FI81460B - DRIVMEKANISM FOER EN VIDEORECORDER. - Google Patents

Description

♦ 1,81460

VCR CONTROL MECHANISM

In known video magnetic tape devices using the oblique groove method, the magnetic tape is guided in a helical manner at a fixed screwing angle around the audio head-5 drum. In this case, the sound main drum device is positioned obliquely at a certain angle with respect to the base plate to compensate for the height difference caused by tape screwing between the beginning and end of entanglement in the sound main drum and to provide tape control which forms a substantially non-crossover

To do this, it is necessary to pull the tape out of the cassette and bring it into position by means of turning means, which are usually formed as pins or rolls. Conventionally, these pins also take on the task of positioning the tape in operation, so that they must take their end-to-end position with very high accuracy. It is therefore essential to adjust the responses of these pins, in which case this adjustment must be maintained throughout the service life of the device.

The object of the invention is to provide a drive mechanism of a video recorder with a tape control, by means of which the magnetic tape is brought into the correct position independently in operation. This object is solved by the invention set out in claim 1 25. Further developments of the invention are set out in the subclaims.

The invention is in principle formed in such a way that the turning elements included in the threading mechanism are formed as tipping or pendulum pins without side flanges guiding the magnetic tape. These pins have a cylindrical or conical sleeve which is suspended in its axially measured central part in a point-like manner and which is mounted in a plane so as to be movable relative to the fixed inner part.

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If the magnetic strip is guided around the sleeve so that the center of the magnetic strip is outside the tip or pendulum axis of the sleeve against the pin, the sleeve will be positioned so that the strip tends to slide transversely of the strip along the pin in the direction of kippikohdasta. The distance between the center of the magnetic strip and the tip of the core of the sleeve then determines the force components with the strip pull transverse to the direction of travel of the strip. In the sound main drum area, the magnetic tape is guided by guide pins fixedly arranged in front of and after the exit point of the sound main drum vertically with respect to the direction of travel of the tape. These guide pins are provided at their upper end with a flange, the inner edge 15 of which rests on the edge of the magnetic strip for height control.

The pendulum pins automatically position the magnetic strip against the flanges of the guide pins. Approximately in the middle of the entanglement ring in the sound main drum, the magnetic tape is at one edge against the other fixed guide portion. The advantage of the pre-20 belt guide is that the pendulum pins compensate for possible belt guide errors. Thus, viewed over the width of the magnetic strip, a uniform tension (strip tension profile) is formed in the magnetic strip, thereby avoiding flutter of the magnetic strip.

Another advantage is that the pendulum pin included in the threading mechanism, which is movably arranged with the threading mechanism in the frame, does not need any precise adjustment in its operating position, since it itself adjusts optimally. Thus, expensive adjustable responses 30 are eliminated. Preferably, the branches in front of and behind the pendulum pins are separated mechanically. Thus, inaccuracies in the tape guide do not affect the groove or partition accuracy outside the partitioning unit.

In the following, an embodiment of the invention will be explained with reference to Figures 1-5:

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3,81460

Figure 1 shows the course of the belt guide in the drive mechanism according to the invention

Figure 2 shows, in a simplified side view, the control of the magnetic tape in the area of the sound main drum; Fig. 3 shows a part of the drive mechanism on the section line A-3;

Fig. 4 shows a partial view as a side view of section A-B of Fig. 3, and

Figure 5 shows in sectional views an embodiment of a pivot pin according to the invention.

Figure 1 shows a drive mechanism in which a video cassette 1 is inserted. The rubber compression roller 4, pivot pins 8, pivot roller 12 and tape traction sensor 13 have pulled a magnetic tape 20 from the video cassette 1 and placed it 20 wraps around the sound main drum 2 in an approximately central support by means of a fixed guide part 11. The magnetic tape 20 is pressed by a rubber compression roller 4 against the drive shaft 3 and passes the audio output head 5, the audio output audio output 6 and the universal output audio output 7. In normal use, the tape 20 of the magnet-20 is conveyed from the left unwinding reel of the video cassette 1 to the right winding reel. The conveying direction of the tape and the direction of rotation of the sound main drum 2 are the same in normal operation (sweeping).

Figure 2 shows a slopingly mounted one-piece sound main drum 2 around which the magnetic tape 20 is wound helically. The supply of the magnetic strip 20 takes place in each case via one pivot pin 8 and the strip guide pins 9 and 10. The magnetic strip 20 is guided so that, due to the positioning of the pivot pins 8, it is automatically from the edge 30 against the flanges of the guide pins 9 and 10. Another Mag the tin threat edge is arranged approximately half kietoutumiskehän item of a fixed guide member 11 on top. This arrangement enables the three-point bearing of the magnetic strip 20 4 81 460 to be entangled in the entanglement region of the sound main drum. The pivot pins 8 are provided with a cylindrical sleeve arranged around a transverse axis 22 below the center line 23 of the magnetic strip. By means of the belt pull 5, these cylindrical sleeves are positioned so that at each belt speed the upper edge of the belt automatically rests against the flanges of the guide pins 9, 10. Such an arrangement is disclosed in co-pending German patent application P 33 00 378.5-31, which is another of the priority applications.

In the one-piece sound main drum 2 shown, the guide part 11, on which the lower edge of the magnetic tape rests, protrudes into the rotating groove 24 without touching the sound main drum 2. The guide part 11 15 is fixed to the drive body 25 and can be adjusted For scanning, the tape can be adjusted so that the sound head 26 accurately scans the desired grooves. However, this is not the case with the changed belt speeds. By means of the opposite height adjustment of the guide pins 9 and 10, the screwing angle can now be changed in the entanglement region of the sound main drum so that, depending on the adjustment of the guide pins 9 and 10,

Figures 3 and 4 show a device for adjusting the guide pins 9 and 10. By means of the opposite height adjustment of the pins 9 and 10, a change in the screwing angle around the sound main drum 30 2 of the magnetic tape 20 is effected. The guide pins 9 and 10 are guided in counter-moving threaded sleeves and are connected by pivot levers 27 operated via a push rod 28 by an electrodynamic transformer 29. The transformer 29 is controlled by signals obtained in repetition-35 operation as described in Grundig

Technische Informationen "3-1980 No. 3 from the control signals stored above. However, the adjustment of the control pins 9 and 10 can also be achieved by changing the belt speed.

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5 81460 with the pre-set locking stations taking care of the correct groove position. If necessary, additional continuously controlled post-adjustment can be used.

The adjustment paths of the pins 9, 10 depend on the speed at which the magnetic strip 20 moves in the longitudinal direction. At N times the speed, the control path must have n groove widths, i. the second pin must be moved with n / 2 groove width in the other direction and the second pin with n / 2 groove width in the other 10 directions. This is true, for example, by moving forwards and backwards in opposite directions.

Thanks to the independent positioning of the pendulum pins 8, when adjusting the pins 9 and 10, it is ensured that the belt control is optimally adjusted even at changed belt speeds.

Fig. 5 shows sectional views of an embodiment of a pivot pin 8 according to the invention. A metallic pin 30 at one end on both sides of the plane, centrally thinned with respect to the axis, with a thread arranged for fastening, includes a metal ball 31 in the hole in the center portion 20 of the plane in the thinned portion. The ball diameter is selected to protrude from the thinned portion of the pin 30 on both sides. sides. A cylindrical plastic part 32 with a recess in the central part of the shaft fitted in a thinned part of the metal pin 30 is pushed from its arms 25 onto the thinned part provided with the ball 31 of the pin 30.

In this case, the branches spread due to the effect of the ball 31. A metal sleeve 33, the inner diameter of which is formed so that it can be pushed without clearance onto the plastic part 32, is pushed onto the plastic part 32. The hooks 30 of the plastic part 32 are rigidly pressed onto the ball 31 so that the ball 31 is pressed into the plastic part 32. Thus, a point-like core bearing 33 is formed on the shaft. Selecting the outer diameter of the plastic part 32 relative to the diameter of the metal pin 30 determines the possible deviation.

Claims (6)

A drive mechanism for a video recorder having a head drum (2) screwed into a magnetic strip (20), with a first guide portion (11) supported at the circumference of the main drum (2), arranged at the first edge of the drum (2) a second and third guide portion (9, 10) acting on the second edge of the magnetic tape (20) acting on the second edge of the magnetic tape (20) on the second edge of the magnetic tape (20), characterized in that on the path of the magnetic tape (20) to the second and third guide members (9, 10), the turning pin (8) with a cylindrical sleeve (33) pivotable about a tipping point (22) lying in the direction of the first edge of the magnetic strip (20) is displaced to its center line (23), the sleeves (33) being directed through the belt pull so that the magnetic belt (20) lies with its second edge towards the second and third guide members (9, 10). 2. A drive mechanism according to claim 1, characterized in that the second and third guide members (9, 10) are formed parallel in relation to the belt surface and substantially vertically arranged in the delay direction in the belt direction, which always exhibits both at the upper end a flange, the underside of which forms the support for the second edge of the magnetic strip (20). Drive mechanism according to claim 1 or 2, characterized in that the first control part (11) forms a substantially point-shaped support for the magnetic belt (20). Drive mechanism according to any of claims 1-3, characterized in that the second and third control members (9, 10) are adjustable opposite to each other approximately transversely in the direction of the magnetic belt (20). Il 9 81460 Drive mechanism according to claim 1, characterized in that the first control part (11) projects into a ring bar (24) surrounding a main drum (2). 6. A drive mechanism according to claim 1, characterized in that the turning pins (8) contain a concentric pin (30) flattened to their axis on both sides with a part which functions for an indirect attachment to the chassis (25), in particular a threaded part, that the pin (30) has in the flattened part a bore (31) receiving bore which projects on both sides forward over the flattened part, that a substantially cylindrical plastic part (32) has been provided with a shaft center arranged a recess adapted to the flattened part of the pin (30), the legs of which have been pushed over the flattened part provided with the ball (31), and that a sleeve (33) is inserted over the connected parts (30, 31, 32) without clearance, that the ball (31) is pressed into the shanks of the plastic part (32) and the sleeve (33) is pivotable relative to the pin (33) around a tipping point (22).