DE2159152A1 - BATTERY OPERATED PHOTOGRAPHIC TWO SECTOR SHUTTER WITH MAGNETIC DRIVE AND ADDITIVE THRESHOLD COMPENSATION FOR INTERCHANGEABLE LENSES - Google Patents

Description

Battery operated photographic two sectors shutter with magnetic drive and additional sill compensation for wax lenses.

The increasing desire to have different lens focal lengths in photographic Optimally adapting single image cameras to the respective subject, led to that more and more cameras were equipped with interchangeable lenses. This development brought with it that the focal plane shutter continued its well-known Disadvantages compared to the central lock came more and more to use.

The reason for this is primarily to be found in the fact that the central or intermediate lens shutter the drive mechanisms for the sector system, the time formation device, the adjustment lever, as well as the actuation and release mechanism ring-shaped Us das Sector system are arranged and so much assigned to the lens than to the camera. In addition, all controls originating from the camera must be mechanized be transferred to the closure, which beidngt a high cost of coupling members. Such interchangeable lens systems require a complete shutter for each lens, which significantly increases the cost of the lenses and ultimately makes the camera more expensive.

Another version assigns the shutter on the camera side, with either only the front part of the lens is exchanged, or the intermediate lens lock will add Minter lens shutter, which although the replacement of the entire lens system allowed, but here the shutter opening sets limits.

The invention relates to a photographic lens shutter for Wax lenses, in which all operating elements, control, switching and timing device on the camera side and only those necessary to operate the sectors and aperture system Drives and their holding and control elements are assigned on the objective side. The locking system is divided into lens shutter and lens mount.

The lens shutter can rust with and without a worm gear be, is provided with a coupling tube and has a corresponding Locking device, which the inner same position of the lens in the Camera guaranteed.

The lens mount, which is used as a camera standard or as a camera front panel formed a can, is equipped with an automatic coupling device and has such a large lens opening that even the most powerful lenses can dip into the coupling opening with a correspondingly large Minter lens. There there will be no shutter or bathing organs all control and switching processes are carried out on the camera side and can either be done directly mechanically on the lens mount or electronically via a remote control will.

According to the invention, a sector and drive system was developed, which, taking into account the design explained at the beginning, is achieved by a as simple as possible, reliable and parts-saving construction, as well as through exact functionality. In addition, the drive system must be used for actuation of the sectors necessary mechanical forces without interference, with little loss and as much as possible easily transferred from the camera to the lens shutter via the coupling system will.

A mechanical transmission would either be by means of a tension spring direct or stored force, which is needed after the triggering and would therefore lead to great mechanical effort.

Definitely the simplest and most reliable power transmission is the electromagnetic force, which acts like a pulse. That is, a Current impulse excites a drive magnet and opens the shutter, a second current impulse energizes an opposing drive magnet and closes the shutter of the.

As a sector system with reciprocating sectors except the disadvantage of the associated delay in the exposure blanking even nor that of the slow reduction of the magnetic field of the opening magnet and thus adversely affected the short exposure times, a two-sector system was used created, which each equipped with a drive magnet, independently by The impulse is activated and returned to the starting position by means of a return spring is brought.

In order to accommodate the drive magnets as space-saving as possible the plunger magnets arranged in a ring, the magnet armature, which is attached directly to the Sector drive ring is attached, also dips circularly into the solenoid a.

In the case of the two sector systems created in this way, the respective one exists System no frictional connection; the movements become independent caused by the respective drive magnets or by the return spring. Since the The drive magnet independent of the position of the armature in the magnet coil Move sectors. can be adjusted by means of a simple push pin mechanism Stop are created, which counteracts the action of the return spring of the closing sector system limits the full opening and thus forms the aperture.

There are already closures with a separate opening and a separate locking sector systems known, each equipped with a drive magnet are. Most of the time, however, the drive magnets must be kept so large that they can no longer be accommodated in the lock housing. In addition the required voltage increases so high at the moment the drive magnet is switched on, that the arrangement of a correspondingly large energy source would be a prerequisite, on the other hand always make it necessary to carry one or more reserve batteries. Therefore closures with magnetic drive are mostly only for technical photography or Regiestrier- and surveillance systems used and mostly by Metz companies Control devices powered and operated.

Two sector locks are also known, in which the lock sector system for diaphragm formation is controlled.

A lock of this type has a mechanical drive, wherein a sector system performs the conventional reciprocating motion and the aperture sectors initiate the actual exposure time limitation. Here is the delay in the exposure process caused by the back and forth swinging movement switched off, but the mechanical structure is relatively large and thus the Costs and the possible susceptibility to failure.

According to the invention, a two sector system was created in which the first sector system, the opening sector system when the shutter is released by the solenoid the sector system against the action of the return spring in the Moved to full opening. Since this movement occurs only as a result of a short current surge, As soon as I have reduced the magnetic field of the coil again, the sectors would close again, which is done by mini notches in an electro-mechanical Verriagelungseinrichtung is prevented. Krst after expiry of the exposure time, if by a second Current surge of the drive magnet of the closing sector system is excited and the lens opening lock, the locking device, which the opening sector system Hold open, unlocks and releases the sector drive ring, which is located below the action of the return spring closes more slowly than the closing sector system, which is under the action of the drive magnet. After removal of the magnetic field of the closing sector system becomes the closing sectors under the action of the return spring returned to their starting position limited by the push pin mechanism. Thus, the set aperture is formed again and the shutter is back in its Exposure. This sequence of movements allows short exposure times and results high locking efficiency due to short opening and closing times.

Since the closure efficiency depends largely on the drive speed which sector systems are determined, it is from great importance, that the opening time (t1) and the closing time (t3) are as short as possible. Therefore must at the moment the drive magnet is switched on, it is used to build up the magnetic field The required switch-on current is available in full and without a drop in voltage. As a result of the very high current rise when the drive magnet is switched on a direct power supply that is secured over a longer period of time by a portable power supply not guaranteed by a battery pack. The magnetic pulse current must therefore can be transferred and saved accordingly, to then at the moment of switching on of the magnet with full power and without voltage drop, for the shutter opening or closing available.

According to the invention this is achieved in that the matter current by means of of a back-to-back converter correspondingly high transferred and via resistance and Diode charges an electrolyte capacitor. When the capacitor is saturated, it switches the converter turns itself off automatically. At the moment of tripping, the capacitor current is discharged directly into the magnetic coil and the current surge stored in this way builds up like a shear the required force field of the magnet for the drive and drives at high speed the sector system. When the capacitor is discharged, the converter switches itself on back on and unlock the capacitor again in a few seconds. Since with this Shutter system to keep the lens opening open for longer exposure times no magnet holding current is required, the battery current is only used for a short time taken, it is therefore possible with a. relatively small battery pack the power supply to ensure over a longer period of time and many exposures.

Since the current surge is relatively short and therefore the duty cycle is less than 1 X ED is, the conditional heating of the winding of the magnet cannot come into effect; it is therefore possible to keep the drive magnet as small as possible.

The magnet operated with a high overload builds up as a result of the rapid Saturation of the magnetic field, the force field of the magnet abruptly and guaranteed due to the high sector speed a high shutter efficiency.

It is known that di. A certain aperture depending on the opening size Has an influence on the exposure time constant. Will not open fully during operation If the closure is exploited, larger areas result, especially in the case of short periods of time Values where I even double the exposure time depending on the aperture diameter can. The exposure time (effective time) specified in accordance with DIM 19015 leaves the set aperture largely disregarded. To now over the entire aperture range To ensure a constant exposure reading, the shutter opening and closing time are each divided into an exposure-technically active time and an inactive time, the former representing the time that the sectors From the closed state to the respective set aperture diameter and managed to return to the closed state-The second, dt. inactive. Time the Time span is what di.

Sectors need around from aperture diameter to full opening and again to get to the aperture diameter.

Both times together always give the same time span, but Only when the aperture is fully open does the exposure time fully take effect comes; the inactive time is then 0. Change depending on the aperture setting calibrate the values proportionally and result in the total time with the fully open time. Yes the more the shutter opening is dimmed, the greater the inactive period of time, but which now to achieve the constant total time in addition to the active one Open time, fully open time and active closing time must be added. This additi-ve time is formed via an adjustment resistor coupled with the aperture adjustment and supplied to the set cons @ ant time value in such a way that with the same time setting and the respective changed aperture setting, the total time always remains constant. Around a further increase in the accuracy of the timing and a reduction in the spread To achieve the measured values, the triggering of the timing, variable in each case at the Point relocated where the opening sectors form the diameter which the respectively set one Has aperture.

Figure 1. shows the shutter system, consisting of lens with Shutter and lens mount.

Figure 2. shows the structure and arrangement of the two-sector shutter, their sectors and aperture control Figure 3. shows the lens mount and the automatic coupling device.

Figure 4. shows the mode of action of the mutually pressing Clamp balls in the locking groove of the coupling tube.

Figure 5. shows the schematic circuit of the electrical and electronic control of the locking system.

Figure 6 shows the schematic shutter time diagram.

In the drawings, 1. is the lens with the shutter and with II. denotes the lens mount. In Figure 1. there is 1 in the lens. between the front lens 1. and the rear lens located in the coupling tube 2. To recognize the shutter. For the sake of clarity, in this illustration the opening sector system A. omitted to puncture the closing sector system B. and the push pin mechanism C. in the lock housing 3. to be able to better represent. On the closure plate 4., in which the guide grooves 5. for the sector nits 6. of the sectors 7. moves the sector drive ring 8. on which the magnet armature 9. is attached directly. The magnet coil lo.

is the opening sectors and the solenoid 11. is the closing sectors assigned. The return spring 12 moves the sectors against the drive direction in their starting position.

The notch 13., which when fully opened into the notch 14.

engages, is unlocked again when the solenoid is excited. The intermediate disk 16 separates the two sector systems. The push pin 17. which is guided in the locking sleeve 18, which at the same time prevents rotation, acts through the compression spring 19. those located in the lens mount II Control cam 20. of the aperture setting ring 21. The one with the push pin 17. Moving Doppelstauerkurve 22. causes. that the axial thrust of the push pin is deflected into a radial movement acting on both sides. The one moving with it Stop 23 has a limiting effect on the fully open sector drive ring the closing sectors and thus forms the aperture. The opposite.

Adjusting slide 24, which simulates the aperture setting moves, adjusts the changeover contact 25. always so that the opening sector drive ring attached switching cam 26. then actuates the changeover contact when the sectors of the opening sector system A. form the same diameter as the set one Diaphragm diameter of closing sector system B. With the diaphragm adjusting ring 21. is the sliding contact 27. coupled, which via the flat resistor 28. the closure opening and closing time corresponding to the set aperture and the basic exposure time added. The clutch button 29 is connected to the clamping ring 30 in a force-locking manner. The coupling tube 2. releases by inserting the lens into the lens mount by pressing on the release pins 32. the retaining latch 33., which as a result of the Engagement in the groove 34. the clamping ring 30 has kept off. The compression spring 36. moves the clamping ring radially and causes the control cams 37. the clamping balls 38.

thereby the coupling sleeve 31 alternately, against the conical surface the groove located in the coupling tube 2.

There for control. previously described locking systems are two separate circuit required, but from a common power source are fed and operated via an interdependent control. The battery set D. is switched via the control unit E. By switching the switching strip 39. from 0 to Z, the switch 8.1 is closed, the control lamp 40. lights up, at the same time switch S2 is closed. which the circuit for the time-forming unit closes and the release button 41., which is the switch U 1 actuated, is unlocked. By switching from Z to T, the switching cam is activated 42. free switch S2 and interrupt the circuit for the timing unit, simultaneously the release button 43 is unlocked, which via the switch s 3 the magnet 15 energized and releases the lock for the opening sector drive ring. Of the Push-pull chopper G., which via the transformer TR. transforms the battery current and via the diodes D1 and D2 and resistors A1 and R2, the capacitor bank i. Cl u. C2 charges, switches as soon as the full capacity is reached and the over the voltage divider K3 u.

R4 of the glow lamp 44. voltage supplied exceeds the ignition voltage, the transistor Tl through, whereby the output stage transistor T3 is switched off via the translator R2 will. The glow lamp and the capacitor battery only go out after the capacitor battery has been discharged is charged by a renewed oscillation of the chopper.

The time formation unit 1., which is preferably with an electronic Threshold and amplifier circuit is built with diekreten components and represents an integrated circuit JC, loads after actuation of the Umachalters 25. via the adjustable resistance chain 45. the capacitor C3, the Variable resistor R, which is coupled to the diaphragm ring, sets the additive time.

After the threshold voltage has been reached, the switching transistor T4 controlled through and the relay 47 switches over. In the J. Steering Committee, which is located in Lens is located, the drive magnet 10. the opening sectors and the drive magnet 11. the closing sectors and the magnet 15. the electromechanical locking device assigned. The diode n5 lets the current pulse, which move the closing sectors, also get to the solenoid 15. so that the opening sector system can close. The switch 25., which in the starting position the capacitor discharged after the exposure and thus the time formation unit for a new exposure makes ready, is switched by the switching cam 26. This puts voltage on the Circuit is laid and the exposure process can proceed.

Figure 6 underlines the schematic shutter speed diagram Consideration of the shutter behavior in the case of diaphragm-independent display as a result add-on threshold adjustment. Diagram 1. shows the curve of the trapezoid, which records the way in the height and the time in its baseline. From the trigger point, which is below the zero line due to the sector overlap, the opening edge rises to full opening suf, whereby within this path, depending on the aperture setting located variable trigger point of the exposure timing is triggered. The fully open time, which constant time is entered only results in the opening and closing times Total time.

Diagram 2. shows the curve in the dimmed state, where the timer is triggered when the set aperture diameter is reached and after the constant time has elapsed, the additive time is added to the closing flank falls off.

The adjacent time-path diagram shows the theoretical relationship the additive time to the diaphragm diameter.

The operation of the locking system described above is in individual as follows.

As long as the lens is not coupled to the lens mount, If the electrical and electronic switching system is paralyzed, neither can it unintentional power consumption occur. Only after the lens is in the lens mount used and so that the automatic clutch was triggered is not only that optically fixed in the camera system, but the circuits of the locking system are closed, the camera is ready for use.

The switching strip 39. is switched from 0 to Z ", thereby the Release button 41. unlocked, switches S1 and 82 closed, the control lamp 40. lights up. Because the capacitor banks C1 and C2 always immediately after the exposure process are recharged, the push-pull converter will only start to oscillate when the The voltage has dropped due to the capacitors' inherent losses. After setting the Aperture and selection of the exposure time, the shutter is ready to take a picture. By actuation the release button 41. the switch EI disconnects the capacitors C1 from the charging connection and applies the capacitor current directly to the magnetic coil 10. of the opening sector system, which moves at high speed into the full opening. The switch cam 26. switches the changeover switch 25, which is moved in opposite directions with the diaphragm control.

at the moment when the diameter of the opening sectors that of the has reached the set aperture of the closing sectors and thus sets the time lapse of the Schwellwertverwtärkers in progress. When it is fully open, the notch fills up 13th

into the notch 14. of the sector drive ring 8. and holds the Opening sectors fully open. After reaching the threshold voltage, which from the set exposure time plus the additive time of the sector opening and closing time, the integrated circuit J-C switches the switching transistor T4 through and relay 47.

switches the capacitor battery C2 from the charging connection directly to the Solenoid 11. of the closing sector system uç, with part of the pulse current reach the haynet coil 15 via the diode L-5, which is the opening sector system releases and I close again under the action of the return spring. At the same time, the switching cam 26 releases the switchover gate 25. As a result, the time-forming unit becomes currentless and the capacitor C3 is discharged and ready for a new exposure stands. After the magnetic field of the locking sector system has been removed, the effect the return spring 12. moves the closing sectors into full opening until the stop 23. limits the path and thus forms the set aperture.

As a result of the voltage drop at the glow lamp 44. the transistor T1 is controlled and the push-pull converter swings again and charges the capacitors on.

By switching from Z to T, the switching cam 42 gives.

the switch S2 free; the circuit of the timing unit is interrupted, at the same time the test 43rd is cleared.

If the trigger button 41 is now pressed, the will open Opening ketor system, but the timing unit is not activated. That The opening ketor system engages in the full opening and can now be in this state be held until the button 43 is pressed, which closes the switch 83, whereby the magnet 13 is excited and the drive ring of the opening ketor system releases, which shoots itself under the action of the return spring 12. The capacitors Cl were already new after the switch Ul has reached its starting position ran up.

Claims (1)

PATENT CLAIMS 1. Photographic two-sector shutter for interchangeable lenses with two independent drive magnets, which by means of a a converter transformed capacitor pulse current are driven, with a Sector system is controlled by means of a push pin mechanism for the formation of diaphragms, characterized in that the S.ktorensysteme and their drives the lens are assigned and separated during lens recording and shutter control weden. 2. Photographic two-sector shutter according to claim 1, characterized in that the opening gate system always reaches full opening and so long in the open position by means of an electromechanical locking device is held until the timer has reached the threshold value the Schliesektorenasysten is controlled and simultaneously with the excitation of the Drive magnet coil also the magnet of the locking device of the opening sector system free gives. which closes under the action of the Rückolfender langasander like the closing sector system rotating under the action of the drive magnet. After the magnetic field of the closing sector drive has been removed the sectors behind the closed opening sectors through the return furnace moved back into the starting position limited by the diaphragm stop. 3. two-sector shutter according to claim 1 and 2, characterized gekennzeicnet that the drive magnets are designed as ring-shaped segments and that the armatures are attached directly to the sector drives. 5. two-sector shutter according to claim t. - 3rd, thereby marked that a push pin mechanism which one on the control curve of the diaphragm adjustment ring caused raidal movement via a mechanical deflection in two to both sides redirects counter-rotating radial movement. Characterized in that a radial movement is used to adjust a stop segment, which is aimed at full opening Closing sectors limited and so forms the aperture. That opposite Adjustment segment moves a changeover contact synchronously with the aperture setting, which the changeover contact is activated by a switching cam attached to the opening sector drive ring always operated when the opening sectors form the same diameter as the aperture set in each case. 5. two-sector lock according to claim 4, characterized in that that the adjustable changeover contact switches on the timing device, wherein the quiescent current cycle discharges the capacitor of the timer. 6. two-sector shutter according to claim 1 - 3, characterized in that that the lens with a coupling tube in which one is on both sides conically rising groove is provided, the guide sleeve which the The push pin guides the lens in the lens mount against rotation. 7. two-sector shutter according to claim 1 - 6, characterized in that that the clamping balls are arranged in the coupling sleeve of the lens mount so that that they in the uncoupled state in the recess which the control cam of the clamping ring forms can recede and after releasing the retaining latch by the compression spring of the clamping ring via the control cam through the coupling sleeve alternately into the Wute of the coupling tube are pressed. 8. two-actuator shutter according to claim 1 - 7, characterized in that that there are two separate circuits, which are fed by a battery pack are, with a circuit corresponding to the battery current via a push-pull converter transferred and one or more electrolytic capacitors auflld and after reaching the capacitor disconnects the converter. 9. two-sector shutter according to claim 8, characterized in that that each drive magnet is assigned a capacitor bank and that the capacitor current act directly on the drive magnets. le. Two-sector shutter according to claim 8, characterized in that that a second circuit directly with the battery voltage, the timing unit and powers the shutter control. 11. Two-sector shutter according to claim 1 - 10, characterized characterized in that an adjustable resistor is coupled to the diaphragm adjustment which adds the inactive opening and closing times to the fully open time and so with the active opening and closing time the total time, regardless of the aperture setting guaranteed with the same exposure time setting. With regard to the state of the art, reference was made to the following documents. D.P. Kr 3 759 o43 561 DAS No. 1 217 201 DAS No. 1 212 638 DAS No. 1 265 573 THE r. 1 916 473 DAS No. 1 81o 375 Photo closures With electronic Exposure time formation. by W. kentschler, volume 6. Feinwerktechnik 75. 1975. German industrial standard DIN 19015 Lee rs ei t e