JPS63259822A - Magnetic recording medium and its production - Google Patents

Abstract

PURPOSE:To prevent a degradation in output by use or preservation at a high temp. and an increase in off-track quantity by forming a magnetic layer on a flexible base, then subjecting the base molded to a use shape to a heat treatment while the base is fixed, thereby enhancing the thermal stability thereof and uniformizing the same in all bearings. CONSTITUTION:After the magnetic layer is formed on the flexible base, the base is molded to the use shape as a magnetic recording medium such as a circular cookie like, for example, floppy disk and this molding is fixed partially or over the entire part and is subjected to the heat treatment at 55-96 deg.C. Burst signals for alignment are written in all the tracks of such magnetic recording medium. The off-track quantity of the burst signals for alignment of this magnetic recording medium with respect to the track width is specified to <=4.0% when the above-mentioned recording medium is rested for 24hr at 60 deg.C, then 30hr at a room temp. The magnetic layer of a coating type formed by using hexagonal Ba ferrite as magnetic powder is effective and the flexible base essentially consisting of polyethylene terephthalate is more preferable.

Description

Detailed Description of the Invention (Field of Industrial Application) The present invention relates to a flexible magnetic recording medium, particularly a flexible magnetic recording medium in which a magnetic Pi layer is formed on a flexible polymer support such as polyester. .

(Prior art) In recent years, flexible supports such as floppy disks!
A large number of magnetic recording media in which a magnetic layer is formed on the magnetic layer are used because of their simplicity and high v1 performance.

Among these, floppy disks are particularly popular because they are convenient to carry, economical, and have a relatively large storage capacity.

However, since a magnetic layer is formed on a flexible support, often a polyester film,
During recording, storage, and reading, off-track may occur due to the high temperature of the atmosphere, and +I for reading may occur.
Problems such as outputting T raw output have been addressed.

Particularly recently, there has been a demand for devices with large recording densities (storage capacity), and this has been increasing. For example, a 3.5 inch float 6. In the past, there were many IBM disks (abbreviated as FT), but 2MB and 4MB.
B and Renyo Publishing have been developed.

In addition, in the past, needle-shaped magnetic powders mainly composed of γ-Fe20,,'5 were the most common, but in recent years, magnetic powders that can be perpendicularly magnetized, such as hexagonal barium ferrite, have been used for high volume h1. The magnetic recording medium used has also been developed.

In such a high-density magnetic recording medium, the off-track caused by the high temperature becomes even more noticeable. In order to reduce the occurrence of off-track due to high temperature, [A]
CB) A method of heat-treating only a flexible support to improve its thermal stability at high temperatures, thereby reducing the amount of off-track; A conventionally known method is to apply a coat of paint to a surface, calendar it, and then heat treat it.

(Problems to be Solved by the Invention) This invention has been proposed to reduce the amount of off-track generated in a magnetic recording medium in which a magnetic layer is formed on a flexible support due to high temperatures or high temperature differences. In the conventional techniques [A] and [B], the heat treatment is not done in the shape of the magnetic recording medium to be finally used (the direction in each magnetic recording medium is changed). Uniformity in thermal properties cannot be obtained in terms of thermal stability and thermal properties.In other words, by heat-treating a long shape, uniformity in thermal properties in all directions cannot be obtained as an individual medium. It is difficult to do so.

Furthermore, as proposed in JP-A-59-127233, the effect of heat treatment on a plurality of sheets piled up in the form of a sheet is greater than that on the individual medium (
It is excellent in terms of uniformity for sheets). However, by stacking multiple sheets, differences tend to occur between the individual sheets in terms of heat transfer uniformity, etc.

(1st step to solve the problem) In a magnetic recording medium in which a magnetic layer is formed on a flexible support I-, when used or stored at high temperatures, the output may decrease or the amount of off-track may increase. In order to solve the problem, various studies were carried out, but they were insufficient. After the magnetic layer has been formed, the magnetic recording medium is formed into a shape that is used as a magnetic recording medium at a point near the end of manufacturing the magnetic recording medium. It has been found that the above-mentioned problems can be solved by fixing the shape (making it difficult to shrink or expand) and heat-treating it.In other words, the present invention provides a magnetic layer on a flexible support. When a burst signal for alignment is written in all tracks of the magnetic recording medium, and the magnetic recording medium on which the signal has been written is left at 60°C for 24 hours, then at room temperature for 30 hours. , a magnetic recording medium with excellent thermal stability, characterized in that the amount of off-track in all tracks of the burst signal for alignment of the magnetic recording medium is 4.0% or less with respect to the track width, After forming a magnetic layer on a flexible support for making the magnetic recording medium, it is shaped into a shape to be used as a magnetic recording medium, and the shaped object is partially or completely fixed. 55~
This manufacturing method is characterized by heat treatment at tIq degrees of 96°C.

The present invention is particularly effective when the magnetic layer is a so-called coated type magnetic layer formed by applying a magnetic paint in which ferromagnetic powder is dispersed. Furthermore, it is particularly effective when the ferromagnetic powder used in the coating type is hexagonal barium ferrite powder, and the flexible support is made of polyethylene terephthalate (polyester-1 as a component), a film of the body. It is particularly effective when
The present invention is particularly effective for circular floppy disks. In the present invention, in the case of a circular floppy disk, the inner or outer circumference or the entire surface of the shoe key is fixed after punching the shoe key. The method is to fix 2 to 3 widths of the inner periphery (the outer periphery when viewed from center-to-center r-1) to other rigid parts with adhesive tape and heat treat them, and also to fix parts of the outer periphery that are not used for recording and playback. are fixed with adhesive tape in a width of 2 to 3 squares, or heat-treated while being strongly crimped with a goichibuko. Furthermore, there is a method in which both of the above methods are used in combination. Also, the outer periphery
There is a method in which the inner periphery (center distance [1) is also heat-treated while being restricted by another rigid member. The heat treatment time is not particularly limited, but may be selected from about 1 hour to 48 hours depending on the temperature. More preferable heat treatment 1 Ma degree is 60
~90°C.

(Function) In describing the function of the present invention, a circular floppy disk will be taken up as a magnetic recording medium, and the function will be described with respect to the floppy disk. With the shape used as a magnetic recording medium, i.e., a circular shoe key with a central circular amount [1], the location or part of the shoe key is fixed partially or completely and heated at 55 to 96°C.
The detailed mechanism by which the thermal stability of the floppy disk, which is independent of the thermal direction, is improved by heat treatment at a temperature of 1 - is not clear. However, since neither the treatment of the base film alone nor the lamination treatment of the footskies are sufficiently effective, in the present invention, heat treatment in a fixed position or part of the footskies partially or entirely is not effective. , the residual internal strain is evened out without free expansion or contraction, and the heat treatment temperature is higher than the actual usage temperature, making it stable in actual use.
That is, it can be said that a magnetic recording medium with an off-track of 4% or less of the alignment burst bow in all trunks after being left at 60° C. for 24 hours can be obtained.

(Example) Raw roll of biaxially stretched polyester film CF-
I), the material roll was heat-treated at 80°C for 24 hours (F-II), and the material roll was heat-treated at 90°C for 24 hours (F-III). Three types of polyester films were used. Fl?
Using three types of polyester films listed in J, a magnetic paint having the following composition classified with a sand mill was applied to the film using a gravure roller so that the thickness after drying was 2.0 μm. .

Next, the coated long objects were calendered and cured at different temperatures (as shown in Table 1). Next, decurl in the usual manner at 60"C, and
．． I punched it out into a 5-inch cutlet.

The punched cutlets were heat-treated using various methods at various temperatures and times (described in Table 1).

Each sample shoe was assembled in a conventional manner and placed in a cartridge to create a 3.5-inch floppy disk. Write the alignment burst signal 3 onto each floppy disk at room temperature, then keep all the floppy disks in an atmosphere of 60°C for 24 hours, then return to room temperature for 30 hours. After the elapsed time, measure the alignment burst signal for all tracks of each floppy disk, measure the off-track amount, and multiply the value obtained by dividing the maximum off-track amount of each floppy disk by the track width of 120μ of the floppy disk by 100. Table as the maximum off-track rate for each floppy disk.
Shown in ■.

The method of I-I will be explained below in the margin, but the kutuki is donut-shaped and has a circular gap [-1 part] in the center. refers to the innermost circumferential part of Kunki, that is, the part between the centers [the outer circumference when viewed from the first part].

Tree 1: The inner circumference of the kunoki is 3 mm wide, and the entire circumference is covered with adhesive tape, using two stainless steel (3 mm thick) discs.
1. A method of clamping and fixing from the first stage and heat treatment.

*2: 1-F with two stainless steel (3 mm thick) discs using adhesive tape over the entire circumference with 3 widths around the outer circumference of Kutsky.
A method of clamping and fixing and heat-treating.

*3: Place the shoe in a container (made of stainless steel with a chain-faced bottom) whose inner circumference is almost equal to the outer circumference of the shoe, and place it in the center from -1 point larger than the 11th circle between the centers of the shoe. A method in which a stainless steel cylinder with a diameter of 5 kg is placed and heat treated in that state.

(Effect of the invention) When manufacturing a magnetic recording medium, after the magnetic layer is formed on the flexible support 11, there is no heat treatment step, that is, after the magnetic layer is formed into a shape used as a magnetic recording medium, the shape is The thermal stability of the magnetic recording medium is made uniform in all directions by heat-treating the object while it is partially or completely fixed according to the J method. Therefore, even after storage and use at high temperatures, the amount of off-track is small.

Claims (8)

[Claims] (1) In a magnetic recording medium in which a magnetic layer is formed on a flexible support, an alignment burst signal is written on all tracks of the magnetic recording medium, and the magnetic recording medium on which the signal has been written is heated at 60°C for 24 hours. 3 hours, then at room temperature
The magnetic recording medium has excellent thermal dimensional stability, characterized in that the amount of off-track in all tracks of the burst signal for alignment of the magnetic recording medium is 4.0% or less with respect to the track width when left for 0 hours. magnetic recording medium. (2) The magnetic recording medium according to claim 1, wherein the magnetic layer is formed by applying a magnetic paint in which ferromagnetic powder is dispersed. (3) The magnetic recording medium according to claim 1, wherein the magnetic layer is formed by applying a magnetic paint in which hexagonal barium ferrite powder is dispersed. (4) The magnetic recording medium according to claim 1, wherein the flexible support is a film mainly composed of polyester containing polyethylene terephthalate as a main component. (5) The magnetic recording medium according to claim 1, wherein the magnetic recording medium is a circular floppy disk. (6) In a method for manufacturing a magnetic recording medium in which a magnetic layer is formed on a flexible support, after forming the magnetic layer, the shape to be used as a magnetic recording medium is partially or completely fixed. A method for manufacturing a magnetic recording medium, characterized by heat treatment at a temperature of 55 to 96°C. (7) The method for manufacturing a magnetic recording medium according to claim 6, wherein the magnetic recording medium has a circular shape. (8) The method for manufacturing a magnetic recording medium according to claim 6, wherein the magnetic recording medium is a floppy disk.