DE2034801C3 - Electrically controlled shutter for photographic cameras - Google Patents

Description

The invention relates to an electrically controlled Shutter for photographic cameras with a photo resistor and a comparison resistor, which are connected in series in a control circuit to determine the object brightness and one Control electromagnets, and with a sector control member actuated by the magnet, which is controlled by the Sectors the shutter according to the exposure time determined by the control circuit the course of which gradually increased, the control circuit, the degree of opening of the diaphragm and the Controls exposure time so that the required amount of light is achieved.

When using a known shutter (DT-AS 12 32 464), the exposure is after Achievement of the full degree of opening by the end of the exposure with the aperture fully open continued. The recorded image will therefore be out of focus due to the large aperture. the Invention makes use of the known fact that with a less open aperture and with an image of better quality can be achieved according to a longer exposure time. With the known shutter is not feasible because it can only be fully opened and the Exposure is continued with the aperture fully open if necessary.

The invention has for its object to design the known closure so that when the

The required exposure time is longer than the time required to fully open the shutter, a smaller degree of shutter opening is maintained until the end of the exposure, so that the exposure is continued after reaching the smaller opening until its end at this opening. In particular, the new shutter is suitable for taking pictures of still objects of low brightness, in which the camera cannot shake the image, since it is constructed in a correspondingly stable manner. _1C

According to the invention, this is achieved by a drive plate which can be stopped by the magnet and a changeover switch operated by the drive plate, by means of which the time constant of the exposure time determining /? CG! Iedes is changed, the changeover switch depending on the excitation or de-excitation of the magnet in Depending on the exposure time determined by the measuring circuit in comparison to the opening time of the sectors, it is brought into one of its two positions, in which the object brightness is determined by the measuring circuit before the beginning of the sector opening and if the determined exposure time is longer than the time required to fully open the sectors is, a locking mechanism stops the sectors at the opened degree and the exposure is continued at this degree of opening until the required amount of light has entered, as well as by a timer controlled by the sector control member to cancel the short circuit of the time-determining capacitor. J ₀

In one embodiment of the invention, a drive plate is provided that the closing process of the Sector control element causes, before the exposure of the electromagnet depending on the measuring circuit determined exposure time in comparison with the time required for the full opening of the aperture Determined starting position of the drive plate and if the determined exposure time is longer than that Time for the shutter to open fully, the movement of the sector control element through the changed starting position the drive plate is limited, while if the determined exposure time is shorter than the time for the is full opening of the diaphragm, the drive plate assumes an initial position in which the sector control member is free in its movement and the diaphragm can be fully opened.

The mode of operation of the new diaphragm shutter proceeds in such a way that when the shutter starts to release the Measuring circuit is actuated that the drive plate is stopped by the magnet when the measuring circuit has found that the exposure takes a longer time than that to fully open the Sectors of the shutter took time. In this case, the is connected to the RC circuit Changeover switch brought into a changeover position. As the aperture continues, it shifts the sector control member and is controlled by the locking mechanism connected to the drive plate Achieving a certain degree of opening hindered the full opening. With this degree of opening * o the exposure continues.

In this way the task is solved. Images of excellent quality with a correspondingly long time Establish exposure time. In another embodiment, a manual operating plate is for the sliding contact of a sliding resistor is provided, which determines the reversing voltage of a switching circuit in the electrical control circuit, with which the movement of the sector control member and thus the degree of opening of the sector to any desired extent can be limited if the determined exposure time is longer than that for fully opening the shutter needed time. When the exposure time determined by the measuring circuit is shorter than the The line required to fully open the sector can be done using the manual actuation plate Locking of the sector control member can be automatically released by the electromagnet. Further the switch from the slide resistor operated according to the state of the electromagnet can open the fixed resistor can be switched when the exposure time determined by the detection circuit is shorter than the time required to fully open the shutter.

The invention is described in more detail below with reference to the drawings.

Fig.! shows a shutter in a side view for a camera according to the first embodiment, before the release process is initiated;

F i g. 2 is also a side view of the main parts of the first embodiment of FIG. 1 after Release method, in which a programmed exposure is carried out;

F i g. 3 shows an example of the electrical control circuit for an embodiment according to FIG. 1 and 2;

Fig. 4 shows another example of the electrical control circuit for the same embodiment of the Clasp;

Fig. 5 shows another example of the electrical control circuit.es for the embodiment according to F i g. 1 and 2;

Fig. 6 shows in a diagram the relationship between exposure time and degree of opening of the sector in the first embodiment;

F i g. 7 shows in a diagram the characteristic of the photoresistor in those shown in FIGS electrical control circuits;

F i g. Fig. 8 is a side view of the main parts of the electrical fastener for a according to the present invention Camera before the release process according to a second embodiment of the invention;

Fig. 9 is a side view of the main parts according to the release method of the second embodiment, the exposure being made in the state in which the degree of opening of the sector is restricted;

F i g. Fig. 10 shows an electric control circuit for a shutter according to the second embodiment;

Fig. 11 is a side view of the main parts of the electrical shutter according to the invention for a camera according to the release method according to a third embodiment, wherein the exposure is made in the state in which the restriction the degree of opening of the sector is freely adjustable;

F i g. 12 shows an electrical control circuit for this third embodiment according to FIG. 11;

Fig. 13 shows a side view of the structure of a fourth embodiment;

Fig. 14 shows an electrical control circuit for the fourth embodiment according to FIG.

In the embodiment according to FIGS. 1 and 2, a plate-shaped sector control member 1 is provided. The same thing however, like the known locking ring, it can also be designed in a ring shape. Ar. this sector controller, that by the spring 15 in Fig. 1 to the right is biased, the stop Ic; the one with the

Release lever 9 described below is engaged, and two pins la and \ b attached. The pin la rests on the contact disc 26 of the timer switch 53, which is designed as a closing switch, and holds this switch 53 closed in the tensioned position in FIG. 1. The pin Xb is always on the lever of the part gear 12 of the counter-clockwise influenced controller; as a result, the sector control member 1, when it is moved to the right by the force of the spring 15, is braked such that it moves at a constant speed and only slowly. 2 with the release rod is referred to, which is moved by pressing the release button, not shown in the drawings, against the force of the spring 10 to the left. During this movement to the left, the lateral projection 2a of the release rod 2 comes to rest against the release lever 9, which is rotatably mounted on the axis 9a and is biased counterclockwise by the spring 13. He releases the engagement of the pawl 9b of the Auslösehcbcls 9 with the stop lc of the sector control member 1. The release rod 2 also has at the end of the actuating head 2b and a second lateral projection 2c, which carries the contact discs 21 and 22, which the contacts described below 19 and 20 of switches 51 and 52 operate.

The control lever 3, which has three arms 3a, 3b and 3c. is rotatably mounted on the axis 3d and biased counterclockwise by the spring 11. The stop arm 3 a rests on the pin 1 a of the sector control member 1. The drive plate 5 is rotatably mounted on the axis 4 and is also biased counterclockwise by the spring 18. On its circumference it has the pins 5a, 5b, 5c, 5d and two engaging teeth with the inclined surfaces 5f, 5g .

The stop pawl Tb is formed at the end of the switching lever 7 facing the drive plate, which is mounted on the axis Ta and is biased counterclockwise by the weak spring 14. When the shutter is cocked, this stop pawl Tb is engaged with the inclined surface 5f of the one engaging tooth of the drive plate 5. The switching lever 7 also has an armature 7c at its other end which faces an electromagnet M.

One arm Sb of the locking lever 8, which is mounted on the axis 8a and is influenced in the counterclockwise direction by the spring 16, faces the actuating head 2b of the release rod 2, and the other arm 8c rests on the pin 5f of the drive plate 5.

If the control lever 3 rotates clockwise about its axis 3d, the position shown in FIG. 1 the position of the drive plate 5 shown, its control arm 3c on the pin 5a of the drive plate 5. This contact is canceled again with a subsequent counterclockwise rotation of the drive plate 5 and the arm 3b of the control lever 3 rests on the pin 5a. In addition, a changeover switch to be actuated by the pin 5c of the drive plate 5 is provided, consisting of the contact disk 23 and the two mating contacts 24 and 25. In the tensioned position of the lock according to FIG held closed against their own spring force. When the drive plate 5 is rotated counterclockwise, the contact disk 23 switches over to the mating contact 25,

The projection 2c of the release rod 2 touches the contact 19 with the contact disk 21 and the contact 20 with the contact disk 22 and thus closes the two switches 5 X and 52.

An example of the electrical control circuit containing the switches mentioned is explained with reference to FIG. The combined photoresistor P, which comprises the two photoresistors CdS 1 and CdS 2 connected in series, is connected to the current source E in series with the switch 51; its second

ίο connection is connected to the contact disk 23, which is switched by the pin 5c. One of the two capacitors C2 and CI connected in parallel with their second connection is connected to the two counter contacts 24 and 25 of the contact disk 23, and the comparison resistor R 1, which is also connected to the switch 51, is connected in series with them. The time switch 53 short-circuits the aforementioned switch 23, 24, 25 and the two parallel capacitors C1, C2.

The switch 52 lies parallel to the comparison resistor R 1 and can short-circuit it. The connection point between the combined photoresistor P and the contact disk 23 is at the base of the transistor Ti. The collector of this transistor Ti is connected to the anode of the current source E via the variable resistor /? 4 and to the base of the transistor via the resistor R 5 TI connected. the emitters of the two transistors TX and T2 are jointly connected to the cathode of the current source E via the bias resistor R3 . The coil of the electromagnet M is switched on between the collector of the transistor Γ2 and the anode of the current source E. The resistor R 2 is a correction resistor which is connected in parallel to the individual photoresistor CdS2.

If the release rod 2 of the locking mechanism described above is moved to the left, the actuating head 2b first presses on the arm 8b of the locking lever 8 and rotates it against the force

the spring 16 clockwise, whereupon the other arm 8c evades the pin 5c. At the same time comes the Contact disk 211 with the contact 19 in contact, whereby the switch 51 is closed. Since the Time switch 53 is still closed at this point in time

is, a circuit to determine the object is closed, consisting of the combined photoresistor P and the comparison resistor RX , which determines whether the brightness of the object is a longer exposure time than that for the full opening of the sector

(not shown in the figures) makes required time T necessary or not. If the object brightness is low and the exposure time is therefore longer than the time T, the transistor Γ2 becomes conductive and the electromagnet M becomes conductive through the action of the photoresistor

gets excited. The armature 7c of the switching lever 7 is therefore attracted by the electromagnet M , so that the pin 5c holds the contact disk 23 with the mating contact 24 in contact and the stop pawl Tb is engaged with the inclined surface 5 / "of the first tooth of the Anlricbsplattc 5. Die rotation of the Anlricbsplattc 5 is locked to say in the g in F i. 1 shown state. the contact disk 22 comes by the further movement of the trip bar 2 to the left with the contact 20 in contact and the switch 52 is closed. the comparison of resistance RX is shorted hereby , so that the resistance between the base of the transistor Π and the cathode becomes 0 and the transistor T2 remains conductive; the rotation of the

Ii

Drive gap 5 is further locked by the stop pawl Tb. Then the projection 2a of the release rod 2 rests against the release lever 9 and rotates it against the force of the spring 13 in a clockwise direction. The engagement of the pawl 9 with the stop Ic of the sector control member 1 is hereby released. The sector control member 1 begins to move relatively slowly to the right due to the tensile force of the spring 15, since the part gear 12 must be rotated by the pin 1 b during this movement. The pin la of the sector control member 1 moving to the right rotates the control lever 3 clockwise via the stop arm 3a. During this rotation, the control arm 3c hits the pin 5d of the drive plate 5. The control lever 3 comes to a standstill in this position and stops the movement of the sector control member 1 to the right. The degree of opening of the sector is thereby limited to a certain degree of full opening.

Simultaneously with the rotation of the control lever 3, the time switch S3 has opened due to its inherent elasticity, whereby the short circuit of the changeover switch 23, 24, 25 and the parallel capacitors C 1, Cl is canceled. The combined photoresistor P is therefore connected to the capacitor Cl through the contact disk 23, the contact 24, whereby a delay circuit (in the reversed position of the switch from FIG. 3) is formed which charges the capacitor Cl.

If the capacitor C2 has reached a certain voltage, the transistors 7Ί and T2 are reversed, and the electrical current through the coil of the electromagnet M breaks off. The armature 7c of the switching lever 7 is released from the electromagnet M. The force of the spring 18 pushes the inclined surface 5 / · the stop pawl Tb aside and the drive plate 5 is rotated counterclockwise. The pin 5a rests on the arm 3b of the control lever 3 and rotates it counterclockwise. The stop arm 3a moves the sector control member 1 against the force of the spring 15 to the left. The sector is then closed and the exposure is completed. Thereafter, the locking lever 8 rotates as a result of the return movement of the release rod 2 to the right, attracted by the spring 16, back counterclockwise. The arm 8c comes to rest on the pin 56 and rotates the drive plate 5 clockwise. The drive plate 5 returns to the position of FIG. 1 and is tensioned against the spring 18.

If the brightness of the object is high and the Slromkrcis to determine this Objekthelligkcit determines an exposure line that is shorter than ι ic time period T. the transistor Tl remains blocked by the action of the photoresistor / 'with the closing of the switch .Sl. The electromagnet M is not energized, and the drive plate 5 rotates because seeds! is blocked by the Umschallhcbcl 7, following the arm 8c of the locking lever 8 rotated by the actuating head 2b, counterclockwise. At the same moment in which the stop pawl Tb of the 1 * switching lever 7 engages the second tooth of the drive plate 5 with the inclined surface 5g , the switch .V2 is closed, whereby the Verglcichswidcrsiand R 1 is short-circuited; the transistor 7 2 wire conductive. The friction plate "5" comes to a standstill through the grille <· ■> of the stop pawl Tb of the switch lever 7, which is attracted by the electromagnet M now carrying current, through the inclined surface 5g . is by its own elasticity from the contact 24 to the contact 25 around, and the capacitor C1 as g in F i. 3, connected to the combined photoresist P. the projection 2a of the trigger rod 2 comes into abutment on the trigger lever 9, this twisted in Clockwise and releases the engagement of the pawl 9b with the stop Ic of the sector control element 1. The sector control element 1 thereby moves to the right and turns the control lever 3 clockwise. whose control arm 3c is located, the sector control member 1 can, as shown in FIG. 2, the position corresponding to the shorter exposure time in which the sector is fully opened.

In addition, the timer 53 opens by moving the sector control member 1 to the right, the short circuit of the capacitor C 1 is canceled and it is charged to a certain voltage; the voltage at the base of the transistor Ti increases and the transistor Tl is blocked. The excitation current de; Electromagnet M tears off, whereupon the drive plate 5 pushes the switching lever 7 aside and continues to rotate. The pin 5a rests on the arm 3b de; Control lever 3 and turn it counterclockwise. The sector control member 1 is thereby moved to the left and closes the sector. The exposure ends. As a result of the return movement of the release rod 2, the drive gap 5, as already described, can return to its starting position.

In Fig. 6 shows the course of the sector opening D with the exposure time 1 comparatively once for the state of the art (line AC) and once for a shutter according to the invention (line AB) . As long as the exposure time is less than or equal to the time period T , the brightness / exposure time is in a certain functional relationship. If the exposure time exceeds time T, the degree of sector opening is limited to a certain time; If the above-mentioned functional relationship between brightness / and exposure time were maintained, the exposure time would be insufficient. Therefore, the relationship between the brightness / un <exposure time must be different from the time tan. Un to achieve this, the photoresistor must have a kinked characteristic as shown in FIG. 7; for this reason, a combined photoresistor is used in the invention.

If a longer exposure time is required, the sector opening is limited to a dimension that is smaller than the full opening. The exposure zci determined by the delay circuit must therefore be discontinuous; it makes a jump at time T and is extended. Since / .i the delay constant of the delay current crisis must change at time T. This win is achieved by the changeover switch, in that the contact disk 23 either aligns with the mating contact 24 or 25 and so switches one of the two capacitors Cl and Cl, which have different capacities, into the circuit.

Instead of switching the capacitors through the switch 25 24, 25, the base of the transistor Tl can be connected to the resistor Rb or to the resistor Rn , as in the assessment circuit according to FIG

709 642/12!

to change the transistors of the switching circuit. As in FIG. 5, two photoresistors P I or P2 can be optionally connected in series to the delay capacitor C through the changeover switch 23, 24, 25.

A second embodiment of the invention is shown in FIGS. The control lever 3 and the drive plate 5 of the first embodiment are formed in one piece. The process of the excitation and demagnetization of the coil of the electromagnets caused by the circuit for determining the brightness of the object is reversed in this embodiment as in the first embodiment. Namely, the switch 52 is normally closed, and it is opened after the switch 51 is closed by the trip method. When the exposure time is shorter than the time T , the electromagnet is energized by the closing of the switch 51. If the exposure time is longer than the time T *, the electromagnet is not energized when the switch 5 1 is closed, but only when the switch 5 2 is opened.

As shown in Fig. 8, instead of the control lever 3 and the pins 5a and 5c / in the first embodiment, a long control arm 5 /? worked on the drive plate 5. This control arm 5h is located in the area of movement of the pin t.'i of the sector control member 1 which is biased to the right. The contact disk 22 of the switch 5 1 is usually in contact with the contact 20. If the release device 2 is actuated, the contact disk 21 first comes into contact with the contact 19, and the shoulder 51 is closed. The further movement of the release element 2 removes the contact between the contact disk 22 and the contact 20 and opens the switch 52. The rest of the structure is the same as that of the first embodiment.

In Fig. 10 the electrical control circuit for this embodiment is shown. The circuit for determining the object brightness, consisting of the comparison resistor R 1 and the photoresistor P \ is parallel to the delay current circuit, consisting of the combined photoresistor P and the capacitors Cl and C2 to be connected to this photoresistor P via the switch 23, 24, 25. The connection point of the comparison resistor R 1 and the photoresistor P ' is connected to the base of the transistor Γ3. The collectors of the transistor Γ3 and the transistor 7Ί, at the base of which the connection point of the combined photoresistor P and the changeover switch is located, are connected in common to the resistor / 4, and the emitters of these two transistors are connected to one another by the normally closed switch 52. The rest of the structure is the same as that of the circuit in FIG.

If the object brightness is sufficiently large that the necessary exposure time is shorter than the cell span T, the transistors T1 and 7'3 remain blocked after the switch 51 is closed because the resistance value of the photoresistor / ″ is less than the resistance value of the comparison resistor R 1 The transistor Γ2 becomes conductive. The Umschallhcbel 7 is attracted by the electromagnet M. Even if the arm 8c of the locking lever 8 releases the locking of the pin 56 after actuation of the release length 2, the stop link Tb prevents its counterclockwise rotation by its engagement with the inclined surface 5i of the first tooth of the drive plate 5; the control arm 5Λ remains at a distance from the pin la, and the movement of the sector control element 1 to the right until the sector is fully opened is released as soon as the projection 2a of the release rod 2 rotates the release lever 9.

On the other hand, if the object helicity is low and the resistance value of the photo opposition P ' is high in comparison with the comparison opposition R 1, the transistor φ3 becomes conductive when the switch 51 is closed; the transistor T2 is therefore blocked. With the

ίο rotation of the locking lever 8 pushes the drive plate 5, the stop pawl Tb of the switching lever 7 aside. The drive plate 5 is rotated until the second tooth of the stop pawl Tb faces and it comes into engagement with the inclined surface 5g. The drive plate 5 comes to a standstill because the switch 52 has meanwhile been opened and, consequently, the transistor Γ2 is only controlled by the transistor 7Ί, i.e. controlled, and the energized electromagnet M pulls the switching lever 7. As a result of the rotation of the drive plate 5, the control arm 5Λ is close to the pin la and offers it a stop when the sector control element 1 moves to the right, so that this movement is limited. The sector opening is thus kept at a certain value. It corresponds exactly to the first embodiment that the movement of the sector control member c 1 to the right is effected by the further movement of the release rod, whereby the switch 53 is also actuated and the charging of the delay capacitor C1 or Γ2 begins. When the capacitor in question reaches a certain voltage, the transistor Ύ2 is blocked and, as a result, the drive plate 5 is rotated counterclockwise by the force of the spring 18; the Sieuerariii 5Λ pushes the pin la and thus the sector control glicd 1 to the left, so that the sector is closed again.

Fig. II shows a third embodiment of the invention. In the event that the determination current Krcis determined exposure time is longer than that

Time span 7; can use the Degree of opening of the sector manually determined as desired will. The switch 56 is opened or closed by rotating the drive plate 5 by one tooth. concluded that if the determined exposure time

is longer than the line T , the indicator lamp W of the electrical control circuit shown in FIG. 12 is ignited. This switch 56 can interact with the changeover switch 23,24,25.

As in the first embodiment, the

Anhalleklinkc Jb, if the determined exposure time is longer than the time period T, by the action of the electromagnet Min, engagement with the inclined surface 5 / of the first tooth is held when the switch 5 1 is closed, and the contact disc 23 is in contact with the mating contact 24 Contact. The switch Sf , which interacts with the changeover switch 23, 24, 25, is closed and the lamp W is ignited

the end 30c of the rotatable about the axis 30a stored connecting lever 30 in the opposite direction Moved towards the left as the pin 306 at the lower end of the connecting lever 30 with the fork 32a de: manual Belätigiingsplalte 32 is engaged

On the other hand, the control lever 3, which rests with its stop arm 3 ″ on the pin 1 a of the sector control element I, also moves in the clockwise direction during its clockwise movement caused by the release process

IO

impact arm 3a in contact with the end 30c of the connecting lever 30, so that the latter Movement of the sector control member I is restricted to the right.

On the laterally downwardly pointing projection 32b, the manual actuating plate 32, the sliding contact 33 is provided, which slides on the sliding resistor 34 and thus forms a variable resistance. This variable resistor is, as shown in Fig. 12, connected to the base of the transistor Tl . The switching voltage of the switching circuit consisting of the transistors T 1 and 72 is therefore variable in conjunction with the determination of the degree of sector opening made by the manual actuation plate, whereby the correct exposure time can be set.

If the exposure time determined in the embodiment according to FIG. 11 is shorter than the time period T, the electromagnet M is not energized, even if the switch 5 1 is closed. The inclined surface 5 / 'of the first tooth thus pushes the stop pawl Tb aside, and the drive plate 5 rotates counterclockwise. By closing dos switch S 2 of the transistor 7 "2 is turned on, so that the stopping pawl Tb is gehallen by the energized electromagnet M in engagement with the inclined surface 5g of the second tooth. This will open the switch 56 and the indicator lamp! Extinguished. In this case, the end 30c of the connecting lever 30 is brought into the position by the manual actuation plate 32 in which it releases the full opening of the sector.

In the above-mentioned embodiment, the degree of opening of the sector is determined according to the length or shortness of the exposure time compared to the time period T determined by the operation of the detection circuit and with a short exposure the sector can be fully opened automatically. As in the second embodiment, the sector is closed by the Stcucrarm 5 / jder drive plate 5. Furthermore, to limit the degree of opening of the sector, an articulated arm 36 is articulated to the end of the connecting lever 30 facing the Scktorsteucr member 1 via the axis 36 «·) . The projection 36c of this articulated arm 36 is in engagement with the cam plate IT, which is mounted in one piece with the anti-friction plate 5 or fixedly connected to it so as to be rotatable on the same axis 4. The control projection ibb of the articulated arm 36 is located, depending on the light conditions, inside and outside the range of motion of the pin 1.) on the sector control element 1 that is biased to the right.

When the detected exposure time is shorter than the time T, the stop link Tb is held in engagement with the inclined surface 5 / "of the first tooth of the drive plate 5 by the electromagnet M fed by the detection circuit. The rotation of the drive plate 5 is thereby locked, and the position of the control cam 37 allows the control projection 3bb to evade the movement of the pin la of the sector control element 1. If an exposure time is determined which is longer than the time period T, the stop pawl Tb released by the detection circuit in the movement is removed from the first tooth of the self The rotating drive plate 5 is pushed away and comes into engagement with the inclined surface 5 ^ 'of the second tooth. In addition, the control cam plate 37 pushes the articulated arm 36 in the direction of the sector control member I by the rotation of the drive plate 5 about one tooth now in the range of motion of the pin la the vorgesp to the right annt sector control element 1. In this case, the variable resistor 33, 34 of the third embodiment is designed so that the changeover switch 23, 24, 25 can switch from it to the fixed resistor Wc (see FIG. 14). The detection circuit is shown in FIG. 14 not shown, but is identical to that of the second version.

In addition 5 sheets of drawings

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Claims (8)

Patent claims: 1. Electrically controlled shutter for photographic cameras with a photoresistor and a comparison resistor, which are connected in series to determine the object brightness in a control circuit and which control an electromagnet, and with a magnet-actuated sector control glicd, the shutter by the sectors according to the The exposure time determined by the control circuit gradually increases as it expires, the control circuit controlling the degree of opening of the diaphragm and the exposure time so that the required exposure is achieved, characterized by a drive plate (5) which can be stopped by the magnet (M, 7) and a from the drive plate (5) actuated changeover switch (23, 24, 25) through the time constant of the exposure time determining /? C element (PX, Cl, C2; P, Q TX, Tl; Rb, Ra; Pi, P2, C) is changed, the changeover switch depending on the excitation or de-excitation of the magnet (M) depending on the The exposure time determined by the measuring circuit (P, RX) is brought into one of its two positions in comparison to the opening time (T) of the sectors, in which the object brightness is determined by the measuring circuit (F, RX) before the beginning of the sector opening, and when the determined exposure time is longer than the time (T) required to fully open the sectors, a locking mechanism stops the sectors when the degree of opening has been reached and the exposure is continued at this degree of opening until the required exposure is achieved, as well as a timer (53) controlled by the sector control element (1) ) to cancel the short circuit of the time-determining capacitor (Cl ₁ C 2, C). 2. A shutter according to claim 1, characterized in that the photoresistor (P) in the delay circuit is a combined photoresistor (CdS 1, CdS2) with a kinked characteristic. 3. A shutter according to claim 1, characterized in that a drive plate (5) is provided which causes the closing process of the sector control member (1), wherein before the exposure of the electromagnet (M) depending on the exposure time determined by the measuring circuit in comparison with that for the full opening of the shutter required time (T) determines the initial position of the drive plate (5) and if the determined exposure time is longer than the time (T), the movement of the sector control member (1) is limited by the changed initial position of the drive plate (5) , while, if the determined exposure time is shorter than the time (T) , the drive plate (5) assumes an initial position in which the sector control member (1) is free in its movement and the diaphragm can be fully opened. 4. A shutter according to claim 3, characterized in that a locking lever (3) is coupled to the drive plate (5) in the locking mechanism, which depending on the state of the electromagnet (M) either the sector control member (1) and the drive plate (5) locked in its cocked position or it releases. 5. A shutter according to claim 3, characterized in that the drive plate (5) has a control arm (5Λ) for the movement of the sector control member (I) which, when the electromagnet (M) locks the drive plate (5) in its tensioned position , located at a sufficiently large distance from a pin (la) provided on the sector control element (1) so that the sector control element (1) is released for full opening of the sector, or in the released position of the drive plate (5) the movement of the sector control element (1 ) limited to a certain level. 6. A shutter according to claim I. characterized by a manual actuating plate (32) for the sliding contact (33) of a sliding resistor (34). which determines the reversing voltage of a switching circuit in the electrical control circuit, with which the movement of the sector control element (1) and thus the degree of opening of the sector can be limited to any degree if the exposure time determined is longer than the time (T). 7. A shutter according to claim 6, characterized in that, when the exposure time determined by the measuring circuit is shorter than the time (T) required to fully open the shutter, the sector control member is locked by the electromagnet ( M) is automatically canceled. 8. A shutter according to claim 6, characterized in that the changeover switch (23, 24, 25 ) actuated according to the state of the electromagnet (M) switches from the slide resistor (33, 34) to the fixed resistor (Rc) when the detected by the measuring circuit Exposure time is shorter than the time required to fully open the aperture (T).