JPS638448B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a dimmable electronic flash device that controls the amount of light emitted from a flash discharge tube (flash emission time) according to the amount of light reflected from a subject.

(Prior Art) Electronic flash devices are attracting attention as a light source for photography in place of reflector lamps and flash bulbs. This electronic flash device basically uses a flash discharge tube such as a xenon lamp to discharge the charge stored in the main discharge capacitor in synchronization with the release of the camera, and uses the flash from this discharge as a light source to illuminate the subject. It is something to do.

However, the light emission time from this electronic flash device is very short, and the amount of light that reaches the subject varies depending on the distance between the flash device and the subject. Therefore, when taking a photograph, it is extremely important to understand the amount of illumination light of the subject and adjust, for example, the amount of light emitted, or the aperture value on the camera side in accordance with the amount of light emitted. However, such adjustment work is generally very difficult.

Therefore, recently, the amount of light emitted from the flash discharge tube reflected by the subject is detected, and when the amount of reflected light reaches a predetermined value, a light emission stop section is activated to control the light emission of the flash discharge tube to be stopped. Therefore, it has been considered to stabilize the amount of light that illuminates the subject. A flash device incorporating this type of function is called a dimmable electronic flash device, and various control methods for stopping the flash have been proposed. However, it is generally extremely difficult to confirm whether or not this type of light control function is working properly, and over-reliance on the light control function often results in insufficient illumination of the object. Therefore, when using a dimmable electronic flash device, sufficient care must be taken, such as checking the amount of light emitted from the flash discharge tube and the shooting distance (subject distance) each time. The need arose.

(Problems to be Solved by the Invention) As described above, in the case of conventional dimmable electronic flash devices, it is difficult to determine whether the dimming function worked normally, that is, whether the amount of illumination of the subject was properly controlled. It is difficult to confirm whether or not the product is being used, and problems remain in terms of usability (handling).

The present invention has been made in consideration of the above circumstances, and its purpose is to detect the amount of light reflected by the subject of the light emitted from the flash discharge tube, and to detect when the amount of reflected light reaches a predetermined value. In an electronic flash device equipped with a dimming function that stops and controls the emission of light from the flash discharge tube by starting a light emission stop section at the same time, a method for easily checking whether or not the dimming function is functioning normally is provided. The purpose of the present invention is to provide a dimmable electronic flash device with good performance.

(Means for Solving the Problems) A dimming type electronic flash device according to the present invention is connected to a power source that charges a main discharge capacitor via a resistor, and is connected in parallel to the main discharge capacitor via a diode. The charging voltage of the main discharge capacitor is detected by the charging voltage detection capacitor, and the first switching element is driven to conduct when the charging voltage of the main discharge capacitor is detected by the charging voltage detection capacitor. and a thyristor circuit that turns on in response to a starting pulse of the flash discharge tube, forms a discharge path for the time-limiting capacitor, and generates a predetermined voltage for a period _T1 determined by the time constant of the discharge path. A second switching element is provided that is driven to conduct for a period _T1 , and a notification means that operates when a predetermined drive voltage is applied is connected to the drive power source through the first and second switching elements in series. and a capacitor that defines a voltage to be applied to the notification means when the first and second switching elements are conductive, and sets the applied voltage to a predetermined driving voltage after a period T ₂ (<T ₁ ). means, the period T ₂ is set to be longer than the longest flash discharge period of the flash discharge tube, and the period T ₁ is set to be longer than the longest flash discharge period of the flash discharge tube;
The period of (T ₁ −T ₂ ) is set shorter than the minimum charging period of the main discharge capacitor, so that the dimming operation can be confirmed by the notification means.

(Function) According to the present invention, when the flash discharge tube is activated to emit flash light, the second switching element is turned on for a predetermined time _T1 . Further, the first switching element is turned on when the charging voltage of the main discharge capacitor is equal to or higher than a certain value. Therefore, the notification means is used within a certain period of time T ₁ from the time of activation of the flash discharge tube,
In addition, power is supplied from the drive power source only when the charging voltage of the main discharge capacitor is equal to or higher than a certain value. However, when power is supplied to the notification means, the operation of the notification means is prohibited by the second time limit means for a predetermined time _T2 , which is the longest light emitting operation time of the flash discharge tube.

As a result, when the dimming operation is functioning normally and charge remains in the main discharge capacitor, and after the longest light emitting operation time of the flash discharge tube indicated by the predetermined time _T2 has elapsed, It will operate only until time T ₁ has elapsed.

In other words, when the flash discharge tube is started, its dimming operation does not function properly and all of the charge accumulated in the main discharge capacitor is discharged through the flash discharge tube, or when the flash discharge tube is started. When I was dead,
Alternatively, the above-mentioned notification means will no longer operate after a certain period of time _T1 from the start of the flash discharge tube.
As a result, the notification means operates only when its dimming function is performed normally.

(Effects) As described above, according to the present invention, by controlling the conduction of the first and second switching elements and controlling the activation timing of the notification means by the timer, the notification is made only when the dimming function is normally performed. Since the operation of the means is permitted, it is easily and reliably confirmed by this notifying means whether or not the dimming operation for the flash light emission was performed normally, that is, whether the amount of illumination of the subject was properly controlled. becomes possible.

(Example) Hereinafter, an example of the present invention will be described with reference to the drawings.

The figure is a diagram showing a schematic electric circuit configuration of a dimming type electronic flash device according to an embodiment, and 1 is a main discharge capacitor. The main discharge capacitor 1 is charged by receiving power from a DC power source (not shown), and stores charges for driving a flash discharge tube 5 such as a xenon lamp to emit flash light. The trigger transformer 2 is energized via a capacitor 3 when a switch 4 such as a synchronization contact of a camera is closed, and generates a high voltage pulse on its secondary side to start discharging the flash discharge tube 5. A flash is emitted by the flash discharge tube 5 discharging the charge accumulated in the main discharge capacitor 1, and the object is irradiated with the light. These constitute the light emitting section of the flash device.

Incidentally, the negative electrode side of the flash discharge tube 5 is connected to the negative power terminal side through a thyristor 6 in the forward direction. This thyristor 6 forms a part of the discharge path of the flash discharge tube 5, and utilizes the fact that a high voltage is applied between the anode and cathode of the flash discharge tube 5 at the initial stage of startup. 2 through the capacitor 25 and becomes conductive upon receiving a starting pulse applied to the gate.

However, on the gate side of the thyristor 6, a thyristor 10 whose conduction is controlled in response to the output of the light receiving section 11 is provided. The light receiving section 11 receives the light emitted from the flash discharge tube 5 and reflected by the subject, and turns on the thyristor 10 when the amount of the received light reaches a predetermined value. Due to the conduction of the thyristor 10, the electric charge of the commutation capacitor 7, which has been charged in advance through a path including the resistors 8 and 9, is discharged, and the discharged electric charge from the commutation capacitor 7 flows into the thyristor 6 in the opposite direction. Then, the thyristor 6 is turned off, and the discharge path of the flash discharge tube 5 is cut off. Such a thyristor circuit constitutes a light emission stopping section for the light emission operation of the flash discharge tube 5.

The above constitutes the main body of the dimming type electronic flash device, and when the switch 4 is closed, the flash discharge tube 5 is turned off.
is driven to emit flash light, and when the amount of light emitted from the flash discharge tube 5 reflected by the subject reaches a predetermined value, the flash discharge tube 5 is activated by the operation of the light emission stop section.
Flash discharge (light emission) is controlled to stop.

The feature of this device is that, in addition to the main body of the dimming type flash device described above, it also has a function to notify when the dimming function by the light emitting stop section operates normally. At the point.

That is, a capacitor 12 to be charged is connected via a resistor 13 between power supply terminals for charging the main discharge capacitor 1. The charge in the capacitor 12 is discharged through the diode 14 during flash discharge of the flash discharge tube 5. A voltage corresponding to the charging voltage of the main discharge capacitor 1 is stored in this capacitor 12 . The voltage between the terminals of this capacitor 12 is divided by resistors 15a and 15b, and the divided voltage is applied via a Zener diode 16 to the base of a transistor 17, which is a first switching element. The transistor 17 is driven to conduct only when the capacitor 12 is generating a terminal voltage of a predetermined value or more, that is, when the charging voltage of the main discharge capacitor 1 is a predetermined value or more.

On the other hand, transistor 2, which is a second switching element, is connected in series to transistor 17.
0 is one whose conduction is controlled by the thyristor 21. This thyristor 21 receives at its gate, via a capacitor 22, a starting pulse generated in the trigger transformer 2 when the switch 4 is closed, and is driven into conduction. Note that the activation pulse applied to the gate of the thyristor 6 may be applied to the gate of the thyristor 21 via the capacitor 29, thereby activating the thyristor 21. Therefore, the thyristor 21 is connected to the capacitor 24 due to its conduction.
The charged charge is discharged through the resistors 23a and 23b, and when the discharge is completed, it is turned off.
As a result, the thyristor 21 is connected to the capacitor 24.
A voltage is generated across the resistor 23b only for a predetermined time _T1 defined by the discharge time constant of the resistors 23a and 23b, and this voltage drives the transistor 20 into conduction. In this way, the circuit section mainly including the thyristor 21 has a first
functions as a time-limited means.

The indicator lamp 19, which is the notification means, is connected to the capacitor 27, which is the driving power source, through the transistors 17 and 20, which are driven to conduct, and the load resistor 18 connected in series, as described above. This indicator light 1
Reference numeral 9 emits light when a predetermined voltage is applied between both ends thereof, and is made of, for example, a neon lamp.

The capacitor 27, which serves as a driving power source for the notification means, is connected to the DC power terminal via a diode 28 and charged, and operates independently of the main discharge capacitor 1 and the like described above.
The first timer described above is also configured to operate in response to power supply from the capacitor 27.

However, the indicator light 19, which is the notification means,
A capacitor 26 as a second timer is connected in parallel. This capacitor 26 is initially charged by the charge supplied from the capacitor 27 when the transistors 17 and 20 are turned on, and generates a voltage between the terminals with a time constant determined by the load resistor 18. . Only when the charging of the capacitor 26 is completed does the voltage from the capacitor 27 change to the indicator light 19.
The discharge charge from the capacitor 27 flows through the indicator light 19. Due to the charging characteristics of the capacitor 26, the indicator light 19
operation is inhibited for a predetermined time T ₂ from the start of conduction of the transistors 17, 20, and the capacitor 26 acts as a second timer for defining the point at which the indicator lamp 19 starts operating.

Here, the control period T ₂ for inhibiting the operation of the indicator lamp 19 by the second timer means is
6 and the load resistor 18, and this period _T2 is the longest period from when the flash discharge tube 5 (thyristor 6) is activated until the thyristor 10 is activated (usually 2 to 3 msec). degree)
is set longer than In other words, the flash discharge of the flash discharge tube 5 continues, and there is a sufficient charge remaining in the main discharge capacitor 1 that drives the flash discharge tube 5, and this charge (the charging voltage of the capacitor 1) This is set to be longer than the period during which the thyristor 10 can conduct, that is, the maximum light emission operation time of the flash discharge tube 5.

On the other hand, the conduction period _T1 of the transistor 20 by the first timer (thyristor 21) is set longer than the time _T2 , and for example, the time difference ( _T1 - _T2 ) is
is set to be shorter than the minimum period from once discharged until discharged again. i.e. time
T ₁ is set as the above-mentioned time T ₂ plus a time shorter than the shortest charging time of the capacitor 12. Such time T ₁ can be realized, for example, by making the charging time constant determined by the resistor 13 and the capacitor 12 larger than the discharging time constant determined by the resistors 23a and 23b and the capacitor 24. Ru.

According to the dimming type electronic flash device configured in this way, during standby, the above-mentioned flash discharge tube 5, thyristors 6, 10, 21, and transistor 2
0 are in the off state, the main discharge capacitor 1 is fully charged, and even if the transistor 17 is conductive, the capacitor 27 is in the off state.
cannot discharge, and therefore the discharge lamp 19 is in an extinguished state.

When the switch 4 is closed, the flash discharge tube 5 and the thyristors 6 and 21 are activated simultaneously, and the flash discharge tube 5 receives the charge from the main discharge capacitor 1 and discharges a flash. Accordingly, the transistor 20 becomes conductive.

Then, as the transistors 17 and 20 become conductive,
The charge of capacitor 27 flows into capacitor 26 via resistor 18 over the aforementioned period T ₂ . Thereafter, if the transistors 17 and 20 continue to be on after this period _T2 has elapsed, that is, the above-mentioned dimming function operates normally and the flash discharge tube 5 stops emitting light, causing the main discharge capacitor to An accumulated charge of 1 remains, and as a result
When the charging voltage of the capacitor 2 is equal to or higher than a predetermined value, the transistor 15 maintains a conductive state, so that the indicator lamp 19 is driven to be lit by the charge from the capacitor 27.

In addition, the dimming function does not work properly and the flash discharge tube 5
When all of the charge in the main discharge capacitor 1 is discharged through the main discharge capacitor 1, the capacitor 1
2 is also discharged from the diode via the flash discharge tube 5. As a result, since the transistor 17 is turned off, discharging from the capacitor 27 is prohibited, and the indicator lamp 19 is no longer driven to turn on.

Through the above-described process, when time T ₁ has elapsed from the activation of the flash discharge tube 5, the transistor 20 is turned off by the off operation of the thyristor 21, and the capacitor is turned off regardless of the operating state of the transistor 17. 27 discharge is prohibited. As a result, lighting of the indicator lamp 19 is prevented.

According to this device that operates in this way, the indicator light 1
Reference numeral 9 indicates that when the flash discharge tube 5 emits light and its dimming function operates normally, it is driven to turn on only after a period T ₂ from the time when the flash discharge tube 5 is activated and up to time T ₁ . . Therefore, from the lighting of the indicator lamp 19, it is possible to reliably and easily confirm that the flash discharge tube 5 is emitting light and that the dimming function for the emitted light is functioning normally. Moreover, a single notification means (indicator light 19) allows the flash discharge tube 5 to emit light,
It is possible to effectively confirm both the normal operation of the dimming function.

Note that the present invention is not limited to the embodiments described above. Although the light emission by the indicator light 19 has been described here as an example of the light control function confirmation and notification means, it is also possible to use other light emission means. Furthermore, it is of course possible to employ sounding means as the notification means instead of the light emitting means. In addition, the present invention can be implemented with various modifications without departing from the gist thereof.

[Brief explanation of the drawing]

The figure is a circuit configuration diagram of a dimmable electronic flash device according to an embodiment of the present invention. 1... Main discharge capacitor, 2... Trigger transformer, 5... Flash discharge tube, 6, 10, 21... Thyristor, 7... Commutation capacitor, 11... Light receiving section, 14... Diode, 12, 22 ,24,2
6, 27, 29... Capacitor, 16... Zener diode, 17, 20... Transistor,
19... Indicator light.

Claims (1)

[Scope of Claims] 1. A subject is irradiated with light emitted by a flash discharge tube upon receiving a charge from a main discharge capacitor, and the amount of light reflected from the subject received by a light receiving section reaches a predetermined value. In the dimming type electronic flash device, the flash discharge tube is configured to stop emitting light at a light emitting stop section when the light emission stops, and the light emitting device is connected to a power source for charging the main discharge capacitor via a resistor, and a diode is connected to the main discharge capacitor. A charging voltage detecting capacitor is connected in parallel through the charging voltage detecting capacitor, and the charging voltage detecting capacitor is charged with a time constant determined by the resistor and the charging voltage detecting capacitor, and the charged charge is used to charge the main discharging capacitor. a charging voltage detection circuit that detects the charging voltage of the main discharge capacitor as the charging voltage of the charging voltage detection capacitor by discharging it through the diode according to the voltage; and a constant value charged to the charging voltage detection capacitor. A first switching element is driven to conduction in response to the charging voltage, and is turned on in response to a starting pulse of the flash discharge tube to form a discharge path for the time capacitor, which is stored in the time capacitor. a thyristor circuit that discharges the charged charge over a period _T1 determined by the time constant of the discharge path and generates a voltage according to the discharge current;
A second switching element is driven into conduction by receiving the voltage generated by the discharge current of this thyristor circuit, and a predetermined switching element is connected to a drive power source through the first and second switching elements in series. a notification means that operates when a drive voltage is applied; and a notification means that is connected in parallel to the notification means and is charged with a predetermined time constant by the drive power source when the first and second switching elements are conductive. and a capacitor that sets the voltage applied to the notification means to the predetermined drive voltage after a period T ₂ (<T ₁ ) has elapsed from the start of conduction of the first and second switching elements. The period T ₂ is set to be longer than the longest flash discharge period of the flash discharge tube, and the period T ₁ is set to be longer than the longest flash discharge period of the flash discharge tube.
A dimming type electronic flash device characterized in that a period of (T ₁ −T ₂ ) is set shorter than a minimum charging period of the main discharge capacitor.