RU214017U1 - Device for igniting a gas discharge lamp - Google Patents

Abstract

The utility model relates to the field of electrical engineering and can be used to ignite and power gas-discharge lamps, in particular high-power bactericidal ultraviolet (UV) lamps used to disinfect various media, including liquid ones. A feature of the device circuits for such lamps is the sensitivity of the inverter circuit to leakage currents from the output circuits of the lamp to other circuits of the device for ignition and different parameters for the operation and start-up of the lamps.

The technical result achieved by the claimed utility model is an increase in reliability.

The technical result is achieved by the fact that the lamp ignition device contains a control unit, an input circuit connected to a controlled inverter control unit, including a capacitive voltage divider. The inverter additionally contains a voltage sensor of the capacitive divider of the inverter, which outputs a signal to the control unit, and at least one current limiter is included in the input circuit, shunted by a key, which is controlled by the control unit. 9 w.p. f-ly, 2 ill.

Description

The utility model relates to the field of electrical engineering and can be used to ignite and power gas-discharge lamps, in particular high-power bactericidal ultraviolet (UV) lamps used to disinfect various media, including liquid ones. A feature of the device circuits for such lamps is the sensitivity of the inverter circuit to leakage currents from the output circuits of the lamp to other circuits of the device for ignition and different parameters for the operation and start-up of the lamps.

To power and ignite gas-discharge lamps, devices for igniting gas-discharge lamps are used - ballasts (ballasts), which can be electromagnetic (EMPRA) and electronic (electronic ballasts).

During the operation of lamps as part of equipment for the disinfection of liquid media, leaks may occur with the formation of current leaks on the ground circuit that can disable the device for igniting a gas discharge lamp and subsequently pose a danger of electric shock to operating personnel. To protect personnel and equipment, a residual current device (RCD) is installed in the power circuit, designed for the total current consumption of a group of several devices for igniting a gas discharge lamp, which has a high differential current threshold. To increase the sensitivity of RCDs for differential current, you can install them individually on each device for igniting a gas discharge lamp, but this is not economically feasible. The above leaks can cause leakage currents between the lamp terminals, on which the RCD does not work, while the device for igniting the gas discharge lamp may also fail. There is a need to implement protective functions against leakage currents in the device itself for ignition of a gas-discharge lamp.

A ballast is known, containing a series-connected filter, a rectifier, a controlled inverter unit, including an independent ignition and lamp burning circuit and an electrode heating circuit, each of which is powered by two independent controlled power sources, a registration and control unit connected to the inverter unit and ignition and heating circuits by means of controlled keys, characterized in that the filter is equipped with a soft starter, a power factor corrector is connected to the rectifier and the inverter unit, the ignition and combustion circuit includes a controlled generator, and a current source is used as a power source for each electrode (RU 2275760 C1, IPC H05B 41/28, published 04/27/2006).

The closest technical solution is a lamp ignition device containing a filter connected in series, a rectifier, a power factor corrector connected to a controlled inverter unit, a lamp unit and a control microcontroller unit, characterized in that it additionally contains a high-voltage key controlled by the microcontroller (RU 2328094 C1, IPC H05B 41/26, published 06/27/2008).

The disadvantage of the analogue and the closest solution is the lack of checks for the diode effect and current leakage from the lamp circuits to the ground, without which the inverter can operate asymmetrically, as a result of which it can fail, since this mode is very dangerous for this type of circuits. The second disadvantage is the lack of reduction in starting currents, which can disable the ignition device of the discharge lamp.

The technical problem solved by the claimed utility model is the creation of a device for igniting a gas-discharge lamp, in which a reduction in starting currents is implemented, the diode effect and current leakage from the lamp circuits are checked, which increases the reliability and extends the service life of the device for igniting a gas-discharge lamp.

The technical result achieved by the claimed utility model is an increase in reliability.

The technical result is achieved by the fact that the lamp ignition device comprises a control unit, an input circuit connected to a controlled inverter control unit, including a capacitive voltage divider, according to the utility model, the inverter additionally contains a voltage sensor of the inverter capacitive divider, which outputs a signal to the control unit, and to the input the circuit includes at least one current limiter, shunted by a key controlled by the control unit.

The input circuit may contain a filter.

The input circuit may contain a rectifier.

The input circuit may contain a power factor corrector.

The input circuit may contain a key.

The input circuit may contain a circuit breaker.

The current limiter is connected in series to the input circuit.

In particular, a PTC thermistor is used as a current limiter.

In particular, an NTC thermistor is used as a current limiter.

In particular, a resistor is used as a current limiter.

A current limiter with a key can be placed in front of the filter.

A current limiter with a key can be located after the filter.

A current limiter with a key can be located after the rectifier.

A mains voltage sensor can be included in the input circuit.

In particular, the mains voltage sensor is connected in parallel to the input circuit.

In particular, the mains voltage sensor is located in front of the filter.

In particular, the mains voltage sensor is located after the filter.

In particular, the mains voltage sensor is located after the rectifier

The sensor of current consumption from the network can be included in the input circuit.

In particular, the current sensor is connected in series to the input circuit.

In particular, the current sensor is located in front of the filter.

In particular, the current sensor is located after the filter.

In particular, the current sensor is located after the rectifier.

A lamp current sensor can be added to the inverter.

A lamp voltage sensor can be added to the inverter.

In particular, the inverter contains capacitors.

In particular, the inverter contains a resonant capacitor.

In particular, the inverter contains a choke.

In particular, the inverter contains a key.

In particular, the inverter contains a driver.

In particular, the inverter includes a generator.

In particular, the inverter contains a diode.

In particular, the inverter contains a transistor.

In particular, the inverter contains a chip.

In particular, the inverter contains additional protection elements.

In particular, the inverter contains current sensors by keys (transistors).

In particular, the inverter contains additional elements that provide heating of the lamp electrodes.

In particular, a key is used as an element that provides heating of the lamp electrodes.

In particular, capacitors are used as elements that provide heating of the lamp electrodes.

In particular, transformers are used as elements that provide heating of the lamp electrodes.

In particular, PTC thermistors are used as elements that provide heating of the lamp electrodes.

The device may contain two or more inverters.

The control unit of the ignition device of the gas discharge lamp can be connected via a data link to the control device.

In particular, a computer can act as a control device.

Fig. 1 - Scheme of the ignition device for a gas-discharge lamp; fig. 2 - An example of a diagram of a device for igniting a gas discharge lamp.

1 - Current limiter;

2 - Key;

3 - Input circuit;

3.1 - Filter;

3.2 - Rectifier;

3.3 - Power corrector;

4 - Mains voltage sensor;

5 - Sensor of current consumption from the network;

6 - Inverter;

7 - Capacitive divider of the inverter;

8 - Voltage sensor of the capacitive divider of the inverter;

9 - Lamp voltage sensor;

10 - Lamp current sensor;

11 - Control unit;

12 - Lamp;

13 - Control device;

14 - Key.

The device for igniting a gas-discharge lamp (device) contains (Fig. 1) a control unit 11, an input circuit 3 connected to a controlled control unit 11, an inverter 6, including a capacitive voltage divider 7.

The inverter 6 contains a voltage sensor 8 of the capacitive voltage divider 7 of the inverter 6, connected to the midpoint of the capacitive divider 7 and to the control unit 11 and outputting a signal to it. The capacitive divider 7 is designed to lower the voltage in the inverter 6 to a level acceptable for the operation of measuring devices. The voltage sensor 8 of the capacitive divider 7 of the inverter 6 is necessary to detect current leakage from the cable of the lamp 12 and/or the circuit of the lamp 12 to ground and to determine the diode effect in the lamp 12.

If there is a diode effect in the lamp 12, the current through the lamp 12 and the inverter 6 has an asymmetric shape, which leads to the asymmetric operation of the inverter 6, since this mode is very dangerous for this type of circuit, as a result, the inverter 6 may fail. Therefore, it is necessary to control the deviation of the voltage from the norm, if it has a diode effect, then this voltage (due to the asymmetrical current) will shift in one direction or another from the norm, which is recorded by the voltage sensor 8 of the capacitive divider 7.

The signal from the voltage sensor 8 is fed to the input of the control unit 11, which receives the voltage value and determines whether the obtained value corresponds to the permissible range for the mode in which the device is currently operating (heating the lamp electrodes, operating mode, etc.) and receives further decision according to the operation algorithm: either switching on, or continuing to work (normal operation, lamp 12 burning), or switching to emergency mode, or switching off.

If there is a leakage of current from the cable of the lamp 12 and/or the circuit of the lamp 12 to ground, and also if there is a diode effect in the lamp 12, the inverter 6 operates in emergency mode. The presence of protection based on the detector - voltage sensor 8 allows the protective shutdown of the device, which turns off the lamp 12, when a current leakage is detected from the lamp cable and / or the lamp circuit to ground or the diode effect is detected, which increases the reliability and safety of the device.

Input circuit 3 includes at least one current limiter 1, shunted by key 2, controlled by control unit 3. As current limiter 1 can be used, for example, PTC thermistor, NTC thermistor, resistor. The presence of current limiter 1 in the input circuit 3 makes it possible to use its resistance to reduce inrush currents when the device is connected to the network, and also to use it as a self-restoring fuse, in the absence of shunting with key 2 (when key 2 is open), during the period of checks (leakage checks from the cable of the lamp 12 and/or) the circuits of the lamp 12 to the ground circuit and checking for leakage in the cable of the lamp 12 and/or the circuits of the lamp 12) when test voltage is applied to the lamp 12. This method avoids overloads and failure of the device in emergency situations, associated with these leaks. This increases the reliability and safety of the device.

Input circuit 3 includes two network outputs: L (Line, Phase) and N (Neutral, Zero). In industrial installations, everything must be connected strictly according to the connection diagram, therefore it will be sufficient to connect one current limiter 1, shunted by key 2 at terminal L, but strict adherence to the connection of the circuit in this case will be mandatory and it will be forbidden to supply the phase at terminal N, otherwise the protection will not be work properly.

In actual use, this point may not be observed, since power can be supplied through the plug without observing the phasing. In this case, it would be preferable to install current limiter 1, shunted by key 2 along two network outputs (L and N), then observing the phasing of L and N is not necessary. Key 2 must be connected in parallel to both the first and second current limiters 1, while the control signal from control unit 11 to both keys 2 will be the same, or key 2 may consist of two keys 2 switched simultaneously.

Obviously, the number of current limiters 1 shunted by key 2 is determined by the specific situation and the destination of the device, somewhere it is enough to have one, which will be cheaper and give a simpler design of the device, and somewhere it is necessary to use two, which will be more expensive and complicate the design of the device.

The input circuit 3 (Fig. 2) may contain a filter 3.1, a rectifier 3.2, a power factor corrector 3.3, switches, automata, connectors. The current limiter 1, shunted by the key 2, can be located, for example, before the filter 3.1, after the filter 3.1, after the rectifier 3.2.

The input circuit 1 can include, for example, a mains voltage sensor 4, which allows a preliminary check of the mains voltage after the device is turned on, or a sensor of current consumption from the mains 5 can be added to it, which makes it possible to determine the power consumption from the mains and determine the power on the lamp 12, taking into account the efficiency of the device. The mains voltage sensor 4, as well as the current consumption sensor from the mains 5 can be located, for example, before the filter 3.1, after the filter 3.1, after the rectifier 3.2.

In the inverter 2, for example, a voltage sensor 9 on the lamp 12 can be added, which makes it possible to control and limit the amplitude of the high voltage pulse generated for the breakdown of the gas discharge gap in the lamp 12; current sensor 10 on lamp 12 for stabilizing current on lamp 12 or power on lamp 12 together with voltage sensor 9; key 14 for shunting the interelectrode distance of the electrodes of the lamp 12. The device may contain two or more inverters 6. The control unit 11 of the device can be connected to the control device 13, which can be, for example, a computer, control panel, tablet, to set the device parameters and the possibility of remote control.

The device circuit contains an input circuit 3, which includes a current limiter 1 in series, to which a key 2 is connected in parallel, which are controlled by the control unit 11; an inverter 6 is connected in series with the input circuit 3, containing a capacitive divider 7, to which a voltage sensor 8 of the capacitive divider 7 is connected in parallel, the signals from which are fed to the control unit 11.

The device works as follows.

The device is connected to the lamp block 12, after which voltage is applied to the device, which turns on the lamp 12. In the case of a diode effect on the lamp 12, the current in the inverter 6 has an asymmetric shape. This leads to asymmetric operation of the inverter 6, which is perceived by the voltage sensor 8 of the capacitive divider 7 of the inverter 6. The voltage sensor 8 transmits a signal to the control unit 11, which switches the device into emergency mode or turns it off, depending on the value of the signal received from the sensor 8 and the specified there are 11 allowable voltage values in the control unit that determine the choice of control unit 11. The current limiter 1 included in the input circuit 3, shunted by key 2, controlled by control unit 11, when the device is connected to the network, allows using its resistance to reduce inrush currents, which helps to avoid overloads and failure of the device in the event of an emergency situation associated with the presence of these leaks.

Thus, the use of the proposed technical solution due to the use of a current limiter shunted by a key in the input circuit, which reduces inrush currents, and the use of a voltage sensor of the capacitive divider of the inverter, which allows determining the presence of a diode effect, which makes it possible to protect the device against overvoltage or mains voltage dips, due to which the ignition device of the gas discharge lamp becomes more reliable and safe, which contributes to its long service life.

Claims (10)

1. A device for igniting a discharge lamp, containing a control unit, an input circuit connected to a controlled inverter control unit, including a capacitive voltage divider, characterized in that the inverter additionally contains a voltage sensor of the inverter capacitive divider, which outputs a signal to the control unit, and to the input circuit at least one current limiter is switched on, shunted by a key controlled by the control unit. 2. The device according to claim 1, characterized in that the input circuit contains a filter, a rectifier, a power factor corrector. 3. The device according to claim 1, characterized in that the current limiter is located in front of the filter. 4. The device according to claim 1, characterized in that the current limiter is located after the filter. 5. The device according to claim 1, characterized in that the current limiter is located after the rectifier. 6. The device according to claim 1, characterized in that the mains voltage sensor is included in the input circuit. 7. The device according to claim 1, characterized in that the input circuit includes a sensor for current consumption from the network. 8. The device according to claim 1, characterized in that a current sensor and a lamp voltage sensor are added to the inverter. 9. The device according to claim 1, characterized in that a key is included in the inverter. 10. The device according to claim. 1, characterized in that the control unit of the ignition device of the discharge lamp is connected to the control device.

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