DE19539062C2 - Device for reading and / or writing magnetic information on a photographic film - Google Patents

Description

The invention relates to a device for reading and / or writing magneti information on a photographic film according to the generic term of Claim 1. Such a device is such. B. known from EP 589270 A1.

Photographic films with a magneti have been known for a long time sizable layer are provided. On this magnetic layer from Film manufacturer, from the recording camera and / or in the course of the following photographic film processing magnetically encoded information on the film are saved, the exchange of information between the filmmaker the photographer, the film processor or the respective used Devices.

EP 437 536 B1 shows such a film. The magnetic layer of the film is divided into different tracks, each with a specific data category are assigned. For example, it is provided in tracks C0 to C3 Record information in a camera. It is also planned in the Tracks F00 to F29 data from film processing equipment such as film processor devices and photographic copiers.

The exchange of information about the magnetic layer of the film is against the advantage of unmagnetized films that additional information such. B.  about the location or the day of the recording, image-wise saved on the film can be saved and available to the users of the film at any time stand. Another advantage in particular of the traces provided by the camera and the film processing device is that processing-relevant informa tion such as B. the information about a flash, magnetic ge can be saved and when processing the film for control of device parameters, e.g. B. a photographic copier who used that can. This allows settings of the film processing devices, for. B. the light intensity when copying the film templates, precisely depending on the image be made and thus the quality of photo prints significantly improved will.

EP 589 270 A1 shows a device with which magnetic tracks of the above-mentioned. Art can be read or written. In the device shown there two film guide elements clamp the film due to a spring force and guide him through it. The disadvantage here is that threading the beginning of a film is difficult because the film guide elements contract.

DE 41 20 033 A1 shows a cassette for film material in which a winding core has a surface with a high coefficient of friction so that the film material rial can be reliably wound up or unwound. US 3,771,705 shows one Feeder for roll paper goods.

It is an object of the invention to provide a device for reading and / or writing magnetic information on photographic film of the above Kind of creating that threading the beginning of the film as safely and easily as possible.

These tasks are solved by the characteristic features of the Vor Direction according to claim 1.

Advantageous embodiments of the invention are the subject of the dependent Expectations.  

According to the invention, film guides are provided in the magnetic reading or writing unit elements are provided that are at most in relation to the film transport direction stand at an angle of 60 °. A film guide element projects into Trans port direction of the film with a protrusion to below a lateral surface of the Magnetic head.  

For safe guiding within the magnetic head are advantageously over lapping areas provided so that a film start is not in the Vorrich can get caught.

Exemplary embodiments of the invention are described below hand of figures are explained in more detail.

Show it:

Fig. 1 shows a device for reading and writing magnetically stored signals,

FIG. 2 shows a second view of the device from FIG. 1, FIG.

Fig. 3 is a fragmentary view of the device according to Fig. 1,

Fig. 4 shows a section along the line II of Fig. 2,

Fig. 5 shows a further view of the device according to Fig. 1,

Fig. 6 shows a further view of the device according to Fig. 1,

Fig. 7 shows a further view of the device according to Fig. 1,

Fig. 8 shows a magnetic head with a shield plate,

Fig. 9 shows a section along the direction A of Fig. 1,

Fig. 10 is a photographic film processing system, and

Fig. 11 is a film running plate.

Fig. 1 shows a magnetic read-write unit 1 with the photographic film, on which at least one magnetic track is, for reading and / or writing can be scanned.

The magnetic reading unit 1 comprises a base body 2 made of metal or conductive plastic. It further comprises a film guide plate 9 and a fastening element 34 for a swing arm 14 . A mounting flange 7 with a fastening supply pin 8 is firmly connected to the base body 2 . The magnetic reading and writing unit 1 can thus be attached to any other device. This device can e.g. B. A photographic copier 60 shown in FIG. 10 or any other photographic processing device. In particular, the magnetic reading and writing unit can be integrated within an optoelectronic scanning unit or in a film running plate within the copying beam path of a photographic copier.

The magnetic head 3 is movably mounted within the base body 2 . For this purpose, it is mounted on the rocker 14 via a bearing 16 . The rocker 14 can turn on the base body 2 about the bearing axis 15 .

The magnetic head 3 is attached to the rocker 14 via a mounting plate 17 . Between the mounting plate 17 and the magnetic head 3 there is also a shielding plate 4 made of a material with high permeability for shielding the magnetic head 3 from external magnetic fields. The inner region of the magnetic reading or writing unit 1 is also shielded from external magnetic fields by an upper housing cover 5 and a lower housing cover 6 . Housing cover 5 and 6 are also made of a material high per meability, z. B. My metal from a FeNi compound or a Permalloy alloy tion. The relative permeability and thus the magnetic susceptibility of the magnetic shielding material is greater than 10⁴. In order to achieve adequate shielding, the wall thickness of the shield is greater than 0.5 mm. The following applies to the geometry of the shielding devices:

where d is the minimum extent of a gap between two shielding parts and s is the distance of the gap to the closest reading gap 43 or 44 of the magnetic head 3 (see FIGS . 4 and 8).

The minimum distance s of the housing parts 5 and 6 from the magnetic head 3 is 5 mm. In the present exemplary embodiment, it is approximately 10 mm.

The lower housing cover 5 and the upper housing cover 6 overlap in regions 25 . This shields external magnetic fields even better because they cannot penetrate the labyrinth between the two housing covers.

Within the shielded area is largely ferromagnetic Components dispensed with, so that magnetic fields caused by gaps in the shielding penetrate the magnetic reading or writing unit, are practically not bundled can.

Furthermore, there is electrical insulation of the magnetic head 3 from the base body 2 in the magnetic reading or writing unit 1 . For this purpose, the rocker 4 is not conductive, at least on its surface. In the embodiment of Fig. 1, the rocker 14 is made entirely of plastic, but it can also consist of anodized aluminum or metal, which is coated with a non-conductive layer (z. B. plastic or anodized). The electrical insulation of the magnetic head can, however, just as well take place on other parts. This electrical isolation of the magnetic head 3 from other electrically conductive devices prevents that electrical charges resulting from friction between the film and the guides are not dissipated via the head ground. For this reason, this isolation is carried out against all film guide components if possible.

A film to be scanned is normally transported in the direction A by the magnetic reading or writing unit 1 . The magnetic reading and writing unit 1 is designed so that the film can also be transported in the opposite direction. The magnetic head 3 is arranged with respect to the second rocker bearing 16 centered on the rocker 14 , so that regardless of the film transport direction, no torque acts on the lateral film edge on which the film guide elements in the area of the magnetic head attack the film.

An upper skid 11 and a lower skid 10 are used to guide the film within the magnetic reading and writing unit 1 perpendicular to the transport direction A. The sliding surfaces of the skids 10 , 11 are at a relatively shallow angle less than 45 ° to the main film running direction A. This ensures that the film threading, ie the insertion of a film start into the magnetic reading and writing unit can be done safely.

In Fig. 2 the magnetic reading and writing unit 1 can be seen in a representation from the film outlet direction. A lower skid 12 and an upper skid 13 guide a film to be scanned on the side of the magnetic head 3rd On the opposite side of the magnetic reading and writing device 1 with respect to the magnetic head 3 and film running direction A, there is an upper skid 28 and a lower skid 27 . In contrast to the skids 10 , 11 and 12 , 13 he stretched the skids 27 , 28 along the direction A through the entire magnetic reading and writing unit 1 , so that a film between these skids 27 , 28 is guided without interruption.

Fig. 3 is a fragmentary view showing the magnetic read and write unit 1. The magnetic head 3 is connected via a flexible electrical data line 33 to an electrical evaluation circuit (not shown in more detail). The energization of the magnetic head 3 can, for. B. according to the teaching of DE 195 13 302, the evaluation of read signals according to DE 195 13 260. The magnetic head 3 is mounted on the mounting plate 17 on a bearing axis 18 on the second Schwingungsla ger 16 of the rocker 14 . In addition to the magnetic head 3, the mounting plate carries a bearing block 32 . The bearing block 32 has two elongated holes 21 in which an axis 20 is slidably mounted transversely to the direction A along a direction C. Instead of the slots 21 can of course another guide, for. B. a linear guide along one or more rods for the axis 20 may be provided. The axis 20 is pressed by pressure springs 22 in the direction C to the magnetic head 3 . A pressure roller 19 is rotatably mounted on the bearing axis 20 via a slide bearing 23 . The pressure springs 22 press the bearing axis 20 and pressure roller 19 with a force of approx. 1 N against the magnetic head 3 . Base body 2 or the film guide plate 9 and the lower housing cover 6 each have a recess 24 through which the pressure roller 19 is freely accessible from the outside. The difference in pressure forces from the springs may not exceed 5%.

At least the surface of the pressure roller 19 consists of a thermoplastic elastomer material. It is characterized by low sliding friction, is elastic and relatively abrasion-resistant in comparison to rubber. This is particularly advantageous when inserting film starting pieces into the magnetic reading or writing unit, because the roller 19 does not turn when the film is first captured. The film then glides smoothly over the roll at this stage.

A skid 26 is fixedly mounted on the bearing block 32 . It has a surface 35 which is parallel and in particular flat to a surface 36 of the film guide plate 9 . The skid 26 is displaceable within the plane defined by the surfaces 35 and 36 approximately in and against the direction B. It precisely follows the movement of the magnetic head 3 and the mounting plate 17 about the two axes of rotation of the bearings 15 and 16 . The skid 26 is located almost centrally between the skids 10 , 11 and 27 , 28 at a certain distance from the magnetic head 3 .

Magnetic head 3 , shielding plate 4 , mounting plate 17 , bearing block 32 , bearing axis 18 , pressure roller 19 , springs 22 , bearing 23 and skid 26 thus form a complex displacement unit which is within the magnetic reading or writing head 1 about the two axes of the rocker bearing 15 and 16 are slidable. This displacement unit is pressed in the direction B by a pressure spring 29 which engages on the one hand on the base body 2 and on the other hand on the rocker 4 . The sliding roller 31 is mounted on an axis 30 . A roller 31 is provided as a counter bearing and is mounted on an axle 30 . The film is pressed against these by the sliders 40 of the magnetic head 3 . It prevents the film from cutting into the relatively soft material of the guides. Instead of the steel sliding roller 31 , another suitable sliding body made of hard material such as ceramic could also be used.

FIG. 4 shows the magnetic reading or writing device 1 along the section line II of FIG. 2.

The magnetic shielding plate 4 is excluded in this section in the area of the bearing axis 20 . As can not be seen in this section, but is shown in Fig. 8, the magnetic shielding plate 4 extends in front of or behind the roller axis 20 with comb-like projections 42 up to close to the lower housing part 6 , the upper part also here mentioned condition

applies. This results in an even better shielding of the magnetic head 3 , in particular the reading gap 44 , from magnetic interference fields also in the region of the axis 20 . An air gap 37 is maintained between the magnetic head 3 and the shielding plate 4 .

The film guide elements 10 , 11 and 27 , 28 can be seen in the view of the magnetic reading or writing device 1 shown in FIG. 5. The guide surface 10 is so wide in the direction of the rocker 14 that a film can still be threaded even when the rocker 14 abuts its - in this illustration - left stop. This makes film threading much easier. The film guide surface 10 widened in the region 38 is then aligned approximately with the lateral film guide surface 40 of the magnetic reading or writing device 1 shown in FIG. 8.

In Fig. 6, the magnetic reading or writing unit 1 is shown in a view which is opposite to the main film direction A. The film guide surfaces 12 , 13 and 27 , 28 are - just like the corresponding film guide surfaces 10 , 11 and 27 , 28 of FIG. 5 - beveled with respect to the plane 39 in which a film runs through the magnetic reading and writing unit. In contrast to the surfaces 10 , 11 and 27 , 28 of the film inlet side shown in FIG. 5, the surfaces 12 , 13 and 27 , 28 of FIG. 6 are inclined at a steeper, ie larger angle, to the film running plane 39 . The film running properties, ie the stability of the film within the magnetic reading and writing unit 1 is thereby ensured to a high degree.

FIG. 7 shows the magnetic reading and writing unit from below, ie with a view perpendicular to the lower housing cover 6 . Through the openings 24 , the surface of the roller 19 is freely accessible from the outside. This enables a simple cleaning of the roller 19 from the outside without having to disassemble the housing parts.

Fig. 8 shows the magnetic head 3 and the attached magnetic shield plate 4 exists. Its core 98 , like the housing parts 5 , 6, is made of highly permeable material and comprises both a part fastened to the magnetic head 3 and a part of the head mirror 96 of the magnetic head 3 which is somewhat thinner but fully shielding part 120 and two comb-like feet 42 , which are directed away from the head mirror 96 . The part 120 protrudes perpendicular to the surface of the head mirror 96 at least 1 mm and about 5 mm beyond this, so that it is aligned with the guide elements 40 , 41 in this direction. The feet 42 extend to a distance of at least 5 mm, here exactly 8 mm from the surface of the head mirror 96 . Through the gap 99 protrudes in the installed state of the magnetic head 3, the roller axis 20 of the roller 19 within the reader or writer 1 , see. FIGS. 3 and 4. mating openings 118, 119 enable a precise alignment of the plate 4 and the magnetic head 3 inside the reading or writing unit 1 by dowel pins are inserted through the fitting holes exactly in corresponding recesses of the basic body 2.

The magnetic head 3 is mounted on the shielding plate 4 in a fixed assignment, so that there is always a defined distance between guide surfaces 41 of the magnetic shielding plate 4 and the magnetic head openings 43 , 44 . The lateral film guide surfaces 41 are preferably made of very hard but low-friction material, e.g. B. polished steel or a ceramic material. Magnetic information on the record carrier is read or written through the columns 43 , 44 in the head mirror 96 . On the ceramic edge guide 40 , 41 several functional surfaces are attached. The side surfaces 40 , which are chamfered relative to the film guide surfaces 41 , are used for threading the film. They prevent a film from jamming in the area of the magnetic head inside the magnetic reading or writing unit 1 .

During the read or write operation are due to the pressing force of the pressure spring 29 , which is transmitted from the rocker 4 , the lateral film guide surfaces 41 of the shielding plate 4 on the side edges of the film. Due to the spring pressure, the lateral film guide surfaces follow every movement of the lateral film edges. The arrangement overall ensures that the magnetic head columns 43 and 44 always come to lie at a predetermined distance from the lateral film edges. This makes it possible to read or write information stored or to be written on the film in the correct direction.

FIG. 9 shows a schematic illustration of essential components provided for the film guidance within the magnetic reading or writing unit 1 . The film 45 is transported in the direction A through the magnetic reading or writing unit 1 . The inclined surfaces of the sliding skids 10 , 11 lying on the input side 54 have a relatively small angle α and at most 60 ° with respect to the film inlet direction. It is preferably about 40 °. In contrast, the inclined surfaces of the skids 12 , 13 on the output side 55 of the device 1 Vorrich a relatively steep angle β of about 50 °. It can be up to 80 °. Within the magnetic reading or writing device, the film 45 is guided on an arc segment 53 around the magnetic head 3 . The film 45 is preferably under a certain tension, so that it largely spans the read / write head surface 56 and a front inclined surface 50 and a rear inclined surface 51 of the magnetic head 3 . The circular arc segment 53 extends over an angle of approximately 22 °, ie it is significantly larger than 11 °. It has been found that a head wrap of more than 11 ° is necessary in order to enable a safe read or write operation. At the turning points 57, the film 45 leaves the predetermined circle segment curve 53 within the magnetic reading or writing device 1 . With regard to the plane predetermined by the geometries of the skids 10 , 11 and 12 , 13 , in which the film 45 runs on the input side 54 and the output side 55 of the magnetic head 3 , the film becomes inside the magnetic reading or writing device along the curvature curve 53 offset by approximately four film thicknesses perpendicular to the plane. Accordingly, the magnetic head 3 projects downward beyond the surface 47 of the skid 11 . This prevents the film from curving within the plane, ie along its transverse axis.

The threading of the film 45 is optimized in that the skid 10 has a pre-given surface profile. It is initially flat in the film inlet area 45 (surface 10 ), then changes into a curved profile and becomes linear again in the area of the turning point 57 . The profile of the runner 10 is designed so that the film 45 strikes the roller 19 at a relatively flat angle of approximately 45 °. When threading, the roll is only swept from the film in its upper segment, ie in an angular range of a maximum of 30 °, preferably only 15 °. In the area of the magnetic head 3, the surface 35 of the sliding skid 26 also acts as a winding aid. It leads the film start 97 from the surface 46 along the sheet 53 to the film roll 19 and thereby prevents the front edge of a film 45 from entering during the winding between the skid 10 and the roll 19 and getting caught there.

As a further measure for trouble-free film guidance within the reading or writing device 1 , the inner surface of the slide skid 10 , ie close to the magnetic head, is used directly, ie only a few film thicknesses, on the surface of the roller 19 . The same applies to the inner surface of the skid 12 . On the side near the magnetic head, the surface of the skid 11 near the magnetic head is also drawn down to below its side wall 52 , ie in the region of the lateral inclined surface 50 of the magnetic head. The surface 47 protrudes there beyond the side surface 52 , so that the film can not get caught in the gap 58 between the skid 11 and the side surface 52 of the magnetic head 3 . The same applies to the surface 49 of the skid 13 . It also protrudes below the inclined surface 51 of the magnetic head 3 , so that there too the film is prevented from getting caught in the gap 59 between the skid 13 and the magnetic head 3 .

In Fig. 10 components for processing photographic films are Darge presents. In a photographic copier 60 there is a tape 61 which contains a plurality of photographic films stuck together. They are wound onto a take-up reel 63 by an unwinding reel 62 , passing through a scanning station 77 and a copying station 64 . In the scanning station 77 , the films are scanned electro-optically frame by frame and the image signals determined in this way are transmitted to an exposure computer 78 . There copying light quantities calculation net, which by means of a filter based drive 71 color filter 70 (yellow, cyan, magenta) will be swiveled in front of a light source 69th In the copying station 64 , the images of the films are each copied onto photographic negative paper 65 . This light-sensitive material is transported from a unwinding roller 66 via a first paper loop 68 to the copying station 64 and is wound onto a take-up roller 67 via a second loop 68 . A zoom lens 73 generates the image scale when copying, depending on the type of copy. More information on Ko pier light control in other procedures within such a Ko pier device can be found, for. B. in European patent application 128 348 B1. The magnetic reading device described in FIGS . 1 to 9 is particularly suitable for being integrated in the mentioned measuring station 77 of the copying machine. In addition to the light source already provided in the prior art for illuminating the lens and electro-optical sensors such as charged coupled devices (CCD), this has a high-precision film drive 76 . This can now also be used for a magnetic reading device according to FIGS . 1 to 9 if it is integrated into the measuring station 77 .

The copying machine 60 also has a drive 79 for transporting the films 61 to the copying station. Between the measuring station 77 and the drive 79 is a film loop 75th This decouples the movements of the drives 76 and 79 .

The magnetic reading or writing device 1 can transmit the data read from the film to the exposure computer 78 , which uses this data for exposure control. In particular, it is e.g. B. advantageous to further process data on the film via flash photography in the exposure computer.

In the copying machine 60 of the present embodiment is inside the copying beam path 64, for example with a beam splitter. B. a plane-parallel plate or a prism, the image located in the copying station mirrored and fed to a CCD camera 74 . This forwards the generated electronic signals via a data line 89 to an electronic image composer 82 . The image composer 82 generates a common image provided with additional information from a multiplicity of images and forwards this via line 94 to an image processing stage 83 , which processes the image signals for an electronic image output device 84 . They are passed on via line 95 to a cathode ray tube 85 of the imagesetter 84 . The cathode ray tube 85 exposes photographic color negative material 86 which is rewound from an unwinding reel 87 to a take-up reel 88 . The overall sequence of the photographic process is controlled by a monitoring computer 81 which monitors a paper processor 80 via line 91 , the copier 60 via line 92 and the image composer 82 via line 93 .

The copier 60 is also connected via a line 90 to the image composer, whereby data which the reader 1 has read can also be supplied to the image composer 82 . This makes it possible to assign image-specific magnetic data via the composer to the corresponding optical images and to output them together in spatial or logical, other assignment via the device 84 .

Fig. 11 shows a magnetic reading device 1 , which is built into a film running plate 10 °. The film running plate 100 is part of a scanning station 77 within a copying machine 60 of FIG. 10. It can be inserted into or removed from the measuring station 77 of the copying machine 60 by means of a handle 114 . The film 45 is guided laterally along two film guide edges 101 and 102 . From a floor level 103 of the film running plate 100 , a lower film running rail 104 is raised, on which the film 45 is transported. In the area of the magnetic reading device 1 , these film tracks 104 each have an inclined inlet surface 105 , which facilitate the threading of a film beginning in the Magnetlesevor direction 1 . The reading device 1 is inserted in recesses 115 of the film platen 100 . The flange 7 of the reading device 1 also engages in a cutout, furthermore the fastening pin 8 .

The magnetic reading device 1 is located directly next to a housing 106 in which a preamplifier for the magnetic head 3 of the reading device 1 is located. This ensures largely interference-free transmission of the signals even when the magnetic read head 3 has low signal strengths.

Regarding the film running direction A in front of the magnetic reading device 1 , there is a reading unit 117 for reading optical codes on the film 45 , e.g. B. for reading a DX code. The film can be illuminated here through recesses 116 in the film drive plate 100 . In the field of magnetic reading apparatus 1, a pivotable cover 108 is provided, the 1 and 103 protects the reading devices against dust and side light. It is pivotable about an axis 109 . The cover 108 also has film guide and film pressure elements 107 which, in the closed state of the cover, ensure an optimal film pressure perpendicular to the main film transport direction A.

From the film transport direction A as seen after the magnetic reading unit 1, there are recesses 111 and 112 in the film running plate 100 , through which film or image-specific information can also be read via lighting devices. The recess 111 serves z. B. the spectral analysis of images, the recess 112 is used to detect sharpness and / or brightness of images. In this area there is also a pivotable cover 110 to protect the film running surfaces 104 , 105 from dust. The film running plate 100 also has a recess 113 through which a film drive permanently installed in a copier 60 can intervene to transport the film through the measuring device 77 . In this area, the film 45 is driven in a highly precise manner in order to be moved at a constant speed in the areas 111 , 112 and in the magnetic reading station 1 and on the DX code reader 117 .

The present invention has been explained on the basis of a few exemplary embodiments. It is clear that various modifications of the invention are possible within the scope of the skilled person. For example, instead of in the measuring device 77 of a copying machine, a magnetic reading or writing head can also be integrated in the area of the copying station 64 , ie, for example, in a film drive plate located there with a copying window. It can be provided to use common film guide elements for the film running plate and for the magnetic reading or writing unit or to use the film guiding elements of the reading or writing device for threading a film into the film running plate.

Claims (20)

1. Device for reading and / or writing magnetically coded information on a photo film coated with a magnetic layer ( 45 ) with a magnetic head ( 3 ), with respect to a film transport direction (A) in front of the magnetic head ( 3 ) at least one film guide element ( 10 , 11 , 27 , 28 ) which leads the film ( 45 ) to the magnetic head ( 3 ), characterized in that an entry surface of the film guide element ( 10 , 11 ), along which the film ( 45 ) into the read / write device ( 1 ) is threaded, with respect to the film transport direction (A) at most at an angle (α) of 60 ° and that a film guide element ( 10 , 11 ) in the transport direction (A) with a projection ( 46 , 47 ) to below a lateral surface ( 52 ) of the magnetic head ( 3 ) protrudes. 2. Device according to claim 1, characterized by pressure means ( 19 , 22 ) for pressing the film ( 45 ) onto the magnetic head ( 3 ), which comprise a roller ( 19 ), the magnetic head ( 3 ) and the roller ( 19 ) a common bracket ( 14 , 17 ) are held. 3. Apparatus according to claim 1 or 2, characterized in that the film guide element ( 10 , 11 ) has at least one curved surface. 4. Device according to one of the preceding claims, characterized in that the film guide element ( 10 , 11 ) has two straight and a curved surface area. 5. The device according to claim 4, characterized in that a straight region ( 46 ) of the film guide element ( 10 , 11 ) protrudes below a second film guide plane ( 35 ) of a second film guide element ( 26 ). 6. The device according to claim 5, characterized in that the magnetic head ( 3 ) protrudes beyond the film guide surface ( 47 ) such that a threaded film ( 45 ) from the plane in which it enters the device ( 1 ) and / or leaks out of it, is deflected by about four film thicknesses. 7. Device according to one of the preceding claims, characterized in that the film ( 45 ) wraps around the magnetic head ( 3 ) with a circular segment ( 53 ) of at least 12 °. 8. The device according to claim 7, characterized in that the film ( 45 ) wraps around the magnetic head ( 3 ) at 22 °. 9. Device according to one of the preceding claims, characterized in that a guide roller ( 31 ) or a sliding body made of hard material such as ceramic is mounted for guiding a lateral film surface in a direction (B) perpendicular to the film transport direction ( 4 ) relative to the magnetic head. 10. The device according to claim 2, characterized in that the common bracket ( 14 , 17 ) comprises a rocker ( 14 ). 11. The device according to claim 10, characterized in that the roller ( 19 ) and the magnetic head ( 3 ) via a plate ( 17 ) on the Schwin ge ( 14 ) are held. 12. The apparatus of claim 10 or 11, characterized in that the rocker ( 14 ) is mounted on a base body ( 2 ). 13. Device according to one of claims 10 to 12, characterized in that the roller ( 19 ) has a surface made of a thermoplastic elastomer. 14. Device according to one of claims 10 to 13, characterized in that second pressing means ( 29 ) are provided which act in wesent union transversely to the pressing direction of the first pressing means ( 19 , 22 ) on the film ( 45 ). 15. The apparatus according to claim 14, characterized in that the second pressure means ( 29 ) comprise a spring which acts on the rocker ( 14 ). 16. The apparatus of claim 14 or 15, characterized in that a movable roller ( 31 ) is provided against which the film ( 45 ) presses due to the second pressure means ( 29 ). 17. The device according to one of claims 14 to 16, characterized in that the second pressure means ( 29 ) with the first pressure means ( 19 , 22 ) are fixedly connected. 18. The apparatus according to claim 10, characterized in that the first pressure means ( 19 , 22 ) means ( 21 ) in particular have elongated holes, which cause the roller ( 19 ) in a certain direction (B) perpendicular to the magnetic head ( 3 ) is. 19. The apparatus according to claim 13 or 14, characterized in that the roller ( 19 ) via an axis ( 20 ) and a spring ( 22 ) is mounted. 20. Device according to one of claims 10 to 19, characterized in that the axis ( 20 ) via two with respect to the roller ( 19 ) symmetrically on the axis ( 20 ) engaging springs ( 22 ) is sprung.