CN101312609A - Flash control circuit - Google Patents

Abstract

The invention relates to a flashlight control circuit, comprising a charging module comprising an oscillator, a flashlight module and a control module for controlling the charging module to start/stop charging the flashlight module, wherein the charging module comprises a protection unit. When the protection unit detects the peak current of the oscillator is higher than a current preset value, the protection unit adopts the control module to control the oscillator to enter in the next charging period. The flashlight control circuit adopts the protection unit to detect the peak current of the oscillator, and when the peak current is over the maximum allowance current of the oscillator, the protection unit adopts the control module to enter the oscillator into the next charging period, thereby effectively protecting the oscillator.

Description

Flash control circuit

Technical field

The present invention relates to a kind of flash control circuit.

Background technology

See also Fig. 1, general flash control circuit 100 comprises charging module 102, flash modules 104 and control module 106, the charging capacitor of 102 pairs of flash modules 104 of these control module 106 may command charging modules (figure does not show) action of charging.When charging signals becomes high level by low level, control module 106 makes charging module 102 begin the electric capacity in the flash modules 104 is charged, when the voltage at electric capacity two ends reaches preset value, then charging signals becomes low level by high level, and control module 106 makes charging module stop the electric capacity in the flash modules 104 is charged.Flash control circuit 100 is by 200 power supplies of the system power supply module in the device at flash control circuit 100 places.

In the prior art, charging module 102 comprises oscillator and has primary coil and the transformer of secondary coil that flash modules 104 comprises rectifier diode.The process that charging capacitor is charged is that the secondary coil of transformer induces induced electromotive force and induced current and the rectifier diode by flash modules 104 charges to charging capacitor.Because the equivalent electric circuit of the primary coil of transformer is the antiresonant circuit of resistance, inductance and electric capacity.In charging process, because the existence of resistance is arranged in the loop, when electric current is flowed through the coil groups of transformer, coil groups can be generated heat, electric current is big more, caloric value is big more, and this moment, the inductance value of primary coil can diminish because temperature raises, and the inductance value of the peak current of transformer and transformer is the relation of being inversely proportional to.Therefore, the peak electricity of the primary coil increase that fails to be convened for lack of a quorum of flowing through.In the electric current rising cycle of the oscillator in charging module 102, when peak current surpassed the maximum current that oscillator connect with this primary coil can bear, oscillator was burnt easily, thus the initiation safety problem.

Summary of the invention

In view of this, be necessary to provide a kind of flash control circuit of protecting oscillator.

A kind of flash control circuit, it comprises: charging module, control module and flash modules.This charging module comprises oscillator.This control module is used to control this charging module flash modules is begun/stop the charging action; wherein; this charging module comprises protected location; the peak current that monitors the oscillator of flowing through when protected location is during greater than the electric current preset value, and this protected location is controlled this oscillator by control module and entered next charge cycle.

A kind of flash control circuit, it comprises charging module, flash modules and control module, this charging module comprises oscillator, wherein, this charging module comprises protected location.This control module output oscillation control signal is to the oscillator of this charging module, and this charging module begins/stop the charging action according to this oscillator signal to flash modules.The peak current that monitors the oscillator of flowing through when protected location is during greater than the electric current preset value, and this protected location output feedback signal is to this control module, and control module is controlled this oscillator according to this feedback signal and entered next charge cycle.

Described flash control circuit; by the peak current of protected location monitoring flow through oscillator; when peak current surpassed the maximum current that oscillator can bear, protected location made oscillator enter next charge cycle by control module, thereby effectively protects oscillator.

Description of drawings

Fig. 1 is the functional block diagram of a kind of flash control circuit of the prior art.

The functional block diagram of a kind of flash control circuit that Fig. 2 provides for the embodiment of the invention.

Fig. 3 is a circuit diagram of the flash control circuit among Fig. 2.

Fig. 4 is a sequential chart of the circuit diagram among Fig. 3.

Embodiment

Below in conjunction with accompanying drawing the embodiment of the invention is described in further detail.

See also Fig. 2, first embodiment of the invention provides a kind of flash control circuit 300, and this flash control circuit 300 comprises charging module 302, flash modules 304 and control module 306.This flash control circuit 300 is in the device by flash control circuit 300 places, as magazine system power supply module 200 power supplies of number.This system power supply module 200 comprises system power supply VB.

See also Fig. 3, this charging module 302 comprises oscillator Q1, step-up transformer T1, protected location 308, resistance R 4 and capacitor C 2.This step-up transformer T1 has first polar curve circle and secondary coil.The end of system power supply VB is connected to an end of resistance R 4 and the first polar curve circle of step-up transformer T1 simultaneously, and control module 306 is held with being connected to and be connected to simultaneously to the other end of resistance R 4 through capacitor C 2.This oscillator Q1 is a MOS type field effect transistor (Metal-Oxide-SemiconductorField-Effect-Transistor); the drain electrode of this MOS type field effect transistor Q1 links to each other with system power supply VB through the primary coil of step-up transformer T1, and grid and the source electrode of this MOS type field effect transistor Q1 all are connected to protected location.The secondary coil of step-up transformer T1 is to be connected to flash modules 304.

This protected location 308 comprises that one is set resistance R 1, comparator A1, a logical AND gate D1, a derailing switch 310 and a DC power supply V.

This end of setting resistance R 1 links to each other with source electrode and input of this comparator A1 of MOS type field effect transistor Q1 simultaneously, and the other end of this setting resistance R 1 is held with being connected to.Another input of this comparator A1 links to each other with the positive pole of DC power supply V, the output of this comparator A1 is connected to the input of this logical AND gate D1, the negative pole of DC power supply V is held with being connected to, the input of derailing switch 310 links to each other with the grid of MOS type field effect transistor Q1, the output of this derailing switch 310 links to each other with another input of this logical AND gate D1, and the output of this logical AND gate D1 is connected to an input of this control module 306.When MOS type field effect transistor Q1 closed, these derailing switch 310 output low levels were to the input of logical AND gate D1, so logical AND gate D1 output low level is closed protected location 308; When MOS type field effect transistor Q1 conducting, these derailing switch 310 output high level are to the input of logical AND gate D1, at this moment, if the output low level of comparator A1 is to another input of logical AND gate D1, then logical AND gate D1 output low level is closed protected location 308; If the output high level of comparator A1 is to another input of logical AND gate D1, then logical AND gate D1 output high level is opened protected location 308.

This flash modules 304 comprises rectifier diode D1, Zener diode D2, charging capacitor C0, capacitor C 1, protective resistance R3 and resistance R 2.The positive pole of rectifier diode D1 links to each other with the secondary coil of step-up transformer T1 and holds through resistance R 2 with being connected to; the negative pole of rectifier diode D1 is connected to the negative pole of Zener diode D2 and the end of charging capacitor C0 simultaneously; the positive pole of Zener diode D2 is connected to an end of capacitor C 1, an end and the control module 306 of protective resistance R3 simultaneously; the other end of charging capacitor C0 is connected to the other end of capacitor C 1 and the other end of protective resistance R3 simultaneously, and holds through resistance R 2 with being connected to.

The input of this control module 306 can be connected to digital signal processor (figure do not show), is used to receive charging signals and controls 302 pairs of flash modules of charging module 304 and carry out/stop the charging action.When the oscillation control signal of control module 306 outputs is low level, MOS type field effect transistor Q1 is closed; When the oscillation control signal of control module 306 outputs is high level, make MOS type field effect transistor Q1 conducting.

Please consult Fig. 3 and Fig. 4 simultaneously, below the operating state of explanation flash control circuit 300 of the present invention is divided into normal condition and guard mode.

Normal condition:

When charging signals becomes high level by low level, the oscillation control signal of these control module 306 output high level, MOS type field effect transistor Q1 conducting this moment, electric current I 1 flows to the ground end by the system power supply VB of system power supply module 200 by transformer T1 primary coil, MOS type field effect transistor Q1 and setting resistance R 1, the primary coil of step-up transformer T1 begins the storage power that magnetizes, and finishes by electric energy and changes magnetic energy into.The derailing switch 310 output high level of protected location 308 are to logical AND gate D1.System power supply VB charges by 4 pairs of capacitor C 2 of resistance R.

When the pressure drop of capacitor C 2 during greater than reference voltage, the oscillation control signal of control module 306 output low levels is closed MOS type field effect transistor Q1.This reference voltage can be set by the reference power source in the control module 306.At this moment, the secondary coil of step-up transformer T1 induces induced electromotive force and induced current and by rectifier diode D1 the charging capacitor C0 of flash modules 304 is charged.Along with charging is carried out, the secondary coil induced electromotive force of step-up transformer T1 can slowly reduce, when induced electromotive force during, the oscillation control signal of control module 306 output high level less than default electromotive force, make MOS type field effect transistor Q1 once more conducting enter next charge cycle.Cycle charging so repeatedly, when charging capacitor C0 end was charged to the voltage preset value, Zener diode D2 was breakdown, and the A point becomes high level.The high level that control module 306 is ordered according to this A is controlled this charging module 302 and is stopped the charging action.Should determine by DC power supply (figure does not show) institute that loads on the step-up transformer T1 secondary coil that the voltage preset value that this charging capacitor C0 holds was generally 300 volts by default electromotive force.

In cycle charging process repeatedly, the temperature of transformer T1 primary coil can rise gradually, and the inductance of transformer T1 primary coil is along with decline, and electric current I 1 descends along with the inductance of transformer T1 primary coil and raises.When just beginning; the peak current Ipk of electric current I 1 does not also surpass the maximum current that MOS type field effect transistor Q1 can bear; peak voltage drop Vpk on the setting resistance R 1 of protected location 308 is less than the pressure drop of the DC power supply V of protected location 308; comparator A1 output low level is to logical AND gate D1, as shown in Figure 4.Another input of logical AND gate D1 is by derailing switch 310 input high levels (MOS type field effect transistor Q1 is in conducting state), and therefore, the output of logical AND gate D1 is a low level.At this moment, protected location is in closed condition.

Guard mode:

Carrying out along with charging cycle; when the peak current Ipk of electric current I 1 surpasses the maximum current that MOS type field effect transistor Q1 can bear; protected location 308 detects the peak voltage drop Vpk that sets on the resistance R 1 pressure drop greater than the DC power supply V of protected location 308; comparator A1 output high level is to the input of logical AND gate D1, as shown in Figure 4.Because another input of logical AND gate D1 is by derailing switch 310 input high levels (MOS type field effect transistor Q1 is in conducting state); therefore; this logical AND gate D1 is output as high level; protected location 308 is opened; and control module 306 is according to the high level of logical AND gate D1; the oscillation control signal of output low level is closed MOS type field effect transistor Q1 and is entered next charge cycle.In the present embodiment, the pressure drop of the DC power supply V of protected location 308 is 48 millivolts.

This protected location 308 is by the peak current Ipk of monitor current I1; when peak current Ipk surpasses the maximum current that MOS type field effect transistor Q1 can bear; protected location 308 is closed MOS type field effect transistor Q1 and is entered next charge cycle, thereby effectively protects MOS type field effect transistor Q1.

In the actual job process, can set the size of protected location 308 monitoring peak current Ipk by the saturation current of transformer coil.The saturation current of coil is: when the electric current of coil was increasing, the inductance of coil can reduce.Drop to 10% when electric current makes the inductance value of the ferrite core of transformer, the inductance value that is used for the dustcore of storage power drops to 20%.The electric current of coil is called the saturation current of coil at this moment.

The general extra-thin transformer of industry, its saturation current between normal temperature to 60 degree centigrade is about 1.8 peaces ~ 1.6 peaces.The operating current of the primary coil of step-up transformer T1 is less than the saturation current of coil.Therefore, preferably, the monitoring peak current Ipk that protected location 308 is set closes MOS type field effect transistor Q1 greater than V/R1=1.6 ampere-hour (V is the DC power supply voltage of protected location).

Be understandable that above-mentioned control module 306 comprises trigger, as set-reset flip-floop, latch, function elements such as gate and comparator, this control module 306 can be with reference to the module of flash control circuit tool controlled function of the prior art and is designed.

The related data of present embodiment are for principle of the present invention and enforcement are described better, and those skilled in the art can spirit according to the present invention make other respective change.Certainly, the variation that these are done according to spirit of the present invention, all should be included in the present invention's scope required for protection in.

Claims (11)

1. flash control circuit, it comprises:

Charging module, this charging module comprises oscillator;

Flash modules; And

Control module; be used to control this charging module flash modules is begun/stop the charging action; it is characterized in that; this charging module comprises protected location; the peak current that monitors the oscillator of flowing through when protected location is during greater than the electric current preset value, and this protected location is controlled this oscillator by control module and entered next charge cycle.

2. flash control circuit as claimed in claim 1, it is characterized in that, described charging module comprises the step-up transformer with primary coil, this oscillator is a MOS type field effect transistor, this MOS type field effect transistor is positioned at the outprimary of this step-up transformer, and the grid of this MOS type field effect transistor is connected to this control module.

3. flash control circuit as claimed in claim 2 is characterized in that described flash modules comprises charging capacitor and rectifier diode, and this charging module charges to this charging capacitor by rectifier diode.

4. flash control circuit as claimed in claim 2; it is characterized in that; described protected location comprises that is set a resistance; a comparator; a logical AND gate; a derailing switch and a DC power supply; this is set resistance one end and links to each other with source electrode and input of this comparator of MOS type field effect transistor simultaneously; the other end is held with being connected to; another input of this comparator links to each other with the positive pole of this DC power supply; the output of this comparator is connected to an input of this logical AND gate; the negative pole of this DC power supply is held with being connected to; the input of this derailing switch links to each other with the grid of MOS type field effect transistor; the output of this derailing switch links to each other with another input of this logical AND gate, and the output of this logical AND gate is connected to this control module.

5. flash control circuit as claimed in claim 4 is characterized in that, described peak current is linear with setting resistance.

6. flash control circuit, it comprises charging module, flash modules and control module, this charging module comprises oscillator, it is characterized in that, this charging module comprises protected location, and this control module output oscillation control signal is to the oscillator of this charging module, and this charging module begins/stop the charging action according to this oscillator signal to flash modules; The peak current that monitors the oscillator of flowing through when protected location is during greater than the electric current preset value, and this protected location output feedback signal is to this control module, and control module is controlled this oscillator according to this feedback signal and entered next charge cycle.

7. flash control circuit as claimed in claim 6, when described oscillation control signal was low level, oscillator cut out, and made charging module begin the charging action to flash modules.

8. flash control circuit as claimed in claim 6, when described oscillation control signal was high level, the oscillator conducting made charging module stop the charging action to flash modules.

9. as claim 7 or 8 described flash control circuits, described charging module comprises the step-up transformer with primary coil, this oscillator is a MOS type field effect transistor, this MOS type field effect transistor is positioned at the outprimary of this step-up transformer, and the grid of this MOS type field effect transistor is connected to control module.

10. flash control circuit as claimed in claim 9; described protected location comprises that is set a resistance; a comparator; a logical AND gate; a derailing switch and a DC power supply; this is set resistance one end and links to each other with source electrode and input of this comparator of MOS type field effect transistor simultaneously; the other end is held with being connected to; another input of this comparator links to each other with the positive pole of this DC power supply; the output of this comparator is connected to an input of this logical AND gate; the negative pole of this DC power supply is held with being connected to; the input of this derailing switch links to each other with the grid of MOS type field effect transistor; the output of this derailing switch links to each other with another input of this logical AND gate, and the output of this logical AND gate is connected to this control module.

11. flash control circuit as claimed in claim 10, described feedback signal exports control module to by logical AND gate, when feedback signal is high level, and the oscillation control signal of this control module output low level.

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