JPH0447768Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Application Field] This invention relates to a magnetic field transfer device that is most suitable for application to high-speed magnetic tape printers that produce soft tapes for video and audio, for example.

[Summary of the idea]

This idea uses a rotating roller of a magnetic field transfer head to run a master tape and a slave tape, which are stacked and pressed onto the circumferential surface of a drive roller that is rotated by a motor. However, in a magnetic field transfer device configured to magnetically transfer signals recorded on a master tape to a slave tape by a magnetic head, the tilt and azimuth of the perpendicular axis of the rotary roller with respect to the perpendicular axis of the drive roller are adjusted. By making it possible to adjust each of them, the master tape and slave tape stacked on top of each other can run extremely stably, allowing highly accurate magnetic field transfer.

[Conventional technology]

For example, as a magnetic field transfer device as a high-speed magnetic tape printer for producing soft tapes (magnetic tapes on which signals are magnetically transferred) for video and audio, there is an example of an earlier application filed by the applicant of this invention (Japanese Patent Laid-Open Publication No. 60-22737).

This prior application has a magnetic field transfer head having a rotating roller that is rotated around the outer periphery of a magnetic gap of the magnetic head, and a drive roller that is rotationally driven by a motor. 2
While running the master tape and slave tape, which are stacked and crimped together, using a drive roller,
It is constructed so that the signals recorded on the master tape are magnetically transferred to the slave tape by a magnetic head.

[Problem that the invention attempts to solve]

According to this prior application, since a rotating roller is provided on the outer periphery of the magnetic gap of the magnetic head, the master tape and slave tape can be separated, for example, from 1 to 2 m apart.
It is possible to produce soft tape at high speed by running the tape at a high speed of sec.

However, in this prior application, if the perpendicular axis of the rotating roller of the magnetic field transfer head is not completely parallel to the perpendicular axis of the driving roller, two sheets will be overlapped on the circumferential surface of the driving roller by the rotating roller. The master tape and the slave tape that are pressed together and run are misaligned, and the accuracy of magnetic field transfer is likely to be extremely degraded, such as track misalignment of the transfer signal.

This invention was devised in order to solve such problems, and allows two superimposed master tapes and slave tapes to run extremely stably.

[Means for solving problems]

This idea is based on the above-mentioned magnetic field transfer device.
a head mounting base on which the magnetic field transfer head is mounted;
a carriage for mounting the head mount on an upper part thereof and moving the head in a direction of distance relative to the drive roller; and a second reference plane that is a plane that is large and perpendicular to the first reference plane, and the head mounting base attached to the upper part of the carriage is set on the first reference plane and the second reference plane. A tilt adjustment mechanism and an azimuth adjustment mechanism are provided for adjusting the tilt and azimuth of the vertical axis of the rotary roller with respect to the vertical axis of the drive roller by respectively adjusting the tilt in two directions along the rotary roller. It is something.

[Effect]

According to the magnetic field transfer device of this invention, it is possible to adjust the tilt and azimuth of the vertical axis of the rotating roller of the magnetic field transfer head with respect to the vertical axis of the drive roller. The vertical axes of the rollers can be adjusted to perfect parallelism. Therefore, the master tape and the slave tape, which are overlapped and pressed onto the circumferential surface of the drive roller by the rotating roller and run, are run extremely stably so that no misalignment occurs between them. be able to.

〔Example〕

An embodiment in which this invention is applied to a high-speed magnetic tape printer will be described below with reference to the drawings.
Note that this high-speed printer is a magnetic field transfer device that produces soft tapes (magnetic tapes on which signals are magnetically transferred) for video and audio.

First, an overview of a high-speed printer will be explained with reference to FIGS. 1 and 2.

A master tape (a magnetic tape on which signals to be transferred are recorded) 1 and a slave tape (a magnetic tape on which signals are transferred by a magnetic field) 2 are guided by a plurality of tape guides 3a to 3c, 4a to 4c, and 5. The vehicle travels in the directions of arrows a and b, respectively, along the traveling routes. In addition, these master tape 1 and slave tape 2 have these recording surfaces (magnetic surfaces) 1
2a and 2a are pressed against a large-diameter drive roller 6 by a rotating roller 8 of a magnetic field transfer head 7 in a superimposed state. Then, the driving rubber roller 6
is rotationally driven in the direction of arrow c by a motor (not shown), so that these master tape 1 and slave tape 2 are rotated in the same direction in the directions of arrows a and b at a high speed of, for example, 1 to 2 m/sec or more. While running at high speed, the signals recorded on the recording surface 1a of the master tape 1 are magnetically transferred to the recording surface 2a of the slave tape 2 by the magnetic field transfer head 7, so that the video or audio soft tape can be played at high speed. It is manufactured. Note that the drive roller 6 is connected to a rotating shaft 9.
The rotating rubber roller has a rubber ring 11 made of urethane rubber or the like fixed to the outer periphery of a metal disk 10 made of aluminum or the like fixed to the roller. ing. The drive roller 6 is rotatably supported by a bearing cylinder 13 fixed to a base 12 via a rotating shaft 9 and a bearing (not shown).
This drive roller 6 is rotated by a motor in the direction of arrow c about a vertical axis _P1 at a circumferential speed of 1 to 2 m/sec or more. Further, the rotating roller 8 of the magnetic field transfer head 7 is made of a non-magnetic material such as ceramic, and the rotating roller 8 is made of a non-magnetic material such as ceramic.
It is arranged around the outer periphery of the magnetic gap 14a of No. 4 and is configured to be rotated at high speed in the direction of arrow d by being driven by the drive roller 6 around the vertical axis _P2 .

Next, as shown in FIGS. 1 to 5, the drive roller 6
A tilt adjustment mechanism for the vertical axis P ₂ of the rotary roller 8 with respect to the vertical axis P ₁ , an azimuth adjustment mechanism, and an R balance adjustment mechanism for the magnetic gap 14 a of the magnetic head 14 will be explained.

First, the magnetic field transfer head 7 is attached to the head mounting base 16, and the head mounting base 16 is attached to the auxiliary base 1.
7 to the upper part of the carriage 18. Then, the carriage 18 is guided by a pair of guide shafts 19 mounted horizontally and parallel to the base 12, and is moved in the directions of arrows d and d' in FIG. It is composed of The carriage 18 is driven in the direction of arrow d by a carriage drive mechanism (for example, a mechanism combining a plunger solenoid and a spring), which is not shown, so that the rotating roller 8 of the magnetic field transfer head 7 is rotated to the master position. The tape 1 and the slave tape 2 are overlapped with each other and are elastically pressed against a rubber ring 11 on the outer periphery of a drive roller 6 with a pressing force of, for example, 1 to 2 kg or more.

Next, the tilt adjustment mechanism 21 will be explained, but as shown in FIG.
A first reference plane _F1 , which is a vertical plane parallel to the vertical axis _P1 of the drive roller 6, is set, and the carriage 18
By adjusting the inclination of the head mounting base 16 attached to the upper part of the drive roller 6 via the auxiliary base 17 in the direction of the arrow X along the first reference plane _F1 , the rotating roller relative to the vertical axis _P1 of the drive roller 6 can be adjusted. This is to adjust the tilt of the vertical axis P ₁ of the lens 8 along the first reference plane F ₁ , that is, the tilt.

As shown in FIGS. 1 and 2, this tilt adjustment mechanism 21 is provided with a fastener with a spring washer 22 at a position directly below the rotating roller 8 on the same axis as the vertical axis P ₂ of the rotating roller 8. A screw 23 is fastened from below to a screw hole 25 of the auxiliary base 17 through a hole 24 of the carriage 18. Also, at the rear position of the head mounting base 16 (the right end position in Figure ₂ ) within the first reference plane F1 in Figure 5, which includes the vertical axis _P2 of the rotating roller 8, the auxiliary base position 7 is Fine adjustment screw 27 in screw hole 26
from above, and insert the tip 27a, which is the lower end of the fine adjustment screw 27, into the upper surface 18a of the carriage 18.
The hollow part 2 at the center of the fine adjustment screw 27
7b, the fastening screw 29 with the spring washer 28 is inserted from above and held in place, and the lower end of the fastening screw 29 is inserted into the elongated hole 30 centered on the hollow hole 24 of the carriage 18, and the nut 3 is inserted.
It is concluded by 1.

Then, when the fine adjustment screw 27 is rotated and adjusted by moving it up and down, the tilt of the head mounting base 16 is adjusted in the direction of the arrow X mentioned above via the auxiliary base 17 on the carriage 18, and the tilt adjustment of the rotating roller 8 is performed. It will be done. After this tilt adjustment, the auxiliary stand 17 is completely fixed on the carriage 18 by fastening the fastening screw 29 and the nut 30.

Next, the azimuth adjustment mechanism 33 will be explained. As _shown in FIG _. A second reference plane _F2 , which is a plane _{perpendicular} to By adjusting the inclination, the inclination of the perpendicular axis P ₂ of the rotary roller _{8 with respect to the perpendicular axis P 1 of the drive roller 6 along the second reference plane F 2 ,} that is, the azimuth, is adjusted.

As shown in FIGS. 1 and 3, this azimuth adjustment mechanism 33 is connected to the second reference plane in FIG.
Screw the pair of fine adjustment screws 35a, 35b into the pair of screw holes 34a, 34b of the head mount 16 from above at both the left and right end positions of the head mount 16 in _F2 (the positions of the left and right ends in Figure 3). Then, connect the tips 35a', 35b', which are the lower ends of these fine adjustment screws 35a, 35b, to the upper surface 17a of the auxiliary table 17.
Fastening screws 37a, 3 with spring washers 36a, 36b are placed in the hollow parts 35a'', 35b'' at the center of these fine adjustment screws 35a, 35b.
7b from above, and insert the lower ends of these fastening screws 37a and 37b into the auxiliary base 1.
7 is fastened from above to a pair of screw holes 38a and 38b.

When the pair of fine adjustment screws 35a and 35b are rotated and adjusted by moving them vertically in opposite directions, the inclination of the head mounting base 16 in the carriage 18 via the auxiliary base 17 is adjusted in the Y direction. , the azimuth adjustment of the rotating roller 8 is performed. After this azimuth adjustment, the head mounting base 16 is completely fixed on the auxiliary base 17 by fastening the pair of fastening screws 37a and 37b.

Next, the R balance adjustment mechanism 40 will be explained.
This R balance adjustment mechanism 40 is
As shown in FIG. 5, the head mounting base 16 attached to the upper part of the head via the auxiliary base 17 is adjusted to rotate in the direction of arrow Z around the vertical axis _P2 of the rotating roller 8. Therefore, the direction of the magnetic gap 14a of the magnetic head 14 is adjusted by rotating around the vertical axis _P2 of the rotating roller 8 in the direction of arrow Z.

Then, this R balance adjustment mechanism 40
As shown in the drawings and FIG. 2, the fastening screw 23, blank hole 24, fastening screw 29, elongated hole 30, and nut 31 of the tilt adjustment mechanism 21 described above serve the same purpose.

That is, loosen the nut 31 and insert the fastening screw 29 along the elongated hole 29 of the carriage 18 in the direction indicated by the arrow in FIG.
When the head mounting base 16 is adjusted in the Z' direction, the head mounting base 16 rotates around the vertical axis _P2 of the rotating roller 8, which is the center of the fastening screw 23 and the hole 24, as shown in FIG. The direction of the magnetic gap 14a of the magnetic head 14 is adjusted by rotation in the Z direction, and the R balance is adjusted. Note that after this R balance adjustment, the auxiliary stand 17 is completely fixed on the carriage 18 by fastening the fastening screw 29 and the nut 30.

Therefore, by the tilt adjustment and azimuth adjustment by the tilt adjustment mechanism 21 and the azimuth adjustment mechanism 33 described above, the vertical axis of the drive roller 6
The perpendicular axis P ₂ of the rotating roller 8 with respect to P ₁ can be adjusted to be perfectly parallel. Therefore, the master tape 1 and the slave tape 2, which are overlapped and pressed onto the circumferential surface of the drive roller 6 by the rotary roller 8 and run, are kept very close so that no misalignment occurs between them. It can run stably. As a result, there is no occurrence of track deviation in the transfer signal, and highly accurate magnetic field transfer can be performed.

In addition, as shown in FIG. 1, a magnetic field transfer head 7
The position of the magnetic gap 14a of the magnetic head 14
P ₃ to a position P ₄ where the master tape 1 and slave tape 2, which are pressed together between the drive roller 6 and the rotating roller 8, are moved away from each other as they travel in the directions of arrows a and b, respectively. The magnetic field transfer described above cannot be performed accurately unless it is accurately set at a position spaced a predetermined distance l on the upstream side in the running direction of both tapes 1 and 2, which is the direction opposite to arrows a and b. However, due to the above-mentioned R balance adjustment operation,
Since the position _P3 of the magnetic gap 14a can be accurately set at a predetermined position, the magnetic field transfer described above can always be performed accurately.

Although the embodiments of this invention have been described above, this invention is not limited to the embodiments, and various effective changes can be made based on the technical idea of this invention.

[Effect of idea]

As described above, the magnetic field transfer device of this invention is capable of adjusting the perpendicular axis of the rotating roller of the magnetic field transfer head to a completely parallel state with respect to the vertical axis of the drive roller. The master tape and the slave tape, which are overlapped and pressed onto the circumferential surface of the drive roller and run in two sheets, can be run extremely stably without any misalignment between them. As a result, track deviation of the transcription signal does not occur, and
Highly accurate magnetic field transfer can be performed.

[Brief explanation of drawings]

The drawings show one embodiment of this invention, in which Fig. 1 is a plan view of the main part, Fig. 2 is a partially cutaway side view taken in the - arrow direction of Fig. 1, and Fig. 3 is a partially cutaway side view of Fig. 1. Fig. 1 is a partially cutaway side view in the - arrow direction, Fig. 4 is an exploded perspective view of the main parts, and Fig. 5 is a tilt, azimuth, R
It is a perspective view explaining the balance adjustment method. In the symbols used in the drawings, 1... Master tape, 2... Slave tape, 6... Drive roller, 7... Magnetic field transfer head, 8... Rotating roller, 14... Magnetic head, 14a... Magnetic gap. , 16... Head mounting base, 18... Carriage, 21... Tilt adjustment mechanism, 33... Azimuth adjustment mechanism, P ₁ ... Vertical axis of drive roller, P ₂
...the vertical axis of the rotating roller, _F1 ...the first reference plane, _F2 ...the second reference plane.

Claims (1)

[Claims for Utility Model Registration] A magnetic field transfer head has a rotating roller that is rotated around the outer periphery of a magnetic gap of the magnetic head, and a drive roller that is rotationally driven by a motor. A master tape and a slave tape, which are stacked and pressed on the circumferential surface, are run by a drive roller, and the signals recorded on the master tape are magnetically transferred to the slave tape by a magnetic head. The magnetic field transfer device includes a head mount to which the magnetic field transfer head is mounted, and a carriage to which the head mount is mounted on top and moves the head in a direction toward and away from the drive roller, the carriage being parallel to the vertical axis of the drive roller. a first reference surface that is a perpendicular surface; and a second reference surface that is parallel to the perpendicular axis and perpendicular to the first reference surface.
by setting a reference plane of the drive roller and adjusting the inclination of the head mounting base attached to the upper part of the carriage in two directions along the first reference plane and the second reference plane, respectively. A magnetic field transfer device comprising a tilt adjustment mechanism and an azimuth adjustment mechanism for respectively adjusting the tilt and azimuth of the vertical axis of the rotating roller with respect to the vertical axis.