CS496990A2 - Band device for tape drive - Google Patents

Description

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BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a tape drive apparatus comprising a clamp assembly for clamping a tape recorder against a drive shaft in which the clamp roller is rotatably mounted on a carrier so as to be rotatable and tilted by two together bearing bearing portions, one of which is a spherical ball, the other being a spherical bushing partially enclosing the ball, the two bearing portions being disposed axially with respect to the axis of the nip roller in an axially oriented depth in said roller and one the two bearing parts are rigidly connected in the recess to the clamping pulley and the other of the two bearing parts is rigidly attached to the support pin.

The invention further relates to a clamp assembly for use in a tape device. Such a clamp assembly as is known from German E-QS .29. $ 65 ,. it serves to ensure that the clamping pulley mounted so as to be freely rotatable can engage along the periphery fully into the drive shaft or tape carrier which is to be driven by this shaft relative to its additional tilting fit, and can co-operate with the drive shaft or s. the tape recorder also in the case of inclination relative to the axis of the clamping pulley. As is known, such a uniform engagement of the clamping pulley with the drive shaft or tape record carrier is of particular importance for the perfectly even movement of the tape recorder. In the aforementioned known assembly of the clamping roller, it is ensured that the ball forming one of the two bearing parts of the housing is rigidly connected to the support pin and the ball housing forming one of the two bearing parts is fixedly connected inside the depression in the clamping roller to said roller so that the ball the sleeve monitors the rotation of the clamp while the ball is stationary.

SUMMARY OF THE INVENTION The subject of the invention is a tape device of the aforementioned type, characterized in that the ball forming one of the two bearing parts is firmly connected in the recess of the clamping roller and the ball housing forming the other of the two bearing parts is fixedly connected via the support pin to the carrier. This further improves the operation of the tape device and the clamp assembly of the aforementioned type, so that when the clamping pulley engages the drive shaft or the recording tape carrier and monitors its rotation, the same uniform engagement of the pulley with the drive shaft or the belt carrier also during the rotation of the clamping roller. Due to the arrangement according to the invention, the ball monitors the rotation of the clamping roller while the ball housing is stationary.

The present invention is based on the recognition that the rotatable mounting of the rotatable portion with respect to the stationary portion is more accurate when the rotatable portion can be produced precisely by another stationary portion that interacts with it. In this case, the ball forming one of the two bearing parts can be made substantially more accurately with respect to the surface shape of the non-spherical housing forming the other of the two bearing parts.

This is the reason why, according to the invention, the ball is chosen as a rotatable bearing part and is consequently fixedly connected in the depression in the clamping roller to said pulley, while the ball sleeve is selected as a stationary bearing part and is therefore rigidly connected via the support pin to carrier.

Therefore, in the assembly of the clamping roller constructed in accordance with the invention, a precisely opposite type of solution is chosen with respect to the assembly of the clamping roller known from the German document CE-CS 29 965. However, it should be noted that this is not a mere use of However, the additional effect which is achieved by the fact that the one of the two bearing parts is selected as rotating which can be made more accurately also plays a role. As a result, the travel of the rotating part is minimized. When the clamping hammer in the drive shaft or in the tape recorder tracks its rotation, a particularly precise operation is achieved and thus a perfectly uniform movement of the record carrier is achieved.

It has proved to be advantageous if the cone forming one of the two bearing parts is asymmetrically surrounded by the ball bushing forming the second of the two bearing parts with respect to the axis of the clamping stick, while when the clamping roller engages the shaft, the opening of the ball housing is inclined towards the drive shaft. In this way, a particularly favorable transmission of force from the carrier is obtained, the clamping bar being pressed against the drive shaft with the tape recorder. because the spherical sleeve partially surrounds the ball in the transmission of force along a larger portion of the circumference than would be the case if the spherical sleeve surrounded the ball symmetrically with respect to the axis of the gripper.

BRIEF DESCRIPTION OF THE DRAWINGS The invention is explained in more detail below with reference to the accompanying drawings, not limiting the scope thereof.

FIG. 1 shows schematically in a reduced scale view of a recording and reproducing apparatus for television signals and audio signals into which a cassette comprising a magnetizable record carrier in the form of a tape located between two adjacent cartridges and television signals of a screw-type can be recorded. These tracks are reproduced from this record carrier with the help of rotatably driven longitudinal magnetic heads. FIG. 2 shows a schematic part of the device of FIG. 1 in a larger scale in FIG. 1, wherein a cassette has been inserted into the device and the record carrier has been pulled out of the cassette and guided around the tracking elements in the device. Cbr. 3 shows a cross-sectional view of a clamping cylinder of a nip roller assembly.

FIG. i illustrates a tape device in the form of a recording and reproducing apparatus which is designed to record and reproduce television signals and audio signals on a magnetizable record carrier in tape form, referred to as a magnetic strip for shortening below. The magnetic strip is housed in a cassette 2 which is schematically illustrated in FIG. 1 and comprises two adjacent cartridges, between which a magnetic strip is guided along a path determined by the tape guide to the cassette. The cassette 2 can be inserted into the manual device 1 by means of a slot 5 through an opening 4, which can be closed by means of an inwardly displaced cover 3. When the cassette 2 is inserted into the device 2, it is moved into the displaced cassette holder by which the cassette is thereafter, when fully inserted into the device, it is lowered in the device substantially perpendicular to the main wall of the cassette to a working position shown schematically in Fig. 2. Switching of operating modes of the device, such as "recording", "replay, normal forward", "rapid shift" The device 2 has two display units 8 and 9, the display elements of which are each formed of, for example, seven segments and serve, for example, to display values. by the computer to measure the tape used and to indicate the time of day.

As already mentioned, the cassette 2 inserted into the device 2 is lowered into the working position. As shown schematically in FIG. 2, two adjacent rotatably driven hubs 22 and 12 are disposed in the cartridge 2 and are magnetically driven.

the tape 22 in the cassette along a path partially indicated by the dotted line23, and on which the magnetic tape can be wound alternately in opposing directions 21 and 21 of winding in accordance with its direction of travel in a particular case. When the cassette 3 is lowered into working position, the two winding spindles 22 and 26 enter the drive connection with the hubs 22 and 22, respectively, and the non-dead spindles are rotatably supported by the bearing plate 22 of the device. ® 22 mounted in a coaxial direction of the corresponding spindle. Of course, the winding spindles may be different in design to that shown and may have, for example, a centrally disposed storage spindle for positioning the hub and the drive spindle mounted eccentrically in the hub to drive the hub. The drive mechanism 22 (which is only shown schematically in FIG. 2) is designed to drive the two winding spindles 22 &apos; 22 in mutually opposite rotational directions 22, 22, said drive mechanism having a motor-driven wheel 20 mounted fixed devices. the drive wheel 22, which may be driven by said drive wheel, is held so as to be slidable parallel to the bearing plate 3 may be circumferentially coupled to the drive coupling as described in more detail below, alternatively with one of the two spindle winders the wheels 22 and 22 mounted coaxially with the winding spindles 22 and 22 attached thereto in terms of rotation and mounted in the same axial plane.

When the cassette 2 is lowered into its working position, the cassette closure cover (not shown) formed in its front 24 opens and releases such an opening of the cassette in its front side 24. With this opening, the magnetic strip 22 stored in the cassette can be guided out of the cassette. and the four guides 25, 26, 22 and the tape and clamp shown in phantom in FIG. 2 in their rest position, enter the three recesses 30, 35 and 32 of the cassette 2 and engage the magnetic band in the region of the dotted line line ± 5. Once the cassette has been lowered, its guides 25, 26, and 42 can each be moved to their working positions, shown in solid lines in the figure, wherein the clamping roller 29 is also slidable to an intermediate position not shown in FIG. in the immediate vicinity of the drive roller 33. During this operation, the magnetic strip 52 is guided out of the cartridge by a hole in the front side 74 of the cartridge. From the above intermediate positions, the clamping roller 29 can be moved by its working position, shown by the solid line in FIG. 2, in which the magnetic strap 5.2 is pressed against the drive roller 33. Since the mechanisms for opening the cassette closure cover, for moving the guide and the clamping roll and for pressing the clamping rollers the tension rollers are not essential to the invention, they are not shown for simplicity. Such mechanisms are known from existing devices of this type.

After the tape guides 25, 26, 27 and 78 have been moved and the pulley 39 is clamped into their working positions, the magnetic strip 5.2 occupies the path shown in FIG. 7 with a solid line. In this arrangement, the magnetic tape from the hub 50 extends through the two tape guides 34 and 35 contained in the cartridge, the tape tension sensing pin 36, which is part of the tape tension control mechanism (not shown), the tape sliders 25, 27 and 26, the fixed magnetic head 37 for erasing all signals recorded on the magnetic tape 12 by a drum-like tracking unit 38 that includes rotatably driven magnetic heads for recording and reproducing television signals adjacent to the video tracks or from these tracks oriented obliquely to the longitudinal direction of the magnetic tape, a fixed tape guide 39, a fixed magnetic head 40 for erasing the audio signals previously recorded in the audio track running in the longitudinal direction of the magnetic tape 12, and the fixed magnetic head 4 for recording and reproducing the audio signals to the audio track and for recording and reproducing the sync signals to the control track of this track, running in the longitudinal direction of the magnetic strip and parallel to the head of the track, the drive track 33 against which the magnetic strip is pressed by the clamping roller 29, the sliding guide 28 of the tape and the fixed guide 42 of the tape and two other guides 43 and 44 tape contained in cartridge 2, on hub 11.

The drive pulley 33, which is typically attached to the disk-shaped flywheel 45, can be driven alternately in one or the other of both directions of rotation at constant speed. In this way, the magnetic strip 22 can be driven alternately in one of the two mutually opposite directions of movement of the constant movement speed when pressing the clamping roller 29 against the drive roller 33. When the drive roller 33 is driven in a predetermined anti-clockwise direction in accordance with FIG. 2, the magnetic tape is driven in a direction 4ύ which corresponds to a so-called normal forward shift, driven in the direction 22n if the drive is a pulley but it is the master of the readings, the magnetic direction is at 4 a and also corresponding to the ecoding mode "playback is done recording the signals in the working mode" record "and also normal playback in the working mode" playback, normal forward shift "and in which, for For example, for the purpose of winding the magnetic strip 12 on the hub 21 / 3e, the drive spindle wheel 23 connected to the winding spindle 22 (driven by the same drive 21) and driven in the same predetermined manner by the drive mechanism 21 and 33 is driven in a clockwise bandwidth 21 <Í 2. 2. Π 4 <<'' '-' '' '' '' '' '' '' ' transverse operation, in which, at prs-, normal reverse, the television signals are played back in reverse and when, for the purpose of winding the magnetic tape 21 on. hub 22, the winding spindle wheel 1 is fixedly fixed from the viewpoint of rotation to the winding spindle 21 driven in the direction 21 by the drive wheel 22 of the drive mechanism 21 ·

As already mentioned, it is also possible to switch to "fast forward" and "fast rewind" operating modes in apparatus 2 / in which the magnetic strip is not increased by the speed of movement between hubs 21 and 21 ''. the strip 21 is fed back into the cartridge 2 before such a winding operation, by moving the sliding guides 25, 2c, 12 and 12 of the strip and the pressure roller 29 from their working positions back to their rest positions shown by the dotted line Fig. 2 and simultaneously driving the drive spindle 21 in the direction of the drive wheel 21 of the drive mechanism 22, the magnetic strip 12 then running again along the path indicated by the black line 13.3 during the rewinding of the magnetic strip to 12 in "fast forward" and "fast rewind" operating modes, the magnetic strip 12 is driven exclusively by driving one of the two hubs 22 and 22 the two winding spindles 22 and 22 are also actuable by the drive mechanism 22 also in the two working modems, the drive wheel 21 of said drive mechanism being brought into the circumferential drive connection with the winding spindle about 25 in the "fast forward" operating mode and the winding spindle wheel 22v "fast rewind" operating mode.

FIG. 3 shows a chassis 221 of a recording and / or reproducing device for a tape carrier for which a drive shaft 33 is provided which is rotatably supported by the chassis superstructure 221 with a bearing bush 1-3. Typically, the tape recorder (not shown) is pressed against the drive shaft 33 by means of a clamping roller 29, as a result of which it is moved by the drive shaft 33, while the drive piece 29 monitors its rotation. In order to press the clamp pulley 29 against the drive shaft in this way, the clamping roller 29 is provided on the carrier 221 by which it can be moved towards or away from the drive shaft 33. In the illustrated embodiment, the carrier 221 is formed by a lever arm. rotatably mounted on the chassis plate 221. Also, a sliding carriage can be used as carrier 221 for the clamping cage 121.

As is known, it is particularly important to perfectly move the tape record carrier so that the clamping roller 29 precisely engages along the periphery of the drive shaft or tape recorder disposed therebetween, especially also when the clamping roller monitors its rotation. In a known manner, the rotary and ball-shaped bearing of the clamping roller 29 is selected for this purpose in order to ensure that the clamping pulley can be adapted in its position as the drive shaft 33, which is required if the axis of the drive shaft 33 is disposed in a resilient manner. χ 2. sv £ axis. j í x x t x x y y y y y y y;;;;;;;;;;;;; ... The bearing arrangement is now achieved by two co-acting bearing parts, one of which is a ball, the other being a spherical shell partially enclosing the ball, the two bearing parts being mounted coaxially with respect to the axis 207 of the clamping roller 29 within the axially extending recess 108 in this pulley and wherein one of the two bearing portions is rigidly attached to the recess 16 to the gripper roller 29, and the other of the two bearing portions is rigidly connected to the support pin 9 by the support pin 99. According to the present invention, the ball 21 is secured by such a rotary bearing. forming one of the two bearing portions is firmly attached inside the recess 1C8 to the clamping roller 29 and the ball bushing forming the other of the bearing portions is rigidly attached to the support pin 9 to the carrier 1C5. For this purpose, it is ensured in the illustrated embodiment that ηε at the bottom 212 of the recess 1C8 formed in the clamping roller 29 is provided with a projection 122 oriented coaxially with the shaft 1C7 of the clamping roller <9 ε to which the HC ball is fixed. In this case, the starting body-blocking pulley 39 consists of a rigid metal housing. The bead 212 may then be provided with a vulcanized rubber layer, not shown, and the bead 212 consists of solid steel, and the bead 212 may be fastened to the runner 212 in a very simple manner by welding. Further, the ball housing 211 can be advantageously made partly synthetic. on a material which is designed to engage the ball 122, while in the present case the ball bush 212 is provided with a collar member 222 (which is pressed against the support pin 222) so that it is itself fixedly attached to the support pin 222 to the carrier 105. Of course, a number of other possibilities are available in the art of single-cylinder 222 with a clamping roller 29 and, on the other hand, of a spherical sleeve 212 with a support pin 212, as is known in the art.

Due to the fact that, in the present case, the ball 22i is connected to the clamping roller 29 and the ball case 222 is fixedly connected to the support 222 by the support pin 222, the ball 11i forms a rotatable bearing portion while the ball housing 1H forms a stationary bearing part. Since the balls can be manufactured with a considerably higher accuracy with respect to the state of their surface than the spherical bushes, the rotatable bearing part has a greater accuracy, as a result of which, when the clamping roller 29 engages the drive shaft 33 - 1. In particular, a particularly accurate run and uniform tape is achieved by tracking or turning the tape carrier. As can be seen from the drawing, in the embodiment shown, the ball housing 222 is designed to asymmetrically swing the ball 110 relative to the shaft 107 of the clamping roller 29, while when the clamping roller 29 engages the drive shaft33, the opening 115 of the ball bushing 111 is inclined towards the drive In this way, a particularly favorable force transmission from the carrier W5 to the clamping pulley 29 is achieved to press it against the drive shaft 33 or the tape recorder, since the ball housing 111 partially encircling the ball 1.22 participates in transferring the proportion of the larger surface than would be if the ball bush surrounds the ball symmetrically with respect to the shaft 17 of the clamping roller.

Claims (2)

11 PATENT'S CLAIMS A tape device for driving a tape comprising a clamping assembly for clamping a tape carrier against a drive shaft in which the clamping roller is rotatably mounted on a rotating and tilting support and is rotatably supported by two co-acting bearing portions, one of which is a ball and the second formed by a spherical bushing partially surrounding the ball, the two bearing portions being disposed coaxially with respect to the axis of the nip roller inside the axially oriented indentation in said pulley, and one of the two bearing portions being rigidly connected via the support pin to the carrier, characterized in that 10 / forming one of the two bearing parts is rigidly connected in the recess (8) to the clamping roller (4) the sleeve (11) forming the second of the two bearing parts is fixedly connected via the support pin (9) to the carrier (5). The tape device according to claim 1, characterized in that the ball (10) forming one of the two bearing parts is surrounded by a ball bush (11) forming the other of the two bearing portions asymmetrically with respect to the clamping roller axis (11f). wherein, when the clamping pulley is flanged into the drive shaft (2), the bore (15) of the ball housing (11) is inclined 1 towards the drive shaft (2). 17 60600