JP3651971B2 - Electronic flash device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an electronic flash device for flash having a DC-DC converter that boosts a power supply voltage.
[0002]
[Prior art]
Conventional flash DC-DC converters include a forward converter and a flyback converter using one oscillation transistor.
[0003]
FIG. 9A is a block diagram of a conventional DC-DC converter.
[0004]
In response to the oscillation control signal “CGON” from the control circuit 2700, the oscillation PNP transistor 300 is oscillated through the oscillation control transistor 600, boosted by the transformer 1700, and rectified by the rectifier diode 200. _S2 Then, the main capacitor 2600 is charged. After the charge level is confirmed by the detection circuit 2300, the light emitting circuit 2400 is operated.
[0005]
At this time, the charging current I charged in the main capacitor 2600 _S2 As shown in FIG. 9 (b), since the oscillation PNP transistor 300 flows only during the ON period, and the charging current does not flow during the OFF period, a charging time loss corresponding to the OFF time occurs and the battery has a low voltage. In this case, it takes a long time to charge and it is impossible to shoot until the charging is completed, and the operability of the camera that performs flash shooting is deteriorated.
[0006]
In order to solve such inconvenience, Japanese Patent Application No. 7-103211 by the present applicant has been filed.
[0007]
6 and 7 are circuit block diagrams of the electronic flash device.
[0008]
The electronic flash device shown in FIG. 6 has two divided primary windings 17a and 17b and divided feedback windings 17c and 17d, and oscillation is controlled by the first oscillation control NPN transistor 6. The push-pull type DC-DC converter circuit includes a first oscillation PNP transistor 3 and a second oscillation PNP transistor 10 controlled by a second NPN transistor 13.
[0009]
By common control using the oscillation control signal “CGON” from the control circuit 27, the first and second oscillation control transistors 6 and 13 are simultaneously controlled to alternately output the first and second oscillation outputs. Is rectified by a fridge type rectifier circuit using diodes 19 to 22 to charge the main capacitor 26.
[0010]
8 is a diagram for explaining the operation of the circuit of FIG. 6. FIG. 8A shows the flow of current when the oscillation transistor 3 is on, and FIG. 8B shows the flow of current when the oscillation transistor 10 is on. Yes. First, when the oscillation transistor 3 in FIG. 8A starts oscillating, a part flows from the oscillation transistor 3 through the emitter of the oscillation control transistor 6 to the resistor 18 through the feedback winding 17d as indicated by an arrow. On the secondary side, the rectified current I _S1 Flows to charge the main capacitor 26. Next, when the oscillation transistor 3 is turned off, the oscillation transistor 10 is turned on, and a current flows through the resistor 18 through the feedback winding 17c. _S1 Flows to charge the main capacitor 26 continuously. In this way, the alternating output by the first and second oscillation control is rectified by the rectifier circuit having a bridge configuration to obtain a charging current, and the first and second oscillation control transistors 6 and 13 are controlled from a common control terminal. Therefore, the off time as shown in FIG. 9B is eliminated, and a sufficient charging current can be supplied to eliminate the loss of the charging time, and the control by a common terminal can be performed. The circuit shown in FIG. 7 has the same configuration and operation except that the first and second oscillation control transistors 6 and 13 shown in FIG.
[0011]
[Problems to be solved by the invention]
However, in the above-described conventional example, when the oscillation for charging is started, the startup is facilitated, and when the charging load becomes light, the oscillation is stopped (intermediate stop), and the feedback is made to the transformer 17 to maintain stable oscillation. Each of the windings 17c and 17d is provided. One end of the feedback winding 17c is connected to the emitter of the second oscillation control transistor 13 and the other end is connected to one end of the resistor 18. One feedback winding 17 d has one end connected to one end of the resistor 18, the other end connected to the emitter of the first oscillation control transistor 6, and the resistor 18 connected the other end to the battery 1. With the configuration described above, the feedback winding is divided into 17d for the first oscillation control circuit and 17c for the second oscillation control circuit, and these are operated independently.
[0012]
Therefore, the oscillation transformer divides the primary winding for the first and second oscillation circuits and also divides the feedback winding to provide terminals, so that the number of terminals of the oscillation transformer is increased and the winding method is complicated. As a result, there was a problem that the transformer was enlarged.
[0013]
Therefore, an object of the present invention is to provide a transformer composed of a divided primary winding and a feedback winding, two oscillation transistors for boosting a power supply voltage, and a switch for controlling the operation of each oscillation transistor. An electronic flash device that can oscillate without splitting the feedback winding, reduce the number of transformer terminals, reduce the circuit scale, and reduce component costs with a push-pull DC-DC converter with elements Is to provide.
[0014]
[Means for Solving the Problems]
In order to achieve the above object, the present invention reduces the number of terminals of an oscillation transformer, enables miniaturization, and reduces the circuit scale and component cost.
[0015]
According to a first aspect of the present invention, there is provided a power supply, a transformer having two divided primary windings and a feedback winding, and a switch operation for boosting the power supply voltage. In an electronic flash device including a push-pull DC-DC converter circuit having two oscillation PNP transistors and a switch element for controlling the operation of each oscillation PNP transistor, the first oscillation PNP transistor and the first oscillation A first oscillation control circuit configured by a first switch element for oscillation control for controlling the base of the PNP transistor for use and a first diode for connecting a cathode to the first switch element and connected in parallel to the battery; , A second switch element for oscillation control for controlling the bases of the second oscillation PNP transistor and the second oscillation PNP transistor, and the second A second oscillation control circuit configured by a second diode connecting a cathode to the switch element and connected in parallel to the battery; and one end connected to one end of the second switch element and the other end connected to the first An electronic flash apparatus comprising a feedback winding connected to one end of a switch element and a feedback circuit including first and second resistors connected in parallel to the first and second diodes, respectively is there.
[0016]
According to this configuration, in the electronic flash device configured by the push-pull type DC-DC converter circuit in which the first and second oscillation transistors are controlled by the first and second oscillation control switch elements, the feedback winding is provided. Oscillation operation is possible without division.
[0017]
According to a second aspect of the present invention, there is provided a power supply, a transformer having two divided primary windings and a feedback winding, and a switch operation for boosting the power supply voltage. In an electronic flash device including a push-pull type DC-DC converter circuit having one oscillation PNP transistor and an NPN oscillation control transistor for controlling the operation of each oscillation PNP transistor, the first oscillation PNP transistor and the first oscillation A first oscillation control circuit comprising a first NPN transistor for controlling oscillation for controlling the base of the PNP transistor for use and a first diode having a cathode connected to the emitter of the first NPN transistor and connected in parallel to the battery. Circuit for controlling the base of the second oscillation PNP transistor and the second oscillation PNP transistor. A second oscillation control circuit configured by a second NPN transistor for control and a second diode having a cathode connected to the emitter of the second NPN transistor and connected in parallel to the battery; First and second resistors connected in parallel to the feedback winding and the first and second diodes respectively connected to the emitter of the NPN transistor and the other end connected to the emitter of the first NPN transistor. The electronic flash device is provided with a feedback circuit.
[0018]
According to this configuration, the feedback winding is divided in the electronic flash device including the push-pull type DC-DC converter circuit in which the first and second oscillation transistors are controlled by the first and second oscillation control transistors. Oscillation operation is possible without any problems.
[0019]
According to a third aspect of the present invention, there is provided a power supply, a transformer having two divided primary windings and a feedback winding, and a switch operation for boosting the power supply voltage. A first oscillation PNP transistor and a first oscillation PNP transistor in an electronic flash device including a push-pull DC-DC converter circuit having two oscillation PNP transistors and an FET for controlling the operation of each oscillation PNP transistor A first oscillation control circuit configured to include a first FET for controlling oscillation of the first FET and a first diode having a cathode connected to the source of the first FET, and connected in parallel to the battery; The oscillation control second FET and second FET for controlling the bases of the oscillation PNP transistor and the second oscillation PNP transistor A second oscillation control circuit comprising a second diode for connecting a sword and connected in parallel to the battery; and one end connected to the source of the second FET and the other end to the source of the first FET The feedback winding by the 1st and 2nd resistance connected in parallel to the feedback winding which is connected and shared, and the 1st and 2nd diode, respectively, 3rd and 2nd from the source of the 1st and 2nd FET The anodes of the four diodes are connected, and the respective cathodes are connected to one and other ends of the secondary winding of the transformer, and the anodes of the fifth and sixth diodes are connected to one and the other ends of the secondary winding of the transformer. Connected to the common rectifier circuit and the respective gates of the first and second FETs and turned on by common one-terminal control to start oscillation and turn off. In electronic flash apparatus characterized by comprising one of the oscillation control terminal to stop the oscillation at Rukoto.
[0020]
According to this configuration, in the electronic flash device including the push-pull type DC-DC converter circuit in which the first and second oscillation transistors are controlled by the first and second oscillation control FETs, the feedback winding is provided. Oscillation can be performed without division.
[0021]
【Example】
Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a circuit block diagram of an electronic flash device according to a first embodiment of the present invention.
The present embodiment shown in FIG. 1 has a power supply unit composed of a battery 1 as a power supply and a power stabilization capacitor 2 connected to both ends of the battery 1.
As a first oscillation control circuit, a first oscillation PNP transistor 3 for boosting the voltage of the battery 1 has an emitter connected to one end of the battery 1 and a collector connected to the oscillation transformer 17a, and a capacitor between the emitter and base. 4 and the resistor 5 are connected in parallel. The first oscillation control NPN transistor 6 has a collector connected to the base of the first oscillation PNP transistor 3 to control on / off of the first oscillation PNP transistor 3. A resistor 7 is connected between the base and emitter of the NPN transistor 6, the cathode of the first diode 8 is connected to the emitter, and the anode of the diode 8 is connected to the other end of the battery 1. Thus, the first oscillation control circuit is configured.
[0022]
The seventh diode 9 has a cathode connected to the base of the NPN transistor 6 and an anode connected to one end of the resistor 28 and the anode of the eighth diode 16 for one-terminal control.
[0023]
Next, as a second oscillation control circuit, the second oscillation PNP transistor 10 for boosting the voltage of the battery 1 has an emitter connected to one end of the battery 1 and a collector connected to the oscillation transformer 17b. A capacitor 11 and a resistor 12 are connected in parallel. The second oscillation control NPN transistor 13 has a collector connected to the base of the second oscillation PNP transistor 10 to control on / off of the second oscillation PNP transistor 10. A resistor 14 is connected between the base and emitter of the NPN transistor 13, the cathode of the second diode 15 is connected to the emitter, and the anode of the diode 15 is connected to the other end of the battery 1. Thus, the second oscillation control circuit is configured. These first and second oscillation control circuits are both connected in parallel to the battery 1.
[0024]
The eighth diode 16 has a cathode connected to the base of the second NPN transistor 13 and an anode connected to one end of the resistor 28 and the anode of the seventh diode 9 for one-terminal control.
[0025]
The primary winding of the transformer 17 for boosting oscillation is divided into 17a and 17b. One end of the primary winding 17a is connected to the collector of the first oscillation PNP transistor 3, and the other end of the battery 1 is the other. Connected to the end.
[0026]
One end of the primary winding 17b is connected to the collector of the second oscillating PNP transistor 10, and the other end is connected to the other end of the battery 1 and the other end of the primary winding 17a. The connection between the primary winding 17a and the collector of the first oscillation PNP transistor 3 and the connection between the primary winding 17b and the collector of the second oscillation PNP transistor 10 are as follows. On the other hand, the latter has a different polarity as it is connected at the end of winding.
[0027]
The feedback winding 17 c has one end connected to the emitter of the second oscillation control NPN transistor 13 and the resistor 18, and the other end connected to the emitter of the first oscillation control NPN transistor 6 and the resistor 31. In addition, the first resistor 31 connected in parallel to the first diode 8 and the second resistor 18 connected in parallel to the second diode 15 have their other ends connected to the other end of the battery 1. ing. Thus, the feedback winding 17c in the present embodiment is not a divided type as in the conventional example, but is shared by the first oscillation control circuit and the second oscillation control circuit.
[0028]
Next, the cathode of the high voltage rectifier diode 19 is connected to one end of the secondary winding 17e of the oscillation transformer 17, and its anode is connected to the emitter of the second oscillation control NPN transistor 13 and the feedback winding 17c of the oscillation transformer 17. Connected to one end. The anode of the high voltage rectifier diode 20 is connected to one end of the secondary winding 17 e and the cathode of the high voltage rectifier diode 19. The cathode of the high voltage rectifier diode 21 is connected to the other end of the secondary winding 17e, and its anode is connected to the emitter of the first oscillation control NPN transistor 6 and the other end of the feedback winding 17c. The anode of the high voltage rectifier diode 22 is connected to the other end of the secondary winding 17e and the cathode of the high voltage rectifier diode 21. The cathode of the diode 22 is connected to one end of the main capacitor 26 in common with the cathode of the high voltage rectifier diode 20. doing.
[0029]
A bridge rectifier circuit is constituted by the above four high voltage rectifier diodes. The configuration from the first oscillation PNP transistor 3 to the high-voltage rectifier diode 22 described above is a push-pull type DC-DC converter circuit that operates as a booster circuit.
[0030]
The detection circuit 23 for detecting the charging voltage when the voltage of the battery 1 is boosted by the boosting circuit and charged to the main capacitor 26 is a circuit composed of, for example, a Zener diode or a dividing resistor, and the detected charging level is the signal CGUP. Is input to the control circuit 27. The light emitting circuit 24 is a circuit including a known trigger capacitor, a trigger coil, and the like that generate a high-voltage trigger pulse for discharging the electric charge charged in the main capacitor 26 to the flash discharge tube 25. The TRG signal terminal of the control circuit 27 A high-pressure trigger signal is applied to the flash discharge tube 25 by the pulse signal to be output, thereby causing the flash discharge tube 25 to emit light. Both the detection circuit 23 and the light emitting circuit 24 are connected to both ends of the main capacitor 26.
[0031]
The flash discharge tube 25 is triggered by the light emitting circuit 24 with the anode connected to one end of the main capacitor 26 and the cathode connected to the other end of the main capacitor 26. The main capacitor 26 is a capacitor for charging energy necessary for flash emission, and is connected to both ends of the flash discharge tube 25.
[0032]
The control circuit 27 is composed of a one-chip microcomputer or the like, and is a one-chip IC circuit with a built-in microcomputer including a CPU, ROM, RAM, input / output control circuit, multiplexer, timer circuit, etc., which can control the camera system by software. The power supply uses the output Vcc of the constant voltage circuit 29.
[0033]
Signal terminals related to flash in the control circuit 27 include a CGON terminal, a CGUP terminal, and a TRG terminal. The CGON terminal is connected to a resistor 28 for supplying a drive current to the first and second oscillation control NPN transistors 6 and 13. The oscillation control signal is a one-terminal control in which oscillation is started by changing from Lo Level (hereinafter referred to as LL) to Hi Level (hereinafter referred to as HL) and stopped by setting to LL.
[0034]
The CGUP terminal detects an input signal from the detection circuit 23, monitors the charging voltage of the main capacitor 26, performs level detection, and judges by the CPU of the control circuit 27 to control prohibition and release of the oscillation operation of the booster circuit. This is a charge detection signal.
[0035]
The TRG terminal is an output signal terminal connected to the light emitting circuit 24. In order to send a one-shot signal pulse to the light emitting circuit 24 and output a high-pressure pulse signal by a trigger capacitor and a trigger transformer, the flash discharge tube 25 is triggered to emit light. This is a light emission output terminal. The constant voltage circuit 29 outputs a constant voltage Vcc even when the voltage of the battery 1 changes, and 30 is a switch circuit such as a release switch.
[0036]
FIG. 2 is a flowchart of the operation of the embodiment shown in FIG.
FIG. 3 is a diagram for explaining the operation of the embodiment shown in FIG.
[0037]
Next, the operation will be described with reference to the drawings.
First, initial setting is performed (S1). That is, the microcomputer program flag of the control circuit 27 is cleared or the contents of the memory are reset.
[0038]
A detection circuit 23 for detecting the voltage of the main capacitor 26 detects the charge level of the main capacitor 26 with a CGUP signal, and a predetermined charge completion level (hereinafter, abbreviated as a charge completion level) in order to emit sufficient light for photographing by the camera. ) Is determined (S2). If the result is not above the full level, the process proceeds to S3.
[0039]
By changing the output signal of the CGON terminal of the control circuit 27 from LL to HL (for example, from 0 V to 5 V), the first NPN transistor 6 and the second transistor 13 are connected via the resistor 28, the diode 9, and the diode 16. A current flows through the base to turn it on (S3).
[0040]
In this case, when the first and second NPN transistors 6 and 13 for oscillation control are turned on, the base currents of the first and second oscillation PNP transistors 3 and 10 are drawn and turned on. Variation in the elements of the PNP transistor 3 and the oscillation PNP transistor 10 (current amplification factor h) _FE Current amplification factor h) _FE The oscillation PNP transistor having a large value starts oscillation first. For example, h of the first oscillation transistor 3 _FE Is larger than that of the second oscillating PNP transistor 10, first, the first oscillating PNP transistor 3 is turned on, so that the primary winding 17a of the transformer 17 is connected from the battery 1 via the emitter and collector. Current I _P1 Shed.
[0041]
FIG. 3A is a diagram showing a current flow when the first oscillation PNP transistor is on.
[0042]
FIG. 3B is a diagram showing a current flow when the second oscillation PNP transistor is on. A more detailed operation will be described with reference to the drawings.
[0043]
When the NPN transistor 6 is turned on, the current from the battery 1 passes through the emitter and base of the oscillation PNP transistor 3 along the current path indicated by the arrow in FIG. A part of the current flows through the emitter to the resistor 18 through the feedback winding 17c, but I flows to the primary winding 17a. _P1 As a result, an induced current flows through the secondary winding 17e, and a current flowing through the emitter of the NPN transistor 6 flows through the diode 21 to the secondary winding 17e of the transformer 17 and charges the main capacitor 26 through the diode 20. This secondary current is expressed as I _S1 And
[0044]
Primary current I flowing through the primary winding 17a _P1 Flows rapidly, but when a certain current flows and the transformer 17 is magnetically saturated, the primary current I _P1 Is blocked and does not flow rapidly, and the polarity of the transformer 17 is reversed.
[0045]
At this time, the polarity of both the secondary winding 17e and the feedback winding 17c is reversed. Therefore, the secondary current I _S1 Flows, the first oscillation control NPN transistor 6 is turned off, the first oscillation PNP transistor 3 is turned off, and the first oscillation control circuit stops oscillation.
[0046]
However, since the CGON signal is HL, the second oscillation control NPN transistor 13 is in an ON state, and a current flows through the resistor 31 via the feedback winding 17c of the transformer 17, and the base current of the second oscillation PNP transistor 10 is reached. When the oscillating PNP transistor 10 is turned on, the current I ′ is shown in FIG. 3B through the emitter and collector from the battery 1 to the primary winding 17b. _P1 Flows.
[0047]
Similarly, I ′ flowing through the primary winding 17b _P1 Causes an induced current to flow through the secondary winding 17e, the current flowing through the emitter and base of the second oscillation PNP transistor 10 and the emitter of the NPN transistor 13 passes through the secondary winding 17e via the diode 19, The main capacitor 26 is charged via 22. This secondary current is expressed as I ′ as shown in FIG. _S1 And
[0048]
Similarly, the primary current is cut off by magnetic saturation, the polarity of the transformer 17 is reversed, and the same operation is repeated. As described above, the main capacitor 26 is repeatedly charged by the first and second oscillation circuits.
[0049]
Here, comparing the difference between the charging of the main capacitor 26 and the conventional example, in the conventional example, as shown in FIGS. 6 to 8, the feedback windings are respectively provided for the first and second oscillation control circuits. When the NPN transistor 6 is turned on when the NPN transistor 6 is turned on, the current flows from the battery 1 to the emitter / base of the oscillating PNP transistor 3 along the current shown by the arrow in FIG. When the NPN transistor 13 is turned on, an operation is performed such that a part of the current flows through the collector / emitter of the NPN transistor 6 and partly flows to the resistor 18 via the feedback winding 17d. The current flows from the battery 1 through the emitter / base of the PNP transistor 10 through the collector / emitter of the NPN transistor 13, and a part of the feedback winding 17. It operates to flow to the resistor 18 via the. Thus, in the conventional example, the first oscillation control circuit and the second oscillation control circuit have independent feedback windings 17c and 17d, respectively.
[0050]
In the present invention, such a division of the feedback winding is stopped, and one end of the feedback winding 17c is connected to the second oscillation winding circuit so that the first oscillation control circuit and the second oscillation control circuit can be operated with one feedback winding. The emitter of the oscillation control NPN transistor 13 and the resistor 18 are connected, the other end is connected to the emitter of the first oscillation control NPN transistor 6 and the resistor 31, and the other ends of the resistor 18 and the resistor 31 are connected to the other end of the battery 1. Connected to.
[0051]
With this configuration, when the NPN transistor 6 is on, current flows to the resistor 18 via the feedback winding 17c, and when the NPN transistor 13 is on, it flows to the resistor 31 via the feedback winding 17c. Can be shared.
[0052]
In addition, like the timing chart of the charging current of the circuit of FIG. 3 shown in FIG. 4, in the case of the circuit shown in FIG. However, in this embodiment, the secondary current I of the first oscillation circuit is _S1 And the secondary current I ′ of the second oscillation circuit _S1 Therefore, the charging current is always supplied to the main capacitor 26. Compared with the circuit of FIG. 9 or the like, the charging time is shortened, and the number of terminals is reduced by controlling both oscillation circuits as one terminal of CGON. Has been.
[0053]
Returning to the flowchart of FIG. 2 again, when the charge completion level is reached, the CGON terminal of the control circuit 27 is changed from HL to LL, and the first NPN transistor 6 and the second NPN transistor 6 are connected via the resistor 28, the diode 9, and the diode 16. The base current of the NPN transistor 13 is turned off and turned off (S4).
[0054]
At this time, a high potential is generated at the emitter of the PN transistor 6 or the NPN transistor 13 by the feedback winding 17c. However, since the bypass is bypassed by the diode 8 or the diode 15, the NPN transistor 6 or 13 is not destroyed. When the NPN transistor 6 or 13 is turned off, the oscillation PNP transistor 3 or 10 is also turned off to stop the oscillation. It is determined whether the release switch 30 is on (S5). If it is on, the operation of a known shutter stop driving circuit (not shown) is started according to the shutter speed stop determined by the known photometry circuit (not shown) (S6). A trigger is output from the TRG signal terminal of the control circuit 27 at a light emission timing determined by a known photometry circuit and distance measurement circuit (not shown) (S7). In response to the trigger output, a trigger pulse is output from the light emitting circuit 24 to the flash discharge tube 25 to emit light (S8). When the appropriate amount of light is reached, the light emission is stopped (S9). The shutter aperture driving operation is stopped (S10). And the operation | movement about a flash is complete | finished.
[0055]
As described above, according to the present embodiment, the oscillation operation can be performed in a shared manner without dividing the feedback winding by the first and second oscillation control circuits, and the charging time can be shortened. Thus, the number of control terminals can be reduced by common control.
[0056]
Next, a second embodiment of the present invention will be described.
FIG. 5 is a circuit block diagram of an electronic flash device according to the second embodiment of the present invention.
The second embodiment shown in FIG. 5 is different from the previous embodiment in that the NPN transistor circuit for oscillation control in the previous embodiment is replaced with an FET (electrolytic effect transistor) circuit, and the first NPN transistor 6 Are replaced by FET 60 and the second NPN transistor 13 is replaced by FET 130.
[0057]
The FET 60 has a drain connected to the base of the first oscillation PNP transistor 3, and a protective resistor 70 and a capacitor 90 are connected in parallel between the gate and the source. The FET 130 has a drain connected to the base of the second oscillation PNP transistor 10, a protective resistor 140 and a capacitor 160 are connected in parallel between the gate and the source, and the gates of the FET 60 and the FET 130 are both CGON terminals of the control circuit 27. It is connected to the one terminal control.
[0058]
Other configurations of the first and second oscillating PNP transistor circuits, feedback circuits, rectifier circuits, light emitting circuits, and the like are the same as those in the previous embodiment.
[0059]
In operation, the FET 60 controls the first oscillation PNP transistor 3 instead of the NPN transistor 6 of the previous embodiment, and the FET 130 controls the second oscillation PNP transistor 10 instead of the NPN transistor 13. Except for, it is exactly the same.
[0060]
In this case, the gates of the FET 60 and the FET 130 are connected to the CGON terminal for one-terminal control, and the control is voltage control via the capacitors 90 and 160.
[0061]
As described above, in the second embodiment, similarly to the previous embodiment, the first oscillation control circuit and the second oscillation control circuit can perform the oscillation operation by sharing the feedback winding 17c. Since the main capacitor is always charged with the next current, the charging time is shortened, and the number of parts can be reduced by one-terminal control or the like.
[0062]
【The invention's effect】
As described above, according to the first aspect of the present invention, the power source, the transformer having two divided primary windings and the feedback winding, and the two switching operations for boosting the power source voltage are provided. In an electronic flash device including a push-pull type DC-DC converter circuit having an oscillation PNP transistor and a switch element for controlling the operation of each oscillation PNP transistor, the first oscillation PNP transistor and the first oscillation PNP transistor A first oscillation control circuit configured by a first switching element for controlling the base of the battery and a first diode connected to the cathode of the first switching element and connected in parallel to the battery; Oscillation control second switch element and second switch for controlling the bases of the oscillation PNP transistor and the second oscillation PNP transistor A second oscillation control circuit comprising a second diode connecting a cathode to the child and connected in parallel to the battery; one end connected to one end of the second switch element and the other end connected to the first switch Since the feedback winding by the first and second resistors connected in parallel to the feedback winding shared by connecting to one end of the element and the first and second diodes is provided, the first and second oscillations are provided. An electronic flash device having a push-pull type DC-DC converter that controls a PNP transistor for use with first and second switch elements, and can perform an oscillation operation without dividing a feedback winding. Since the number of terminals can be reduced and the size can be reduced, the circuit scale can be reduced and the component cost can be reduced.
[0063]
According to the second aspect of the present invention, the power supply, the transformer having two divided primary windings and the feedback winding, the two oscillating PNP transistors to be switched for boosting the power supply voltage, and each oscillating PNP Oscillation control for controlling bases of first oscillation PNP transistor and first oscillation PNP transistor in electronic flash device including push-pull type DC-DC converter circuit having NPN oscillation control transistor for controlling operation of transistor A first oscillation control circuit comprising a first NPN transistor for use and a first diode having a cathode connected to the emitter of the first NPN transistor and connected in parallel to the battery, and a second PNP transistor for oscillation And a second NPN transistor for oscillation control that controls the base of the second oscillation PNP transistor And a second oscillation control circuit comprising a second diode connected to the cathode of the emitter of the second NPN transistor and connected in parallel to the battery, and one end connected to the emitter of the second NPN transistor. Since the other end is connected to the emitter of the first NPN transistor to provide a common feedback winding and a feedback circuit using first and second resistors connected in parallel to the first and second diodes, respectively. In an electronic flash device having a push-pull type DC-DC converter that controls the first and second oscillation PNP transistors with the first and second NPN transistors, the oscillation operation is performed without dividing the feedback winding. Therefore, by reducing the number of terminals of the oscillation transformer and reducing the size, the circuit scale can be reduced and the component cost can be reduced.
[0064]
According to the third aspect of the present invention, the power source, the transformer having two divided primary windings and the feedback winding, the two oscillating PNP transistors for switching operation for boosting the power source voltage, and each oscillating PNP In an electronic flash device including a push-pull type DC-DC converter circuit having an FET for controlling the operation of a transistor, the first oscillation PNP transistor and the first oscillation PNP transistor for controlling the base of the first oscillation PNP transistor A first oscillation control circuit comprising a first FET and a first diode connected to a cathode to the source of the first FET and connected in parallel to the battery; a second oscillation PNP transistor; and a second oscillation A second FET for oscillation control that controls the base of the PNP transistor for use, and a second diode that connects the cathode to the source of the second FET A second oscillation control circuit connected in parallel to the battery, and a feedback winding shared by connecting one end to the source of the second FET and connecting the other end to the source of the first FET And a feedback circuit using first and second resistors connected in parallel to the first and second diodes, respectively, and an anode of the third and fourth diodes connected from sources of the first and second FETs. The respective cathodes are connected to one and other ends of the secondary winding of the transformer, and the anodes of the fifth and sixth diodes are connected from one and the other ends of the secondary winding of the transformer. A common rectifier circuit is connected to the respective gates of the first and second FETs, and is turned on by common one-terminal control to start oscillation and turn off to stop oscillation. Since the control terminal is provided, the feedback winding is divided by an electronic flash device having a push-pull type DC-DC converter that controls the first and second oscillation PNP transistors by the first and second FETs. Oscillation operation can be performed without any problem, and by reducing the number of terminals of the oscillation transformer and reducing the size, the circuit scale can be reduced and the component cost can be reduced.
[Brief description of the drawings]
FIG. 1 is a circuit block diagram of an electronic flash device according to a first embodiment of the present invention.
FIG. 2 is a flowchart of the operation of the electronic flash device shown in FIG.
3 is an explanatory diagram of the operation of the electronic flash device shown in FIG. 1. FIG.
4 is a timing chart of charging current of the electronic flash device shown in FIG. 3;
FIG. 5 is a circuit block diagram of an electronic flash device according to a second embodiment of the present invention.
FIG. 6 is a circuit block diagram of a conventional electronic flash device.
FIG. 7 is a circuit block diagram of an electronic flash device using a conventional FET.
FIG. 8 is an explanatory diagram of the operation of a conventional electronic flash device.
FIG. 9 is a circuit block diagram of a conventional DC-DC converter.
[Explanation of symbols]
1 battery
2, 4, 11, 90, 160 capacitors
3 First oscillation PNP transistor
5, 7, 12, 14, 18, 28, 31, 70, 140 Resistance
6 First NPN transistor
8, 9, 15, 16 Diode
10 Second PNP transistor for oscillation
13 Second NPN transistor
17 Trans
19, 20, 21, 22 High voltage rectifier diode
23 Detection circuit
24 Light emitting circuit
25 Flash discharge tube
26 Main capacitor
27 Control circuit
29 Constant voltage circuit
30 switch circuit
60 first FET
130 Second FET

Claims (3)

A power supply, a transformer having two divided primary windings and a feedback winding, two oscillation PNP transistors for switching operation for boosting the power supply voltage, and a switch element for controlling the operation of each oscillation PNP transistor In an electronic flash device comprising a push-pull type DC-DC converter circuit having
A first oscillation PNP transistor, a first switch element for oscillation control for controlling the base of the first oscillation PNP transistor, and a first diode having a cathode connected to the first switch element, are connected to the battery. A first oscillation control circuit connected in parallel, a second oscillation PNP transistor, a second switch element for oscillation control for controlling the base of the second oscillation PNP transistor, and a cathode connected to the second switch element A second oscillation control circuit comprising a second diode connected to each other and connected in parallel to the battery, and one end connected to one end of the second switch element and the other end connected to one end of the first switch element. connect characterized in that a first and second feedback circuits due to the resistance of which connected in parallel to said first and second diode and the feedback winding to share the electronic Light equipment. A power supply, a transformer having two divided primary windings and a feedback winding, two oscillation PNP transistors that are switched to increase the power supply voltage, and an NPN oscillation control transistor that controls the operation of each oscillation PNP transistor. In an electronic flash device comprising a push-pull type DC-DC converter circuit having
A battery comprising a first oscillation PNP transistor, a first NPN transistor for oscillation control for controlling the base of the first oscillation PNP transistor, and a first diode having a cathode connected to the emitter of the first NPN transistor A first oscillation control circuit connected in parallel to the first oscillation circuit, a second oscillation PNP transistor, and a second NPN transistor for oscillation control and a second NPN transistor for controlling the base of the second oscillation PNP transistor A second oscillation control circuit comprising a second diode having a cathode connected to the emitter and connected in parallel to the battery; one end connected to the emitter of the second NPN transistor and the other end to the first. Connected in parallel to the feedback winding and the first and second diodes connected to the emitter of the NPN transistor Electronic flash device according to the first and characterized in that a feedback circuit is provided by the second resistor that. Push-pull having a power supply, a transformer having two divided primary windings and a feedback winding, two oscillating PNP transistors for switching operation for boosting the power supply voltage, and an FET for controlling the operation of each oscillating PNP transistor In an electronic flash device having a type DC-DC converter circuit,
A first oscillation PNP transistor, a first FET for oscillation control for controlling the base of the first oscillation PNP transistor, and a first diode having a cathode connected to the source of the first FET, A first oscillation control circuit connected in parallel to each other, a second oscillation PNP transistor, an oscillation control second FET for controlling the base of the second oscillation PNP transistor, and a source of the second FET as a cathode A second oscillation control circuit comprising a second diode connected in parallel and connected in parallel to the battery; one end connected to the source of the second FET and the other end connected to the source of the first FET And a feedback circuit using first and second resistors connected in parallel to the first and second diodes, respectively, and a source of the first and second FETs. And the anodes of the fourth diodes are connected, and the respective cathodes are connected to one and the other ends of the secondary windings of the transformer, and the fifth and sixth diodes are connected from one and the other ends of the secondary windings of the transformer. The oscillation is started and turned off by connecting to the common rectifier circuit connected to the anode of each of the anodes and turning on by common one-terminal control by connecting to the respective gates of the first and second FETs. An electronic flash device characterized by comprising one oscillation control terminal for stopping oscillation.

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