DE4216908A1 - Lens barrel for automatic focusing SLR camera - Google Patents

Abstract

The lens barrel for an automatic focusing camera, includes an annular focusing member which moves a focusing lens in a direction of an optical axis by rotating about the optical axis. An automatic focusing device rotates the focusing member by a driving force applied by a motor. An annular changeover member is arranged to be manually rotatable about the optical axis and manually movable in the direction of the optical axis between AF and MF mode setting positions. A clutch releases a connection between the changeover and the focusing members to permit independent rotation thereof when the changeover member is in the AF mode setting position and forms the connection between them to thereby provide a rotationally dependent structure when the changeover member is in the MF mode setting position. A second clutch forms a connection between the automatic focusing device and the annular focusing member when the changeover member is in the AF mode setting position and releases the connection when the changeover member in the MF mode setting position.

Description

The invention relates to a lens barrel for a Auto focus camera, especially a one-eyed mirror reflex camera.

With a single-lens reflex camera with automatic shear focusing has been a switch between manual and automatic focusing with a switch provided on the camera housing performed. Previous single-lens reflex cameras have a motor-driven autofocus in the camera housing Drive shaft, and an interchangeable lens is with a driven shaft provided with the drive shaft is coupled. With this coupling, the autofocus Operation defined. The driven shaft of the interchangeable lens, and the focus sengruppe is ver in the direction of the optical axis poses, so that a focus is possible is. Furthermore, the movement of the Focus ring rotated on the lens.  

Switching from this autofocus mode to manual focus is achieved by decoupling the autofocus drive shaft of the camera body and the driven shaft of the lens. With manual The focus ring on the lens becomes in focus rotated by the user. With this rotation the Focus lens group in the direction of the optical axis moved and the focus was adjusted.

In a previously known lens barrel Focus ring turned even when the focus is fine position automatically. You want to avoid that the focus ring is operated by the user zer while focusing, what is the purpose of Focus ring itself narrow and it on front end of the lens barrel. It has however, it has been shown that a narrow focus ring manual adjustment at the end of the lens barrel sword. But also is the operation of the order switch on the side of the camera housing cumbersome.

The object of the invention is an object tivtubus for an autofocus camera to indicate the User switching between manual and auto Matic focusing on the lens enables and to make this operation easier.

The focus ring should rotate during the automatic focusing can be avoided.

For this purpose, a lens barrel according to the invention has one Switching ring, by rotating the lens barrel in a linear forward and backward movement in rich tion of the optical axis is brought. Besides, is the lens barrel is designed to be in an MF position  manual switching of the switching ring is. In this position, the user can mera manually by turning the switch ring put. Is the switch ring in an AF position that closer to the other end of the line parallel to the opti axis is the automatic focus adjustment tion possible without the switching ring being rotated becomes.

A lens barrel according to the invention accordingly has one Focus ring, the rotation of which focus arm group moved in the direction of the optical axis, and an autofocus device that uses this focus ring motor turns. A switch ring is also provided hen making a straight line movement to the AF position and in the MF position as well as a rotation in manual Operation. A first clutch separates the order switching ring from the focus ring to your free re relative rotation in the AF position and combines both Rings to an element in the MF position of the shift around. A second clutch couples the autofocus on direction and the focus ring or interrupts it Coupling for the AF position or the MF position of the Switching rings.

On a lens barrel constructed in this way, you can directly between manual and automatic focusing be switched, and also the focus ring is not rotated in autofocus mode. Thereby he there is an easy switch between the two be modes, and there will be a malfunction in manual Adjustment on the lens barrel prevented.

In a further development of the inventive concept, the Lens barrel further include a locking device  which releases or blocks the changeover ring when the automatic or manual focusing is switched. This will also cause a random rotation of the switching ring with automatic focusing prevented.

The invention is described below with reference to the drawing explained in more detail. In it show:

Fig. 1 shows the longitudinal vertical section of the obe ren half of a lens as a first embodiment,

Fig. 2 shows the lens barrel according to Fig. 1 in egg ner other operating position,

Fig. 3 shows a first coupling device according to the section AA of Fig. 1,

Fig. 4, the first coupling device according to the section BB in FIG. 2,

Fig. 5 is a perspective view of egg nes an autofocus Transmissionswel le biasing mechanism

Fig. 6 is a perspective view of egg nes coupling pin within the lens barrel,

Fig. 7 shows the section CC of Fig. 2 for Dar position of a locking mechanism in the unlocked state,

Fig. 8 shows the locking mechanism in the locked state according to the section DD of FIG. 1,

Fig. 9 for the lock mechanism in the locked state according to the section DD of FIG. 1 as modified execution,

Fig. 10 shows the view of a lens similar to FIG. 1, but for a second exemplary embodiment of the invention,

Fig. 11 the lens barrel according to Fig. 1 in egg ner other operating position,

Fig. 12, a first clutch device according to the section EE of FIG. 10,

Fig. 13, the first coupling device during manual focusing,

Fig. 14, the first coupling device during manual focusing, however, in another embodiment,

Fig. 15 is a lens barrel in a depicting lung similar to FIG. 1, but as dung drit th embodiment of the OF INVENTION,

Fig. 16 the lens barrel shown in FIG. 15 for manual focusing,

Fig. 17 is a first coupling device of the lens barrel shown in FIG. 15 matic with auto-focus,

Fig. 18, the first coupling device during manual focusing,

Fig. 19 is a perspective view of the first coupling device according to Fig. 17,

Fig. 20 shows a cross section of the front end of a change-over as well as a provided there blocking pinion,

Fig. 21 depicting a lens barrel in a development similar to Fig. 1, but dung than four th embodiment of the OF INVENTION,

Fig. 22 the lens barrel shown in FIG. 21 for manual focusing,

Fig. 23 is a first coupling device of the lens barrel shown in FIG. 22,

Fig. 24, the first clutch device for automatic focus,

Fig. 25 is a perspective view of the first coupling device according to Fig. 24,

Fig. 26 depicting a lens barrel in a development similar to Fig. 1, but dung than five th embodiment of the OF INVENTION,

Fig. 27 the lens barrel according to Fig. 26 for manual focusing,

Fig. 28 shows the cross section of a Sperrmechanis mechanism in the locked state,

Fig. 29 shows the locking mechanism in the unlocked state,

Fig. 30 depicting a lens barrel in a development similar to Fig. 1 as the sixth imple mentation of the invention,

Fig. 31 the lens barrel according to Fig. 30 for manual focusing,

Fig. 32, a first clutch device according to the section AA in FIG. 30 at tomatischer au-focus,

Fig. 33, the first clutch device according to the section BB in FIG. 31 Nueller ma at focus,

Fig. 34 is a perspective view ei ner second coupling device of the lens barrel shown in FIG. 30 matic with auto-focus,

Is a perspective view of the second coupling device according to Fig. 34 lung. 35 for manual focusing Stel,

Fig. 36 is a perspective view of the switching mechanism in the lens barrel of Fig. 30 at automatic focusing,

Fig. 37 is a perspective view of the switching mechanism of FIG. 36 for manual focusing,

Fig. 38 depicting a lens barrel in a development similar to Fig. 1 as a seventh imple mentation of the invention,

Fig. 39 the lens barrel shown in FIG. 38 for manual focusing,

Figure 40 is a plan view showing the interaction lung gear. Kupp and between a gear of an autofocus mechanism Scharfeinstellmechanis,

Fig. 41 is a plan view of a switching mechanism,

Fig. 42 is a coupling device according to the section AA in FIG. 38 in diagrammatic automatic focus,

Fig. 43, the coupling device of FIG. 42 according to the section BB in FIG. 39 for manual focusing,

Fig. 44 the movement sequence of the change-over of a lens barrel according to Fig. 38 as well as the operating states of the zugeord Neten elements,

Figure 45 is a Umschaltmecha mechanism extension. The longitudinal section of a lens in the eighth embodiment of the OF INVENTION,

Fig. 46 is a perspective view of the main parts of the switching mechanism of FIG. 45,

Fig. 47 is a perspective view of the coupling device in the switching mechanism of FIG. 45 at Autofo Kus operation,

Fig. 48 is a perspective view of the coupling device during manual focusing,

Fig. 49 is a perspective view of the wheel of the clutch teeth of a drive gear and a driven gear wheel of the clutch device,

Fig. 50 is a perspective view of the main parts of a Ölschutzvor direction of the switching mechanism of FIG. 45,

Fig. 51 is a perspective view of a diaphragm block, and

Fig. 52 shows the longitudinal section of the switching mechanism according to Fig. 45 for another sectional plane.

First, the first embodiment of a lens barrel for an auto focus camera will be described with reference to FIGS. 1 to 9.

The lens barrel has at its rear end a stationary ring 10 with a base 11 with which the lens barrel is to be attached to a camera housing. In the front region of the inner circumference of the stationary ring 10 is a focusing lens mount 12 vorgese hen carrying a focusing lens L 1 and so fitted is that it can be freely moved in the optical axis direction. The stationary ring 10 consists of several ring elements which are connected to one another. Therefore, the stationary ring 10 is seen as a single element.

A guide groove 13 for linear movement is formed on the stationary ring 10 and runs in the direction of the optical axis. In it, a guide pin 14 is guided, which is provided on the outer circumference of the focusing lens mount 12 . In the guide groove 13 , a focusing ring 15 is guided with the pin 14 , which is fastened on the outer circumference of the focusing lens mount 12 be. The focus ring 15 can be freely rotated around the optical axis. A guide groove 16 , in which the guide pin 14 is seated, is formed on the inner circumference of the focusing ring 15 . When the focus ring 15 rotates around the optical axis, the focus lens frame 12 moves with the focus lens L 1 in the direction of the optical axis and follows the guide groove 13 , the guide groove 16 and the guide pin 14 , whereby the focusing is carried out. The range of rotation of the focus ring 15 is determined by two stops 18 , which are provided on the sta tionary ring 10 , and by further stops 19 on the focus ring 15th Furthermore, a calibrated Ent distance scale 20 is provided on the outer circumference of the focus ring 15 . This can be observed through a window in the stationary ring 10 .

At the rear part of the inner circumference of the focus ring 15 , an internal toothing 24 is introduced coaxially. The stationary ring 10 carries an autofocus transmission shaft 26 on which a first pinion 25 is seated, which engages in the internal toothing 24 so that the autofocus transmission shaft 26 moves along the optical axis and can also rotate about its own axis. At the rear end of the transmission shaft 26 , a second pinion 27 is attached. This engages in a third pinion 29 which is seated on a driven shaft 28 which is parallel to the transmission shaft 26 . The driven shaft 28 is coupled to an autofocus drive shaft (not shown) of the camera housing when the lens barrel is attached to the camera housing in a manner known per se. The rotation of the driven shaft 28 is transmitted to the focus ring 15 via the gears 27 , 29 and 25 .

The stationary ring 10 is provided with a switching ring 31 for switching between automatic and manual focusing, which is arranged in the central region of the lens barrel so that it can be moved in the direction of the optical axis and can also be freely rotated. A decorative outer ring 32 surrounds the switching ring 31 . In the first embodiment described here, the automatic focusing takes effect when the switching ring 31 reaches the end point of its forward movement in the direction of the optical axis, which is shown in FIG. 1 Darge. Manual focus is obtained at the end point of the backward movement in the direction of the optical axis. This position is shown in Fig. 2. The switching ring 31 is thus mounted so that it can be moved in the direction of the optical axis between the AF position and the MF position.

On the inner periphery of the rear part of the switch ring 31 , V-shaped ring grooves 33 and 34 are provided corresponding to the AF position and the MF position. The statio nary ring 10 has a locking ball 35 which fits into each of the V-shaped ring grooves 33 and 34 , and a Blattfe of 36 , which presses the locking ball 35 radially outwards. Furthermore, the switching ring 31 has on its inner circumference a groove 39 which determines the range of motion and which defines the end positions of the switching ring 31 in the direction of the optical axis. The stationary ring 10 has a pin 40 which sits in the groove 39 and strikes the rear or front end when the changeover ring 31 is moved. The pin 40 is provided with an elastic ring 41 , which serves as a damper when the pin 40 strikes the ends of the groove 39 .

A first coupling device 43 is provided between the switching ring 31 and the focus ring 15 . It allows the free rotation of the focus ring 15 relative to the switching ring 31 when the latter is in the AF position in the front area. It connects the focus ring 15 with the switching ring 31 to form a unit when the switching ring 31 is in its rear MF position. The first coupling device 43 has a part 44 of smaller diameter (engaging part), a chamfered part 45 (transition part) and a part 46 of larger diameter (non-engaging part), which merge from front to back in the direction of the optical axis and the inner circumference of the front whose part of the switching ring 31 are opposite. The focus ring 15 has a radial bore 47 for egg NEN coupling pin 48th

The bore 47 is provided so that the coupling pin 48 can be moved in the radial direction, so that it faces either the part 44 of smaller diameter, the transition part 45 or the part 46 larger diameter. The coupling pin 48 projects radially outward, and its movement is limited by a head 49 which strikes the inner surface of the focus ring 15 when the coupling pin 48 is pressed with a leaf spring 50 in the radial direction to the outside. The coupling pin 48 is provided so that its upper end, as shown in FIG. 3, is separated from the inner circumference of the larger diameter part 46 , while its head 49 rests against the inner circumference of the focusing ring 15 . In this state, the coupling pin 48 can come into direct contact with the inner circumference of the part 44 of smaller diameter, so that the head 49 is then separated from the inner circumference of the focusing ring 15 and pressed inward, as shown in FIG. 4.

The leaf spring 50 is fixed at one end by means of a screw 38 to the inner circumference of the focus ring 15 , as shown in FIG. 3. The coupling pin 48 is shown more clearly in FIG. 6 and has a bevel at its upper end, which forms a contact surface 51 of a predetermined width. If the leaf spring 40 presses it against the part 44 of smaller diameter of the switching ring 31 , the friction between the upper end and the part 44 can assume a large value.

The first coupling device 43 is thus constructed such that the upper end of the coupling pin 48 faces the inner circumference of the larger diameter part 46 at a predetermined distance. Characterized the connection between the operating ring 31 and the focus ring 15 is interrupted, and the focus ring 15 can be freely rotated relative to the operating ring 31st On the other hand, the upper end of the coupling pin 48 comes into contact with the inner periphery of the part 44 of smaller diameter when the switching position 31 is used to set the MF position. As a result, who the switching ring 31 and the focus ring 15 connected to one unit and move together. The focus ring 15 is connected to the switch ring 31 in any position and decoupled from it, so that both elements form a stepless clutch.

A second coupling device 53 is provided between the switching ring 31 and the autofocus transmission shaft 26 . It is constructed so that it couples the rit zel 25 of the transmission shaft 26 with the internal toothing 24 of the focus ring 15 when the switching ring 31 is in the front AF position. It separates the pinion 25 from the internal toothing 24 of the focusing ring 15 when the switching ring 31 is in its rear MF position. The second clutch device 53 has an annular groove 54 on the inner circumference of the switching ring 31 . A pin 56 which protrudes from a coupling plate 55 is guided in the annular groove 54 . The coupling plate 55 has a bifurcated section 57 across the optical axis. The bifurcated portion 57 surrounds the autofocus transmission shaft 26 and is located on the side of a flange 58, the wave-sion on the Transmis 26 is provided.

A clutch plate 60 , which is similar to the hitch be plate 55 , sits on the stationary ring 10th It has a forked part 61 transverse to the optical axis. This rests on the side of a ring acted upon by a spring 63 , which can be moved on the autofocus transmission shaft 26 . The other end of the spring 63 abuts the flange 58 . The ring exerts a compressive force on the autofocus transmission shaft 26 so that it is pressed in the forward direction, in which the pinion 25 engages with the internal toothing 24 . The movement of the transmission shaft 26 in the forward direction is limited by the abutment of the flange 58 on the forked part 57 of the clutch plate 55 .

A locking device 65 blocks the rotation of the switching ring 31 when it reaches the AF position, and is arranged between the switching ring 31 and the stationary ring 10 . The locking device 65 is formed by the smooth, annular outer surface 69 of the stationary ring 10 and a plurality of locking grooves 66 , which are seen under the same angular distances on the annular surface 69 before. The switching ring 31 has several openings 70 for holding locking balls 67 in such a way that they can be moved in the radial direction. The locking balls are pressurized with leaf springs 68 , which are attached to one end of the outer circumference of the switching ring 31 . The locking balls 67 are thus pressed out of the openings 70 to the inside of the switching ring 31 and come into direct contact with the ring surface 69 of the stationary ring 10 .

When the switching ring 31 is in the MF position, the locking balls 67 do not lie in any of the grooves 66 , as shown in FIGS. 2 and 7. As a result, the switching ring 31 can be rotated about the optical axis. However, if it is moved from the MF position into the AF position, the blocking balls 67 move in the direction of the optical axis forward over the ring surface 69 on the outer circumference of the stationary ring 10 . When the switching ring 31 is rotated in this state around the optical axis, the locking balls 67 can snap into the locking grooves 66 , as shown in FIGS . 1 and 8, because they are pressurized by the respective leaf spring 68 . This happens ge at an angular position of the switching ring 31 , in which the openings 70 with the locking balls 67 opposite the locking grooves 66 . In this way, the focus ring 15 and the switching ring 31 are connected to each other with respect to their rotational movement, and their rotation is thereby blocked.

The electrical switching between automatic and manual focus can, for example, with a contact brush, not shown, and a code plate, which is also not shown, hen. The contact brush is then connected to the switching ring 31 and the code plate is fastened in a corresponding position on the stationary ring 10 .

In the following, the functions when switching between automatic and manual focusing a lens barrel of the type described above explained.

As Fig. 1 shows, interrupts the first direction Kupplungsvor 43 coupling the change-over 31 to the focus ring 15 when the switchover ring 31 is brought forward in the AF position because the auto-focus is adjusted. The focus ring 15 can then be rotated independently of the switching ring 31 . The second clutch device 53 kop pelt the pinion 25 of the autofocus transmission shaft 26 with the internal teeth 24 of the focus ring 15 when the automatic focus is set, and then the focus ring 15 is rotated via the autofocus transmission shaft 26 . The locking mechanism 65 locks the switching ring 31 on the stationary ring 10 when the automatic focus is set, and thereby the switching ring 31 can not be rotated.

In the AF position of the lens barrel is thus the upper end of the coupling pin 48 , which sits on the focus ring 15 , opposite the part 46 size ren diameter on the inner circumference of the switching ring 31 , but has no contact with the switching ring 31 , as shown in Fig . 3 is shown. On the other hand, the pinion 25 of the autofocus transmission shaft 26 is brought forward into engagement with the internal toothing 24 of the focusing ring 15 by the Druckfe 63 . As a result, the rotation of the driven shaft 28 , which is caused by the drive shaft of the camera housing, is transmitted to the focusing ring 15 , so that the automatic focusing takes place.

The locking balls 67 are located in the locking grooves 66 of the stationary ring 10 , as shown in FIG. 8. Even if the locking balls 67 are not seated in the locking grooves 66 , but are on the outer circumference of the stationary ring 10 in the position shown in FIG. 9, they will soon reach the state shown in FIG. 8 if the switching ring 31 is rotated slightly. For this reason, the operation by the user on the lens tube in the automatic focusing is in no way impaired. The switching ring 31 does not rotate, so that the Greifab section does not rotate, which is formed by the decorative outer ring 32 on the outer circumference of the switching ring 31 when the user holds it.

The first coupling device 43 brings the switching ring 31 and the focus ring 15 in engagement mitein other so that they rotate as a unit when the switchover ring 31 backwards ge in the MF-position is introduced, which is shown in Fig. 2. In this Be manual focus operating state releases the second coupling device 53, the connection between the autofocus transmission shaft 26 and the focus ring 15 on the inner teeth 24, so that the focus ring 15 is no longer rotated by the transmission shaft 26th The locking device 65 releases the switching ring 31 from the locked position so that it can be rotated by the user.

The contact surface 51 at the upper end of the coupling pin 48 of the focusing ring 15 is brought into firm frictional contact with the part 44 of smaller diameter on the inner circumference of the switching ring 31 when the manual focusing is set. As shown in FIG. 4, the switching ring 31 and the focus ring 15 are then connected to each other for common rotation. On the other hand, the bifurcated part 57 of the clutch plate 55 presses the rear part of the transmission shaft 26 against the compression spring 63 when the switching ring 31 moves backward, as a result of which the focusing ring 15 and the internal toothing 24 are separated from one another. The locking balls 67 come into contact with the smooth outer surface 69 of the stationary ring 10 , whereby the switching ring 31 is unlocked.

When the change-over ring 31 is in this state manually ge rotates, the rotation through the portion 44 klei Neren diameter, the coupling pin 48 and the opening of which is transmitted to the focus ring 15 47th The manual focus is thus carried out. The rotation of the driven shaft 28 could not be transmitted to the focus ring 15 even if the shaft 28 were rotated by the drive shaft of the camera housing. The limit positions of the switching ring 31 in automatic and manual focusing are determined by the locking balls 35 and the V-shaped ring grooves 33 or by their mutual engagement.

In the following, further embodiments of the Invention explained. For matching items the same reference numerals as in the above described embodiment used, and them are not specifically explained again.

In Fig. 10 to 14 a second embodiment is shown of a lens which is suitable for a camera with autofocus. The water lens barrel is characterized essentially by the fact that a first clutch device 43 A is provided, which is a stepped clutch, while in the first embodiment, a continuously variable clutch 43 is provided.

Several locking grooves 70 are hen at small Winkelabstän the on the inner circumference of the switching ring 31 from the part 44 of smaller diameter to the transition part 45 hen. A coupling ball 71 instead of the coupling pin 48 of the first embodiment is provided on the focusing ring 15 movable in the radial direction. The coupling ball 71 is pressed by a Blattfe the 50 to the outside, so that it can snap into a locking groove 70 . The leaf spring 50 is Stigt with a screw on the inner circumference of the focus ring 15 BEFE.

In this second embodiment, the automatic focusing is achieved by moving the switching ring 31 forward, as shown in FIGS. 10 and 12. This setting is the same as that of the first embodiment. In contrast, the locking groove 70 31 accepts the change-over the Kupplungsku gel 71, as shown in FIG. 13, so that the switching ring 31 and the focus ring 15 can be rotated together if the manual focusing a is provided, to which the change-over ring 31 after is moved backward as shown in Fig. 11 shows. Depending on the position of the locking groove 70 with respect to the optical axis, the coupling ball 71 can now not face the locking groove 70 , as shown in Fig. 14, when the switching ring 31 has been moved backwards. However, if it is turned slightly, the state shown in FIG. 13 is reached, in which the changeover ring 31 and the focus ring 15 are coupled to one another. This results in the operating mode of manual focus.

In the first embodiment, the coupling pin 48 is arranged radially inside the part 44 smaller diameter, the transition part 45 and the part 46 larger diameter. However, the invention is not limited to this, it can also be realized in any other construction in which the arrangement of these parts is reversed.

The coupling pin 48 can namely be held on the switching ring 31 and ge to the focus ring 15 pressed. A part of smaller diameter, but which is a non-engagement part, an oblique transition part and a part of larger diameter, which is an engagement part, are then provided in this order from front to back on the outer circumference of the rear part of the focus ring 15 . Constructive tion In such Kon is the coupling pin 48 at the shift ring 31 the portion of smaller face in the AF position the diameter of the focus ring 15, so that the change-over ring 31 is freely rotatable relative to the focus ring 15 °. On the other hand, the coupling pin 48 comes into contact with the larger diameter part of the focus ring 15 at the MF position when the switching ring 31 is moved backwards, so that both rings are then connected to one another and rotatable together.

In the second embodiment of the invention, the coupling ball 71 is provided in the switching ring 31 and the locking groove on the focus ring 15 , so that it can be rotated freely relative to the switching ring 31 in the AF position. The switching ring 31 and the focus ring 15 are then connected to one another in the MF position and can be rotated together.

In Fig. 15 to 20 a third embodiment is shown of a lens barrel. This has a first coupling device 43 B, in which the switching ring 31 and the focus ring 15 are connected to each other by a locking pinion 76 engaging with a toothed groove 81 .

This first coupling device 43 B has the locking pinion 76 at several positions on the circumference of the switching ring 31 , as shown in FIG. 20. On the outer periphery of the rear part of the focus ring 15 a toothed release groove 80 and the toothed locking groove 81 are provided, each of which come into engagement with the locking pinion 76 . They lie side by side along a line in the direction of the optical axis. The release groove 80 is arranged in the front and the locking groove 81 in the rear.

The focus ring 15 has a cylindrical shape. If the dividing line of the toothed release groove 80 is regarded as a cylinder surface which is formed by the rotation of the dividing line, the diameter PC 1 of this cylindrical surface can be defined. In the same way, the diameter PC 2 can be defined for the rotation of the dividing line of the locking groove 81 . The diameter PC 2 is just 2 α larger than the diameter PC 1 . Here, α is the distance between the dividing line 80 a of the release groove 80 and the dividing circle 76 a of the locking pin 76 . The outer diameter of the release groove 80 and the locking groove 81 are D 1 and match.

The first coupling device 43 B has a concave part 82 at the front end of the switching ring 31 . At the front end of this concave part 82 , a bearing groove 75 is formed. This belongs to a bearing housing part 75 a, in which an axis 77 for the locking pinion 76 is freely rotatable. A pinion housing part 15 b, which receives the locking pinion 76 is provided in the center of the axis 77 so that it is freely rotatable, but movement to the right and left is impossible. The width of the bearing housing part 75 a forwards and backwards is approximately equal to the diameter of the axis 77 , so that it cannot be moved forwards and backwards. The depth of the bearing housing part 75 a is smaller than the diameter of the axis 77 , so that the upper part of the axis 77 protrudes upwards.

Leaf springs 78 are arranged on both sides of the locking pin 76 and lie on the axis 77 . With their rear ends they are fastened with screws 79 at the rear end of the concave part 82 . Since the upper part of the axis 77 protrudes from the bearing housing 75 A, the leaf springs 78 press on the axis 77 and thus the locking pinion 76 against the release groove 80 or the locking groove 81st

In this third exemplary embodiment, the locking pinion 76 engages in the toothed release groove 80 , since it is under the corresponding pressure effect by the leaf springs 78 . This applies to manual focus adjustment when the switching ring 31 is moved forward, as shown in FIGS. 15 and 17. Then there is a distance α between the pitch circle 76 a of the locking pin 76 and the dividing line 80 a of the release groove 80 . Since the locking pinion 76 can be moved freely in the circumferential direction. The switching ring 31 and the focus ring 15 are then decoupled from each other, so that they are freely rotatable relative to each other and the automatic focusing is possible.

If the switching ring 31 is moved backwards, as shown in FIGS. 16 and 18, the Sperrit zel 76 moves together with the switching ring 31 on the toothed release groove 80 and is thereby rotated. It then reaches the locking groove 81st The outer diameter of the locking groove 81 is equal to the outer diameter of the release groove 80 , while the diameter PC 2 of the parting line of the locking groove 81 is larger than the diameter PC 1 of the dividing line of the release groove 80 . The locking pinion 76 is thereby raised together with the axis 77 by the amount x 1 ( FIG. 18).

As a result, the locking pinion 76 is subjected to a greater pressure due to the leaf springs 78 , since these are deflected accordingly by x 1 . Since the locking pinion 76 is pressed firmly against the teeth of the locking groove 81 , there is a strong frictional effect between the locking pinion 76 and the locking groove 81 . The focus ring 15 is thereby verkop pelt with the switching ring 31 , so that both can be rotated together and the manual focus is possible.

The locking pinion 76 rotates over the Freiga benut 80 and the locking groove 81 when the switching ring 31 is moved backwards relative to the focus ring 15 , and the inhibiting force of the locking pinion 76 is extremely low in this direction of movement. As a result, the emotional impression when moving the switching ring 31 is improved for the user.

In Fig. 21 to 25 a fourth embodiment is shown of a lens barrel. Here, a first coupling device 43 C is provided, which has a part 83 of smaller diameter instead of a toothed free groove 80 at the rear end of the focus ring 15 , but otherwise corresponds to the coupling device 43 B of the previous embodiment. The part 83 of smaller diameter has a distance x 2 from the teeth of the locking pin 76 . This can therefore not come into contact with the focus ring 15 in the area of the part of smaller diameter 83 .

If the switchover ring is in the ge in Fig. 21 and 23 showed forward position 31, the switching can ring 31 and the focus ring 15 so do not mitein be connected on the other, while the auto-focus adjustment is performed. The focus ring 15 can be freely rotated relative to the switching ring 31 . As shown in FIGS . 22 and 24, the lock pinion 76 comes into contact with the lock groove 81 , and the lock pinion 76 is firmly pressed, as is the case with the third embodiment. When the manual focus is set, the switching ring 31 and the focus ring 15 are connected to each other so that they are rotated together.

In the third and fourth exemplary embodiments, the invention is also implemented if the arrangement of the locking pin 76 on the one hand and the toothed free slot 80 and the toothed locking groove 81 is reversed. Even if the locking pinion 76 on the focusing ring 15 is arranged so that it is pressed radially inward, and the locking groove 81 is provided on the outer circumference at the front end of the switching ring 31 , while the release groove 80 is behind the locking groove 81 , the result effect sought with the invention. This is also possible in the fourth exemplary embodiment, if the locking pinion 76 is arranged on the switching ring 31 and is pressed radially inward, while the locking groove 81 on the outer circumference of the front end of the switching ring 31 and the part 83 have a small diameter behind the locking groove 81 lies.

The four exemplary embodiments described above the invention related to a lens barrel for automa table focusing, in which the driving force of  the camera body is supplied. The invention can also be used in the same way for a lens barrel be realized in which the drive motor in the Lens is installed.

In the exemplary embodiments described above, a changeover ring 31 is provided which moves in a straight line in the direction of the optical axis and can also be rotated about the optical axis. It enables manual focusing when it is in the MF position, whereas automatic focusing is possible in the AF position, for which purpose the switching ring 31 does not have to be rotated. With automatic focus, it stands still. Thus, the invention enables the construction of a lens barrel with improved functional properties, which does not require any change in the hold when switching to manual focus, since the user can hold the switch ring 31 in the automatic focus. As a result, an improved sliding guide of the lens barrel is achieved, and the user can easily take manual adjustment by turning the switching ring 31 after to switch to manual focusing.

In the exemplary embodiments described above, the switching ring 31 is provided on its rear part with a latching mechanism which comes into effect when the AF position or the MF position is reached. However, the invention can also be implemented in conjunction with other constructions, as is the case, for example, in the fifth exemplary embodiment shown in FIGS . 26 to 29.

In the fifth embodiment, the Rastmecha mechanism is hen hen vorgese on the front part of the switching ring 31 . The focus ring 15 already described above has a coaxial gear 118 on the rear part. The internal toothing 24 is provided on the inner circumference of this toothed rack 118 . A clutch 127 , which is to be connected to the drive shaft of the camera housing, is provided at the rear end of the autofocus transmission shaft. The pinion 25 is continuously pressed with a Druckfe the 128 so that it is in engagement with the internal toothing 24 .

The stationary ring 10 is provided on the outer circumference of its front part with the switching ring 31 so that it moves freely forwards and backwards in the direction of the optical axis and can be rotated about the optical axis. In the fifth embodiment of the invention, the AF position is defined by the switching ring 31 reaching the end point of its forward movement, as shown in FIG. 26. The MF position is defined by the end of the backward movement, as shown in FIG. 27. On the inner circumference of the front part of the switching ring 31 , V-shaped grooves 133 and 134 are accordingly seen the AF position and the MF position, as has already been described above. On the outer circumference of the stationary ring 10 , a locking ball 135 is held, which optionally engages in one of the two grooves 133 and 134 . A leaf spring 136 presses the locking ball 135 in the radial direction to the outside. To switch ring 31 is provided on the inside of its front part with stop walls 137 and 138 , which limit its movement Be. These walls 137 and 138 are in contact with a part of the stationary ring 10 , so that thereby stops for the switching ring 31 are formed. The walls 137 and 138 are provided with elastic elements 139 as a buffer when they strike the corresponding walls of the stationary ring 10 .

A first coupling device 43 , which is constructed in the same way as the first coupling device of the first embodiment, is located between the switching ring 31 and the focus ring 15 . A hitch be plate 153 is provided as a second coupling device 53 . This coupling plate 153 is held on the stationary ring 10 so that it can be moved parallel to the optical axis, while it is arranged on the rear part of the switching ring 31 . A roller 154 , which is in contact with the switching ring 31 , is seen at the upper end of the clutch plate 153 . A bifurcated part 155 , which comes with a forward and backward movable wheel 129 , which forms a unit with the pinion 25 , is hen at the rear end of the clutch plate 153 .

When the switching ring 31 is brought back to the MF position, the clutch plate 153 is pushed backward by it, and the pinion 25 is brought with the forked part 155 and the forward and backward movable wheel 129 into a position in which it is disengaged from the internal toothing 24 . When the switching ring 31 is moved forward into the AF position, the pinion 25 and the clutch plate 153 are also moved forward by the force of the compression spring 128 , so that the pinion 25 comes into engagement with the internal toothing 24 .

A locking device 165 locks the switching ring 31 when it is brought into the AF position. It is provided between the front end of the switching ring 31 and the stationary ring 10 . It has a plurality of locking grooves 166 with mutual angular spacing on the stationary ring 10 , as shown in FIGS. 28 and 29. The switching ring 31 is provided with locking pins 167 which engage in the locking grooves when the switching ring 31 is in the AF position. A spring 168 pushes the respective locking pin 167 forward in the direction of the optical axis. The locking pin 167 is held by a head 169 ge, which is fastened by a screw connection to the order switching ring 31 .

The lens barrel according to the fifth embodiment of the invention works as follows:
When the lens barrel is brought into the automatic position with the switch ring 31 moved forward as shown in FIG. 26, the first clutch device 43 releases the switch ring 31 and the focus ring 15 , and the clutch plate 153 leaves the pinion 25 in engage the internal toothing 24 . Furthermore, the locking device 165 locks the changeover ring 31 on the stationary ring 10 . The front end of the hitch be pin 48 , which is provided on the switching ring 31 , is thus in the position of the part smaller diameter on the outer surface of the focus ring 15 , so that it is disengaged from the focus ring 15 or only a slight Generated frictional contact. The pinion 25 moves forward due to the force of the compression spring 128 and comes into engagement with the internal toothing 24 . The locking pin 167 of the Sperrvor direction 165 comes into one of the locking grooves 166 on the stationary ring 10 , as shown in FIG. 28.

In this AF position, the automatic focusing is carried out as in the first embodiment. The switching ring 31 reaches the position shown in FIG. 26 in a short time, if it is rotated slightly, even if the locking pin 167 has not yet engaged in the locking groove 166 . When the lens barrel is brought into the automatic position, the switching ring 31 does not rotate, and the lens barrel cannot produce any unexpected effects due to the handle part being rotated unintentionally.

If the lens barrel is then brought into the MF position, for which purpose the switching ring 31 is moved backwards, as shown in FIG. 27, the coupling plate 153 releases the pinion 25 of the transmission shaft 26 from its engagement with the internal toothing 24 of the focusing ring 15 , and the locking device 165 releases the switching ring 31 . With the movement of the change-over ring 31 in the rearward position of the forked member 153 presses the clutch plate, the pinion 25 against the Druckfe 128 backward, so that the focus ring 15 comes out of engagement with the internal teeth 24th The locking pin 167 comes from the locking groove 166 , as shown in FIG. 29, and releases the switching ring 31 . If this is rotated manually, the rotation is transmitted to the focus collar 15 via the coupling pin 48 and the pin opening 47 . It is manually focused.

Even if the autofocus transmission shaft is rotated by the drive shaft of the camera housing, this rotation will not be transmitted to the focus ring 15 because the position of the switch ring 31 on a line in the direction of the optical axis by a detent of the detent ball 135 in the V-ring groove 133 is set.

Referring to Figs. 30 to 37 a sixteenth Stes embodiment will be described below, wherein like parts with be already described parts entspre have accordingly matching reference numerals and are not specifically explained.

In this embodiment, an internal gear 24 is constantly engaged with a clutch gear 225 for the focus ring on the stationary ring 10 so that it is freely rotatable about an axis that is parallel to the optical axis. A Antriebswel le 227 is arranged coaxially with the clutch gear 225 and can be moved relative to this in the direction of the optical axis. The construction of the lens barrel is different from the previously described embodiments by a second coupling device 226 , which is provided between the coupling gear 255 and the drive shaft 227 , so that it connects these two elements selectively. The drive shaft 227 receives the rotation of an auto focus connection shaft 229 via a gear 228 . As is known per se, the connecting shaft 229 is rotated by a drive belonging to an auto focus mechanism of the camera body, and this rotation is transmitted to the drive shaft 227 .

The second coupling device 226 , which is arranged at the upper end of the drive shaft 227 , consists of a convex coupling element 218 A, which has approximately the shape of a cross, and a concave coupling element 218 B, which has a cross-shaped convex part which is connected to the convex Coupling element 218 A comes into engagement. Both coupling elements 218 A and 218 B are made of a wear-resistant material. The clutch gear wheel 225 is continuously pressed forward with a compression spring 230 in the direction of the optical axis, ie in a direction in which the concave coupling element 218 B is to come into engagement with the convex coupling element 218 A.

In the same way as in the first embodiment, the stationary ring 10 carries a switching ring 31 which is freely movable back and forth in the direction of the optical axis and can be rotated about it. An inclined part 233 and a V-shaped annular groove 234 are provided on the inner circumference of the switching ring 31 in accordance with the AF position and the MF position. The stationary ring 10 is provided with detent balls 235 , which are inserted into the inclined part 233 and the annular groove 234 , and a leaf spring exerts pressure on the razor balls 235 toward the inner circumferential surface of the switching ring 31 .

A first coupling device 43 , which is largely identical to that of the first exemplary embodiment, is located between the switching ring 31 and the focus ring 15 . A part 44 of smaller diameter, an inclined part 233 and a part 46 of larger diameter are provided in this order from front to back in the direction of the optical axis on the inner circumference of the front region of the switching ring 31 . The focus ring 15 is provided with pin openings 47 along a line in the circumferential direction, which are directed radially ge. A coupling pin 48 , which can be brought into engagement with the part 44 of smaller diameter, the transition part 233 or the part 46 of larger diameter, can be moved in the radial direction. Each coupling pin 48 is pressed with a leaf spring 50 to the outside to the switching ring 31 . The leaf spring 50 is fixed at one end by means of a screw 251 on the inner circumference of the focus ring 15 be. On the stationary ring 10 , a circumferential slot 238 is provided, which allows the passage and the movement of the coupling pin 48 .

An annular groove 252 is also provided on the inner circumference of the switching ring 31 . A roller 254 on the coupling element 253 has a radial axis of rotation and is seated in the annular groove 252 . The coupling element 253 has a bifurcated part 256 which is held on the inner circumference of the stationary ring 10 so that it is movable parallel to the optical axis. It comes into engagement with a flange which is integrally formed on the coupling tooth wheel 225 for the focus ring 15 . With the forward or backward movement of the switching ring 31 , the coupling element 253 moves in the same direction and moves with its forked part 256, the clutch gear 225 forward or backward in the axial direction.

This means that the coupling element 253 does not act on the flange 255 of the coupling gear 225 when the switching ring 31 is in the AF position. The clutch gear 225 moves forward because it is under the action of the compression spring 230 , and the concave clutch member 218 B engages the convex clutch member 218 A. When the switch ring 31 is brought back to the MF position, the clutch member 253 presses but the clutch gear 225 against the force of the compression spring 230 , whereby the concave coupling element 218 B and the convex coupling element 218 A disengage. In this MF position, the internal gear 24 and the clutch gear 225 are not separated from each other.

Between the switching ring 31 and the stationary ring 10 , a switching device 270 is provided, which he summarizes the AF and the MF position of the switching ring 31 . It can be seen in the lower region of FIGS. 30 and 31 and is also shown in FIGS. 36 and 37. The switching device 270 has a circuit board 271 which in the direction is displaceable on the stationary ring 10 parallel to the optical axis, a roller 272 which is disposed on the circuit board 271 and is located in an annular groove 252 of the change-over ring 31, and a switching contact piece 273 and a base plate 274 , which are each arranged on the circuit board 271 and the stationary ring 10 and come into contact with each other. The switching device 270 detects the movement of the switching ring 31 in the AF or the MF position and generates by changing the position of the Schaltkon clock pin 273 and the base plate 274 a signal which characterizes the AF or the MF position of the switching ring 31 . This signal is transmitted via a pin 275 to a control circuit in the camera housing.

The lens barrel of the sixth embodiment described here works as follows. If the switching ring 31 is brought forward into the position shown in FIG. 30, the first coupling device 43 releases the switching ring 31 and the focus ring 15 , and the second coupling device 226 enables engagement of the concave coupling element 218 B of the coupling gear 225 with the convex coupling element 218 A of the drive shaft 227 . The Sperrvorrich device 65 locks the switching ring 31 on the statio nary ring 10th The upper end of the coupling pin 48 , which is held on the focus ring 15 , is then at the location of the part 46 larger diameter sers on the inner circumference of the switching ring 31 , as shown in FIG. 32, and is kept out of contact with the switching ring 31 . The concave coupling element 218 B of the clutch gear 225 , which is pressed forward by the compression spring 230 , comes into engagement with the convex coupling element 218 A of the drive shaft 227 .

When the autofocus link shaft 229 is rotated by a drive shaft of the camera body while the lens barrel is in the AF position, the rotation of the link shaft 229 on the focus ring 15 via the gear 228 , the drive shaft 227 , the concave coupling member 218 B , the convex hitch be element 218 A, the clutch gear 225 and the internal gear 24 transmitted so that the automatic focusing takes place. The locking ball 67 is seated in one of the locking grooves 66 of the changeover ring 31 . Even if it has not yet engaged, this can easily be achieved by slightly turning the switching ring 31 . Therefore, the switching ring 31 does not rotate in the AF position, and the lens barrel cannot produce any adverse effect that would otherwise be caused by unintentional rotation of the switching ring 31 , because this is held by the user as a grip part.

If the lens barrel is brought into the MF position, for which purpose the switching ring 31 is moved backward, as shown in FIG. 31, the first coupling device 43 brings the switching ring 31 and the focusing ring 15 into engagement, and the second coupling device 226 moves the coupling gear wheel 225 backward, whereby the concave coupling member 218 B and the convex Kupp averaging element 218 A come out of engagement. The Sperrvor direction 65 releases the switching ring 31 . The upper end of the coupling pin 48, the ring of the focusing 15 is held, is in strong friction contact with the part 44 of smaller diameter on the inner surface of the change-over ring 31 so that it and the focus ring 15 form a unit.

The forked part 256 of the coupling element 253 presses the clutch gear 225 of the focus ring 15 backwards, together with the backward movement of the switching ring 31 , so that the concave coupling element 281 B and the convex coupling element 218 A come out of a grip. The locking ball 67 moves out of the locking groove 66 . In this state, the switching ring 31 can be freely rotated, and if it is rotated manually, this rotation is transmitted to the focusing ring 15 via the part 44 of smaller diameter, the coupling pin 48 and the pin opening 47 , so that the manual focusing takes place.

At this MF position of the lens barrel, the auto focus drive shaft of the camera housing is not rotated, because an MF signal, which is emitted via the switching device 270 and the pin 275 , prevents the corresponding drive from being switched on. Thus, the connection shaft 229 is not rotated. The rotation is not transmitted because the concave coupling element 218 B and the convex coupling element 218 A are disengaged. The position of the switching ring 31 is limited in the axial direction by the detent ball 235 in the V-shaped annular groove 234 .

In the sixth embodiment described above, the drive shaft 227 is fixed in the direction of the optical axis, while the clutch gear 225 can be moved in the direction of the optical axis. In connection with the interaction of the clutch gear 225 and the drive shaft 227 it should be noted that the invention can also be implemented in such a way that the clutch gear 225 is fixedly arranged in the direction of the optical axis, while the drive shaft 227 , namely the convex coupling element 218 A can be moved along the optical axis. In this case, a coupling element 253 can be provided which moves the drive shaft 227 , namely the convex coupling element 218 A.

Referring to Figs. 38 to 44, a seventh example of execution is a lens barrel for a camera with auto matic focusing explained. Here, too, parts that have already been described are provided with the same reference characters, and they are not explained in more detail.

In this lens barrel, a focus ring 15 has a coupling pin 318 , which is aligned radially. An intermediate ring 319 is freely rotatable about the optical axis and is provided on the inner circumference of the stationary ring 10 . A clutch arm 320 is attached to this intermediate ring 319 with a screw 321 . The clutch arm 320 comes into engagement with the clutch pin 318 , whereby the intermediate ring 319 and the focus ring 15 are coupled. The intermediate ring 319 and the focus ring 15 can thus be rotated as one element.

A first clutch device 343 , which is shown in FIGS. 38, 39, 42 and 43, is provided between the switching ring 31 and the intermediate ring 319 . It is constructed in such a way that it enables the intermediate ring 319 to rotate freely relative to the changeover ring 31 when the changeover ring 31 is in the AF position. The switching ring 31 and intermediate ring 319 are each connected ver, when the switchover ring 31 in the MF position. The intermediate ring 319 has a plurality of coupling pin openings 347 in the radial direction, which are distributed around its order. In each opening 347 sits a coupling pin 348 , which optionally engages with the part 44 of smaller diameter, the transition part 45 or the part 46 of larger diameter and is displaceable in its opening. Each coupling pin 348 protrudes through the respective opening and is prevented from falling out by a head. A leaf spring 350 acts on the head and pushes it outward. The leaf spring 350 is attached at one end to the intermediate ring 319 by means of a screw 338 .

The switching ring 31 has stop portions 339 and 340 on the front and rear end sides. The stationary ring 40 is provided with stop walls 341 and 342 which come into contact with the stop regions 339 and 340 and thereby limit the range of movement for the forward and backward movement. The stop areas 339 and 340 are provided with an elastic element 330 , which forms a buffer when they come into contact with the walls 341 and 342 .

On the inner circumference of the switching ring 31 , a transmission ring 324 is provided on the inner circumferential surface of the intermediate ring 319 . This transmission ring 324 has an annular groove 325 on its outer circumference. A roller 326 , which is attached to the switching ring 31 and whose axis is directed radially, is set in the annular groove 325 . When the switching ring 31 is moved forward and backward in the direction of the optical axis, the transmission ring 324 is combined to move forward and backward in the direction of the optical axis.

In this seventh embodiment, the second coupling device 353 is provided with a coupling ring 328 , which enables free movement in the direction of the optical axis and is provided in the rear region of the transmission ring 324 . A clutch gear 327 is formed on the inner periphery of the clutch ring 328 . The clutch ring 328 is continuously pressed in the forward direction with a leaf spring 329 .

The clutch gear 327 is constructed so that it comes into engagement with an AF gear 355 of the AF drive mechanism, or is released therefrom, which depends on the position of the clutch ring 328 or the switching ring 31 in the direction of the optical axis. The AF gear 355 is via a gear 357 with a connecting shaft 356 , which is exposed on the back of the statio nary ring 10 , as shown in FIG. 40, brought into engagement and driven from the camera housing. The AF gear 355 is thus rotated in its fixed position relative to the optical axis when the connec tion shaft 356 in the AF position of the lens barrel to drive force is supplied.

A switching device 360 which detects the AF and the MF position of the change-over ring 31 is provided in the order switching ring 31st It has a stationary base plate 361 and a slide plate 362 which is arranged and mounted on the base plate 361 so that it can be displaced in the direction parallel to the optical axis. At the front end of the slide plate 362 , an engagement part 364 is formed, which comes with an inner flange 363 on the back of the transmission ring 324 into engagement. A tension spring 367 , which moves the slide plate 362 forward, is tensioned between the pin 365 on the slide plate 362 and a pin 366 on the switching ring 31 .

An AM switch 368 is provided over the stationary base plate 361 and the slide plate 362 . It is designed so that it detects the AF setting by moving the slide plate forward when the tension spring 367 is applied, while it detects the MF setting by moving the slide plate to a rearward position against the force of the tension spring 367 . The switching device 360 or the AM switch 368 operates in accordance with the position into which the switching ring 31 is moved, and thus independently of the interaction between the clutch gear 327 and the AF gear 355 .

A locking device 370 that locks the switching ring 31 when it is brought into the AF position is provided between the front end of the switching ring 31 and the stationary ring 10 . The locking device 370 is, as shown in FIGS . 38 and 39, with a plurality of locking grooves 371 at angular intervals of the stationary ring 10 , locking pins 372 in the locking grooves 371 when the switching ring 31 is in the AF position, and compression springs 373 which act on the individual locking pins 372 act.

The seventh embodiment of the lens barrel is working tet as follows.

As shows FIG. 38, the front end of the clutch pin 348 greater in the intermediate ring 319 in the position of member 46 diameter at the inner periphery of the order-switching ring 31. It is not in contact with the switch ring 31 when the lens barrel is in the AF position with the switch ring 31 moved forward. The clutch gear 327 of the clutch ring 328 is engaged with the AF gear 355 by the action of the leaf spring 329 . In this state, the rotation of the connecting shaft 356 due to the drive from the camera body on the focus ring 15 via the AF gear 355 , the clutch ring 328 , the intermediate ring 319 , the clutch arm 320 and the clutch pin 318 is transmitted, so that the automatic Focus is done. The locking pin 372 of the switching ring 31 sits in one of the locking grooves 371 of the statio nary ring 10th Even if this is not yet the case, it can easily be achieved by slightly rotating the switching ring 31 .

The lens barrel constructed in this way cannot exert any adverse effect on the user due to unintentional rotation of the handle part in the AF setting, since the switching ring 31 is not rotated in this state.

In this state of the lens barrel, the transmission ring 324 is moved to the front region, and its inner flange 363 has released the bent part 364 of the slide plate 362 . Therefore, the slide plate 362 slides forward by the action of the tension spring 367 , so that the AM switch 368 detects the AF setting.

If, however, the lens barrel is brought into manual focus, for which purpose the switching ring 31 is moved backwards, as shown in FIG. 39, the front end of the coupling pin 348 on the intermediate ring 319 comes into strong frictional contact with the part 344 of the smaller diameter of the switching ring 31 , whereby this and the intermediate ring 319 are coupled to one another. On the other hand, the transmission ring 324 moves backward together with the switching ring 31 , whereby the clutch ring 328 is acted upon and the clutch gear 327 and the AF gear 355 come out of engagement. In addition, the locking pin 372 moves out of the locking groove 371 , whereby the switching ring 31 is released.

If the switching ring 31 is rotated manually in this state, its rotation is transferred to the intermediate ring 319 via the part 344 of smaller diameter, the coupling pin 348 and the pin opening 347 . The rotation of the switching ring 31 is then transmitted to the focus ring 15 via the coupling arm 320 and the coupling pin 318 . Manual focus can therefore be carried out.

In this state of manual focusing, the inner flange 363 of the transmission ring 324 presses the bent part 364 and pushes the sliding plate 362 backwards against the force of the spring 367 . The AM switch 368 in the switching device 360 detects there through the MF operation of the lens barrel and outputs a signal to the camera housing. As a result, no torque is transmitted from the camera housing to the connection shaft 356 . Even if this were the case, such a rotation would not be transmitted to the clutch gear 327 , since the AF gear 355 and the clutch gear 327 are not coupled to one another.

As shown in FIG. 44, the setting of the AF operation and the MF operation with the AM switch 368 are detected at certain positions of the switching ring 31 independently of the engagement of the clutch gear 327 with the AF gear 355 . Therefore, a signal indicating the successful setting of the AF operation is given to the camera housing with absolute certainty, even if incomplete engagement of the clutch gear 327 with the AF gear 355 when switching between the AF operation and the MF operation with the Switching ring 31 is present, in particular at the time of switching from the MF mode to the AF mode. Accordingly, the AF gear 355 is rotated with the connecting shaft 356 and comes into engagement with the clutch gear 327 , which is acted upon by the leaf spring 329 , at a time when the AF gear 355 has been rotated slightly, so that the lens barrel is secure is brought into AF operation.

An eighth example of the lens barrel execution is explained with reference to FIGS. 45 to 52.

The 253 lens barrel 410 is provided for an interchangeable lens that contains two lens groups, namely a front lens group L 1 and a rear lens group L 2 . The focus is adjusted by moving the rear lens group L 2 in the direction of the optical axis. The front lens group L 1 is firmly seated in a stationary tube 412 , which has a holder 411 at its rear end for connection to the camera housing. The stationary tube 412 has a switching ring 413 on the outer circumference of its front end, which can be moved in the direction of the optical axis, and has a calibrated distance ring scale 414 , which is held on the inner circumference of its rear part. The switch ring 413 can be freely rotated. It also serves as a manual adjustment ring when it is placed in the MF position. The stationary tube 412 has an inner stationary cylinder 412 a, on the outside of which a guide ring 415 is freely rotatable. A movable tube 416 is fitted on the inner circumference. The distance ring scale 414 and the guide ring 415 are connected to a connecting element 417 and are always rotated in the same way. A calibrated distance scale, not shown, is provided on the outer circumference of the scale ring 414 and can be viewed through a window in the stationary tube 412 , which is also not shown.

A guide groove 419 for linear movement parallel to the optical axis is provided in the inner stationary cylinder 412 a. The guide ring 415 has a guide groove 420 . Radial pins 422 on the movable tube 416 are inserted into the guide groove 419 and the guide groove 420 so that the movable tube 416 is moved along the guide grooves 419 and 420 in the optical axis direction when the guide ring 415 is rotated. The movable tube 416 holds the rear lens group L 2 and an aperture block 418 . The rear lens group L 2 is therefore movable in the direction of the optical axis and is used for focusing when the guide ring 415 , ie the distance ring scale 414 , is rotated.

The auto focus mechanism rotates the range ring scale 414 with an electric motor, and an inner gear 423 concentric with the optical axis is formed on the inner periphery of the range ring scale 414 . A Ver connecting gear 425 is rotatably attached to the socket part 411 and a bearing plate 424 . It can be coupled via a coupling element provided on its rear side 425 a with a pinion within the camera housing and has teeth 425 b on the front side. This is in engagement with a gear 427 , which is mounted on the bearing plates 424 and 426 . A small gear 427 a, which sits on the axis of this gear 427 , constantly engages in a drive clutch toothed wheel 429 , which is fixedly connected at least in the axial direction to a switchover axis 428 . The drive clutch gear 429 is thus securely rotated when a driving force acts from the camera body via the connecting gear 425 .

The switching axis 428 carries a driven clutch gear 430 freely rotatable about the optical axis, and movable in the direction of the optical axis. This clutch gear 430 is freely rotatable with an axle bearing 431 held on the inner surface of the stationary tube 412 and engages in the internal gear 423 of the distance ring scale 414 . The driving clutch gear 429 and the driven clutch gear 430 have clutch teeth 429 a and 430 a on their mutually facing sides. These have as Fig. 49 a shape such that the driving clutch gear 429 and the driven clutch gear to be moved as a unit 430 when they are engaged to approach each other. All other gears except the inner gear wheel 423 are small gears that sit on the circumference of the lens barrel and are not concentric with the optical axis.

The upper end of the Umsch 13758 00070 552 001000280000000200012000285911364700040 0002004216908 00004 13639altwelle 428 is held on a guide plate 434 , which is attached to the stationary tube 412 with screws 433 . With a compression spring 435 , which surrounds the switching shaft 428 , as well as a washer 436 and a C-ring 437 at the front end of the switching shaft 428 , the guide plate 434 is pressed forward in a direction in which the clutch teeth 429 a of the driving clutch gear 429 in Engagement with the clutch teeth 430 a of the driven gear 430 come.

A switchover plate 438 for AF, MF detection is arranged on the guide plate 434 . This Umschaltplat te 438 has an elongated hole 438 a, which is dimensioned according to the screws 433 , a projection 438 b, which comes with a projection 413 a of the switching ring 413 in a handle and an engagement part 438 c for engagement with a step 428 a of the switching shaft 428 . The switch plate 438 can be moved in the same direction as the switch shaft 428 . It is also biased forward with a tension spring 439 which is secured between it and the guide plate 434 . The switchover plate 438 is assigned a code plate 440 which is fastened in the stationary tube 412 . A contact brush 441 is in contact with the code plate 440 and is attached to the switch plate 438 . The code plate 440 detects a shift between the AF position and the MF position, the contact brush changing its contact points on the code plate 440 , and transmits the information of the position change to an auto-focus motor control circuit 445 in the camera housing via a flexible circuit carrier 442 and an information port 443 near the socket part 411 . The engaging part 438 c moves the switching shaft 428 together with the switching plate 438 backwards when it is subjected to the projection 413 a of the switching ring 413 .

Coupling devices 413 c and 414 c are provided on the opposite side faces of the switching ring 13 and the range ring scale 414 . Connect reversing ring 413 with the distance ring scale 414 into one unit so that it turned anyone know when the operating ring 413 back in the MP position was the Windwärts moves.

In the lens barrel 410 , the switching shaft 428 and the driving clutch gear 429 move forward by the force generated by the compression spring 435 when the switching ring 413 is in the AF position, as shown in FIG. 45. Clutch teeth 429 a of the driving clutch gear 429 engage characterized in the clutch teeth 430 a of the driven clutch gear 430th Then the information that the switching ring 413 is in the AF position is detected with the code plate 440 and the contact brush 441 and the AF motor control circuit 445 via the flexible circuit carrier 442 and the information connection 443 leads to. The AF motor control circuit 445 rotates the connecting shaft to reverse the positive and negative sides in the camera body in accordance with the information about the focusing of the object to be recorded. The rotation of the connecting shaft is transmitted to the connecting gear 425 , and this movement is further transmitted to the driven clutch gear 430 via the gear mechanism described above and from the internal gear 423 to the removal ring scale 414 , the guide ring 415 and the movable tube 416 . Therefore, the rear lens group L 2 moves in the direction of the optical axis, and the automatic focusing is carried out.

In contrast, the projection 413 a pushes on the projection 438 b when the switching ring 413 is moved backward into the MF position, and the projection 438 b then moves the switching shaft 428 and the driving clutch gear 429 via an engaging part 438 c, whereby the Clutch teeth 429 a and 430 a come out of engagement. At the same time the switching ring 413 is connected via the coupling device 413 c and 414 c to the range ring scale 414 , so that both rotate uniformly. With the rotation of the switching ring 413 , manual focusing is carried out. The information that the switch ring 413 is in the MF position is detected with the code plate 440 and the contact brush 441 and output to the AF motor control circuit 445 via the flexible circuit carrier 442 and the information terminal 443 . In the MF setting, motor control circuit 445 does not rotate the connection shaft from the camera body.

As described above, this eighth exemplary embodiment has a coupling device which, although it has a simple structure, works with a high level of security and therefore makes the switchover between AF and MF operations smooth and effective. For this purpose, the lens barrel, in which the focusing lens group is moved in the direction of the optical axis by rotating a focusing ring, is provided with a gearwheel concentric with the optical axis, a floating clutch gearwheel which is rotated by the camera housing being arranged in such a way that that it engages in a driven clutch gear or is separated from it. The driven clutch gear can constantly engage in the gear concentric with the optical axis. It is moved relative to the driven clutch gear with a switch shaft that moves in the optical axis direction and is coupled to the switch ring 413 .

The aperture block 418 has a plurality of diaphragm blades 453 between an opening and closing ring 451 and a diaphragm retaining ring 452 known per se. A to drive element 453 a on one side of Blendenlamel le 453 sits in a non-illustrated Blendenbe tätigungsnut in the opening and closing ring 451, and an orifice pin 453 b on the other side of the baffle plate 453 sits in a holding opening 452 a of the retaining ring 452 . The retaining ring 452 is fixed to the stationary tube 412 , and the opening and closing ring 451 can be rotated freely. It has a drive rod 455 , which is parallel to the optical axis and is moved with a drive arm 456 . The drive arm 456 is attached to the statio nary tube 412 with an axis 457 , the rear part being driven 456 a at the rear holding the frame part 411 ge and the connecting pin on the front part acts on the drive rod 455 . The axis 457 is provided on the holding plate 459 , which is fastened to the stationary tube 412 with a screw 458 . The driven part 456 a is rotated by a predetermined angle, for example with a diaphragm drive element, and thereby the diaphragm opening, which is formed with the diaphragm blades 453 , is enlarged or reduced.

In the lens barrel 410 , the internal gear 423 in the distance ring scale 414 is a large gear coaxial with the optical axis, which is coated with a small amount of lubricating oil. This can adhere to the clutch gear 430 , which continuously meshes with the inner gear 423 . If the clutch gear 430 is rotated rapidly, the lubricating oil is splashed rich in its loading. The aperture block 418 is arranged near the clutch gear 430 and comes next when the lens is set to infinity, with the rear lens group L 2 , namely the movable tube 16 , being shifted farthest backwards. If oil is splashed onto the aperture block 438 and adheres to the aperture blades 453 , for example, its function deteriorates and the adhering oil produces a glitter effect which causes reflection on the inner surface of the lens. If the oil adheres to the lens surface of the rear lens group, it produces an optical deterioration of the lens and similarly a reflection on the inner surface of the lens.

Therefore, a protective cover 447 is provided on the clutch gear, which continuously engages in the internal gear 423 , so that splashing of oil on the side of the optical axis is prevented. This cover 447 is fastened with a screw 446 to the bearing plate 431 , which is rigidly connected to the stationary tube. The cover 447 has a circular cover part 447 a, which covers the clutch gear 430 according to its outer contour. Furthermore, a release part 447 c with an insert groove 447 b for the switching shaft 428 is provided. This cover 447 lies with the circular cover part 447 a to the side of the optical axis (ie towards the diaphragm block 418 ), and with the release part 447 c radially outwards.

The cover 447 can prevent the oil, which is thrown off the clutch gear 430 when the clutch gear 430 rotates rapidly, from adhering to the aperture block 418 or the lenses of the rear lens group L 2 .

The rotation of the clutch gear 430 with high speed Ge occurs in the AF setting, in which the clutch teeth 429 a and 430 a are in a handle, with the switching ring 413 according to FIG. 45 in its foremost position. Here, the rotation is transmitted to the connecting gear 425 via the coupling with the camera body. The rotation of the connecting gear 425 is further transmitted to the clutch gear 430 via the gear train described above and then transmitted from the internal gear 423 to the range ring scale 414 , the guide ring 15 and the movable tube 416 .

In contrast, the switching ring 413 presses its projection 438 b when it moves backward with the projection 413 , which moves the switching shaft 428 and the clutch gear 429 with the engagement part 438 c backwards. This disengages the clutch teeth 429 a and 430 a. At the same time, the switching ring 413 is brought into engagement with the distance ring scale 414 with an engagement mechanism , not shown, so that both rotate uniformly. The manual focusing can then be carried out by turning the switch ring 413 .

Although in the eighth embodiment described above Example of the invention as an autofocus lens Interchangeable lens described with a gear mechanism ben, the invention can also be a so-called PZ lens can be applied. There is an oil cover then in a similar manner for at least part of the To provide gears of the drive mechanism when one Lens group variable magnification via a gear is moved. In this case too, it is advantageous an oil protection cover on the small gear to provide that constantly in the optical axis concentric drive gear for the lens takes hold.

The eighth embodiment described above a lens barrel has a construction in which a Cover as oil protection at least the outer circumference of the gear on the side of the optical axis  and is provided in at least one of the gears, which are not concentric with the optical axis and are arranged in the peripheral region of the lens barrel. It this eliminates the risk that lubricating oil in the Area of the optical axis is thrown and the Individual parts arranged there are dirty, for example instruct the aperture and the lenses of an electrically driven lens, in which a lens group in Rich device of the optical axis is moved via a gear.

Claims (27)

1. lens barrel for a camera with automatic focusing, with a focusing ring ( 15 ) for moving a focusing lens (L 1 ) in the direction of the optical axis by rotating around the optical axis, and with an automatic focusing device ( 28 ) for rotating the focusing ring ( 15 ) by drive with a motor, characterized by a changeover ring ( 31 ) which can be rotated manually about the optical axis and can be moved in the direction of the optical axis between an AF position for automatic focusing and an MF position for manual focusing, by ei ne first coupling device ( 43 ) for releasing a connection between the switching ring ( 31 ) and the focus ring ( 15 ) for their mutually independent rotation in the AF position of the switching ring ( 31 ) and for connecting the switching ring ( 31 ) with the Focus ring ( 15 ) for the purpose of uniform rotation in the MF position of the switching ring ( 31 ) and by a tw eite coupling device ( 53 ) for connecting the automatic focusing device ( 28 ) and the focusing ring ( 15 ) in the AF position of the switching ring ( 31 ) and for releasing this connection in the MF position of the switching ring ( 31 ). 2. Lens barrel according to claim 1, characterized by a locking device ( 65 ) for locking the switching ring ( 31 ) in the direction of rotation when it is in the AF position, and for releasing this lock when it is in the MF position. 3. Lens barrel according to claim 1 or 2, characterized in that the first coupling device ( 43 ) contains:
at least one coupling pin (48) on the order shift ring (31) or the focus ring (15) to the focus ring ei NEN non-engaging portion (46) (15) or the operating ring (31) for disengagement from the coupling pin (48), when the switch ring ( 31 ) is in the AF position, and an engagement part ( 44 ) on the focus ring ( 15 ) or the switch ring ( 31 ) for engagement with the clutch pin ( 48 ) when the switch ring ( 31 ) in the MF position is to connect it to the focus ring ( 15 ) for common rotation. 4. lens barrel according to claim 3, characterized in that the coupling pin ( 48 ) on the focus ring ( 15 ) and the non-engaging part ( 46 ) and the engaging part ( 44 ) on the switching ring ( 31 ) are provided. 5. Lens barrel according to one of the preceding claims, characterized in that the first coupling device ( 43 ) contains:
at least one locking ball (71) on the switching ring (31) or the focus ring (15), and min least one latching groove (70) on the focus ring (15) or the operating ring (31) ball of the detent (71) when the Switching ring ( 31 ) is in the MF position in order to connect the switching ring ( 31 ) with the focusing ring ( 15 ) for common rotation with one another. 6. lens barrel according to claim 5, characterized in that the locking ball ( 71 ) on the sharp adjusting ring ( 15 ) and the locking groove ( 70 ) on the switching ring ( 31 ) is provided. 7. Lens barrel according to one of the preceding claims, characterized in that the first coupling device ( 43 ) contains:
a blocking pinion (76) which is rotatably supported on the operating ring (31) or the focus ring (15), a toothed circumferential groove (80) on the focus ring (15) or the operating ring (31) with egg nem predetermined distance from the blocking pinion ( 76 ) when the switch ring ( 31 ) is in the AF position, and a toothed locking groove ( 81 ) on the focus ring ( 15 ) or the switch ring ( 31 ) on which the locking pinion ( 76 ) sits when the switch ring ( 31 ) is in the MF position, whereby the locking pinion ( 76 ) generates a frictional engagement between the switching ring ( 31 ) and the focus ring ( 15 ) for the purpose of common rotation. 8. lens barrel according to claim 7, characterized in that the locking pinion ( 76 ) on the switching ring ( 31 ) and the toothed circumferential groove ( 80 ) and the toothed locking groove ( 81 ) on the focusing ring ( 15 ) are provided. 9. lens barrel according to one of claims 1 to 7, characterized in that the first coupling device ( 43 ) contains:
a locking pinion ( 76 ), which is rotatably mounted on the switching ring ( 31 ) or the focus ring ( 15 ), a cylindrical part ( 83 ) small diameter on the focus ring ( 15 ) or the switching ring ( 31 ), which is a predetermined distance to the locking pinion ( 76 ) when the switching ring ( 31 ) is in the AF position, and a toothed locking groove ( 81 ) on the focusing ring ( 15 ) or the switching ring ( 31 ) on which the locking pinion ( 76 ) sits, when the switching ring ( 31 ) in the MF-Posi tion, so that the locking pinion ( 76 ) a frictional connection between the switching ring ( 31 ) and the focus ring ( 15 ) for common rotation he testifies. 10. lens barrel according to claim 9, characterized in that the locking pinion ( 76 ) on the switching ring ( 31 ) and the cylindrical part ( 83 ) of small diameter and the toothed locking groove ( 81 ) on the focusing ring ( 15 ) are provided. 11. Lens barrel according to one of claims 1 to 7, characterized in that the first coupling device ( 43 ) contains:
at least one coupling pin ( 48 ) on the switching ring ( 31 ) or the focus ring ( 15 ), a cylindrical part ( 44 ) of small diameter on the focus ring ( 15 ) or the switching ring ( 31 ) for contact with the coupling pin ( 48 ) or Release the coupling pin ( 48 ) from the focus ring ( 15 ) when the switch ring ( 31 ) is in the AF position, and a cylindrical part ( 46 ) of large diameter on the focus ring ( 15 ) or the switch ring ( 31 ) into one strong friction circuit with the coupling pin ( 48 ) and its connection with the focusing ring ( 15 ) when the switching ring ( 31 ) is in the MF position, around the switching ring ( 31 ) with the focusing ring ( 15 ) for common rotation connect to. 12. Lens barrel according to claim 11, characterized in that the coupling pin ( 48 ) on the switching ring ( 31 ) and the cylindrical part ( 44 ) of small diameter and the cylindrical part ( 48 ) of large diameter on the focusing ring ( 15 ) are provided . 13. Lens barrel according to claim 12, characterized in that the switching ring ( 31 ) has at least egg ne radial opening ( 47 ) into which the coupling pin ( 47 ) is inserted movably. 14. Lens barrel according to claim 13, characterized in that the first coupling device ( 43 ) contains a pressure element ( 50 ) for pressing the coupling pin ( 48 ) out of the focus ring ( 15 ), and that the cylindrical part ( 46 ) of large diameter comes into contact with the coupling pin ( 48 ) against the pressure force of the pressure element ( 50 ). 15. Lens barrel according to one of the preceding claims, characterized in that the second coupling device ( 53 ) contains:
a clutch gear ( 327 ) which is rotatable with the rotation of the focus ring ( 15 ) and movable in the direction of the optical axis with the movement of the switching ring ( 31 ) between the AF position and the MF position, and an autofocus gear ( 353 ), which is driven by the motor and engages in the clutch gear ( 327 ) when the switching ring ( 31 ) is in the AF position, while it does not engage in the clutch gear ( 327 ) when the switching ring ( 31 ) is in the MF position. 16. lens barrel according to any one of the preceding claims, characterized by a Erfassungsvor direction ( 360 ), which detects the setting of the automatic focusing or manual focusing as an operating mode. 17. Lens barrel according to claim 16, characterized in that the detection device ( 360 ), the AF mode or the MF mode accordingly, the position of the switching ring ( 31 ) independently of the actuation of the clutch gear ( 327 ). 18. Lens barrel according to one of the preceding claims, characterized in that the sharp collar ( 15 ) contains a central gear ( 423 ) coaxial with the optical axis. 19. Lens barrel according to claim 18, characterized in that the first coupling device ( 43 ) has a driven clutch gear ( 430 ) in a handle with the central gear ( 423 ) of the focus ring ( 15 ), a driving clutch gear wheel ( 429 ) in connection with the motor and in Rich direction of the optical axis for engagement with the driven clutch gear ( 430 ) movable and a shift shaft ( 428 ) in conjunction with the driving clutch gear ( 429 ) and movable in the direction of the optical axis, wherein the driving clutch gear ( 429 ) engages in the driven clutch gear ( 430 ) when the switching ring ( 31 ) is in the AF position. 20. Lens barrel according to one of the preceding claims, characterized in that the automatic focusing device includes a gear train for transmitting the torque from the motor to the focusing ring ( 15 ). 21. Lens barrel according to claim 20, characterized by an oil protection cover ( 447 ) on a gear wheel ( 430 ), which forms the gear train and lies outside the optical axis, for covering at least the outer circumference of the gear wheel ( 430 ) towards the optical axis, to prevent splashing of the oil supplied to the gear train. 22. lens barrel according to claim 21, characterized in that with the cover ( 447 ) verse hene gear in a central gear ( 423 ) engages, which is rotatable about the optical axis and the focusing lens (L 1 ). 23. lens barrel for a camera with automatic focusing, with a focusing ring ( 15 ) for moving a focusing lens (L 1 ) in the direction of the optical axis by rotating around the optical axis, and with an automatic focusing device ( 227 ) for rotating the focusing ring ( 15 ) by drive with a motor, characterized by a switching ring ( 31 ) for optionally setting an AF position for automatic focusing or an MF position for manual focusing, which can be rotated manually around the optical axis and in the direction of the opti rule between the AF position and the MF position is movable by a coupling gear ( 225 ) which is rotatable together with the focus ring ( 15 ), by a first clutch device ( 43 ) for releasing a connection between the switching ring ( 31 ) and the focus ring ( 15 ) for their independent rotation when the switch ring ( 31 ) is in the AF position t, and for connecting both for common rotation when the switch ring ( 31 ) is in the MF position, and by a second clutch device ( 226 ) for connecting the automatic focusing device ( 227 ) and the clutch gear ( 225 ) when the switch ring ( 31 ) is in the AF position, as for releasing this connection, when the switching ring ( 31 ) is in the MF position. 24. Lens barrel according to claim 23, characterized by a locking device ( 65 ) for locking the switching ring ( 31 ) in the direction of rotation when it is in the AF position, and for releasing the lock when it is in the MF position. 25. Lens barrel according to claim 24, characterized in that the automatic Fokusierungsvor direction has a drive shaft ( 227 ) in connection with the motor and a handle portion provided thereon ( 18 A), and that the engaging part ( 18 A) with the clutch gear ( 225 ) engages to connect the two to rotate together when the switch ring ( 31 ) is in the AF position, while the engagement part ( 18 A) is released from the clutch gear ( 225 ) when the switch ring ( 31 ) is in the MF position. 26. Lens barrel according to claim 25, characterized in that the clutch gear ( 225 ) and the drive shaft ( 227 ) are coaxial. 27. Lens barrel according to claim 26, characterized in that the coupling gear ( 225 ) with the drive shaft ( 227 ) is connected so that it is movable in the direction thereof.