DE1522200B - Electronic exposure time control device for a camera shutter - Google Patents

Description

The invention relates to an electronic exposure time control device for a camera shutter with a single time control circuit for the holding time for self-release and for the exposure

ao time, a mechanical member that can be tensioned against the action of a spring, which after actuation The self-timer is released electromagnetically to control the circuit automatically by self-timer to switch to exposure control, and to after the exposure time has elapsed to trigger the closing process of the shutter electromagnetically.

It is known to determine the exposure time on the basis of the charging time of a capacitor. One known shutter control, which works on this principle, is designed so that the circuit is on as long as the shutter button is pressed. With a short exposure time is therefore unnecessary consumes electrical power, and if the exposure time is long, the intended exposure time will not be achieved if the shutter button is released too quickly. For the latter reason The known arrangement is also unsuitable for controlling the exposure time, if a self-timer control should be provided.

Next is a shutter control with two drive members and two magnets for holding the Drive members known which are controlled by an electronic device. Besides that the use of two drive members and magnets is expensive, must in the known lock the switch to control the electrical power source can be operated manually so that the and turning off the power source is not done automatically, which in turn leads to unnecessary consumption of electrical power leads.

In contrast, the invention is based on the object of an electronic exposure control device of the type mentioned at the beginning using the charging time of a capacitor, which does not have the disadvantages set out above and in particular the needs of a Self-timer control is adapted, the time delay being effected by an electrical circuit which is also suitable for automatically determining the exposure time. It should So the possibility will be created of the usual mechanical self-timer control by an electrical to replace working self-timer, whereby on the one hand the space requirement for the electronic Reduced exposure time control including self-timer control and, on the other hand, freedom of movement the structural design is increased.

3 4

The structural complexity of the exposure time control unit of the cam 10 is provided in a counterclockwise direction,

direction should be kept as low as possible. A nut 13 holds parts 9 and 10 together.

According to the invention, this object is thereby achieved. The release lever 14 has a hook-like end release, that the device has a single electrical part 14 a, is rotatably mounted on a pin 15 and Magnets both to control the movement of the 5 is pre-mechanical by a spring 16 counterclockwise Limb as well as the closing process tensioned. He is in the direction of the arrow in A b b. 4th of the closure. pivoted when the conventional way

It is recommended that the decision according to the invention be disengaged. A shift lever 17 is on

design exposure time control device so that a pin 18 rotatably mounted and supported by a spring

the mechanical link is biased from its tensioned position 19 in the counterclockwise direction. A role

ment can be moved into an expired position and 20 and an isolated pin 21 sit on one or the other

that in the event of self-release, the link initially mecha- the end of the lever 17. Here, the roller 20

niche released and then by energizing the elec- tron against the lower cam surface 10 b of the cam 10

solenoid is locked, after which it is pressed, while the isolated pin 21 on one

Connect the timing circuit to a power source- 15 second and third switches S ₂ and S _{3 are} working. A

the main switch has closed, and that after the stop lever 22 for the trigger element 4 of the previous

The end of the self-triggering dwell time of the diaphragm component can be rotated on a shaft 23

gnet is de-energized to switch the circuit from self-releasing and is counterclocked by the spring 24

to switch to exposure control. biased clockwise. An eccentric pin 25 is on

In the following, the invention is arranged on the basis of a stop lever 22 in 20 so that it against

In the embodiment shown in the drawing, the upper cam surface 10 a of the cam 10 is pressed

wrote; it shows, with the contact position against the cam

Fig. 1 shows a cross section through the main part of the surface 10 a through the eccentricity of the pin 25 a

Embodiment, is provided. One of the trailing part of the membrane

A b b. 2 and 3 sectional views along the line II 25 arranged stop lever 26 comes into contact with

or III in A b b. 1, the trigger pin 8 and the pin 11 and is on one

A b b. 4 to 7 views according to A b b. 2 rotatably mounted on pin 27, a spring 28 den

Explanation of the individual operating phases, lever 26 pretensioned in a clockwise direction.

A b b. 8 a view corresponding to A b b. 3 in a one end of the stop lever 26 is with a

other operating phase, 30 beveled surface provided and designed so that

A b b. 9 is a partial view of the arrangement according to the lever when the magnet M is de-energized, the other

A b b. 2 to explain another mode of operation, which is provided by the trigger pin 8 and

Fig. 10 is a partial view of the arrangement after the pull-up pin 11 is pushed up. An iron

A b b. 2 of a modified embodiment and piece 29 is at the other end of the stop lever 26

Fig. 11 the electrical circuit diagram of the execution 35 attached and faces the magnet M. A

form. at 31 mounted locking member 30 has an approach

In the drawings, 1 means a camera body 30 a on the circumference. If the approach 30 a against

2 presses the drum shaft of a conventional burning switch S ₃ , it closes,

level lock (focal plane shutter) and 3 the A b b. 11 shows the basic circuit diagram. It means C

on the shaft 2 attached disk for the leading 40 a capacitor, D a photoconductor, z. Legs

Membrane part of the closure. The disc 3 is a cadmium sulfide cell, E is a battery, M is the magnet

provided with an arc slot groove 3 α through which a th and S ₁ the first switch. The latter will like

Connecting pin 7 engages freely through it. A pressed follows:

Release element 4 for the leading part of the membrane is 1. When cocking the lock, press open

attached to the lower end of the shaft 2. The one for the 45 pull pin 11 and release pin 8 the upper and lower

trailing diaphragm part of the closure in front of the contact piece depending on the top to open the switch

The drum 5 shown is rotatable on the shaft 2 (Fig. 2).

camps. An intermediate part 6 is rotatably seated in the camera 2. If the pull-up pin 11 begins to run down, it will

body 1 and on the shaft 2. The connecting pin 7 released the upper contact piece, and the switch

is on the upper arm 6a of the intermediate link 6 closes (Fig. 4).

solidifies, is with the drum 5 through the groove 3 a. 3. When the pulling pin 11 and the release pin 8

through connected and prevents the opposite - twisted together for the lagging part of the membrane

The upper and lower contact pieces will be the upper and lower contact pieces

3ö when the lock is cocked. released, and the switch opens. This is in A b b. 7th

The trigger member 8 for the trailing mem- 55 shown with dashed lines,
br component is on the lower arm 6 b of the intermediate link 6 S ₂ and S ₃ are the second and third switches. T _{1 is} provided and operates on the lower contact piece and T ₂ are npn transistors and R ₀ is the club's first switch S ₁ . delay resistor for self-triggering. His

A winding gear 9 rotatably sits on the camera resistance value is considerably higher than that of the

body 1 and is with a conventional resistor 60 still provided resistors R ₁ to R ^.

locking mechanism (not shown) connected.

the. A control cam 10, which is clamped in one unit, the pulling pin 11 and the release

with the winding gear 9 rotates, has pin 8 on the circumference in the in A b b. 2 positions shown to the

an upper and a lower cam surface 10 a or switch S ₁ to open and to keep this state

10 b. A pull-up pin 11 on the control cam 65 th until the circuit is used. Then begins

10 sits, works on the upper contact piece of the at the time of the lock notch, the

Switch S ₁ and on a lock release lever pull-up pin 11 by pressing the release lever 14 in

14. A spring 12 is to rotate the wheel 9 and direction of the in A b b. 2 shown arrow released.

ben will rotate the cam 10 counterclockwise due to the spring 12, and the upper contact piece of the switch S ₁ and the receiving pin 11 are separated. The switch S ₁ closes to excite the magnet M. But since the switches S ₂ and S _{3 are} open, the capacitor C is charged via the delay resistor R ₀ . The rotation of the control cam 10 leads to a stop of the pulling pin 11 on the inclined surface of the locking lever 26. The latter does not evade because the magnet M is excited (A b b. 4). The charging time of the capacitor C can be extended sufficiently by increasing the resistance R ₀ accordingly. This resistance therefore determines the hold time of the self-timer.

After a predetermined period of time (through R ₀ ) has elapsed, during which the charging voltage across the capacitor C has increased to a predetermined value, a signal current flows to the left transistor T ₁ , and this becomes conductive. Therefore, the emitter potential of the right transistor T _{1 is} increased and the base potential is reduced, whereby this transistor switches off and the magnet M is de-excited. The stop lever 26 for the trailing diaphragm part, the inclined surface of which has previously stopped the pulling pin 11, can now be pushed up by the latter, and the control cam 10 starts rotating again. The lower cam surface 10 δ turns the switching lever 17 clockwise via the roller 20 in order to close the switch S ₀ (A b b. 5). As a result, the capacitor C is discharged again to the voltage zero. The base of the transistor T ₁ thus again assumes ground potential, whereby the transistor T _{2 is} conductive and the magnet M is excited in order to attract the stop lever 26 assigned to the trailing membrane part. Therefore, as soon as S _{2 is} opened, the switch S ₃ is closed in the position in which one end of the switching lever 17 drops into the lowest point of the lower cam surface 10 b , and the capacitor C is now charged again via the cell D. The charging time now required is mainly determined by the resistance value of cell D, ie by the brightness of the object. Therefore, if the capacitance of the capacitor C is appropriately selected in consideration of the expected cell resistance changes, an appropriate exposure can be achieved automatically.

The rotation of the control cam 10 presses (see A b b. 7) with the upper cam surface 10 a the locking lever 22 of the leading diaphragm part through the eccentric pin 25 upwards (it should be noted that the result of the individual processes by the design of the lock is determined and can be changed by correcting the delay of the magnet excitation.)

The trigger element 4 of the leading membrane part

ίο is therefore released, the assigned to this Disk 3 starts rotating counterclockwise and exposure begins. The drum 5 of the trailing membrane portion begins to rotate in an associated manner to rotate the disk 3.

But since the release pin 8 by the inclined surface of the stop lever 26 of the trailing member is prevented, the drum 5 is stopped in this position.

When the voltage of the capacitor C has increased to the predetermined value, the transistor T ₁ becomes conductive and the transistor T ₀ is blocked to de-energize the magnet M. The release pin 8 can therefore push the lever 26 up and stop the exposure while continuing to turn. At this point in time, the lower contact piece of switch S _{1 is} released (dashed lines in Fig. 7) and switch S ₁ switches off the current.

Of course, it is possible to change the holding time of the self-triggering selectively by the delay resistor R ₀ is configured as a variable resistor and it can (s. Fig. 10 and 11), a fourth switch S ₄ is provided on the side of the delay resistor .R ₀ which can be actuated coupled with the switching of the switch S _3.

If the self-release is not used, the locking member 30 is turned (A b b. 9) in order to _{permanently close the switch S 3} , or the resistor R ₀ , which is coupled to the switch S ₄ (Fig. 11) , designed as a variable resistor in order to bring the resistance value to the smallest value.

Provision can also be made for a predetermined exposure value to be set by hand, in that a variable resistor is provided in place of the photoconductive cell D.

The principle of the invention can not only apply to a focal plane shutter (focal plane shutter), but can also be used with a lens shutter.

1 sheet of drawings

Claims (7)

Patent claims: 1. Electronic exposure time control device for a camera shutter with a single Time control circuit for the hold time for self-release and for the exposure time, one against the action of a spring tensionable mechanical member, which after actuation of the Self-timer is released electromagnetically to control the circuit automatically by self-timer to switch to exposure control and after the exposure time has elapsed to trigger the closing process of the shutter electromagnetically, characterized in that, that the device uses a single electromagnet (M) both to control the movement of the mechanical link (10) as well as the closing process of the closure. 2. Device according to claim 1, characterized in that the mechanical member (10) can be moved from its cocked position into an expired position and that, upon self-triggering, the member is first mechanically released and then blocked by energizing the electromagnet (M) after it _{has closed a main switch (S 1} ) connecting the timing control circuit to a power source, and that after the self-timer switching time has elapsed, the magnet is de-energized in order to switch the circuit from self-timer to exposure control. 3. Device according to claim 2, characterized in that the main switch (S ₁ ) is opened during the closing process of the shutter. 4. Device according to one of claims 1 to 3, characterized in that the device to control the mechanical member (10) and the closing process of the shutter a Has lever (26) which is rotatably mounted on a pin (27), a spring (28) the one End (29) of the lever (26) in contact with the magnet (M) urges, and the other end of the Lever (26) is provided with a beveled surface, as well as with another link (11) above the mechanical member (10) and with a control member (8) for controlling the closing process of the closure can be brought into contact, whereby the lever (26) against the force of The spring (28) is pivoted by the two links (8 and 11) when the magnet (M) is de-energized will. 5. Device according to one of claims 1 to 4, characterized in that cam surfaces (10 a, 10 b) are provided on the mechanical member (10), one of which (10 b) has a second switch (S ₀ ) via a Switching element (17) is actuated, which determines the start of charging of a capacitor (C), and of which the other (10 a) actuates a locking element (22) to open the shutter (at 4), the mutual relationship of the cam surfaces (10 a, 10 b) is set to compensate for the delay in magnet excitation. 6. Device according to claim 4 and 5, characterized in that the leading membrane portion a focal plane shutter through the locking member (22) and its trailing membrane part can be held in the clamping position by the control member (8). 7. Device according to claim 5 or 6, characterized in that when the mechanical member (10) expires from its tensioned to the expired position, the cam surface (10 b) first the start of charging of the capacitor (C) determining switch (S ₂ ) closes, then opens it again and closes another switch (S ₃ ) almost at the same time and thereby switches a resistor (D) that determines the exposure time into the timing circuit.