DE2805386A1 - Aperture setter for automatic SLR camera - has drive element with curved section displacing push rod axially w.r.t. optical axis - Google Patents

Abstract

The shutter aperture setter is for an automatic s.l.r. system camera. A push rod is axially movable w.r.t. the optical axis. A drive element is released when the shutter release button is pressed to bring the shutter setting - starting from the largest aperture - to the setting demanded by the internal exposure meter. When this stipulated value is reached it remains stationary. The drive element has a curved section to displace the push rod. During the working of the drive element the curved section pushes the rod. A pivoted lever (12) is installed between the push rod (1) and curved section (3).

Description

Shutter driving device for a camera

with diaphragm tappet lens The invention relates to a diaphragm drive s device for a camera with a lens, one axially to the optical axis having movable diaphragm plunger, in particular for a reflex camera with such an interchangeable lens, with a drive member that when the shutter is released runs freely and is stopped when the target aperture setting is reached, and with a control cam arranged on the drive member for adjusting the diaphragm plunger, which, when the drive member is running, is essentially transverse to the direction of adjustment of the diaphragm slide moves.

Such diaphragm drive devices are particularly found in what are known as Automatic diaphragm reflex cameras with such interchangeable lenses Use. With such a shutter automat, this is through the lens on a object light falling behind the diaphragm is measured and from an exposure control device this light measurement and the input Exposure parameters, such as exposure time and film speed, the target aperture setting certainly. This light measurement takes place immediately after the camera shutter is triggered. Since simultaneously with the release of the camera shutter, the drive element of the diaphragm drive device is released, the aperture will start from their largest aperture, increasingly adjusted in the direction of the smaller aperture. The exposure control device at the same time compares the actual aperture with the determined target aperture and sets if the two coincide, the drive member is still. The required aperture is thus set.

In a known diaphragm drive device of the type mentioned at the beginning Art (DT-OS 22 57 608) is the drive member as a transverse to the optical axis movable Formed slide, which is driven by a solenoid. The control curve consists of an inclined surface on the drive member on which the diaphragm plunger is applied under spring pressure. If the solenoid is switched on when the shutter is released, so the slide is moved transversely to the direction of displacement of the diaphragm plunger. Of the Orifice plunger runs along the inclined surface and becomes with increasing displacement of the slide is increasingly pushed into the lens. The aperture will be increasingly smaller starting from the maximum aperture.

In this known diaphragm drive device, adjustment forces on the diaphragm tappet not only in the direction of displacement of the diaphragm tappet, but also exercised across the board. Since the axial guide of the diaphragm plunger in the lens is usually has a certain amount of play, this effect transversely to the direction of displacement on the diaphragm plunger attacking forces a lateral tilting of the diaphragm plunger in its leadership. This means that there is a certain stiffness of the diaphragm plunger, one exact aperture setting in accordance with the adjustment path of the control cam difficult. In addition, the surface of the control cam, which is on the free Slides along the end of the diaphragm plunger, even with the best processing certain roughness.

In the braking phase of the drive member, that is, when the drive member suddenly stopped and stopped when the target aperture setting is reached the orifice plunger arrives as a result of the unevenness on the surface the control cam in vibrations that are transmitted to the diaphragm blades. Since the adjustment of the aperture practically simultaneously with the release of the shutter is initiated, the aperture does not take during the actual film exposure their exact target aperture setting, but oscillates, with the aperture opening slightly enlarged or

scaled down. An exposure error is caused by this, especially with very short exposure times, unavoidable.

The invention is therefore based on the object of a diaphragm drive device to improve the type mentioned so that a lateral tilting of the diaphragm plunger and the occurrence of vibrations when the drive member is stopped is avoided will.

According to the present invention, this object is achieved by that between the diaphragm plunger and the control cam a fixed pivot lever is arranged, which rests on the control cam at a distance from its pivot point and on which the diaphragm plunger with its free end at a distance from the pivot point is applied - These measures are used by the control cam on the orifice plunger almost exclusively only those adjustment forces are transmitted in the adjustment direction of the diaphragm plunger act.

The transverse forces caused by the transverse movement of the control cam are picked up by the lever. Also the influence of the surface of the control curve is compensated because the control cam is no longer directly at the free end of the orifice plunger slides along, but now on the lever that controls the movement of the cam exclusively converted into an adjustment acting in the direction of adjustment of the diaphragm plunger. the Roughness of the control cam surface that occurs during the transverse movement of the control cam adversely affect the function of the known drive device, can by the according to the invention provided pivot lever between control cam and diaphragm plunger no Have more of an effect on the diaphragm tappet. Thus on the one hand prevents the diaphragm plunger from tilting to the side during the diaphragm adjustment and on the other hand, a vibration-free aperture stop achieved. With the inventive Aperture drive device can be all aperture openings exactly and with reproducible set constant aperture value.

According to one embodiment of the invention, the pivot lever is of this type designed and arranged that the pivoting direction of the contact surface of the diaphragm plunger on the swivel lever in almost the entire swivel range of the swivel lever the direction of adjustment of the diaphragm tappet is aligned. This prevents that even the smallest transverse force components on the diaphragm plunger when the drive member is running may occur.

According to a further embodiment of the invention by the Pivot point of the pivot lever-extending lever axis essentially transverse to Direction of displacement of the diaphragm plunger arranged. The by the transverse movement of the The lateral forces acting on the control cam on the lever are thereby removed from the bearing of the lever recorded.

According to a further embodiment of the invention, the pivot lever formed at the contact points of the control cam and tappet in such a way that the common Contact areas are small. This increases the coefficient of friction on the contact surfaces largely reduced.

According to a further embodiment of the invention, there are control cams and diaphragm plunger in contact with the lever at the same distance from the pivot point. As a result, the transmission ratio of the lever is 1: 1, and when interpreting the The control cam does not need the translation of the lever. to be considered.

According to a preferred embodiment of the invention it is provided that the pivot lever is approximately T-shaped, that the pivot point of the pivot lever arranged at the free end of the long leg of the pivot lever is and that control cam and orifice plunger each on the end faces of the two short leg of the swivel lever.

According to a further embodiment of the invention, the two are short leg of the T-shaped pivot lever shaped so that the surface normal the end face of one short leg resting against the control cam approximately perpendicularly on the control cam and the surface normal of the end face of the other short leg is roughly aligned with the axis of the diaphragm plunger.

According to a further embodiment of the invention, there is the lever made of a material with high sliding properties, preferably Dellrin.

The invention is based on the exemplary embodiments shown in the drawing described in more detail below. The figures show: FIG. 1 a schematic plan view a diaphragm drive device according to a first embodiment and FIG. 2 is a schematic plan view of a diaphragm drive device according to a second Embodiment.

The diaphragm drive device according to FIGS. 1 and 2 is used in a camera with an objective which is axially movable to the optical axis Has diaphragm plunger 1, such as, in particular, single-lens reflex cameras with interchangeable lenses with axial aperture plunger. In the present exemplary embodiments, the camera is designed as a so-called shutter automat, in which the shutter drive device of an exposure control circuit of the camera is controlled such that in dependence from the manually entered exposure time and film speed and the measured Object brightness the required aperture, the so-called target aperture, is set automatically will.

The diaphragm drive device has a drive member 2, which-at Shutter release runs freely and when the target aperture setting is reached a signal of the exposure control circuit of the camera is stopped. the Exposure control circuit is known and therefore not described in detail. The drive link 2 carries a control cam 3 for adjusting the diaphragm plunger 1, which occurs during the process of the drive member 2 is essentially transverse to the direction of adjustment A of the diaphragm plunger 1 moves.

In Fig. 1 the drive member 2 is in a known manner as a rod 4 formed, which is actuated by a lifting magnet 5 in the manner of a linear motor and moves transversely to the direction of displacement A of the diaphragm plunger 1. With a Toothing 6 on the rod is a pinion 7 in engagement with a disk 8 made of ferromagnetic material sits on a common shaft 9. At the extent the disc 8 are the poles of an electromagnet 10 with the formation of a narrow Air gap. A tension spring 11 is used to return the rod 4 to the basic position.

Between the diaphragm tappet 1 and the control cam 3 there is a stationary one Pivoting lever 12 arranged at a distance from its pivot point 13 on the control curve 3 rests and on which the diaphragm plunger 1 with its free end at a distance from Pivot point 13 is applied. The pivot lever 12 is designed and arranged in such a way that that the pivoting direction of the contact surface of the diaphragm plunger 1 on the pivot lever 12 in the entire swivel range of the swivel lever 1-2 approximately with the adjustment direction A of the diaphragm plunger is aligned.

The lever axis extending through the pivot point 13 of the pivot lever 12 14 is arranged essentially transversely to the displacement direction A of the diaphragm plunger 1. The swivel lever is at the contact points of control cam 3 and orifice plunger 1 12 designed such that the common Contact areas if possible are small. The common contact surfaces of pivot lever 12, control cam 3 and diaphragm plunger 1 are equidistant from pivot point 13 of pivot lever 12. This results from the additionally inserted pivot lever 12 between the control cam 3 and orifice plunger 1 no reduction or transmission ratio, what the interpretation the control cam 3 is significantly simplified.

In Figs. 1 and 2, the pivot lever 12 is approximately T-shaped. The pivot point 13 of the pivot lever 12 is at the free end of the long leg 15 of the pivot lever 12 is arranged. Control cam 3 and orifice plunger 1 are each located on the end faces 16 and 17 of the two short legs 18 and 19 of the pivot lever 12 at. The two short legs 18 and 19 of the T-shaped pivot lever 12 are shaped in such a way that the surface normal of the front surface resting on the control cam 3 17 of the short leg 19 approximately perpendicular to the control curve 3 and the surface normal the end face 16 of the other short leg 18 with the axis of the diaphragm plunger 1 is aligned. The pivot lever 12 is made of a material with high sliding properties, for example made of Dellrin.

The operation of the diaphragm drive device according to Figure 1 is like follows: When the shutter is released, the lifting magnet 5 is excited and this moves the Rod 4 transversely to the direction of displacement A of the diaphragm plunger 1. With increasing displacement the rod 4, the pivot lever 12 is pivoted clockwise and the pivot lever 12 moves the diaphragm slide 1 in the direction of displacement A. The exposure control device the camera calculates in a known manner from the entered exposure parameters Exposure time and film speed necessary for optimal exposure Cover. As soon as the set aperture corresponds to this target value, the exposure control device gives a signal from the camera. This Signal causes the excitation of the The electromagnet 10 and the ferromagnetic disk 8 are suddenly stopped.

The rod 4 stands still and holds via control cam 3 and pivot lever 12 the diaphragm plunger 1 in the position that it is at the moment of the signal output the exposure control device of the camera has taken, creating the desired Aperture is set for the duration of the photograph. After closing of the lock, the solenoid 5 is de-energized and the rod 4 takes effect the tension spring 11 back to its original position.

The diaphragm drive device according to the embodiment in Fig. 2 differs from the output device just described only in that that the drive member 2 is designed as a control cam 21 pivotable about a pivot point 20 is. The control cam 21 carries the control cam 3 on its circumference. Between the control cam 3 and the diaphragm tappet 1, as in FIG. 1, the same pivot lever 12 is arranged.

The control cam 21 is to be driven in a suitable manner, which is here has not been specifically represented. If the control cam 21 rotates around his Pivot point 20, the control cam 3 moves as in Fig. 1 essentially across the direction of displacement A of the diaphragm plunger 1. Due to the increasing slope the control cam 3, the pivot lever 12 is pivoted, its pivoting in a linear adjustment of the diaphragm plunger 1 in adjustment direction A implements. Otherwise correct structure and mode of operation of the diaphragm drive device in the embodiment according to Fig. 2 with the embodiment of FIG. 1, so that for the same Components with the same reference numerals have been used. Blank page

Claims (8)

Claims end drive device for a camera with a Objective that has an aperture plunger that can be moved axially to the optical axis, especially for a reflex camera with such an interchangeable lens a drive member that runs freely when the shutter is released and when the Target aperture setting is stopped, and one arranged on the drive member Control cam for adjusting the diaphragm plunger, which occurs when the drive element is running moves substantially transversely to the direction of adjustment of the diaphragm slide, d a d u r c h g e k e n n n z e i c h n e t that between orifice plunger (1) and control cam (3) a stationary pivot lever (12) is arranged, which is spaced from its pivot point (13) rests on the control cam (3) and on which the diaphragm plunger (1) rests with its free end at a distance from the pivot point (13). 2. Aperture drive device according to claim 1, d a d u r c h g e k E n n z e i c h n e t that the pivot lever (12) is designed and arranged in such a way is that the pivoting direction of the contact surface of the diaphragm plunger (1) on the pivot lever (12) in the entire swivel range of the swivel lever (12) approximately with the adjustment direction (A) of the Orifice plunger (1) is aligned. 3. Aperture drive device according to claim 1 or 2, d a d u r c h g e k e n n n z e i c h n e t that through the pivot point (13) of the pivot lever (12) extending lever axis (14) essentially transversely to the direction of displacement (A) of the diaphragm plunger (1) is arranged. 4. diaphragm drive device according to any one of claims 1-3, d a it is indicated that the pivot lever (12) is on the contact surfaces (17,16) of the control cam (3) and orifice plunger (1) is designed such that the common contact areas are small. 5. diaphragm drive device according to any one of claims 1-4, d a D u r c h g e k e n n n z e i c h n e t that control cam (3) and orifice plunger (1) at the same distance from the pivot point (13) of the pivot lever (12) on the pivot lever (12) are in contact. 6. diaphragm drive device according to any one of claims 1-5, d a it is indicated that the pivot lever (12) is approximately T-shaped is that the pivot point (13) of the pivot lever (12) at the free end of the long Leg (15) of the pivot lever (12) is arranged and that control cam (3) and Orifice plunger (1) on the end faces (16, 17) of the two short legs (18, 19) of the pivot lever (12) are in contact. 7. diaphragm drive device according to claim 6, d a d u r c h g e k It is noted that the two short legs (18, 19) of the T-shaped pivot lever (12) are shaped so that the surface normal of the contact on the control cam (3) End face (17) of one short leg (19) approximately perpendicular to the control cam (3) and the surface normal of the end face (16) of the other short leg (18) is aligned with the axis of the orifice plunger (1). 8. diaphragm drive device according to any one of claims 1-7, d a it is indicated that the pivot lever (12) is made of a material with high lubricity.