JP2632517B2 - Charge stop device in flash discharge light emitter - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to an illuminator for photographing, a flash discharge illuminator used as a signal source of an automatic ranging device of a camera or a signal source of a remote control device, and the like. The present invention relates to a charging stop device.

"Prior art" This type of flash light emitter uses a DC-DC
The converter boosts and charges the main capacitor,
In addition, the electric energy stored in the capacitor is discharged through a xenon discharge tube to emit a flash light.

Many flash discharge light emitters have a charge stop circuit. That is, the charging operation is stopped when the main capacitor is charged to a predetermined charging voltage to prevent wasteful consumption of battery power.

Conventionally, various configurations of the charge stop circuit have been proposed. One example is shown in FIG.

In FIG. 4, 1 is a switching transistor for oscillating operation, 2 is a step-up transformer, 3 and 4 are starting resistors and capacitors, 5 is a capacitor for stabilizing the oscillating operation,
Reference numeral 6 denotes a diode as a rectifier.
Reference numerals 6 denote DC-DC converters, which are circuits for boosting the voltage of the battery power supply 8 connected when the power supply switching 7 is closed.

9 is a main capacitor charged by the DC-DC converter.

Reference numeral 10 denotes a flash discharge tube connected to the main condenser 9, reference numeral 11 denotes a trigger transformer for applying an excitation voltage to the flash discharge tube 10, reference numeral 12 denotes a trigger switch, and reference numeral 13 denotes a trigger capacitor. The light emitting circuit 14 is formed.

Reference numeral 15 denotes a Zener diode, which conducts by receiving a divided voltage appearing at the dividing resistor 16 when the main capacitor 9 reaches a predetermined charged voltage, and conducts a reverse current (Zena current) of the transistor 17 for amplification. Give to the base.

Reference numeral 18 denotes a short-circuiting switching transistor to which a base current is given when the transistor 17 is turned on. When the transistor 18 is turned on, the base and the emitter of the oscillation transistor 1 are short-circuited. The OFF state continues, and the oscillation of the DC-DC converter stops.

As can be seen from the above, Zener diode 15, split resistor
The transistor 16 and the transistors 17 and 18 form a charge stop circuit.

In the above conventional example, the DC-DC converter is connected to the power switch 7.
Starts oscillation, and the main capacitor 9 is charged by the oscillation.

Until the main capacitor 9 reaches a predetermined charging voltage, the Zener diode 15 is in a non-conductive state, and both the transistors 17 and 18 are off. The charging of the main capacitor 9 proceeds, and when the capacitor 9 is charged to a predetermined charged voltage, the Zener diode 15 becomes conductive.
From this, the transistor 17 is turned on by the base input of the Zener current of the Zener diode 15, so that the transistor 17 is turned on.
18 is turned on, the base and the emitter of the transistor 1 for oscillation are short-circuited, and at this time, the oscillation of the DC-DC converter temporarily stops. When the oscillation of the DC-DC converter stops, the voltage of the main capacitor 9 drops due to self-discharge, and when this voltage drops slightly, the Zener diode 15 becomes non-conductive, and both the transistors 17 and 18 are turned off.

As a result, the DC-DC converter starts oscillating, and charges the main capacitor 9 again to a predetermined charging voltage.

As described above, after the main capacitor 9 reaches the predetermined charging voltage, the DC-DC converter repeats oscillation and stop at an early cycle, and keeps the charging voltage of the main capacitor 9 substantially constant.

If the trigger switch 12 is closed under the above condition,
The flash discharge tube 10 emits light by a known method, and the electric energy stored in the main capacitor 9 is discharged at a stroke.

When the charged voltage of the main capacitor 9 drops due to the above-described energy discharge, the Zener diode 15 is restored and becomes non-conductive, so that both the transistors 17 and 18 are turned off, and the DC-DC converter oscillates again. And continuous oscillation is started.

The oscillation of the DC-DC converter is stopped immediately when the power switch 7 is opened.

"Problems to be Solved by the Invention" As described above, the charge stop circuit of the above-described conventional example is composed of the Zener diode 15, the dividing resistor 16, and the two transistors 1
7 and 18. That is, in the circuit configuration of the above-described conventional example, the transistor 17 for amplification and the transistor 18 for short-circuiting are required.

The reason is that there was no Zener diode with a high Zener voltage. In other words, since the configuration is such that the divided voltage is detected by the divided resistor 16, the Zener diode
Since the zener current of 15 is small, the zener current is amplified by the transistor 17 and then applied to the base of the transistor 18.

In addition, there is a rotating configuration in which the lighting current of a neon tube connected in parallel to the main capacitor 9 instead of the zener diode 15 and the dividing resistor 16 is applied to the base of the transistor 17, but the lighting current of the neon tube also has a small value. Because
An amplifying transistor 17 is required.

On the other hand, since the dividing resistor 16 is connected in parallel with the main capacitor 9, current flows through the dividing resistor 16 during the charging operation as well as after the charging operation, resulting in wasteful power consumption.

"Means for solving the problems" The present invention has been developed in view of the above problems,
A switching transistor that has an emitter connected to the negative side of the battery power source and oscillates by receiving the base current, and a switching transistor that has one end of the secondary coil connected to the main capacitor and the other end connected to the negative side of the battery power source. A DC-DC converter having a step-up transformer that boosts the DC voltage of the battery power supply in accordance with the oscillation operation of the battery is provided, and the electric energy stored in the main capacitor is discharged by the output of the DC-DC converter to light energy. In a flash discharge light emitting device provided with a flash discharge tube for conversion, a base and an emitter of the switching transistor are connected via a switching member, and a generation point of a detection voltage is previously determined in an induction coil of the boosting transformer. This detection voltage when the charged voltage of the capacitor reaches a predetermined value Depending made conductive the switching member to propose a charging stop device being characterized in that a structure for stopping the oscillating operation of the transistor.

[Operation] The above-described charging stop device is configured such that the detection voltage generated in the induction coil of the step-up transformer rises as the charging of the main capacitor progresses, and when the main capacitor reaches a predetermined charge pressure, the charging stop device responds to the detection voltage. As a result, the switching member conducts.

Therefore, the base and the emitter of the oscillating transistor are short-circuited, the transistor continues to be in the OFF state, and the charging by the DC-DC converter is stopped.

When the charged voltage of the main capacitor slightly drops below a predetermined value due to spontaneous discharge, the detection voltage drops accordingly, the switching member becomes non-conductive, the transistor starts oscillating again, and the DC-DC converter is charged. Operation.

In this way, charging and discharging of the DC-DC converter are repeated at a rapid cycle, and the main capacitor is maintained at a substantially predetermined charged voltage.

When the charging voltage of the main capacitor drops due to light emission of the flash discharge tube, the switching member continues to be in a non-conductive state, so that the charging operation by the DC-DC converter is continued until the charging voltage reaches the predetermined value. Continued.

"Example" Next, an example of the present invention will be described with reference to the drawings.

FIG. 1 is a partial view of a flash discharge light emitter circuit showing only a charging circuit as a first embodiment.

In this figure, reference numeral 20 denotes a switching transistor that oscillates, 21 denotes a step-up transformer having a primary coil 21p and a secondary coil 21s, 22 and 23 denote starting resistors and capacitors, 24
Is a capacitor for stabilizing the oscillating operation, 25 is a rectifying diode, these members 20 to 25 form a DC-DC converter, and a voltage of a battery power supply 27 connected under a closed power switch 26. To charge the main capacitor 28.

The secondary coil 21s of the step-up transformer 21 is connected to the negative line of the battery power supply 27 via the resistor 29, and a tap a is provided in the middle of the secondary coil 21s.
Is connected to the base of the transistor 30 that performs the switching operation. Transistor 30 has its collector connected to the base of switching transistor 20 and its emitter connected to battery power.
Each of them is connected to 27 negative side lines. When the transistor 30 is turned on, the switching transistor 20 is turned on.
Short-circuits between the base and the emitter of the switching transistor 20 to stop the oscillation operation of the switching transistor 20.

The diode 31 shown is for protecting the switching transistor 20.

In the charging circuit of this embodiment, the base current flows through the switching transistor 20 by closing the power switch 26, the transistor 20 is turned on, and the input current i from the battery power supply 27 via the primary coil 21p of the step-up transformer 21 is supplied. ₁ flows. Therefore, the secondary coil 21s output current i ₂ with high voltage is generated, the diode 25, the main capacitor 28, a switching transistor (base-emitter)
20, flows through the path of the resistor 29, and the main capacitor 28 is charged.

When the increase in the input current i ₂ approaches saturation, the step-up transformer 21
A secondary coil 21s is cracking induced voltage in the reverse direction the table to the above, the reverse voltage is applied between the base-emitter of the switching transistor 20, the transistor 20 is OFF and the input current i ₁ is interrupted.

Since the input current i ₁ by OFF of the transistor 20 is abruptly cut off, the secondary coil 21s and large reverse voltage is generated, which is based - of the switching transistor 20
Applied between the emitters, the diode 31 then acts to protect this transistor 20.

Thereafter, the base current flows from the battery power supply 27 to the switching transistor 20, and the switching transistor 20 is turned on again, and shifts to the current operation as described above.

As described above, this charging circuit operates as a blocking converter that oscillates when the switching transistor 20 is repeatedly turned on and off. On the other hand, transistor 30
The tap position of the secondary coil 21s is determined so that the main capacitor 28 is kept OFF until the main capacitor 28 is charged to a predetermined charged voltage Vo.

Therefore, when the charging progresses and the main capacitor 28 reaches the charged voltage Vo, the transistor 30 is turned on by receiving the voltage of the tap a as the base, and the switching transistor 20 is turned on,
Stop OFF oscillation. By stopping this oscillation, the output current i
_{When 2} stops, a flyback voltage is generated in each coil of the step-up transformer 21, and the transistor 20 remains OFF. As described above, the charging operation is stopped when the main capacitor 28 reaches the charge-to-charge pressure Vo.
Since the output current i ₂ from the base current flows through the transistor 30 and there is a slight time lag until the stop charging people pressure becomes Vo + Delta] Vo.

When the charged voltage of the main capacitor 28 drops below Vo due to spontaneous discharge or the like, the DC-DC converter immediately starts oscillating and is charged again to Vo + ΔVo.

In this way, the charged voltage of the main capacitor 28 becomes Vo ~
It is kept stable within the range of (Vo + ΔVo).

When the flash discharge tube emits light to discharge the charge of the main capacitor, the charge is performed in the same manner as described above.

Next, a charge stop circuit including the transistor 30 will be described using mathematical expressions.

Vbe + ib · Rb = E ₃ − (i ₂ + ib) R (1) In this equation (1), Vbe, ib, and Rb are transistors 3
These are 0 base-emitter voltage, base current, and base resistance. Also, E ₃ is the voltage between the connecting end b of the tap a resistor 29, the resistance value of R is the resistance 29 (the number Omega).

Also, However, E ₂ is the secondary voltage, n ₂ the upper secondary coil turns than tapping a, n ₃ is the lower side of the secondary coil winding than tap a.

When the voltage E ₃ is in the stop voltage (when the charging s pressure of the main capacitor 28 reaches Vo), the transistor 30
, The base current ib starts to flow. When this base current ib is obtained from equation (1), The (3) As seen from the equation, the instantaneous output current i ₂ is stopped, the base current ib tends to increase with a decrease in the output current i _2. This is a kind of positive feedback operation, and the charging stop operation is performed sensitively. Note that resistor 29
Although those to improve the accuracy of charging stop operation, the time difference between the stop time of the time when the base current ib flows an output current i ₂ by changing the resistance value, that is, it is possible to change the charging people pressure Delta] Vo.

In the above embodiment, the voltage Vbe between the base and the emitter of the transistor 30 is the reference value of the charge stop, so that the same charge stop accuracy as that of the conventional example can be obtained unless affected by the ambient temperature.

In addition, the charging voltage Vo is ± 10 V for an ambient temperature of 0 to 40 ° C.
If an error other than the above is allowed, the charging circuit of the above embodiment is useful.

FIG. 2 is a circuit diagram similar to FIG. 1 showing a second embodiment of the present invention in which a change in ambient temperature is taken into consideration.

In this embodiment, a zener diode 32 is connected to the base of the transistor 30, and the reference value is increased so that a change ΔVbe between the base-emitter voltage Vbe of the transistor 30 and the ambient temperature can be ignored.

By appropriately setting the Zener voltage of the Zener diode 32, the temperature characteristic of the charging voltage Vo is extremely improved. For example, the change of the charging voltage Vo can be kept within ± 2 V to ± 3 V within 0 to 40 ° C. .

However, in this embodiment, the flyback voltage kE ₃ (k = 2 to 4) of the coil portion below the tap a of the secondary coil 21s
Is less than the reverse withstand voltage (about 5 to 7 V) of the voltage between the base and the emitter of the transistor 30.

When kE ₃ exceeds the reverse withstand voltage in the above flyback, as shown in FIG. 3, a diode 33 is connected to the base of the transistor 30 and a resistor 34 for passing a bias current to the Zener diode 32 somewhat is connected between the base and the emitter. Connect between.

In the above embodiment, the case where the present invention is applied to a DC-DC converter using an NPN-type switching transistor has been described. However, the present invention can be similarly applied to a converter using a PNP-type switching transistor. Equipped with DC-DC converter and feedback winding
It can also be implemented for a DC-DC converter. In a device having a feedback winding, a tap may be drawn from a part of the winding and the transistor 30 may be controlled according to the voltage of the tap. Also, transistor 30 can be replaced by another switching member that operates similarly.

[Effects of the Invention] As described above, in the present invention, the charging stop device is configured by using the induced voltage of the step-up transformer, so that a dividing resistor and an amplifying transistor as in the conventional example are not required. This results in a charging stop device that consumes very little power and minimizes circuit components. In addition, since the reference voltage for stopping charging is determined by the winding ratio of the step-up transformer, the operation accuracy is the same as that of a conventional device using a divided resistor.

[Brief description of the drawings]

FIG. 1 is a partial view showing a charging circuit of a flash discharge light emitting device provided with a charge stopping device according to the present invention, and FIG. 2 is a drawing similar to FIG. 1 showing a charging stopping device to which a zener diode for preventing the influence of ambient temperature is added. FIG. 3 is a partial view similar to FIG. 1 in which a protection diode for a transistor included in a charge stop circuit is added, and FIG. 4 is a view showing a conventional flash discharge light emitter circuit provided with a charge stop device. is there. 20 Switching transistor 21 Step-up transformer 28 Main capacitor 29 Resistance 30 Transistor 32 Zener diode 33 Diode 34 Resistance

Claims (1)

(57) [Claims] 1. A switching transistor having an emitter connected to the negative side of a battery power source and oscillating by receiving a base current, one end of a secondary coil being connected to a main capacitor, and the other end being connected to the negative side of the battery power source. A DC-DC converter including a boost transistor that boosts the DC voltage of the battery power supply in accordance with the oscillation operation of the switching transistor, and discharges the electric energy stored in the main capacitor by the output of the DC-DC converter. In a flash discharge light emitting device having a flash discharge tube for converting light energy into light energy, a base and an emitter of the switching transistor are connected via a switching member, and a point at which a detection voltage is generated in advance in an induction coil of the step-up transformer. And that the charged pressure of the main capacitor has reached a predetermined value. The response to the detected voltage by conducting the switching member charging stop device being characterized in that a structure for stopping the oscillating operation of the transistor.