CN116647949A - Square wave driving damping sine pulse high-voltage power supply suitable for DBD excimer UV lamp - Google Patents

Abstract

The application discloses a square wave driving damping sine pulse high-voltage power supply suitable for a DBD excimer UV lamp, which comprises the following components: the square wave driving circuit is connected with the square wave driving power supply and is used for converting power supply input into square wave output; the high-voltage side of the step-up transformer is connected with the DBD excimer UV lamp, and the low-voltage side of the step-up transformer is connected with the square wave driving circuit; the step-up transformer and the DBD excimer UV lamp form a load resonant circuit; the square wave output frequency is 1/N times of the resonance frequency of the load resonance circuit, so that N damped sine oscillation waves taking the resonance frequency of the load resonance circuit as a period are formed in the positive half cycle and the negative half cycle of the square wave, the high voltage generated by the first cycle of the damped sine oscillation of the positive half cycle and the negative half cycle of the square wave is used for breakdown of the DBD to form discharge, and the rest damped sine oscillation waves are used for time intervals among pulses. The high voltage formed by the damping sine pulse driven by the square wave improves the excitation efficiency of the DBD excimer UV light source.

Description

Square wave driving damping sine pulse high-voltage power supply suitable for DBD excimer UV lamp

Technical Field

The application relates to the technical field of DBD light source power supply, in particular to a square wave driving damping sine pulse high-voltage power supply suitable for a DBD excimer UV lamp.

Background

The commonly used 254nm ultraviolet rays have the characteristics of pure physical and efficient sterilization, no secondary pollution, high power and the like, and are applied in a large-area environment, and direct irradiation is harmful to human bodies and eyes. And therefore can only be used in an unoccupied environment. Related studies have shown that 222nm wavelength ultraviolet light generated by KrCl krypton chloride excimer discharge is equally effective against many pathogens, but does not adversely affect the skin and eyes. The technology is expected to be widely applied to the public disinfection and sterilization field.

Dielectric barrier discharge (Dielectric Barrier Discharge, DBD) is a gas discharge in which an insulating substance is inserted into a discharge space. When a sufficiently high excitation voltage is applied across the discharge electrodes, the gas between the electrodes breaks down and microdischarges occur in the microdischarge channels. The discharge structure enables the DBD to generate discharge in a wide excitation voltage frequency and air pressure range, the micro discharge belongs to alternating discharge in a high-air pressure non-thermal equilibrium state, the discharge is driven by high voltage of thousands of volts, and the discharge frequency can be from a few Hz to a few GHz. The discharge consists of a large number of thin wire-like irregular fast pulse discharge channels, called microdischarges. Each micro discharge has a very short time, a lifetime of less than 10ns, a channel radius of no more than 0.1mm, and a current density of up to 0.1-1KA/cm ² . When the external electric field voltage across the gas gap exceeds the breakdown voltage of the gas, the gas breaks down, then a conductive path is established, space charges are transported in the discharge gap and accumulated on the medium, and at this time the surface charges of the medium will establish an electric field in a direction opposite to the external electric field, thereby weakening the applied electric field, so that the discharge current is interrupted. At the same position, only when the voltage is raised to the original breakdown voltage value again, the re-breakdown occurs, and the micro discharge is generated again.

Each microdischarge includes three stages of development: 1) The formation of a discharge, i.e. the breakdown of an electric field; 2) The charge transport process in the gas, i.e. the formation of continuous current pulses; 3) The excitation ionization of the atomic molecules is performed,

since the dielectric barrier discharge circuit includes a gas and a dielectric barrier layer, the discharge phenomenon is different from the general discharge phenomenon. The circuit contains two distinct states, discharged and undischarged, in a complete cycle. When the DBD circuit is in an undischarged stage, the DBD circuit can be equivalently a structure that a medium capacitor Cd and a gas gap capacitor Cg are connected in series; when the circuit is in a discharge stage, the dielectric capacitor Cd and the air gap breakdown discharge maintaining voltage can be used for series equivalent.

Experiments have shown that to fully exploit the performance of a DBD load, not only is it necessary to apply a high frequency, steep pulse rise rate dv/dt excitation voltage waveform thereto, but the excitation voltage waveform also provides a characteristic particle state recovery time for the DBD load (the current through the DBD load at this stage is near zero). However, the existing dielectric barrier discharge load power supply based on series-parallel load resonance is difficult to meet the two requirements at the same time.

The traditional driving mode of the DBD excimer light source is sine wave high voltage and pulse high voltage, the sine wave driving mode cannot simultaneously meet the requirements of short rise time and time interval requirement of the pulse high voltage proposed by the DBD excimer light source, and the traditional pulse high voltage generating mode has the defects of complex circuit structure, low output power and the like.

Disclosure of Invention

The technical problem to be solved by the application is to provide a square wave driving damping sine pulse high-voltage power supply suitable for a DBD excimer UV lamp, wherein a plurality of damping sine oscillation waves taking the resonance frequency of a load resonant circuit as a period are formed in the positive half cycle and the negative half cycle of the square wave, high voltage is generated in the first damping sine wave of the positive half cycle and the negative half cycle of the square wave for breakdown of the DBD to form discharge, and the rest damping sine oscillation waves are used for time intervals among pulses, so that shorter rising and falling edges and longer pulse time intervals are formed, and the high-efficiency driving requirement of the DBD excimer UV lamp is met.

The application provides a square wave drive damping sine pulse high-voltage power supply suitable for a DBD excimer UV lamp, which comprises the following components:

the square wave driving circuit is connected with the square wave driving power supply and used for converting the square wave driving power supply into square wave output;

the high-voltage side of the step-up transformer is connected with the DBD excimer UV lamp, and the low-voltage side of the step-up transformer is connected with the square wave driving circuit; the step-up transformer and the DBD excimer UV lamp form a load resonant circuit;

the frequency of the square wave output is 1/N times of the resonance frequency of the load resonance circuit, so that N damped sine oscillation waves taking the resonance frequency of the load resonance circuit as a period are formed in the positive half cycle and the negative half cycle of the square wave, the high voltage generated by the first cycle of the damped sine oscillation of the positive half cycle and the negative half cycle of the square wave is used for breakdown of the DBD to form discharge, the rest damped sine oscillation waves are used for time intervals among pulses, wherein N is more than or equal to 2.5 and less than or equal to 20, and N is not an integer; when the number of the resonance points of the load resonance circuit is larger than one, the frequency corresponding to the highest resonance point is taken as the resonance frequency.

Further, when the square wave driving circuit is a half-bridge square wave driving circuit, the low-voltage side of the step-up transformer is connected with the square wave driving circuit through a blocking capacitor;

when the square wave driving circuit is a full-bridge square wave driving circuit, the low-voltage side of the step-up transformer can be connected with the square wave driving circuit through a blocking capacitor or directly connected with the square wave driving circuit without the blocking capacitor;

when the step-up transformer is connected with the square wave driving circuit through the blocking capacitor, the load resonant circuit further comprises the blocking capacitor.

Further, the value of N satisfies the frequency range of 14KHz-500KHz of square wave output.

Further, the square wave drive power supply has a voltage of 12VDC-800VDC.

Further, the resonance frequency point of the resonance frequency of the load resonance circuit is obtained by adopting conventional calculation, software simulation or actual measurement.

The application has the following advantages:

1. when the working frequency of the square wave is in the damped sinusoidal oscillation region through proper selection of N, the first cycle of the positive half cycle and the negative half cycle of the square wave are used for generating high voltage, so that the DBD excimer UV lamp obtains steeper pulse edges, and a damped sinusoidal pulse forming time interval with lower high voltage is arranged between positive and negative high voltage pulses, and therefore the requirements of steep pulse high voltage edges (dv/dt is high) and a time interval between pulses can be met simultaneously. The dv/dt (N times) of the steeper pulse high-voltage edge is obtained, and the time interval between the high-voltage pulses is increased, so that the particle state recovery time special for the DBD load (the current flowing through the DBD load is close to zero at the stage) is favorably provided, the plasma has enough time to be compounded between two adjacent discharges, the next pulse is ensured to have enough plasma to participate in the discharge, and the excitation efficiency of the DBD excimer UV light source is improved by 30% -50%.

2. Because the independent inductor (used as current limiting or impedance matching) is not used, but only leakage inductance of the step-up transformer is adopted to participate in resonance, the resonance network inductance is reduced, the resonance frequency point of the lamp load can be effectively improved, the dv/dt of the pulse edge is improved, the circuit efficiency is high, the circuit structure is simplified, the number of elements is small, and the cost performance is high.

3. By adopting the working mode that the square wave output frequency is 1/N times of the resonance frequency of the load resonant circuit, the current flowing through the booster transformer winding is the damped oscillation current with the load resonant circuit frequency being periodic, compared with the current of an inductance load booster transformer working in a non-resonant mode, the inductance of the required low-voltage winding is smaller, the corresponding turns are fewer, the temperature rise of the booster transformer is lower, and the efficiency is improved.

4. Stability of the output high voltage amplitude is improved: the working frequency of the square wave is only 1/N times of the resonance point frequency of the load resonance circuit, so that the load resonance circuit can obtainThe equivalent Q value of the circuit is not high compared with the working point near the resonance point Fr, the influence of load change on the working state of the circuit is small, and a complex control circuit such as frequency tracking can be omitted, so that more stable output high voltage can be obtained, and further stable lamp output power can be obtained.

Drawings

The application will be further described with reference to examples of embodiments with reference to the accompanying drawings.

FIG. 1 is a graph of amplitude versus frequency for a periodic square wave signal in the prior art;

fig. 2 is a schematic structural diagram of a square wave driving damping sine pulse high voltage power supply suitable for a DBD excimer UV lamp according to an embodiment of the present application;

FIG. 3 shows a half-bridge circuit structure of a square wave drive circuit according to an embodiment of the present application;

FIG. 4 is a schematic diagram of another half-bridge circuit structure of a square wave drive circuit according to an embodiment of the present application;

FIG. 5 shows a full-bridge circuit structure of a square wave drive circuit according to an embodiment of the present application;

FIG. 6 is a schematic diagram of another full-bridge circuit configuration of a square wave drive circuit according to an embodiment of the present application;

FIG. 7 is a schematic diagram of the amplitude-frequency characteristic scan result and the working area of the load circuit portion of the DBD excimer UV light source according to the embodiment of the application;

fig. 8 is a graph of the high voltage frequency relationship of a square wave driving damped sinusoidal pulse with n=3 in an embodiment of the present application;

fig. 9 is a graph of the high voltage frequency relationship of a square wave drive damped sinusoidal pulse with n=5 in an embodiment of the present application;

fig. 10 is a graph of the high voltage frequency relationship of a square wave drive damped sinusoidal pulse with n=7 in an embodiment of the present application;

fig. 11 is a graph of the high voltage frequency relationship of a square wave drive damped sinusoidal pulse with n=9 in an embodiment of the present application;

FIG. 12 is a schematic circuit diagram of an embodiment of the present application power supply applied to a 150W DBD excimer UV lamp;

fig. 13 is a schematic diagram of the actual driving square wave, damped sinusoidal pulse high voltage and micro-discharge current waveforms of the DBD excimer UV lamp at n=5 in the embodiment of fig. 12.

Detailed Description

The embodiment of the application provides a square wave driving damping sine pulse high-voltage power supply suitable for a DBD excimer UV lamp, wherein a plurality of damping sine oscillation waves taking the resonance frequency of a load resonant circuit as a period are formed in the positive half cycle and the negative half cycle of a square wave, the first damping sine oscillation cycle of the positive half cycle and the negative half cycle of the square wave generates high voltage, and the rest damping sine oscillation waves are used for time intervals among pulses, so that shorter rising and falling edges and longer pulse time intervals are formed, and the high-efficiency driving requirement of the DBD excimer UV lamp is met.

The technical scheme in the embodiment of the application has the following overall thought:

the conventional DBD excimer UV light source is driven by several modes, namely a pulse high voltage and a sine wave high voltage are common, and in view of the fact that the electrical characteristics of the DBD are capacitive loads, the high frequency high voltage is difficult to realize on the capacitive loads, the pulse high voltage (rising edge, dV/dt value of falling edge is as large as possible) is adopted for realizing efficient excitation of the DBD excimer light source, and a time interval is needed between pulses, but a conventional circuit is complex in circuit structure and high in cost.

The load side formed by the DBD excimer UV light source, the step-up transformer, the connecting wire and the like has resonance characteristics, so that the driving pulse dv/dt of the DBD excimer light source can be as large as possible with a simple circuit structure by fully utilizing the resonance characteristics, and the requirement of time interval between the pulses can be met.

The fourier series of a square wave (50% duty cycle) can be expanded as:

wherein Am is the amplitude of the square wave, the amplitude of the fundamental wave is 4/pi×am, and the amplitude of each corresponding higher harmonic is

From fourier spectrum analysis, it is known that the periodic square wave may be composed of higher harmonics such as fundamental wave, 3 rd order harmonics, 5 th order harmonics, 7 th order harmonics, 9 th order harmonics, etc. as a period, the amplitude is 1 per fundamental wave, each higher harmonic (3, 5,7,9, etc.) is (1/3, 1/5,1/7,1/9, etc.) of the amplitude of the fundamental wave, that is, the periodic square wave contains each odd-order higher frequency harmonic, and the amplitude is 1/N of the fundamental wave, as shown in fig. 1.

By utilizing the characteristics of each high-frequency harmonic wave contained in the square wave and combining the resonance characteristics of a load loop formed by the DBD excimer light source, the step-up transformer, the connecting wire and the like, proper square wave frequency is selected to enable the load formed by the DBD excimer light source, the step-up transformer, the connecting wire and the like to resonate near a certain harmonic wave of the square wave (the square wave frequency is only 1/N of the resonance frequency of a load network), as the resonance point of the DBD excimer load network is higher than N times of the square wave frequency, the period is only 1/N times of the period of the square wave, the value of dv/dt is improved when the period is reduced, damping sinusoidal oscillation is shown in the upper half period and the lower half period of the square wave, the first pulse of oscillation generates high voltage for breakdown of the DBD to form discharge, and the time interval between high-voltage pulses formed by subsequent damping pulses is further used for meeting the requirement of efficiently driving the DBD excimer light source.

Examples

The present embodiment provides a square wave driving damped sinusoidal pulse high voltage power supply suitable for DBD excimer UV lamps, as shown in fig. 2, comprising:

and the square wave driving circuit is connected with a square wave driving power supply (the power supply voltage range is 12VDC-800 VDC) and used for converting the square wave driving power supply into square wave output.

A step-up transformer T1, the high voltage side (3, 5) of the step-up transformer T1 is connected with a DBD excimer UV lamp (Cd represents a medium Capacitor (Dielectric Capacitor), cg represents an air gap Capacitor (Gas Capacitor), and Vth represents a threshold voltage (Threshold voltage), namely a Gas discharge breakdown voltage), and the low voltage side (1, 2) of the step-up transformer T1 is connected with the square wave driving circuit; the step-up transformer T1 and the DBD excimer UV lamp form a load resonant circuit (when the square wave driving circuit is connected with the step-up transformer T1 through the blocking capacitor C, the load resonant circuit comprises the blocking capacitor C, the step-up transformer T1 and the DBD excimer UV lamp, and the square wave driving damping sine pulse high-voltage power supply comprises the square wave driving circuit, the blocking capacitor C and the step-up transformer T1).

The square wave output frequency is 1/N times (2.5 is less than or equal to 20 and can be not an integer) of the resonance frequency of the load resonance circuit, when the number of resonance points of the load resonance circuit is larger than one, the frequency corresponding to the highest resonance point is taken as the resonance frequency, so that N damped sine oscillation waves taking the resonance frequency of the DBD load as a period are formed in the positive half cycle and the negative half cycle of the square wave, high voltage generated by the first cycle of the damped sine oscillation of the positive half cycle and the negative half cycle of the square wave is used for breaking down the DBD to form discharge, and the rest damped sine oscillation waves are used for time intervals among pulses to form shorter rising and falling edges and longer pulse time intervals, so that the high-efficiency driving requirement of the DBD excimer UV light source is met.

Preferably, the square wave driving circuit may be generated by the two half-bridge circuit structures shown in fig. 3 and 4 or by the two full-bridge circuit structures shown in fig. 5 and 6. The half-bridge or full-bridge circuit is adopted to generate square waves, so that the power range suitable for the square waves is large, and the square waves are particularly suitable for high-power application scenes.

When the square wave driving circuit is a half-bridge square wave driving circuit, the low-voltage side of the step-up transformer T1 is connected with the square wave driving circuit through a blocking capacitor; the load tank (in the box) of fig. 3 contains one blocking capacitor C1, and the load tank (in the box) of fig. 4 contains two blocking capacitors C1, C2.

When the square wave driving circuit is a full-bridge square wave driving circuit, the low-voltage side of the step-up transformer T1 can be connected with the square wave driving circuit through a blocking capacitor or directly connected with the square wave driving circuit without the blocking capacitor; the load tank (in the box) of fig. 5 does not contain a blocking capacitor, and the load tank (in the box) of fig. 6 contains a blocking capacitor C1.

The high voltage winding of the step-up transformer T1 is connected to the DBD excimer UV lamp composition resonant network via a dc blocking capacitor (the full bridge circuit of fig. 5 is not used) connected to the low voltage winding of the step-up transformer T1. The circuit structure is simplified because the leakage inductance of the step-up transformer is adopted to work instead of using an independent inductance (as current limiting or impedance matching).

In a specific embodiment, the selection principle of the driving square wave frequency is shown in fig. 7. In fig. 2, taking a resonant frequency point (Fr) = 135.14KHz formed by a load resonant circuit composed of a blocking capacitor C, a step-up transformer T1 and a DBD excimer UV lamp as an example (Fr resonant frequency point is obtained by conventional calculation, software simulation or actual measurement), the sweep frequency range is 0-200KHz, and the frequency sweep can be divided into 4 regions according to different working states of a circuit:

zone 4: fw (operating frequency of square wave) > Fr; the area is a conventional sinusoidal oscillation working area, the load resonant circuit is inductive, the square wave driving circuit can realize soft switching, the du/dv is gradually increased along with the increase of the selected frequency, but the time interval of the high-voltage pulse is too short, no enough time is needed in the DBD excimer UV lamp to compound plasma, and the radiation efficiency of the light source is low. And the working frequency of the square wave is larger than the resonance point of the load resonance circuit, the equivalent circuit Q value is higher when the square wave is closer to the resonance point, the high-voltage output amplitude is greatly influenced by peripheral parameters, and the output power of the circuit is unstable. To improve the stability of the output high voltage and power, the phase-locked loop is relied on to track the load resonant frequency by square wave frequency, the circuit structure is complex, and the cost is high.

Zone 3: (Fr/2.5= 54.056 KHz) < Fw (operating frequency of square wave) < (fr= 135.14 KHz); the regional load resonant circuit is capacitive, the square wave driving circuit cannot realize soft switching, and the loss of a switching device is too large to work.

Zone 2: 14KHz < fw (operating frequency of square wave) < (Fr/2.5= 54.056 KHz); the damping sinusoidal operation region of this embodiment is selected by proper N (such as n=3, 5,7, 9), so that the square wave operation frequencies fw=fr/n=45.04 khz,27.028khz,19.306khz,15.016khz (corresponding to n=3, 5,7, 9) can be obtained, and the high dv/dt of the high voltage pulse and the time interval between the high voltage pulses have been achieved.

Zone 1: fw (operating frequency of square wave) <14KHz; because the 20Hz-14KHz is an audible frequency range which can be heard by human ears, in order to avoid noise from not working in the area, the area is close to another low-end resonance point formed by a load resonance circuit consisting of a blocking capacitor, a step-up transformer and a DBD excimer UV lamp, and the area is also prevented from being too close to avoid unstable circuit operation.

Therefore, the value of N is adjusted by changing the working frequency through the parameter setting of the half-bridge driving circuit or the full-bridge driving circuit (such as the peripheral element of the half-bridge control IC circuit with the model of L6599), and when the value of N meets the frequency range of 14KHz-500KHz of square wave output, noise can be avoided and the normal working requirement of the circuit is met.

When the square wave frequency is in the damping sine working area through proper selection of N, the DBD excimer UV light source obtains steeper dv/dt (N times) pulse edges, and a damping sine pulse forming time interval with lower high voltage is arranged between positive and negative high voltage pulses, which is beneficial to providing the particle state recovery time (the current flowing through the DBD load is close to zero at the stage) specific to the DBD load, so that the two requirements of high dv/dt of the pulse high voltage edges and the time interval between the pulses can be simultaneously met, and the excitation efficiency of the DBD excimer UV light source is improved by 30% -50%.

Although the choice of N can be flexibly set within 2.5-20 according to practical requirements, the inventors found that a better time relationship between square wave driving and damped sine pulse high voltage can be obtained when N is an odd number. For example, fig. 8 to 11 show the frequency relationship of the square wave driving the high voltage of the damped sine pulse and the dc blocking capacitor, the step-up transformer and the load resonant circuit formed by the DBD excimer UV lamp when n=3, 5,7,9, respectively.

As shown in fig. 12, a schematic circuit diagram of a 150W DBD excimer UV lamp power supply according to an embodiment is shown:

m1 module 120-277Vac alternating current power supply input and EMI filter circuit

M2 module PFC power factor correction

M3 module square wave oscillation and power output

Load resonant circuit composed of M4 module blocking capacitor, step-up transformer and DBD excimer UV lamp

M5 module PFC power factor control circuit

Auxiliary power supply inside M6 module

The specific implementation steps of the circuit element parameter determination and circuit control may be as follows, wherein reference numerals of the circuit elements refer to fig. 13:

1. measuring the series value of a dielectric capacitor Cd and an air gap equivalent capacitor Cg of the DBD excimer UV lamp when the DBD excimer UV lamp is not discharged and the discharge maintaining voltage Vth of the dielectric barrier discharge lamp in an off-line manner;

2. multiplying the amplitude of square wave voltage by 4/pi to obtain the amplitude of fundamental wave, multiplying the amplitude of fundamental wave by (1/N) to obtain the amplitude of Nth harmonic, taking Q=5 as the quality factor of a resonant circuit, calculating and considering the discharge maintenance voltage Vth (usually 2000V) of the dielectric barrier discharge lamp, and determining the turns ratio of a low-voltage winding and a high-voltage winding of the transformer;

3. determining the resonance point frequency Fr of a load resonant circuit consisting of a blocking capacitor, a step-up transformer and a DBD excimer UV lamp by adopting a calculation or software simulation mode according to the number ratio of turns of the step-up transformer, the inductance value of a winding, the leakage inductance value and other parameters, and Cd and Cg of the DBD excimer UV lamp, and referring to FIG. 7;

4. and according to the obtained resonance point frequency Fr of the load resonant circuit, selecting the adopted harmonic frequency N, and finally determining the working frequency=Fr/N of the square wave.

In accordance with the design principles described above, a set of circuit typical parameters are given below:

direct current voltage DC:450V; capacitance C1:0.22uF; turn ratio of step-up transformer T1 = 1:10, low side inductance=1200 uH, leakage inductance=130 uH, high voltage winding inductance=90 mH; the DBD excimer UV lamp Cd is connected in series with Cg=81 pF, the resonance point Fr= 135.14KHz (the lamp is not discharged) of the load resonant circuit is replaced by Vth after the lamp is discharged, the equivalent capacitance is increased, the resonance point of the load resonant circuit is reduced to 111.11KHz, and the square wave working frequency is 27.028KHz.

(N＝111.11KHz/27.028KHz＝4.11)

The circuit operating waveforms under this set of parameters are shown in fig. 13, and are described in detail as follows:

the channel CH2500V/DIV is a square wave with the frequency of 27.028 KHz;

the channel CH12A/DIV is the lamp current waveform pulse current amplitude=6a or so of the DBD excimer UV lamp;

the channel CH42KV/DIV is about 5KV of the peak value of the lamp voltage waveform pulse voltage of the DBD excimer UV lamp;

x-axis time base 10us/DIV;

the input power of DBD excimer UV lamp=158W.

When the working frequency of the square wave is in a damped sinusoidal oscillation area through proper selection of N, the positive half cycle and the negative half cycle of the square wave are damped and sinusoidal oscillation first cycle generates high voltage, so that the DBD excimer UV lamp obtains steeper dv/dt (N times) pulse edges, and a damped sinusoidal pulse forming time interval with lower high voltage is arranged between positive and negative high voltage pulses, which is beneficial to providing the particle state recovery time (the current flowing through the DBD load is close to zero at the stage) special for the DBD load, therefore, the requirements of the pulse high voltage edge high dv/dt and the time interval between pulses can be simultaneously met, and the excitation efficiency of the DBD excimer UV light source is improved by 30% -50%. Because the independent inductor (used as current limiting or impedance matching) is not used, but only leakage inductance of the step-up transformer is adopted to participate in resonance, the resonance network inductance is reduced, the resonance frequency point of the lamp load can be effectively improved, the dv/dt of the pulse edge is improved, the circuit efficiency is high, the circuit structure is simplified, the number of elements is small, and the cost performance is high. By adopting the working mode that the square wave output frequency is 1/N times of the resonance frequency of the load resonant circuit, the current flowing through the winding of the step-up transformer is the damped oscillation current with the load resonant circuit frequency being periodic, compared with the current of an inductance load step-up transformer working in a non-resonant mode, the current limiting device has the advantages that the inductance of the winding required by current limiting is smaller, the number of turns is smaller correspondingly, the temperature rise of the step-up transformer is lower, and the efficiency is improved. The stability of the lamp output power is improved: because the square wave frequency is 1/N of the frequency of the resonance point of the load resonant circuit, the equivalent Q value of the circuit is not high compared with that of an inductive working area working in a 4-area, the influence of load change on the working state of the circuit is small, and a complex control circuit such as frequency tracking and the like can be omitted, so that more stable lamp power can be obtained.

While specific embodiments of the application have been described above, it will be appreciated by those skilled in the art that the specific embodiments described are illustrative only and not intended to limit the scope of the application, and that equivalent modifications and variations of the application in light of the spirit of the application will be covered by the claims of the present application.

Claims (5)

1. A square wave drive damped sinusoidal pulse high voltage power supply suitable for DBD excimer UV lamps, comprising:

the square wave driving circuit is connected with the square wave driving power supply and used for converting the square wave driving power supply into square wave output;

the high-voltage side of the step-up transformer is connected with the DBD excimer UV lamp, and the low-voltage side of the step-up transformer is connected with the square wave driving circuit; the step-up transformer and the DBD excimer UV lamp form a load resonant circuit;

the frequency of the square wave output is 1/N times of the resonance frequency of the load resonance circuit, so that N damped sine oscillation waves taking the resonance frequency of the load resonance circuit as a period are formed in the positive half cycle and the negative half cycle of the square wave, the high voltage generated by the first cycle of the damped sine oscillation of the positive half cycle and the negative half cycle of the square wave is used for breakdown of the DBD to form discharge, the rest damped sine oscillation waves are used for time intervals among pulses, wherein N is more than or equal to 2.5 and less than or equal to 20, and N is not an integer; when the number of the resonance points of the load resonance circuit is larger than one, the frequency corresponding to the highest resonance point is taken as the resonance frequency.

2. The power supply of claim 1, wherein:

when the square wave driving circuit is a half-bridge square wave driving circuit, the low-voltage side of the step-up transformer is connected with the square wave driving circuit through a blocking capacitor;

when the square wave driving circuit is a full-bridge square wave driving circuit, the low-voltage side of the step-up transformer can be connected with the square wave driving circuit through a blocking capacitor or directly connected with the square wave driving circuit without the blocking capacitor;

when the step-up transformer is connected with the square wave driving circuit through the blocking capacitor, the load resonant circuit further comprises the blocking capacitor.

3. The power supply of claim 1, wherein: the value of N satisfies the frequency range of 14KHz-500KHz of square wave output.

4. The power supply of claim 1, wherein: the square wave drive power supply voltage range is 12VDC-800VDC.

5. The power supply of claim 1, wherein: the resonance frequency point of the resonance frequency of the load resonance loop is obtained by adopting conventional calculation, software simulation or actual measurement.