DE3011693C2 - Lock for a single-lens reflex camera - Google Patents

Description

The invention relates to a shutter for a single-lens reflex camera.

So far, as a drive source to achieve the Expiration of the shutter curtains of a camera shutter ses generally a spring use. On the other hand exists recently with the advancing electro equipment of cameras predominantly the tendency the exposure setting, the photographic tax electrically controlled run and the like. Since also with the very much electronics equipped cameras the ver final drive system is still mechanically constructed, appears from the point of view of "electronization" the whole structure of such a camera is so complicated as before. To simplify this complicated structure has already been proposed, the closure electro magnetically driven.  

When using an electromagnetic drive source in a camera through which the shutter of electro magnetic forces are driven or actuated, there is of course no need for movable mechani various types of parts as in the case of conventional ones Having to use cameras, causing the camera to open construction can be simplified considerably.

With regard to the attachment of an electrical Energy source inside the camera body difficult however, that is only available to a limited extent Space the use of a battery with the most required large capacity and thus large dimensions sung. For this reason, the shutter curtains and their drive and actuation devices if possible be easily constructed with their moving parts have to work with as little friction as possible, so that an electromagnetic drive source with low Dimensions that a lower electrical Stromver needs, can be considered. At Consideration or fulfillment of these demands however the camera is significantly sensitive to shock, because when a shock occurs in the ready to run Starting position of the shutter curtains for an exposure they are accidentally set in motion and thereby unintentionally exposing the film lead or a control switch for the power supply the electromagnetic drive source is faulty is done, with the result that the closure or closures drapes run off.  

A closure with the features of the preamble of patent Claim 1 is known from the publication JP 49- 19821A. This known closure has a reset mechanism for returning the first operating lever and of the second operating lever in their starting positions, the take them before starting an exposure. To reset Mechanism belongs to a control section that for the purpose of return rens of the two operating levers in a stationary, first position tion is rotated. A first comes during this rotation Contact section of the control part in contact with the first Actuating lever so that this ge in its starting position is brought, and comes a second contact portion of the tax issued in contact with the second operating lever so that this is also brought into its starting position. In its starting position is the first operating lever held locked by a locking lever, and also the second operating lever is in its starting position held by a second locking lever. While the control part is in its resting, first position thus both the first operating lever and the second Operating lever in each of their starting positions This lock does not exist and is released, wah rend the control part in its second position. While the control unit is in its first position, it is not standing in contact with the first operating lever and the second Operating lever.

If an exposure is to be made, will be the same in time with the swiveling of the swivel mirror in its out of the optical exposure path retracted position the control part from his first position to his second position moves. The control part releases the first during this movement Locking lever from its engagement with the first actuator supply lever, so that the locking of the first actuation bels is released and the leading slats can run off nen. After a given exposure time, enters Electromagnet free the second locking lever so that  this from its engagement with the second operating lever can be solved and then the trailing curtain can run.

Although the two actuators in this known closure lever are locked in their home positions while the control unit takes its first position, it can under under certain circumstances incorrect exposures still occur. At for example if due to an action on the camera Push the second locking lever out of his for a short time Engagement with the second operating lever would be released the latter begin a clockwise movement and cannot be locked again. This would be the case later Release of the lock cause the trailing Curtain immediately the movement of the leading curtain would follow without ver the desired exposure time strokes.

The invention has for its object the generic to further develop the closure so that an example malfunction of the shock caused by external shocks Closure is prevented.

This object is achieved according to the invention by the closure Claim 1 solved. With this the control part is independent depending on the reset mechanism and it stands in its first position in direct contact with both first actuation lever as well as with the second actuation lever, so that the control part itself a common locking forming part for the first and second actuating levers. As long as the control unit is in its first position, Therefore, the two operating levers can neither be complete still perform a partial sequence movement.  

Further developments of the invention are in the Unteran sayings marked.

The invention is described below using exemplary embodiments with reference to the drawing described in more detail.

Show it:

Fig. 1 is an exploded perspective view of a first embodiment of an execution according to the invention be stalteten closure,

Fig. 2 is a perspective view showing the particulars of the closure of FIG. 1 and an electromagnetic drive source illustrated

Fig. 3 is a partly in the form of a block diagram executed electrical diagram of a control circuit for controlling the closure according to Fig. 1,

Fig. 4 is an exploded perspective view of a second Ausführungsbei game,

Fig. 5 is a control circuit for the off operation example according to FIG. 4,

Fig. 6 is an exploded perspective view of a third embodiment example, and

Fig. 7 shows a third embodiment of the control circuit.

In Fig. 1, reference numeral 1 denotes a winding axis which rotates together with a transportation lever of the camera (not shown) and having a fixed at its lower end cam 2. The reference numeral 3 denotes a lever pivotable about an axis 3 b, which is provided with a pin 3 a and carries a fixedly attached cam follower 4 which engages with the cam disk 2 . The reference numeral 5 designates a for tensioning a diaphragm and mirror drive mechanism mus serving lever, which is pivotable about an axis 5 c and interacts via a (not shown) inter mediate member with the pin 3 a. A pin 5 b fixedly attached to the end of the lever 5 is engaged with an arm of a tensioning lever 60, which will be described in more detail below. The reference number 10 denotes a release device from the camera, which has an electromagnet 8 with a permanent magnet 9 . 8 a denotes an armature carried by a carrying lever 7, which is attracted by the electromagnet 8 . The reference number 6 denotes a trigger signal lever, which is attached to a common axis 7 b of the carrying lever 7 , so that the two levers can rotate together. With 7 a spring is referred to, which acts on the armature 8 a to achieve a movement away from the electromagnet 8 . 6 b is a pin referred to, which is fixedly attached to the trigger signal lever 6 and a fixedly attached to the connecting lever 5 mounted a leaf spring 5 is engaged. In addition, a pin 6 a is fixedly attached to the lever 6 , which is in engagement with an arm 11 b of a release lever 11 .

The release lever 11 is pivotable or rotatable about an axis 11 d, its opposite end part 11 c being fork-shaped and having a rear end piece of a locking lever 12 rotatable about an axis 12 a. The reference numeral 13 designates a drive lever which is pivotable or rotatable about an axis 13 e and, when rotated in the counterclockwise direction, clamps a diaphragm drive spring 13 a. The drive lever 13 has an end part 13 c, which can be brought into engagement with a hook-shaped end part of the locking lever 12 and can thereby be locked in the tensioned state.

Reference numeral 15 denotes a diaphragm drive lever which is pivotable or rotatable about the axis 13 e, wherein an angled section 15 b of one arm engages with a pin (not shown) for automatic aperture control of a lens. In the middle of an arm of the drive lever 13 , a pin 14 c is fixedly attached, by means of which an intermediate or connecting lever 14 is rotatably held, which is biased by a spring 14 a for a clockwise rotation to the opposite end 15 a of Aperture drive lever 15 to engage. With 15 c, a spring is referred to, which forces the diaphragm drive lever 15 in a direction in which it engages with the intermediate lever 14 . The clamping lever 60 is rotatable or pivotable about an axis 60 d, one arm 60 c with a pin 5 b of the connecting lever 5 being in a grip, while the free end 60 b of a pin 60 fixedly attached in the middle of this arm a with an arm 13 b of the drive lever 13 is engaged, thereby taking place in the clockwise rotary motion of the dung Verbin lever 5 for tensioning the spring 13 a to the drive lever 13 is transferable. The release lever 11 is biased by a spring 7 with respect to a weaker spring 11 a in the counterclockwise direction, one arm 11b set with the pin 6 a of the trip signal lever 6 is engaged.

The reference numeral 17 denotes an automatic aperture signal lever, which is rotatable or pivotable about an axis 17 a and one with a lever 14 located on the intermediate lever 14 b engaging arm 17 c and a return with the lower end of a mirror Signal lever 30 has another arm 17 b in engagement. Reference numeral 16 denotes an impact that limits the range of motion of the drive lever 13 .

The reference numeral 18 denotes a mirror drive lever, which is rotatable about a stationary axis 18 d and at its lower end part engages with an arm 13 d of the drive lever 13 , its upper end part having a bent section with which a drive source for one Swivel mirror in the form of a mirror drive spring 18 a is connected. On the lower arm of the mirror drive lever 18 , an axis 18 c is fixedly mounted on which a locking lever 23 is pivotally mounted. The locking lever 23 is biased by a spring 23 a for movement in a clockwise direction and has at its free end a hook 23 a, which can be brought into engagement with a latch portion 22 b of a mirror flip-up lever 22 rotatable about the axis 18 d.

The reference numeral 24 denotes an intermediate lever rotatable about an axis 24 c, the section with a pin 25 a of a mirror support plate 25 engaging Endab 24 b and a pin 24 a firmly attached to its opposite arm and with an arm 22 c of the mirror - Folding lever 22 is engaged. The reference number 26 denotes an axis of rotation, while the reference number 27 denotes the pivoting mirror.

An arm of the mirror drive lever 18 is provided with a projection 18 b, the portion of a switch actuating lever 51 can be engaged with a lower free end. The switch operating lever 51 is rotatable or pivotable about an axis 51 c and is pre-tensioned by a spring 51 a for movement in a counterclockwise direction, its opposite arm 51 b being arranged such that it touches one of the contact elements to stop the termination Mirror flip-up movement monitor the normally open signal switch 29 closes this switch. In addition, the arm 51 b can engage on its underside with the upper end of a plate-shaped control part 34 described below.

In addition, on the axis 51 c a provided for the rear shutter curtain signal lever 52 is pivotally mounted, which has an arm 52 a with an actuating lever for the rear shutter curtain, which will be described in more detail below, and an opposite arm 52 b, which has a End 30 a of the mirror return signal lever 30 is engaged. The mirror return signal lever 30 is pivotally mounted on an axis 30 f, a pin 30 b fixedly attached to one arm of the lever being in engagement with the opposite arm 23 b of the locking lever 23 . Reference numeral 41 denotes a shutter base plate that is provided with a display window 41a, while the reference numeral 42 has a leading or front curtain and reference numeral 43 a trailing or rear curtain call.

As shown in Fig. 2 in detail, the front shutter curtain 42 consists of three opaque thin slats 42-1 , 42-2 and 42-3 , articulated by pins 42 a to 42 f with two actuating levers 36 and 36 'a related party and are arranged such that they move along the shutter base plate 41, whereby the Bildfen edge 41 a is opened and closed. The operation lever 36 'is on one located on the shutter base plate 41 axle 36' mounted 'pivotally, while the operating lever 36 is mounted firmly on a drive shaft 35 of an electromagnetic drive source 67 for the front curtain and is supported by the shutter base plate 41 so that it together is rotatable with the drive shaft 35 .

The rear shutter curtain 43 consists of three similar thin slats 43-1 , 43-2 and 43-3 , which are articulated via pins 43 a to 43 f with actuating levers 38 and 38 'and are arranged such that they resemble the picture window in a similar manner How to open and close the front shutter curtain.

The actuating lever 38 'is pivotally mounted on an axis 38 a located on the closure base plate 41 , while the actuating lever 38 is fixedly attached to a drive shaft 37 of a (not shown) electromagnetic drive source for the rear closure curtain and can be pivoted by the joint rotary movement with the drive shaft 37 is.

The electromagnetic drive source 67 comprises a frame 65, a fixed to a portion fixed to the frame 65 permanent magnet 62 and a mag- nets around the Perma 62 rotatable reel 66, the fixed to the coil 66 drive shaft 35 in provided in the frame 65 provided for fitting holes 65 a and 65 b is rotatably held. Reference numeral 61 denotes a yoke arranged around the coil 66 and fixedly attached to the frame 65 . Although only the electromagnetic drive source for the front shutter curtain is shown in FIG. 2, the electromagnetic drive source for the rear shutter curtain has a similar or identical structure. These electromagnetic drive sources form a rotary drive mechanism for the slats of the two shutter curtains. If the coil of the respective electromagnetic drive source is supplied with current, the associated drive shaft 35 or 37 rotates within a predetermined range lying within 180 °, as a result of which the actuating levers 36 and 38 are driven or adjusted and who the front and rear shutter curtain in their Move drain positions.

As can be seen again in FIG. 1, a return lever or arm 35 a serving for resetting the closure is fixedly attached to the free end of the drive shaft 35 for the front closure device, with an arm 22 a of the mirror fold-up lever 22 in Intervention can occur. The mirror flip-up lever 22 and the arm 22 a thus form a reset mechanism for the shutter curtains.

The reference numeral 34 denotes a plate-shaped control part, which is slidably attached to the closure base plate 41 and is biased by a spring 34 a for an upward movement (according to FIG. 1). With 34 b, a first contact section is referred to, which engages with a pawl section 36 a of the first actuating lever 36 for the front closure curtain, while with 34 c, a second contact section is referred to, with a pawl part 38 a of the second actuating lever 38 for the rear Locking curtain engages. When the closure according to Fig. 1 is reset to the initial position and movement for the Ablaufbe ready, the front Verschlußvor closes hang the picture window 41 a, while the rear shutter curtain is moved out of the image window. Here, the rear shutter curtain is prevented from a further upward movement by a stop member (not shown), while the front shutter curtain bumps with its uppermost lamella 42-3 via a hump (not shown) against the lamella 43-1 of the rear shutter curtain and is prevented from further upward movement. Incidentally, the shutter curtains 42 and 43 are prevented from moving downward from the positions shown in Fig. 1 by engagement of the control part with the operating levers. The control part thus forms a common locking part for the first actuation lever 36 and the second actuation lever 38 . This locking thus ensures that no erroneous triggering can occur even due to a shock or an accidental application of current to the coil.

In Fig. 3, an electrical circuit diagram is Darge shows an embodiment of a control circuit for controlling the operation of the closure shown in FIGS. 1 and 2. In Fig. 70, reference numeral 70 denotes a photo-element (silicon photocell) while the reference numeral 71 designates an operational amplifier, which represents a preamplifier for the switched between its two inputs photoelement 70, wherein a logarithmic signal compression serve de diode 72 in a feedback path of the operational amplifier 71 is connected. The reference numeral 73 designates a computing circuit of a known type. The reference numeral 74 designates a variable resistor for setting a predetermined aperture stop number value (ΔAv), while the reference number 75 designates a variable resistor for setting an ASA film sensitivity value (Sv) of the film used in each case. The arithmetic circuit 73 emits an output signal which represents the shutter speed value (Tv) to be controlled. Reference numeral 76 denotes a capacitor for storing the shutter speed Tv, while reference numeral 77 denotes a changeover switch, which is normally connected to a contact "a" and is switched over to a contact "b" in response to an upward movement of the oscillating mirror. Reference numeral 78 denotes an operational amplifier which forms a voltage follower circuit. Reference numeral 79 denotes a transistor for logarithmic signal expansion, the collector of which is connected to a timing capacitor 80 . Reference numeral 81 denotes a switching transistor for the count start, while reference numeral 82 denotes an operational amplifier forming a comparator circuit, the non-inverting input of which is connected to the collector of the signal expansion transistor 79 , while a reference voltage Vs is supplied to the inverting input. The reference numeral 83 denotes a differentiator connected to the output of the comparator circuit 82 , while the reference numeral 84 denotes a timer circuit which outputs the negative differentiating pulse of the differentiator 83 to emit a high-level output signal which lasts for a predetermined time (e.g. 20 ms) is triggered. The reference number 85 denotes a differentiator which is connected on the input side to the output of the timer circuit 84 .

The reference numeral 29 denotes a make contact switch, which is closed when the upward movement of the oscillating mirror is ended. Closing this switch causes a downstream differentiating element 87 to emit a negative differentiating pulse. The reference number 88 denotes an RS flip-flop circuit, the set input of which is connected to the output of the differentiator of the 87 and the Q output of which is connected to a delay element 89 . The delay element 89 again has an output Q ', which is connected to the base of the counting switching transistor 81 via a resistor.

Tr1 denotes a transistor, the base of which is connected to the Q output of the flip-flop circuit 88 and the collector of which is connected to a constant current source 93 , the constant current source 93, in turn, forming a part of the drive source for the front closing coil 66 connected is. With Tr2 a transistor is designated, the base of which is connected to the output of the timer circuit 84 and the collector of which is connected to a constant current source 95 , the constant current source 95 in turn being connected to the part 66 of the drive source for the rear shutter curtain. Reference numeral 99 be a trigger switch which cooperates with a (not shown) shutter release button. Reference numeral 97 denotes a differentiator, while reference numeral 98 denotes a timer circuit which is responsive to the output pulse of the differentiator 97 to form an output signal representing a predetermined period of time. With Tr9 is a transistor connected to the output terminal of the timer circuit 98 , while the reference number 8 denotes the electromagnet of FIG. 1.

Hereinafter, closer to the operation of the embodiment according to FIGS. 1, 2 and 3 are addressed. It is assumed here that all the mechanisms shown in the figures assume a position in which the closure is returned to the starting position and the front and rear closure curtains can run down.

When the release button (not shown) is pressed in this state, the release switch 99 is closed according to FIG. 3. As a result, the differentiator 97 triggers the timer circuit, which results in the formation of a high-level signal for a predetermined period of time. The transistor Tr9 is consequently turned on and supplies the electromagnet 8 with electrical energy. As a result, the attraction force of the permanent magnet 9 according to FIG. 1 is canceled or compensated and the armature 8 a is moved by the spring 7 a in the counterclockwise direction. The pin 6 of a coupled to the supporting lever 7 trip signal lever 6 thus pushes against the release lever 11 which is pivoted in a clockwise direction against the spring force of the spring. 11 Since the locking lever 12 is now rotated by the release lever 11 in the counterclockwise direction, the engagement with the end portion 13 c of the drive lever 13 is released , which is now pivoted ver by the spring 13 a in the clockwise direction. This movement of the drive lever 13 be acts on the intermediate lever 14, a common Drehbe movement of the diaphragm drive lever 15 in the clockwise direction, which in turn rotates a (not shown) pin of a diaphragm drive ring in the lens barrel in the clockwise direction. In this way, diaphragm blades (not shown) are closed up to the predetermined aperture value. This movement of the drive lever 13 also causes the mirror drive lever 18 is rotated counterclockwise by the spring 18 a when the drive lever 13 with its free end of the lower end portion of the Spiegelan drive lever 18 moves. The mirror drive lever 18 and the mirror flip-up lever 22 rotate on the same axis in the same direction together with the flip-up locking pawl 23 , while the arm 22 c of the mirror flip-up lever 22 abuts against the pin 24 a of the intermediate lever 24 , so that this lever is rotated in a counterclockwise direction, which in turn has the result that the opposite end portion 24 b of a rotating intermediate lever 24, the mirror support plate 25 via the befind union of their pin 25 about the axis 26 and the mirror support plate 25 thus against the spring force of the Spring 28 is folded up.

This upward movement of the mirror also causes the changeover switch 77 according to FIG. 1 to switch from contact "a" to contact "b", whereby the shutter value Tv is stored in the capacitor 76 of the circuit arrangement according to FIG. 3. Namely, since the circuit arrangement shown in FIG. 3 by closing a (not constitute provided) main switch or battery switch prior to actuation of the release button in operation is made, the operational amplifier 71 outputs an output signal in the form of one of the object brightness Bv and the F-number Avo of completely open lens-dependent voltage, which is processed by the arithmetic circuit 73 together with the aperture value given by the number of closing snap points passed by the minimum possible lens aperture and the film sensitivity value Sv to form an output signal presenting a shutter speed value Tv re. This shutter speed information Tv is thus entered into the capacitor 76 and stored there.

When the mirror driving lever 18 to the mirror rotates by 45 °, at which value the upward movement of the mirror is completed, the projection of the mirror 18 rotates b drive lever 18 the operating lever 51 against the spring force of the spring 51 a in the clockwise direction, the free end portion 51 b of the Actuating lever 51 presses the control part 34 against the spring force of the spring 34 a, so that the contact sections 34 c and 34 b of the control part 34 disengage from the pawl parts 38 a and 36 a of the actuating lever 38 and 36 for the shutter curtains. The shutter curtains can now be actuated or released. At this point, the shutter curtains are secured by suitable means such as e.g. B. by friction, a pawl and a spring or spring lock of a known type, held stationary, since otherwise a malfunction would occur due to their own weight. In addition, this movement of the actuating lever 51 to close the switch 29 , whereby the differentiating member 87 is controlled according to FIG. 3. As a result, the flip-flop circuit 88 is set and emits a high-level signal via its output stage Q. This signal turns on the transistor Tr1, so that a current regulated by the constant current circuit 93 flows through the coil 66 , with the result that a force is exerted in the part of the coil winding in the magnetic field according to FIG. 2. Since this force exerts a moment on the drive shaft 35 , the drive shaft 35 is rotated clockwise, where the actuating lever 36 for the front shutter is moved clockwise so that the front shutter opens the image window and thus initiates the exposure . The setting of the flip-flop circuit 88 also causes the delay element 89 to emit a high-level signal with a predetermined time delay, whereupon the transistor 81 blocks. As a result, the capacitor 80 begins to be charged by the collector current of transistor 79 . Since the base of transistor 79 is connected to the output of amplifier 78 , this collector current corresponds to the value obtained by logarithmic expansion of the Tv information stored in capacitor 76 . The capacitor 80 is thus charged as a function of the shutter speed value determined on the basis of the object brightness, ie the voltage across the capacitor reaches the magnitude of the reference voltage Vs within a time interval which depends on the Tv value. As a result, the output signal of the comparator circuit 82 is inverted and triggers the differentiating element 83 , which in turn emits a differentiating pulse for triggering the timer circuit 84 . In a predetermined time, the timer circuit 84 generates a high level signal through which the transistor Tr2 is turned on, so that a constant current flows through the coil 66 'of the electromagnetic drive source for the rear shutter curtain. As a result, the drive shaft 87 rotates in the direction of the arrow, whereby the shutter curtain 43 is closed and the exposure is thus ended. The time during which the output signal of the timer circuit 84 remains at a high level is to a certain extent greater than the time required from the beginning to the end of the downward movement of the rear closure device, thereby ensuring that the closure is high Reliability closes. When the high-level signal output by the timer circuit 84 ends, that is, when the output signal of the timer circuit 84 changes to a low level after the closure of the shutter, the differentiator 85 is triggered to emit a differentiating pulse that the flip-flop circuit 88 is fed to their provision. The termination of the exposure control thus leads to the blocking of the transistors Tr1 and Tr2.

While the drive shaft 37 rotates in the direction of the arrow and the rear closing curtain begins to run, the pawl part 38 a of the actuating lever 38 abuts against the arm 52 a of the signal lever 52 , whereby the arm 52 a is rotated counterclockwise. The signal lever 52 abuts against the free end portion 30 thereby a signal of the lever 30, so that the signal lever 30 rotates in the direction pointer PM. Also the stepped part with the befind Liche operation lever 51 rotates in this case the signal lever 52 is engaged in the counterclockwise direction. The clockwise movement of the signal lever 30 causes the pin 30 b, the locking pawl 23 rotates counterclockwise and releases them from their engagement with the mirror flip lever 22 . The mirror support plate 25 is then no longer held in the folded-up position and returns to the position shown due to the action of the return spring 28 .

At this time, the intermediate lever 24 also rotates clockwise, its movement being transmitted via the pin 24 a and the arm 22 c and causing the mirror flip-up lever 22 to rotate clockwise, as a result of which the reset lever 35 a through the arm 22 a is turned in the direction of the arrow. At this time, the electric power supply of the electromagnetic power sources is already interrupted, causing this rotation of the reset lever 35 a that the operating lever 36 rotates counterclockwise. In this way, the front and the rear closure are returned to their original positions. At the same time, the control part 34 is set back, because it is moved upwards by the spring force of the spring 34 a, so that the closure is locked again by means of the latch parts 36 a, 38 a.

As described above, takes place during rotation of the signal lever 30 a rotation of the signal lever 17 in a counterclockwise direction, whereby the Zwischenhebei 14 b via the engaged pin 14 in counterclockwise direction is rotated so that the downwardly extending portion 15a of the shutter drive lever 15 except Engagement with the intermediate lever 14 . The diaphragm drive lever 15 is then rotated by the spring 15 c in the counterclockwise direction, whereby the diaphragm blades are fully opened via a mechanism known in the art. This completes a first half cycle of the photographic process.

The second half cycle of the photographic process, in which the film is transported one frame at a time, is explained in more detail below. When actuating the (not shown) transport lever, the winding axis 1 is rotated in the direction of the arrow, whereby the lever 3 is rotated clockwise about the axis 3 b when the cam disc 2 abuts the cam follower 4 . Depending on this movement, the connecting lever 5 rotates in a clockwise direction about the axis 5 c, pressing it against the end part 60 c of the clamping lever 60 which is in engagement with the pin 5 b, so that the clamping lever 60 in a clockwise direction about the axis 60 b is rotated. In this case, the stepped portion 60 pushes b of the pin 60 located on the clamping lever 60 against the arm 13 b of the drive lever 13, whereby the on operating lever 13 in a counterclockwise direction about the axis 13 e is rotated and with its arm 13 c is engaged with the locking lever 12 devices. This rotational movement of the drive lever 13 causes also that the drive spring 13a is tensioned and that the free end portion 14 b of the intermediate lever 14 gets back to the bent portion 15 a of the shutter drive lever 15 is engaged. Apart from the leaf spring 5 presses a of the connecting lever 5 b against the pin 6 of the signal lever 6, whereby the signal lever 6 against the spring force of the spring 7 is a rotated clockwise and the anchor located on the supporting lever 7 8 a into contact with the electromagnet 8 arrives and is held in this position by the force exerted by the permanent magnet 9 attraction.

The rotational movement of the drive lever 13 described above causes also that the mirror driving lever is turned d 18 due to the engagement of its lower end portion to the drive lever 13 in the clockwise direction about the axis 18, is stretched whereby the mirror drive spring 18 a. The locking lever 23 moves together with the rotary movement of the mirror drive lever 18 and comes back into engagement with the mirror flip lever 22 , whereby the preparation for the next image exposure is completed.

In the embodiment described above, the control part 34 is constructed and arranged such that it is held in its first or active position using the spring 34 a. In a further embodiment shown in FIGS. 4 and 5, the corresponding control part 34 'is held by a magnet and can be released or triggered electromagnetically.

In Fig. 4, reference numeral 40 denotes an electric magnet and reference numeral 48 denotes a permanent magnet which is fixedly attached to the upper end part of the plate-shaped control part 34 'and serves as an armature for the electromagnet 40 . In the de-energized state of the electromagnet 40 , the armature 48 is held on the yoke of the electromagnet 40 , whereby the control part 34 'is held in its first position. 34 a denotes a spring which prestresses the control part for a downward movement in the manner shown in the figure, while the reference number 34 d denotes a connecting arm for one end of the spring 34 a. Reference numeral 30 'denotes a signal lever having a similar function as the above-described mirror return signal lever 30, but a permanent magnet 31 at the upper end portion of the signal lever 30' is fixedly mounted and arranged such that it is ten firmly supported on the yoke of an electromagnet 32, when the electromagnet 32 is not energized. With 30 a, a spring is designated, which biases the signal lever 30 'for a movement away from the electromagnet 32 . With 51 'is a rotatable about an axis 51 c switch control lever, the lower end portion with the projection 18 b of the mirror drive lever 18 ' and the upper Endab cut with a signal indicating the completion of the upward movement of the mirror 29 can be brought into engagement. With 51 a, a spring is designated, which biases the switch control lever 51 'for movement in the counterclockwise direction. The reference numeral 33 designates a rotatable lever about an axis 33 , the one with the arm 34 d of the control part 34 'in engagement arm 33 a and with a fixed to the upper end of the signal lever 30 ' attached pin 30 d engageable has another arm 33 b.

The reference number 39 denotes a normally open switch, which is arranged such that it can be closed by a bent arm 38 d of an operating lever 38 '' for the rear curtain. With the exception of the above-mentioned parts, all parts correspond to those of the exemplary embodiment according to FIG. 1, parts with the same functions having the same reference numerals.

In Fig. 5, a control circuit for the embodiment example of FIG. 4 is shown, in which the same or similar parts as in the circuit arrangement of FIG. 3 are provided with the same reference numerals. In Fig. 5, reference numeral 96 denotes a timer circuit connected to the output of the differentiator 87 described above, the output signal of which is fed to a transistor Tr7 and turns it on for a predetermined period of time during which the electromagnet 40 is energized. The reference number 39 denotes the above-mentioned normally open switch, which can be closed by the drive lever 38 '' for the rear closure device. When this switch is closed, a differentiator 97 'gives a pulse. Reference numeral 97 denotes a timer circuit which is triggered by the 'output from the differentiator 97 differentiation pulse and then a high level output signal for a predetermined period of time to write, while with Tr8 one of the output signal of the timer circuit 97 for energization of said front stationary electromagnet 32 switchable transistor is designated.

The mode of operation of this exemplary embodiment is discussed in more detail below. In the Ausführungsbei of FIG game. 4 of the automatic aperture and mirror driving mechanism is charged, the shutter curtains are provided on ratchet portions 36 a, 38 a of the operating levers 36 and 38 '' in engagement with the control part 34 ', so that the latter as a locking part, the front and locks the rear shutter curtain in its home positions under the action of the attractive force exerted by the permanent magnet 48 . If in this position a (not shown) trigger button is pressed, the trigger switch 99 is closed as in the embodiment described above to excite the electromagnet 8 , whereby the trigger lever 11 is rotated and the locking connection with the drive lever 13 is released. Due to the energy stored in the drive spring 13 a, an automatic aperture setting process is carried out. In connection with this, the mirror drive lever 18 is rotated in order to fold up the oscillating mirror 27 . When the upward movement of the mirror is completed, the projecting part of the mirror drive lever 18 is engaged with the lower end of the switch control lever 51 ', whereby the switch control lever 51 ' against the spring force of the spring 51 a is rotated clockwise about the axis 51 c.

The switch 29 is then closed and the differentiating element 87 emits a differentiating pulse. This pulse is fed to the timer circuit 96 , which is triggered thereby and generates a high-level output signal for a predetermined period of time. This high-level signal causes the transistor Tr7 to be turned on to excite the electromagnet 40 , as a result of which an oppositely polarized magnetic flux is formed in relation to the magnetic flux generated by the permanent magnet 48 . The force exerted by the permanent magnet is therefore temporarily lifted up or compensated, so that the control part 34 'can move down under the spring force of the spring 34 a. As a result, the operating levers 36 and 38 '' are released from their locking connection. The shutter curtains can thus be actuated due to the release of the lock, but are held stationary in their starting positions by friction or by other means in the manner already described above until the electromagnetic drive sources are supplied with electrical energy.

In the meantime, the differentiating pulse output by the differentiating element 87 has also been supplied to the set input S of the flip-flop circuit 88 , where it is set by the flip-flop circuit 88 and outputs a high-level output signal via its output Q. This signal turns on the transistor Tr1, whereupon a current regulated by the constant current circuit 93 flows through the coil 66 of the electromagnetic drive source for the front shutter curtain. The operation of the front and rear shutter curtain is controlled in the same manner as in the first embodiment described above.

When the electromagnetic drive source for the rear shutter curtain is energized, the rear shutter curtain expires. At the end of the movement of the rear shutter curtain, the actuating lever 38 '' enters via its shoulder 38 e with the signal switch 39 for the rear shutter curtain and closes the switch.

As a result, the differentiator 97 'is activated and triggers the timer circuit 97 , which in turn switches the transistor Tr8 to excite the electromagnet 32 . In this way, the attractive force of the fixed upper loses at the end of the signal lever 30 'attached to the permanent magnet 31 is temporarily its effect and it thus enables one on the spring force of the spring 30 a based, directed away from the electromagnet movement. As a result, the signal lever 30 'is rotated clockwise about the axis 30 f. This movement of the signal lever 30 'causes the signal lever 17 in engagement with it to be rotated in the counterclockwise direction about the axis 17 a, which in turn has the result that the intermediate lever 14 is released from engagement with the auto matic aperture drive lever 15 . The Blendenan drive lever 15 is then guided back by the spring force of the spring 15 a to fully open the aperture blades. In addition, the locking lever 23 is rotated by the pin 30 b located on the signal lever 30 'about the axis 18 c, whereby the flip-up lever 12 releases from the locking connection. As described above, the mirror 27 is thus quickly returned by the return force of the spring 28 , while the reset lever 35 a is rotated counterclockwise by the arm 22 b of the flip-up lever 22 to return the front and rear shutter curtain.

At the same time presses on the signal lever 30 'be sensitive pin 30 d against the arm 33 b of the lever 33 , whereby the lever 33 is rotated counterclockwise about the axis 33 c, while the opposite arm 33 a against the arm 34 d of the control part 34 'Presses and this moves upwards against the spring force of the spring 34 a in the figure until the arms 34 b and 34 c come into engagement with the latch parts 36 a and 38 a of the actuating lever. At this point, the control part 34 'is again held by the attraction of the permanent magnet 48 on the yoke of the electromagnet 40 .

In Figs. 6 and 7, for example illustrates a further execution, in which takes place the resetting of the shutter using an electromagnetic drive source rule.

In the embodiment of FIG. 6, the drive shaft 35 of the electromagnetic drive source for the front shutter curtain does not have the actuating lever 35 a as shown in FIG. 4, so that the mirror flip lever 22 'not with the arm 22 b for engagement with the Adjusting lever 35 a is provided. The other parts correspond to the exemplary embodiment according to FIG. 4.

In Fig. 7, the reference numeral 90 denotes a connected to the output of the differentiator 85 shown in FIG. 5 timer circuit, which is triggered by the negative differentiating pulse of the differentiator 85 to output a high-level output signal, which for a predetermined period of time (e.g. B. 20 ms) is maintained. Reference numeral 91 denotes an inverter connected to the output of the timer circuit 90 . With Tr11 through Tr16 transistors are designated, the circuit comprising a driver for supplying a driving current to the ON drive coil 66 of the electromagnetic driving source for the front curtain and the driving coil 66 'of the electromagnetic driving source for the (not shown) rear curtain form. The transistors Tr11, Tr12, Tr13 and Tr14 form a bridge circuit for the drive coil 66 , so that the direction of the current flowing through the drive coil 66 can be controlled. Another combination of the transistors Tr11, Tr12, Tr15 and Tr16 forms a bridge circuit for the drive coil 66 ', whereby the direction of the current flowing through the drive coil 66 ' current is controllable. The driver circuit described above also has constant current circuits 92 to 95 .

The mode of operation of the exemplary embodiments according to FIGS. 6 and 7 is discussed in more detail below. If it is assumed that the tensioning process for resetting the closure is completed according to FIG. 6, the switch 99 for energizing the electromagnet 8 is closed, as in the case of the exemplary embodiment described above, when the release button (not shown) is actuated, whereupon the automatic aperture drive lever 15 and the Spiegelan drive lever 18 begin to move. At the beginning of the upward movement of the mirror, the switch 77 switches from the contact position "a" to the contact position "b", so that the Tv value is stored in the capacitor 76 . With completion of the upward movement of the mirror, the projection 18 presses b of the mirror driving lever 18 against the lower end of the switch control lever 51 ', whereby this lever a is rotated tung in Uhrzeigerrich against the spring force of the spring 51 and its free end portion of the signal switch 29 for signaling the completion the mirror upward movement closes. The differentiator 87 then outputs a differentiating pulse which triggers the timer circuit 96 to output an output signal which is at a high level for a predetermined period of time. Depending on this high-level signal, the transistor Tr7 is turned on to excite the electromagnet 40 . The electromagnet 40 therefore generates an oppositely polarized magnetic flux to the magnetic flux of the permanent magnet 48 , with the result that the locking of the locking plate 34 is released.

At the same time, the differentiating pulse output by the differentiator 87 is also supplied to the set input of the flip-flop 88 , whereby the flip-flop 88 is set and outputs a high-level signal via its output Q and a low-level signal via its output. As a result, the transistors Tr11 and Tr14 are turned on, so that a current flows in the direction indicated by an arrow A through the drive coil 66 for the front shutter curtain, with the result that the drive shaft 35 rotates clockwise and thus also a Clockwise rotation of the actuating lever 36 causes. In this way the shutter begins to open.

This setting of the flip-flop 88 also causes the delay element 89 to generate a high-level signal with a predetermined time delay, which is fed to the transistor 81 to block it. As a result, the capacitor 80 begins to be charged by the collector current of transistor 79 . Since the base of transistor 79 is connected to the output of amplifier 78 , this collector current corresponds to the logarithmically expanded value of the Tv information stored in capacitor 76 . The capacitor 80 is thus charged as a function of the shutter speed value determined on the basis of the brightness of the object. If the voltage across the capacitor 80 reaches the reference voltage value Vs within a time interval dependent on this Tv value, the output signal of the comparator circuit 82 is inverted and triggers the differentiator 83 . The differentiator 83 then outputs a differentiating pulse which triggers the timer circuit 84 , which then generates an output signal which has a high level for a predetermined period of time. As a result, the transistor Tr16 is switched on, so that a current flowing in the direction marked by the arrow A marked via the transistors Tr11 and Tr16 of the drive coil 66 'of the rear United circuit curtain is supplied so that the drive shaft 37 rotates clockwise and the rear shutter curtain runs off. It should be noted that the duration of the high level output of the timer circuit 84 is set to a slightly longer value than is required to cover the entire distance of the trailing movement of the rear shutter curtain to ensure that the shutter closing operation is completed with high reliability.

After the completion of the downward movement of the rear shutter curtain, the differentiator 85 is triggered at the transition of the output signal of the timer circuit 84 from its high to its low value and emits a differentiating pulse, which is fed to the flip-flop 88 to reset it. The differentiating pulse of the differentiator 85 also triggers the timer circuit 90 , which then generates a high-level signal for a predetermined period of time, while the inverter 91 outputs a low-level signal, with the result that the transistors Tr11, Tr14 and Tr16 block and the transistors Tr12, Tr13 and Tr15 can be switched through. Thus, a current flows in the direction indicated by the arrow B through the drive coils 66 and 66 ', so that the electromagnetic drive sources for the front and rear Ver curtain in the opposite direction to the case described above, ie, the drive shafts 35th and 37 are rotated counterclockwise. In this way, the shutter is set back. It should be noted that the duration of the output of the timer circuit 90 is set to a somewhat longer value than that required to reset the front and rear shutter curtains. In addition, it should be noted that the output current of the constant current circuit 92 is held at a higher value than the output current of the constant current circuit 94 , so that the current flowing through the drive coil 66 of the front shutter curtain current is greater than that through the drive coil 66 'of the rear shutter curtain is flowing current, with the result that the front shutter curtain presses against the rear shutter curtain during the entire return movement of the closure, so that accidental opening of the closure during the reset operation cannot occur.

When the shutter reset operation thus completed is completed, the output of the timer circuit 90 goes low, at which all the transistors of the driver circuit are turned off, thereby preventing unnecessary power consumption.

The to the flow movement of the rear curtain following operation largely corresponds to the second embodiment and causes the signal switch 39 for the rear curtain of the bent portion 38 e of the drive arm 38 is closed, the automatic aperture mechanism and the Spie gel driving mechanism quickly returned are and the control part 34 returns to its first or active position.

Claims (6)

1. A shutter for a single-lens reflex camera, which has a pivoting mirror, which can be pivoted into a position within an optical exposure path and into a position retracted therefrom, with leading blades ( 42 ) and trailing blades ( 43 ), each with a rotary drive mechanism for the leading and trailing slats, which provides the driving force for the discharge of the slats in question, with a first actuating lever ( 36 , 36 ') for the leading slats ( 42 ), which transmits the driving force to them, with a second actuating lever ( 38 , 38 '') for the trailing slats ( 43 ), which transmits the driving force to them, with a reset mechanism ( 22 , 35 a) for returning the first actuating lever ( 36 , 36 ') and the second actuating lever ( 38 , 38 ') in their initial positions which they assume before the start of an exposure, and a control part (34, 34 ) Which in a resting, first position, wherein the first operating lever (36, 36 ') and the second actuating lever (38, 38' ') are locked in their home positions and can be brought into a second position in which the locking the first and second actuating levers ( 36 , 36 '; 38 , 38 '') is released, the control part ( 34 , 34 ') having a first contact section ( 34 b) which can come into contact with the first actuating lever ( 36 , 36 ') and a second contact section ( 34 c) has, which can come into contact with the second actuating lever ( 38 , 38 ''), and wherein the control part ( 34 , 34 ') simultaneously with the pivoting of the pivoting mirror ( 27 ), which is before the start of exposure from its position within of the optical exposure path pivots into the retracted position, can be moved from the first position into the second position, characterized in that the control part ( 34 , 34 ′) is designed independently of the reset mechanism ( 22 , 35 a) and in that the control part ( 34 , 34 ') in its first position with its first contact section ( 34 b) directly touches the first actuating lever ( 36 , 36 ') and thereby locked in its starting position and with its second Contact section ( 34 c) directly touches the second operating lever ( 38 , 38 '') and thereby locked in its starting position, so that the control part ( 34 , 34 ') forms a common locking part for the first and second operating levers. 2. Closure according to claim 1, characterized in that the control part ( 34 ) is biased by a spring ( 34 a) in the direction of its first position. 3. Closure according to claim 1 or 2, characterized in that the movement of the control part ( 34 ) from its first position to its second position by means of a drive source ( 18 a) for the swivel mirror ( 27 ), which the swivel mirror ( 27th ) swivels from its position within the optical exposure path into its retracted position. 4. Closure according to one of claims 1 to 3, characterized in that the return of the control part ( 34 ) from its second position to its first position simultaneously with the pivoting back of the pivoting mirror ( 27 ) from its retracted position into the position within the opti's Exposure path takes place. 5. Closure according to one of claims 1 to 4, characterized in that the control part ( 34 , 34 ') moves parallel to the outlet planes of the leading slats ( 42 ) and the moving slats ( 43 ). 6. Closure according to one of claims 1 to 5, characterized in that the rotary drive mechanism has an electro-magnetic drive source ( 67 ) which generates an electromagnetic driving force when energy is supplied.