JP2002099028A - Stroboscopic device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To compose a stroboscopic device having dimming function at a low cost. SOLUTION: When a charging switch 32 is turned on, a booster circuit 24 is activated and an oscillation transistor 33 oscillates. The primary and secondary electric currents increase of an oscillation transformer 34, a high-tension induction electromotive force is generated in the secondary coil 34b and a main capacitor 26 is charged. While the secondary current increases, an induction electromotive force which is about several volts is generated in a tertiary coil 34c. A drive capacitor 52 is charged by the induction electromotive force. When stroboscopic light-emitting starts, electric charge stored in the drive capacitor 52 flows into a dimming circuit 30 and the dimming circuit 30 is activated.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] 1. Field of the Invention [0002] The present invention relates to a flash device having a dimming function.

[0002]

2. Description of the Related Art As a simple camera, a film unit with a lens in which an unexposed photographic film is incorporated in a unit body in which a photographing mechanism such as a photographing lens and a shutter mechanism is incorporated has been manufactured and sold by the present applicant. I have. Also, a film unit with a lens having a built-in strobe device has been widely known in order to enable photographing at night or indoors.

A flash unit built into a currently available film unit with a lens irradiates a fixed amount of strobe light at one flash regardless of a shooting distance to a main subject and the like. The main subject was overexposed. For this reason, there has been an inconvenience that the main subject will fly white in the printed photograph, or the background will be dark even if the main subject is reproduced at an appropriate density.

On the other hand, a compact camera or the like is provided with a strobe device having an automatic light control function called an auto strobe. In this auto strobe device, at the same time that the strobe discharge tube emits light, reflected light from a subject is received by a light receiving element, and a photoelectric current generated by the reflected light is integrated. Then, when the integration amount reaches a predetermined level, a non-contact switch such as a thyristor is operated to stop the discharge of the main capacitor in the strobe discharge tube, thereby stopping the light emission of the strobe discharge tube. Therefore, the strobe light amount can be appropriately adjusted according to the distance to the main subject.

[0005]

The above-mentioned auto strobe device requires a power supply voltage for driving a light receiving element, a thyristor, and the like. Therefore, a separate power supply circuit is provided in a compact camera or the like. However, since such a power supply circuit is complicated and expensive, there is a problem that when a light control function is provided in a film unit with a lens, the feature of the film unit with a lens, which is small and inexpensive, is impaired. .

The present invention has been made in consideration of the above problems, and has as its object to provide a strobe device capable of performing a dimming operation with a simple configuration.

[0007]

According to a first aspect of the present invention, there is provided a strobe device having a primary coil, a secondary coil, and a tertiary coil which are inductively coupled to each other, and a primary side flowing through the primary coil. An oscillating transformer for charging the main capacitor with an induced current flowing through the secondary coil due to an increase or decrease of the current; a strobe discharge tube for discharging a charge charged in the main capacitor by applying a trigger voltage to generate a strobe light; A dimming circuit for receiving the reflected strobe light and stopping the discharge in the strobe discharge tube when the amount of received light reaches a predetermined level; and a tertiary coil based on a change in a secondary current flowing through the secondary coil. A driving capacitor that is charged by an induced electromotive force generated at the time, and outputs an operating voltage necessary for operation of the dimming circuit at the time of strobe light emission. It is provided. This makes it possible to realize a circuit for generating an operation voltage required for the operation of the dimming circuit with a simple configuration.

[0008] The strobe device may be incorporated in a film unit with a lens, and the primary coil may be connected to a dry battery built in the film unit with a lens.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 shows the appearance of a film unit with a lens incorporating a flash device according to the present invention. The film unit with a lens includes a substantially rectangular parallelepiped unit main body 11 and a label 12 that partially covers the unit main body 11. Various photographing mechanisms such as a shutter device and a film feeding mechanism are incorporated in the unit body 11, and a film cartridge containing an unexposed photographic film is loaded in advance.

At the front of the unit body 11, a photographic objective lens 1 and a finder objective window 1 exposing a finder 14 are provided.
5, a strobe light emitting unit 16, a charge button 17 for strobe charging, and a light receiving window 20 for light control.
On the upper surface of the unit main body 11, a shutter button 21 and a film counter 22 indicating the remaining amount of the film are provided. A photo film is placed on the back of the unit body 11.
A part of the winding knob 23 for feeding frames is exposed. A finder eyepiece window and a charging completion confirmation window are provided on the back surface of the unit body 11.

The charge button 17 is linked to a charge switch 32 shown in FIG. 2. When the charge button 17 is pressed, the charge switch 32 is turned on to start charging. When the shutter button 21 is pressed after charging is completed, a shutter mechanism (not shown) is operated to perform one shot. In synchronization with this photographing operation, strobe light is emitted from the strobe light emitting section 16 toward the subject. A phototransistor 57 shown in FIG. 3 is disposed behind the light receiving window 20, and the phototransistor 57 receives reflected light from a main subject and adjusts the amount of strobe light emission during strobe light emission.

FIG. 2 shows a circuit configuration of the strobe device. The strobe device includes a booster circuit 24, a trigger circuit 25, a main capacitor 26, a strobe discharge tube 27, a dimming circuit 30,
It is composed of a battery 31 and the like. The battery 31 is, for example, an AA dry battery with an electromotive force of 1.5 V, and is held inside the unit main body 11 by a battery holder (not shown).

The booster circuit 24 includes a charge switch 32, an NP
N-type oscillation transistor 33, oscillation transformer 34, PN
P-type latch transistor 35, rectifier diode 3
6 and so on. The oscillation transistor 33 and the oscillation transformer 34 constitute a known blocking oscillation circuit, and the main capacitor 26 is charged by a high voltage generated on the secondary side of the oscillation transformer 34 when the blocking oscillation circuit is operating. Is done.

The oscillation transformer 34 includes a primary coil 34a, a secondary coil 34b, and a tertiary coil 34c, each of which is inductively coupled. One end of the secondary coil 34b and one end of the tertiary coil 34c are connected and shared. Terminal. The oscillating transistor 33 has a collector terminal connected to one end of the primary coil 34a and a base terminal connected to the collector terminal of the latching transistor 35. The latch transistor 35 has an emitter terminal connected to the positive electrode of the battery 31 via the charging switch 32 and a base terminal connected to a common terminal of the oscillation transformer 34.

When the charging switch 32 is turned on, the voltage of the battery 31 is applied between the base and the emitter to conduct the latch transistor 35. Then, a base current flows through the latch transistor 35 through a path between the plus electrode of the battery 31, the charging switch 32, the emitter and base of the latch transistor 35, and the minus electrode of the battery 31. The collector current flows into the base terminal of the oscillation transistor 33.

When the latch transistor 35 is turned on, the oscillating transistor 33 is turned on by the collector current flowing into the base terminal. Then, a collector current corresponding to the amount of the base current flows into the primary coil 34a as a primary current, and a high voltage, for example, an electromotive force of about 300 V is generated in the secondary coil 34b according to a winding ratio with the primary coil. I do. With this electromotive force, the rectifying diode 3
The secondary side current flows through 6, and the main side capacitor 26 is charged by the secondary side current.

The secondary current flowing through the secondary coil 34b is:
The current flows as the base current of the latch transistor 35, and the corresponding collector current flows into the base terminal of the oscillation transistor 33. With this positive feedback loop, the oscillation transistor 33 oscillates, and the primary current and the secondary current increase.

The tertiary coil 34c is inductively coupled to the secondary coil 34b. When the amount of the secondary current flowing through the secondary coil 34b increases or decreases, the winding between the tertiary coil 34c and the secondary coil 34b. An electromotive force is generated according to the line ratio. The tertiary coil 34c includes a feedback diode 38.
Is connected to the emitter terminal of the latching transistor 35 via the. When the electromotive force generated in the tertiary coil 34c becomes larger than the forward voltage of the feedback diode 38, the feedback diode 38 conducts, and a feedback current flows from the tertiary coil 34c to the emitter terminal of the latching transistor 35.

When the amount of the primary side current is saturated and does not increase, the current flowing through the secondary coil 34b and the tertiary coil 34c also does not increase, and all the coils 34a to 34a
In c, a back electromotive force is generated in a direction opposite to the electromotive force generated first. When a back electromotive force is generated in the secondary coil 34b,
The latch transistor 35 is turned off when a positive voltage is applied to the base terminal thereof from the secondary coil 34b, and accordingly, the oscillation transistor 33 is also turned off. After the back electromotive force disappears, the base current flows through the latch transistor 35 again, and the oscillation transistor 33 oscillates.

The main capacitor 26 has a positive terminal connected to one end of a secondary coil 34 via a rectifying diode 36, and a negative terminal connected to a negative electrode of the battery 31. The main capacitor 26 is positively charged by the secondary current generated during the increase of the primary current so that the potential of the positive terminal becomes higher while the potential of the negative terminal is kept constant.

The neon tube 37 lights up when the main capacitor 26 is charged to a specified charging voltage. The neon tube 37 is provided at a position facing a confirmation window provided on the back side of the unit main body 11, and the photographer can know that the charging is completed by turning on the neon tube 37 observed through the confirmation window. .

The trigger circuit 25 includes a trigger capacitor 4
0, a synchro switch 41, and a trigger coil 42. The trigger capacitor 40 is charged by the secondary current output from the booster circuit 24. When the shutter button 21 is pressed, a shutter blade (not shown) is turned to turn on the synchro switch 41, and the electric charge stored in the trigger capacitor 40 flows to the primary side of the trigger coil 42. Then, a trigger voltage of, for example, about 4 kV is generated on the secondary side of the trigger coil 42, and this trigger voltage is applied to the strobe discharge tube 27 via the trigger electrode 43. As a result, the insulation between the electrodes of the strobe discharge tube 27 is broken, and the electric charge of the main capacitor 26 is transferred to the strobe discharge tube 2.
Discharge occurs in 7 and strobe light is generated. A choke coil 44 is provided between the main capacitor 26 and the strobe discharge tube 27 to delay the increase of the discharge current. When the synchro switch 41 is closed, an excessive discharge current is generated. To prevent it from flowing into.

As shown in FIG. 3, the light control circuit 30 includes a light receiving circuit 45, a bypass circuit 46, a PNP switch transistor 47, a switching unit 50, and a discharge thyristor 51 which is a three-terminal thyristor (SCR). And so on. Further, a driving capacitor 52 is connected in parallel to the dimming circuit 30, and the dimming circuit 30 operates with an operating voltage output from the driving capacitor 52.

The driving capacitor 52 is connected to a tertiary coil 34c shown in FIG. The rectifying diode 53 has an anode connected to the tertiary coil 34c and a cathode connected to the positive terminal of the driving capacitor 53. While the secondary current is increasing, a forward voltage of about several volts is generated in the tertiary coil 34c. Then, the tertiary coil 34c, the rectifying diode 53, the driving capacitor 52, the tertiary coil 34
A current flows through the capacitor c, and the driving capacitor 52 is charged with a voltage corresponding to the magnitude of the electromotive force of the tertiary coil 34c. When the electromotive force generated in the tertiary coil 34c is small, or when the back electromotive force is generated in the tertiary coil 34, the rectifying diode 53 does not conduct, so that the charging current flows through the driving capacitor 52. Absent.

The bypass circuit 46 includes a switching capacitor 54 connected between the base and the emitter of the switching transistor 47, and a resistor 55 and a capacitor 56 connected between the switching capacitor 54 and the synchro switch 42. Be composed. When the synchronizing switch 41 is closed while the driving capacitor 52 is charged, the electric charge stored in the driving capacitor 52 is transferred to the bypass circuit 46.
And the switching capacitor 54 is charged. The charging voltage of the switching capacitor 54 is applied between the base and the emitter of the switching transistor 47. When the charging voltage of the switching capacitor 54 exceeds a predetermined value after a lapse of a predetermined time, the switching transistor 47 is turned on, and an operation voltage corresponding to the charging voltage of the driving capacitor 52 is applied to the light receiving circuit 45. The light receiving circuit 4 is operated by this operating voltage.
5 is activated.

The light receiving circuit 44 includes a phototransistor 57
, Capacitors 60 and 61, and resistors 62 and 63. The phototransistor 57 has a collector terminal connected to the switching transistor 47 via the capacitor 60 and the resistors 62 and 64, and an emitter terminal connected to one end of the driving capacitor 52. The capacitor 61 includes a phototransistor 57 and a capacitor 6.
It is connected in parallel with a series circuit composed of 0 and a resistor 62, and is provided to suppress noise caused by a trigger current flowing in the circuit when the synchro switch 41 is turned on.

The phototransistor 57 is arranged at a position facing the light receiving window 20. Switch transistor 47
Is conducted, and while the operating voltage is being applied from the driving capacitor 52, the reflected light from the subject is received, and a photoelectric current corresponding to the intensity of the received light is generated. The capacitor 60 is charged by the photoelectric current, and a charging voltage corresponding to the amount of received light is generated at both ends of the capacitor 60. Note that a photodiode or the like may be used instead of the phototransistor 57.

The switching unit 50 includes transistors 50a and 50b and a capacitor 50c. A base terminal of the transistor 50a and a collector terminal of the transistor 50b are connected to a connection point between a resistor 62 and a resistor 64, respectively. Further, the collector terminal of the transistor 50a is connected to the base terminal of the transistor 50b. Further, the emitter terminal of the transistor 50a is connected to one end of the driving capacitor 52 via the resistor 65,
The emitter terminal of the transistor 50b is connected to the other end of the driving capacitor 52.

In the switching unit 50, when the charging voltage of the capacitor 60 reaches a predetermined value, the transistors 50a and 50b are turned on, and the discharge current from the driving capacitor 52 flows to the resistor 65. The capacitor 50c is provided to prevent the switching unit 50 from being turned on by electric noise.

The discharge thyristor 51 has a gate terminal and a cathode terminal connected to both ends of the resistor 65.
The anode terminal of the discharge thyristor 51 is connected to the plus terminal of the main capacitor 26 via the choke coil 44, and the cathode terminal is connected to the main capacitor 26.
Is connected to the negative terminal of

When a current flows through the resistor 65, a constant gate voltage is applied between the gate and the cathode of the discharge thyristor 51, so that the discharge thyristor 51 is turned on. The discharge thyristor 51 is connected to the main capacitor 26 in parallel with the strobe discharge tube 27, and the electric charge stored in the main capacitor 26 is discharged through the discharge thyristor 51 having a lower impedance. Then, light emission from the strobe discharge tube 27 stops.

The main capacitor 26 has a voltage of 300 V
Since such a high voltage is applied, at the moment when the discharge thyristor 51 is turned on, a large discharge current flows between the anode and the cathode, and the discharge thyristor 51 may be broken. In order to prevent such a situation, a choke coil 57 is connected between the main capacitor 26 and the discharge thyristor 47 to reduce the amount of discharge current flowing at the moment when the discharge thyristor 51 is turned on.

Next, the operation of the above configuration will be described.
When performing night photography or indoor photography, the photographer presses the charge button 17. As a result, the charge switch 32 is turned on, the booster circuit 24 starts operating, and the main capacitor 26 and the trigger capacitor 40 are charged by the output current. Further, as the secondary current increases, an induced electromotive force of about several volts is generated in the tertiary coil 34c. Due to this electromotive force, a charging current flows into the driving capacitor 52 via the rectifying diode 53, and the driving capacitor 52 is charged.

When the main capacitor 26 reaches the specified charging voltage, the neon tube 37 lights up. The photographer confirms the lighting of the neon tube 37 from the confirmation window provided on the back side of the unit main body 11, determines the photographing range and composition through the viewfinder 14, and presses the shutter button 21 to perform photographing.

When the shutter button 21 is pressed, the synchro switch 41 is turned on together with the opening / closing operation of the shutter blades. Then, the trigger voltage generated by the trigger coil 42 is applied to the strobe discharge tube 27, and the electric charge stored in the main capacitor 26 is discharged through the strobe discharge tube 27 to generate strobe light. Irradiated.

When the sync switch 41 is closed, the electric charge stored in the driving capacitor 52 flows into the sync switch 41 through the bypass circuit 46. When the charging voltage of the switching capacitor 54 exceeds a predetermined value, the switching transistor 47 is turned on, the charging voltage of the driving capacitor 52 is applied to the light receiving circuit 45, and the light receiving circuit 45 operates.

When the object is irradiated with strobe light, a part of the reflected light enters the phototransistor 57 through the light receiving window 20. In the phototransistor 57, while the switching transistor 47 is conducting, a photoelectric current having a magnitude corresponding to the intensity of light reflected from the subject flows, and charges the capacitor 60.

When the charging voltage of the capacitor 60 exceeds a predetermined value, the switching unit 50 is turned on and the electric charge stored in the driving capacitor 52 is transferred to the switching unit 5.
The current flows through the resistor 65 through 0 to discharge. And resistance 6
5 is applied between the gate and cathode of the discharge thyristor 51, and the discharge thyristor 51 is turned on. Thereby, the electric charge stored in the main capacitor 26 is discharged through the discharge thyristor 51, and the light emission in the strobe discharge tube 27 stops. When the charging voltage of the main capacitor 26 becomes equal to or lower than a predetermined value, the discharging thyristor 51 is turned off.

Therefore, even when the distance to the main subject is short or when the reflectance of the main subject is high, the strobe is prevented from fully emitting light, and the main subject illuminated by the strobe light is provided with an appropriate density on a printed photograph. , And at the same time, it is possible to reproduce a background having no strobe light illumination effect and using room light as a light source with appropriate brightness. Of course, even when the distance to the main subject is long, an appropriate amount of strobe light can be emitted.

FIG. 4 is a circuit diagram of a booster circuit according to another embodiment of the present invention. NPN type oscillation transistor 70
Is connected to one end of a tertiary coil 34c via resistors 72 and 73, and the collector terminal is connected to one end of a primary coil 34a. The oscillation transistor 7
The negative electrode of the battery 31 is connected to the 0 emitter terminal.

When the charge switch 32 is turned on, the battery 3
1 flows into the base terminal of the oscillation transistor 72 via the tertiary coil 34c, and the oscillation transistor 7
2 is turned on. Then, the collector current of the oscillation transistor 72 flows through the primary coil 34a, an induced electromotive force is generated in the secondary coil 34b in the secondary coil 34b, and the main capacitor 26 is charged by the secondary voltage. Also, a part of the secondary current flowing through the secondary coil 34b flows into the base terminal of the oscillation transistor 70 via the tertiary coil 34c. This positive feedback action causes the oscillation transistor 70 to oscillate, and the primary current and the secondary current increase.

Further, while the secondary current increases, an induced electromotive force of about several volts is generated in the tertiary coil 34c, and the induced electromotive force causes a charging current to flow through the driving capacitor 52, so that the driving capacitor 52 Charged. The same members as those in the first embodiment are denoted by the same reference numerals, and detailed description is omitted.

The driving capacitor 52 is charged by using the induced electromotive force generated in the tertiary coil 34c when the main capacitor 26 is charged, and the charged voltage is used to generate a voltage for driving the dimming circuit at the time of strobe light emission. Therefore, the power supply for the dimming circuit can be realized with a simple configuration.

In the above embodiment, the main capacitor 26
The booster circuit 34 is configured to positively charge the main capacitor 2 by keeping the potential on the oscillation transistor 33 side constant and lowering the potential on the rectifying diode 36 side.
The booster circuit 24 may be configured so that 6 is negatively charged. Further, in the above embodiment, the completion of charging is detected by using the neon tube 37, but the tertiary coil 34c
LEDs are provided at both ends of the tertiary coil 34c when the charging current decreases and the electromotive force generated at both ends of the tertiary coil 34c decreases.
A current may be supplied to the ED to light it. Thus, the neon tube 37 can be omitted to reduce the cost.

The configuration of the booster circuit 24 and the trigger circuit 25 described above is merely an example, and the charge of the main capacitor 26 is reduced by the application of the trigger voltage.
7, any configuration may be used. Further, although the switching unit 50 is configured using the two transistors 50a and 50b, a three-terminal thyristor or another non-contact switch may be used. Further, the dimming circuit 30 includes a three-terminal thyristor 5.
1 is used, but other non-contact switches may be used as long as they have equivalent functions.

In the above embodiment, the function of the light receiving circuit 45 is reduced for a predetermined period immediately after the start of flash emission, but the operation of the light receiving circuit 45 may be stopped for a predetermined period. Furthermore, in the above embodiment, an example in which the strobe device of the present invention is applied to a film unit with a lens has been described. However, the strobe device of the present invention is used by being attached to a strobe device built in a camera or a camera. It can also be used for strobe devices.

[0047]

As described above, according to the strobe device of the present invention, the drive capacitor charged by the induced electromotive force generated in the tertiary coil of the oscillating transformer is provided, and when the strobe emits light, the drive capacitor is charged. Since the dimming circuit is driven using the voltage, a power supply circuit for driving the dimming circuit can be realized with a simple configuration. Thus, a strobe device having a dimming function can be provided at low cost.

[Brief description of the drawings]

FIG. 1 is a perspective view of a lens-fitted film unit embodying the present invention.

FIG. 2 is a circuit diagram showing a booster circuit and a trigger circuit.

FIG. 3 is a circuit diagram showing a dimming circuit.

FIG. 4 is a circuit diagram showing a booster circuit and a trigger circuit according to another embodiment of the present invention.

[Explanation of symbols]

 11 Unit Main Body 26 Main Capacitor 27 Strobe Discharge Tube 30 Dimming Circuit 34c Tertiary Coil 41 Synchro Switch 45 Light Receiving Circuit 51 Discharge Thyristor 52 Driving Capacitor

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) G03C 3/00 575 G03C 3/00 575A H02M 3/28 H02M 3/28 G 3/338 3/338 A

Claims (2)

[Claims] An oscillation transformer having a primary coil, a secondary coil, and a tertiary coil inductively coupled to each other, and charging a main capacitor with an induction current flowing through a secondary coil by increasing or decreasing a primary current flowing through the primary coil; A strobe discharge tube for generating strobe light by discharging a charge charged in the main capacitor by applying a trigger voltage; and receiving strobe light reflected from a subject, and when the amount of received light reaches a predetermined level, A dimming circuit for stopping discharge in the strobe discharge tube, and charged by induced electromotive force generated in the tertiary coil due to a change in the secondary current flowing in the secondary coil, which is necessary for the operation of the dimming circuit at the time of strobe emission And a driving capacitor for outputting a stable operating voltage. 2. A strobe device incorporated in a film unit with a lens, wherein the primary coil is connected to a dry cell built in the film unit with the lens. apparatus.