JPH11237668A - Flash charging device for camera - Google Patents

Abstract

PROBLEM TO BE SOLVED: To rapidly detect the default of circuit parts, etc., and to rapidly stop charging operation. SOLUTION: This device is provided with a light emission part 10 for emitting flash light, a capacitor 12 by which the light emission part 10 performs flashing action by discharging stored charge, a DC/DC converter 14 for charging the capacitor 12, a charge voltage detection part 16 for detecting voltage at both ends of the capacitor 12, and a control part 24 for controlling the entire action. The charge voltage of the capacitor 12 detected in a specified cycle is compared with a reference value in the specified cycle. When it does not satisfy the reference value, the action of the DC/DC converter 14 is stopped by judging that the charging action is inappropriate.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a flash charging device for charging a flash circuit built in a camera.

[0002]

2. Description of the Related Art Conventionally, this type of flash charger has been
The light-emitting device includes a light-emitting means for generating a flash, a capacitor for storing light-emitting energy of the light-emitting means, a charging means for charging the capacitor, and a power supply for supplying light-emitting energy. In the flash charging device configured as described above,
It is necessary to take safety measures to stop the charging operation when an abnormality occurs in the charging circuit in order to prevent smoke or ignition.

For this reason, it has been proposed that, for example, a scheduled charging completion time is set, and if the charging is not completed within this time, the charging operation is stopped and the release is prohibited (Japanese Patent Laid-Open No. Hei 7 (1999)). -168260). In addition, it is proposed that the temperature change of the circuit components and the like constituting the charging circuit in the camera be detected by a temperature sensor, and when the circuit components or the like generate abnormal heat, the circuit is short-circuited and the power supply fuse is cut. (JP-A-7-333676). It has also been proposed to monitor the load current of the charging circuit and stop the sequence when the load current exceeds a reference value (Japanese Patent Laid-Open No. Hei 9-15675).

[0004]

However, in the method of setting the scheduled charging completion time, it is necessary to set the charging time by adding a time considering the power supply voltage, the ambient temperature, the variation of circuit components, and the like. For example, if it takes about 5 seconds to complete charging under normal conditions, it takes 15 seconds to complete charging when the power supply voltage is low or the ambient temperature is low.
Because it may take about 2 seconds, the charging completion time is set to 1
This will be set to 5 to 20 seconds. In this case, even if a failure in the short-circuit mode occurs in the circuit component, the charging operation is continued until the set time elapses. Therefore, a large current flows in the circuit, which may lead to an accident such as smoke or ignition.

Further, in a method of detecting a temperature change of a circuit component or the like with a temperature sensor and blowing a power supply fuse when an abnormality occurs,
If a circuit component that does not have a temperature sensor fails, the power supply fuse does not operate, which may lead to an accident such as smoking or ignition.On the other hand, if a circuit component has an open mode failure, Does not flow, so that there is no risk of an accident. However, a failure cannot be detected until the set time has elapsed.

In the method of stopping the sequence when the monitored load current exceeds the reference value, no current flows when an open mode failure occurs in a circuit component. Although there is no risk of an accident, a failure cannot be detected until the set time has elapsed.

SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a flash charging device for a camera which can quickly detect a failure of a circuit component or the like and stop the charging operation accordingly.

[0008]

In order to achieve the above object, the present invention is directed to a capacitor for causing a light emitting means to perform a flashing operation by discharging accumulated charges, and for charging the capacitor from a built-in power supply. Charging circuit, charging voltage detecting means for detecting the voltage across the capacitor, aptitude determining means for determining whether the charging operation is appropriate from the detected voltage, and stopping the charging operation when the charging operation is determined to be inappropriate. And charging stop means for causing the charging to stop.

According to this configuration, while the charging voltage of the capacitor is detected, it is determined from the detected voltage whether the charging operation is proper or not. If it is determined that the charging operation is not proper, the charging operation is stopped. . As a result, a failure of a circuit component or the like is detected within a time required for a full charge during a normal operation of the circuit. As a result, there is no danger of accidents such as smoke and ignition. Further, even when a failure in the open mode occurs in the circuit component, the failure is detected and the charging operation is stopped without waiting for the time required for full charge.

Note that during normal operation of the circuit, the charging operation is stopped when the capacitor is fully charged. The charging operation may be stopped by detecting a charging voltage, or may be performed when a preset time at which full charging is expected is reached.

According to a second aspect of the present invention, in the first aspect, the time point of voltage detection by the charging voltage detecting means is set to a predetermined time shorter than a time required for full charging from the start of charging. It is characterized by:

According to this configuration, the charging voltage of the capacitor is detected in a time shorter than the time required for full charge in the normal operation of the circuit from the start of charging, and whether the charging operation is appropriate is determined based on the detected voltage. When it is determined that the charging operation is not appropriate, the charging operation is stopped. As a result, even when a short-mode failure occurs in a circuit component, a large current flows through the circuit only for a short time, so that there is no possibility that an accident such as smoking or ignition may occur.
Further, even when a failure in the open mode occurs in the circuit component, the failure is detected and the charging operation is stopped without waiting for the time required for full charge.

[0013] The invention of claim 3 is the invention of claim 1 or 2.
Wherein the suitability judging means judges the suitability of the charging operation by comparing the detection voltage detected by the charging voltage detecting means with a reference value.

According to this configuration, the detection voltage detected by the charging voltage detection means is compared with the reference value to determine whether the charging operation is appropriate. That is, when the detected voltage is less than the reference value or less than the reference value, it is determined that the charging operation is not appropriate, and the charging operation is stopped. Therefore, the suitability of the charging operation is accurately determined, and when the charging operation is not appropriate, the charging operation is immediately stopped.

The invention according to claim 4 is the invention according to claim 1 or 2.
Wherein the suitability judging means causes the charging voltage detecting means to perform voltage detection at least twice at predetermined intervals, and compares the difference between the detected voltages with a reference value to determine whether the charging operation is appropriate. It is characterized by the judgment.

According to this configuration, at least two voltage detections are performed at predetermined intervals by the charging voltage detecting means, and the difference between the detected voltages and the reference value are compared to determine whether the charging operation is appropriate. You. That is, when the difference is less than the reference value or less than the reference value, it is determined that the charging operation is not appropriate, and the charging operation is stopped. Therefore, the suitability of the charging operation is accurately determined, and when the charging operation is not appropriate, the charging operation is immediately stopped. Note that the difference between the detection voltages may be an increase amount or an increase rate of the detection voltage.

Further, the invention of claim 5 provides the invention according to claims 1 to 4
Any of the above, further comprising a power supply voltage detecting means for detecting a voltage of the built-in power supply, wherein the reference value is prepared in a plurality of values corresponding to a power supply voltage detected at the start of charging. Features.

According to this configuration, the voltage of the built-in power supply is detected at the start of charging, and a reference value corresponding to the detected power supply voltage is selected. As a result, even if the time until the internal power supply is consumed and the battery is fully charged becomes long, the failure of the circuit component or the like is accurately detected.

Further, the invention of claim 6 is the invention of claims 1 to 5
Wherein the reference value is prepared in a plurality of values corresponding to a voltage detected by the charging voltage detecting means at the start of charging.

According to this configuration, the voltage across the capacitor is detected at the start of charging, and a reference value corresponding to the detected voltage is selected. As a result, even if the voltage across the capacitor at the start of charging changes every time the charging operation is performed, a failure of a circuit component or the like can be accurately detected.

Further, the invention of claim 7 provides the invention according to claims 1 to 6
The present invention is characterized in that a notifying means for notifying the stop of the charging operation is provided.

According to this configuration, when a failure occurs in a circuit component or the like and the charging operation is stopped, the notification unit is notified. Thereby, the user of the camera can be reliably made aware that the charging abnormality has occurred.

[0023] Further, the invention of claim 8 is based on claims 1 to 7.
The storage device according to any one of the above, further comprising storage means for storing stop information of the charging operation, wherein the charging operation is prohibited while the storage means holds the stop information.

According to this configuration, when the charging operation is stopped due to a failure of a circuit component or the like, the stop information is stored in the storage means, and the start of the charging operation is prohibited while the stop information is held. . As a result, even when a short-mode failure occurs in a circuit component, current does not flow through the circuit, and accidents such as smoking and ignition are reliably prevented.

[0025]

FIG. 1 is a diagram showing a circuit configuration of a flash charging device for a camera according to an embodiment of the present invention. In this figure, the camera flash charger is
A light emitting unit 10 that generates a flash, a capacitor 12 that causes the light emitting unit 10 to perform a flash operation by discharging accumulated charges, and a DC / DC converter 1 that charges the capacitor 12.
4, a charging voltage detecting unit 16 for detecting a voltage across the capacitor 12, a built-in power supply 18 including a battery for driving the DC / DC converter 14, and a power supply voltage measuring unit 20 for detecting a voltage value of the built-in power supply 18. Timer circuit 22 for counting charging operation time, DC / DC converter 1
4 and a control unit 24 for controlling the charging operation and the like.
The power supply voltage measuring section 20 and the timer circuit 22 are connected to the control section 24.

The light emitting unit 10 includes a Xe for emitting a flash.
The control circuit includes a discharge tube and a trigger circuit for generating a trigger signal for flash emission.
A flash emission signal is input from the CPU. For this reason, when a flash emission signal is input to the trigger circuit, the Xe discharge tube performs a flash operation by supplying accumulated charges from the capacitor 12.

The DC / DC converter 14 is of a self-excited type and includes a switching circuit, a step-up transformer, and a rectifier diode. The switching circuit receives a charge control signal from the control unit 24. Has become. Therefore, when the charging control signal is input to the switching circuit, the DC / DC converter 14 starts driving. That is, the DC voltage of the built-in power supply 18 is intermittently supplied to the primary winding of the step-up transformer by the switching element in the switching circuit repeating the ON / OFF operation, and the high-voltage AC voltage is applied to the secondary winding of the step-up transformer. Is induced. The AC voltage induced in the secondary winding is applied to the capacitor 12 via a rectifier diode.

The charging voltage detecting section 16 is composed of a series circuit of resistors R ₁ and R ₂ , and detects a voltage (charging voltage) across the capacitor 12 by dividing the voltage. The voltage detected by the charging voltage detector 16 is input to the controller 24. When the charging voltage of the capacitor 12 reaches a value at which flash photography is possible (this state is called full charge), the control unit 24.
Is interrupted, the DC / D
The driving of the C converter 14 is stopped. Note that the charging voltage detection unit 16 and the control unit 24 constitute a charging voltage detection unit that detects a voltage across the capacitor 12.

The control unit 24 includes a CPU 241 for performing predetermined calculation and control processing, a ROM 242 in which a predetermined processing program and the like are stored, and a RAM for temporarily storing data.
243. Further, the CPU 241 includes a first comparing unit 244 for comparing the charging voltage of the capacitor 12 detected by the charging voltage detecting unit 16 with the charging voltage value in the fully charged state stored in the ROM 242, and the detection by the charging voltage detecting unit 16. Second comparing means 245 for comparing the charging voltage during charging of the capacitor 12 with the reference value, when the charging voltage of the capacitor 12 detected by the charging voltage detecting unit 16 is in a fully charged state, or when the charging voltage detecting unit 16 Each function realizing means of the stopping means 246 for stopping the driving of the DC / DC converter 14 when the charging voltage of the capacitor 12 being charged detected in the step (1) does not satisfy the reference value is provided.

FIG. 2 is a time chart for explaining the operation of the flash charging device for a camera configured as described above. That is, when the camera is set to the flash photography mode, the control unit 24 outputs a charge control signal (for example, switches from a high signal to a low signal) and inputs the charge control signal to the switching circuit of the DC / DC converter 14. Thereby, the DC / DC converter 14
Is driven to start a charging operation (reference numeral (a)), charges are accumulated in the capacitor 12, and the charging voltage gradually increases (reference numeral (b)).

When the camera is set to the flash photography mode, a boost detection signal is output at a period of time T ₁ counted by the timer circuit 22 (code (c)).
Each time this boosting detection signal is output, the charging voltage detecting unit 16
The charging voltage of the capacitor 12 detected in step (1) is A / D converted and is taken into the control unit 24. The acquired charging voltage is compared by the first comparing means 244 with the charging voltage value in the fully charged state stored in the ROM 242.

When the battery is not fully charged, the driving of the DC / DC converter 14 is continued.
Is interrupted (for example,
Switch from low signal to high signal. ), The drive of the DC / DC converter 14 is stopped. The boost detection signal is output immediately before the DC / DC converter 14 is driven.
When the capacitor 12 is already fully charged before the DC / DC converter 14 is driven, the DC / DC converter 14 is not driven. When the capacitor 12 is fully charged, an unillustrated LED (Light Emitting
Diode) is lit to notify the camera user that flash photography is possible.

At the same time as the output of the boost detection signal, the period of the time T ₂ counted by the timer circuit 22 (in the present embodiment, the time T ₂ is set to an integral multiple of the time T ₁ ). , An abnormality detection signal is output (symbol (d)), and the charging voltage of the capacitor 12 taken in at that time is compared with a reference value by the second comparing means 245. This reference value is experimentally obtained in advance as described below.

That is, the capacitor 12 has a DC / DC
After the drive of converter 14 is started, it reaches a full charge level according to a boosting curve as shown in FIG. here,
The curve indicated by a solid line indicates a case where the voltage value of the built-in power supply 18 is at a high level at the start of driving of the DC / DC converter 14 (ie, at the start of charging), the curve indicated by a chain line indicates a case where the voltage value is at a medium level, The curves indicated by the dashed-dotted lines indicate the case where the level is low, and the value on the curve corresponding to the voltage value of the built-in power supply 18 every time the time T ₂ elapses is the reference value corresponding to each cycle of the time T ₂ It is said.

Thus, when the charging voltage during charging does not satisfy the reference value, charging is not normally performed, and it can be considered that a failure has occurred in a circuit component or the like. The curve shown by the dotted line shows an example in which a circuit component or the like in the DC / DC converter 14 has a failure, and shows a case in which the full charge level is not reached even after a predetermined charging time has elapsed. ing.

The reference value in each cycle of the time T ₂ is:
Internal and power source 18 is stored in the ROM242 to correspond to the voltage value in a table format, R each time that a value corresponding to the voltage value of the internal power supply 18 at the start of charging time elapses T ₂
Read from OM242. When the charging voltage fetched from the charging voltage detector 16 does not satisfy the read reference value, it is considered that a failure has occurred in a circuit component or the like, and is output from the controller 24 by the stopping means 246. The charge control signal is cut off and the DC / DC converter 1
4 is stopped. Note that the boosting curve shown in FIG. 3 is obtained in consideration of the variation in characteristics of circuit components and the like. The reference value may be set to a value near the value different from the value on the boosting curve, and may be set to a value that can be regarded as having a failure in a circuit component or the like when the charging voltage is equal to or less than the reference value. You may make it set.

Since it is necessary to make the reference value different according to the voltage value of the built-in power supply 18 as described above,
A power supply voltage detection signal is output immediately before the C / DC converter 14 is driven (symbol (e)). When the power supply voltage detection signal is output, the voltage value of the built-in power supply 18 is changed to the power supply voltage measurement unit 2.
It is measured by 0. The measured voltage value of the built-in power supply 18 is A / D converted, taken into the control unit 24, and stored in the RAM 243.

The flash charging device for a camera according to the present invention detects the voltage between both ends of the capacitor 12 as described above, compares the detected voltage with a reference value, and determines whether the detected voltage is less than the reference value or less than the reference value. Is configured to stop the operation of the DC / DC converter 14 by judging that the charging operation is not appropriate, and when a failure occurs in a circuit component or the like, a time required for a full charge in a normal operation of the circuit. It is possible to detect a failure of a circuit component or the like and stop the charging operation.

Therefore, even when a short-mode failure occurs in a circuit component, a large current flows through the circuit only for a short time, and it is possible to prevent accidents such as smoke and ignition. Further, even when a failure in the open mode has occurred in the circuit component, the failure can be detected and the charging operation can be stopped in a short time as in the case where the failure in the short mode has occurred. Also, failure of the capacitor 12,
If the leakage current increases due to deterioration, etc.,
Although charging is possible, the charging voltage may be rapidly reduced due to leakage, which may cause inconvenience in normal use. However, in the present invention, it is possible to detect an abnormality in such a case. The release is prohibited when the charging operation is stopped due to the detection of a failure of a circuit component or the like.

The flash charging device for a camera according to the present invention is not limited to the configuration of the above embodiment, but may adopt various modifications as described below.

(1) In the above embodiment, the capacitor 12
DC / DC converter 1 by detecting that the battery is fully charged
Although the driving of the DC / DC converter 14 is stopped, the driving of the DC / DC converter 14 may be stopped when a preset charging time expected to be fully charged during normal operation of the circuit is reached. . In this case, in the period of time T ₂ of the order to be compared with the reference value may be detected charging voltage.

(2) In the above embodiment, the capacitor 12
The detection voltage at both ends of the battery is compared with the reference value at a predetermined cycle. You can also For example, in a camera that discharges all the voltage charged in the capacitor 12 in one light emission (so-called full light emission type) and reaches a fully charged state of 330 V after about 7 seconds under minimum conditions, it always becomes 1 after 2 seconds.
When it is confirmed that the voltage exceeds 00 V, if the charging voltage after 2 seconds from the start of charging is lower than 100 V, it is considered that a failure has occurred in a circuit component or the like, and the driving of the DC / DC converter 14 is stopped. You may make it. Here, the minimum condition includes, for example, a state immediately before the lock is applied due to a decrease in the voltage value of the built-in power supply 18 and a low temperature, including a variation in characteristics of circuit components.

(3) In the above embodiment, the reference value is not changed according to the charging voltage (remaining voltage) of the capacitor 12 at the start of charging, but a flash circuit of a type that controls the amount of light emission In, the residual voltage of the capacitor 12 at the start of charging changes according to the amount of light emission. In addition, even in a flash circuit of a full light emission type, the charge voltage decreases due to spontaneous discharge due to being left after being fully charged, and the remaining voltage at the start of charging is not constant. Therefore, it is preferable to change the reference value according to the remaining voltage of the capacitor 12 at the start of charging.

In this case, the boosting curve shown in FIG. 3 may be obtained experimentally corresponding to the remaining voltage of the capacitor 12, and the reference value may be set based on the boosting curve. If the reference value is set in consideration of the ambient temperature, a more accurate value can be set.
In this case, a temperature sensor may be installed in the camera, and a reference value corresponding to the detected ambient temperature may be read from the ROM 242.

(4) In the above embodiment, the cycle of comparing the detected voltage with the reference value is set to an integral multiple of the cycle of detecting the charged voltage. However, both can be set to the same cycle. is there. If the comparison cycle with the reference value is set to an integral multiple of the charging voltage detection cycle, the number of comparison operations can be reduced, the operation is simplified, and failures of circuit components and the like are detected efficiently. be able to. Further, the comparison cycle with the reference value and the charging voltage detection cycle can be performed in cycles that are not related to each other. In this case, the charging voltage of the capacitor 12 may be detected in each cycle.

(5) In the above embodiment, the detected voltage is directly compared with the reference value.
Is provided with a function realizing means as a calculating means 247 for calculating the amount of increase of the detection voltage at both ends of the capacitor 12,
Calculates the increase amount by subtracting the previous detection voltage value from the detected voltage of the current in the period of time T _2, it may be compared with this increase with a reference value. The calculating means 24
7 may calculate the rate of increase in the detected voltage instead of the amount of increase in the detected voltage. In these cases, the voltage across the capacitor may be detected at least twice at predetermined intervals. In the present invention, the amount of increase or the rate of increase of these detection voltages is called a difference between the detection voltages.
Further, the reference value in these cases is the increase amount or increase rate obtained from the boosting curve shown in FIG.

(6) In the above embodiment, the charging operation is only stopped when a failure of a circuit component or the like is detected. However, the notifying unit 26 such as an LED or a buzzer is connected to the control unit 24, and Stopping means 2 when abnormality is detected
The notifying means 26 may be operated at the same time as the operation of 46. In such a case, the user of the camera can be quickly made aware that the charging abnormality has occurred.

(7) In the above embodiment, when a failure of a circuit component or the like is detected, only the charging operation is stopped, but the stop information is stored in a storage means such as the RAM 243, while the CPU 241 is charged. It is also possible to provide a function realizing unit as the prohibiting unit 248 for prohibiting the start of the operation, and prohibit the start of the charging operation while the storage unit holds the stop information. In such a case, even if a short-mode failure occurs in the circuit component, current does not flow through the circuit, and accidents such as smoking and ignition can be reliably prevented.

[0049]

As described above, according to the first to fourth aspects of the present invention, there is provided a capacitor for causing a light emitting means to perform a flashing operation by discharging accumulated charges, a charging circuit for charging a capacitor from a built-in power supply, Charging voltage detecting means for detecting a voltage across the capacitor; aptitude determining means for determining whether the charging operation is appropriate from the detected voltage; and charging stopping means for stopping the charging operation when the charging operation is determined to be inappropriate. Therefore, it is possible to quickly detect a failure of a circuit component or the like and stop the charging operation.

Further, according to the invention of claim 5, as the reference value,
Since a plurality of values corresponding to the power supply voltage detected at the start of charging are prepared, even if the built-in power supply wears out and the voltage value decreases, the charging time becomes longer and failure of circuit components etc. may occur. Detection can be performed accurately.

Further, according to the invention of claim 6, as the reference value,
Since a plurality of values are prepared corresponding to the detection voltage detected at the start of charging by the charging voltage detection means, even if the voltage across the capacitor fluctuates each time charging is performed, it is possible to accurately detect a failure of a circuit component or the like. Can be done.

Further, since the invention of claim 7 is provided with a notifying means for notifying the stop of the charging operation, the camera user can be surely recognized that a failure has occurred in a circuit component or the like. .

Further, the invention according to claim 8 has storage means for storing stop information of the charging operation, and the charging operation is prohibited while the storage means holds the stop information. Even when a short-mode failure occurs in a circuit component, current does not flow through the circuit, so that accidents such as smoking and ignition are reliably prevented.

[Brief description of the drawings]

FIG. 1 is a diagram showing a circuit configuration of a flash charging device for a camera according to an embodiment of the present invention.

FIG. 2 is a time chart for explaining the operation of the flash charging device of the camera shown in FIG. 1;

FIG. 3 is a view showing a boosting curve until a capacitor reaches a full charge level in the flash charging device of the camera shown in FIG. 1;

[Explanation of symbols]

 Reference Signs List 10 light emitting unit 12 capacitor 14 DC / DC converter (charging circuit) 16 charging voltage detecting unit 18 built-in power supply 20 power supply voltage measuring unit 22 timer circuit 24 control unit 26 reporting unit 244 first comparing unit 245 second comparing unit Judgment means) 246 Stop means (Charge stop means) 247 Calculation means 248 Prohibition means

Claims (8)

[Claims] 1. A capacitor for causing a light emitting means to perform a flashing operation by discharging accumulated charge, a charging circuit for charging the capacitor from a built-in power supply, a charging voltage detecting means for detecting a voltage across the capacitor, and a detecting circuit. A flash charging device for a camera, comprising: a propriety judging means for judging whether or not a charging operation is proper from a voltage; and a charging stopping means for stopping a charging operation when judging that the charging operation is not proper. 2. A flash charging device for a camera according to claim 1, wherein a time point of voltage detection by said charging voltage detecting means is set to a predetermined time shorter than a time required for full charging from the start of charging. . 3. The apparatus according to claim 1, wherein the suitability judging means judges the suitability of the charging operation by comparing the detection voltage detected by the charging voltage detecting means with a reference value. 3. The flash charging device for a camera according to 2. 4. The suitability judging means makes the charging voltage detecting means perform voltage detection at least twice at predetermined intervals, and compares the difference between the detected voltages with a reference value to determine whether the charging operation is appropriate. 3. The flash charging device for a camera according to claim 1, wherein the device is used for determining. 5. A flash charging device for a camera according to claim 1, further comprising a power supply voltage detecting means for detecting a voltage of said built-in power supply, wherein said reference value is a power supply detected at the start of charging. A flash charging device for a camera, wherein a plurality of values are prepared corresponding to voltages. 6. The method according to claim 1, wherein a plurality of values are prepared for the reference value corresponding to a voltage detected by the charging voltage detecting means at the start of charging. Camera flash charger. 7. The flash charging device for a camera according to claim 1, further comprising a notifying unit for notifying a stop of the charging operation. 8. The flash charging device for a camera according to claim 1, further comprising a storage unit configured to store stop information of a charging operation, and charging the storage unit while the storage unit holds the stop information. A flash charging device for a camera, the operation of which is prohibited.