JPS63128597A - Lighting equipment - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed description of the invention] (Industrial application field) The present invention relates to a lighting device.

(Prior Art) Generally, in a lighting device, a lamp 2 emits light by a power source 1, as shown in FIG.

When the power source 1 is a battery, for example, the time during which the lamp 2 can emit light is determined by the capacities of the lamp 2 and the battery, and is therefore limited.

On the other hand, in some lighting devices, it is required to make the illuminance variable. Conventionally, in order to change the illumination intensity of the lamp 2, it is necessary to insert a resistor 3 between the power source 1 and the lamp 2. It has been done.

(Problem to be solved by the invention) However, by inserting the resistor 3, the lamp 2
When the illuminance of the resistor 3 is changed, power is also consumed by the resistor 3, and since the power source is limited as described above, the power consumed by this resistor is extremely wasteful.

The purpose of the present invention is mainly to effectively utilize the power source to extend the illumination time, and particularly to eliminate unnecessary power consumption even when adjustment of illuminance is required.

(Means for Solving the Problems) In order to achieve the above object, the lighting device of the present invention includes a photoelectric element that receives light from a lamp, converts it into an electric signal, and outputs it, and an electric signal generated by the photoelectric element. and a high/low reference signal, and outputs an ON signal when the signal from the photoelectric element is lower than the lower reference signal, and outputs an OFF signal when it is higher than the higher reference signal; The basic configuration includes a controller that inputs the output signal of the comparator and makes the power supply conductive to the lamp when the signal is ON, and does not make the power supply conductive when it is OFF. The above-mentioned high and low reference signals can be adjusted in level.

(Function and Effect) Generally, when a voltage (V) with a rectangular waveform as shown by the solid line in Figure 5 is applied to the lamp, the response waveform of the lamp illuminance (D8) is constant as shown by the two-dot chain line in the figure. Shows rising and falling with a delay.

With the above configuration, the present invention can effectively utilize this characteristic, and has the following effects.

That is, the photoelectric element receives light from the lamp, converts it into an electrical signal, and outputs it. The comparator compares the electrical signal from this photoelectric element with a high and low reference signal, and turns ON when the signal from the photoelectric element is lower than the lower reference signal.
When the signal is higher than the higher reference signal, an OFF signal is output. When the output signal from the comparator is ON, the controller conducts the power supply to the lamp, so that a voltage is applied to the lamp. When the output signal from the comparator is OFF, it does not conduct, so that the voltage applied to the lamp is OFF.

Therefore, if we take the reference signal corresponding to the higher illuminance,
□If the reference signal corresponding to the lower illuminance is L□ (see Figure 5), when the lamp illuminance obtained as an electrical signal by the photoelectric element exceeds L@a11, the voltage application is turned off. As a result, the lamp illuminance falls with a certain delay as described above, and when it falls below L, rl, the voltage application is turned on and the lamp illuminance rises with a certain delay as mentioned above. This operation will be repeated. As a result, the lamp illuminance is maintained between .

In this case, the lamp illuminance increases from □ to L s r
Since no voltage is applied until it drops to n,
Electric power will be saved accordingly.

Furthermore, in this case, even when the voltage application is turned off, the lamp illuminance falls with a certain delay, so the lamp illuminance as a whole does not decrease much.

Moreover, when illuminance adjustment is required, it is sufficient to lower both the levels of the high and low reference signals L88M and La1n, or to lower only Lsrn, and in this case, power consumption is further reduced. That will happen.

As described above, according to the present invention, it is possible to effectively utilize a 1ML source to extend the illumination time, and even if a uniform illuminance of l is required, no power is wasted. Therefore, it will be used even more effectively.

(Example) The illustrated embodiment will be described below.

FIG. 1 is a block diagram showing an embodiment of a lighting device according to the present invention.

In the figure, reference numeral 10 denotes a photoelectric element, which is placed on the back of the reflector 4 of the lamp 2, as shown in FIG. It is designed to receive light. The photoelectric element IO converts the received light into an electrical signal a and outputs it. A general optical sensor may be used as the photoelectric element, but since its output signal a is usually small, it is amplified by an amplifier 11 to obtain a.

12 is a comparator which outputs the electric signal a° from the photoelectric element 10 and the high/low reference signal L□X) Llli.

(Hereinafter, this will also be used as the code of the reference signal value). Then, this comparator 12 connects the electric signal a'' from the photoelectric element 1O and the high and low reference signals L□Yo, L□
. When the signal a° from the photoelectric element is lower than the lower reference signal L□8, the ON signal is used, and when it is higher than the higher reference signal L□8, the OFF signal will be described later. Output to the controller 13. Reference numeral 14 denotes a reference signal generator, which includes variable resistors 17 and 18, whereby the high and low reference signals L maM t Llli
It is now possible to adjust the level of ll.

A controller 13 is connected to the comparator 12, the lamp 2, and the power source 15. When the output signal from the comparator 12 is ON, the controller 13 connects the power source 15 to the lamp 2 and connects the lamp 2.
A voltage is applied to the lamp 2, and when the lamp 2 is turned off, the power supply 15 is not made conductive and the voltage application state to the lamp 2 is turned off. 16 is a power supply check circuit, and power supply 1
When the battery 5 is configured with a battery or the like, it is designed to prevent over-discharge of the battery or the like and protect the battery or the like. Sho 1
Numeral 9 is a variable resistor, which allows the value of the voltage applied to the lamp 2 to be adjusted.For the reasons mentioned above, it is not normally used. Use only when it is necessary to reduce the illuminance of step 2.

The above device uses variable resistors 17 and 18,
The higher reference signal value corresponding to the illumination intensity and the lower reference signal value corresponding to the degree of sliding are set and used, and their operation is as follows. Become.

That is, when the power switch is first turned on, a predetermined voltage V is applied to the lamp 2 as shown in FIG. The lamp illuminance l1M obtained as the electric signal a° is the lower reference signal value □. Therefore, the voltage application state is maintained by the operation of the comparator 12 and the controller 13. Then, after T1 time, the lamp illuminance reaches the higher reference signal value, and when it exceeds □, the voltage is immediately applied or turned off by the operation of the comparator 12 and controller 13, and the lamp illuminance rises with a certain delay as described above. (3rd
(See Figure D□). After 12 hours, if the lamp illuminance falls below the lower reference signal value LI1.11, comparator 1
2 and the controller 13, the voltage application is turned ON again, and the lamp illuminance rises with a certain delay as described above (see FIG. 11).

Furthermore, when the lamp illuminance exceeds the higher reference signal value L□yo after T1 time, the voltage application is immediately turned off by the operation of the comparator 12 and the controller 13, and the lamp illuminance falls with a certain delay. Become(
(See FIG. 3 D0), and then, until the power switch is turned off, this operation, that is, the operation indicated by 'J xt and 01, is repeated. As a result, the lamp illuminance was between 18 and Ll, 7, which was L□ as a whole. and La
It will be maintained at a value higher than the intermediate value of Ill i +1. Again, this value varies depending on the response characteristics of the lamp 2.

In this case, the lamp illuminance is L□8 to L wa i
. Since no voltage is applied during the time T2 until the voltage drops to zero, power is saved by that amount T2.
Although T1 varies depending on the characteristics of the lamp, in general, as shown in FIG. 3, approximately T2 = Tx, so the power consumption is approximately halved compared to the conventional one. Furthermore, in this case, even if the voltage is applied or turned off, the lamp illuminance falls with a certain delay, so the lamp illuminance as a whole does not decrease much.

Moreover, if illuminance adjustment is required, the variable resistor 1
7.18, the high and low reference signals L m a wL m
Either lower the levels of r and n, or L□. In this case, power consumption is further reduced.

Furthermore, when the illuminance of the lamp 2 is lowered by inserting the resistor 3 as in the conventional device, the color temperature of the lamp 2 also drops significantly, making it unsuitable for lighting for photographing, but the present invention In this case, the color temperature does not drop much overall, so it is also suitable as lighting for photography.

Although one embodiment of the present invention has been described above, it goes without saying that the present invention is not limited to the above-mentioned embodiment, and can be modified as appropriate within the scope of the gist of the invention.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing an embodiment of the lighting device according to the present invention, FIG. 2 is a schematic diagram showing the lamp portion of the same, FIG. 3 is an explanatory diagram of the operation of the same, and FIG. 4 is an explanatory diagram of the conventional device. FIG. 5 is a waveform diagram showing the response characteristics of a general lamp. 2... Lamp, 10... Photoelectric element, 12... Comparator, 13... Controller, 15... Power supply. ,,J,C ε ε''

Claims (2)

[Claims] (1) In a lighting device that includes a power source and a lamp that emits light when energized by the power source, a photoelectric element that receives light from the lamp, converts it into an electrical signal, and outputs it, and this photoelectric element A comparator that inputs an electrical signal from the photoelectric element and a high/low reference signal, and outputs an ON signal when the signal from the photoelectric element is lower than the lower reference signal, and an OFF signal when it is higher than the higher reference signal. and a controller to which the output signal of the comparator is input, and when the signal is ON, the power source is made conductive to the lamp, and when the signal is OFF, the power source is not conductive. (2) The lighting device according to claim 1, wherein the levels of the high and low reference signals are adjustable.