UA68705A - Alternating-current power-supply source for luminescence lamps - Google Patents

Abstract

The proposed alternating-current power-supply source for two luminescence lamps contains an electronic chopper, a current converter, a high-voltage generator, a unit for lighting the lamps, and a unit for controlling the light intensity of the lamps. The lamps are connected to the output of the high-voltage generator. The output of the unit for lighting the lamps is connected to the control input of the generator. The output of the unit for controlling the light intensity of the lamps is connected to the control input of the chopper.

Description

Description of the invention

The invention relates to lighting equipment, and more specifically, it relates to power sources for 2 fluorescent lamps, in particular, AC power sources of industrial frequency.

It is known that a fourth part of the electricity produced in the world is consumed by artificial lighting systems, so this area is extremely attractive for efforts to improve the efficiency of use and reduce electricity consumption.

Currently, the most common economic light sources are gas discharge lamps, which are increasingly used instead of conventional incandescent lamps. In addition, fluorescent lamps have a much longer service life compared to incandescent lamps. However, the widespread implementation of fluorescent lamps is hindered by the need for an expensive choke, and the service life of the lamps is limited by the premature burnout of the filaments.

The principle of their operation consists in the luminescent glow of the gas that fills the lamp when an electric current flows through it (high-voltage breakdown), which is provided by applying high voltage to the lamp's electrodes. Gas discharge lamps can be divided into two types, the first is lamps of high luminous intensity and fluorescent lamps of low pressure. Low-pressure lamps are used for lighting in most cases of everyday life - in administrative buildings, offices, residential premises. they are distinguished by a saturated white light, close to daylight (hence the name - "daylight lamps"). High-pressure lamps are used for outdoor lighting - in street lamps, floodlights, etc.

If a conventional incandescent lamp, when turned on, is a constant resistive load, then all gas discharge lamps have negative impedance characteristics that require current stabilization. In addition, it is necessary to take into account such points as: resonance mode of operation, protection in case of lamp failure; high-voltage ignition, special power bus control. The main mode, which must be observed throughout the lifetime of the fluorescent lamp, is the current mode (ideally, "stabilization of power is necessary throughout the lifetime of the lamp).

Currently, a large number of various devices for powering fluorescent lamps are described in the scientific and technical and patent literature |1). As a rule, the lamps are powered by an alternating voltage to equalize the wear of the electrodes (in the case of a constant voltage supply, the service life is shorter by 5095). A so-called magnetic ballast was traditionally used to control gas-discharge lamps, but due to its inefficiency and unreliability, recently electronic control schemes have become more and more common - electronic ballast, which allows to increase the efficiency and service life of lighting systems, to make the light more evenly and natural for the eyes. with

It is known that the ability to control the luminous flux of light emitters is of great importance in lighting engineering. It is possible to control the luminous flux of fluorescent lamps either by completely turning off the supply of fluorescent lamps, or by changing the voltage and current of fluorescent lamps. When using the first method, it is necessary to create a powerful electronic unit to disconnect the supply voltage from electronic ballasts. The second way is characterized by the fact that each ZPRA (electronic starter control device) has an input for supplying a low-voltage control signal. This signal affects the ZPRA control circuit C 50, thereby changing the current and voltage of the fluorescent lamp. The advantages of the first method c include the maximum possible energy saving, however, it is impossible to achieve smooth

From" controlling the luminous flux of fluorescent lamps. When using controlled ZPRA, the main disadvantage is the presence of energy consumption even when there is no discharge in the lamp. In this mode, energy consumption occurs in the control circuit of the electronic ballast and losses in the cathodes of the lamp, which are necessary for their piercing, also occur. b The main issue that arises when creating power supply units for fluorescent lamps with the ability to control the light flow is the maximum reduction of their price with maximum energy saving. At the same time, the main preference is given to systems with smooth adjustment of the light flux in the widest possible 7 ranges. aw! 20 There are three main ways of controlling the luminous flux of fluorescent lamps: amplitude regulation, frequency regulation and pulse-width regulation of the voltage at the output of the power inverter |2). Amplitude control can be performed by changing the voltage value at the output of the power factor corrector. IN

A step-down converter circuit with amplitude control must be used, which simultaneously implements the function of the power factor corrector. The value of the frequency and duration of the pause with 25-pulse width regulation is set using the inverter control system. in. It is known from the literature that the best results in terms of the width of the power control range and the linearity of the control are provided by the amplitude and pulse-width control methods. However, one of the most important issues in the construction of controlled ZPRAs is the cost and energy losses in ZPRAs. The lowest costs for control input can be obtained when using the frequency control method, because in this case small changes are made to the typical inverter control scheme. This method is well studied and widely used in the development of microcircuits for ballasts as a typical solution. From the point of view of energy saving, the worst is the use of amplitude control. A step-down pulse converter circuit is used to introduce amplitude control, which is used as a power factor corrector. In the step-down converter circuit, the transistor is used in a heavier current mode, with the same power transferred to the load, and therefore it dissipates more power than in the step-up converter circuits for building power correctors. When using pulse-width regulation, the main advantages, in addition to a wide range of power regulation and high linearity of regulation, are the use of a power boosting corrector circuit and the introduction of width regulation

By changing the control scheme.

The closest among the known ones to the proposed power supply unit for fluorescent lamps is the start-up device for powering gas-discharge lamps |4), which contains a power supply unit with a direct current source, an inverter, a starting current generator, an inductive-capacitive ballast circuit and an ignition unit for gas-discharge lamps. The inverter includes an adder, two control keys and a timer connected in series, a 7/0 control unit and a generator, and the device is equipped with a sensor for increasing the voltage on the lamps, a sensor for reducing the voltage on the lamps, a sensor for the voltage on the internal filaments of the lamps and a sensor for breaking the lower glow of the lamps. at the same time, the specified sensors are connected to a hysteresis adder, the starting current generator is connected to a direct current source and includes limiting resistors, a field-effect transistor, reference voltage elements that filter the capacity and a current resistor, and when the device is started, the starting generator is powered from 7/ 5 control circuits of the inverter to ensure the activation of its keys and the supply of power to the high-frequency rectifier, which supplies power to the constant voltage source and disconnects the starting current generator. This start-up device is more reliable than known similar devices, provides power for two lamps connected in series and allows less power loss.

The described power supply unit has a complex design based on the use of an electronic ballast, which leads to non-productive energy losses and limits the possibilities of controlling the glow of the lamps.

The invention is based on the task of improving the power supply unit for fluorescent lamps with alternating current, in which, by changing the design of the power supply circuit of the lamps and the lamp ignition unit and the glow regulator unit, the presence of any ballast is eliminated, the entire design of the power supply unit is simplified, and a wide range of light flow control is provided lamps, with minimal energy loss.

The task is solved by the fact that in the power supply unit for fluorescent lamps with alternating current, which contains the power supply circuit of two series-connected lamps, connected to the industrial network, the lamp ignition unit and the unit for adjusting their glow, it is proposed to make the power supply circuit in the form of a series-connected electronic breaker , a current converter and a high-voltage generator, to the output of which fluorescent lamps are connected, as well as a comparator, which is connected to the current converter by one of its inputs, and a lamp current selector is connected to its second input, while it is proposed to make the lamp ignition unit in the form of a control scheme a high-voltage generator connected to the output of the comparator, and the unit for regulating the brightness of the lamps is made in the form of a control scheme - an electronic interrupter connected to the output of the comparator.

Common to the prototype, the essential features of the invention are as follows: co " Power supply unit for fluorescent lamps with alternating current. co "" The unit contains a power supply circuit of two serially connected lamps, connected to an industrial network. "The power supply unit contains a lamp ignition unit and a unit for adjusting their brightness.

New essential features of the proposed invention should be considered: "The power supply circuit is made in the form of a series-connected electronic circuit breaker, a current "converter" and a high-voltage generator. in s "- Fluorescent lamps are connected to the output of the high-voltage generator. " A comparator is connected to the current converter, one of the inputs. ;" " A lamp current selector is connected to the second input of the comparator. " The lamp ignition unit is made in the form of a high-voltage generator control circuit connected to the comparator output. b " The lamp brightness control unit is made in the form of an electronic circuit breaker control circuit connected to the comparator output. The essence of the invention is illustrated by the drawing, which shows the block diagram of the proposed power supply unit -I fluorescent lamps with alternating current.

The proposed power supply unit contains a power supply circuit made in the form of an electronic circuit breaker 1, a current converter 2 and a high-voltage generator C connected in series, to the output of which two fluorescent lamps 4 are connected in series. Comparator 5 is connected to one of the inputs of the current converter. At the same time, the unit for adjusting the brightness of the lamps is made in the form of circuit b for controlling the electronic breaker, which is connected to the output of the comparator, and the unit for lighting the lamps is made in the form of circuit 7 for controlling the high-voltage generator, which is also connected to the outputs comparator. The lamp current setter 8 is connected to the second (inverse) input of the comparator. Except this power supply unit

P" is equipped with a means of automatic disconnection from the network.

The proposed power supply works as follows. When the unit is switched on, the voltage of the industrial network through the open electronic breaker 1 and the ohmic circuits of the current converter 2 is applied to points A and B of the lamps 4. At the same time, the high-voltage generator C is started, which acts on the series-connected lamps in the maximum active mode. After some time (2-3) ts., (which depends on the temperature of the environment and the condition of the lamps themselves), they have a glow discharge, which, growing like an avalanche, turns into an arc discharge. At the same time, the current flowing through the lamps increases, which means through the electronic circuit breaker, current converter and high-voltage generator connected in series. At the moment of switching on block 65, the current selector 8 is automatically transferred to the maximum permissible value of the current of the lamps (for the fastest exit of the lamps to the operating mode). The device is in this mode for 3-4 seconds.

to stabilize starting processes in lamps. At the end of this time, the current selector automatically switches to the pre-selected lamp current value. Thus, upon reaching the maximum permissible current in the lamps, the comparator simultaneously affects the electronic converter and the high-voltage generator.

The corresponding control schemes for them, that is, through the converter control scheme b and scheme 7, control the generator, keeping the current in the lamps at this level for 3-4 seconds, in order to heat the gas in the lamps and stabilize the ionization processes. From the moment of switching on to a stable burning mode, the comparator controls the electronic breaker and the generator so that the current in the lamps strictly corresponds to the value determined by the current setter. If, after supplying voltage from the network to the input of the power supply unit, the lamps (for some reason) do not light up within 3-4 seconds, then the power supply unit is automatically disconnected from the network and must be turned on again to activate its operation. To change the brightness of the lamps, switch 8 is changed to a different current value.

The proposed block provides power for two series-connected lamps of the LB-40 or LB-80 type, which is advantageous when using this block in lamps and when lighting large areas. Introduced improvements /5 provide the power supply unit with a number of advantages, both in comparison with the classic (throttle-starter) scheme and with modern schemes with electronic ballast. First of all, it is the absence of any ballast at all, which allows you to change the load current within wide limits, which means the brightness of the lamps, as well as to eliminate energy losses in the ohmic circuits of the ballasts. In addition, the luminance of the lamps increases by 20-25 percent thanks to their high-frequency alternating current supply, and high reliability of lamp ignition is ensured even at low ambient temperatures of 2o.

Sources of information 1. Krasnopolsky A.E. etc. Start-up devices! for discharge lamps. - M.: Atomizdat, 1988. - P. 139-144. 2. Krasnopolsky A.E. etc. Start-up devices! for discharge lamps. / A.E. Krasnopolsky,

Sokolov V.B., Troitskyi A.M. / Sub-district ed. A.E. Krasnopolskyi - M.: Znergoatomizdat, 1988. - 206 p.

Z. Rabodzei A. Electronics in lighting engineering. // Zlektronica. Science. Technology. Business. - 1997. - Mo 1. - b. « 15-19, 4. Patent of Russia No. 2175818 by M.Kl. - NOBV41/298 Start-up control device for powering gas discharge lamps.

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Claims (1)

The formula of the invention Р Power supply unit for fluorescent lamps with alternating current, containing a power supply circuit of two series-connected lamps, connected to an industrial network, a lamp ignition unit and a unit for adjusting their glow, which is distinguished by the fact that the power supply circuit is made in the form of a series-connected electronic circuit breaker, current converter and a high-voltage generator, the output of which is connected to fluorescent lamps, as well as a comparator connected to the current converter by one of its inputs, and to its second input a lamp current selector is connected, while the lamp ignition unit is made in the form of a high-voltage generator control circuit connected to the output comparator, and the unit for adjusting the brightness of the lamps is made in the form of an electronic circuit breaker control circuit connected to the output of the comparator. b5 we and and and and and. Official bulletin "Industrial Property". Book 1 "Inventions, useful models, topographies of integrated microcircuits", 2004, M 8, 15.08.2004. State Department of Intellectual Property of the Ministry of Education and Science of Ukraine. "IS) o cha s (Se) shi s;" (22) (ee) -I at 50 sl 60 b5