DE1930898C3 - Programmed shutter - Google Patents

Description

The invention relates to a programmed shutter according to the preamble of claim 1.

In known shutter locks of this type, a tensioning member is provided which must be actuated after the shutter has been released in order to bring the escapement and the closing drive member back into the tensioned position. In this case, it is considered disadvantageous that a ^ ⁰ actuation of the tensioning member is required by the user.

It is also already a tensioning and release device known for a lens shutter (DT-AS 14 086), in which by changing the direction of rotation an actuating ring, the cocked lock can be triggered, which is why it is also with this lock is required, the closure by a manu

to tension all actuation.

It is therefore the object of the invention to provide a conclusion of the aforementioned; Kind of verbes like that That the shutter is automatically cocked when the shutter release is released after the shutter has been released This object is achieved by the characterizing features of claim 1 Advantageous further developments of the invention are the subject matter of the subclaims.

Particular advantages of the invention are in addition to a relatively simple construction of the required mechanism to be seen in it, if such a! Shutter is provided in a camera in which the film is transported with the aid of a drive motor

With reference to the drawing, the invention is intended for example are explained in more detail. It shows

F i g. 1 is a view of an embodiment; Closure according to the invention in the tensioned state,

F i g. 2 a fig. 1 corresponding view after the release of the lock and the start of the opening movement,

F i g. 3 is a rear view of a circuit board for the mechanism in FIG. 1 and 2 and

F i g. 4 is a circuit diagram of the associated electrical circuit.

In the case of the FIG. 1 and 2, a mounting plate 1 is provided, on which pins 3, 4 are arranged, which serve to guide a trigger 2 provided with guide tips. The trigger 2 has a part 2a on which in FIG. 1, an arm 6a of an intermediate link 6 is applied, which is hinged to a pin 10 and is biased clockwise by a spring 11. The intermediate member 6 engages with an arm 6b on a pin 13 of a tooth segment 12 of an escapement mechanism 23,24,25. The intermediate member engages with a part 6c on a ratchet lever 7, which can be pivoted downwards around a pin 15 against the action of a spring 16 by a projection 2b on the trigger 2. A pin provided on the intermediate member 6 is used to open the contacts 54, 55 of a timing switch.

The toothed segment 12 of the escapement mechanism is hinged to a base plate 17 with a pin 18 and is biased clockwise by a spring 19. 1, the arm % b of the intermediate lever engages a pin 13 on the toothed segment in order to prevent it from rotating. The toothed segment 12 is provided with a cam surface 12a which engages a pin 22 of an opening and closing lever 21 which is hinged to a pin 20 on the base plate of the escapement mechanism. The toothed segment 12 meshes with a pinion 23, and a steering wheel 24 is in engagement with an armature 25. An arm 21a of the ring lever 21 rests on a pin 28 of a sector ring 27 in order to open and close the sectors 26. Another arm 216 of the lever 21 lies in the movement path of a pin 30 on a drive closing member 29. A spring 31 engages a pin 28 on the sector ring 27 so that the sector ring is rotated counterclockwise in the opening direction when the cam surface 12a of the tooth segment 12 after release by the intermediate member 6 allows a rotation of the lever 21.

The drive locking member 29 is mounted on a pin 32 on the base plate 17 and by a spring

33 biased clockwise On the closing drive member 29, a pin 30 is provided, on which an arm 8a of an adjusting lever 8 engages, which is hinged to a pin 34 and is biased by a celebration 35 in the counterclockwise direction. With a part 2c on the trigger 2, the adjusting lever 8 can be pivoted clockwise when the trigger is actuated.

The closing drive member 29 is provided with cam surfaces 29a to J9e, the stops for arms 36a, 366 a control lever 36 form. The control lever 36 is hinged to a pin 37 on the base plate 17 The control lever has an armature 38 at the right end, which is attracted by an electromagnet 39.

A locking lever 40 is articulated on a pin 41 and biased clockwise by a spring 42. An arm 40a of the locking lever 40 rests on the pin 30 of the locking drive member 29, while the other arm 40b in the tensioned state in the path of movement of an arm 8c on the Adjusting lever 8 is.

F i g. 3 shows a circuit board 50 with contacts 51, 52, 53 which correspond to the contacts 9a, 96, 9c of a contact piece 9 (Fig. 1) are assigned to the trigger. F i g. 3 also shows the timer switch with the contacts 54 and 55. Openings 56, 57, 58 serve to receive the pin 3, the pin 10 and the pin 15 in Fig. 1.

The in F i g. 4 includes a voltage source 60, a first transistor fit, a circuit shown second transistor 62, an electromagnet 63, a three-pole CdS photoresistor 64, a capacitor 65, variable resistors 66 and 67, a fixed resistor 68 and a correction resistor 69, as well as the Contacts 9a to 9c of the contact piece 9 and the corresponding contacts 51, 53 and the contacts 54, 55 of the timer switch.

The method of operation will be explained in more detail below. If the trigger is contrary to the action of the Spring 5 is pressed down, the contact 9a touches the contact 51, so that an exposure measurement is carried out. Whether the first transistor 61 is blocked or conductive depends on its base potential, which is determined by the Resistance value of the photoresistor 64 and the variable resistor 65 is determined. When the object brightness is low, is the resistance value of the photoresistor 64 high, so that the base potential is low and therefore the transistor 61 is non-conductive during the second transistor 62 is conductive and the electromagnet 63 is excited. Therefore then becomes the anchor 38 (Fig. 1) is attracted by the yoke 39 of the solenoid. By further depressing the shutter release 2, the part 2c of the trigger pivots the arm 86 of the actuating lever 8 so that it is clockwise is pivoted. When the adjusting lever 8 is pivoted, the closing drive link 29 rotates clockwise due to the action of the spring 33. The cam surface 29a then strikes against the arm 36a of the control lever 36, which is not pivoted because of the attraction of the armature 38 by the electromagnet, so that the closing drive member 29 is stopped in a slightly rotated clockwise position. Accordingly the locking lever 40 is stopped in a somewhat clockwise pivoted position because the arm 40a of which rests against the pin 30. The arm 406 then remains in the pivoting range of the arm 8c on the Adjusting lever 8, so that in this position the trigger 2 cannot be depressed any further.

In contrast, when the object is bright, there is resistance of the resistance is relatively low, so that the transistor 61 is conductive and the transistor 62 becomes non-conductive and no current flows through the electromagnet 63, which is why the control lever 35 is versciiwenki can be. Therefore, by further depressing the trigger 2, the adjusting lever 8 is turned clockwise pivoted so that the locking drive member 29 can oxehen clockwise and its Curved surface 29a the arm 36 ^ of the control lever 36 pivoted when the trigger is further depressed 2, the contacts 9c and 53 come into contact, so that the first transistor 61 is non-conductive and the second transistor 62 becomes conductive and a current flows through electromagnet 63 in this position can

Is the control lever 36 not counterclockwise because of the attraction are pivoted by the electromagnet, as a game between the armature 38 and the yoke 39 of the electromagnet is present

If the trigger 2 is depressed further,

jo, the closing drive member ¹ 29 rotates further clockwise, and the cam surface 296 presses against the arm 366 to pivot the control lever clockwise so that the armature 38 closes the yoke 39 of the electromagnet, whereby the play is reduced,

: tS so that the control lever 36 cannot be pivoted because of the attraction by the electromagnet. A clockwise rotation of the cam disk 29 is prevented by a movement of the cam surface 296 which engages the arm 366 of the control lever 36. On the other hand, the one engaging the pin 30 becomes Lock lever 40 pivoted clockwise. Since the panning is greater than with low object brightness is the arm 406 moves out of the pivoting range of the arm 8c of the adjusting lever 8, so that another Depressing the trigger 2 is no longer obstructed. If then the trigger 2 is depressed further is, the projection 26 pivots the ratchet lever 7 so that the engagement with the intermediate member 6 is canceled and the intermediate member 6 is pivoted clockwise by the action of the spring 11 will. When the intermediate member 6 is pivoted, the toothed segment 12 is due to the effect its spring is rotated clockwise so that the climbing wheel 24 is rotated to which the armature 25 is attached.

engages. The sector ring 27 is then under the action of the spring via the pin 28, the lever 21 and the pin 22 31 rotated counterclockwise according to the scanning of the cam surface 12, so that the sectors 26 open. During this movement, the pin 14 opens

the intermediate element 6, the contact 54 of the timing switch, so that the capacitor 65 is charged via the photoresistor 64. The result is then that shown in FIG. 2 position shown.
As soon as the charging voltage of the

capacitor 65, the transistor 61 is conductive, the transistor 62 is non-conductive, so that the electromagnet 63 is no longer aroused. The control lever 36 is then pivoted counterclockwise, and the lock drive member 29 rotates clockwise on the ground

the action of the spring 33. The pin 30 then strikes the arm 216 on the lever 21, so that this in the Is pivoted counterclockwise and the sector ring 27 clockwise against the action of the Spring 31 rotates and the locking sectors 26 are closed again.

After the end of the exposure and release of the shutter release 2, the spring 5 moves it upwards postponed. The arm 2a then moves the arm 6a

on the intermediate member 6 in order to pivot this clockwise, while the other arm 6b rotates the toothed segment 12 in the clockwise direction through the stop on the pin 13. The contact 54 of the timer switch then contacts the contact 55 again, and the S pawl lever again engages the projection 6c on the intermediate member 6. The arm Sa on the actuating lever 8 is pivoted counterclockwise during the return movement of the trigger 2, so that it engages the pin 30 on the closing drive member 29 in order to rotate it counterclockwise against the action of the spring 33. This rotary movement is stopped in a position when the cam surface 29e strikes against the arm 36a, because the timer switch is closed and the transistor 61 is blocked and therefore the transistor 62 is conductive, so that the electromagnet is excited and the control lever Ii does not pivot any further counterclockwise can be. Regardless of this, however, the trigger 2 can move back into its starting position. When the contact 9a is lifted from the contact 51, the voltage source is switched off so that the electromagnet is no longer excited, which is why the control lever 36 can rotate in the counterclockwise direction. The closing drive member 29 is then turned counterclockwise by the adjusting lever 8 into the position shown in FIG. 1 shown tensioned position turned back.

For this purpose 3 sheets of 2 drawings

Claims (3)

Patent claims: 1. Programmed 'shutter with an electromagnet containing Beiichtungsteu- S circuit, with an inhibitor to control the opening movement of the shutter sectors, with a controllable by the electromagnet closing drive member, and with a spring preloaded in its initial position trigger> ° water, thereby characterized in that between a part (2a) of the trigger (2) and the inhibitor (12, 23 ", 24, 25) a pivotable intermediate member (6) is arranged that when the trigger (2) is pressed down, the inhibitor passes through the intermediate member (6) is released and when the trigger is moved back after the shutter has been released, it is tensioned via the intermediate member (6), and that between a part (2c) of the trigger and the closing drive member (29) an adjusting lever (8) which is pre-tensioned by a spring (35) is arranged in such a way that when the trigger (2) is pressed down after the escapement has been released, the closing element (29) is pivoted by pivoting the adjusting lever (8) against the action of which the spring (35) is released and is tensioned during the return movement of the trigger after the shutter has been released by pivoting the adjusting lever (8) by its spring (35). 2. Programmed shutter according to claim 1, characterized in that in the path of movement of a part (2b) of the trigger a pawl lever which locks the intermediate member (6) and is biased by a spring (16) into the locking position (7) is arranged, and that when pivoting the intermediate member (6) by a provided thereon Projection (14) of the switches (54, 55) short-circuiting the capacitor (65) of the timing circuit is opened. 3. Programmed shutter according to claim 1 or 2, characterized in that the Control lever (8) engages on a pin (30) on the closing drive member (29), and that on the pin (30) a locking lever preloaded by a spring (42) for the adjusting lever (8) in the opposite direction engages, so that on the return movement of the trigger, the locking lever (40) by the adjusting lever (8) in the tensioned starting position is pivoted.