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Claims  |
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I claim:
1. In an improved electronic flash unit having a flashtube, a flashtube
trigger circuit including a trigger capacitor for initiating a
flash-firing operation, a flash firing capacitor for producing a sustained
flash following flash-firing initiation, and means for connecting said
trigger and firing capacitors to a source of electrical potential for
controllably charging said trigger and firing capacitors, said electronic
flash unit further including input means for coupling said flash unit to a
camera having a shutter and a flash lamp firing mechanism of the type
which produces a flash lamp energization signal in response to actuation
of the camera in timed relation to operation of the camera shutter, the
improvement comprising:
a. circuit means, coupled to said input means, having (1) a non-conductive
state for electrically isolating said input means from said trigger
circuit and (2) a conductive state for producing a time-delay signal a
predetermined time interval following the occurrence of the energization
signal, said time interval being functionally related to the timed
relation between the flash lamp energization signal and operation of the
camera shutter;
b. switch means responsive to (1) said firing capacitor being charged to a
level sufficient to flash said flashtube, and (2) the occurrence of the
energization signal for switching said circuit means into its conductive
state; and
c. switching means responsive to said timedelay signal for permitting said
flashtube trigger circuit to trigger said flashtube ON.
2. In an improved electronic flash unit having a flashtube, a flashtube
trigger circuit including a trigger capacitor for initiating a
flash-firing operation, a flash-firing capacitor for producing a sustained
flash following flash-firing initiation, and means for connecting said
trigger and firing capacitors to a source of electrical potential for
controllably charging said trigger and firing capacitors, said electronic
flash unit further including an electrical input circuit for electrically
coupling said flash unit to a camera having a shutter and a flash lamp
firing mechanism of the type which produces a flash lamp energization
signal in response to actuation of the camera prior to operation of the
camera shutter, the improvement comprising:
a. circuit means interconnecting said electrical input circuit and said
trigger circuit, said circuit means having (1) a first non-conductive
state for electrically isolating said input circuit from said flashtube
trigger circuit to prevent the energization signal from rendering said
trigger circuit effective to trigger said flashtube ON, and (2) a second
conductive state for producing a control signal a predetermined time
interval following the initiation of the flash lamp energization signal,
said time interval being proportional to the time period between the
occurrence of the flash lamp energization signal and operation of the
camera shutter;
b. flash-ready switch means responsive to the charge on said firing
capacitor and having (1) a first, non-conductive state for maintaining
said current means in said non-conductive state while said firing
capacitor is charged to a level insufficient to flash said flashtube and
(2) a second, conductive state in response to said firing capacitor being
charged to a level sufficient to flash said flashtube for permitting said
circuit means to assume its conductive state in response to the occurrence
of the flashlamp energization signal; and
c. electronic switching means responsive to said control signal for
rendering said flashtube trigger circuit effective to trigger said
flashtube ON.
3. An electronic flash unit as set forth in claim 2 wherein said
flash-ready switch means further includes means for optically signaling
that the charge on said firing capacitor is sufficient to flash said
flashtube.
4. In an improved electronic flash unit having a flashtube, a flashtube
trigger circuit including a trigger operation for initiating a
flash-firing operation, a flash firing capacitor for producing a sustained
flash following flash-firing initiation, and means for connecting said
trigger and firing capacitors to a source of electrical potential for
controllably charging said trigger and firing capacitors, said electronic
flash unit further including input means for coupling said flash unit to a
camera having a shutter and a flash lamp firing mechanism of the type
which produces a flash lamp energization signal in response to actuation
of the camera in timed relation to operation of the camera shutter, the
improvement comprising:
a. means operatively associated with said input means for producing a
control signal having a particular parameter a predetermined time interval
following the initiation of the flash lamp energization signal;
b. voltage-sensitive switching means responsive to the voltage across said
flash firing capacitor for rendering said control signal producing means
conductive when the firing capacitor voltage is adequate to flash said
flashtube;
c. electronic switching means responsive to said control signal for
rendering said flashtube trigger circuit effective to trigger said
flashtube ON; and
d. second voltage-sensitive switching means responsive to the discharge of
said flash firing capacitor for rendering said control signal producing
means non-conductive.
5. In an improved electronic flash unit having a flashtube, a flashtube
trigger circuit including a trigger capacitor for initiating a
flash-triggering operation, a flash firing capacitor for producing a
sustained flash following flash-firing energization, and means for
connecting said trigger and firing capacitors to a source of electrical
potential for controllably charging said trigger and firing capacitors,
said electronic flash unit further including input means for coupling said
flash unit to a camera having a shutter and a flash lamp firing mechanism
of the type which produces a flash lamp energization signal in response to
actuation of the camera in timed relation to operation of the camera
shutter, the improvement comprising:
a. first electronic switching means having a gate electrode operatively
associated with said flashtube trigger circuit for controlling triggering
of said flashtube; and
b. circuit means interconnecting said input means and said first electronic
switching means, said circuit means including:
i. means having a resistor and timing capacitor for producing a control
signal having a particular amplitude in a time interval following
initiation of the flash lamp energization signal proportional to the
product of the resistance and capacitance value;
ii. first voltage-sensitive means for producing a signal to render said
control signal producing means effective to produce said control signal
once said firing capacitor is charged above a predetermined level;
iii. second electronic switching means having a gate electrode electrically
coupled to said input means for permitting said timing capacitor to charge
following initiation of the flash lamp energization signal; and
iiii. second voltage-sensitive means having a nonconductive state for
rendering said circuit means non-conductive, said second voltagesensitive
means assuming said non-conductive state during a flashtube-firing
operation to effectively open circuit said resistor and capacitor
combination.
6. In an improved electronic flash unit having a flashtube, a flashtube
trigger circuit including a trigger capacitor for initiating a
flash-firing operation, a flash firing capacitor for producing a sustained
flash following flash-firing initiation, and means for connecting said
trigger and firing capacitors to a source of electrical potential for
controllably charging said trigger and firing capacitors, said electronic
flash unit further including input means for coupling said flash unit to a
camera having a shutter and a flash-firing mechanism of the type which
produces a flash lamp energization signal in response to actuation of the
camera in timed relation to operation of the camera shutter, the
improvement comprising:
a. means defining an electrical circuit interconnecting said input means
and said flashtube trigger circuit and having first and second parallel
branches, said first branch comprising a voltage-sensitive switching
element in series with a resistor, said first branch having a first,
non-conductive state and a second, conductive state for producing a
control signal, said conductive state occurring when a charge exists on
said firing capacitor above a predetermined level, said second branch
comprising first electronic switching means a resistor, a capacitor,
second electronic switching means, and means for interconnecting said
first and second electronic switching means, said resistor and said
capacitor in a series configuration, said first electronic switching means
having controllable gate means connected to said first branch for
rendering said second branch conductive with the occurrence of said
control signal, said second electronic switching means having controllable
gate means coupled to said input means for rendering said second branch
effective to charge said capacitor upon the presence of the flash lamp
energization signal; and
b. third electronic switching means having a gate electrode responsive to
the voltage across said capacitor for rendering said trigger circuit
conductive to effect a flash-firing operation.
7. An electronic flash unit as set forth in claim 6 wherein said electrical
circuit defining means further includes means interconnecting said first
and second branches for permitting said first electronic switching means
to remain electrically conductive while said second electronic switching
means is nonconductive.
8. An electronic flash unit as set forth in claim 7 wherein said second
branch further includes voltage-sensitive switching means for rendering
said first electronic switching means non-conductive when the firing
capacitor voltage is below a particular level. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates to an electronic flash unit for use with cameras
having a flash lamp firing mechanism adapted to fire flash lamps in timed
relation with the operation of a camera shutter.
2. Description of the Prior Art
In photographic cameras which are adapted for flash photography by firing
or igniting a flash lamp or flashbulb, various arrangements are known for
firing the flash lamp in timed relation with the operation of the camera
shutter control mechanism. The light intensity from a flash lamp is
transient and, typically, is of a duration of approximately 40
milliseconds (ms), the peak light intensity being reached within
approximately 10 ms followed by a gradual decay. Because the light from
flash lamps is of a relatively long duration and because flash lamps do
not reach peak light intensity instantaneously, the timing between the
opening (and closing) of a camera shutter and the firing of the flash
lamp, although important, is not severely limited. In some flash cameras,
the shutter may begin to open before the flash lamp is energized to allow
for dynamic shutter delays occasioned in the period to allow the shutter
to initially open whereas in other cameras the flash lamp may actually be
fired prior to actuation of the shutter to permit the flash light to
approach its peak light intensity before the shutter is initially opened.
On the other hand, electronic flash units, which may have a light source
such as a xenon-filled flashtube, have a very short duration light output
on the order of a millisecond and reach peak light intensity almost
instantaneously. Therefore, it is not feasible to fire a flash unit before
the camera shutter is actuated. Care must be taken to fire a flash unit
after the camera shutter is actuated to allow for mechanical delays
associated with the shutter to assure that the shutter is opened before
the flashtube is fired.
To provide an electronic flash unit adapted to be mounted or coupled to a
flash lamp receiving socket operatively associated with the camera and to
be fired from a flash lamp firing mechanism located in the camera presents
the problem of synchronizing the shutter opening and flash unit firing
operations. This problem is particularly acute when the flash lamp firing
mechanism is of the type which is actuated prior to the occurrence of
shutter opening movement.
It is known in the prior art to provide an electronic flash unit for use
with cameras adapted to receive and to fire flash lamps, and in which the
flash unit is fired from the same source in the camera used to fire the
flash lamp. In particular, it is known in the prior art to fire a flash
unit from a camera having a flash lamp firing mechanism which is actuated
prior to the initiation of shutter opening movement. For example, U.S.
Pat. No. 3,559,548, issued to M. S. Ackerman on Feb. 2, 1971, and U.S.
Pat. No. 3,521,540, issued to W. C. Cavallo on July 21, 1970, disclose a
rechargeable stroboscopic flash attachment adapted to be connected to a
flash lamp receiving receptacle of a camera of the type having a shutter
delay mechanism for delaying operation of the camera shutter until the
flash lamp normally used with the camera has reached its peak light
intensity. In the Ackerman patent the flash unit is electrically connected
to a pair of flash lamp terminals and includes an electronic time delay
circuit which provides a flash ignition signal to fire the flashtube a
fixed, predetermined time period after a flash lamp would normally be
fired. The delay is related to the shutter delay period so that the strobe
is fired when the shutter is opened.
In the Cavallo patent, a shutter activating signal having a duration
related to the delay induced by the shutter delay mechanism is utilized to
energize an input relay. While the relay is energized, a control capacitor
is charged. When the relay is de-energized, which occurs upon termination
of the shutter activating signal, the relay contacts are switched which
causes the capacitor to discharge and trigger the flashtube ON.
SUMMARY OF THE INVENTION
One of the objects of the present invention is to provide an improved
electronic flash unit for use with a camera of the type adapted to fire
flash lamps.
Another object of the invention is to provide an electronic flash unit of
the aforementioned type, the flash unit having an improved circuit for
synchronizing the operation of the camera shutter with the firing of the
flashtube.
A yet another object of the present invention is to provide an improved
electronic flash unit having an electronic time delay circuit for
synchronizing the operation of the camera shutter and the flashtube, the
flash unit further including means for signaling the operational readiness
of the flashtube while automatically rendering the delay circuit effective
to synchronize the shutter with the flashtube.
A still further object of the instant invention is to provide switching
means operatively associated with the time delay circuit and responsive to
the strobe firing capacitor voltage for automatically resetting the strobe
trigger circuit for subsequent flashtube energization.
A still further object of the instant invention is to provide an improved
electronic flash unit of the aforementioned type which employs a time
delay circuit that can be efficiently manufactured at a low cost.
Another object of the instant invention is to provide an improved
electronic flash unit for use with cameras of the type adapted to fire
flash lamps, which flash unit can operate relatively independent of the
characteristics of the flash lamp firing signal.
In accordance with the above objects, there is provided an electronic flash
unit adapted to be fired from a camera having a flash lamp firing
mechanism for energizing a received flash lamp in timed relation with the
operation of the camera shutter, the flash unit comprising means
responsive to a flash lamp energization signal for producing a control
signal in timed relation to the occurrence of the energization signal,
means for enabling the control signal producing means effective to produce
the control signal once the flash unit firing capacitor is charged to a
predetermined level, and electronic switching means responsive to the
control signal for rendering the flash unit trigger circuit conductive to
thereby effect a flash unit firing operation.
The invention, and its objects and advantages, will become more apparent in
the detailed description of a preferred embodiment presented below.
BRIEF DESCRIPTION OF THE DRAWING
In the detailed description of a preferred embodiment of the invention
presented below, reference is made to the accompanying drawing, in which:
FIG. 1 illustrates a perspective view of an electronic flash unit, which
includes the present invention, mounted on a camera of the type adapted to
receive and to fire flash lamps; and
FIG. 2 is a schematic of an electronic circuit included in the flash unit
shown in FIG. 1, which circuit in accordance with the teachings of the
instant invention operates to synchronize the camera shutter with the
firing of the flashtube.
DESCRIPTION OF A PREFERRED EMBODIMENT
Because electronic flash units are well known, the present description will
be directed in particular to elements forming part of, or cooperating more
directly with, apparatus in accordance with the present invention. It is
to be understood that flash unit elements not specifically shown or
described may take various forms well known to those having skill in the
art.
There is shown in FIG. 1 of the drawing a camera, designated generally with
the numeral 10, having an enclosed generally light-tight housing 12,
within the top wall 13 of which is located a shutter release member 15 and
a knurled focus setting button 17 which is movable for focusing a taking
lens (not shown) mounted within the housing in alignment with exposure
aperture 20. Camera 10 also includes a shutter mechanism (not shown)
located to regulate the amount of scene light projected through exposure
aperture 20, the shutter being actuatable in response to a camera operator
depressing shutter release member 15. Mounted within faceplate 22 is a
viewfinder 23 and a window 24 behind which is located a light-sensitive
device (not shown) such as a photocell for sensing the intensity of the
scene light. Camera 10 may also include an electronic exposure control
circuit operably associated with the photocell so as to automatically
control the amount of scene light passing through aperture 20 once the
shutter is opened under the influence of release member 15.
An electronic flash unit 30 is mounted on camera 10 by means known in the
art such as a mounting base (not shown) which depends from the bottom of
housing 32 and is adapted to fit snugly into a flash-receiving shoe or
receptacle (also not shown) located within top wall 13. Flash unit 30 is
electrically connected to camera 10 as is shown schematically in FIG. 2 by
a pair of electrical conductive strips 33a, 33b located in the flash base
and spaced for making contact, respectively, with corresponding spaced
contacts 34a, 34b located within the camera flash-receiving receptacle.
Contacts 34a, 34b are connected to a flash-firing mechanism 35, shown in
block form, which mechanism is of the kind normally utilized for igniting
a photographic flash lamp or flashbulb. Flash-firing mechanisms are well
known in the art and may, for example, include apparatus for electrically
firing the flash lamp which comprises a low voltage source and associated
circuitry arranged to produce a flash lamp firing pulse in timed relation
to the actuation of the camera shutter mechanism or, on the other hand,
may include a piezoelectric crystal located and arranged so as to produce
a high voltage impulse in timed relation to shutter opening movement.
Arrangements of the latter type have been described in several patents,
one of which is U.S. Pat. No. 2,972,937 issued to C. G. Suits on Feb. 28,
1961, entitled FLASH APPARATUS.
Flash unit 30 includes an electronic flashtube 36, also shown schematically
in FIG. 2, mounted within housing 32 in optical communication with a flash
window 38. Housing 32 is formed of a pair of complimentary shaped portions
32a, 32b which are releasably coupled together by suitable means such as
screws (not shown) to permit an operator access to the inside of the flash
unit.
A spring loaded plunger-type switch member S1, shown in FIG. 2, protrudes
from the bottom wall of housing 32 and is closed when flash unit 30 is
properly inserted into the aforementioned flash-receiving receptacle so as
to connect flash unit battery 40, for the purpose of operating flashtube
36.
To fire flashtube 36 in response to each flash lamp firing signal generated
by camera 10 at contacts 34a, 34b and in synchronism with the camera
shutter mechanism, electronic flash unit 30 includes an internal circuit
denoted generally 50, as shown in FIG. 2, which circuit constitutes the
principal part of the instant invention and will be readily understood by
those skilled in the electronics art from the following description read
in conjunction with the drawing.
As is shown in FIG. 2, circuit 50 includes a conventional electronic flash
circuit 51 having a main firing capacitor 52 connected in parallel across
flashtube 36 to provide the firing voltage for the flashtube. This
conventional circuit further includes a fixed resistor 53, a trigger
capacitor 54 of relatively small capacitance, and the primary winding 55
of an ignition transformer 56, the resistor, trigger capacitor and primary
being interconnected to form a series circuit which is in parallel across
flashtube 36. Ignition transformer 56 has its secondary winding 57
connected in series to trigger electrode 36a as shown.
A silicon controlled rectifier (SCR) 58 connected in parallel across
trigger capacitor 54 and primary 55, as shown, constitutes means for
rendering the flash trigger circuit conductive to fire flashtube 36. As is
known in the electronics art an SCR is an electronic switching device
which is normally non-conducting but which is rendered conductive when a
momentary pulse of current is caused to flow into its gate electrode and
which remains conductive even after gate electrode current ceases as long
as the magnitude of the current signal that flows from anode to cathode is
above a predetermined level. With SCR 58 interconnected as shown, primary
winding 55 forms a series circuit with trigger capacitor 54 and the anode
to cathode junction of SCR 58, which circuit operates to discharge trigger
capacitor 54 through the primary winding when the SCR conducts.
To obtain an adequate voltage potential for operating flashtube 36, a
voltage converter circuit denoted generally 59 is provided which is
adapted to step-up or convert the relatively low voltage of battery 40 to
a level sufficient to adequately charge firing capacitor 52 and trigger
capacitor 54. Voltage converter 59 includes a transformer 60, the
secondary winding of which comprises a high voltage winding 61 and a low
voltage winding 62, and a transistor 63, the emitter electrode 63a being
connected to transformer primary 64 as shown, base electrode 63b being
connected in series to the low voltage winding 62 and collector electrode
63c being connected to common conductor 65. A control capacitor 66 is
connected in parallel across the emitter-base junction of transistor 63
and winding 62 as shown and operates due to the high impedance combination
of battery 40, current limiting resistor 67 and primary 64 to provide
positive feedback to emitter electrode 63a of the base electrode current.
When switch S1 is closed, current is caused to flow from battery 40 through
primary 64. Initially, the portion of the battery voltage which appears
across primary 64 is relatively small and only a slight amount of current
is caused to flow into emitter electrode 63a and to charge capacitor 66.
However, with a voltage across primary 64, a voltage is induced across the
secondary windings under the influence of transformer 60 and current is
caused to flow through each of the secondary windings in the direction of
arrow A. As this occurs, a portion of the current through winding 62 is
fed back through capacitor 66 and into emitter electrode 63a. As this
happens, transistor 63 is rapidly driven into saturation and the voltage
across primary 64 approaches a constant equal approximately to the level
of the battery voltage. For this condition to be maintained, the flux
produced by primary coil 64 must increase linearly, or, in other words,
current which continually increases in amplitude must be drawn from
battery 40. Since battery current is limited, constantly increasing
battery current is maintained only for a brief duration during which
capacitor 66 is charged with a polarity as shown, and a high voltage pulse
is produced across winding 61 which pulse operates to cause control diode
68 to conduct and to thereby charge firing capacitor 52 while at the same
time charging trigger capacitor 54 through resistor 53 and the primary
winding of transformer 56.
Once battery current ceases to increase, the flux field produced by winding
61 relapses and consequently a voltage of opposite sense is
instantaneously induced across the secondary windings of transformer 60.
When this happens, it is necessary, in order to fully understand the
operation of circuit 59, to consider two conditions which occur. First,
because of the series interconnection between control diode 68 and winding
61, the diode does not conduct and trigger capacitor 54 and firing
capacitor 52 are not charged. Secondly, capacitor 66 discharges through
transistor 63 to thereby cause base current to flow through secondary
winding 62 in the direction of arrow A. As this happens, positive feedback
again occurs through capacitor 66 and the cycle is repeated. The net
result is that a series of positive, repetitive pulses is produced across
winding 61 which repetitively turn diode 68 ON and charge the capacitors
52, 54. The repetition rate of the pulsed signal is selectively controlled
by the value of the elements of circuit 59 and capacitors 52, 54 are
charged to a voltage level, which in accordance with a preferred
embodiment of the invention is approximately 250 volts for the trigger
capacitor and approximately 300 volts for the firing capacitor.
As a safety means for discharging these relatively high voltages from
capacitore 52, 54 on such occasions as when the flash unit operator may
deem it necessary to separate housing portions 32a, 32b for access to the
inside of flash unit 30, there is provided a bleeder resistor 69 connected
in series to a normally open switch 52, the series combination being
connected in parallel across firing capacitor 52. Switch S2 may for
example comprise a resilient conductive strip, one end of which is
connected to resistor 69 and the other end of which is held out of contact
with capacitor 52 by means such as a rigid finger member (not shown)
connected internally to one portion of housing 32. When the housing is
opened, the finger is displaced to permit the conductive strip to contact
capacitor 52 so as to discharge the capacitors 52, 54 through resistor 69
to conductor 65.
The emission of light from flashtube 36 is commenced upon the application
of a voltage signal to trigger electrode 36a. This condition occurs when
SCR 58 is rendered conductive whereby trigger capacitor 54 discharges
through primary 55. As this happens a high voltage trigger pulse, due to
transformer 56, is applied to trigger electrode 36a, which causes some of
the xenon in the tube to be ionized. When this ionization occurs, the
inter-electrode resistance of flashtube 36 is sharply reduced, and firing
capacitor 52 is caused to rapidly discharge through the tube until a
capacitor voltage level hereinafter referred to as the voltage necessary
to sustain conduction is reached. The result is a brief flash, on the
order of a fraction of a millisecond, of high intensity light.
In accordance with the teachings of the present invention, circuit 50
includes an electronic shutter-flash synchronization circuit, denoted
generally 70, operatively coupled between the contacts 34a, 34b of camera
flash-firing mechanism 35 and flash circuit 51 for controlling the firing
of flashtube 36 in synchronism with the opening of the camera shutter
mechanism. Shutter-flash synchronization circuit 70 includes a current
limiting input circuit denoted generally 71, and a voltage-sensitive
indicator such as a neon lamp 72 connected in series with a fixed resistor
74, the series combination forming the branch 75 connected in parallel
across firing capacitor 52. The operational parameters of this series
circuit are selectively controlled such that when firing capacitor 52 is
charged to a level sufficient to properly fire flashtube 36, lamp 72 is
caused to glow so as to be visible through a flash-ready window (not
shown) located in the rear of flash unit 30 to indicate to a camera
operator the flash unit is ready to be fired. Furthermore, when lamp 72
glows, the lamp and resistor 74 operate as a voltage divider with the
voltage signal that appears at terminal 76 operating to supply gate
current to an SCR 77.
SCR 77 in combination with flash-ready lamp 72 constitutes means for
enabling an electronic time delay circuit, described in detail
hereinafter, to be turned ON, once flash circuit 51 is readied for firing,
to accomplish the aforementioned synchronous operation. With this
arrangement, a camera operator who fails to realize firing capacitor 52 is
not sufficiently charged to fire flashtube 36 and who thereby
inadvertently actuates the camera flash-firing mechanism, cannot
unnecessarily cause trigger capacitor 54 to discharge. How this result is
achieved will become readily apparent from the detailed description which
follows.
Connected in series with SCR 77 is a voltage sensitive neon lamp 78, a
variable resistor 80, an SCR 82 and a timing capacitor 84, the
aforementioned components being interconnected so as to form a branch or
series circuit 85 in parallel with the branch 75. The lamp 78 operates as
a current switch with the operational characteristics thereof being
selected so that the lamp 78 ceases to glow when the voltage on firing
capacitor 52 approaches the aforementioned firing capacitor voltage
necessary to sustain conduction. With this arrangement, when capacitor 52
discharges through the flashtube, lamp 78 is caused to turn OFF before
flashtube 36 is extinquished. When the former condition occurs, branch 85
is effectively open circuited and ceases to conduct. This switching
operation is necessary to render branch 85 temporarily non-conductive,
once the flash is triggered ON, to set or initialize the branch 85 for
subsequent flash firings.
The resistor 80 and timing capacitor 84 operate in combination as an
electronic RC delay which induces a delay proportional to the product of
the capacitance and the resistance, which is variable as indicated in FIG.
2.
When shutter release member 15 is actuated under the influence of operator
finger pressure, a flash-firing signal is produced at contacts 34a, 34b,
which signal operates to supply gate current to SCR 82 through input
circuit 71. Assuming firing capacitor 52 is sufficiently charged so as to
turn flash-ready lamp 72 ON and to thereby render SCR 77 conductive, the
gate current causes SCR 82 to turn ON and branch 85 to conduct current. As
this happens, timing capacitor 84 charges at a rate proportional to the
product of resistor 80 and the timing capacitor. As capacitor 84 charges
to a predetermined voltage level, a voltage signal proportional thereto is
produced at terminal 86, which signal is adequate to supply gate current
to SCR 58 and to thereby cause that SCR to conduct. When the latter
condition occurs, substantially the entire voltage across trigger
capacitor 54 is discharged through SCR 58 and across primary coil 55,
which condition initiates a flash as described hereinbefore.
As firing capacitor 52 discharges through flashtube 36, first lamp 72 is
turned OFF, then lamp 78 ceases to conduct, both switching operations
occurring as the firing capacitor voltage drops.
When lamp 78 is turned OFF, branch 85 ceases to conduct current. When this
happens, the voltage across timing capacitor 84 discharges through
resistors 88, 90 and the gate electrode of SCR 58 and circuit 70 is
initialized for subsequent flash firings.
It can be seen that circuit 70 operates to delay the firing of flashtube 36
for a time interval after a flash lamp firing signal is produced, which
time interval is settable according to the resistance value selected for
resistor 80. In a typical situation, this time interval would be on the
order of 10 milliseconds to allow for dynamic delays during shutter
opening movement as well as any time interval which would exist if the
shutter is actuated so as to be opened after the flash-firing circuit is
energized.
Furthermore, it can be seen from the description hereinbefore that due to
the operational interrelationship between flash-ready lamp 72 and branch
85 that the flash lamp firing signal cannot prematurely ionize the xenon
in the flashtube in the absence of adequate voltage across firing
capacitor 52. With the circuitry constituting the instant invention,
battery drain and circuit malfunction from inadvertent flashfiring
operations is eliminated.
It shall be understood that although the schematic circuit shown in FIG. 2
and described herein in association with a camera flash-firing mechanism
for firing a flash lamp with an electrical signal, included within the
scope of the invention are cameras having flash-firing mechanisms 35 of
the type which fire a flash lamp mechanically such as by means of a
percussive flash-firing mechanism. Firing mechanisms of this type have
during the recent past appeared in many commercially available cameras and
are shown and described in several U.S. Patents, one of which is U.S. Pat.
No. 3,661,063 issued to D. E. Beach on May 9, 1972, entitled MECHANISM FOR
SENSING THE CONDITION OF A PERCUSSIVE FLASH DEVICE AND FOR EFFECTING
SYNCHRONOUS PERCUSSIVE FLASH EXPOSURES, and assigned to the assignee of
the instant invention. A percussive flash lamp firing mechanism may
include a high energy lever released from a set position in response to
displacement of a shutter release member, and operates to actuate the
camera shutter and release a flash lamp striker member to percussively
fire the lamp in synchronism with shutter operating movement. To fire an
electronic flash unit with a camera adapted to percussively fire flash
lamps, the striker member may be utilized to close a switch connected to
the flash unit battery and the input terminals to the flash-shutter
synchronization circuit whereby an electrical signal or pulse, similar to
the electrical flash-firing mechanism, is applied to the flash input
contacts 33a, 33b.
In accordance with a preferred embodiment of the instant invention, there
has been described an improved electronic flash unit for cameras adapted
to receive and to fire flash lamps which flash unit accomplishes the
aforementioned objectives.
This invention has been described in detail with particular reference to a
preferred embodiment thereof, but it will be understood that variations
and modifications can be effected within the spirit and scope of the
invention.
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