DE4312490A1 - Zoom camera lens barrel - detects focal length variance such that data is transmitted to camera body through flexible printed circuit board - Google Patents

Abstract

A code plate (36) detects focal length variance during zooming so that focal length data can be transmitted to a camera body, through a flexible printed circuit (FPC) board (37). One of the code plate and brush assembly (41) is secured to a mounting member and the other is secured to a linearly movable member movable with respect to the mounting member. The brush assembly has deformable legs for connectors to the board and is connectable to the plate. A screw (33) is rotatable against the bias of a spring (30) to adjust the relative position of the plate and bushes.

Description

The invention relates to a tube for a vario Objectively, as he in the preamble of claim 1 is specified. With this zoom lens one can Focal length change with a code plate and on it contact brushes are detected so that corresponding data on a flexible printed Circuit can be transferred to the camera body.

In a known zoom lens with a cam ring To change the focal length, the set one is used Focal length recorded with a code plate on a stationary ring is attached and to the contact brushes while rotating the cam ring. The code plate has a predetermined contact pattern. When changing the focal length, the contact brushes rotated together with the cam ring and slide on the Code plate so that the ent of the respective focal length speaking data to a control circuit of the camera can be transferred. The one to control the camera  Required data is made up of multiple data tables variable information selected and the tax switching of the camera depending on the focal length data fed.

The known lens barrel is flexible Circuit carrier with the contact brushes at solder joints connected. But soldering is cumbersome and expensive playful.

Furthermore, since the corresponding focal length Tax data from tables of variable information selects and according to the recorded focal length Camera housing must be transferred, the contact brush and code plate in predetermined reference positions must be arranged very precisely. Otherwise would be the angular position of the cam ring relative to that stationary ring of the camera body is not precisely recorded and an error in focal length detection during introduced their change.

Furthermore, in the known zoom lens, the code plate attached to the outer circumference of the stationary ring, and the contact brushes are turned by turning the cam around the code plate in the circumferential direction of the statio guided around the ring. It is therefore very difficult rig, an accurate and optimal relative position of the code plate and the contact brushes z. B. by a fine position during assembly. To do this the shape and position of the code plate and the Contact brushes can be extremely accurate, which also makes the manufacturing costs are increased.

Since the camera operation depends on the focal length data is controlled, which is removed via the contact brushes  must be predetermined with a constant Press against the code plate to make a to achieve accurate signaling. However, this requires costly and complicated arrangements in the vario lens.

It is an object of the invention to provide an improved Specify lens barrel in which a simpler ver bond between the contact brushes and the flexible Circuit carrier is possible.

The invention solves this problem by the features of Claim 1, 6 or 17. Advantageous further education are subject of respective subclaims.

The invention leads to a tube for a vario objective where the position of the contact brushes between a code plate and a flexible scarf can be easily adjusted. Same thing applies to setting the code plate and the contact brush relative to each other. Overall, there is a simple lens barrel, in which the contact brushes with a largely constant pressure against the code plate pressed and thereby a correct reading of the Signals indicating focal length data is possible.

In one embodiment of the invention, the code plate or the contact brush arrangement on one Mounting element and the other part in one be linearly movable element attached. It is the contact brush assembly with one or more elastically deformable legs provided on the flexible circuit carriers are to be attached while a connecting portion with the code plate in verbin manure stands. The stationary or the linearly movable  Element to which the contact brush arrangement is attached has an insertion groove for the flexible circuit carrier with which the or the elastically deformable Legs of the contact brush assembly come into contact can. The flexible circuit carrier has an on setting part, between the insertion groove and the elastic deformable legs is used.

A basic idea of the invention is therefore that elastically deformable legs in elastic contact to bring with the flexible circuit carrier.

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

Fig. 1 is a perspective view of a connecting device auseinandergezo gene between a code plate and a flexible printed circuit board as an exemplary embodiment,

Fig. 2 sten the longitudinal section of a front lens barrel and which dissolved Kontaktbür,

Figure 3 is a front lens barrel costs. The longitudinal section with inserted Kontaktbür,

Fig. 4 shows the longitudinal section of a front lenses tubus with contact brushes and eliminator system restraining member,

Fig. 5 is a rear view of the code plate and the flexible circuit carrier according to Fig. 3,

Fig. 6 is a rear view of another Anord voltage of a code plate and a fle ible circuit carrier with a slightly modified guide groove,

Fig. 7 is a rear view of an amended an arrangement, similar to FIG. 6,

Fig. 8 is a perspective view of egg ner code plate on the inner surface ei nes Frontlinsentubus,

Fig. 9 is a plan view of the ge in Fig. 8 showed arrangement,

Fig. 10 shows the section of a code plate,

11 is a perspective view towards a auseinanderge plated Einstellvor.,

Fig. 12 is a rear view in FIG. 11 ge showed apparatus,

Fig. 13 and 14 are representations of a viewing window in which a trademark of Einstellvorrich tung appears, for different positions,

Fig. 15 is a longitudinal section of a tube according to the invention,

Fig. 16 is a longitudinal section of the principal parts of the tube of FIG. 15, and

FIG. 17 is a perspective exploded view of the most important parts of the tube shown in FIG. 15.

In the following, a tube for a zoom lens, in which the invention is to be applied, is explained generally with reference to FIGS. 15 and 17. A stationary lens tube 11 , which is connected to a camera housing, carries a screw ring 12 attached to it, which is provided with an internal thread 12 a. In this sits an external thread 10 a of a cam ring 10 . This has on its inner circumference an internal thread 10 b and an inner guide groove 10 c. An external thread 13 a of a front lens barrel 13 is engaged with the Innenge thread 10 b. Shielding plates 25 and 26 with openings 25 d and 26 d, each of which corresponds to an opening of the camera housing, are arranged behind the rear end of the cam ring 10 . They have at their upper edges positioning recesses 25 a and 26 a, so that Introductio approximately part 23 b of a fixed to the camera body linear motion guide 23 in the Positionierausschnit te 25 a and 26 a and b in a Positionierausschnitt 15 can be used in a linear motion guide ring 15 . The shielding plates 25 and 26 are attached to the guide ring 15 so that the Positionieraus sections 25 a and 26 a are aligned with the positioning cutout 15 b. The cam ring 10 is rotatably placed on the guide ring 15 . The linear motion guide 23 is attached to holding parts 24 and on the camera housing with screws 22 so that the guide part 23 b is in the direction of the optical axis.

On the front lens barrel 13 , a shutter bracket 13 c is attached, which holds the rear end of an annular shutter unit 16 . The closure unit 16 has on its inner circumference a screw ring 17 into which a front lens mount 18 is screwed, which holds a front lens group L1. The closure unit 16 has a drive pin 16 a, on which a driven pin 18 a acts, which is formed on the front lens frame 18 .

As is known, the drive pin 16 a corresponding to an object distance signal rotated, which is discharged from an unillustrated distance measuring unit, and the rotation of the drive pin 16 a is transmitted to the front lens barrel 18 via the driven pin 18 a. As a result, the lens frame 18 with the front lens group L1 is moved in the direction of the optical axis while being rotated to focus. The shutter unit 16 opens and closes its shutter blades 16 b depending on a brightness signal that is caused by the object to be recorded. In Fig. 17 a lens is further illustrated aperture 13 f. A rear lens frame 19 holds a rear lens group L2 and has a cam pin 19 a, which protrudes in the radial direction and sits in the inner guide groove 10 c of the cam ring 10 . The rear lens frame 19 and the bracket 13 c for the closure unit are guided on linear movement guides 15 a, which are provided on the guide ring 15 . The linear motion guides 15 a guide them accordingly, linear motion guides 19 b of the rear lens holder 19 , as shown in FIG. 17.

The cam pin 19 a of the rear lens frame 19 is seated in a recess 19 b at the rear of the front lens barrel 13 . If an external thread 13 a of the front line sentubus 13 sits in the internal thread 10 b of the cam ring 10 , the cam pin 19 a is in the guide groove 10 c. At the end of the lens assembly, the front lens barrel 13 and the rear lens mount 19 are moved independently of one another in the direction of the optical axis, corresponding to the threads 10 b and 13 a and the guide groove 10 c, when the cam ring 10 is rotated.

By its rotation, the cam ring 10 is moved in the direction of the optical axis, since the threads 10 a and 12 a interlock. At the same time, the front lens tube 13 and accordingly the front lens group L1 as well as the guide ring 15 is moved linearly in the direction of the optical axis, and the front lens tube 13 is also moved linearly relative to the cam ring 10 and the guide ring 15 . The linear movement of the front lens barrel 13 arises because the thread 10 b and 13 a and the linear movement guide of the closure bracket 13 c and the guide ring 15 ineineinergrei fen. When the cam ring 10 is rotated, the rear lens frame 19 or the rear lens group L2 is also moved in the same direction because the guide ring 15 moves in the direction of the optical axis, and the rear line frame 19 becomes the same if opposite the cam ring 10 and the guide ring 15 moves linearly. The linear movement of the rear lens barrel arises because the guide groove 10 c of the cam ring 10 and the cam pin 19 a of the rear lens barrel 19 and the ren Linearbewegungsfüh approximately mechanism of the rear lens barrel 19 and the guide ring 15 mesh. This changes the focal length of the lens.

The cam ring 10 has at its rear part a multiple external thread 10 a and a plurality of parallel teeth 10 d, each forming a gear wheel, the teeth of which are parallel to the axis of the cam ring 10 . The serrations 10 d have a slope in the same direction as the threads of the external thread 10 a. Between adjacent teeth 10 d is a thread 10 a '. The multiple thread 10 a is so partially cut away in the circumferential direction to form the threads 10 a ', so that the teeth 10 d are formed in the cut parts wegge. In the illustrated embodiment, the multiple thread 10 a has three threads, so that the teeth 10 d are in their cut parts Wegge. The multiple thread 10 a, the threads 10 a 'and the serrations 10 d have a matching axial length s.

The screw ring 12 has on its inside a multiple internal thread 12 a and recesses, etc. accordingly the multiple external thread 10 a, the threads 10 a 'and the three teeth 10 d of the cam ring 10th If the cam ring 10 is rotated according to the thread engagement with the multiple thread 10 a (threads 10 a ') and the thread 12 a, the serrations 10 d are moved in the wells without having contact.

The screw ring 12 has a Ausspa tion 12 d so that a not shown, there angeord net pinion can engage in the teeth 10 d. The pinion has an axial length that enables engagement in at least one of the three toothings 10 d via the full movement of the cam ring 10 . Nevertheless, the pinion engages only in the rearmost or frontmost toothing 10 d when the cam ring 10 is in its front most or rearmost limit position. The pinion is rotated with a drive motor, not shown.

An adjusting device is described below. This forms a variomechanism that is driven by rotating the cam ring 10 to change the focal length of the lens. This includes a code plate 36 on the inner circumference of the front lens barrel 13 (linearly movable element), which is moved linearly in the direction of the optical axis. A contact brush holder 40 holds contact brushes 41 which are in contact with the code plate 36 in order to detect the respective focal length. An adjustment mechanism for the contact brushes adjusts the position of the contact brush holder 40 in the direction of the optical axis. Accordingly, a reference angular position of the cam ring 10 is changed when adjusting the position of the contact brush holder with the adjusting device. A device is also provided which detects when the cam ring 10 is in a predetermined reference angular position.

As shown in Fig. 10, the code plate 36 has a predetermined contact pattern. During the lens adjustment, the code plate 36 is moved together with the front lens tube 13 in the direction of the optical axis, and the contact brushes 41 then optionally come into contact with the contact pattern, so that the digital signals (focal length data) corresponding to the current focal length are sent to a control circuit ( not shown) can be delivered to the camera. In accordance with the focal length data, control data are selected from data tables which contain variable information.

The front lens barrel 13 has an insertion groove 13 e on its inner circumference, which lies parallel to the optical axis O. As shown in FIG. 8, it has at its end facing the aperture 13 f an engagement projection 13 d, which sits in a positioning hole 36 a at one end of the code plate 36 . The code plate 36 is set in the direction parallel to the optical axis when the grip projection 13 d sits in the positioning hole 36 a. It is firmly connected with its back to the bottom of the insertion groove 13 e (glued).

The contact brush holder 40 is shown in Fig. 2 and consists of a in the side view L-shaped plate te made of synthetic resin. It has a stopper portion 40 b that comes with a holding portion 15 c of the guide ring 15 (stationä res element) is in contact, and a positioning part 40 c, the 41 accordingly transmits the four contact brushes the contact pattern of the code plate 36 and positio ned. The holding part 15 c has a bore 33 in which an adjusting screw 31 is seated. The stop part 40 b has a threaded bore 40 a, which is opposite to the bore 33 . The contact brushes 41 have at one end an elastically deformable contact section 41 a (for abutment on the flexible circuit carrier), which comes into elastic contact with egg nem connection section 37 a of a flexible circuit carrier 37 when the contact brush holder 40 on the holding part 15 c with A set screw 31 is attached. The other ends of the contact brushes 41 have contact sections 41 b which are in sliding contact with the code plate 36 .

The holding part 15 c also has a spring insertion opening 32 (FIGS . 1 and 17) near the bore 33 . The spring insert opening 32 extends through the holding part 15 c to the stop part 40 b similar to the bore 33 . A spacer spring 30 is compressed in the spring insert opening 32 and lies at one end on the contact brush holder 40 and at the other end on the shield plate 26 , so that the ge with the holding part 15 c holding contact brush holder 40 with the spacer spring from the holding part 15th c is pushed away.

The bore 33 is accessible through the opening 26 c ( Fig. 1, 11 and 12) of the shield plate 26 when the order is mounted. The opening 26 c and the bore 33 are arranged within the aperture A ( Fig. 12). Therefore, they are exposed when a rear wall, not shown, is opened.

In the assembled state, in which the contact brush holder 40 is attached to the holding part 15 c, the contact brush holder 40 is moved when the adjusting screw 31 is tightened or loosened. This enables the position of the terminals 41 b of the contact brush 41 to be set relative to the code plate 36 . The spacer spring 30 , which pushes the contact brush holder 40 away from the holding part 15 c, and the adjusting screw 31 , which holds the contact brush holder 40 on the holding part 15 c, form a contact brush adjusting device.

As is apparent from the above description, the relative position of the code plate 36 and the con tact brushes 41 can be easily adjusted when the adjusting screw 31 is rotated after opening the rear wall. Therefore, the shape and position of the code plate and contact brushes can be less accurate than before. This leads to reduced manufacturing costs for the lens barrel.

As shown in FIG. 1, the linear motion guide 15 a, which is provided with the holding part 15 c, has a receiving groove 38 for the contact brush holder 40 with the contact brushes 41 . The width of the receiving groove 38 largely corresponds to the width of the contact brush holder 40 . This linear movement guide 15 a has in its center an inhibiting element 39 which bridges the receiving groove 38 .

The inhibiting element 39 limits the sliding contacts 41 b of the contact brushes against an extreme external position in the direction of the code plate 36 , ie it limits the outward restoring force of the sliding contacts 41 b. So these are secured by a simple barrier 39 in the form of a Querele bridging the receiving groove 38 element.

The inhibiting element 39 prevents the Schleifkontak te 41 b of the contact brushes 41 from touching the code plate with excessive pressure by limiting the restoring force of the sliding contacts 41 . Furthermore, the inhibiting element 39 prevents the sliding contacts 41 b from touching the rear side of the front lens barrel 13 during assembly, so that they cannot be damaged thereby.

Since the inhibiting element 39 prevents the free ends of the contact brushes ( FIG. 4) from moving outward by the restoring force, it contributes to a largely constant contact pressure of the contact brushes 41 on the code plate 36 , so that the detection signals indicating the focal length are correctly read can.

The holding part 15 c has, as shown in FIGS . 2 and 5, an outer flattening 15 e, on which the connecting part 37 a of the flexible circuit carrier 37 is arranged. At the connections 41 a of the contact brushes 41 touch this to the connecting section 37 a elastic. It forms an insert part of the flexible circuit carrier 37 , which is to be inserted into a space between the flattening 15 e and the connections 41 a. The connection section 37 a has electrically conductive, in the direction of insertion elevations 37 b, which are electrically connected to the terminals 41 a.

To the contact brush 41 in the receiving groove 38 to consolidate to be, they are arranged on the flattened portion 15 e, and thereafter the contact brush holder 40 is nahmenut in the up used 38, so that the b with the terminals 41 provided portions of the contact brushes 41 at the rear the barrier 39 . The Anschlussab section 37 a is inserted between the connections 41 a and the flat 15 e and hold festge between the two. Thus, the contact brushes 41 can be easily and securely connected to the flexible circuit carrier 37 , which in turn is connected to the control circuit of the camera.

Even after the connection between the contact brushes 41 and the flexible circuit carrier 37 has been established , the connections 41 a of the contact brushes 41 can slide on the connection section 37 a of the circuit carrier 37 . It is therefore not necessary to provide a bent or loosened section of the circuit carrier beforehand in order to lengthen or shorten it. There is also no need for a special space to accommodate such a section, in contrast to previous solutions in which the contact brushes are soldered to the circuit board.

The displaceability of the contact brushes 41 relative to the circuit carrier 37 is explained below with reference to FIGS. 5 to 7.

In Fig. 5, the receiving groove 38 has an elongated, U-shaped shape and is open at the top. The Anschlussab section 37 a of the circuit carrier 37 is held only with the flat 15 e and the connections 41 a.

As shown in Fig. 6, Ver recesses 38 a can be provided in the receiving groove 38 on opposite edges of their bottom to better prevent an elastic deformation of the terminals 41 a of the contact brushes 41 upwards.

Alternatively, it is also possible to provide a receiving groove 38 with a dovetail shape 38 b, as shown in FIG. 7, in order to prevent such deformation of the connections 41 a of the contact brushes 41 even more reliably.

The holding member 15 c, which is shown in Fig. 5, 6 and 7, has a left and a right guide hole 15 d, in which a right and a left guide protrusion 40 d of the brush holder 40 is inserted. Therefore, the sliding contacts 41 b can slide well on the code plate 36 without changing their relative position perpendicular to the sliding direction.

As Fig. 17 shows the guide ring 15 has two Füh approximately holes 15 on either side d of the holding member 15 c, so that can slide well th when inserting the guide projections 40 d of the contact brush holder 40 in the guide holes 15 d the sliding contacts 41 b relative to the code plate 36 without changing their relative position perpendicular to the sliding direction.

For a certain focal length, the position of the code plate 36 should remain unchanged relative to the contact brushes 41 . If the relative position of the contact brushes 41 and the guide ring 15 in the direction of the optical axis is different, for example due to a manufacturing error etc., the relative position of the guide ring 15 and the code plate 36 changes , which results in an error in the angular position of the cam ring 10 results.

To prevent this, the relative position of the contact brushes 41 and the code plate 36 in the direction of the optical axis must be adjusted and checked in accordance with a suitable position of the front lens barrel for the retracted position of the barrel, with the cam ring 10 in a predetermined angular position. For this purpose, a detection device for the position of the cam ring 10 is used , which is explained below with reference to FIGS. 11 and 12.

The shielding plates 25 and 26 are attached to the guide ring 15 with screws 44 ( Fig. 17) which sit in corresponding holes 25 b and 26 b of the shielding plates 25 and 26 and are screwed into threaded holes 43 of the guide ring 15 . The first shielding plate 25 has a viewing window 25 e to the left of the positioning cutout 25 a, and the second shielding plate 26 has a viewing window 26 e corresponding to the viewing window 25 e of the shielding plate 25 .

The shielding plates 25 and 26 are shaped so that they are larger than the back of the guide ring 15 and smaller than the contour of the cam ring 10 . The view window 25 e and 26 e face the back 10 e of the cam ring 10 and are elongated, wherein they extend in the circumferential direction of the back 10 e.

The cam ring 10 has on its rear side 10 e a mark 45 in the form of two dots (small circles) which appear in the viewing windows 25 e and 26 e only when the cam ring 10 is in a predetermined precise angular position.

If the guide ring 15 is correctly arranged in the camera housing, its positioning cutout 15 b is located at the top in the middle, as shown in FIGS. 11 and 12. In this state, for example during assembly, the contact brush adjusting device can be operated manually by turning the adjusting screw 31 in the bore 33 with a screwdriver which is inserted through the hole 26 c of the shielding plate 26 .

If the position of the cam ring 10 is checked in connection with the relative position of the contact brushes 41 and the code plate 36 , the camera body is placed with these parts in a test machine which contains a drive motor. This is operated according to the manual movement of the contact brushes 41 most relative to the code plate 36 described above. The motor in turn rotates the cam ring 10 over the conditions 10 d.

The cam ring 10 is moved during its rotation in the direction of the optical axis in accordance with the engagement of the threads 10 a ( 10 a ') and 12 a etc., whereby the relative position of the front lens group L1 and the rear lens group L2 and thus the focal length changes ver becomes. Since the mark 45 on the back 10 e of the cam ring 10 is visible through the viewing window 26 e when the sliding contacts 41 b of the contact brushes 41 are positioned exactly relative to the code plate 36 , the adjusting screw 31 can be turned clockwise or counterclockwise while that Viewing window 26 e is observed until the two points of mark 45 appear in viewing window 26 e, as shown in FIG. 12. This confirms the correct position of the cam ring 10 .

It is not always necessary to have the two points of the mark 45 completely in the viewing window in order to confirm the correct position of the cam ring 10 , as shown in FIG . If more than half of one of the two points (small circles) of mark 45 and the other point completely appears in the viewing window 26 e, as shown in FIGS. 13 and 14, the correct position of the cam ring 10 can be assumed.

The shape of the mark 45 and the viewing window 26 e ( 25 e) is not limited to the exemplary embodiment shown. Any other arrangement for visual confirmation or detection of the position of the cam ring 10 relative to the shielding plates 25 and 26 can be used here ver.

Since the signal transmission between the code plate and the flexible circuit carrier easy and safe without laborious soldering  can be obtained for the used Elements a simpler construction with less Manufacturing costs.

Because the contact brushes elastically deformable legs have that in elastic contact with the flexible Circuit carrier and the code plate are obtained easy and safe production of the signal easy to carry out without cumbersome soldering Connection process, which reduces manufacturing costs will.

Because the elastically deformable legs of the contact brushes are displaceable on the circuit carrier, this must not a bent or loosened section have the lengthening or shortening of the scarf carrier. So far this has been unavoidable. There is therefore no room to accommodate one loosened section required.

The relative position of the code plate and the contact brushing can be easily adjusted by turning the on set screw is turned. With this setting poss the form of the code plate and the contact brushing is not highly precise, and both must also cannot be positioned exactly. This also leads at a reduced manufacturing cost of the lens barrel.

Since the contact brushes on the contact brush holder be are consolidated and the inhibiting element on the stationary Part of the camera body is provided and the movement the free ends of the contact brushes towards the code plate limited, there is a largely constant Contact pressure of the sliding contacts, causing the signals for the focal length read with great accuracy that can.

Claims (20)

1. Tube for a zoom lens with a code plate and a contact brush arrangement, which comes optionally in contact with the code plate in order to capture the respective focal length of the zoom lens and to transmit focal length data via a flexible circuit carrier to a camera housing, the code plate or the contact brushes Order on a mounting element and the other part is attached to a linearly movable element relative to the mounting element, characterized in that the contact brush arrangement has one or more elastically deformable legs that are to be connected to the circuit carrier, while a sliding contact on the code plate is present that the stationary element or the linearly movable element to which the contact brush arrangement is attached has an insertion groove for the circuit carrier with which the elastically deformable legs or the contact brush arrangement can come into contact, and that the switching ungträger is seen with an insertion section, which is to be inserted between the insertion groove and the or the elastically deformable legs. 2. Tube according to claim 1, characterized in that the insertion section of the circuit carrier one Connection part and at least one in insertion tion extending, electrically conductive Er has lift.   3. Tube according to claim 1 or 2, characterized net that the linearly movable element is a front lens barrel, which is used to adjust the focal length Direction of the optical axis is moved. 4. Tube according to claim 3, characterized in that the front lens barrel on its inner circumference Insert slot into which to insert the code plate and which is parallel to the optical axis stretches. 5. Tube according to claim 4, characterized in that the code plate has a position at one end nierloch, and that the insertion groove on their the Aperture of the front lens tube facing end an insertion protrusion for the positioning hole Has. 6. Tube for a zoom lens with a code plate and a contact brush arrangement, which is optional comes into contact with the code plate, the ever capture the focal length of the zoom lens and focal length data via a flexible scarf transfer carrier to a camera housing, with the code plate or contact brushes on order on a stationary element and that because another part on one compared to the assembly element linearly movable element is attached, characterized by a contact brush holder, that on the stationary element or the linear movable element is held by a spring, which the contact brush holder from the stationary or the linearly movable element strikes, and by an adjusting screw that the Contact brush holder against the force of the spring  the stationary or the linearly movable Ele ment holds. 7. Tube according to claim 6, characterized in that the stationary element is a linear motion guide ring is the linear movement of a Front lens barrel parallel to the optical axis leads. 8. Tube according to claim 7, characterized in that the linear motion guide ring a holding part for the contact brush holder. 9. Tube according to claim 8, characterized in that the contact brush holder has a stop part, that is in contact with the holding part of the linear movement guide ring. 10. Tube according to claim 9, characterized in that the contact brush holder is held on the holding part is - and that the holding part is an opening for the Has adjusting screw. 11. Tube according to claim 10, characterized in that that the stop part has a threaded hole that faces the opening of the holding part. 12. Tube according to claim 11, characterized in that that the holding part near a spring insertion opening the opening for the adjusting screw, which one ver through the holding part up to the stop part running. 13. Tube according to claim 12, characterized by a Compression spring, which sits in the spring insert opening,  around the contact brush holder away from the holding part squeeze. 14. Tube according to claim 13, characterized in that that turning the adjusting screw causes a shift Exercise of the contact brush holder relative to the Code plate evokes. 15. Tube according to claim 14, characterized by a Shielding plate facing the direction of light arranged behind the linear motion guide ring is and is not rotatable relative to this. 16. Tube according to claim 15, characterized in that the shielding plate has a viewing window that the opening for the adjusting screw of the Linearbe faces guide ring, so that the Adjusting screw is accessible from the outside. 17. Tube for a zoom lens with a code plate and contact brushes with elastically deformable free ends, optionally in contact with the Code plate come to the respective focal length of the Capture zoom lenses, the code plate or the contact brushes on a stationary el ment and the other part against each other linearly movable element above the mounting element is fixed, characterized by a contact brush holder, and by an inhibiting element that the stationary or the linearly movable element is arranged closer than the contact brush holder, to limit the restoring force by which the free ends of the contact brushes towards the code plate are acted upon.   18. Tube according to claim 17, characterized in that that the stationary element is a linear motion Guide ring for movement in the direction of the optical axis. 19. Tube according to claim 18, characterized in that that the linear motion guide ring several Füh has at least one of them Has a groove for the contact brush holder, the width of which is essentially that of the Contact brush holder matches. 20. Tube according to claim 19, characterized in that that the inhibitor is a wall that the on in the middle section of the linear motion bridging guide surface.