RU121980U1 - STARTING DEVICE FOR HIGH PRESSURE DISCHARGE LAMPS - Google Patents

Abstract

A ballast for high-pressure discharge lamps containing a rectifier unit, an inverter, a polarity switch, a control device, a main transformer containing a primary and a secondary winding, and a controlled transformer on a three-core core, containing two in series, according to the connected primary windings, located one on each of side rods of the three-rod core and connected in series with the primary winding of the main transformer, two in series, according to the connected secondary windings, also located one on each of the side rods of the three-rod core, and a control winding located on the central rod of the three-rod core, while the rectifier unit is connected with its outputs to the inputs of the inverter, one of the outputs of which is connected to one of the terminals of the series-connected primary windings of the main and controlled transformers, characterized in that the device complements it is equipped with a capacitor connected parallel to the primary windings of the controlled transformer; ballast connected in series to the circuit of the other output of the inverter and the other output of the primary windings of the main and controlled transformers; the first and second high-frequency rectifiers, each of which with its inputs is connected in parallel to the corresponding primary windings of the main and controlled transformers, while a circuit consisting of series-connected outputs of the first and second high-frequency rectifiers and outputs of the control winding of the controlled transformer�

Description

The technical field to which the utility model relates.

The utility model relates to the field of electrical engineering and is intended for ignition and direct current supply of high-pressure discharge lamps.

State of the art

Known pulse ignition devices for high-pressure discharge lamps containing a power circuit, a microprocessor, a control circuit and a transformer. [Gareev, V.M. Pulse ignition devices for high-pressure discharge lamps / V.M. Gareev, O.G. Fomin, P.V. Memikov // Bulletin of Novgorod State University. - 2001. - No. 19.]

The disadvantage of such devices is the high material consumption and design complexity.

Known electronic ballasts containing a frequency converter, the output of which is connected to the discharge lamp through a series-connected first winding of the transformer. The second winding of the transformer is connected to the ignition device. (Panfilov D.I., Polyakov V.D., Chepurin I.N., Obzherin E.A. Controlled ballasts for high pressure sodium lamps. - Journal of Practical Power Electronics, No. 10, 2003, p. 37 -42.)

The disadvantage of such devices is their low reliability, due to the fact that at the moment of starting the start pulse in the primary winding of the transformer, the high-voltage pulse arising in its secondary winding also affects the elements of the inverter of the frequency converter, which can damage its semiconductor switches (field effect transistors) .

The closest in technical essence and the achieved positive effect and adopted by the authors for the prototype is a ballast for high-pressure discharge lamps, containing a rectifier unit, an inverter, a polarity switch, a control device, a main transformer containing primary and secondary windings, and a controlled transformer on a three-core core containing two consecutively included primary windings located one on each of the side rods of three hundred the core core and connected in series with the primary winding of the main transformer, two sequentially connected secondary windings, also located one on each of the side rods of the three-core core and a control winding located on the central core of the three-core core, with the rectifier unit connected to the inverter inputs by its outputs , one of the outputs of which is connected to one of the outputs of the series-connected primary windings of the main and controlled trans formators. [Samoilenko, V.V. Control gear for high-pressure discharge lamps / V.V.Samoilenko. - Methods and technical means to improve the efficiency of use of electrical equipment in industry and agriculture. - Stavropol: AGRUS, 2011. - 348 p. 273-277 s].

The disadvantage of this ballast for high-pressure discharge lamps is the low reliability due to the complexity of the phase matching of the output voltages of the main and controlled transformers, especially if it becomes necessary to regulate the discharge lamp by changing the frequency of the inverter.

Disclosure of invention

The technical result that can be achieved using the proposed ballasts for gas discharge lamps, is to increase the reliability of the device.

The technical result is achieved using a ballast for high-pressure discharge lamps, comprising a rectifier unit, an inverter, a polarity switch, a control device, a main transformer containing primary and secondary windings, and a controlled transformer on a three-core core, containing two primary windings arranged in series with one on each of the side rods of the three-core core and connected in series with the primary winding ov transformer, two sequentially connected secondary windings, also located one on each of the side rods of the three-core core and a control winding located on the central core of the three-core core, while the rectifier unit has its outputs connected to the inputs of the inverter, one of the outputs of which is connected to one from the conclusions of series-connected primary windings of the main and controlled transformers, while the device is additionally equipped with a field switch ries, a control device, a capacitor connected in parallel to the primary windings of a controlled transformer; ballast connected in series to the circuit of another inverter output and another output of the primary windings of the main and controlled transformers; the first and second high-frequency rectifiers, each of which with its inputs connected in parallel to the corresponding primary windings of the main and controlled transformers, while the circuit consisting of series-connected outputs of the first and second high-frequency rectifiers and the terminals of the control winding of the controlled transformer is connected to the inputs of the polarity switch, and the output of the control device is connected to the control input of the polarity switch, the outputs of which are connected to the terminals of the gas discharge amps.

Brief Description of the Drawings

Figure 1 is a structural diagram of a ballast for high-pressure discharge lamps.

Figure 2 is a diagram of the location and connection of the windings of a controlled transformer on a three-core core.

The implementation of the invention

The control device for high-pressure discharge lamps includes a rectifier unit 1 (Fig. 1), an inverter 2, a main transformer 3, consisting of a primary winding 4 and a secondary winding 5 and a controlled transformer 6 made on a three-core core (Fig. 2). At the same time, the controlled transformer 6 contains two primary windings 7 and 8 connected in series according to their findings, located one on each of the side rods (not indicated in FIG. 2) of the three-core core, two secondary windings 9 and 10 connected in series, also located along one on each of the side rods (not indicated in FIG. 2) of the three-core core, and a control winding 11 located on the central rod (not indicated in FIG. 2) of the tri-core. The primary windings 7 and 8 of the controlled transformer 6 are connected in series with the primary winding 4 of the main transformer 3. The inverter 2 can be made in particular on the basis of a half-bridge high-frequency converter (not indicated in Fig. 1).

The rectifying unit 1 with its outputs (not shown in FIG.) Is connected to the inputs (not shown in FIG.) Of inverter 2, one of the outputs of which is connected to another terminal (not indicated in FIG.) Of the primary winding 7 of the controlled transformer 6.

The series-connected primary windings 7 and 8 of the controlled transformer 6 and the parallel connected capacitor 12 form a parallel resonant LC circuit (not indicated in FIG. 1).

Ballast 13, made in particular in the form of a capacitor, is connected in series to the circuit of another output (not shown in FIG.) Of the inverter 2 and another output (not indicated in FIG.) Of the primary winding 4 of the main transformer 3.

The secondary windings 9 and 10 of the controlled transformer 6 are connected to the inputs of the first high-frequency rectifier 14, made in particular according to the scheme of the diode multiplier.

The secondary winding 5 of the main transformer 3 is connected, in turn, to the inputs of the second high-frequency rectifier 15, made in particular according to the scheme of a half-wave rectifier with doubling.

The circuit consisting of the series-connected outputs of the first and second high-frequency rectifiers 14 and 15 and the control winding, also connected in series with it, is connected to the inputs of the polarity change switch 16. The polarity switch 16 can be made in particular based on a bridge switch (in FIG. marked) on semiconductor switches.

The control device 17 is connected by its output (not shown in FIG.) To the control input (not indicated in FIG.) Of the polarity change switch 16. The outputs (not shown) of the polarity change switch 16 are connected to the terminals of the discharge lamp 18.

The control device for high-pressure discharge lamps works as follows.

Until the ignition of the discharge lamp 18, the main transformer 3 and the controlled transformer 6 operate in idle mode.

Since the primary windings 7 and 8 of the controlled transformer 6 are connected in series, the same current flows through them. This current flowing through the primary winding 7 of the controlled transformer 6 creates a magnetic flux Φ ₁ in the side rod of the core (Fig. 2), under the influence of which a voltage is induced in the secondary winding 9 located on the same side rod as the primary winding 7 . Under the influence of the same current flowing through another primary winding 8 of the controlled transformer 6 located on the other side terminal of the controlled transformer 6, a magnetic flux Ф ₂ arises inducing in the other secondary winding 10 located on the same side terminal of the controlled transformer 6 as primary winding 8, voltage.

Magnetic fluxes F ₁ and F ₂ basically close through the central rod. Since the primary windings 7 and 8 of the controlled transformer 6 have the same design parameters, the magnetic fluxes F ₁ and F ₂ are equal to each other. Since the primary windings 7 and 8 are turned on according to, in the central terminal of the controlled transformer 6, these magnetic fluxes mutually cancel each other, and a high-frequency electromotive force does not occur in the control winding 11 mounted on the central terminal of the controlled transformer 6.

When you turn on the ballast in the network, the DC voltage from the output of the rectifier 1 is supplied to the input of the inverter 2 and converted into high-frequency.

The frequency of the output voltage of the inverter 2 is selected so that its value coincides with the resonant frequency of the LC circuit, consisting of a parallel-connected capacitor 12 and the primary windings 7 and 8 of the controlled transformer 6. At resonance, the input resistance of the parallel circuit formed by the capacitor 12 and the primary windings 7 and 8 controlled transformers will be maximum and can reach tens of kilo-ohms. (see Atabekov, G.I. Theoretical Foundations of Electrical Engineering: A Textbook for High Schools. - 5th ed., Rev. And add. - M .: Energy, 1978. - 592 s).

High-frequency voltage is supplied from the inverter 2 to a series-connected LC circuit, the primary winding 4 of the main transformer 3 and the ballast 13 and is distributed between them in proportion to their impedance. Since the input impedance of the LC circuit is much higher than the total resistance of the ballast 13 and the primary winding 4 of the main transformer 3, most of the output voltage of the inverter 2 will be distributed exactly on the parallel connected capacitor 12 and the primary windings 7 and 8 of the controlled transformer 6.

The output voltage from the secondary windings 9 and 10 of the controlled transformer 6 is supplied to the inputs of the first high-frequency rectifier 14.

The output voltage from the secondary winding 5 of the main transformer 3 is supplied to the inputs of the second high-frequency rectifier 15.

Since the first and second high-frequency rectifiers 14 and 15 are connected in series with their outputs, the rectified voltage is added and fed to the input of the polarity switch 16. The value of this voltage should be sufficient to ignite a high-pressure gas discharge lamp (for a DNaT lamp - 2 ... 3 kV). From the output of the polarity switch 16 voltage is supplied to the terminals of the discharge lamp 18.

After starting the discharge lamp 18, a current limited by the resistance of the ballast 13 begins to flow through it. Under the influence of this current, with the appropriate choice of the number of turns of the control winding 11, the magnetic core of the controlled transformer 6 is saturated.

The dynamic magnetic permeability of the core of the controlled transformer 6 is sharply reduced, which leads to a decrease in the inductance of the primary windings 7 and 8 of the controlled transformer 6. A decrease in the inductance of the primary windings 7 and 8 of the controlled transformer 6 with a constant power frequency of the inverter 2 sharply increases the conductivity of the LC circuit. Accordingly, the voltage between the primary windings 7 and 8 of the controlled transformer 6, the primary winding 4 of the main transformer 3 and the ballast 13 are redistributed. To enhance the saturation effect, one should choose magnetic material for the core of the controlled transformer 6 with a rectangular hysteresis loop, and assemble the core without gaps.

As a result, the voltage decreases on the primary windings 7 and 8 of the controlled transformer 6, and increases on the primary winding 4 of the main transformer 3.

Accordingly, there will be a change in voltage on the secondary windings 9 and 10 of the controlled transformer 6 and the secondary winding 5 of the main transformer 3.

Since the transformation coefficient of the controlled transformer 6, designed to ignite the discharge lamp 18, significantly exceeds the transformation ratio of the main transformer 3, designed to maintain the operating mode of the discharge lamp 18, such a redistribution of voltages on the primary windings 7 and 8 of the controlled transformer 6 and the primary winding 4 of the main transformer 3 will cause a significant decrease in the output voltage on the secondary windings 9 and 10 of the controlled transformer 6 and some A slight increase in voltage on the secondary winding 5 of the main transformer 3.

The total voltage of the first and second high-frequency rectifiers 14 and 15 connected in series will accordingly decrease to the operating voltage of the combustion of the discharge lamp 18 (for DNaT lamps -100 ... 120 V).

It is known that prolonged operation of discharge lamps 18 in constant current mode causes the phenomenon of cataphoresis and accelerated wear of the burner electrodes. In this connection, the control device 17 at certain intervals transmits control signals to the polarity switch 16, thereby changing the polarity of the voltage supplying the discharge lamp 18.

The proposed ballast for high-pressure discharge lamps in comparison with the prototype and other well-known technical has the following advantage:

- The increased reliability of the device, due to the coordination of the output voltages of the controlled and the main transformers 6 and 3, using two high-frequency rectifiers 14 and 15.

Claims (1)

A control gear for high-pressure discharge lamps, comprising a rectifier unit, an inverter, a polarity switch, a control device, a main transformer containing primary and secondary windings, and a controlled transformer on a three-core core containing two primary windings connected in series, one on each of side rods of a three-core core and connected in series with the primary winding of the main transformer, two in series with clearly connected secondary windings, also located one on each of the side rods of the three-core core, and a control winding located on the central core of the three-core core, while the rectifier unit is connected with its outputs to the inputs of the inverter, one of the outputs of which is connected to one of the outputs of the series-connected primary windings of the main and controlled transformers, characterized in that the device is additionally equipped with a capacitor connected in parallel with the primary coils of a controlled transformer; ballast connected in series to the circuit of another inverter output and another output of the primary windings of the main and controlled transformers; the first and second high-frequency rectifiers, each of which with its inputs is connected in parallel to the corresponding primary windings of the main and controlled transformers, the circuit consisting of series-connected outputs of the first and second high-frequency rectifiers and the terminals of the control winding of the controlled transformer connected to the inputs of the polarity switch, and the output of the control device is connected to the control input of the polarity switch, the outputs of which are connected to the terminals of the gas discharge MPa.