DE1300008B - Photographic shutter with two sequential shutter links - Google Patents

Description

The invention relates to a photographic shutter with two shutter members running one after the other, of which the first release when it expires and the second when it expires Closing the shutter opening causes, and with a first control switch by applying Exposure control circuit that can be transferred to a built-in voltage source in standby position or exposure control circuit, the timer function of which is triggered by a second control switch is, and in which a relay with a dependent on the current flow through a photoresistor Delay for the release of the second locking member drops, in which a to trigger the shutter moving part causes the second control switch approximately simultaneously with the release of the Expiry of the first closure member is actuated.

In a proposal that does not belong to the prior art, this second control switch is from two fixed contacts formed with a contact bridge arranged on the opening lamella in such a way cooperate that approximately simultaneously with the beginning of the opening movement of the opening lamella this second control switch is opened. The part that is moved to trigger the shutter is here as Pawl formed, which causes a mechanical release of the opening lamella.

According to this suggestion, the control switch could then approximately simultaneously with the start of the sequence the opening slat can be operated. However, it may be desirable to bring this point forward; H. to open the second control switch before the first closure member expires or for the purpose of adjustment the exposure control device the time of actuation of the second control switch on the To move the time axis relative to the movement of the closure members.

According to the invention, this possibility is created by the fact that the one for releasing the lock moving part actuated the second control switch immediately. This makes it possible to use the control switch to operate independently of the sequence of the closure members, d. That is, the switch can also already be actuated while the closure member is still stationary.

According to a preferred embodiment of the invention, the is moved to trigger the lock Part designed as a pawl, which when it releases the first locking member causing movement actuates the control switch. This pawl can then easily be adjusted so that the time sequence or the timing of the release of the mechanical latching and the mechanical one Switch actuation takes place in the desired manner.

The pawl is expediently moved by a slide running under the action of a spring, which in turn is released to the process by the trigger handle. By switching on this intermediate member (slide) ensures that the pawl with each release of the shutter with the the same speed is pivoted, so that the time sequence of the switch actuation and linking approval is always correct.

Here, the movement can be transmitted from the sliding carriage to the pawl by an this attached inclined surface take place against which a cam of the carriage runs.

An exemplary embodiment of the invention is described below with reference to the drawing. In this shows

1 shows a schematic representation of the photographic shutter according to the invention in FIG Clamping position,

FIG. 2 is a view of the shutter shown in FIG. 1 in the exposure position.

F i g. 3 a f i g. 1 and 2 corresponding view of the lock after all locking links have expired,

F i g. 4 a trigger circuit which determines the time sequence of the sequence of the closure members,

F i g. 5 is an expanded timing diagram showing the sequence of events that occurred during Occur locking process.

The camera housing 20 has an exposure opening 24 through which the light originating from a scene to be photographed can pass onto the film, not shown in the drawing, in order to expose it to an extent which depends on the mode of operation of the exposure control device, which includes a shutter and Has shutter control members. The closure consists of two flat, opaque lamellae 28 and 36, which can be moved independently of one another in translation in separate rail guides 42 , namely perpendicular to the optical axis of the camera, which is defined by the center of the opening 24 . When the lamella 28 has reached the end position (this is referred to as the closed position), as can be seen from FIG. 1, the front edge 30 lies under the opening, and the fixed section of the lamella completely blocks the opening. If, on the other hand, this lamella is in the other end position (this is referred to as the open position), then, according to FIG. 2, an opening 34 in the lamella is precisely aligned with the opening 24. When the lamella 36 in FIG. 1 assumes the end position (open position) shown, the front edge 38 exposes the opening 24 . However, when the lamella has reached the end position according to FIG. 3 (closed position), the rear edge 40 is in front of the opening, and the fixed section of the lamella blocks the opening completely. Between the two end positions of the two slats there is an intermediate position in which only part of the opening is covered. For conventional reasons, it should be assumed that the intermediate position in which the lamella 28 (this is referred to as the opening lamella) releases the exposure opening halfway on its way to the closed position into the open position is that position (this is called the release position) at which the exposure is initiated. The intermediate position in which the lamella 36 (this is referred to as the closing lamella) covers the opening halfway when it moves from the open to the closed position (this position is to be referred to as the shut-off position), is that position in which the exposure is terminated.

F i g. 1 shows the position of the individual elements before exposure is initiated. A projection 60 pivotably mounted on the release element 68 and pretensioned by a spring 70 rests resiliently against an enlarged section 62 of a pin 63 which is fixed on the opening lamella 28 and presses the closing lamella into the closed position. The opening

lamella is held in its closed position because the pawl section 92 of the pawl 90, which is pivotably mounted at 96 in the housing 20 , is releasably connected to a tab 94 of the trigger element 68 , a translational movement of the part relative to the housing through the interaction between Pin 72, which is fixed to the housing, and the slot 74 in the element 68 and the pin 76, which is fastened on the element 68 , and the housing slot 78 comes about. The lamella 28 holds the closing lamella 36 in the open position because the rear edge 32 of the lamella 28 abuts against pins 114 and 116 which are rigidly attached to the lamella 36.

Upon actuation of the shutter release button not shown in the drawing by the element 100, the switch contacts 142 are closed 144 that set the shutter control device in activity in the described further below, immediately before the rear portion 102 of the element 90 loading so actuated. The latter is used to rotate the element 90 about the pin 96 so that the section 92 comes free of the tab 94 on the trigger slide 68. The carriage 68 moves under the influence of the torsion spring 86 as shown in FIG. 1 to the left, the torsion spring moving the tensioning lever 80 around the pin 84 according to FIG. 1 pushes counterclockwise, causing the slotted end portion to cooperate with the pin 76 of the trigger element in order to transmit the desired movement to this. The torsion spring 44, one end of which is anchored in the housing in a notch 52 of a stop 48 and the other bears against a pin 46 which is attached to the opening blade 28 , presses the latter into the release position when the trigger element 68 moves to the left begins to move. The interaction of the trailing edge 32 of the opening lamella with pins 114 and 116 on the closing lamella serves to hold the latter in the unlocked position prior to initiation of the exposure, and it is therefore clear that movement of the opening lamella to the left causes the against The torsion spring 54 attached to the pin 56 attached to the closing lamella tries to move the closing lamella simultaneously with the opening lamella into the locking position.

The shutter control device has, however, been activated by closing the contacts 142, 144 and releasably holds the shutter in the open position for a time interval after the opening shutter has been triggered, this time interval being sufficient to effect a proper exposure. Therefore, only the opening blade is released in accordance with the operation of the shutter release. After the initial movement of the opening lamella out of the open position, a section 64 of the pin 63 of the opening lamella of reduced diameter cooperates with a pawl section 104 of a time delay element 106 , which is pivotably mounted on the housing at 108 and prevents further movement of the opening lamella until the pin 76 of the Trigger slide cooperates with the cam surface 112 of the time delay element and the latter rotates about the pin 108 against the action of the torsion spring 110. The rotation of the time delay element has a dual function. Once the opening lamella is opened to initiate the exposure.

released, and the approach 156 of the element 106 opens the switching contacts 150, 152. This latter function is used to activate the time delay circuit, which forms part of the exposure control device and actually determines the exposure time. The exposure is initiated when the opening slat has reached the unlocked position. Both the opening lamella and the release slide 68 move to the left under the influence of the springs 44 and 86, respectively. After a predetermined time, during which the two lamellae occupy the position shown in FIG. 2, the closing lamella 36 is released by the shutter control device, and under the influence of the spring 54 it moves to the left and thus terminates the exposure when it reaches its covering position achieved. After the exposure is complete, the two lamellae take the position shown in FIG. 3 position shown.

After completion of the exposure, the two lamellae can be moved into their tensioned position, which they assume before the exposure, by manually turning the tensioning lever 80 in a clockwise direction according to FIG. 1 to 3 is rotated. This moves both the closing lamella and the opening lamella to the right until the pawl portion 92 of the element 90 is again captured by the tab 94 of the element 68 , and the camera is now ready for the next exposure.

The above-mentioned shutter control device comprises a shutter operating device and an exposure time delay device. The latter has a voltage-dependent trigger circuit and a delay circuit. The shutter actuation device consists of an electromagnet 120 (FIG. 6), which is equipped with a U-shaped core of magnetizable material and is fastened to the housing by means of screws 122. The magnetic coil 124 of the electromagnet 120 is wound on a leg 2 , and the holder 117, 118 is attached at 114 to the closing lamella 36. The free ends of the parallel legs 2 and 4 of the core define separate, flat surfaces 6 and 7 which lie in a plane substantially normal to the plane of the closing lamella. These surfaces are designed in cross section relative to the holder 117, 118 such that the contact takes place essentially along a straight line. When the holder 117, 118 comes into contact with the surfaces 6 and 7 of the pole pieces, a magnetic circuit with a certain magnetic resistance is defined so that a preselected magnetomotive force (current of the coil of the electromagnet) is impressed on the magnetic circuit which is sufficient to produce a attractive force to maintain between the pole piece 1 and the holder 117, 118 , which is sufficient to overcome the opposing forces which are exerted by the biasing action of the springs 44 and 86 on the closing lamella, which force caused by attraction is also sufficient to take up dynamic loads that z. B. by impact.

The shutter control device also includes a shutter delay mechanism, the purpose of which is to supply an exciting current to the coil of the electromagnet 120. If the camera is to be designed to be portable and accordingly must be operated by a battery, it is essential to reduce the current load on the battery.

reduce. Taking into account this fact, the trigger circuit is sometimes conductive stage, a premature release of the closing lamella 36 has a transistor ₂ , the base of which is 138 b , and a precise control of the time, during which its collector is 138 c and its emitter is rend der the closing plate is designated in opening position overall 138e. The collector 138 e is held by the fact that the magnet 5 terminal 130 via the electromagnet 124 so abruptly connected to the coil shortly before releasing the opening that the latter is excited when the lamella is excited, and further in that the transistor g _{2 is} conductive. The base 138 b of the transistor closing lamella from the electromagnet to which the Storsg ₂ is abruptly released with the collector 128 c of the transistor _{g 1 at a} suitable time. connected, and the emitter 138 e of the transistor g ₂

The electromagnet must be excited before the io is connected to the opening slat via the variable resistor 136 from the closed position - terminal 134 . With this arrangement, moving is begins because these lamella provided over the pins, a common emitter resistor, and 114 and 116 causes the holder 117, 118 switch the setting of the resistor 136 is used to fänglich brought into contact with the pole piece 1 purpose, Set the voltage at which the will. If the holder is even once done by a 15 circuit. In the foregoing, the two small amounts have been removed from the pole piece, stages of the circuit are referred to as "normally non-conductive" the magnetic resistance of the magnetic circuit or "normally conductive", but it is clear that the current flowing in the magnetic coil that this characterization is only not able to generate a tightening force when a voltage source at the terminals overcomes the force of the spring 54 , so that the 20 130 and 134 is located.

Closing lamella is transferred to the closed position. To the voltage source 140 in the form of a The sudden release of the _{closing blade of the battery with the potential j} E ₀ , which can be brought about between the electromagnets, terminals 130 and 134 above the normally open that suddenly the switch S ₁ feeding the electromagnet is located, to be arranged in such a way that current is reduced. If this current suddenly 25 of the power consumption of the battery is reduced as low as possible, is due to the inductance of the held, the contacts 142, 144 closed by the electromagnet and the distributed capacitance of a the element 100 when the latter is induced for the purpose of voltage which the Capacitor 126 is releasing the pawl 90 charges through the release slide, which is manually depressed in shunt with the electromagnet. The result is present and prevents the transistor 30 g of ₂ damaged gears, as a result of depression of the Elewird. The current occurring in the coil of the electromagnet element 100 will , however, quickly reach a point in the following, at which the effect on the diagram according to FIG. 5 is reduced so far that they wrote. When the force of attraction of the pole pieces begins to be pressed down on the holder like element 100 , switch S _{1 is} closed, except that there is spring force which causes the separation. DIE at 35 before the pawl 90 of the rotation given a release sem point the movement of the holder sets 117, 118 of the carriage has caused. Because the human response when the closing lamella goes into the discharge position due to the spring preload time when the element is actuated, namely the voltage. The time between - the time to depress the element and to see it, the moment when the flow in g ₂ rapid release, and the inertia of the element is reduced at, and the moment when the 40 of the return to the normal position essentially closing blade is released, lasts extremely longer than the longest average exposure, small compared to the usual exposure inter- under normal snapshot conditions of a light and is only a fraction of a million scenes, the contacts of the switch remain ₁ second. Under these circumstances it off, at least as long in the open position, as will be gone in that the reduction of conductivity 45 requires the proper exposure time, skill of ₂ g and the movement of the closing A consideration of the level of the transistor Q ₂ of insert the lamella essentially at the same time. Circuit teaches that the base 138 b represents the input to the aforementioned goal, namely a water stage, that the collector 138 c forms the Ausrapide circuit of the current input of the coil of the gang and that the emitter 138 e to the input electromagnet and one low energy output 50 and is in common. To achieve between the use, the exposure time delay electrode 138 b and the terminal 130 switched generating device in the form of a transistorized resistor 132 serves as a base resistance to provide a fixed base current before Schmitt type with two-stage, modified trigger circuit of the closed switch ₁ on (Fig. 4) to supply the output voltage, which causes the transistor _{organ 2} voltage of a time delay circuit to respond and 55 is immediately conductive with the closing of S ₁ , controls the actuation of the closure members. The span- The setting of the variable resistor 132 usage-dependent trigger circuit has a normally- corrects the switching point at which the transient non-conductive stage, which makes a transistor Q ₁ stor g ₂ conductive in such a way that the one through the coil, which is preferably of the Silicone construction of the electromagnet 124 flowing current is set type with low residual current and a base 128 b, 60 can be to the required magnetomotive force in the magnetic circuit of the electromagnet 120 has a collector 128 c and an emitter 128 e. The collector 128 c of the transistor Q ₁ is to be generated, which prevents an accidental release of the closing of the terminal 130 of the exposure time delay lamella 26 when the opening lamella is set up via a resistor 132 to initiate the exposure in the release position changeable bias connected; the emitter 128 e 65 moves. The current flow through the resistors 132 and the transistor Q ₁ is effected with the terminal 134 of the loading 136 when the transistor g _{2 is} conductive that the bias variable resistor 136 is switched on at the light time delay device via a collector and emitter electrode of Q ₁ . The normalization has a first value which is of the size

Claims (4)

the corresponding currents and the resistance values. Until the opening lamella moves out of its closed position, the contacts 150 and 152 of the switch S2 are closed. The connection 141 is at an initial voltage value, namely the earth potential, when the switch i1 is closed. When the voltage at junction 141 is at its initial value and the voltages at the collector and emitter of transistor Q1 are at their initial values of bias due to the conductivity of Q2, the collector and emitter connections of transistor Q1 are reverse biased so that transistor Q1 is off. For this reason, the bias of Q1 can be said to be primarily determined by the voltage at junction 141. In the meantime, the current flowing through the solenoid coil increases rapidly to its maximum value and generates the maximum retaining force on the closing blade shortly after S1 has been closed and shortly before the portion 92 of the tab 94 which allows the movement of the slide has been released. As already mentioned, the initial movement of the opening slat causes the contacts of switch S2 to open, as a result of which a voltage is applied to the time delay stage, which activates it. The time delay stage comprises a capacitor C in series with a photoresistor 139, e.g. This circuit is between the terminals 130 and 134 of the exposure timer device and forms a conventional integrator stage, the input terminal of which is 130 and the output terminal 141 of which forms the connection between the capacitor and the photoresistor. Terminal 141 is connected to base 128 & of transistor Q1 and this electrode forms the input electrode of that stage. By opening the switch S2 the time delay circuit is activated, i. i.e., the latter produces a voltage at junction 141 having an initial value (in this case it is the ground potential) which causes transistor 1 to be reverse biased so that it is in the non-conductive position, which voltage is then changes over time and reaches a preselected value, which is referred to as the trigger voltage, by means of which the transistor organ1 is biased in the other direction in a time interval, which is referred to as the trigger release time. When the voltage at junction 141 reaches the trigger voltage, the emitter-base junction of Q1 is forward biased. Now the element 139 acts like a base resistor, the value of which depends on the ambient brightness, and supplies a base current bias, which causes the transistor 1 to conduct the collector current at the output electrode, which flows through the resistor 132 and increases the voltage drop across it and the voltage at the Input electrode of transistor g2 decreased. This reduces the forward bias of transistor g2, resulting in a decrease in the flow of current through the latter and causing the voltage drop across bias resistor 136, thereby further increasing the forward bias across transistor g2. This positive feedback between the two stages of the voltage-dependent trigger circuit causes the conductivity to suddenly switch from g2 to Qv when a sufficiently high collector current is available in transistor Q1. Assuming that this is the case, the various current flows through the bias resistors 132 and 136 create conditions for second values of biases on the electrodes 128c and 128e of Q1, so that the conductivity of g2 decreases sharply and suddenly is and thereby suddenly de-energized the electromagnet 124, whereby the closing lamella is immediately released. As soon as the closing lamella is released, it begins to move out of the open position and, as mentioned above, ends the exposure as soon as it is in the covering position. Accordingly, the shutter stops exposure in response to the shutdown of the shutter actuators. Referring to FIG. 5 it can be shown that the time interval between the initiation of the time delay process (opening of the switch S2) and the end of the time delay process (the trigger voltage is reached) is the same as the time interval between the initiation and termination of the exposure, provided that the inertia of the opening lamella is the same as that of the closing lamella. Then the time period is the same even if the mentioned time periods do not exactly coincide. It is assumed that the delay times are essentially the same, so that the actual exposure time corresponds to the time determined by the trigger circuit. From Fig. 5 it can be seen that the time interval between the release of the opening lamella and its initial movement for the purpose of opening the switch ^ can be made extremely small by using a sufficiently strong spring to bias the lamella. Furthermore, the time between closing the switch S1 and reaching the maximum retaining force on the closing lamella can be kept extremely short by various factors. Accordingly, it can be determined that all processes between closing the switch S1 and opening the switch S2 take place essentially simultaneously, in particular because the relevant time segment represents only a small fraction of the actual exposure. It can therefore be assumed that the actual exposure time essentially coincides with the time segment in which the current flowing through the coil of the electromagnet is large enough to keep the shutter in the release position, or, in other words, the actual exposure time coincides with the time the shutter actuator is energized. Patent claims: 1. Photographic shutter with two shutter members running one after the other, from the first to release when it expires and the second to close when it expires the shutter opening causes, and with a 909530/337 by a first control switch by applying to a built-in voltage source in the standby position transferable exposure control circuit or exposure control circuit, the timer function of which is triggered by a second control switch, and in which a relay drops with a delay depending on the current flow through a photoresistor to release the second shutter member a part moved to release the lock causes the second control switch to be actuated approximately simultaneously with the release of the sequence of the first locking member, characterized in that the part moved to release the lock _{actuates the second control switch (S 2} ) directly. 2. Closure according to claim 1, characterized in that the part moved to trigger the closure is designed as a pawl (106) which actuates the control switch (S ₂ ) when it moves to release the first closure member. 3. A closure according to claim 2, characterized in that the pawl (106) of one is moved under the action of a spring running slide, which in turn by the release handle is released to the process. 4. A closure according to claim 3, characterized in that the transmission of motion from the running carriage is carried out on the latch through an inclined surface attached to it, against which a cam of the slide runs against. For this purpose 2 sheets of drawings