DE4112742C2 - - Google Patents

Description

The present invention relates to a rotatable movable magnetic head device for magnetic Recording and playback devices and the like and in particular on a rotatable movable magnetic head device that has a variable head gap width and in which the magnetic head as a whole in the direction of the width of a Magnetic tape is movable.

With recording and playback devices accordingly the 1-inch spiral system designed for the Broadcast transmissions are used an automatic scanning track system (AST) and a dynamic tracking system (DTF) in practice been implemented. With these systems it will Magnetic tape automatically at the time of playback tracked, with the magnetic head in the direction the width of the track of the magnetic tape moves becomes.  

This technique is shown in Figs. 7-12. In Fig. 7, two magnetic heads 1 , 2 for recording and playback are arranged on a rotatable drum. Two heads 3 , 4 for special reproduction only, which are used at the time of the AST or DTF, are each movably supported by bimorph piezoelectric elements 5 , 6 . The rotating drum rotates at a speed of 1800 revolutions per minute.

Fig. 8 shows the structure of a head-actuating element of the DTF system, with the reference numeral 8 denoting the fixed drum and 9 a magnetic tape.

Fig. 9 shows the principle of the operation of the bimorph piezoelectric element 5 which is usually used. The bimorph piezoelectric element 5 is composed of two piezoelectric elements 5 a, 5 b composite plate, each between electrodes 5 and 5 c and 5 d and e are between electrodes 5 d. At the free end of the bimorph piezoelectric element 5 of the head 3 is secured only for special reproduction, so that the bimorph piezoelectric element 5 to warp in the axial direction of the drum 7, whereby the head 3 is moved only for special reproduction such as in Fig. 8 is shown.

The exact structure of the heads 1 , 2 for recording and playback is shown in FIGS. 10 and 11. These heads 1 , 2 are explained as an example using a recording format of a recording and reproducing device of the VHS system. The video track width in the normal mode of operation, in which the tape speed is 3.335 cm / sec, is 58 µm and the video track width in triple recording density mode, in which the tape speed is 1.112 cm / sec, is 19 µm. So that both track widths can be processed, a composite head is provided, which by attaching a head 1 a ( 1 b) for recording and playback in normal mode, in which the track width is 58 μm, and a head 1 d ( 1 c) for Recording and playback in the triple recording density mode, in which the track width is 19 microns, on a base plate 1 e with a distance of 1H (370 microns) between the heads 1 a and 1 d, as shown in Figs. 10 and 11 , is produced and two head units, each consisting of heads 1 a, 1 d and 1 b, 1 c, are arranged diametrically opposite on the rotary drum 7 .

When recording or playing back in normal mode, heads 1 a, 1 b are put into operation, while heads 1 c, 1 d and heads 3 , 4 only rotate for special playback only without function.

On the other hand, when recording or reproducing in the triple recording density mode, the heads 1 c, 1 d are operated, while the heads 1 a, 1 b and the heads 3 , 4 rotate only for special reproduction only without function.

In the following the case of using the heads 3 , 4 is explained only for special reproduction.

The principle of high-speed reproduction (low-noise high-speed search) is explained below with reference to FIG. 12. The symbols A ₁ , B ₁ , A ₂ , B ₂ , A ₃ , B _3,. . . denote video tracks of the magnetic tape 9 with data drawn thereon. The azimuth angles at which data on tracks A ₁ , A ₂ , A ₃ ,. . . recorded by the head are different from the azimuth angle at which the data on the tracks B ₁ , B ₂ , B ₃ ,. . . be included.

It is now assumed that signals are reproduced at five times the speed as an example of the high speed search. Provided that the bimorphic piezoelectric element 5 for the head 3 is operated only for special reproduction, the course of the head is only for special reproduction, which scans the magnetic tape 9 , the one shown in Fig. 12 by the broken line L ₁ If the azimuth of the head 3 coincides with that of the track A only for special reproduction, since the signal can only be obtained by scanning the dashed area of the tracks A ₁ , A ₂ and A ₃ ,. . . is reproduced, a noise bar is produced on the display screen.

To fully enter the data on the track A ₁ wiederzu, even if the video tape at five times the speed running, the head is used only for special reproduction in the axial direction of the track (the left in FIG. 12) moved by four track pitches in a field, while the head comes into contact with the magnetic tape 9 only for special reproduction. In the next field, the opposite head 4 is moved by four track distances only for special reproduction. In this way, the tracks A₁, B₃, A₆. . . fully scanned, producing noiseless playback signals. In other words, noiseless playback at any speed is realized by moving the rotatable magnetic head in the width direction of the track in accordance with the tape speed at the time of playback as described above.

In a prior art head drive system using a piezoelectric element, one end of the bimorph plate is fixed as shown in Fig. 8 and the head is moved vertically for special reproduction only by applying the warping of the bimorph plate as shown in Fig shown. 9, the head gaps being inclined surface as shown in Fig. 8 is shown, and it is difficult to bring the head gaps face in tight contact with the magnetic tape 9. In some cases, the entire head gap area does not come into uniform contact with the magnetic tape 9 , but only with the top or bottom surface of the head, which can increase the contact noise or make it impossible to sample the signal itself. This phenomenon is exacerbated when the speed of the noiseless speed search is increased 9 or 11 times because the amount of head movement must also be increased in proportion to the search speed. Therefore, it is impossible to use the bimorph plate if the amount of head movement is more than ± 400 µm.

In the case of data both at normal recording density operating mode in which the track width is 58 µm is as well as in the triple recording density operating mode in which the track width is 19 µm, have been included, it is impossible to Head gap width of the head only for special Playback to the optimal value for the Track widths in both recording modes to fix. For example, if the head gap width is set to 30 µm, they are when searching for speed in normal recording density mode sampled signal components low in number, while those in the Triple-recorded density mode Signals many crosstalk components of the adj beard signals. That means that in both Modes of operation the image obtained is deteriorated S / N ratio.

The invention is therefore based on the object the disadvantages of the prior art described above Avoid technology and a rotatable magnetic head create device with which the gap width of the head in accordance with the recording density mode can be changed and any Scanning history in accordance with a video trace by evenly engaging the form the entire head column area with the tape can.

This object is achieved by the kenn characterizing features of the main claim solved. The rotatable movable magnetic head device according to the present invention has a composite Magnetic head based on layers and integral  Connect a variety of heads with under different gap widths is produced, with the head gap areas in close contact are arranged to each other and to each other are directed. The composite magnetic head is attached to one on the rotating drum Actuator in the manner of a voice coil attached. At the time of playback it is possible to select a head that has a gap width that matches the width of the track matches from which the data is reproduced should be. It is also possible that To drive the head actuator so that the corresponding video track in accordance with the special playback mode becomes.

The same applies to the rotatable magnetic head device the present invention is a magnetic head element with a variable head gap width attached to an elastic material in such a way that the magnetic head is vertical along the axis of rotation is movable. It is therefore possible to watch the video track at the optimal track width, by the video tape on which data in two Speed types are included, again is given. It will also be a good one Scanning process with the entire head gap area in even contact with the magnetic head educated.

An embodiment of the invention is in the Drawing shown and is in the following Description explained in more detail.

Show it:  

Fig. 1 shows a cross section of a rotary drum of a rotary Magnetkopfvor device according to the present invention,

Figs. 2A and 2B are cross-sectional views of a head unit according to the in Fig. 1 embodiment shown,

Fig. 3A and 3B are plan views of support springs that are used in the head unit shown in FIGS. 2A and 2B,

Fig. 4 is an explanation of the operation of the head unit shown in FIGS. 2A and 2B,

Fig. 5A and 5B are a perspective view and an exploded perspective view of the structure of the composite head according to this embodiment,

Fig. 6 is an electrical circuit for driving the head unit,

Fig. 7 is a perspective view showing the structure of a rotary drum according to the prior art,

Fig. 8 is an explanation of the operation example of a movable head according to the prior art,

Fig. 9 is a schematic diagram of a piezoelectric element for driving a movable head according to the prior art,

Fig. 10 is a plan view of the arrangement of a composite head according to the prior art,

Fig. 11 is a perspective view of the structure of a prior art composite head, and

FIG. 12 shows the track course of the magnetic head, which tracks the tracks at the time of a speed search, which is representative of special reproduction, in accordance with the prior art.

Fig. 1 is a cross section of the entire component of a drum with heads accommodated therein. A rotary drum 17 attached to an axis of rotation 20 carries movable heads 13 , 14 only for special reproduction by means of movable head units 100 . An electrode brush group 10 is provided so that it supplies a current to each coil of the movable heads 13 , 14 only for special reproduction. The electrode brush group 10 comes with a sliding ring 11 , which rotates together with the axis of rotation 20 , in sliding contact. The axis of rotation 20 is directly connected to a drum motor 12 and rotates at a constant speed, such as 1200 revolutions per minute, as is generally known.

A fixed drum 18 attached to a head drum support (not shown) is arranged coaxially with the rotatable drum 17 , and a belt is wound on the outer periphery of both drums 17 , 18 .

Fig. 2A shows a perspective sectional view of the head unit 100, which is formed by an actuating element in the manner of a voice coil, and Fig. 2B is a cross-sectional view of the structure of the head unit 100.

The head unit 100 consists of an actuating element which moves the head 13 or 14 in the direction of the width of a track and comprises a hollow bobbin 103 which is axially movable by means of two disc-shaped carrier springs 101 , 102 carried by a fixed yoke 107 .

On the outer circumference of one of the carrier springs 101 , the head 13 or 14 is fastened for special purposes only. The hollow bobbin 103 is fixed to the peripheral ends of the carrier springs 101 , 102 by an adhesive, and a fine copper wire (for example, with a diameter of 0.1 mm) is wound around the outer periphery of the bobbin 103 with 250 turns, whereby a coil 104 arises.

A rare earth cobalt alloy permanent magnet 105 is fixed to the inner lower portion of a yoke 107 , and a soft iron pole piece is integrally connected to the permanent magnet 105 . A lid 109 is attached to the opening of the upper portion of the yoke 107 and a printed circuit board 110 for electrical connection to the coil 104 is attached to the lid 109 . A terminal of the printed circuit board 110 is electrically connected to the slide ring 11 .

FIGS. 3A and 3B are plan views respectively of the carrier springs 101, 102. Each of the support springs 101, 102 is made of a beryllium copper sheet of 0.8 mm thickness and is provided with a plurality of slots to provide a stable elasticity to manufacture. A fastening part 103 a, 103 b is inserted into the inner peripheral region of the spring 101 , 102 and fastened thereon, and the coil body 103 with the coil 104 is fastened to the fastening part 103 a, 103 b. The outer circumference of one of the carrier springs 101 is used to attach the head 13 or 14 only for special reproduction.

The unit consisting of the light bobbin 103 with a fine copper wire wound around it and the two support springs 101 , 102 according to FIGS . 3A and 3B, which are attached to the regions of the outer circumference, is attached to the inner surface of the yoke 107 by gluing or holding , as shown in Fig. 2A and 2B, respectively. When the hollow bobbin 103 moves vertically together with the circular support springs 101 , 102 attached to the yoke, the head 13 or 14 also moves in the vertical direction only for special reproduction. This state is shown in more detail in Fig. 4 Darge, with respect to FIGS . 1 and 2 in the opposite direction.

The mode of operation is explained in more detail below with reference to FIG. 4. As shown there, the outer peripheral surfaces of the two carrier springs 101 , 102 , which support the light bobbin 103 , are attached to the yoke 107 . The permanent magnet 105 is provided in the hollow bobbin 103 which is fixed to the yoke 107 .

If the N-pole and the S-pole of the permanent magnet 105 is determined as shown in FIG. 4, a current flows through the coil 104 , the drive force being indicated in the left hand by the arrow A in accordance with Fleming's rule Direction is applied, whereby the hollow bobbin 103 moves downward. Since the carrier springs 101 , 102 connected to the yoke 107 on the outer peripheral surfaces have a uniformly high elasticity, the coil body 130 as a whole moves downward (in the direction indicated by the arrow A) in proportion to the magnitude of the current. With the movement of the bobbin 103 , the head 13 or 14 fastened to the long piece of the carrier spring 101 only moves down for special reproduction (in the direction indicated by the arrow A) parallel to the bobbin 103 . The fact that the head 13 or 14 only moves parallel to the bobbin 103 for special reproduction without being inclined, as in the prior art of Fig. 8, is very important for the present invention.

On the other hand, when the direction of the current flowing through the coil 104 is reversed, the bobbin 103 moves upward.

Since, as described above, according to the present invention, the head 13 or 14 only moves vertically parallel to the axis of rotation 20 of the drum 17 for special reproduction only, the entire sliding surface of the head 13 or 14 comes into constant contact with the only for special reproduction Magnetic tape. It is therefore possible to sample the maximum FM signals and the tape is not damaged by the edge of the outer peripheral surface of the head.

In the following, the head elements of the heads 13 or 14 are described in more detail only for special reproduction.

Fig. 5A shows a perspective view of the detailed structure of the assembled magnetic head 13 or 14, and Fig. 5B is an exploded perspective view of the magnetic head. In these drawings, reference numerals 301 and 311 represent head elements made of a single crystal ferrite material. The head elements 301 , 311 have sliding surfaces 301 a, 311 a that come into contact with the magnetic tape and head gap regions 302 , 312 that come into direct contact with the magnetic tape for reproduction. A head column region 302 has a width of 39 μm and the other head column region 312 has a width of 19 μm. Both column regions 301 , 302 are aligned in close contact with one another and the notches on both sides are filled with glass 303 , 313 in order to strengthen the connection.

Coils 304 and 314 are wound independently of one another around the head elements 301 , 311 and thus the head elements 301 , 311 form independent magnetic heads. So that the coils 304 , 314 can be wound around the elements 301 , 311 , the head elements 301 , 311 are provided with openings 305 , 315 through which the coils 304 , 314 pass. The head elements 301 , 311 are also provided with grooves 306 , 316 so that the head elements 301 , 311 can be joined tightly together.

The two head members 301 , 311 having the structure described above are fastened in close contact and in alignment with the head gap regions 301 , 302 to each other and connected together to form a composite head as shown in Fig. 5A. The thickness of the adhesive layer on the sliding surfaces of the head elements 301 , 311 is approximately 1 μm and the coils 304 , 314 are each received in the grooves 306 , 316 . In this state, both elements 301 , 311 are firmly connected to one another.

In the assembled head 13 , 14 , the head element 301 provides a head gap width of 39 μm and the head element 311 provides a head gap width of 19 μm. That is, the total head gap width of the composite head 13 is 58 µm. Thus, when only the coil 314 is energized, the composite head 13 , 14 operates as a head with a gap width of 19 µm, and when both coils 314 , 304 are energized such that both magnetic fluxes are added, the composite head 13 , 14 operates as a head with a head gap width of 58 µm.

In the above explanation, the 1 µm thickness of the adhesive layer can be neglected, but the gap width of the gap portion 302 is set to 38 µm, leaving 1 µm for the thickness of the adhesive layer. It is desirable that the curvatures of the sliding surfaces 301 a and 311 a are the same. For this purpose, the sliding surfaces 301 a, 311 a are polished together after the two head elements 301 , 311 have been connected to one another.

The assembled heads 13 , 14 with the structure described are attached to the rotary drum 17 exactly diametrically opposite in such a way that they protrude from the rotary drum 17 by 40 microns and a magnetic tape is loaded.

At the time of a special reproduction of data recorded in the normal mode of operation, both head elements 301 , 311 are operated such that the composite head 13 , 14 is used as a head with a gap width of 58 μm. On the other hand, at the time of the special reproduction of data stored in the triple recording density mode, only the head element 311 is operated in such a way that the composite heads 13 , 14 are used as heads with a gap width of 19 µm. In this case, it is possible to switch the head gap width of the head to the optimum head gap width only for special reproduction in accordance with the recording density in which the data was recorded on the tape.

FIG. 6 shows a block diagram of the electrical circuit for driving the head units 100 , which are produced by mounting the assembled heads 13 , 14 with variable head gap widths on the carrier springs 101 , 102 .

In this circuit, a signal for scanning the envelope in the special playback mode, an FG signal for determining the rotational speed of the tape transport roller 27 and a control signal (CTL) from a control head 28 are supplied to a pattern generator 120 . The pattern generator 120 and a microcomputer 121 calculate the necessary amount of movement of the movable heads 13 , 14 . The output signals of the pattern generator 120 and the microcomputer 121 are added to adders 122 , 123 , filter circuits 124 , 125 , gain setting devices 126 , 127 and current amplifiers 128 , 129 and the currents corresponding to these output signals are supplied to the brush group 10 and the sliding rings 11 to the Coils 104 are given, whereby the movable heads 13 , 14 are driven. In other words, the relative positions of the movable heads 13 , 14 and the video track are determined by the control signal and the FG signal of the tape transport roller 27 , and the movable heads 13 , 14 are driven depending on the determined relative positions. The arrow 29 indicates the direction of movement of the tape, the reference number 30 denotes a video track with an azimuth angle of + 6 ° and the reference number 31 denotes a control signal recorded on the magnetic tape 9 .

When the playback speed for the magnetic tape 9 is greater than the standard speed as given in the normal playback mode, the control currents for moving the movable heads 13 , 14 down (in the direction indicated by the arrow A in Fig. 4) ) from the standard head positions at the time of the standard speed along the axis of rotation 20 of the drum 17 . On the other hand, when the playback speed for the magnetic tape 9 is lower than the standard speed, the control currents for moving the movable heads 13 , 14 are calculated from the standard head positions upward along the rotation axis 20 .

According to the structure described above it is possible to refer to the positions of the heads  the video track at a given tape transport calculate speed and the positions to correct, thereby ensuring accurate tracking is made possible. In the same way it is for Time of a special playback possible, the low noise condition both in the normal Operating mode in which the track width is 58 µm as well as in the long-term mode in which the track width is 19 µm.

As described above, it is the same as before lying invention possible, first head gap width corresponding to the track width of the Tape by the tape transport speed at the time of recording (58 µm in normal Recording density mode and 19 µm in Triple recording density mode) is to select the head devices in the to operate special playback mode and the heads along the axis of rotation of the drum to move, the noise at the time the special reproduction is eliminated and the S / N ratio of the image as a whole ver is improved.

In this embodiment, a plurality of support springs 102 can be provided, but they have to be selected from those types of springs which have high elasticity and reliability. Although a plurality of slots are provided in the carrier springs 101 , 102 , their structure is not limited to this, and a similar function can be achieved by providing radial slots or different thicknesses of the spring leaves.

The coil 104 is provided at one end of the bobbin 103 in this embodiment, but since it is desirable to have as much clearance between the support springs 101 and 102 as possible, the coil 104 can be arranged in the center of the bobbin 103 and that Carrier springs 101 , 102 can be provided at opposite positions with the coil 104 between them.

Although the magnetic recording and playback device in this example as a VHS system is the present invention also on video devices of the β system and Spiral scanning system applicable.

In addition, the head gap widths are the Heads only for special playback not 58 µm and 19 µm limited.

It is also possible to head no less than three elements for a compound head too use and three different head gap widths to set with three special playback Agree operating modes.

The coil of the head can also be found elsewhere be arranged as long as the magnetic flux closed is. The two ferrite cores or such existing headers can with their aligned gap areas not only with an adhesive but also by "sputtering" or the like with each other get connected.  

As described above, the movable uses Head device according to the present Invention a compound head made by Layering and joining a variety of heads elements with different head gap widths is produced, the head gap areas are aligned with each other. The composite Head is on the movable part of an actuator element attached in the manner of a voice coil, which is arranged on the rotary drum in such a way that it is parallel to the axis of rotation of the rotating drum is movable. It is therefore possible to have the head gap choose width so that the track width of the Video tape with data recorded on it with special playback both with normal Recording density mode as well Triple recording density mode fits. By closely tracking the video track and steering the excitation current of the actuating element in such a way that the surface contact between the video head and the tape is maintained, it will noise caused by tracking errors from the reproduced images eliminated. In addition becomes the S / N ratio of the image as a whole greatly improved since it is possible to view the video appropriate and without interference in the neighboring beard traces.

Claims (6)

1. Rotatable movable magnetic head device, characterized by
a composite magnetic head which is produced by layering and integrally connecting a plurality of heads, the head gap regions being aligned with one another,
an actuating element designed in the manner of a voice coil, which is attached to a rotatable drum for moving the assembled magnetic head parallel to the axis of rotation of the rotating drum,
Means for switching the plurality of heads in accordance with the width of the track to be tracked and
Means for driving the actuator such that the corresponding video track is tracked in accordance with the special playback mode. 2. Magnetic head device according to claim 1, characterized characterized that each head of the variety of heads a head element that has a predetermined Gap width and one around the head element wrapped around reading coil, the Head column areas in alignment and arranged in close contact with each other are.   3. Magnetic head device according to claim 2, characterized characterized that each head element a groove for receiving the reading coil has other head element, the Head column areas in close contact with brought to each other. 4. Magnetic head device according to claim 1, characterized characterized that the head gap width at least one of the head elements on one Gap width is set to that of the width a trace with on it with a multiple the density of the normal operating mode stored data corresponds and that the total gap width of the plurality of each other aligned header elements to a width a track with on it in normal operating mode stored data is set. 5. Magnetic head device according to claim 1, characterized characterized in that the actuator like a voice coil, one on the rotatable one Drum-mounted yoke, one on the yoke attached permanent magnets, a coils body made of carrier springs around the permanent magnets around on the yoke in the way will bear that he along the axis of the Permanent magnet is movable, one around Coil body wound excitation coil and assembled on the bobbin Head embraces.   6. Magnetic head device according to claim 1, characterized characterized that the means for driving the actuator in the head Move operation to a position indicated by Drive the actuator the track with the recorded data with the through Switch the magnetic heads selected gap broad matches.