DE2032085C - Electric camera shutter - Google Patents

Description

The invention relates to an electrical camera shutter. especially for a single lens reflex camera with light measurement through the lens, with storage of the intensity of the object outgoing light indicating information for the duration of the release.

An electric camera shutter. z. B. for a single-lens reflex camera with load measurement through the lens is designed such that the light falling on a light-sensitive element is interrupted during the release. In this case, a memory element is provided which, from a point in time shortly before the triggering until the triggering itself, stores information that indicates the intensity of the light falling from the object on a light-measuring element. The well-known electric camera shutters of this type contain ' »N switches that set the storage capacitor, which is charged according to the object lighting. after opening the shutter, apply to the control circuit that causes the shutter to close.

The invention is based on the object of another way of connecting the storage capacitor to indicate to the control circuit, with which a more exact storage of the light value is possible.

The invention solves this problem in that the capacitor provided as a storage element with a resistor forms an integrating circuit, leren charging time is determined by another RC element which consists of the photosensitive element and a second capacitor which is an electronic Activate the switch that controls the charging of the storage capacitor, and that the former A signal corresponding to its charge for a control circuit of an electromagnetic capacitor Lock mechanism supplies the trigger pcgel determined by the control circuit.

The light value is saved by a process shortly before the triggering without a Load on the light-sensitive element evaluating the light intensity.

Embodiments of the invention are described below with reference to the figures. It shows

1 shows a control circuit operating according to the invention Door an electric camera shutter,

Fig. 2 shows another embodiment according to The control circuit according to the invention has an electric camera shutter.

F i g. 3 shows a control circuit of the circuit shown in FIG. 2 with additional ones in the charging circuit of the storage capacitor provided switching elements and

F i g. 4 shows a control circuit according to the invention, in which the charging time of the storage capacitor in controlled in a special way.

In the control circuit shown in FIG. 1, an oil filter 1 is shown, which serves as a light-sensitive element and switches with a timer 3 and a voltage source 1 in line A transistor switch 4 is arranged in such a way that it receives at its base the voltage generated at the connection point P between the photoconductor 1 and the transmitter capacitor 3 as a trigger voltage, while its emitter voltage is a potentiometer 5. The collector of this switching transistor 4 is connected to a UcI.us 6. A storage capacitor 7 is charged via a resistor 8 and a relay contact 9. A transistor amplifier 10 with a high input impedance is connected to the storage capacitor 7 Output Q is connected to the limittei of a transistor control circuit 11. The transistor amplifier 10 and the control section 11 have a common emitter resistor 12. A synchronous switch 13 is s It is closed synchronously with the actuation of the shutter and switches on a timer consisting of a resistor 14 and a capacitor 15 connected in series with it. The connection point S of this series circuit carries a varying voltage and is connected to the base of the transistor control circuit 11. An electromagnet 16 for actuating the camera shutter is connected to the collector of this circuit 11. An on / off switch 17 is also provided.

The in F i g. The circuit arrangement shown in FIG. 2 corresponds to that in FIG. 1 but includes it Place the transistor amplifier 10 a comparator circuit 10 ', which makes a comparison between the span voltage of the storage capacitor 7 and the voltage at the connection point S of the timer circuit. The output signal generated by this comparison controls the transistor circuit 11 ', which the in Fig. I corresponds to that shown.

The mode of operation of the electrical camera shutter according to the invention is described below. If the on / off switch 17 is closed after the first half of the actuation of a lock button, the capacitor 3 is charged depending on the resistance value of the photoconductor 1 and thus depending on the intensity of the light emanating from the object; at the same time, the storage capacitor 7 is charged via the relay contact 9 and the resistor C charged. This is set according to the sensitivity of the film used. The capacitor 15 of the Zcitgcbcrschaltunu is still charged because the synchronous switch 13 is still open and the shutter is not yet actuated. The voltage V _u at the capacitor 3 and the voltage V ₁₁ across the storage capacitor 7 have a time course indicated by the following _formulas:;

V _n = e (i -e -r \ c;)

V ₂ - e (i -c "« ic;).

(Π)

Here, E is the voltage of the current source 2, K _{1 is} a resistance value of the photoconductor 1, R _{2 is} a resistance value of the resistor 8, C is the capacitance of the capacitor 3 and C _{2 is} the capacitance of the storage capacitor 7.

If the capacitor 3, when it is charged via the photoconductor 1, reaches a predetermined voltage K _n after the time t from the closing of the switch 17, the transistor switch 4 becomes conductive and the relay 6 is switched on, so that the contact 9 is opened. The duration of the charge of the Speuhnrkondensators 7 is thus determined by the time between the closing of the switch 17 and the actuation of the relay 6. This time is out of the

Form "1 (1)

ί = R ₁ C ₁ ■ In

E -

(Ul)

At this point in time, the voltage K _{12 of} the storage capacitor 7 can be expressed as follows by substituting the formula (III) in the formula (II):

-cr _: c _:

K ₁ C,, E

(IV)

The voltage E and the voltage V ₁₁ are now given so that the expression

-—- —.- = c (base of the natural logarithm) t - v _cv

is. if

^C '- K

is. The voltage V ₁₂ -. of the storage capacitor 7 is then:

V ₁

C2 '

The process that takes place during the first half of the pressure movement of the shutter button is completed in a very short time, although it depends on the light intensity emanating from the object. Therefore it is finished before the release of the shutter at the end point of the further pressure movement of the shutter button.
Synchronously with the shutter opening on release, the synchronous shutter 13 is closed and the capacitor 15 is charged via the resistor 14, which is set, for example, according to the value of the aperture. The voltage V _{1 of} the capacitor 15 increases with progress

f> 5 the line on, and the transistor control circuit 1 i, the emitting output of which is connected to the emitter terminal Q of the transistor amplifier 10 controlled by the storage capacitor 7, switches the Rlektro-

magnets 16 off when the voltage of the capacitor 15 the value

V ₁₃ =

(VI)

reached, where 7 'is the set time value. R _{3 is} the resistance of resistor 14 and C, the capacitance of capacitor 15. For the achievement of these trigger voltage is assumed that the trigger level voltage V _1, the voltage V ₁ corresponds to the Q Ausgangsklcmmc. The lock, which has been blocked against closing by the electromagnet 16 up to this point in time, can now be closed.

As already described elsewhere. If a transistor switch is used to control the shutter speed with a timer circuit that supplies a trigger voltage based on the sensitivity value of the film and the set value of the aperture, the set value of the time t depends on the intensity of the light emanating from the object Formula (Vl) can be obtained as follows:

T = R., C, -In

Assuming that

V ₁ -λ

(VII)

In - _E -_- y-- = h. (VIII)

where b is a parameter. which can be given by a series expansion, results from formula (VIII)

(IX)

When operating the camera shutter according to the invention, the transistor control circuit 11 operates in reverse when its trigger voltage V _{13 reaches} the trigger level V _tl , so that both values are the same. This results in the following new formula from formulas (V) and (IX)

-c '

= E (I - e

(X)

From the formula (X) it can be seen that b = KR ₁ , where K is a constant and R _{1 is} the resistance of the photoconductor 1. An electrical camera shutter designed according to the invention can accordingly determine the setting value of the time T according to the intensity of the light emanating from the object and measured with the photoconductor 1. Furthermore, this value can be determined within a wide range of changes in the light intensity. In the in F i g. 2 compares the comparison circuit 10 'the voltages of the storage capacitor 7 and the capacitor 15, both of which are based on the FIG. 1 have the function described. These two capacitors 7 and 15 are charged, and when the difference between the two voltages reaches a predetermined value, a trigger signal is supplied to the transistor control circuit 11 ', which controls the electromagnet 16 for actuating the shutter in the manner already described.

The storage capacitor 7 is during one of the intensity of the emanating from the object and on the photoconductor 1 falling light charged depending on the time, and the setting value for the time is by a trigger level voltage relative to the trigger voltage supplied by a Zcitgcbcrkondcnsator 15 definitely. It acts during the release of the lock according to the one present at that point in time electric charge. Even with a light measurement through the lens, in which the photoconductor I receives the light emanating from the object and falling through the lens, provides the information of the

ίο Intensity of this light after storage in the condenser 7 the signal for determining the trigger level relative to a change in the voltage of a CR timer circuit per second. This does not work in the same way as the one emanating from the object

is light, but for example according to the set Key word. The information signal to be stored can be stored in the same manner as in the direct light measurement outside the lens can be processed, and there is no additional step to

ίο Storage required, e.g. no logarithmic c Conversion of the information signal. Furthermore, the invention is an electrical camera shutter designed so that the charging line for the storage capacitor 7 by an integrating switching

J ₅ ment is controlled, which contains the photoconductor 1 standing under the action of light from the object. Therefore, no load circuit is required to store the information, and the connection to the voltage source is only during the light measurement

; o required. This saves performance and the oCfiüiirritCiiänisrnüs be vcrciniiiCrii. In the arrangement According to the invention, the setting value of the time is determined by the information in the storage capacitor determines its charging time by the integrating circuit and the light-sensitive contained in it Element is controlled according to the light emanating from the object. this makes possible a selection of the setting of the time within a large change range of the light intensity

40. and thus a versatile application of the invention Closure.

in fig. 1 and 2 is also the release button 101 shown, the axis 102 of which is provided with two pins 103 and 104. A lever arm 105 lies with his

one end on pin 103. Another lever arm 106 is similarly arranged, but has at rest the button a distance to the pin 104. The lever arm 105 is bcwcf and thereby closes the on / off switch 17. The planer arm 106 is moved by pin 104 and acts au! a pawl 108 which füi a drive shaft 107 locked a focal plane shutter. By releasing this drive shaft, the focal plane shutter (i.e. the slot opening) through the focal plane ge

leads and the switch 13 is closed. A drive axle 109 for the subsequent part of the The focal plane shutter is locked by a pawl 110 and is activated by switching on the electromagnet 16 released to close the shutter.

In the circuit arrangement shown in FIG. 2, the drive axle 107 is used for the first part of the Focal plane shutter operated together with the switch 12 by the relay 6.

The circuit shown in Fig. 3 works after

the principle of the circuit according to F i e. 2 with the difference that an additional diode ~ 201 and eir Capacitor 202 are provided in the charging circuit, which consists of the resistor 8 and the memory

Ordered capacitor 7. They form a liooistrap posture with positive Hmiller tension feedback. In the same way, the charging section is formed from resistor 14 and timer capacitor 15. With such an arrangement, the signals I-, _{2 and} V ,, are directly proportional to the line. Therefore, an easy and precise addition of the exposure factors that are present in addition to the light intensity (focus on the turning point and the light template of the film) can be carried out by changing the resistance value of the resistors 8 or 14.

The in F i g. The circuit shown in FIG. 4 differs from the exemplary embodiment already described in that the time for charging the capacitor 7 through one conductivity period of the transistor 4 in each case is hcstinmu. A unijunction transistor 301 is used as the transistor 4 here. The pulse signals generated by this transistor (small amount of electricity) are successively input into the storage capacitor 303 via a diode 302. This capacitor 303 receives a '. adiing. which corresponds to the number of pulses entered.

The time during which these pulse signals are generated is kept constant by a timer circuit consisting of a resistor 304 and a capacitor 305. The number of impulses is determined according to the intensity of the light emanating from the object »-» (higher intensity results in more impulses, nci-in cere I η tensitiit fewer impulses).

The electrical charge or the voltage of the storage capacitor 303 therefore depends on the intensity of the light. The photoconductor 1 and the resistor 304 can be exchanged in the circuit. Since the capacitor voltage corresponds to the sum of the stored pulses, it is directly proportional to the intensity of the light emanating from the object, although no continuous additional storage takes place. The following circuits correspond to those in FIG. 3 constructed embodiment shown.

The formwork arrangement shown in FIG works with impulses to store information. Therefore a change is possible, in which a multi-oscillator circuit instead of tier from the Unijune'.ion transistor existing oscillator circuit is provided. Although iedc of the described embodiments, the resistor 14 and the capacitor Ί5 existing Zeilgeberschalliing contains, whose temporal control effect is possible by charging the capacitor. can also be a Use RC-Citizen Management, in which the timing is done by discharging the capacitor. This embodiment is described > levels equivalent. Then, however, a change in the transistor control signal 11 is required, dall transistors with a different conductivity type ver are turned and the Apschlusspunkl of the Schill age 13 is relocated.

For this purpose I sheet drawings

309 607/413

Claims (8)

Patent claims: 1. Electrical camera shutter, especially for a single-lens reflex camera with light measurement through the lens, with storage of the intensity of the light emanating from the object information indicating the duration of the trip, characterized in that the door as a storage element provided capacitor (7) with a resistor (8) an integrating circuit forms whose charging time is determined by another RC element, the one from the light-sensitive Element (1) and a second capacitor (3) comprising an electronic switch (4; 301) which controls the charging of the storage capacitor (7; 303), and that the capacitor (71 a signal corresponding to its charge for a control circuit (111 of an electromagnetic Lock mechanism (16) supplies. that determines the trigger level of the control circuit dl). 2. Camera shutter according to claim 1, characterized in that the interruption of the charging circuit of the storage capacitor (7) after charging is effected by the contact (9) of a relay (6), which in turn is effected by the output current of said electronic switch (4) is excited. 3. Camera shutter laughs one of claims 1 and 2, characterized in that one of said control circuit (11) and .inem over a variable resistor (H) whose set resistance value is the same as de. Object brightness Photographic factors that determine the opening time of the camera shutter (e.g. film sensitivity and / or set working panel) indicates a chargeable third capacitor (15) Existing timer circuit is provided. that the charging start of this third Capacitor (15) mechanically (by means of 106) synchronized with the opening of the camera shutter actuatable contact (13) is determined and that the closing of the camera shutter by means of an electromagnetic device (16) which can be excited by the control circuit (11) is, the period of time that elapses until the control switch ang (11) responds on the one hand by the charging time constant of the third capacitor (15) and on the other hand by the;, o the brightness of the object corresponding to the state of charge of the storage capacitor (7) characteristic trigger level of the control circuit (11) is determined. 4. Camera shutter according to one of claims 1 to 3, characterized in that in the charging circuit of the first and / or third capacitor (7, 15) a diode (201, 203) and an additional one Capacitors (202, 204) are provided which form a bootstrap circuit (FIG. 3). fto 5. Camera shutter according to one of claims 1 to 4, characterized in that a comparison circuit (10 ') is provided, which compares the charging voltage of the first capacitor (7) with the charging voltage of the third capacitor (15) and when a voltage difference occurs, a trigger voltage for the control circuit (11) generated (Fig. 2). 6. Camera shutter according to claim 1, characterized in that said electronic Switch (301) together with the light-sensitive element (1) and the second capacitor (3) form an oscillator circuit, the Frequency depends on the brightness of the object and its output pulses during a through a Another timer circuit (304, 305) determines a pulsed charging of the storage capacitor for a period of time (303) cause. 7. Camera shutter according to claim 6, characterized in that the electronic switch (301) from an electrically bistable switching element connected in parallel to the second capacitor (3), in particular the control path of a unijunction transistor (301) consists of a periodic Charging and discharging of this second capacitor (3) and thus the generation of tilting vibrations with a brightness characteristic of the object Frequency causes. 8. Camera shutter according to claim 6 or 7, characterized in that the output pulses the oscillator circuit by means of a pulse shaper stage (e.g. eiii. - transistor) convertible into pulses are. \ v> n which each individual the storage capacitor (303) independent of the pulse repetition frequency each dl; supplies the same amount of charge.