UA9853U - Lighting unit - Google Patents

Abstract

The lighting unit has lighting block, the power input of this one is connected to accumulator battery; charging unit, the output of this one is connected to the accumulator battery, and control circuit; solar battery, this is connected to the input of the charging unit. The control circuit is arranged as a block for control of illumination, the first input of this one is connected to solar battery, the second input û to accumulator battery, and the output û to the control input of the lighting block.

Description

Description of the invention

The utility model refers to lighting equipment and can be used for the manufacture of both 2 autonomous portable and stationary lighting devices using solar batteries as a supply voltage generator.

Famous electric lighting device | D. Sirota. Battery-powered lamp. - Radio,

Mo11, 2001, p. 234), which contains a gas discharge lamp, a battery, a voltage converter and a control circuit (switching elements for selecting the operating mode of the illuminator). The converter is made in the form of a 70 autogenerator with a transformer, the output winding of which is connected to a gas discharge lamp.

The need to charge the rechargeable battery from the 2208 network causes the low efficiency of the device, and the dependence on the mains power source limits the autonomy of such an illuminator.

The closest to the proposed solution is a lighting device (V.M. Polei. Small-sized high-voltage converters.-Radioamator, 2003, Mo10, p. 36-37|), which contains a lighting unit, the power 12 input of which is connected to a battery, a charger a device whose output is connected to a storage battery and a control circuit.The lighting unit consists of a gas discharge lamp and a voltage converter for supplying the gas discharge lamp, and the control circuit is a multi-position mechanical switch.

Such a lighting device does not provide battery protection during overcharging or critical discharge, which significantly reduces its service life. The power at the output of the converter is regulated discretely by a transistor with two positions, which involves the use of two lamps (to increase the voltage at the output of the converter). In addition, with such a connection, the operation of the illuminator in the mode of two lamps is unstable. In addition, the mains voltage 2208 is required to charge the battery, which cannot always be provided, especially during long journeys and in inaccessible places.

The useful model is based on the task of creating an economical and reliable autonomous 22 lighting device by ensuring the ability to perform various functions with one unit of the device: - generation of electrical energy, control of the level of illumination, creation of conditions for reliable operation of the battery.

The task is solved by the fact that the lighting device, which contains the lighting unit, the power input of which is connected to the battery, the charger, the output of which is connected to the battery and the control circuit, according to the useful model, additionally contains a solar battery, under connected to the input of the charger, and the control circuit is made in the form of a lighting control unit, the first input of which is connected to the solar battery, the second input to the storage battery, and the output to the control input of the lighting unit. The control circuit may additionally contain a unit for monitoring the discharge of the battery F battery, the input of which is connected to the battery, and the output - to the control input of the lighting unit. 325 The charger can be made in the form of a diode, the anode of which is connected to the solar battery, and the cathode - to the battery. The lighting unit can be made in the form of a gas discharge lamp connected to the output of the converter, the power input of which is connected to the battery, and the control input to the outputs of the lighting control unit and the discharge control unit. In addition, the solar battery can be connected to the first -(Ш-) input of the lighting control unit and the input of the charger through a connector, and a switch can be installed at the output of the battery. c In the proposed device, the solar battery serves simultaneously as an electricity generator for charging

With" a battery during daylight hours and a light level sensor. This provides double energy savings: savings from using solar energy to charge the battery and savings from automatically turning off the device at high light levels during the day. At the same time, the possibility of selecting the voltage of the solar battery depending on the used battery allows you to avoid the failure of the latter due to its recharging. In addition, the ability to monitor the state of battery discharge and turn off the load when a critical discharge is reached also allows you to significantly extend the life of the battery, protecting it from destruction by deep discharge. As a result, the proposed lighting device has a number of advantages: se" 20 - allows you to charge the battery independently from the solar battery without using mains voltage, and this makes it possible to use it in places remote from the centralized power supply and save electricity; - provides the ability to control the lighting of the solar battery and automatically turn on the lighting when it gets dark - a gas-discharge lamp that can be used for autonomous automatic

Co» illumination of certain objects or territories; - the scheme for charging the battery is significantly simplified due to the use of the advantages of the solar battery; - the functionality of the device is expanded, as it is possible to place the solar battery at a distance from the lighting unit. 60 The drawing shows the block diagram of the lighting device.

The device consists of a lighting unit 1, the power input of which is connected to a storage battery (AB) 2, a charger (ZP) 3, the output of which is connected to a storage battery 2, a control circuit 4 and a solar battery (SB) 5. Diagram control (SC) 4 consists of the lighting control unit 6 (SBC) and the battery 2 discharge control unit 7, and the first input of the unit 6 is connected to the solar battery 5, because the second input is to the battery 2, and the output is to the controller the input of the lighting unit 1. The input of the discharge control unit 7 (BKR) is connected to the battery 2, and the output is connected to the control input of the lighting unit 1. The figure shows the implementation of the lighting unit 1 in the form of a gas discharge lamp (L) 8, connected with the output of the converter (P) 9, the power input of which is connected to the battery 2, and the control input is connected to the outputs of the lighting control unit 6 and the discharge control unit 7. It should be noted that a different design of the lighting unit is possible, for example, in the form of a light-emitting diode or a halogen incandescent lamp. The solar battery 5 is connected to the first input of the lighting control unit 6 and the input of the charger C through a connector 10, and a switch 11 is installed at the output of the battery 2. The charger C is made in the form of a diode 3, the anode of which is connected to the solar battery 5, and cathode - to battery 2. 70 The proposed lighting device works as follows.

The electrical energy produced by the solar battery 5 flows through the diode C (to reduce energy losses, a Schottky diode is used) to the storage battery 2 for its charging. Moreover, the voltage of the solar battery 5 is selected in such a way that the battery 2 does not overcharge. From the battery 2, the supply voltage is supplied to the converter 9 and the control circuit 4. Both control units 6, 7 7/5 function independently of each other and work to prohibit the operation of the converter 9 by applying an electrical signal (low voltage potential) to it. If the illumination of the solar battery 5 decreases and the voltage generated by the solar battery 5 becomes less than the voltage that is proportional to the voltage at the second input of the illumination control unit 6 (regulated when adjusting the sensitivity of the illumination control unit), then the output of the unit 6 goes into a high-resistance state (state with a high output resistance), which allows the operation of the converter 9. When the illumination of the solar battery 5 increases, a low voltage signal (prohibition signal) appears at the output of the control unit b and blocks the operation of the converter 9. The electrical energy produced by the solar battery 5 flows through the diode Connect to battery 2 and it charges.

If the voltage on the battery 2 is within the permissible limits, then the output of the discharge control unit 7 is in a high-resistance state and the operation of the converter 9 is allowed - the lamp 8 is turned on. In the case of a decrease in the voltage on the battery 2 below the permissible value, a low voltage potential appears at the output of the discharge control unit 7, which blocks the operation of the converter 9 and turns off the gas discharge lamp 8.

As noted, the solar battery 5 is connected to other units of the device through a connector 10. This allows, using an extension cord, to place the solar battery 5 at a certain distance from the lighting unit 1, which expands the functionality of the lighting device. In addition, this device has a solar battery of 5 s

Zo serves not only as an electric current generator to charge battery 2 during daylight hours, but also as a light level sensor for automatic operation. When the solar battery 5 is disconnected from the lighting unit 1, the disconnector 10 is activated in such a way that it closes the contacts between themselves, as a result of which the voltage potential at the first input of the lighting control unit 6 becomes low and, accordingly, the output of the unit 6 becomes high-impedance the state and block b does not affect the operation of the converter 9. In this mode of operation, the lighting unit 1 is turned off by the switch 11.

The proposed lighting device can be manufactured using standard elements of electronic equipment. The following components can be used: a solar battery of mass production in Ukraine or Russia, any compact battery, for example, made in China, a gas-discharge lamp - O-shaped or ordinary finger-cylindrical, for example, from the company "RAiirz". Block b lighting control and block 7 Z

Discharge control is represented by operational amplifiers that work in comparator mode. c The proposed lighting device is characterized by compactness, light weight, stable operation, economy and can be used both in stationary and on-the-go conditions, when other sources;" power supplies are missing or their use is less appropriate.

Claims (5)

The formula of the invention se) co 1. A lighting device containing a lighting unit, the power input of which is connected to a storage battery, a charger, the output of which is connected to a storage battery and a control circuit, which is characterized by the fact that the device additionally contains a solar battery connected to the input of the charging device, and the control circuit is made in the form of a lighting control unit, the first input of which is connected to the solar battery, the second input to the storage battery, and the output to the control input of the lighting unit. 2. The lighting device according to claim 1, which is characterized by the fact that the control circuit additionally includes a C;o55 battery discharge monitoring unit, the input of which is connected to the battery, and the output is connected to the control input of the lighting unit. C. The lighting device according to claim 1, which differs in that the charger is made in the form of a diode, the anode of which is connected to a solar battery, and the cathode is connected to a battery. 4. The lighting device according to claims 1, 2, which is characterized by the fact that the lighting unit is made in the form of a gas discharge lamp connected to the output of the converter, the power input of which is connected to the battery, and the control input to the outputs of the lighting control unit and discharge control unit. 5. Lighting device according to claims 1, 2, which is characterized by the fact that the solar battery is connected to the first input of the lighting control unit and the input of the charger through a connector, and a switch is installed at the output of the battery. b5