CN202475910U - Constant light control circuit for high-power pulse xenon lamp with ultra-large pulse width - Google Patents

Abstract

The utility model provides a constant light control circuit for a high-power pulse xenon lamp with an ultra-large pulse width. At a charging preparation period, a direct-current charging and discharging power supply is used for charging a plurality of storage capacitors; after an xenon lamp is trigger to work, each storage capacitor is controlled by using a time sequence pulse generator to discharge for the xenon lamp in sequence through a corresponding switching element, so that light power output of a super long pulse width can be obtained conveniently, and the working stability and reliability of the entire circuit are enhanced greatly; and the quantity of the storage capacitors can be determined according to a needed pulse width. Meanwhile, a light strength feedback control loop is used for adjusting the luminous power of the xenon lamp at any moment by detecting the luminous state of the xenon lamp, so that the light power output of the xenon lamp is kept in a constant state.

Description

The permanent light control circuit of a kind of highpowerpulse xenon lamp of overlength pulsewidth

Technical field

The utility model relates to a kind of control circuit of xenon flash lamp, particularly a kind of permanent light control circuit of highpowerpulse xenon lamp that is used for the overlength pulsewidth of pulse solar simulator.

Background technology

Solar simulator is generally used for producing the sunlight of simulation, and solar cell or solar module are tested.Business-like solar simulator has two types: one type is the stable state solar simulator, and as light source, the common illuminating area of this type solar simulator is less with the lamp source (like stable state xenon lamp, tungsten lamp or mercury lamp) of Chang Liang, and the measured object temperature rise is very fast; Second type is the pulse solar simulator, is light source by one or two long arc xenon flash lamp usually, and this type solar simulator illuminating area is bigger, because be short time pulse flash of light, so the measured object temperature rise can be ignored.

The illuminating source of pulse solar simulator adopts the highpowerpulse xenon lamp usually at present; In the practical application; Because the highpowerpulse xenon lamp is operated under high voltage, the current state; The working pulse width of conventional electric capacity and capacitance group energy storage discharge mode of operation is usually less than 40ms, if the working pulse width requirement greater than 40ms (like 100ms--200ms) and require under the situation of permanent light, the control circuit of routine just is difficult to realize.

The utility model content

The technical problem that the utility model will solve is: a kind of permanent light control circuit of highpowerpulse xenon lamp of overlength pulsewidth is provided, can obtains overlength pulsewidth, luminous power output that light intensity is constant easily.

The utility model is to solve the problems of the technologies described above the technical scheme of being taked to be: the permanent light control circuit of a kind of highpowerpulse xenon lamp of overlength pulsewidth, and it is characterized in that: it comprises:

Direct current discharges and recharges power supply, is used for comprising earth terminal, charging end and discharge end to energy capacitance set charging and discharge;

Energy capacitance set; Comprise N storage capacitor; The positive pole of each storage capacitor is connected through the charging end that charging diode and direct current discharge and recharge power supply; The positive pole of each storage capacitor also is connected through the discharge end that discharge diode and direct current discharge and recharge power supply, and the negative pole of each storage capacitor is connected and ground connection with the earth terminal that direct current discharges and recharges power supply;

Sequence timer comprises common port and pulse output end;

The pulse switch group; Comprise N switch element; The positive pole of N switch element is connected with the positive pole of N said storage capacitor successively, and the negative pole of switch element is connected with the common port of sequence timer, and the control end of switch element is connected with the pulse output end of sequence timer; The negative pole of switch element is connected with the xenon lamp positive pole;

The light intensity feedback control loop is that voltage is compared with reference voltage through photoelectric sensor with the transform light energy of xenon lamp, again the luminous power through power regulator control xenon lamp;

Power supply provides power supply for direct current discharges and recharges power supply, sequence timer and light intensity feedback control loop;

Said N is the natural number more than or equal to 2.

Press such scheme, it also comprises buffer capacitor, and the positive pole of buffer capacitor is connected with the discharge end that said direct current discharges and recharges power supply through discharge diode, the minus earth of buffer capacitor; Connect between the negative pole of said switch element and the xenon lamp positive pole buffer resistance and a current-limiting resistance; Simultaneously the positive pole of buffer capacitor also is connected with node between the current-limiting resistance with buffer resistance.

Press such scheme, described direct current discharges and recharges power supply and comprises charging circuit, discharge circuit and charge-discharge control circuit;

Solid-state relay SSR of series connection on the described charging circuit, the charging control end of charge-discharge control circuit is connected with the control end of solid-state relay SSR;

Described discharge circuit comprises discharge control valve, discharge switch and current-limiting resistance; Said storage capacitor, discharge diode, current-limiting resistance, discharge switch and earth terminal constitute discharge loop; Discharge switch is by the control of discharge control valve, and the discharge control valve is by the discharge control end control of charge-discharge control circuit;

Described charge-discharge control circuit comprises sample circuit, bleeder circuit, discharges and recharges and forbid terminal, first comparator and second comparator; Sample circuit is taken a sample to the voltage of said storage capacitor, and bleeder circuit output charging voltage threshold values V1 and discharge voltage threshold values V2 discharge and recharge and forbid terminal input xenon lamp light on and off information; First comparator input terminal input discharge voltage threshold values V2, storage capacitor voltage and xenon lamp light on and off information, output is the discharge control end; The second comparator input terminal input charging voltage threshold values V1, storage capacitor voltage and xenon lamp light on and off information, output is the charging control end.

The operating state of the utility model is divided into charging preparatory stage, discharge adjustment period and xenon lamp duty cycle three phases: in the charging preparatory stage; Direct current discharges and recharges the charging end of power supply and respectively each storage capacitor is charged through corresponding charging diode, after the terminal voltage of each storage capacitor reaches the charging voltage threshold values that direct current discharges and recharges power settings, stops charging; In discharge adjustment period, if reaching direct current, the terminal voltage of storage capacitor discharges and recharges power supply discharge threshold values, storage capacitor can discharge through the discharge end that direct current discharges and recharges power supply; In between above-mentioned charging preparatory stage and discharge adjustment period,, make the terminal voltage of each storage capacitor remain on direct current and discharge and recharge in the voltage range that power supply sets through continuous charging and discharge adjustment process; Xenon lamp be triggered start working after; Each pulse output end of sequence timer is output control pulse successively in order; Open successively respectively and be attached thereto each switch element that connects; Make corresponding storage capacitor successively to flashlamp discharge, each storage capacitor just discharges to xenon lamp in a relatively short period, reaches needed overlength working pulse width thereby add up the discharge time of each storage capacitor.

The beneficial effect of the utility model is:

1, between the charging preparatory stage, direct current discharges and recharges power supply and earlier a plurality of storage capacitors is charged; After xenon lamp triggering work; Each storage capacitor is through corresponding switch element; In order successively to flashlamp discharge, can obtain the luminous power output of overlength pulsewidth by sequence timer control easily, the job stability and the reliability of entire circuit are greatly enhanced; Wherein the number of storage capacitor is decided by required pulsewidth.

2, the light intensity feedback control loop is adjusted its luminous power constantly through detecting the luminous situation of xenon lamp simultaneously, makes the luminous power output of xenon lamp keep steady state.

3, through increasing the filter action of buffer resistance and buffering electric capacity, make that the voltage at buffer capacitor two ends is level and smooth relatively, no spike and burr.

4, direct current discharges and recharges the inner charge-discharge control circuit of power supply and can charge to storage capacitor by the voltage control charging circuit of setting, and also can when the storage capacitor terminal voltage reaches the discharge threshold values of setting, control discharge circuit storage capacitor is discharged; Can also when emergencies such as charge-discharge control circuit dead electricity, directly discharge to storage capacitor; At the xenon lamp duration of work, charge-discharge control circuit will be forbidden charging, the discharge operation of charging circuit and discharge circuit.

Description of drawings

Fig. 1 is the main circuit schematic diagram of the utility model one embodiment.

Fig. 2 is the waveform and the sequence timer output waveform figure of each reference point among Fig. 1.

Fig. 3 discharges and recharges power supply internal circuit configuration figure for direct current.

Embodiment

Fig. 1 is the main circuit schematic diagram of the utility model one embodiment, and it comprises:

Direct current discharges and recharges power supply 1, is used for comprising earth terminal GND, charging end OUT1 and discharge end OUT2 to energy capacitance set charging and discharge.

Energy capacitance set; Comprise N storage capacitor Ca, Cb ..., Cn; The positive pole of each storage capacitor through charging diode Da1, Db1 ..., Dn1 is connected with the charging end OUT1 that direct current discharges and recharges power supply 1; The positive pole of each storage capacitor also through discharge diode Da2, Db2 ..., Dn2 is connected with the discharge end OUT2 that direct current discharges and recharges power supply 1, the negative pole of each storage capacitor is connected and ground connection with the earth terminal GND that direct current discharges and recharges power supply 1.

Sequence timer 2, comprise common port G and pulse output end a, b ..., n.

The pulse switch group; Comprise N switch element Ka, Kb ..., Kn; The positive pole of N switch element is connected with the positive pole of N said storage capacitor successively, promptly Ka anodally be connected with the Ca positive pole ..., Kn is anodal is connected with the Cn positive pole, the negative pole of switch element is connected with the common port G of sequence timer; The control end of switch element is connected with the pulse output end of sequence timer, promptly the Ka control end be connected with a ..., the Kn control end is connected with n; The negative pole of switch element is connected with xenon lamp L positive pole.

The light intensity feedback control loop is that voltage is compared with reference voltage through photoelectric sensor with the transform light energy of xenon lamp, again the luminous power through power regulator control xenon lamp; Comprise light intensity control circuit 3, power regulator Q, photoelectric sensor Es, an input input reference voltage V of light intensity control circuit 3 _REF, another input is connected with photoelectric sensor Es, and the control end of power regulator Q is connected with the control output end of light intensity control circuit 3, and the anode of power regulator Q is connected with the negative electrode of xenon lamp L, the minus earth of power regulator Q.

Power supply 4 provides power supply for direct current discharges and recharges power supply 1, sequence timer 2 and light intensity feedback control loop.

Buffer capacitor C, the positive pole of buffer capacitor C is connected the minus earth of buffer capacitor C through discharge diode D with the discharge end OUT2 that said direct current discharges and recharges power supply 1; A buffer resistance Ra and a current-limiting resistance Rb connect between the negative pole of said switch element and the xenon lamp positive pole; Simultaneously the positive pole of buffer capacitor C also is connected with node between the current-limiting resistance Rb with buffer resistance Ra.

If the node that the negative pole of all switch elements connects is as public output stage A, the just very Node B of buffer capacitor C.

In the xenon lamp duration of work,, make the luminous power output of xenon lamp keep steady state through the light intensity feedback control loop that current-limiting resistance Rb, xenon lamp L, power regulator Q, photoelectric sensor Es and light intensity control loop are formed.Reference voltage V _REFVoltage magnitude can adjust the luminous power output variable of xenon lamp L, reference voltage V _REFVoltage magnitude high more, the output of the luminous power of xenon lamp L is also big more.Reference voltage V _REFPolarity can control the Push And Release of the luminous power output of xenon lamp L: work as reference voltage V _REFPolarity be on the occasion of the time, power regulator Q has drive signal, can work in permanent light state, xenon lamp L works in permanent light output state; Work as reference voltage V _REFPolarity be negative value or when being zero, power regulator Q does not have drive signal, works in cut-off state, xenon lamp L does not have luminous power output.

Light intensity feedback control loop and sequence timer all belong to existing ripe control technology, and its operation principle is no longer done detailed elaboration at this.

It is as shown in Figure 3 that direct current discharges and recharges the internal circuit configuration of power supply 1, comprises charging circuit 5, discharge circuit 6 and charge-discharge control circuit 7.The discharge control end 17 of charge-discharge control circuit 7 is connected with the control end of the discharge control valve VT2 of discharge circuit 6; The charging control end 18 of charge-discharge control circuit 7 is connected with the control end of the solid-state relay SSR of charging circuit 5.

When direct current discharges and recharges the charge-discharge control circuit work of power supply 1 inside; Can charge to outside storage capacitor by the charging voltage threshold values control charging circuit of setting; Also can when the storage capacitor terminal voltage reaches the discharge voltage threshold values of setting, control above-mentioned discharge circuit outside storage capacitor is discharged, can also when emergencies such as control circuit dead electricity, directly discharge storage capacitor; At the xenon lamp duration of work, charge-discharge control circuit will be forbidden charging, the discharge operation of charging circuit and discharge circuit.

As shown in Figure 3, charging circuit 5 is made up of current-limiting resistance R1, solid-state relay SSR (conducting and the off state of the control side controllable switch side of solid-state relay SSR), diode D1 and capacitor C 1.When the control side high level of solid-state relay SSR; The switch-side conducting of solid-state relay SSR; The current rectifying and wave filtering circuit that AC power AC IN forms through current-limiting resistance R1, solid-state relay SSR, diode D1 and capacitor C 1; Through OUT1 output DC source, charging end, through external charge diode Da1, Db1 ..., Dn1 to storage capacitor Ca, Cb ..., Cn carries out charging operations.

Discharge circuit 6 is made up of discharge control valve VT2, discharge switch VT3, current-limiting resistance R3, discharge end OUT2, earth terminal GND etc.The on off state of discharge switch VT3 is controlled by the level of the control end of discharge control valve VT2.When the control end of control valve VT2 is low level; Discharge switch VT3 conducting, storage capacitor Ca, Cb ..., Cn can pass through external discharge diode Da2, Db2 ..., composition such as Dn2, discharge end OUT2, current-limiting resistance R3, discharge switch VT3 and earth terminal GND discharge loop carry out discharge operation.

Charge-discharge control circuit 7 by the first comparator A1, the second comparator A2, voltage-regulation potentiometer VR, discharge and recharge and forbid that terminal Vi, stabilized voltage power supply VCC, charging control end 18, discharge control end 17 and divider resistance Rc, Rd, Re, Rf, Rg etc. partly form.The sample circuit that resistance R c, Rd form through discharge end OUT2 to external storage capacitor Ca, Cb ..., Cn terminal voltage U take a sample; The bleeder circuit that resistance R e, Rf, Rg form accurately is provided with charging/discharging voltage threshold values V1, V2; Voltage-regulation potentiometer VR can to external storage capacitor Ca, Cb ..., Cn terminal voltage U carry out the setting of preliminary scope; The output of the first comparator A1 links to each other with discharge control end 17 through diode D3, can be to the control valve VT2 that the discharges control of discharging; The output of the second comparator A2 control end 18 that promptly charges links to each other with the control side of solid-state relay SSR, can be to the solid-state relay SSR control of charging; During the xenon lamp flash of light; Forbid terminal Vi input high level from discharging and recharging, control end 18 output low levels of then charging, solid-state relay SSR turn-offs; Charging circuit 5 stops charging; The control end 17 that discharges simultaneously is high level, and VT3 turn-offs through discharge control valve VT2 control switch element, and discharge circuit 6 stops discharge.

The control principle of charge-discharge control circuit 7 is such: after voltage-regulation potentiometer VR adjustment was fixing, Rc, Rd and Re, Rf, the equal resistance value of Rg confirm, charging voltage threshold values V1 and discharge voltage threshold values V2 were just definite; If external storage capacitor Ca, Cb ..., Cn terminal voltage U when being lower than charging voltage threshold values V1; The positive input terminal of the second comparator A2 is higher than the level of negative input end; Promptly charge control end 18 of the output of the second comparator A2 is high level; The switch-side conducting of solid-state relay SSR at this moment; The current rectifying and wave filtering circuit that AC power AC IN forms through current-limiting resistance R1, solid-state relay SSR, diode D1 and capacitor C 1, through OUT1 output DC source, charging end, through external charge diode Da1, Db1 ..., Dn1 to storage capacitor Ca, Cb ..., Cn carries out charging operations.When external storage capacitor Ca, Cb ..., Cn terminal voltage U be charged to when being higher than charging voltage threshold values V1; The positive input terminal of the second comparator A2 is lower than the level of negative input end; Promptly charge control end 18 of the output of the second comparator A2 is low level; This moment, the switch-side of solid-state relay SSR was turn-offed, and charging process stops.

In the above charging control process; Because external storage capacitor Ca, Cb ..., Cn terminal voltage U be lower than discharge voltage threshold values V2 all the time; The positive input terminal of the first comparator A1 level than negative input end all the time is high; The output of the first comparator A1 control end 17 that promptly discharges is always high level, makes discharge switch VT3 turn-off through discharge control valve VT2 control always, and discharge circuit 6 is in halted state.Because the control features of the charge circuit that above-mentioned solid-state relay SSR etc. form is limit; Be the necessary zero-crossing switching of solid-state relay SSR, so even the switch-side of solid-state relay SSR is turn-offed, charging process not necessarily can stop at once; Like this storage capacitor Ca, Cb ..., Cn terminal voltage U possibly continue to rise; If storage capacitor Ca, Cb ..., Cn terminal voltage U greater than discharge voltage threshold values V2, the positive input terminal of the first comparator A1 is lower than the level of negative input end, the output of the first comparator A1 control end 17 that promptly discharges is always low level; Make discharge switch VT3 conducting through discharge control valve VT2 control, discharge circuit 6 is in discharge condition.In this process; Because external storage capacitor Ca, Cb ..., Cn terminal voltage U be higher than charging voltage threshold values V1 all the time; The positive input terminal of the second comparator A2 level than negative input end all the time is low; The output of the second comparator A2 control end 18 that promptly charges is always low level, and the switch-side of solid-state relay SSR is in off state all the time, and charging circuit stops charging operations all the time.

Fig. 2 is the waveform and the sequence timer output waveform figure of each reference point among Fig. 1, and wherein 8 is oscillograms of the terminal voltage U of storage capacitor Ca, Cb, Cc, Cn; The 9th, reference voltage V _REFOscillogram, the luminous control waveform figure of xenon lamp in fact just; The 10th, the oscillogram of the pulse output end a voltage U a of sequence timer 2; The 11st, the oscillogram of the pulse output end b voltage U b of sequence timer 2; The 12nd, the oscillogram of the pulse output end c voltage U c of sequence timer 2; The 13rd, the oscillogram of the pulse output end n voltage U n of sequence timer 2; The 14th, the oscillogram of the voltage U A of public output stage A in the accompanying drawing 1; The 15th, the oscillogram of the voltage U B of Node B in the accompanying drawing 1; The 16th, the voltage U at photoelectric sensor Es two ends in the accompanying drawing 1 _EsOscillogram, in fact it represented the luminous power waveform of xenon lamp output.

Below in conjunction with accompanying drawing 1, accompanying drawing 2, the course of work of the control circuit of the utility model embodiment is described: the adjustment period that the operating state of foregoing circuit being divided into charging preparatory stage, discharge and xenon lamp duty cycle three phases:

In the charging preparatory stage: when storage capacitor Ca, Cb ..., Cn terminal voltage U when being lower than direct current and discharging and recharging the charging voltage threshold values V1 that power supply 1 sets, direct current discharge and recharge power supply 1 through corresponding charging diode Da1, Db1 ..., Dn1 respectively to storage capacitor Ca, Cb ..., Cn charges; When storage capacitor Ca, Cb ..., Cn terminal voltage U reach and stop charging after direct current discharges and recharges the charging voltage threshold values V1 that power supply 1 sets.Because the local action of capacitor itself, storage capacitor Ca, Cb ..., Cn terminal voltage U can slowly descend, so above-mentioned charging process can intermittently be carried out.

In the adjustment period of discharge: because the necessary zero-crossing switching of solid-state relay SSR; So even the switch-side of solid-state relay SSR is turn-offed; Charging process not necessarily can stop at once; Like this storage capacitor Ca, Cb ..., Cn terminal voltage U might continue to rise, if storage capacitor Ca, Cb ..., Cn terminal voltage U meet or exceed direct current when discharging and recharging the discharge voltage threshold values V2 of power supply 1, storage capacitor Ca, Cb ..., Cn discharges through the discharge end OUT2 that direct current discharges and recharges power supply 1.

In between above-mentioned charging preparatory stage and discharge adjustment period, through continuous charging and discharge adjustment process, make storage capacitor Ca, Cb ..., Cn terminal voltage U remain on direct current and discharge and recharge in voltage range V1≤U≤V2 that power supply 1 sets.

In the xenon lamp duty cycle; The pulse output end a of sequence timer 2, b ..., n in order successively output control pulse Va, Vb ..., Vn; Open successively respectively be attached thereto the switch element Ka that connects, Kb ..., Kn; Make corresponding storage capacitor Ca, Cb ..., Cn through buffer resistance Ra and buffering capacitor C successively to xenon lamp L discharge, thereby reach needed work pulsewidth; The output voltage of public output stage A is VA, through the filter action of buffer resistance Ra with the buffering capacitor C, makes that the voltage VB at buffer capacitor C two ends is level and smooth relatively, no spike and burr.

Claims (3)

1. the permanent light control circuit of the highpowerpulse xenon lamp of an overlength pulsewidth, it is characterized in that: it comprises:

Direct current discharges and recharges power supply, is used for comprising earth terminal, charging end and discharge end to energy capacitance set charging and discharge;

Energy capacitance set; Comprise N storage capacitor; The positive pole of each storage capacitor is connected through the charging end that charging diode and direct current discharge and recharge power supply; The positive pole of each storage capacitor also is connected through the discharge end that discharge diode and direct current discharge and recharge power supply, and the negative pole of each storage capacitor is connected and ground connection with the earth terminal that direct current discharges and recharges power supply;

Sequence timer comprises common port and pulse output end;

The pulse switch group; Comprise N switch element; The positive pole of N switch element is connected with the positive pole of N said storage capacitor successively, and the negative pole of switch element is connected with the common port of sequence timer, and the control end of switch element is connected with the pulse output end of sequence timer; The negative pole of switch element is connected with the xenon lamp positive pole;

The light intensity feedback control loop is that voltage is compared with reference voltage through photoelectric sensor with the transform light energy of xenon lamp, again the luminous power through power regulator control xenon lamp;

Power supply provides power supply for direct current discharges and recharges power supply, sequence timer and light intensity feedback control loop;

Said N is the natural number more than or equal to 2.

2. the permanent light control circuit of the highpowerpulse xenon lamp of overlength pulsewidth according to claim 1; It is characterized in that: it also comprises buffer capacitor; The positive pole of buffer capacitor is connected with the discharge end that said direct current discharges and recharges power supply through discharge diode, the minus earth of buffer capacitor; Connect between the negative pole of said switch element and the xenon lamp positive pole buffer resistance and a current-limiting resistance; Simultaneously the positive pole of buffer capacitor also is connected with node between the current-limiting resistance with buffer resistance.

3. the permanent light control circuit of the highpowerpulse xenon lamp of overlength pulsewidth according to claim 1 and 2, it is characterized in that: described direct current discharges and recharges power supply and comprises charging circuit, discharge circuit and charge-discharge control circuit;

Solid-state relay SSR of series connection on the described charging circuit, the charging control end of charge-discharge control circuit is connected with the control end of solid-state relay SSR;

Described discharge circuit comprises discharge control valve, discharge switch and current-limiting resistance; Said storage capacitor, discharge diode, current-limiting resistance, discharge switch and earth terminal constitute discharge loop; Discharge switch is by the control of discharge control valve, and the discharge control valve is by the discharge control end control of charge-discharge control circuit;

Described charge-discharge control circuit comprises sample circuit, bleeder circuit, discharges and recharges and forbid terminal, first comparator and second comparator; Sample circuit is taken a sample to the voltage of said storage capacitor, and bleeder circuit output charging voltage threshold values V1 and discharge voltage threshold values V2 discharge and recharge and forbid terminal input xenon lamp light on and off information; First comparator input terminal input discharge voltage threshold values V2, storage capacitor voltage and xenon lamp light on and off information, output is the discharge control end; The second comparator input terminal input charging voltage threshold values V1, storage capacitor voltage and xenon lamp light on and off information, output is the charging control end.

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