JPH0244523A - Device and method for transferring magnetic tape - Google Patents

Abstract

PURPOSE:To uniformly and efficiently transfer the recording pattern of a master tape to a copy tape by executing energy irradiation to the both edges of the copy tape, which is traveled with being adhered to the master tape, in a width- wise direction so that the both edges can be strongly heated in comparison with a central part. CONSTITUTION:A master tape 1 and a copy tape 2 are traveled with adhering respective surfaces, to which a magnetic material is applied, in an outer circumference 4 of a rotating wheel 3. When this copy tape 2 is continuously irradiated with a slit beam 7, the copy tape 2 is speedily heated only at a moment, when the copy tape is irradiated, and after that, the copy tape is speedily cooled by high pressure air 5 or the radiating effect of the rotating wheel 3. Then, the transferring is executed. At such a time, for the slit beam 7, since the intensity of a light is stronger in the both edge parts rather than in the central part concerning the width-wise direction of the copy tape 2, the copy tape 2 is heated so that almost uniform temperature distribution can be obtained. Then, the recording pattern of the master tape 1 is transferred to the copy tape 2 by a comparatively uniform recording level.

Description

Detailed Description of the Invention [Field of Industrial Application] The present invention relates to a magnetic tape transfer device and a transfer method for mass-duplicating magnetic tapes such as video tapes, and particularly relates to a transfer method using heat. The present invention relates to a magnetic tape transfer device and a transfer method.

[Conventional technology]

As a method for mass-duplicating magnetic tapes such as video tapes, there is a technique of copying by transfer. Replication by transfer is performed by recording signals on a master tape in advance, then bringing a copy tape into close contact with the master tape, and transferring the entire signal recording pattern of the master tape onto the copy tape.

Transfer from the master tape to the copy tape is performed by heating the copy tape to a temperature higher than the Curie temperature of the copy tape in the portion where the master tape and the copy tape are in close contact.

This type of transfer technology using heat is, for example, U
S P4,631,602 and US P4,698,7
01 etc.

In the devices shown in these documents, the copy tape and master tape are run at a constant speed.

The laser emitted from the laser oscillation device is irradiated so that the irradiation pattern is formed into a thin cotton in the width direction of the copy tape. According to this device, the copy tape is rapidly heated at the portion irradiated with the laser, and is rapidly cooled after passing through the portion irradiated with the laser. Then, the master tape temperature remains relatively low, so
The master tape can be used repeatedly because the signals recorded on the master tape do not deteriorate.

In addition, as a transfer device using heat, microwave is used in Japanese Patent Publication No. 52-42374, Japanese Patent Publication No. 50-3
In addition to those using infrared rays in No. 935, there are also those that use electron beams.

The most important problem with conventional magnetic tape transfer devices as described above is how to efficiently and uniformly transfer signals recorded on a master tape onto a copy tape.

Therefore, in conventional magnetic tape transfer devices, it is necessary to mutually adjust the traveling speed of the copy tape and the laser irradiation power, or to adjust the power distribution of the laser irradiated onto the copy tape in the width direction of the copy tape. , was carried out in detail.

[Problem to be solved by the invention]

A problem with conventional magnetic tape transfer devices is that it is difficult to transfer signals recorded on the entire surface of a master tape to a copy tape with uniform transfer efficiency. For example, if a signal recorded on a master tape is recorded at a uniform recording level over the entire surface of the master tape, when that signal is transferred to a copy tape by transfer, the recording level of the signal will vary depending on the part of the copy tape. The problem is that they are different. The cause of this problem is that sufficient consideration was not given to the temperature distribution of the copy tape when heating the copy tape.

Generally, the efficiency of signal transfer from a master tape to a copy tape is closely related to the temperature at which the copy tape is heated. Transfer efficiency decreases if the copy tape temperature is too low or too high.

On the other hand, heating of copy tape is performed efficiently at the central part in the width direction of the copy tape, and not efficiently at both ends of the width direction.In other words, even if you try to heat the copy tape evenly in the width direction, Cooling progresses more easily at both ends of the tape.As a result, when uniform heating energy is irradiated across the width of the copy tape, the center of the copy tape will have a high temperature, and the ends of the copy tape will have a lower temperature. This results in a temperature distribution.

[Means to solve the problem]

In order to solve the above-mentioned problems, the present invention provides a magnetic tape transfer device comprising: a contact means for running a master tape and a copy tape in close contact with each other; and a contact means for causing the copy tape to be brought into close contact with the master tape. an energy irradiation means for irradiating energy toward the copy tape in order to heat the copy tape; This magnetic tape transfer device is characterized by emitting radiation that heats the tape more strongly than the magnetic tape.

[For production]

When the above-described measures are taken, the master tape and the copy tape run as one unit while being in close contact with each other to prevent them from shifting due to the contact means.

The energy irradiation means irradiates energy for heating the copy tape to a portion where the master tape and the copy tape are in close contact, particularly to the copy tape. This energy is, for example, a laser.

The energy irradiated by the energy irradiation means is
The copy tape is irradiated in the width direction so that the ends of the copy tape are heated more strongly than the center. However, copy tape that has been irradiated with energy,
In the width direction of the copy tape, cooling progresses more easily at both ends than at the center. As a result, the copy tape is heated to have a nearly constant temperature distribution in its width direction.

〔Example〕

FIG. 1 shows the main parts of a magnetic tape transfer device embodying the present invention. In FIG. 1, 1 is a master tape on which signals have been recorded in advance.

2 is a copy tape. 3 is a rotating wheel. The master chip 11 and the copy tape 2 are guided around the outer periphery 4 of the rotary wheel 3 so that the surfaces coated with magnetic material are in close contact with each other. Furthermore, high-pressure air is blown onto the outer periphery 4 of the rotary wheel 3 in the direction indicated by an arrow 5 from an air outlet (not shown). master tape 1
The high-pressure air causes the copy tape 2 and the copy tape 2 to come into close contact with each other at the outer periphery 4 of the rotating wheel 3 so that they do not shift.

The master tape 1 and the copy tape 2 are configured such that when either the master tape 11 or the copy tape 2 is caused to travel by a drive device (not shown), the other one that is not driven also follows.

Reference numeral 6 represents energy irradiation means, such as a laser irradiation device. Beam 7 irradiated from laser irradiation device 6
is irradiated toward the copy tape 2. The irradiation pattern 8 of the beam 7 is formed into a long and narrow shape so as to cross the copy tape 2 in the width direction.

The copy tape 2 is heated to a high temperature at the moment it is irradiated with the beam 7, and thereafter rapidly cooled down by the flow of high-pressure air shown by the arrow 5 and the radiation effect of the rotating wheel 3.

FIG. 2 shows the configuration of the laser irradiation device 6 shown in FIG. 1 in more detail.

FIG. 3 is a graph explaining the operation of the components of the laser irradiation device 6 shown in FIG. Figure 3 (al (b)
) (C) (dl is expressed as a graph with the light intensity on the vertical axis and the position in the diameter direction of the beam on the horizontal axis, each showing the beam pattern.

Furthermore, (X) and (Y) in FIG. 3 indicate two different observation axes that are perpendicular to the beam traveling direction, respectively.

As shown in FIG. 2, the laser irradiation device 6 includes a laser oscillator 9, a collimator 10, a forming means 11, and a cylindrical lens 12. A laser oscillator 9 emits a source beam 13. The beam pattern of the source beam 13 is as shown in FIG. 3(a).
When oscillating in TEM00 mode, it is a single thin beam.

Collimator 10 produces a beam 14 that is a diameter widening of source beam 13 . FIG. 3 (bl shows the beam pattern of the beam 14).

The forming means 11 deforms a part of the beam 14,
In the direction of the observation axis (Y), a modified beam 15 is generated in which the intensity of light is stronger at the outside of the beam than at the center of the beam. FIG. 3(C) shows the beam pattern of the deformed beam 15. When the beam 14 is incident, the forming means 11 returns components of the beam pattern outside a certain range inward. If the beam 14 has a general Gaussian distribution beam pattern, the deformed beam 15 can be selectively generated. Forming means 1
1 is actually composed of a plurality of reflecting mirrors.

The cylindrical lens 12 transforms the modified beam 15 into a slit beam 7. FIG. 3 (dl shows the beam pattern of the slit beam 7. The slit beam 7 is irradiated onto the copy tape 2. The slit beam 7 is elongated in the width direction of the copy tape 2, and The length of the copy tape 7 is slightly longer than the width of the copy tape 2.

When the magnetic tape transfer device is configured as described above, as shown in FIG.
runs in close contact with the outer periphery 4 of the rotating wheel 3. The slit beam 7 is continuously irradiated onto the copy tape 2. Then, the copy tape 2 is rapidly heated only at the moment when it is irradiated with the slit beam 7. The copy tape 2 that has passed through the slit beam 7 is rapidly cooled by the heat dissipation effect of the high pressure air 5 and the rotating wheel 3. - On the other hand, the copy tape 2 is heated more efficiently at the central portion than at both ends of the copy tape 2 in the width direction. However, in the width direction of the copy tape 2, the slit beam 7 has a stronger light intensity at both ends than at the center.

Therefore, the copy tape 2 is heated to have a nearly uniform temperature distribution.

Next, we used a master tape with a width of 12.5 mm and recorded video signals used in consumer bidets, and used a chromium dioxide magnetic material with the same width as a copy tape. An example of a tape transfer method will be described.

The recording pattern of the video signal recorded on the master tape consists of a control signal recorded by a fixed head at one end of the tape, a video signal recorded by a rotating head at the center, and two signals recorded by a fixed head at the other end. Consists of audio signals.

Ideally, the video signal recorded in this way should be recorded on a copy tape at a recording level where the two audio signals are recorded at the same recording level, there is no overshoot of the control signal, and the recording level of the video signal is above the standard level. must be transcribed.

The laser irradiated from the laser irradiation device 6 shown in FIG. 1 is a solid-state laser with a wavelength of 1.06 micrometers, and oscillates in a single mode. Further, the overall power of the slit beam 7 irradiated from the laser irradiation device 6 is controlled by the temperature when the copy tape 2 is heated, and the beam pattern of the slit beam 7 is controlled by the optical system built in the laser irradiation device 6. controlled by the adjustment of Then, if the running speed of the copy tape 2 is constant, the two parameters that change the transfer characteristics are the overall power of the laser irradiation device 6 and the beam pattern of the slit beam 7.

FIG. 4 shows a beam pattern of the slit beam 7 as an embodiment of the present invention. In the example, when the width W of the beam is 14 mm and the intensity of the light at the center is 1.0, the intensity M at both ends is
was set to 1.4. The distribution pattern was designed to rise smoothly from the center to both ends.

At this time, the video signal obtained by transferring to the copy tape 2 had a level difference of 1.5 decibels between the two audio signals when the recording level of the video signal was set to the set level.

On the other hand, as a comparative example, although not shown, when the beam width W is 15.5 mm and the beam pattern is constant between the widths W, at the same video signal recording level as in the example, The level difference between the two audio signals was 2.0 decibels.

At this time, a difference occurred in the overshoot of the control signal between the example and the comparative example, and when the overshoot in the example was taken as 1.0, it was 1.1 in the comparative example.

Furthermore, when the overshoot of the control signal was made to be the same between the example and the comparative example, the difference between the two audio signals increased to about 20 decibels in the comparative example.

FIG. 5 shows the relationship between the beam power, which is the entire power of the slit beam 7 shown in FIG. 1, and the level of the video signal transferred to the copy tape 2 for the previous example and comparative example. It is something.

As shown in FIG. 5, in the example, the level of the video signal does not change much even if the beam power is changed, but in the comparative example, it changes significantly depending on the beam power. This relationship between the beam power and the video signal level has no direct bearing on the quality of transfer of the copy tape 2, but it shows that the operation of the example is more stable and the adjustment of the laser irradiation device 6 is easier. There is.

By implementing the transfer method of the present invention as described above, it is possible to perform high-quality transfer with simple adjustments.

It should be noted that the present invention may include many other variations in addition to the embodiments described above. For example, the energy irradiated onto the copy tape is not limited to laser, but may also be electron beams, infrared rays, or electromagnetic waves. Further, when a laser is used as energy, there are lasers of various oscillation modes and of various materials, and the present invention can be implemented by using a suitable optical system for each. Further, as for the adhering means for adhering the master tape and the copy tape shown in FIG. 1, in addition to using high pressure air, a roller may be used.

〔effect〕

According to the magnetic tape transfer device and transfer method according to the present invention, it is possible to transfer the signal recording pattern of the master tape to the copy tape at a relatively uniform recording level.

[Brief explanation of the drawing]

Fig. 1 is an explanatory diagram of the main parts of the transfer device of the present invention, Fig. 2 is a detailed explanatory diagram of the laser irradiation device, and Fig. 3 (a) (b) (C
) (dl is an explanatory diagram of the operation, FIG. 4 is an explanatory diagram showing the beam pattern according to the present invention, and FIG. 5 is a comparative diagram showing the relationship between the beam pattern and the video signal level. 1... ... Master tape, 2 ... Copy tape, 3 ... Rotating wheel, 6 ...
Energy irradiation device, 7...Beam, 9...
... Laser oscillator, 1o, old... collimator, 11
......Forming means, 12--...-Cylindrical lens. Arithmetic 3rd

Claims (4)

[Claims] (1) Transferring the signals recorded on the master tape to the copy tape by bringing a master tape on which a signal has been recorded in advance and a copy tape on which no signal is recorded and heating the copy tape. In a magnetic tape transfer device, the adhesion means causes the master tape and the copy tape to run in close contact with each other, and the adhesion means directs the master tape and the copy tape toward the copy tape in order to heat the copy tape that is in close contact with the master tape. An energy irradiation means for irradiating energy is provided, and the energy irradiated by the energy irradiation means is radiated so as to heat both ends of the copy tape in a width direction more strongly than a central portion of the copy tape. A magnetic tape transfer device featuring: (2) In the magnetic tape transfer device according to claim 1, the energy irradiated onto the copy tape by the energy irradiation means is a laser that heats a magnetic material coated on the copy tape. Features a magnetic tape transfer device. (3) In the magnetic tape transfer apparatus according to claim 1, the energy irradiated by the energy irradiation means is emitted in a long and thin line across the copy tape in the width direction, and A magnetic tape transfer device characterized in that the energy density is distributed such that it becomes stronger from the center to the edge of the copy tape. (4) In a method of transferring a pre-recorded master tape signal to a copy tape on which no signal is recorded, the master tape and the copy tape are run in close contact with each other so that their respective magnetic materials are in contact with each other, and the copy tape is irradiating the magnetic material of the tape with energy so as to heat both end portions in the width direction of the copy tape more strongly than the center portion in the width direction of the copy tape; and the copy tape heated by the irradiation of energy. A magnetic tape transfer method comprising steps of cooling the magnetic tape.