JP2572236B2 - Visible magnetic recording sheet - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a visible magnetic recording sheet that can repeatedly record information magnetically and displays the recorded information visually. Specifically, a display layer is formed by applying a layer of microcapsules containing magnetic fine particles that move by the action of a local magnetic field on the back surface of a transparent base material, and a magnetic recording layer is provided on the back surface of the display layer to form a magnetic layer. The magnetic particles of the microcapsules corresponding to the magnetic domains are moved by the write magnetism for the recording layer and the residual magnetism after removing the write magnetic field, thereby displaying the microcapsules in which the magnetic fine particles have moved and the microcapsules in which the magnetic fine particles have not moved. The present invention relates to a visible magnetic recording sheet in which the contents of magnetic recording are displayed so as to be visually recognizable by surface contrast.

The present applicant has disclosed in Japanese Patent Application No. 62-124371,
A magnetic recording layer is provided on the back surface of the display layer formed by coating microcapsules containing magnetic particles movably, and the magnetic particles are moved by a write magnetic field for the magnetic recording layer, and the magnetic particles are moved by the residual magnetism of the recording portion. We have proposed a visible magnetic recording sheet that retains the display of recorded contents by retaining the moved magnetic fine particles.

The visible magnetic recording sheet is formed by applying microcapsules filled with a suspension of flake-like magnetic fine particles (magnetic flakes) having high light reflectance and a fluid on the back surface of a transparent base material in layers to form a display layer. And a magnetic recording layer is formed on the back surface of the display layer, and the magnetic frame in the microcapsule reflects light incident on the microcapsule from the microcapsule to the base material side, or the microframe. The magnetic flakes in the microcapsules can be selectively oriented so as to diffuse into the capsule, the magnetic flakes in the microcapsules are oriented by the action of a write magnetic field on the magnetic recording layer, and the orientation state is changed by the residual magnetic force of the magnetic recording layer. It is intended to be retained.

However, in this prior art, first, since magnetic fine particles having a special shape and physical properties are used, it is difficult to obtain them and the cost is high. Secondly, the magnetic fine particles magnetized by the writing magnetic field receive the action of the residual magnetic field of the magnetic recording layer and are oriented along the lines of magnetic force in the microcapsule to display the recorded contents, but the response speed is slow. Third, while the magnetized magnetic particles are floating in a state of being oriented in the microcapsule, they tend to gradually aggregate in a lump due to the suction of different polarities, and therefore the contrast is reduced and the display is reduced. The content becomes unclear. And the like.

In view of the above, the present invention improves the combination of substances filled in microcapsules, and renews the display principle based on the write magnetic field on the magnetic recording layer and the residual magnetic force after writing, thereby obtaining materials. It is an object of the present invention to provide a visible magnetic recording sheet which can be manufactured at low cost, has an improved display response speed for magnetic recording, and has improved contrast.

Means for Solving the Problems In order to solve the above problems, in the present invention, a visible magnetic recording sheet, a transparent base material, magnetic fine particles, having a different color or light reflectance from the magnetic fine particles, and the specific gravity is higher than the magnetic fine particles A microcapsule filled with large non-magnetic fine particles, a surfactant and a solvent was formed on the back surface of the transparent substrate in a layered manner, and a magnetic recording layer provided on the back surface of the display layer. Surfactants and solvents are used to prevent agglomeration of the particles and to smooth the fluidity of the particles due to the difference in specific gravity or the action of a magnetic field.

When the transparent substrate side of the magnetic recording sheet on which nothing is recorded on the magnetic recording layer, that is, when the display surface side is viewed upward, the specific gravity of the non-magnetic fine particles is larger than that of the magnetic fine particles. Are settled on the magnetic recording layer side of the microcapsule, and the magnetic fine particles are gathered on the display surface side.
Therefore, the color of the magnetic fine particles is uniformly displayed on the display surface.

On the other hand, when arbitrary information is recorded on a part of the magnetic recording layer via the magnetic head, in the microcapsule corresponding to the recorded part, the magnetic fine particles are attracted in the direction of the magnetic recording layer by the write magnetic field. Receive strength. Since the magnetic fine particles and the non-magnetic fine particles are wrapped in a surfactant and dispersed in a solvent, the flow resistance is small, and the volume in the microcapsules is constant. The magnetic fine particles move toward the display surface in a reactive manner, and a smooth position exchange is performed between the two. Even when the write magnetic field is removed, the magnetic fine particles are held on the recording layer side and the non-magnetic fine particles are held on the display surface side due to the residual magnetism of the magnetic recording layer.

Therefore, a contrast occurs between the color of the magnetic fine particles of the microcapsules corresponding to the portion not recorded on the display surface and the color of the nonmagnetic fine particles of the microcapsule corresponding to the recorded portion, and information is displayed by the color of the nonmagnetic fine particles. Is done.

Next, an embodiment of the present invention will be described with reference to the drawings.

As shown in FIG. 1, a visible magnetic recording sheet according to the present invention has a transparent base material A on one surface which is a display surface of the sheet.
A display layer B is formed on the back surface of the base material A by coating a myriad of transparent microcapsules 1 very thinly and uniformly with a transparent binder 2, and the back surface of the sheet is formed on the back surface of the display layer. Is provided.

When the visible magnetic recording sheet is used as a magnetic recording paper, a substrate A having a thickness of, for example, 20 to 100 μm is used.
A μm thick one is used.

In the cavity of each microcapsule 1, as shown in FIG. 2, magnetic fine particles 3, non-magnetic fine particles 4, a surfactant 5 covering these fine particles, and a solvent 6 in which the fine particles are dispersed are mixed to form a fluid. It is full.

The non-magnetic fine particles 4 have a higher specific gravity than the magnetic fine particles 3,
Further, the color or the light reflectance is different from the magnetic fine particles 3. Such magnetic fine particles are, for example, ferromagnetic ferric oxide (Fe ₃ O
₄ ) As the non-magnetic fine particles, for example, white barium can be used according to the use of black iron oxide for the magnetic fine particles. However, for the non-magnetic fine particles, other known materials that satisfy the above two conditions that the specific gravity and the magnetic fine particles can be reliably identified can be used.

The surfactant 5 and the solvent 6 covering the magnetic fine particles 3 and the non-magnetic fine particles 4 are used to disperse the magnetic fine particles 3 and the non-magnetic fine particles 4 in the microcapsule 1 with high fluidity. Since the surfactant has magnetism and the same poles repel each other, the fine particles do not aggregate in the solvent and become a stable colloid solution. In order to improve the fluidity of the fine particles, the magnetic fine particles 3 have an average diameter of 100 to 1
Spherical or oval iron oxide of about 30 ° is used, and spherical or oval particles having an average diameter of about 3 μm are used as the non-magnetic fine particles 4 to increase the particle diameter ratio.

The diameter of the microcapsule 1 and the thickness of the binder 2 are set as large as possible so that the write magnetic field applied when magnetically recording information on the magnetic recording layer C reaches the magnetic fine particles 3 in the microcapsule. Desirably thin.
From this viewpoint, in the present invention, the display layer B and the magnetic recording layer C
The magnetic recording layer C is directly bonded to the microcapsule 1 and the binder 2 without interposing a seal film or the like between them, so that the magnetic recording layer approaches the magnetic fine particles in the microcapsule.

 Reference numeral 7 denotes a magnetic recording surface protection film.

The mixing ratio of the microcapsule 1 and the binder 2 is such that the bonding area of the binder 2 to the base material 2 can secure the necessary bonding force or holding force of the microcapsule, and one or more magnetic domains generated in the recording portion. It is desirable to set so that the distribution ratio in which the microcapsules exist can be obtained.

With the above configuration, in the microcapsule corresponding to the non-magnetized area of the magnetic recording layer C, the specific gravity of the non-magnetic fine particles is larger than that of the magnetic fine particles, and therefore, as shown in FIG. While it is settling in
The magnetic fine particles 3 are gathered on the display surface side.

Therefore, when the display surface of the visible magnetic recording sheet on which no information is recorded on the magnetic recording layer is viewed, the magnetic recording is seen through the gap between the color of the magnetic fine particles in the microcapsule and the microcapsule in the binder 2 over the entire surface. Only the color of the layer is visible, and there is no display.

On the other hand, when a write magnetic field is applied from the magnetic head to the magnetic recording layer and a part of the magnetic recording layer is magnetized, the magnetic fine particles 3 in the microcapsule corresponding to the magnetic domain are attracted to the magnetic force generated in the magnetic domain. Then, as shown in FIG. 4, the gap between the non-magnetic fine particles flows in the magnetic domain direction, so that the non-magnetic fine particles 4 existing on the magnetic recording layer side move to the display surface side. That is, the magnetic fine particles and the non-magnetic fine particles exchange positions. Non-magnetic fine particles 4 have an average diameter of 3 μm
On the other hand, the average diameter of the magnetic fine particles is 100 to 1
Since the diameter ratio is as small as about 50 °, when the magnetic fine particles 3 existing on the substrate A side of the microcapsule 1 are subjected to the action of the write magnetic field on the magnetic recording layer C, the non-magnetic fine particles 4 existing on the magnetic recording layer side Flows smoothly in the direction of the magnetic recording layer B without resistance.

Therefore, when the information in the magnetic recording layer is recorded, as shown in FIG. 5, the magnetic fine particles face the display surface side in the microcapsules corresponding to each magnetized area, and the magnetic fine particles face the display surface side in the microcapsules corresponding to the non-magnetized area. As a result of facing the display surface side, contrast occurs, and the recorded information is displayed in the color of the non-magnetic fine particles.

The display speed on the display surface for information recording is equal to the moving speed of the non-magnetic fine particles, that is, the replacement speed of the magnetic fine particles and the non-magnetic fine particles, but these fine particles are coated with a surfactant on the surface and dispersed in a solvent. It has a very high response speed because of its high fluidity. When the average diameter of the magnetic fine particles is smaller than the average diameter of the non-magnetic fine particles, there is an effect that the initial movement of the magnetic fine particles is fast, and then the flow and the position exchange are smoothly performed. When both particles are spherical or oval, the response speed is higher than in other shapes.

Furthermore, when the volume ratio of the magnetic fine particles to the non-magnetic fine particles is smaller than the former, a part of the non-magnetic fine particles in the non-magnetized area is visible from the display surface side, and the contrast with the information display part is reduced. Therefore, the display information may be unclear, but as in the preferred embodiment, when the volume ratio between the magnetic fine particles and the non-magnetic fine particles is almost equal or the former is larger than the latter, the non-magnetic fine particles in the non-magnetic area Is completely hidden by the magnetic fine particles, so that the contrast is improved and the display definition is increased.

Effects of the Invention As described above, according to the present invention, a visible magnetic recording sheet has a transparent substrate, magnetic fine particles, a color or light reflectance different from that of the magnetic fine particles, and a specific gravity higher than that of the magnetic fine particles. Although a display layer formed by applying a layer of microcapsules filled with non-magnetic fine particles, a surfactant and a solvent on the back surface of the transparent substrate, and a magnetic recording layer provided on the back surface of the display layer, Since the display principle is based on the exchange of positions between magnetic fine particles and non-magnetic fine particles by the action of a local magnetic field in the recording portion, both magnetic and non-magnetic fine particles can be spherical or oval, and these are mass-produced. Since it is easily and inexpensively available on the market, the visible magnetic recording sheet can be manufactured at low cost.

In addition, since the display of recorded information is based on the exchange of positions of the magnetic fine particles and the non-magnetic fine particles in the microcapsule by the local magnetic field, a stable and remarkable contrast is obtained as compared with the conventional technology that uses the orientation of the magnetic flakes as a display principle. can get.

Furthermore, the response speed depends on the displacement speed of the magnetic fine particles and the non-magnetic fine particles due to the action of the local magnetic field, but a sufficiently high fluidity can be obtained by the surfactant, the solvent and the shape of the fine particles. Indicates speed.

[Brief description of the drawings]

BRIEF DESCRIPTION OF THE DRAWINGS The drawings show an embodiment of the present invention. FIG. 1 is a partially enlarged sectional view, FIG. 2 is an enlarged sectional view showing only one microcapsule extracted, and FIGS. FIG. 3 is an enlarged sectional view of a main part for explaining a display principle, FIG. 3 shows a positional relationship between magnetic fine particles and non-magnetic fine particles in a microcapsule corresponding to a specific magnetization area, and FIG. 3 shows a similar positional relationship within a microcapsule. Fifth
The figure is an enlarged sectional view showing the information recording of the magnetic recording layer and the state of the fine particles in each microcapsule. A: substrate, B: display layer, C: magnetic recording layer, 1 ... microcapsule, 2 ... binder, 3 ... magnetic fine particles, 4 ... non-magnetic fine particles, 5 ... surfactant 6: solvent, 7: magnetic recording surface protective film.

Claims (4)

(57) [Claims] (A) a transparent base material, (b) magnetic fine particles, non-magnetic fine particles having a different color or light reflectance from the magnetic fine particles and having a specific gravity larger than that of the magnetic fine particles, a surfactant, and A visible magnetic recording sheet, comprising: a display layer formed by applying microcapsules filled with a solvent on the back surface of the substrate in a layered manner; and (c) a magnetic recording layer provided on the back surface of the display layer. 2. The visible magnetic recording according to claim 1, wherein the magnetic fine particles and the non-magnetic fine particles are spherical or oval, and the diameter of the magnetic fine particles is smaller than the diameter of the non-magnetic fine particles. Sheet. 3. The diameter of the microcapsules is 30 to 50 μm, the average diameter of the magnetic fine particles is about 100 to 150 °, the average diameter of the nonmagnetic fine particles is about 3 μm, and the thickness of the magnetic recording layer is 15 to 30 μm.
3. The visible magnetic recording sheet according to claim 2, wherein the thickness is approximately the same. 4. The method according to claim 1, wherein the volume ratio of the magnetic fine particles to the non-magnetic fine particles is substantially equal or the former is slightly larger than the latter. Visible magnetic recording sheet.