JPS59177730A - Apparatus and method for hardening film of magnetic tape - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a method and apparatus for curing a coating on a moving tape material, and more particularly to a method and apparatus for curing a resin coating on a magnetic tape using an electronic phone hard (or an electronic hammer or a projection). and DJ equipment related.

The magnetic tape medium is a 71.6-mila, polymer-based tape such as that obtained from Teyupon Co., Ltd., on polyethylene terephthalate clay and a resin coating with embedded magnetic particles. The manufacturing process for such tapes requires that the coating be cured by heating or electronic bombardment. The present invention relates to the curing of tape coatings of the latter type.

The problem in the past has been absorbing enough energy from the electronic beam to cure without overheating.

It has been recognized that a single exposure of a magnetic binder tape to a high energy FM beam is inadequate as a means of binding and hardening the agent. If the energy of the electron beam is insufficient to cure the binder, or the energy is high enough to cure, the tape is heated to about 80'
It was known that O exceeds the glass transition temperature of Mylar.

This difficulty could probably be eliminated by passing the tape through a low-energy electron beam several times, but the time required to cure the tape would have a negative impact on production efficiency, making it difficult to control the temperature of the tape. I can't.

These and other shortcomings of conventional methods and apparatus for curing magnetic tape coatings include the use of a means for generating an electron beam, a rotatable tape manipulation means made of high atomic number material placed within the electron beam; , is eliminated by the present invention, which has means to internally control the tape degree with sufficient precision to prevent overheating without interfering with the curing process.

Two preferred embodiments of the invention will be described. First example (
Here, a hollow, relatively large diameter roller with a coolant inside is provided within the electron beam. The magnetic tape to be cured is rotatably supported on rollers within the electronic beam. Preferably, the rollers are made of materials such as copper or steel. Then, the electrons that penetrate the tape and are projected onto the roller bounce back and penetrate the tape again, increasing the amount of electrons hitting the tape.

In a second embodiment of the invention, a plurality of cooled rollers are provided rotatably parallel to each other within the electron beam.
The tape snakes around the rollers within the electronic beam. The rollers are preferably made of high atomic number materials such as copper or steel and are cooled from internal forces. In the second embodiment, electrons also bounce.

It is therefore an object of the present invention to provide an improved method and apparatus for curing the coating of a magnetic tape in an electronic phone hard while cooling the tape.Another object of the invention is to provide an improved method and apparatus for curing the coating of magnetic tape in an electronic phone hard while cooling the tape. The purpose of the present invention is to obtain a magnetic tape coating cured by the method.

Yet another object of the present invention is to control the temperature of the tape to prevent overheating while proceeding with curing.

The novel features and advantages of the device and method of the invention will become apparent from the embodiments of the invention which are explained below by way of example with the aid of the figures.

Figure 1 E: width approx. 55cm, thickness approx. 0.005cm
The coated polymer tape (10) of m is passed through the apparatus of the invention for curing. Tape (10) can be made of any of a variety of polymeric materials such as polyethylene terephthalate (Mylar) and others. The coating of magnetic material is well known in the industry and may be any of the various types of materials that can be cured by heat or electronic bonding. See, for example, US Pat. No. 4,004,997.

The tape 00) advances horizontally from the coating station (not shown) into the shielded housing C1) and passes over a large diameter roller I, preferably copper or steel. The electron beam α6 generated by the electron beam generator (18) passes around the
) and go vertically downward. The coating on the tape is cured during passage through the tape. The tape then leaves contact with the surface of roller α and travels horizontally again under lift to another roller. The roller u4) rotates the tape uO) at a predetermined speed, for example about 254 Cm/sec, by a motor drive device # (not shown). In most cases, ideally about 1337 Galat/Cm1 min (about 4000
irradiation dose (megarad/foot/min).

The electron beam (, 16) penetrates the tape uO)f to the extent (approximately 20%) and rebounds from the roller u4 and returns to the tape Q.
O) and increases the total radiation (nariko) dose through the tape. Since the electronic bombardment causes the roller ua to become extremely hot, a means of controlling the cooling of the roller and thus the tape in contact with it is required.

As mentioned above, the present invention is primarily concerned with controlling the temperature of the tape during curing. A certain amount of energy is accumulated in the tape by the time it is heated to the point of deformation. Conversely, if the temperature of the tape is too low, curing will not proceed. The actual operating temperature will depend on the chemistry of the binder and base substrate used. Curing temperature and deformation temperature are parameters well known to those skilled in the art.

The present invention deals with providing the technician with an apparatus to control and select the temperature range in which a particular binder/base substrate will be cured without deformation.

To further the above objective, a ring-shaped space (57) is provided into which a coolant, water or any other liquid capable of removing thermal energy, is placed.

This ring-shaped space +57) can be fixedly attached to the roller u4I and rotate with it, or can be freely floating or fixedly attached to the housing (241).In the latter embodiment, the ring-shaped space +57) There is a sliding engagement with the rollers.In both cases, the schematic &
A means for determining the temperature of the liquid shown in C(56) is provided. By way of example, a liquid may pass through a sensor (50), and the sensor (50) measures the temperature of the liquid. Sensor force 1
The signal is sent to the controller (51) and this signal is compared to the value set by the handler for the particular tape.The controller sends the signal to the actuator (51).
52), and the actuator uses the signal to send the heated liquid from the valve (54) y) to the valve (54).
53). Alternatively, if the temperature of the liquid is too low, the liquid and the roller U force are heated by the heating action of the electron beam without supplying the liquid.

When heated or cooled liquid is supplied to the ring-shaped space (57) at (55), the liquid overflows as schematically shown at (58). In Figure 1, the inlet and outlet of the liquid are shown in a vague manner, but this means that the space (
57) since the only thing that can be controlled is the overall temperature of the liquid in it, and thus the temperature of the roller circle. The annular space (57) can, for example, be provided with baffles to increase the velocity of the liquid and facilitate the transfer of energy between the roller U(a) and the cooling liquid.

Instead of a ring-shaped space, in the device according to the invention a device for spraying water into the hollow roller I can be provided. Similar to the embodiments described above, the temperature of the spray can be controlled by sampling the liquid collected within the roller with a sensor.

Information from the sensor force 1 is sent to the controller and actuator to increase or decrease the temperature of the spray (force) and spray as much as necessary for cooling. In any case, it is within the scope of the present invention to control the temperature of the roller by bringing the liquid into contact with the inner surface of the roller.

In the embodiment of FIG. 2, instead of contacting the tape uO) around one water-cooled large diameter roller u4J, an electron beam 16) generated by an electron beam generator u8) is used. A series of parallel rollers (26, 28°3
0, 32.34.36.38).

That is, the tape goes around the first roller (26), then parallel to the roller (26) but slightly below it in FIG. Go around No. 20-La (28) at . Roll this pattern (30, 32, 34, 36
, 38) is repeated.

After the tape uO) leaves the roller U8), it is transferred to the housing (2).
) and goes around the rollers (20) outside to the finishing station (not shown). Roller (26, 30, 34, 38)
are arranged in the first row, and rollers (28, 32, 36) are arranged in the second row.

The first row is closer to the electron beam generator u81. Since the vertical spacing between the first row of rollers is less than the diameter of the second row of rollers, substantially all of the adult heap is incident on the tape.

The # moving speed of the tape and the Hong-Hart rate of electrons are almost the same as in the example of actual performance in Figure 1. The diameter is roller U4
), but the rollers (26-38) are also water-cooled and made of copper or a suitably high atomic number material.

Here again, the electron beam that has penetrated the tape (10) K is bounced off by the rollers (26-38) and penetrates the tape again, increasing the effective electron beam dose for curing the tape coating.

Implementation of Figure 1 - Similar to ○, the roller (26
~38) A means for controlling the temperature is provided.

A coolant, such as water, is extracted from the internal force of the roller (to) as shown schematically at (60), and the sensor ωl)
This temperature information is sent to the controller (62) to determine whether the temperature is above or below the optimum temperature. This information is the actuator (63)
are sent to the taps (64, 65) to supply hot or cold liquid to the system (6B) via the respective lines (66, 67).

The terms and expressions used herein are for purposes of explanation and not limitation, and do not exclude other equivalent terms and expressions. It will be appreciated that various modifications may be made within the scope of the invention.

[Brief explanation of the drawing]

FIG. 1 is an elevational view showing a part of the first practical example of the present invention in cross section. FIG. 2 is a view of the fifth section of FIG. 10... Tape 14... Roller 16.
...electronic heat 24...housing 26.2
8, 30, 32, 34, 36.38... Intermediate viewing roller 50... Sensor 51... Controller 53.
54... Actuator 57... Ring-shaped coolant 9 space 61... Sensor 62... Controller 63... Actuator 64.65... Tap 52... Actuator

Claims (9)

[Claims] (1) A tape for passing the tape through the electron beam, comprising a device for generating an electron beam, at least one roller having a peripheral surface for supporting the tape in the electron beam, and means for controlling the temperature of the roller. An apparatus for curing a resin component on a moving tape, comprising a transfer device and a housing surrounding the electronic beam generator and the tape transfer device. (2) The tape transport device includes a plurality of rollers whose peripheral surfaces support the tape within the electron beam and onto which the electron beam is projected, the rollers being rotatably mounted parallel to each other, and the tape being positioned within the electron beam. 2. The device according to claim 1, wherein the device has a meandering circumference. (3) A plurality of rollers are arranged in two rows with respect to the electron beam generator, and the distance between the rollers in the row closer to the electron beam generator is smaller than the diameter of the rollers in the other row. The device according to item 2. (4) The apparatus according to claim 1 or 2, wherein the tape enters the tape transport device ζ in a horizontal direction and exits in a horizontal direction. (5) The device according to claim 1 or 2, wherein the tape transport device includes a material having an atomic number that is at least the same as that of copper. (6) The apparatus according to claim 1, wherein an electronic beam is projected onto the roller through a tape, and a portion of a force of 1 of the projected electronic beam is transmitted through the tape and reflected. (7) The device according to claim 1 or 2, wherein the rollers are made of copper or steel. (8) The device according to claim 1 or 2, wherein the means for controlling the temperature of the roller is to bring a liquid into contact with the inner surface of the roller. (9) The device according to claim 8, wherein the liquid is contained within a ring-shaped space defined by the inner surface of the roller. do) place the liquid adjacent to the inner surface of the roller, sample this liquid with a sensor, determine with the controller whether the temperature of the liquid is higher or lower than a preset value, and send that signal to the actuator. 3. Apparatus according to claim 1 or 2, characterized in that the temperature of the roller is characterized by adding heated or cooled liquid to the remaining liquid adjacent to the roller. Circle is in contact with a support roller whose inner surface is in contact with liquid,
Passing a tape with an uncured coating on its surface through an electron beam, measuring the temperature of the liquid with a sensor, and sending information on this temperature to a control device to adjust this temperature and a preset temperature. a method of curing resin on a moving tape, the control device transmitting a signal to an actuator to increase or decrease the temperature of the liquid.