JPH067386U - Infrared remote control transmitter for transmitter - Google Patents

Abstract

(57) [Summary] [Purpose] By increasing the output of infrared rays, which is the remote control signal when the fluorescent lamp is on,
Improve the S / N ratio and improve the operability of the infrared remote control control lighting fixture lighting fixture. [Structure] A lighting device for lighting a fluorescent lamp is blinked by remote control, and a control section 6 blinks an infrared light emitting element 4 composed of an infrared light emitting diode in a predetermined signal pattern. A main power source 1 which is made up of a battery and supplies power to the infrared light emitting element 4 is provided, and a power source which is made up of a solar cell which receives illumination light from a lighting fixture to generate power and cooperates with the main power source 1 to supply power to the infrared light emitting element 4 is provided. A power supply 7 is provided.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 This invention is a transmitter for an infrared remote control control lighting device that blinks the infrared remote control control lighting device such as a fluorescent lamp lighting device incorporating an inverter type lighting device by remote control by sending a remote control signal by an infrared light emitting diode or the like. It is about.

[0002]

[Prior art]

 2. Description of the Related Art Conventionally, an infrared remote control device using infrared rays as a remote control signal has been used so that lighting equipment can be turned on, turned off, and dimming can be selected at hand. The infrared remote control control lighting device transmitter in the infrared remote control device is configured by adding peripheral parts to a control circuit composed of an integrated circuit which is generalized for infrared remote control. The infrared remote control transmitter for lighting equipment uses a battery as a power source and switches the state in the order of turning off → all lighting → dimming lighting → turning off each time the switch connected to the control circuit is turned on once. A corresponding signal is generated from the control circuit and the infrared emitting diode is blinked in the corresponding signal pattern to send the remote control signal.

On the other hand, the lighting equipment is provided with an infrared remote control receiver. That is, the lighting equipment has an inverter type lighting device that lights the fluorescent lamp by the output of the high frequency inverter, and by controlling the output level of the high frequency inverter by the switch circuit, the full lighting state, the dimming lighting state and the unlit state. And can be selected. This switch circuit is controlled by the remote control signal sent from the infrared remote control control lighting device transmitter. That is, the remote control signal is received by the photodiode, the output of the photodiode is input to the control circuit consisting of a general-purpose integrated circuit for infrared remote control, the remote control signal is decoded, and the switch circuit is controlled according to its meaning. is there.

By the way, when the output frequency of the above high-frequency inverter is, for example, 42 kHz, the emitted light immediately after the fluorescent lamp (for example, FDL27 manufactured by Matsushita Electric Works, Ltd.) and the emitted light 10 minutes after the lighting are respectively Spectral distribution (wavelength (nm) -relative irradiance (%) characteristics) as shown in FIGS. 3 and 4 is obtained. That is, immediately after the fluorescent lamp is turned on, the spectrum due to the argon gas enclosed in the fluorescent lamp appears at 780 to 860 nm and 900 to 940 nm, and when the lighting state of the fluorescent lamp is stable, the spectrum due to mercury appears at 1013 nm.

In FIG. 4, the alternate long and short dash line A ₁ indicates the characteristics of the wavelength (nm) of the infrared light emitting diode (λ _P = 900 nm) -relative irradiance (%), and the alternate long and short dash line A ₂ indicates the infrared light emitting diode. The characteristic (wavelength (nm) of (λ _P = 950 nm) -relative irradiance (%)) is shown, and the broken line A ₃ is the characteristic of a shortcut filter that transmits light having a wavelength of 1000 nm or less.

[0006]

[Problems to be solved by the device]

The red rays emitted from the fluorescent lamp are mainly incident on the photodiode provided in the lighting fixture. Here, since the infrared light emitting diode has a central peak at 880 to 950 nm as shown by a chain double-dashed line A ₁ in FIG. 4, the ambient temperature is low, and moreover, immediately after the fluorescent lamp is turned on, The infrared rays emitted from the argon gas generated by the fluorescent lamp and the infrared rays emitted from the infrared light emitting diode cannot be discriminated from each other, which may cause malfunction or non-operation of the luminaire.

[0007] In addition, when the temperature of the fluorescent lamp is low, the luminous intensity of the fluorescent lamp is usually higher than that at room temperature. Therefore, not only when the ambient temperature is low, However, there was a problem that the light emission brightness was high even immediately after lighting, which made it more difficult to receive remote control signals. Infrared rays are not emitted from the fluorescent lamp when the fluorescent lamp is off. However, when the fluorescent lamp is turned on by the inverter type lighting device, the infrared rays are emitted as noise from the fluorescent lamp, and the infrared remote control control lighting device. The S / N ratio of the remote control signal from the power transmitter decreases. Due to this decrease in the S / N ratio, there is a problem that the operability of the infrared ray remote control controlled lighting fixture is deteriorated.

An object of the present invention is to improve the S / N ratio by increasing the output of infrared rays, which is a remote control signal when the fluorescent lamp is lit, and to improve the operability of the infrared remote control lighting equipment. It is an object of the present invention to provide a transmitter for an infrared remote control controlled lighting device that can improve the above.

[0009]

[Means for Solving the Problems]

 An infrared remote control control lighting device transmitter according to the present invention is for remotely lighting a lighting device for lighting a fluorescent lamp. An infrared light emitting element and a control unit for flashing the infrared light emitting element in a predetermined signal pattern. And a main power supply consisting of a battery for supplying electric power to the infrared light emitting element, and an auxiliary power supply consisting of a solar cell for receiving the illumination light from a lighting fixture to generate power and supplying electric power to the infrared light emitting element in cooperation with the main power supply ing.

[0010]

[Action]

 According to the configuration of this invention, there are the following effects. When the fluorescent lamp is turned off, the infrared light emitting element in the transmitter for infrared remote control lighting equipment is supplied with electric power only from the battery which is the main power source. When the fluorescent lamp is lit (it is easily affected by noise), the solar battery, which is an auxiliary power source, uses the illumination light as an energy source to generate electricity, and the infrared light emitting element in the infrared remote control light source transmitter The power is supplied from the battery, which is the main power source, as well as from the solar cell. As a result, even if infrared rays that generate noise from the infrared remote control control lighting fixture are generated from the infrared remote control control lighting fixture, the power supply from the solar cell increases, so the level of the remote control signal can be increased. Therefore, malfunction due to noise can be suppressed.

If the output of infrared rays, which is a remote control signal, is simply increased, the power supplied from the battery, which is the main power source, to the infrared light emitting element may be increased. In this case, the power source is the main power source. Battery life is greatly reduced, which is a problem for commercial products. The present invention is intended to improve the operability of an infrared remote control lighting device without accelerating battery consumption.

[0012]

【Example】

 A first embodiment of the present invention will be described with reference to FIG. This infrared remote control illuminator transmitter, for example, has a built-in inverter type lighting device to remotely flash a luminaire for lighting a fluorescent lamp, for example, as shown in FIG. A series circuit of 1 and a diode 2 is connected to a series circuit of a resistor 3, an infrared light emitting element 4 composed of an infrared light emitting diode, and a transistor 5. An auxiliary power supply 7 made of a solar cell and a capacitor 8 are connected in parallel to the diode 2. The blinking of the infrared light emitting element 4 is controlled by turning on / off the transistor 5 by the control unit 6.

In the configuration described above, the control unit 6 causes the infrared light emitting element 4 to blink via the transistor 5 in a predetermined signal pattern. The main power supply 1 consisting of a battery supplies electric power to the infrared light emitting element 4, and the auxiliary power supply 7 consisting of a solar cell which receives illumination light from a lighting fixture to generate electric power supplies the infrared light emitting element 4 with electric power in cooperation with the main power supply 1. Supply. When the fluorescent lamp is turned off, the infrared light emitting element 4 in the infrared remote control light source transmitter is supplied with power only from the battery which is the main power source 1. In addition, when the fluorescent lamp is turned on (it is easily affected by infrared noise), the solar battery that is the auxiliary power source 7 generates power by using the illumination light as an energy source, and the infrared light emitting element in the transmitter for the infrared remote control control lighting fixture. Power is supplied to 4 from the battery that is the main power supply 1, and power is supplied from the auxiliary power supply 7 that is a solar battery. As a result, even if the infrared remote control lighting equipment emits infrared rays that generate noise when the infrared remote control lighting equipment is turned on, the amount of power supplied from the auxiliary power supply 7 consisting of solar cells increases, so the remote control signal It is possible to raise the level of the infrared ray, suppress malfunctions due to noise, and improve the operability of the infrared remote control controlled lighting equipment. Further, since the power supplied from the main power source 1 to the infrared light emitting element 4 is not increased, the life of the battery which is the main power source 1 is not shortened.

The difference in the current flowing through the infrared light emitting element 4 when the fluorescent lamp is off and when it is on will be described. When the electromotive force of the main power source 1 is E, the voltage generated across the capacitor 8 by the solar battery that is the auxiliary power source 7 is E ', and the resistance value of the resistor 3 is R, infrared rays are emitted when the fluorescent lamp is turned off. The current I ₁ flowing through the light emitting element 4 is

[0015]

## EQU1 ## I ₁ = E / R. When the fluorescent lamp is turned on, the current I ₁ flowing through the infrared light emitting element 4 is

[0016]

## EQU2 ## I ₂ = (E + E ') / R. Therefore,

[0017]

## EQU00003 ## I ₁ << I ₂ can be set, and the level of the remote control signal when the fluorescent lamp is turned on can be significantly increased compared to the level of the remote control signal when the fluorescent lamp is turned off. The N ratio can be greatly increased. As a result, even if there is red noise when the fluorescent lamp is lit, the remote control operation can be performed well.

The solar battery, which is the auxiliary power supply 7, can not only convert the illumination light from the infrared remote control control lighting fixture into electric power, but also can convert natural light into electric power. In this case as well, the main power supply 1 can be used. The output of the infrared light emitting element 4 can be increased without increasing the power consumption of a certain battery, that is, without shortening the life of the battery. Needless to say, natural light may be converted into electric power to exhibit the same effect.

A second embodiment of the present invention will be described with reference to FIG. This infrared remote control control transmitter for lighting fixtures has a built-in inverter type lighting device to turn on and off the lighting fixtures for lighting fluorescent lamps. As shown in FIG. A series circuit of a resistor 3, an infrared light emitting element 4 and a transistor 5 is connected. A series circuit of a main power source 1 and a resistor 3 is connected in parallel with a series circuit of an auxiliary power source 7 made of a solar cell and a resistor 3 ', and a capacitor 8 is connected in parallel with the auxiliary power source 7. The blinking of the infrared light emitting element 4 is controlled by turning on / off the transistor 5 by the control unit 6.

In the configuration as described above, the control unit 6 causes the infrared light emitting element 4 to blink through the transistor 5 in a predetermined signal pattern. The main power supply 1 consisting of a battery supplies electric power to the infrared light emitting element 4, and the auxiliary power supply 7 consisting of a solar cell which receives illumination light from a lighting fixture to generate electric power supplies the infrared light emitting element 4 with electric power in cooperation with the main power supply 1. Supply. When the fluorescent lamp is turned off, the infrared light emitting element 4 in the infrared remote control light source transmitter is supplied with power only from the battery which is the main power source 1. In addition, when the fluorescent lamp is turned on (it is easily affected by infrared noise), the solar battery that is the auxiliary power source 7 generates power by using the illumination light as an energy source, and the infrared light emitting element in the transmitter for the infrared remote control control lighting fixture. Power is supplied to 4 from the battery that is the main power supply 1, and power is supplied from the auxiliary power supply 7 that is a solar battery. As a result, even if the infrared remote control lighting equipment emits infrared rays that generate noise when the infrared remote control lighting equipment is turned on, the amount of power supplied from the auxiliary power supply 7 consisting of solar cells increases, so the remote control signal It is possible to raise the level of the infrared ray, suppress malfunctions due to noise, and improve the operability of the infrared remote control controlled lighting equipment. Further, since the power supplied from the main power source 1 to the infrared light emitting element 4 is not increased, the life of the battery which is the main power source 1 is not shortened.

Here, a difference in current flowing through the infrared light emitting element 4 when the fluorescent lamp is turned off and when it is turned on will be described. When the electromotive force of the main power source 1 is E, the voltage generated across the capacitor 8 by the solar cell that is the auxiliary power source 7 is E ', and the resistance values of the resistors 3 and 3'are R and R', respectively, When the fluorescent lamp is turned off, the current I ₁ flowing through the infrared light emitting element 4 is

[0022]

## EQU00004 ## I ₁ = E / R. When the fluorescent lamp is turned on, the current I ₁ flowing through the infrared light emitting element 4 is

[0023]

## EQU5 ## I ₂ = E / R + E '/ R'. Therefore,

[0024]

[Equation 6] I ₁ << I ₂ can be set, and the level of the remote control signal when the fluorescent lamp is turned on can be significantly increased compared to the level of the remote control signal when the fluorescent lamp is turned off. The N ratio can be greatly increased. As a result, even if there is red noise when the fluorescent lamp is turned on, the remote control operation can be favorably performed, and the operability of the infrared remote control control lighting device can be improved.

In each of the above-described embodiments, the infrared remote control control lighting fixture is described as lighting the fluorescent lamp using the inverter lighting device, but the lighting device is not limited to the inverter lighting device. The present invention can also be applied to an infrared remote control controlled lighting device having a normal copper-iron type lighting device. Further, the light source of the lighting equipment is not limited to the fluorescent lamp, and the present invention can be applied to any light source that emits infrared rays whose wavelength band overlaps with infrared rays which are remote control signals.

[0026]

[Effect of device]

 According to the infrared remote control control lighting device transmitter of the present invention, an auxiliary power source composed of a solar cell for converting the illumination light of the infrared remote control lighting device into electric power is provided, and the infrared light emitting element is also powered from this auxiliary power source. Since the power is supplied, the level of the remote control signal can be increased when the fluorescent lamp of the infrared remote control control lighting fixture is turned on and the infrared noise is large. As a result, even if infrared rays that generate noise due to lighting of the infrared remote control control lighting equipment are generated from the infrared remote control control lighting equipment, the power supply from the auxiliary power source consisting of solar cells increases, so the level of the remote control signal level increases. Can be improved, malfunctions due to noise can be suppressed, and the operability of the infrared remote control-controlled lighting device can be improved. Moreover, since the power supplied from the main power source to the infrared light emitting element is not increased, the life of the battery, which is the main power source, is not shortened.

[Brief description of drawings]

FIG. 1 is a circuit diagram showing a configuration of an infrared remote controller-controlled lighting device transmitter according to a first embodiment of the present invention.

FIG. 2 is a circuit diagram showing a configuration of a transmitter for infrared remote control controlled lighting equipment according to a second embodiment of the present invention.

FIG. 3 is a spectrum diagram (wavelength-relative irradiance characteristic diagram) of radiated light immediately after a fluorescent lamp is turned on.

FIG. 4 is a spectrum diagram (wavelength-relative irradiance characteristic diagram) of radiated light 10 minutes after the fluorescent lamp is turned on.

[Explanation of symbols]

 1 main power supply 2 diode 3, 3'resistor 4 infrared light emitting element 5 transistor 6 control unit 7 auxiliary power supply 8 capacitor

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁵ Identification code Office reference number FI technical display location H05B 37/02 C 8715-3K

Claims (1)

[Scope of utility model registration request] 1. A transmitter for an infrared remote control illuminator for remotely illuminating an illuminator, comprising an infrared light emitting element, a controller for blinking the infrared light emitting element in a predetermined signal pattern, and a battery. Infrared provided with a main power source for supplying power to the infrared light emitting element, and an auxiliary power source comprising a solar cell for generating power by receiving illumination light from the lighting fixture, and an auxiliary power source for supplying power to the infrared light emitting element in cooperation with the main power source. Transmitter for remote control lighting equipment.