DE1522200C - - Google Patents

Description

The structural complexity of the exposure time control device should be kept as low as possible.

According to the invention this object is achieved in that the device has a single electromagnet to control both the movement of the mechanical link and the closing process of the closure.

It is advisable to use the exposure time control device according to the invention to design so that the mechanical member can be moved from its tensioned position into a deferred position and that with self-triggering the limb is first released mechanically and then by energizing the electromagnet is blocked, after which there is a connecting the time control circuit with a power source Main switch has closed, and that after the self-timer hold time has elapsed, the magnet is de-energized to switch the circuit from self-timer to exposure control.

In the following the invention is based on an in the embodiment shown in the drawing described; it shows

A b b. 1 is a cross section through the main part of the embodiment,

A b b. 2 and 3 sectional views along the line II and III in Fig. 1,

A b b. 4 to 7 views according to A b b. 2 to explain the individual operating phases,

A b b. 8 a view corresponding to A b b. 3 in another operating phase,

A b b. 9 is a partial view of the arrangement according to A b b. 2 to explain another mode of operation,

Fig. 10 is a partial view of the arrangement according to A b b. 2 of a modified embodiment and

Fig. 11 shows the electrical circuit diagram of the embodiment.

In the drawings, 1 denotes a camera body, 2 the drum shaft of a conventional focal plane shutter (focal plane shutter) and 3 the disk attached to the shaft 2 for the leading membrane portion of the shutter. The disk 3 is provided with an arcuate slot groove 3 α through which a connecting pin 7 extends freely. A release element 4 for the leading diaphragm part is attached to the lower end of the shaft 2. The drum 5 provided for the trailing membrane part of the closure is rotatably mounted on the shaft 2. An intermediate part 6 sits rotatably in the camera body 1 and on the shaft 2. The connecting pin 7 is attached to the upper arm 6 a of the intermediate member 6, is connected to the drum 5 through the groove 3 α and prevents the opposite direction of the shutter with the end part the groove 3 α when the shutter is cocked.

The release element 8 for the trailing membrane part is provided on the lower arm 6 b of the intermediate element 6 and operates on the lower contact piece of a first switch S ₁ .

A winding gear 9 is rotatably seated on the camera body 1 and is connected to a conventional shutter tensioning mechanism (not shown). A control cam 10, which rotates in one unit with the winding gear 9, has an upper and a lower cam surface 10 a and 10 i on the circumference. A pull-up pin 11, which sits on the control cam 10, operates on the upper contact piece of the switch S ₁ and on a lock release lever 14. A spring 12 is provided for rotating the wheel 9 and the cam 10 counterclockwise. A nut 13 holds parts 9 and 10 together. The release lever 14 has a hook-like end part 14a, is rotatably mounted on a pin 15 and is biased by a spring 16 in the counterclockwise direction. He is in the direction of the arrow in A b b. 4 pivoted when the lock is released in a conventional manner. A shift lever 17 is rotatably mounted on a pin 18 and supported by a spring

ίο 19 preloaded counterclockwise. A roller 20 and an isolated pin 21 sit at one or the other end of the lever 17. Here, the roller 20 is pressed against the lower cam surface 10 b of the cam 10, while the isolated pin 21 is on a second and third switch S _{2 and S 2,} respectively. S ₃ works. A stop lever 22 for the release element 4 of the leading diaphragm part is rotatably mounted on a shaft 23 and is biased by the spring 24 in the counterclockwise direction. An eccentric pin 25 is arranged on the stop lever 22 in such a way that it is pressed against the upper cam surface 10 a of the cam 10, the contact position against the cam surface 10 α being set by the eccentricity of the pin 25. A stop lever 26 assigned to the trailing diaphragm part comes into contact with the release pin 8 and the pin 11 and is rotatably mounted on a pin 27, a spring 28 biasing the lever 26 in a clockwise direction.

One end of the stop lever 26 is provided with a beveled surface and is designed so that the lever is pushed up by the release pin 8 and the pulling pin 11 when the magnet M is de-energized, which is provided at the other end. An iron piece 29 is attached to the other end of the stop lever 26 and faces the magnet M. A locking member 30 mounted at 31 has a shoulder 30 a on the circumference. When the approach 30 a _{presses against the switch S 3} , it closes.

Fig. 11 shows the basic circuit diagram. It means C a capacitor, D a photoconductor, e.g. B. a cadmium sulfide cell, E a battery, M the magnet and S ₁ the first switch. The latter is operated as follows:

1. When the bolt is cocked, the pull-up pin 11 and the release pin 8 press the upper and lower ones Contact piece upwards to open the switch (Fig. 2).

2. If the pull-up pin 11 begins to run down, the upper contact piece is released and the switch closes (A b b. 4).

3. When the pull-up pin 11 and the release pin 8 for the trailing membrane part are twisted together the upper and lower contacts are released and the switch opens. This is in A b b. 7th shown with dashed lines.

S ₀ and S ₃ are the second and third switches, respectively. T ₁ and "T., are npn transistors and R ₀ is the delay resistor for the self-triggering. Its resistance value is considerably higher than that of the resistors .R ₁ to R _x still provided.

When the shutter is cocked by the winding wheel 9, the pulling pin 11 and the release pin 8 turn into the positions shown in A b b. 2 positions shown _{to open the switch S 1} and to hold this state

until the circuit is used. Then begins at the time of the lock release, the Pull-up pin 11 by pushing the release lever 14 in 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 _{2 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 106 turns the switching lever 17 clockwise via the roller 20 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 increases to attract thus again earth potential, whereby the transistor T _1, conductive and magnetic M is energized to the the trailing membrane portion associated stop lever 26th Therefore, the switch S _3, when S is opened _0, closed in the position in which the one end of the shift lever 17 drops to the lowest point of the lower cam surface 10b , and the capacitor C is now charged again via the cell D. The charging time now required is mainly due to the resistance value of the cell D, i.e. the brightness of the Therefore, if the capacitance of the capacitor C is appropriately selected in consideration of the expected cell resistance changes, an appropriate exposure can automatically e be achieved.

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 consequence 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 Γ., 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 that time-

z5 point 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 are 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 rotated (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 (6)

ι 2 by the control member (8) in the tensioned position durable Patent claims: are. 7. Device according to claim 5 or 6, there- 1. Electronic exposure time control device characterized in that during the expiry of the metung for a camera shutter with a single 5 mechanical element (10) from its tensioned in umpteen time control circuit for the holding time in the position that has elapsed, its cam surface is self-triggering and for the exposure time, _{one (106) first closes the switch (S 2} ) determining the start of charging of the condenser counter to the action of a spring tensionable meter (C), mechanical element that opens again after actuation of the latter and thereby releases an approximately self-timer electromagnetically at the same time further switch (S ₃ ) closes to switch the circuit automatically from self-control and thereby a determination of the exposure time release control to exposure control switches the resistor (D) into the time circuit,
to switch and to close the shutter after the exposure time has elapsed to be triggered electromagnetically, thereby 15 indicates that the device has a The invention relates to an electronic exposure single electromagnet (M) both for the control time control device for a camera tion of the movement of the mechanical link with a single timing circuit for the end (10) as well as the closing process of the shutter hold time for self-release and for the exposure ses has. 20 time to counteract the action of a spring 2. Device according to claim 1, characterized in that the mechanical member after actuation indicates that the mechanical member (10) is electromagnetically released by the self-timer from its tensioned position to an expired position in order to automatically move the circuit from the self-timer position and that in the case of self-release, the element is mechanically released and then switched to exposure control, and then, after the exposure time has elapsed, the closing process of the shutter is electromagnetically blocked by energizing the electromagnet (M), after triggering the time control switch. It is known that the exposure time by means of the switch (S ₁ ) has closed, and that after the charging time of a capacitor is determined. A deletion of the self-release switching time of the shutter control, which is de-energized according to this principle to operate the circuit of self-zip, is, however, designed in such a way that the sound release can be switched to exposure control. device is on as long as the shutter release button is pressed 3. Device according to claim 2, is thereby. In the case of a short exposure time, it is therefore unnecessarily indicated that the main switch (S ₁ ) consumes electrical power and is opened when the shutter is closed for a long time. 35 exposure time can be the intended exposure time 4. Device according to one of claims 1 can not be achieved if the trigger is too fast to 3, characterized in that the device is released again. For the latter reason Device for controlling the mechanical member (10), the known arrangement is also not suitable for and the closing operation of the shutter, controlling the exposure time, if a self-timer lever (26), which should be provided on a pin (27) rotation control. is mounted bar, with a spring (28) one further a lock control with two ends (29) of the lever (26) in contact with the drive members and two magnets for holding the magnets (M) urges, and the other end of the drive members known, which are controlled by an electronic lever (26) with a sloping surface ver device. Apart from the fact that it can be seen, as well as with a further member (11) 45, the use of two drive members and Maabove the mechanical member (10) and with gneten is expensive, must in the known association control member (8) to control the closing circuit The switch for controlling the electrical operation of the shutter can be brought into contact with the power source manually operated so that the on, whereby the lever (26) against the force of and switching off the power source does not automatically spring (28) through the two members (8 and 11 ) so happens, which in turn leads to unnecessary consumption of when the magnet (M) de-energizes electrical power,
will. . In contrast, the invention has the object to- 5. Device according to one of claims 1, an electronic exposure control device 4, characterized in that cam of the type mentioned using surfaces (10 a, 106) on the mechanical member 55 of the charging time of a capacitor (10) provided are, of which the one (10 b) which does not have the disadvantage set out above, a second switch (S ₂ ) via a switching element and in particular actuates the needs of a (17) which is adapted to the start of charging of a self-release control, the time Capacitor (C) determined, and of which the delay is determined by an electrical circuit (10a) a blocking element (22) acts to open the 60, which is also suitable for actuating the closure (at 4), whereby the backlighting time to be determined automatically. In this case, the lateral relationship of the cam surfaces (10a, 106) is to be created, which is the usual way of compensating for the delay in the mechanical self-release control by means of electrical excitation. to replace trically working self-timer control, 6. Device according to claim 4 and 5, da- 65 where on the one hand the space requirement for the electronic characterized in that the leading mem- exposure time control including the self-burning component a focal plane shutter is reduced by the lock release control and, on the other hand, the free organ (22) and its trailing membrane component speed of the constructive execution is increased.