JPH02170073A - Magnetic sensor - Google Patents

Abstract

PURPOSE:To detect external magnetic field by sticking a ferromagnetic substance to the back surface of the sheet which has a microcapsule including liquid in which magnetic particles are dispersed and disturbing a visual pattern with the external magnetic field equal to or exceeding the coercive force of the ferromagnetic substance. CONSTITUTION:As to a plastic sheet 1, the slender or plate-like magnetic particles 4 dispersed in the liquid 5 are included in many microcapsules 3. The particles 4 are oriented in the thickness direction of the sheet 1 along a magnetic flux near a magnetic pole 10 on the surface of the ferromagnetic substance 2 and light transmittivity becomes large, then the visual pattern corresponding to the magnetized pattern is formed. Since the pattern is disturbed with the external magnetic field equal to or exceeding the coercive force of the substance 2, the presence or absence the external magnetic field is detected from the turbulance of the visual pattern. The density of the particles 4 in the liquid 5 is within 15-25% by volume so as to make contrast excellent. The polymer plasticizer such as vinyl chloride resin is used as the liquid 5 and the diameter of the microcapsule is within the range of 20-150mum.

Description

[Detailed Description of the Invention] [Field of Industrial Application] The present invention relates to a magnetic sensor that can visually detect an external magnetic field, and in particular detects an external magnetic field at a detection level corresponding to the coercive force of a ferromagnetic material attached. This invention relates to a magnetic sensor that can visually detect.

[Conventional technology]

Recently, with the spread of various magnetic recording media such as floppy disks and magnetic cards, the protection of magnetically recorded information has become an important issue. In general, magnetically recorded information can be destroyed by damage or bending of the recording medium itself, by exposure to high temperatures, and by exposure to an external magnetic field. In the first case, damage and bending can be seen visually and can be prevented by handling the recording medium itself carefully. In the second case, heat is perceivable by humans and can therefore be easily avoided. However, in the third case, the magnetic field cannot be directly sensed by humans, so it is possible that the recording medium is unknowingly exposed to a large external magnetic field.

Examples of devices for detecting external magnetic fields include Gauss meters.

[Problem to be solved by the invention]

However, since such magnetic measuring instruments are not easy to handle, they are not practical for monitoring external magnetic fields to protect recording media in daily work.

Therefore, an object of the present invention is to provide a magnetic sensor that can easily detect external magnetic fields.

[Means to solve the problem]

As a result of intensive research in view of the above objectives, the present inventors focused on the fact that magnetic particles dispersed in a liquid are oriented and moved by an external magnetic field, and found that if a pattern of magnetic particles is formed in advance, The present invention was completed based on the discovery that external magnetic fields can be easily detected by pattern disturbance.

That is, the first magnetic sensor of the present invention includes a sheet having a large number of microcapsules containing a liquid in which elongated or plate-shaped magnetic particles are dispersed, and a ferromagnetic material having a predetermined coercive force attached to the back surface of the sheet. The sheet includes:
By applying a magnetic field of a predetermined pattern, a visual pattern having the same shape as the pattern is formed, and when an external magnetic field that exceeds the coercive force of the ferromagnetic material is present, the visual pattern is disturbed. It is characterized by being able to visually detect external magnetic fields.

A second magnetic sensor of the present invention includes a sheet in which a space between a pair of substrates held at a constant interval is filled with a liquid in which magnetic particles are dispersed, and a sheet with a predetermined coercive force affixed to the back surface of the sheet. a ferromagnetic material having It is characterized by the fact that a visual pattern is disturbed, thereby making it possible to visually detect an external magnetic field.

The present invention will be explained in detail below.

A first magnetic sensor of the present invention includes a sheet 1 having a large number of microcapsules containing a liquid in which elongated or plate-shaped magnetic particles are dispersed, and a ferromagnetic material 2 having a predetermined coercive force attached to the back surface of the sheet 1. It consists of. This sheet 1 is the second
As shown in the figure, it is made of a plastic sheet having a large number of microcapsules 3, etc., and each microcapsule 3 is filled with a liquid 5 in which a large number of elongated or plate-shaped magnetic particles 4 are dispersed. There is.

The elongated or plate-shaped magnetic particles 4 need to be colloidal in order to be well dispersed in the liquid.

For this reason, the size of the magnetic particles 4 is generally about 50 to 300 A in length and 30 to 2 A in diameter in the case of an elongated shape.
Approximately 00 people. If the magnetic particles are larger than this, the dispersibility in the liquid 5 will be reduced, and if the magnetic particles are smaller than this, the visual change due to orientation or movement will be small. Further, in the case of a plate shape, the ratio of size to thickness is such that the difference in light transmittance due to orientation is sufficiently large.

In the first magnetic sensor, the magnetic particles 4 are oriented by the ferromagnetic material 2 . As shown in FIG. 1, a large number of magnetic poles are formed in a pattern on the surface of the ferromagnetic material 2. As shown in FIG.

A visual pattern is formed on the sheet 1 according to this magnetized pattern. The reason why a visual pattern is formed is that, as shown in FIG. 4, in the vicinity of the magnetic pole 10, the elongated magnetic particles 4 oriented along the magnetic flux are oriented in the thickness direction of the sheet 1, so that light cannot pass through. This is because although the light shielding rate is high, in other parts, the magnetic particles 4 are oriented horizontally, so the light shielding rate is high. As a result, when magnetized, a part (bright part) with high light transmittance is formed in the vicinity of the magnetic pole 10, and a part (dark part) with low light transmittance in the other part 11, resulting in a magnetized pattern. A corresponding visual pattern is formed.

This visual pattern is maintained by the coercive force of the ferromagnetic body 2, but in the presence of an external magnetic field greater than the coercive force of the ferromagnetic body 2, this pattern will be disturbed. Therefore,
The presence or absence of an external magnetic field can be detected by the disturbance of this visual pattern.

Therefore, in order to form a visual pattern of clear contrast, the magnetic particles 4 must be dispersed in the liquid 5 at a sufficiently high concentration. For the purposes of the present invention, the magnetic particles 4 are preferably about 10-30% by volume;
More preferably, it is about 15-25%.

As the liquid for dispersing the magnetic particles 4, US Pat. No. 44
Polar organic carriers such as those disclosed in No. 30239 can be used. Examples of such polar organic carriers include polymeric plasticizers such as vinyl chloride resins, diesters, triesters and polyesters of 06-C1□ saturated hydrocarbon acids, dioctyl phthalate and other dialkyl phthalates. There are phthalates, etc.

A large number of microcapsules 3 containing a liquid 5 in which magnetic particles 4 are dispersed are dispersed within the plastic sheet 1.

The size of each microcapsule 3 is 20 to 150 in diameter.
It is preferable that the thickness be on the order of μm. 20 microcapsules 3
If it is smaller than μm, the orientation of the magnetic particles 4 is insufficient;
Moreover, if the microcapsule 3 is larger than 150 μm,
The magnetic particles 4 tend to move within the microcapsules 3, causing visual pattern disturbance.

Note that such a sheet 1 may be created by any method. For example, a liquid 5 in which magnetic particles 4 are dispersed
It may be made by preparing a magnetic fluid consisting of in advance, polymerizing the resin in a finely dispersed state, and molding it into a sheet shape.

Further, the ferromagnetic material 2 can be formed by blending magnetic powder with a resin or the like so as to have a relatively small coercive force. Alternatively, it can be formed by forming a magnetic thin film and appropriately magnetizing it.

A visual pattern is formed in the magnetic sensor composed of the sheet 1 and the ferromagnetic material 2 by the following method.

First, an external magnetic field of a predetermined pattern is applied to this ferromagnetic material 2. As the external magnetic field source, a magnetizing device having a large number of magnetizing yokes in a predetermined pattern or a magnet magnetized in a predetermined pattern is used. Once a visual pattern is formed by magnetization, the pattern is retained even after magnetization due to the coercive force of the ferromagnetic material 2. The coercive force of the ferromagnetic material 2 can be set appropriately depending on the purpose, but for example, the strength of the harmful external magnetic field for floppy disks is about 500e, so the ferromagnetic material 2 is suitable for floppy disks. The coercive force of 500e may be set somewhat lower than 500e. For example, if the coercive force of the ferromagnetic material 2 is 300e, the visual pattern will not be disturbed even if there is an external magnetic field of less than 300e, but if there is an external magnetic field larger than that, the visual pattern will be disturbed and it may be dangerous. It can be seen that the condition is - Once the visual pattern is disturbed, it returns to its original state due to the coercive force of the ferromagnetic material 2 when the external magnetic field is removed.

FIG. 3 schematically shows a second magnetic sensor sheet of the invention. This magnetic sensor consists of a pair of sheet substrates 6, 6', and between both sheet substrates 6, 6' are a large number of columnar bodies 7. ... are provided with spaces 8 maintained at constant intervals. Note that instead of the columnar bodies 7, particles with a large diameter may be sandwiched between them. The space 8 is filled with a magnetic fluid containing the same magnetic particles 4 as described above.

In this magnetic sensor, since the magnetic fluid is not separated into small pieces by barriers, the magnetic particles 4 can move freely. Therefore, due to the ferromagnetic material having a predetermined pattern of magnetic poles, the magnetic particles 4 cause shading by moving.
It orients itself with it and forms a distinct visual pattern. When an external magnetic field exceeding the coercive force of the ferromagnetic material is applied to this visual pattern, pattern disturbance occurs.

Thereby, an external magnetic field can be easily detected similarly to the first magnetic sensor.

Although the magnetic sensor of the present invention has been described above, in the present invention, instead of using one of these magnetic sensors alone, a plurality of these magnetic sensors can be used in combination. In that case, by setting the coercive force of the ferromagnetic material 2 in each sensor in stages, the magnitude of the external magnetic field can be easily detected.

For example, if magnetic sensors containing a 200e ferromagnetic material, a 400e ferromagnetic material, and a 600e ferromagnetic material are used together, none of the visual patterns will be disturbed in the case of an external magnetic field of 100e; In the case of an external magnetic field of 300e, only the visual pattern of the magnetic sensor with 200e ferromagnetic material is disturbed, and with an external magnetic field of 500e, the visual pattern containing 200e ferromagnetic material and 400e ferromagnetic material, respectively. The target pattern is disrupted, and furthermore, for example, 10
Any external magnetic field greater than 0 lee will disrupt all visual patterns. In this way, the magnitude of the external magnetic field can be approximately detected.

Furthermore, in a single magnetic sensor, if the strength of each magnetic pole in the magnetization pattern of the ferromagnetic material 2 is provided with a stepwise distribution, the magnitude of the external magnetic field can be visually detected.

〔Example〕

The present invention will be explained in further detail by the following examples.

Example 1 Acicular ferrite particles were colloidized, dispersed in a polar organic solvent, and microencapsulated to create a sheet having the structure shown in FIG. 2. Further, a ferromagnetic sheet with a thickness of about 1 mm was prepared by mixing 60% by weight of ferrite powder with a coercive force of 8000e and 40% by weight of rubber, and was attached to the above sheet. This was magnetized in a striped pattern as shown in FIG. The coercive force of the obtained magnetized ferromagnetic material was 8600e. In the figure, 12 is a dark area, and 13 is a bright area. When a magnet of approximately 9000e was brought close to this, visual pattern disturbance was observed.

〔Effect of the invention〕

As explained in detail above, according to the magnetic sensor of the present invention, the presence or absence of an external magnetic field above a certain level can be easily detected by visual pattern disturbance.
External magnetic fields can be easily detected without the need for complicated equipment. By pasting such a magnetic sensor on the cover or case of a floppy disk, dangers caused by external magnetic fields can be detected in advance, and this is extremely useful for protecting magnetic recording.

[Brief explanation of the drawing]

FIG. 1 is a partially enlarged cross-sectional view showing a magnetic sensor of the present invention, FIG. 2 is a partially enlarged cross-sectional view of a sheet of a magnetic sensor according to an embodiment of the present invention, and FIG. FIG. 4 is a diagram schematically showing the principle of forming a visual pattern in the magnetic sensor of the present invention, and FIG. 5 is a partially enlarged sectional view of a sheet of a magnetic sensor according to an embodiment. FIG. 6 is a diagram showing a state in which the visual pattern of FIG. 5 is disturbed by an external magnetic field. 1...Plastic sheet 2...Ferromagnetic material, microcapsule, magnetic particles, liquid 3, 4, 5, 6, 6' 7, 8, 10, 11, 12, 13, sheet substrate columnar space Magnetic pole parts and other dark areas and bright areas Applicant

Claims (2)

[Claims] (1) It consists of a sheet having a large number of microcapsules containing a liquid in which elongated or plate-shaped magnetic particles are dispersed, and a ferromagnetic material having a predetermined coercive force attached to the back surface of the sheet, and the sheet has the following: By applying a magnetic field of a predetermined pattern, a visual pattern having the same shape as the pattern is formed, and when an external magnetic field that exceeds the coercive force of the ferromagnetic material is present, the visual pattern is disturbed. A magnetic sensor characterized by being able to visually detect an external magnetic field. (2) In the space between a pair of substrates held at a constant distance,
It consists of a sheet filled with a liquid in which magnetic particles are dispersed, and a ferromagnetic material with a predetermined coercive force attached to the back side of the sheet.By applying a magnetic field in a predetermined pattern, a visual field with the same shape as the pattern is created. A magnetic sensor characterized in that a visual pattern is formed, and when an external magnetic field exceeding the coercive force of the ferromagnetic material is present, the visual pattern is disturbed, thereby making it possible to visually detect the external magnetic field. .