistor 15 and the CDS sensor 13 into a digital value by using an A / D converter, and the illuminance value converted into the digital value is equal to or less than a predetermined value. At this time, the light emitting device 7 installed in the bus platform 2 is turned on.
The light emitting device 7 includes an LED module or an LED light guide plate, and an LED 41 is used as a light emitting source for the LED module or LED light guide plate, and the brightness of the light emitting device 7 is adjusted to the light emitting device 7. Or an illumination controller 17 for turning on and off the light emitting element 7,
The first controller 11 provided in the lighting controller 17 adjusts the brightness of the LED 41 provided in the light emitting element 7 or turns the LED 41 on or off. Transmits a control signal to the second control unit 37 to
The lighting controller 17 is connected to two or more LEDs 41 connected in series or in parallel, and the cathode terminals of the LEDs 41 disposed at the rearmost end of the LEDs 41, respectively, to be supplied to the LEDs 41. And a current sensing unit 43 for measuring a current in real time, and the second control unit 37 includes the LED 41 brightness data (current value) and the current sensing unit 43 transmitted from the first control unit 11. Comparing unit 45 for comparing the current value transmitted from the LED, the brightness data (current value) and the current sensing unit 43, the LED 41 transmitted from the first control unit 11 by the comparison unit 45 As a result of comparing the transmitted current value, if the LED 41 brightness data (current value) transmitted from the first control unit 11 is larger than the current value transmitted from the current sensing unit 43, one period is applied to the switching unit 31. Increasing the pulse width of the high level included in the pulse signal of the transfer to the switching unit 31, the brightness of the LED 41 transmitted from the first control unit 11 When the data is smaller than the current value transmitted from the current sensing unit 43, the pulse width control unit for reducing the pulse width of the high level included in the pulse signal of one cycle to the switching unit 31 to transmit to the switching unit 31 ( 47)
The lighting controller 17 has an input terminal connected to the rechargeable battery 3 so as to supply electricity transmitted from the rechargeable battery 3 to the filter unit 51 according to a pulse signal transmitted from the pulse width controller 47. And a filter unit 51 connected to an output terminal of the switching unit 49 to convert a square wave voltage output through the switching unit 49 into a fixed voltage.
The human body sensing unit 53 is connected to an output terminal of the human body detecting sensor 57 for detecting a human movement in the bus platform 2 and the human body detecting sensor 57 and outputs from the human body detecting sensor 57. A low pass filter 59 for removing high frequency noise, and an amplifying unit 61 for amplifying a signal output from the low pass filter 59 to a predetermined level and then transferring the signal to the first control unit 11. A solar lighting system installed on a bus stop.
delete The method of claim 1,
The bus platform 2 is equipped with an exercise mechanism 63 for rotating gears by human rotational movement,
The exercise device 63 is equipped with a generator for converting the rotation of the gear into electrical energy,
The electricity generated by the generator is stored in the rechargeable battery 3,
Solar bus system installed in the bus platform, characterized in that the bus platform (2) is equipped with a bus charge charger (66) driven by the power of the rechargeable battery (3).
delete The method of claim 1,
The bus station 2 is provided with a wind generator,
The rechargeable battery 3 is installed at the bus platform, which simultaneously charges electricity generated from the solar panel 1 and the wind generator, or accumulates electricity generated from either the solar panel 1 or the wind generator. Solar lighting system.

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