KR100733526B1 - Recording medium and production method therefor - Google Patents

Abstract

The recording medium 11 includes a medium body 12 that holds data. The first printed layer 15 having the first thickness and the second printed layer 16 having the second thickness larger than the first thickness are spread on the surface of the media body 12. On the surface of the medium main body 12, a print protection layer 18 is formed which covers the first and second print layers 15 and 16. The print protection layer 18 has an inclined surface 19 that is inclined with respect to the surface of the media body 12. When the relative moving speed of X [m / s] is set between the recording track and the header on the medium body 12, an inclination angle smaller than 0.49e ^-0.20X is provided between the inclined surface 19 and the surface of the medium body 12. Is set. When this inclination angle is set, the header can smoothly perturb the surface of the print protection layer 18. Collision of the header with the surface of the print protection layer 18 can be avoided. Good relative displacement is always achieved between the headers.

Recording media, print protection, thickness, covering, media body, collision, avoidance, relative displacement

Description

Recording medium and its manufacturing method {RECORDING MEDIUM AND PRODUCTION METHOD THEREFOR}

BACKGROUND OF THE INVENTION Field of the Invention The present invention relates to a recording medium having a medium body for holding data, a printing layer extending on the surface of the medium body, and a manufacturing method thereof.

In an optical disk called a compact disk (CD), printing of letters or graphics that display the contents of software stored on a CD, for example, is performed on the surface of the substrate. On the other hand, in the magneto-optical disk called a magneto-optical disk (MO disk) or a mini-disk (MD), the above-mentioned character or figure is not printed on the surface of a board | substrate. Since the current MO disk or MD is accommodated in the cartridge case and used, letters and figures are printed on the outer surface of the cartridge case.

By the way, in the magneto-optical disk of the magnetic field modulation recording method called MD, data is written in the magneto-optical recording layer while contacting or floating the magnetic head on the surface of the substrate. In such a magneto-optical disk, the magnetic field strength changes as the distance between the magneto-optical recording layer and the magnetic head changes. Based on the change in the magnetic field strength, data cannot be written normally in the magneto-optical recording layer. In addition, when the magnetic head collides with the level difference on the surface of the substrate, the magnetic head is damaged. Data cannot be written. Therefore, in a magnetic recording medium called a magneto-optical disk of the magnetic field modulation recording method, it is desired that there is no step on the surface of the substrate.

As mentioned above, in the magneto-optical disk called MD, printing is not performed on the surface of a board | substrate. In such a magneto-optical disk, only the unevenness | corrugation of the surface of a board | substrate is a guide groove about 100 nm formed in a board | substrate. Such unevenness does not affect the perturbation characteristics or the floating characteristics of the magnetic head. In the future, however, it is contemplated to mount the disk directly to the spindle motor without receiving it in the cartridge case. Moreover, also in the magnetic disk drive apparatus, the aspect which attaches and uses a removable magnetic disk to a spindle motor is considered. In such a case, it is necessary to print characters or figures on the surface of the substrate. In the magneto-optical disk which printed on the surface of a board | substrate, since a printed layer is thick, a level | step difference arises in the surface of a board | substrate. Based on this step, stable perturbation or stable injury of the magnetic head is prevented. Data cannot be written normally.

[Patent Document 1]

Japanese Patent Publication No. 2002-367250

[Patent Document 2]

Japanese Patent Laid-Open No. 2001-148138

<Start of invention>

This invention is made | formed in view of the said situation, and an object of this invention is to provide the recording medium which can always implement favorable relative displacement with a head.

In order to achieve the above object, according to the first invention, there is provided a medium body for holding data, a first printed layer spread over the surface of the medium body at a first thickness, and a surface of the medium body at a second thickness larger than the first thickness. There is provided a recording medium comprising a print protective layer having a second print layer spreading on the surface, and an inclined surface coated on the first and second print layers on the surface of the medium body and inclined with respect to the surface of the medium body. .

MEANS TO SOLVE THE PROBLEM This inventor discovered that the film thickness of the printed layer differed according to the kind of color in the printed layer colored by several types of color. It was confirmed that a step was generated at the boundary between colors based on the difference in film thickness. Irrespective of such a step, if the aforementioned inclined surface is established on the surface of the print protective layer, a good relative displacement can be realized between the head and the surface of the print protective layer. The head may perturb the surface of the print protective layer or may continue to rise from the surface of the print protective layer at a predetermined lift height. In either case, the collision of the head with the print protective layer can be reliably avoided. In addition, the surface of the recording medium can be decorated in a multicolored manner by the action of the first and second printing layers.

In such a recording medium, when the relative moving speed of X [m / s] is set between the recording track and the head on the medium main body, an inclination angle smaller than 0.49e ^-0.20X is set between the inclined surface and the surface of the medium main body. do. According to the verification of the present inventors, it was confirmed that when such an inclination angle is set, relative displacement is always satisfactorily realized between the head. This inclined surface may be lowered outward from the outline of the second printed layer. Similarly, the inclined surface may be lowered outward from the outline of the first printed layer.

The first and second printed layers may be formed adjacent to each other. In this case, the inclined surface may be formed on the boundary between the first and second printed layers. The medium body may include a magnetic recording film that spreads along the surface of the substrate. The substrate may be made of a material having transparency. Such a recording medium may be constituted, for example, as a magneto-optical recording medium.

At least the second printed layer may be drawn with a mixed color of two or more kinds of primary colors. When the inks and toners of primary colors are mixed, the film thickness of the printing layer increases in accordance with the mixing ratio. In this way, the second thickness can be set in the second printed layer by changing the mixing ratio of two or more kinds of primary colors.

In the production of the recording medium as described above, a step of preparing a media body having a printing layer colored in a plurality of colors on the surface of the substrate, and a resin material on the surface of the printing layer while rotating the media body at a first speed. A step of dropping the fluid of the step, rotating the medium body at a second speed greater than the first speed, and spreading the fluid of the resin material along the surface of the medium body based on the centrifugal force, and a third greater than the second speed. What is necessary is just to implement the process of rotating a medium main body at speed.

According to the manufacturing method as described above, the aforementioned inclined surface is formed on the surface of the fluid of the resin material. The predetermined angle of inclination may be set based on the adjustment of the rotation speed or the rotation time of the medium body. In such a manufacturing method, compared with the time to hold a 2nd speed, the time to hold a 3rd speed should just be set short.

According to the second invention, there is provided a medium body for holding data, a first printed layer spread over the surface of the medium body, and a second print spreading over the surface of the medium body with the same thickness as the first printed layer adjacent to the first printed layer. A layer is provided, and a printing protective layer which covers the first and second printing layers on the surface of the medium body is provided.

In such a recording medium, since the first and second printed layers have the same thickness, no step occurs at the boundary between the first and second printed layers. The surface of the print protective layer can be planarized. In this way, if a flat surface is established on the surface of the print protection layer, good relative displacement can be realized between the head and the surface of the print protection layer. The head may perturb the surface of the print protective layer or may continue to rise from the surface of the print protective layer at a predetermined lift height. In either case, the collision of the head with the print protective layer can be reliably avoided. In addition, the surface of the recording medium can be decorated in a multicolored manner by the action of the first and second printing layers. In such a recording medium, the boundary between the first and second printing layers may traverse the recording track defined on the medium body.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a plan view schematically showing the structure of an embodiment of the recording medium of the present invention, that is, a magneto-optical disk.

2 is a partially enlarged vertical sectional view of the magneto-optical disk according to the first embodiment of the present invention.

3 is an enlarged, partial vertical cross-sectional view of the magneto-optical disk according to any recording track.

4 is a partially enlarged vertical cross-sectional view of the magneto-optical disk showing the structure of the medium body;

Fig. 5 is a partially enlarged sectional view of a magneto-optical disk showing a scene in which magnetic information is written.

Fig. 6 is a partially enlarged cross-sectional view of a magneto-optical disk showing a scene in which a fluid of resin material is dropped onto the surface of the medium body.

Fig. 7 is a partially enlarged cross-sectional view of a magneto-optical disk showing a scene in which a resin material is spread on the surface of the medium body while rotating the medium body.

Fig. 8 is a partially enlarged cross-sectional view of a magneto-optical disk showing a scene in which a resin material is further spread on the surface of the medium body while rotating the medium body.

9 is a table showing verification results of a magneto-optical disk.

10 is a table showing verification results of a magneto-optical disk.

11 is a table showing verification results of a magneto-optical disk.

Fig. 12 is a graph showing the correlation between the relative movement speed X between the recording track and the magnetic head and the limit angle Y of the inclination angle α.

13 is an enlarged partial vertical cross-sectional view of the magneto-optical disk corresponding to FIG. 2 and according to one modification.

14 is an enlarged fragmentary vertical sectional view of a magneto-optical disk according to a second embodiment of the present invention.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described, referring an accompanying drawing.

1 schematically shows a recording medium, that is, a magneto-optical disc 11, according to the first embodiment of the present invention. Such a magneto-optical disk 11 is represented by, for example, a mini disk (MD) or a magneto optical (MO) disk.

The magneto-optical disk 11 has a medium main body 12 that holds data, that is, magnetic information. The medium body 12 is configured in a disk shape. Details of the media body 12 will be described later. The surface of the medium main body 12 is decorated with a decoration 13 based on printing. The ornament 13 is colored, for example, in plural kinds of colors. The decoration 13 includes a base printing layer 14 spreading on the surface of the medium body 12, a first printing layer 15 and a second printing layer 16 placed on the surface of the base printing layer 14. It is formed based on.

2 schematically shows the cross-sectional structure of the magneto-optical disk 11. The base printing layer 14 spreads with a uniform film thickness on the surface of the medium main body 12. For example, ultraviolet curable resin ink is used for the basic printing layer 14. The basic printed layer 14 may be drawn in white, for example.

UV curable resin ink is used for the first and second printed layers 15 and 16. As the ink, three primary colors such as cyan, magenta, and yellow may be used. In the first and second printed layers 15 and 16, various kinds of colors are realized based on the mixing of the primary colors. In general, the thicknesses of the first and second printed layers 15 and 16 are different for each kind of color. Here, the first printed layer 15 may be drawn in one kind of primary color, for example. In this way, the first thickness, that is, the minimum thickness, is defined in the first printed layer 15. At least the second printed layer 16 may be drawn in a mixed color of two or more kinds of primary colors. Here, the second thickness, that is, the maximum thickness larger than the first thickness in the second printed layer 16 is defined. A step 17 is formed around the second printed layer 16 with respect to the basic printed layer 14 and the first printed layer 15. Similarly, a step 17 is formed around the base printing layer 14 around the first printing layer 15.

The first and second printed layers 15 and 16 are covered with a print protective layer 18 on the surface of the medium body 12. For example, an ultraviolet curable resin may be used for the print protective layer 18. The surface of the print protective layer 18 reflects the step 17 described above. As a result, in the print protection layer 18, the inclined surface 19 which inclines with respect to the surface of the medium main body 12 is formed. The inclined surface 19 descends outward from the contour of the second printed layer 16. Similarly, the inclined surface 19 descends outward from the outline of the first printed layer 15. The inclined surface 19 is formed on the boundary between the first printed layer 15 and the second printed layer 16. Here, when the relative movement speed of X [m / s] is set between the recording track on the medium main body 12 and the magnetic head described later, the inclination angle α smaller than 0.49e ^-0.20X is set.

Here, a specific method of the inclination angle α will be briefly described. 3 shows an enlarged partial vertical cross section along any recording track. The upper end of the inclined surface 19 is connected to the upper surface 21. The lower end of the inclined surface 19 is connected to the lower surface 22. The first reference plane 23 is defined parallel to the media body 12, ie the surface of the substrate. The bottom surface 22 is enlarged in the first reference plane 23. The second reference plane 24 is defined parallel to the first reference plane 23. Top surface 21 is enlarged in second reference plane 24. That is, the distance between the 1st and 2nd reference planes 23 and 24 commensurate with the height measured from the lower end surface 22 to the upper end surface 21.

A first intermediate reference plane 25 is defined between the first and second reference planes 23, 24. The first intermediate reference plane 25 extends parallel to the first and second reference planes 23, 24. The first intermediate reference plane 25 is arranged equidistant from the first and second reference planes 23, 24.

A second intermediate reference plane 26 is defined between the first reference plane 23 and the first intermediate reference plane 25. The second intermediate reference plane 26 extends parallel to the first reference plane 23 and the first intermediate reference plane 25. The second intermediate reference plane 26 is disposed equidistant from the first reference plane 23 and the first intermediate reference plane 25.

Similarly, a third intermediate reference plane 27 is defined between the first intermediate reference plane 25 and the second reference plane 24. The third intermediate reference plane 27 extends parallel to the first intermediate reference plane 25 and the second reference plane 24. The third intermediate reference plane 27 is disposed equidistant from the first intermediate reference plane 25 and the second reference plane 24.

The second intermediate reference plane 23 and the inclined plane 19 intersect at the first intersection point 28. The third intermediate reference plane 27 and the inclined plane 19 intersect at the second intersection point 29. The first and second intersection points 28 and 29 are connected to each other by a straight line 31. The angle measured between the straight line 31 and the first intermediate reference surface 25 corresponds to the inclination angle α.

4 shows a cross-sectional structure of the media body 12. The medium body 12 has a substrate 32 as a support. The substrate 32 may be made of a material having light transmittance. For such a material, a synthetic resin such as polycarbonate, acrylic or polyolefin may be used. Grooves 32a having a groove shape are formed on the surface of the substrate 32. The groove 32a is formed in the spiral shape on the surface of the board | substrate 32, for example. The optical head is driven based on the guidance of the groove 32a. Lands 32b are formed between the grooves 32a. This land 32b constitutes a recording track.

The first dielectric layer 33 spreads over the surface of the substrate 32. For example, an SiN film may be used for the first dielectric layer 33. On the surface of the first dielectric layer 33, a recording magnetic film, that is, a magneto-optical recording layer 34, is placed. Magnetic information is recorded in the magneto-optical recording layer 34. For example, a TbFeCo film may be used for the magneto-optical recording layer 34.

The second dielectric layer 35 is placed on the surface of the magneto-optical recording layer 34. As the second dielectric layer 35, a SiN film may be used as in the first dielectric layer 33 described above. The light reflecting layer 36 is disposed on the surface of the second dielectric layer 35. For example, an Al film may be used for the light reflection layer 36. The protective layer 37 spreads on the surface of the light reflection layer 36. For example, an ultraviolet curable resin may be used for the protective layer 37.

Now, a scene in which magnetic information is written into the magneto-optical disk 11 is assumed. First, the magneto-optical disk 11 is rotationally driven based on a drive motor (not shown). As shown in FIG. 5, the magnetic head 38 is perturbed at the surface of the magneto-optical disk 11. On the other hand, the optical head 39 faces the rear surface of the magneto-optical disk 11. The magnetic head 38 and the optical head 39 are positioned on the same recording track at the front and back surfaces of the magneto-optical disk 11.

At this time, the magnetic head 38 applies a magnetic field toward the magneto-optical recording layer 34. At the same time, the optical head 39 irradiates the laser light 41 toward the magneto-optical recording layer 34. The temperature of the magneto-optical recording layer 34 rises due to the action of the laser light 41. Since the coercive force decreases in the magneto-optical recording layer 34 based on the temperature rise, the direction of magnetization is defined based on the magnetic field acting from the magnetic head 38. When the laser light 41 from the optical head 39 moves, the temperature decreases in the magneto-optical recording layer 34. Magnetization is fixed to the magneto-optical recording layer 34 in a predetermined direction. In this way, the magnetic information is written.

Next, a scene in which magnetic information is read from the magneto-optical disk 11 is assumed. First, as described above, the magneto-optical disk 11 is driven to rotate. The optical head 39 is positioned on a predetermined recording track on the rear surface of the magneto-optical disk 11. The laser light 41 of predetermined output is irradiated from the optical head 39 toward the magneto-optical disk 11. The output of the laser beam 41 is set lower than the above-described output at the time of writing. The irradiated laser light 41 passes through the magneto-optical recording layer 34. The transmitted laser light 41 reflects off the light reflection layer 36. The reflected laser light 41 passes through the magneto-optical recording layer 34 again. In the transmitted laser light 41, the polarization plane rotates based on the direction of magnetization recorded in the magneto-optical recording layer 34. The rotation of the polarization plane is converted into intensity of light and read by a photoelectric conversion element (not shown). In this way, the magnetic information is read.

In the magneto-optical disk 11 as described above, since the predetermined inclination angle α is set on the inclined surface 19, the magnetic head 38 can perturb the surface of the print protection layer 18 smoothly. Collision between the magnetic head 38 and the print protection layer 18 can be avoided. In the magneto-optical disk 11, a good relative displacement with the magnetic head 38 can be realized. Magnetic information can be reliably written in the magneto-optical recording layer 34.

Next, the manufacturing method of the magneto-optical disk 11 is demonstrated in detail. First, a disk-shaped substrate 32 is prepared. The substrate 32 is molded based on, for example, an injection molding method. Thereafter, the first dielectric layer 33, the magneto-optical recording layer 34, the second dielectric layer 35, and the light reflecting layer 36 are successively formed on the surface of the substrate 32. In formation, for example, a sputtering method is used. The substrate 32 is mounted to the sputtering apparatus. Here, a SiN film is used for the first dielectric layer 33. As the magneto-optical recording layer 34, a TbFeCo film is used. The SiN film is used for the second dielectric layer 35. An aluminum film is used for the light reflection layer 36.

Subsequently, a protective layer 37 is formed on the surface of the light reflection layer 36. In forming, for example, a spin coat method is used. Substrate 32 is mounted to a spin coater. Ultraviolet curable resin is dripped on the surface of the board | substrate 32. FIG. Dropping may be performed, for example, on the inner circumferential side of the substrate 32. Based on the rotation of the substrate 32, the ultraviolet curable resin is evenly spread on the surface of the substrate 32. The ultraviolet curable resin cures based on the irradiation of ultraviolet rays. In this way, the protective layer 37 is formed on the surface of the light reflection layer 36.

Thereafter, the base printing layer 14 is formed on the surface of the protective layer 37. Screen printing is performed in formation. Substrate 32 is mounted to a screen printing machine. Here, white ultraviolet curable resin ink is used, for example. Ink is applied to the surface of the protective layer 37. Thereafter, ultraviolet rays are irradiated toward the substrate 32. UV curable resin ink cures. In this way, the basic printing layer 14 is formed on the surface of the protective layer 37.

Subsequently, first and second printed layers 15 and 16 are formed on the surface of the basic printed layer 14. In forming, for example, offset printing is performed. Here, ultraviolet curable resin ink of three primary colors is used, for example. Primary colors and mixed inks are applied to the surface of the base printing layer 14. Thereafter, ultraviolet rays are irradiated toward the substrate 32. UV curable resin ink cures. In this way, the first printed layer 15 having the first thickness and the second printed layer 16 having the second thickness are formed. Such a thickness is set based, for example, on the mixing ratio of ink, the pigment used for ink, and an additive. In this way, the media main body 12 which holds the 1st and 2nd printing layers 15 and 16 on the surface of the board | substrate 32 is prepared. However, electrophotographic printing may be performed in the formation of the first and second printing layers 15 and 16.

Subsequently, a print protective layer 18 is formed on the surfaces of the first and second printed layers 15 and 16. In forming, for example, a spin coating method is used. The media body 12 is mounted to a spin coater. The media body 12 is caused to rotate over a predetermined time at a first speed. Here, the first speed is set to 10 rpm. At this time, as shown in FIG. 6, the fluid 42 of the resin material is dropped on the surfaces of the first and second printed layers 15 and 16. The dropping of the fluid may be performed on the inner circumferential side of the medium body 12. As the fluid 42 of the resin material, for example, a transparent ultraviolet curable resin may be used.

Thereafter, the medium body 12 is caused to rotate over a predetermined time at a second speed that is greater than the first speed. Here, the second speed is set to 500 rpm. In this way, as shown in FIG. 7, the fluid 42 of the resin material spreads along the surface of the medium body 12 based on the centrifugal force.

Subsequently, the media main body 12 is rotated over a predetermined time at a third speed which is larger than the second speed. Here, the third speed is set to 5000 rpm. As shown in FIG. 8, the fluid 42 of the resin material spreads further along the media body 12. In this case, the time for holding the third speed may be shorter than the time for holding the second speed. In this way, the print protection layer 18 is formed. On the surface of the printed protective layer 18, the inclined surface 19 is formed based on the step | step 17. As shown in FIG. In this way, the predetermined inclination-angle (alpha) mentioned above is set.

Next, the present inventor verified the correlation between the average film thickness of the print protective layer 18 and the inclination angle α. In the verification, the first to seventh embodiments were produced based on the above-mentioned manufacturing method. Here, the substrate 32 having a diameter of 120 mm was used. In each embodiment the print protective layer 18 was set to a different average film thickness. However, the average film thickness was calculated from the maximum thickness and the minimum thickness of the print protective layer 18. The inclination angle (alpha) at this time was measured. In the measurement, a stylus measuring instrument is used. As a result, it was confirmed that when the average film thickness of the print protective layer 18 increases, the inclination angle α decreases.

At the same time, the inventor verified the perturbation characteristics of the magnetic head. In the verification, the first to seventh embodiments described above were prepared. A relative moving speed X of 1.2 [m / s] was set between the recording track on the medium body 12 and the magnetic head. The magnetic head was perturbed at the surface of the print protective layer 18 based on the rotation of the media body 12. As a result, as shown in Fig. 9, when the inclination angle α was set to 0.35 degrees or less, it was confirmed that the magnetic head did not collide with the surface of the print protective layer 18. That is, it was confirmed that the magnetic head perturbed in the good state. On the other hand, when the inclination angle α was set larger than 0.35 degrees, it was confirmed that the magnetic head collides with the surface of the print protective layer 18. That is, it was confirmed that the magnetic head vibrates violently.

Next, the inventor changed the relative moving speed X of the recording track and the magnetic head to 2.4 [m / s]. As described above, the first to seventh embodiments were prepared. As a result, as shown in Fig. 10, when the inclination angle α was set to 0.23 degrees or less, it was confirmed that the magnetic head did not collide with the surface of the print protective layer 18. That is, it was confirmed that the magnetic head perturbed in the good state. On the other hand, when the inclination angle α was set to be larger than 0.23 degrees, it was confirmed that the magnetic head collides with the surface of the print protective layer 18. That is, it was confirmed that the magnetic head vibrates violently.

Next, the inventor changed the relative moving speed X of the recording track and the magnetic head to 4.8 [m / s]. As described above, the first to seventh embodiments were prepared. As a result, as shown in FIG. 11, when the inclination angle α was set to 0.14 degrees or less, it was confirmed that the magnetic head did not collide with the surface of the print protective layer 18. FIG. That is, it was confirmed that the magnetic head perturbed in the good state. On the other hand, when the inclination angle α was set to be larger than 0.14 degrees, it was confirmed that the magnetic head collides with the surface of the print protective layer 18. That is, it was confirmed that the magnetic head vibrates violently.

From the above verification, the present inventor derived a correlation between the relative movement speed X [m / s] of the recording track and the magnetic head and the inclination angle α. As shown in Fig. 12, it was confirmed that the inclination angle? Should be set small in inverse proportion to the magnitude of the relative moving speed X. In this way, a correlation between the relative movement speed X and the inclination angle α was derived. Correlation is defined by the following formula | equation as mentioned above.

α < ^{0.49e -20X}

In addition, as shown in FIG. 13, a third printed layer 43 may be further formed on the surface of the basic printed layer 14 in addition to the first and second printed layers 15 and 16. As for the 3rd printing layer 43, what is necessary is just to set the thickness between the 1st thickness of the 1st printing layer 15 and the 2nd thickness of the 2nd printing layer 16, for example. As the above-mentioned, the ultraviolet curable resin ink is used for the 3rd printing layer 43. As shown in FIG. The first to third printed layers 15, 16 and 43 spread at least over the entire recording area of the magneto-optical disk 11. However, the recording area is defined in the data writing area partitioned on the magneto-optical recording layer 34.

As described above, the step 17 is formed around the second printed layer 16 with respect to the first printed layer 15 or the third printed layer 43. Steps are formed around the third printed layer 43 with respect to the first printed layer 15. The surface of the print protective layer 18 reflects the step 17. As a result, in the print protection layer 18, the inclined surface 19 which inclines with respect to the surface of the medium main body 12 is formed. The inclined surface 19 descends outward from the contour of the second printed layer 16. Similarly, the inclined surface 19 descends outward from the outline of the third printed layer 43. On the inclined surface, as described above, when the relative moving speed of X [m / s] is set between the recording track on the medium main body 12 and the magnetic head described below, an inclination angle α smaller than 0.49e ^-0.20X is set. .

14 shows a cross-sectional structure of the magneto-optical disk 11 according to the second embodiment of the present invention. In the second embodiment, as shown in FIG. 14, the first and second printed layers 15 and 16 may be set to the same thickness. The first and second printed layers 15 and 16 are spread over at least the entire recording area of the magneto-optical disk 11. The first and second printed layers 15, 16 may be drawn in a mixed color of two or more kinds of primary colors, for example. At this time, for example, the thickness of the reference is set in the first printed layer 15. What is necessary is just to set the thickness of the 2nd printing layer 16 based on the thickness of this reference | standard. In setting the thickness, the mixing ratio of the ink may be adjusted. Here, the thicknesses of the first and second printed layers 15 and 16 are set equally based on the adjustment of the mixing ratio of the ink. In addition, the same code | symbol is attached | subjected to the structure and structure equivalent to embodiment mentioned above.

The second printed layer 16 is adjacent to the first printed layer 16. At this time, the boundary between the first and second printed layers 15 and 16 may traverse the recording track defined on the medium body 12. Since the first and second printed layers 15 and 16 have the same thickness, no step is formed at the boundary between the first and second printed layers 15 and 16. An inclined surface is not formed on the surface of the print protection layer 18. As a result, collision between the magnetic head and the print protection layer 18 can be reliably avoided. The magnetic head can smoothly perturb the surface of the print protection layer 18. In the magneto-optical disk 11, a good relative displacement with the magnetic head 38 can be realized. Magnetic information can be reliably written in the magneto-optical recording layer 34.

In addition, a lubricant may be added to the printed protective layer 18, for example. Such a lubricant may weaken the friction force on the surface of the print protection layer 18.

In the magneto-optical disk 11 as described above, the structure of the layer and the material used for each layer may be appropriately changed. It is not limited to embodiment mentioned above. In the magneto-optical disk 11, three or more printed layers from which thickness differs may be formed, for example. The printed layer may be formed directly on the surface of the protective layer 37. That is, the formation of the basic printing layer 14 may be omitted. In addition, the magneto-optical disk 11 may be formed in a card shape (square).

In addition, the magneto-optical disk 11 may be configured as a so-called concurrent ROM-RAM magneto-optical disk. In such a magneto-optical disk, RAM (random access memory) information can be written from time to time on a magnetic recording film formed on the surface of a substrate, similar to a general magneto-optical disk. In addition, the optical phase pit is previously partitioned on the surface of the substrate. ROM (read only memory) information is written based on the optical phase pit.

Claims (17)

A media body holding data, a first printed layer spreading on the surface of the media body at a first thickness, a second printing layer spreading on the surface of the media body at a second thickness greater than the first thickness, and a surface of the media body And a print protective layer coated on the first and second print layers and having an inclined surface descending from the second print layer toward the first print layer. The method of claim 1, When a relative moving speed of X [m / s] is set between the recording track and the head on the medium main body, an inclination angle smaller than 0.49e ^-0.20X is set between the inclined surface and the surface of the medium main body. Recording media. The method according to claim 1 or 2, And said inclined surface descends outward from the outline of the second printed layer. The method of claim 3, And said inclined surface descends outward from an outline of said first printed layer. The method according to claim 1 or 2, And the first and second printed layers are adjacent to each other. The method of claim 5, And the inclined surface is formed on the boundary of the first and second printed layers. The method according to claim 1 or 2, And the medium body includes a recording magnetic film that spreads along the surface of the substrate. The method of claim 7, wherein And the substrate is made of a material having light transmittance. The method according to claim 1 or 2, At least the second printed layer is drawn with a mixed color of two or more primary colors. A medium body holding data, a first printed layer spreading on the surface of the medium body, and a surface of the medium body having the same thickness as the first printed layer, which is drawn adjacent to the first printed layer in a different color from the first printed layer. And a print protective layer coated on the first and second print layers on the surface of the medium body. The method of claim 10, The boundary between the first and second printed layers crosses a recording track defined on the medium body. The method according to any one of claims 1, 2, 10 or 11, And the first and second printed layers are formed at least on the entire recording area of the main body of the medium. The method of claim 12, And the print protective layer is formed on at least the entire recording area of the medium body. The method according to any one of claims 1, 2, 10 or 11, And the first and second printed layers are formed on the basis of offset printing. The method according to any one of claims 1, 2, 10 or 11, And the first and second printed layers are formed on the basis of electrophotographic printing. Preparing a medium body having a print layer colored in a plurality of colors on the surface of the substrate; and dropping a fluid of a resin material forming a print protective layer on the surface of the print layer while rotating the medium body at a first speed. And rotating the medium body at a second speed greater than the first speed, and spreading the fluid of the resin material along the surface of the medium body based on the centrifugal force, and at a third speed greater than the second speed. And rotating the surface of the printing protective layer on the surface of the printing protective layer based on the rotation. The method of claim 16, The time for holding the third speed is shorter than the time for holding the second speed.

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