RU59205U1 - OFFLINE LIGHTING - Google Patents

Abstract

The utility model relates to indoor lighting devices and is intended for use mainly in emergency situations in the absence of conventional (stationary) lighting. The self-contained illuminator is made of at least one light source associated with it through an element for controlling the energy supply of the battery and the photoelectric converter, while the self-contained illuminator is equipped with a sensing element for controlling illumination, connected in parallel with the photoelectric converter and connected to the element for controlling the supply energy. In an embodiment of an autonomous illuminator, it can be additionally equipped with a step-down voltage converter, made according to a reactance circuit, connected in parallel with a sensitive element for controlling illumination, and can also be equipped with a matching element associated with the battery. The technical result of the proposed utility model is to increase its life, as well as providing automatic control of turning on and off the light source.

Description

A self-contained illuminator refers to indoor lighting devices and is intended for use mainly in emergency situations in the absence of conventional (stationary) lighting.

A lighting device is known that contains a photoelectric converter and a battery and a light source connected to each other via respective switch contacts, a pulse step-up voltage regulator connected to a photoelectric converter and a charge current pulse shaper (see description of the invention RU 2256845, class F 21 S 19 / 00, published July 20, 2005).

A disadvantage of the known device is the insufficient duration of its operation during operation, as well as the lack of the ability to automatically control the on and off light source.

The technical result of the proposed utility model is to increase its life, as well as providing automatic control of turning on and off the light source.

The technical result of the proposed utility model is achieved by performing an autonomous illuminator from at least one light source associated with it through an element for controlling the energy supply of the battery and a photoelectric converter, while the autonomous illuminator is equipped with a sensitive element for controlling illumination connected in parallel with the photoelectric a transducer and an associated element for controlling power supply.

In addition, a self-contained illuminator can be equipped with a step-down voltage converter, made according to the reactance circuit, connected in parallel with a sensitive element for controlling illumination, containing a diode rectifier and a voltage level stabilizer.

In addition, an LED or an incandescent lamp, or a fluorescent lamp, or an energy-saving lamp can serve as a light source.

In addition, a self-contained illuminator may be equipped with a matching element associated with the battery.

The utility model is illustrated in figure 1, which schematically shows the connection of the elements of an autonomous illuminator.

The self-contained illuminator comprises at least one light source 1, an energy supply control element 2 through which a battery 3 is connected to the light source 1 and serving as a switch for controlling the energy supply to the light source 1 from the battery 3 and connected through an element 2 for controlling the energy supply with the light source 1 and the battery 3 of the photoelectric transducer 4, designed to produce in the daytime with sufficient natural light broadcasting the voltage and current required to charge the battery 3. The self-contained illuminator comprises a sensing element 5 for controlling the illumination connected in parallel with the photoelectric converter 4 and connected to the power supply control element 2, for monitoring the illumination at the location of the photoelectric converter 4 and supplying a signal to the element 2 to control the energy supply for switching the battery 3 from the mode of supplying voltage to the light source 1 in the off mode eniya from the light source 1 and vice versa. In an embodiment of an autonomous illuminator, in order to ensure recharging of the battery 3 from a stationary current source, a step-down voltage converter 6 connected to the battery 3 is additionally included in the reactance circuit and additionally contains a diode rectifier and a voltage level stabilizer (not shown) . also in

In an embodiment for using an autonomous illuminator as an emergency power supply, it additionally has a voltage output from the battery 3 by means of a matching element 7 associated with it, which represents the corresponding additional connectors.

With a decrease in illumination (lowering the voltage at the photoelectric converter 4 below a predetermined threshold value), the current flows through the sensing element 5 to control the illumination, which leads to the inclusion of the light source 1. When resuming the flow of current through the sensing element 5 to control the illumination - increase the illumination (voltage increase on the photoelectric converter 4 above a predetermined threshold value), the light source 1 is automatically turned off.

As the light source 1, an LED, or an incandescent lamp, or a fluorescent lamp, or an energy-saving lamp can be used.

The power supply control element 2 can be, for example, a transistor type switch or, for example, a relay type.

A sensing element 5 for controlling illumination is designed to determine when the light source 1 is turned on in the dark or when there is a lack of artificial or natural light.

The principle of operation of the sensing element 5 for light control is as follows:

- with sufficient illumination, the photoelectric converter 4 has an output voltage sufficient to trigger the sensing element 5 to control the illumination. As a sensing element 5 for controlling illumination, a parametric voltage stabilizer (zener diode) can be used,

introduced into the circuit of the photoelectric transducer 4, which when the stabilization voltage of the zener diode applied to it is exceeded, begins to pass an electric current. The current flowing through the sensing element 5 for controlling illumination is blocking for the element 2 for controlling the supply of energy, which leads to its closure and, therefore, to turn off the light source 1;

- when the illumination decreases below a predetermined threshold value, the voltage at the output of the photoelectric converter 4 also decreases and becomes lower than the response voltage (stabilization voltage) of the zener diode. When this current through the zener diode stops and, therefore, stops the blocking current for the element 2 to control the supply of energy, which opens and supplies voltage to the light source 1.

Thus, the use of an autonomous illuminator with the above characteristics allows it to be used for a functionally unlimited time in case of switching off stationary electric lighting. The self-contained illuminator automatically turns on (illuminates) with the onset of the dark time of the day and turns off when the morning comes - when the illumination on the photovoltaic converter rises, so it does not require external influence from the consumer to turn it on and off. An autonomous illuminator is able to receive additional charging of the battery from a stationary power supply network, it is quite economical and has a long glow time resource, and can also be successfully used as a backup power source to ensure the operation of various external current consumers.

Claims (5)

1. A stand-alone illuminator comprising at least one light source, connected thereto by means of an element for controlling the supply of energy to a battery and a photoelectric converter, characterized in that it is equipped with a sensing element for controlling illumination, connected in parallel with the photoelectric converter and connected to the element to control the power supply. 2. The self-contained illuminator according to claim 1, characterized in that it is equipped with a step-down voltage converter, made according to the reactance circuit, connected in parallel with a sensitive element for controlling light. 3. The stand-alone illuminator according to claim 2, characterized in that the step-down voltage converter further comprises a diode rectifier and a voltage level stabilizer. 4. The self-contained illuminator according to claim 1, characterized in that the light source is an LED, or an incandescent lamp, or a fluorescent lamp, or an energy-saving lamp. 5. The self-contained illuminator according to claim 1, characterized in that it is equipped with a matching element associated with the battery and serving to supply the stored energy to external current consumers.