JP2001176312A - Solar light - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a solar light that allows lighting to start at a desired surrounding illuminance intensity for the start of lighting by setting an output voltage of a solar battery, and that allows each solar light to be turned ON simultaneously without scattering when a large number of solar lights are provided. SOLUTION: A solar light of the present invention comprises a solar battery SB, a storage battery BT for charging the solar battery SB, a lighting circuit 1 actuated for lighting with the power of the storage battery BT, and a control unit 2 for actuating the lighting circuit 1 for lighting when the output voltage is compared with and lower than a reference value that can be set variable.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a solar light having a lighting start ambient illuminance variable setting device and the like, which can start lighting without variation.

[0002]

2. Description of the Related Art Lighting of this type of conventional solar light is generally performed by detecting sunset by the output voltage of a solar cell. However, the output voltage characteristic of the solar cell varies from one solar cell to another in a low illuminance region. However, there is a problem that characteristics cannot be controlled, and the ambient illuminance at the start of lighting varies, and when multiple lamps are installed, variations in lighting start occur among the solar lights.

[0003] There is a demand for adjusting the lighting start illuminance and for eliminating variations when installing multiple lamps, but no specific measures have been taken. For this reason,
The fact that the ambient illuminance at the start of lighting varies and that multiple solar lights are scattered in the start of lighting when multiple lights are installed has been cleared up due to local sunlight.

[0004]

Accordingly, an object of the present invention is to set the output voltage of a solar cell so that lighting can be started at a desired lighting start ambient illuminance. An object of the present invention is to provide a solar light capable of adjusting the lighting time of the solar light without variation.

[0005]

According to a first aspect of the present invention, there is provided a solar light, comprising: a solar battery; a storage battery for charging the power of the solar battery; a lighting circuit for performing lighting operation using the power of the storage battery;
A control unit for lighting the lighting circuit when the output voltage falls below the reference value by comparing the output voltage of the solar cell with a variably settable reference value.

According to the first aspect of the present invention, the characteristic that the relationship between the output voltage of the solar cell and the ambient illuminance is small in a solid state is small, and the output voltage of the solar cell corresponding to a desired lighting start ambient illuminance is adjusted. By setting, the lighting can be started at a desired lighting start ambient illuminance, and by changing the setting of the reference value, the setting of the lighting start illuminance of the solar light can be changed.

The solar light according to the second aspect is the first aspect.
In the above, the reference value is stored in a memory, and the reference value stored in the memory is rewritten to a value of the output voltage of the solar cell by a lighting start setting button.

According to the solar light of the second aspect, in addition to the same effects as those of the first aspect, the lighting start setting voltage can be reset by pressing the lighting start setting button. It is easy and reliable to change the lighting start time. Further, the lighting start setting voltage can be reset only by pressing the lighting start setting button installed in the control unit, so that the customer can set the lighting start setting voltage on site. Further, for adjustment when using multiple lamps, the lighting timing of each solar light can be adjusted without variation. Further, it is possible to match the lighting timing of the lighting fixture controlled by the EE switch with the lighting timing without variation.

The solar light according to the third aspect is the first aspect.
Wherein the reference value is set by a variable resistor.

According to the third aspect of the invention, in addition to the same effects as those of the first aspect, the reference value is set to another desired reference value by adjusting the variable resistance by turning the knob of the variable resistance. be able to.

According to a fourth aspect of the present invention, the solar light sets a solar battery, a storage battery for charging the power of the solar battery, a lighting circuit that is lit by the power of the storage battery, and a time at which the lighting circuit starts lighting. A time timer.

According to the solar light of the fourth aspect, the lighting time can be set by the time timer, and the turning off time can also be set, so that the turning on and off can be performed. Therefore, it is possible to eliminate variations in lighting start time when multiple lamps are installed.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described with reference to FIGS. That is, the solar light includes the solar cell SB, the storage battery BT, the lighting circuit 1, and the control unit 2.

A known solar cell SB is applied. Generally, the irradiance (W / m ² ) and the output voltage (V) of the solar cell have a relationship shown in FIG.

The storage battery BT charges the power of the solar cell SB. A known battery is also applied to the storage battery BT.

The lighting circuit 1 performs a lighting operation using the power of the storage battery BT. In the embodiment, it is composed of a ballast 3 and a lamp 4 connected to the ballast 3. The storage battery BT is connected to a booster circuit unit 5 of a control unit 4 described later, the booster circuit unit 5 is connected to a polarity inversion circuit unit 6, and the polarity inversion circuit unit 6 is connected to the ballast 3 to operate the ballast 3. . The booster circuit section 5 and the polarity inversion circuit section 6 are controlled by a general-purpose microcomputer IC which is a control means in the control unit 2.

The control unit 2 compares the output voltage of the solar cell SB with a variably settable reference value and turns on the lighting circuit 1 when the output voltage falls below the reference value. The reference value is stored in a memory IC3 using an EEPROM IC, and the reference value stored in the memory IC3 is changed to a switch S
The output voltage of the solar cell SB is rewritten by the lighting start setting button of W1. The control unit 2 of the embodiment is provided in a box of the storage battery BT.

In the embodiment shown in FIG. 1, IC ₁ is a regulator IC, and IC ₂ is the general-purpose microcomputer I described above.
C and IC ₃ are the above-described EEPROM ICs, X1 is an oscillator, Q1 is an FET, D1 and D2 are diodes, and R1 to R
5 is a resistor, and SW1 is a switch of a lighting start setting button. 2, reference numeral 10 denotes various control switches, 11 denotes various display LEDs, and 12 denotes a connector.

In the daytime, the voltage generated by the solar cell SB charges the storage battery BT when the general-purpose microcomputer IC2 outputs a signal for turning on the FET Q1. When the voltage of the solar cell SB decreases, the divided voltage V by the diode D2 and the resistors R1 and R2.
When R2 falls below a voltage Vref1, which is a reference value set by the general-purpose microcomputer IC2, it is determined that the nighttime is set,
A signal for turning off Q1 is output and the booster circuit 5
Then, the polarity inverting circuit section 6 is operated to supply a voltage to the ballast 3 to turn on the lamp 4.

When the switch SW1 of the lighting start setting button is turned on, a new set voltage Vref2 is stored in the memory IC3.
(= VR2), so that the lamp 4 can be turned on with desired ambient brightness (illuminance).

The operation of the solar light will be described with reference to the timing chart of FIG. 4A and the relationship between the output voltage of the solar cell SB and the irradiance of FIG. 4B. Since this is a solar light operation, the lighting is started by recognizing the output voltage of the solar cell SB and detecting sunset without using a normal timer or EE switch. When the ambient illuminance decreases (during sunset), the output voltage of the solar cell decreases as shown in FIG. Compared with a certain lighting start set voltage V _A , V
When it becomes _A or less, it is detected as sunset and the lamp of lighting equipment 4
Lights up. After the lighting is started, the lighting fixture is turned on by a timer inside the control unit 2 for a certain time T, and turned off after the elapse of the T time.

At this time, when a switch SW1 of a certain button of the control unit 2 is pressed, the solar cell S at that time is pressed.
B is stored in the IC inside the control unit 2 as the new set voltage V _A ′, and thereafter, sunset detection is performed at the new set voltage V _A ′. Thereby, the lighting start time can be changed from the time of the initial setting.

As described above, the control unit 2 can recognize the output voltage of the solar cell SB. When the output voltage falls below a certain reference value (threshold value, that is, a lighting start set voltage), the control unit 2 detects the sunset, and the lighting circuit Power is supplied from the storage battery BT to the lighting fixture having the lighting. At this time, by pressing the switch SW1 of the lighting start setting button provided in the control unit 2, the output voltage of the solar cell SB at that time is stored in the control unit 2 and set as a new lighting start setting voltage.

According to the first embodiment, the portion of the control unit 2 for performing the lighting start operation in the solar light system is provided with a device capable of resetting the lighting start set voltage. By pressing the lighting start setting button of the switch SW1, an operation of setting the output voltage of the solar cell SB at that time as a new lighting start setting voltage is performed. This value can be stored in the control unit 2. Therefore, the lighting of the lamp 4 of the solar light can be started at the desired lighting start ambient illuminance.

Therefore, using the characteristic that the relationship between the output voltage of the solar cell SB and the ambient illuminance has little variation in a solid, the solar cell SB corresponding to the desired lighting start ambient illuminance is used.
The lighting can be started at the desired lighting start ambient illuminance by setting the output voltage of, and the setting of the lighting start illuminance of the solar light can be changed by changing the setting of the reference value.

To reset the lighting start set voltage,
Since this can be performed by pressing the lighting start setting button, it is easy and reliable to change the lighting start time of the solar light. Further, since the reset voltage of the lighting start set voltage can be reset only by pressing the lighting start setting button provided in the control unit 2, the customer can set the voltage at the site. Further, for adjustment when using multiple lamps, the lighting timing of each solar light can be adjusted without variation. Further, it is possible to match the lighting timing of the lighting fixture controlled by the EE switch with the lighting timing without variation.

A second embodiment of the present invention will be described with reference to FIG. That is, in the solar light, the setting of the reference value in the first embodiment is performed by the variable resistor.

According to this embodiment, the reference value can be set to another desired reference value by adjusting the variable resistor by turning the knob 13 of the variable resistor. In the method using the variable resistor, it is not necessary to be at the site at a desired ambient illuminance, but it is not possible to confirm at what time the illuminance will be started at that time.

The other points are the same as in the first embodiment.

A description will be given of a third embodiment of the present invention. In each of the above embodiments, the characteristics of the relationship between the output voltage of the solar cell and the ambient illuminance are small in solids, and the lighting is started at the desired ambient illuminance by setting the solar cell output voltage at the lighting start ambient illuminance. In order to match the start of lighting when multiple lamps are installed, a method of installing a time timer (not shown) to turn on and off the light is used.

A time timer is installed in the control unit 2 to set a light-on time and a light-off time, and turn on and off.

According to the third embodiment, by adjusting the lighting times, it is possible to eliminate variations in the lighting start times when multiple lamps are installed. However, lighting cannot be started with desired illuminance.

[0033]

According to the solar light according to the first aspect,
Using the characteristic that the relationship between the output voltage of the solar cell and the ambient illuminance has little variation in solids, the lighting is set at the desired lighting start ambient illuminance by setting the output voltage of the solar cell corresponding to the desired lighting start ambient illuminance. The setting can be started, and the setting of the lighting start illuminance of the solar light can be changed by changing the setting of the reference value.

According to the solar light of the second aspect, in addition to the same effects as those of the first aspect, the lighting start setting voltage can be reset by pressing the lighting start setting button. It is easy and reliable to change the lighting start time. Further, the lighting start setting voltage can be reset only by pressing the lighting start setting button installed in the control unit, so that the customer can set the lighting start setting voltage on site. Further, for adjustment when using multiple lamps, the lighting timing of each solar light can be adjusted without variation. Further, it is possible to match the lighting timing of the lighting fixture controlled by the EE switch with the lighting timing without variation.

According to the third aspect of the present invention, in addition to the same effects as those of the first aspect, the reference value is set to another desired reference value by adjusting the variable resistor by turning the knob of the variable resistor. be able to.

According to the solar light of the fourth aspect, the lighting time can be set by the time timer, and the turning-off time can also be set, so that turning on and off can be performed. Therefore, it is possible to eliminate variations in lighting start time when multiple lamps are installed.

[Brief description of the drawings]

FIG. 1 is a circuit block diagram according to a first embodiment of the present invention.

FIG. 2 is an external perspective view of a control unit.

FIG. 3 is an explanatory diagram illustrating configurations of a solar cell, a storage battery, and a control unit.

FIG. 4A is a graph showing turning on and off with respect to time, and FIG. 4B is an output voltage (V) of a solar cell with respect to irradiance (W / m ² ).

FIG. 5 is an external perspective view of a control unit according to a second embodiment.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Lighting circuit 2 Control unit SW1 Button switch SB Solar cell BT Storage battery IC2 General-purpose microcomputer IC IC3 Memory

 ──────────────────────────────────────────────────の Continuing on the front page (72) Kaoru Ibaru, Kazuma Kadoma, Osaka Prefecture, 1048 Kadoma, Matsushita Electric Works, Ltd.

Claims (4)

[Claims] 1. A solar battery, a storage battery for charging the power of the solar battery, a lighting circuit for lighting and operating with the power of the storage battery, and comparing the output voltage of the solar battery with a reference value that can be set variably. And a control unit for lighting the lighting circuit when the output voltage falls below the reference value. 2. The solar light according to claim 1, wherein the reference value is stored in a memory, and the reference value stored in the memory is rewritten to a value of the output voltage of the solar cell by a lighting start setting button. 3. The solar light according to claim 1, wherein the reference value is set by a variable resistor. 4. A solar battery comprising: a solar battery; a storage battery that charges the power of the solar battery; a lighting circuit that operates to light with the power of the storage battery; and a time timer that sets a time at which the lighting circuit starts lighting. Light.