KR20020015767A - Disk Substrate For Near Field Recording Using Fiber Reinforced Plastics - Google Patents

Abstract

PURPOSE: A near-field recording disk substrate using fiber reinforced plastic is provided to enable mass production of the disk substrate, reduce manufacturing time and cost, and improve mechanical strength of the disk substrate. CONSTITUTION: A molten resin material is injected into a mold of a stamper to injection-mold and compression-mold a near-field recording disk substrate(100). Fiber reinforced plastics(200) are used as the molten resin material of the disk substrate. Fibers(300) of the disk substrate using the fiber reinforced plastics are arranged radially in a manner that the interval between fibers becomes wide as it goes from the center of the disk substrate to the edge of the substrate.

Description

Disk Substrate For Near Field Recording Using Fiber Reinforced Plastics

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a disk substrate for near field recording using a fiber-reinforced polymer, and more particularly, to fabricating a disk substrate using a fiber reinforced polymer (FRP) material (Fibre ReinforcedPlastics hereinafter referred to as "FRP"). The present invention relates to a near-field recording disk substrate using a fiber-reinforced polymer (FRP) in which a disk substrate for near field recording (hereinafter referred to as "NFR") is suitable for mass production at low cost.

Generally known recording media for optical information storage are compact discs (CDs), digital video discs (DVDs), and hard disk drives (HDDs).

1 is a perspective view showing a conventional disk for storing information.

The CD, DVD and HDD are widely known as optical disc media, and the material for producing CD, DVD and HDD is made of polycarbonate, glass fiber, polymer (FRP) and aluminum, which are amorphous resins.

In the manufacturing process for manufacturing the disk substrate 1 of the CD, DVD and HDD, a material of polycarbonate, which is an amorphous resin, is placed in an input hopper installed in a conventional injection molding machine, and after heating the material, the molten resin material is sent to the stamper. The disk substrate 1 is manufactured by injection molding and compression molding.

The CD manufactured as described above is provided with a protective film formed from a photocurable resin to protect a reflective film made of an aluminum substrate, which is usually formed on a CD substrate, and the DVD and HDD are formed of two thin disk substrates 1. And a reflective film between the disk substrates (not shown).

The reflective film is provided on the surface of the disk substrate 1 on which the pits are formed for recording information, and the reflective film is usually formed by deposition of aluminum.

However, in the case of the metal substrate using the aluminum, the rigidity is very good, but the corrosion and weight is heavy, which causes the vibration of the disk substrate (1) at high speed rotation to increase the width of the vibration to hinder the noise and reliability of recording and storage There was this.

In addition, the technology introduced in Korean Patent Application No. 88-15710 filed with the Republic of Korea Patent Office is sputter-etched after sputtering in the recess formed in the composite substrate mixed with glass fiber in plastic Si 3 N₄ is applied to fill the recess formed on one side of the glass fiber.

The problem of the composite substrate in which glass fibers are mixed is that a recess is formed on the surface of the disk under the influence of a kind of surface tension, and the sputtering and sputter-etching processes are required to prevent the recess, and thus, the disk substrate (1) There was a disadvantage in that the production time and cost increase during production.

Accordingly, the present invention is to solve the conventional problems as described above, an object of the present invention, by using a fiber-reinforced polymer material as the material of the disk substrate when manufacturing the disk substrate, low-cost mass production due to the reduction of the production cost of the product To provide a near-field recording disk substrate using a fiber-reinforced polymer to enable the.

Another object of the present invention is to use a fiber-reinforced polymer instead of aluminum, which is a conventional metal, to reduce the very high modulus, high rigidity and weight of the product, and sputter etching process after sputtering for the surface roughness of the disk. By omitting, it is to provide a near-field recording disk substrate using a fiber-reinforced polymer that can reduce manufacturing time and cost.

Another object of the present invention is to form a fiber array of a disk substrate radially by using a fiber-reinforced polymer in a product, so as to improve the mechanical rigidity of the disk substrate to be rotated at high speed for near field recording using a fiber-reinforced polymer. It is to provide a disk substrate.

In order to achieve the above object, the near-field recording disk substrate using the fiber-reinforced polymer of the present invention is injected into a mold of a stamper to a near-field recording disk substrate produced by injection molding and compression molding using the stamper. The fiber-reinforced polymer is used as a molten resin material of the disc substrate for fabricating the disc substrate, and the fiber arrangement of the disc substrate using the fiber-reinforced polymer has a gap width between fibers from the center of the disc substrate to the outside of the disc substrate. It is characterized by consisting of radially widening.

1 is a perspective view showing a conventional disk substrate for information storage;

Figure 2 is a plan view showing the fiber arrangement of the disk substrate for a hard disk drive using a fiber-reinforced polymer according to an embodiment of the present invention.

Figure 3 is a side cross-sectional view showing a fiber arrangement direction of the disk substrate of Figure 2;

<Explanation of symbols for the main parts of the drawings>

100 disk substrate 200 fiber reinforced polymer (FRP)

300: fiber 400: sprue

Hereinafter, a near-field recording disk substrate using a fiber-reinforced polymer according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a plan view showing a fiber arrangement of a near field recording disk substrate using a fiber reinforced polymer according to an embodiment of the present invention, and FIG. 3 is a side cross-sectional view showing a fiber arrangement direction of the disk substrate of FIG.

The present invention will be described for the formation of the disk substrate 100 using a crystalline resin, that is, fiber-reinforced polymer (FRP) 200 in near field recording (NFR), which is being studied as a next generation computer information storage device.

First, an injection molding machine is required to manufacture the disk substrate 100 for near field recording (NFR), so that the injection molding machine uses the material of the fiber reinforced polymer (FRP) 200, as shown in FIGS. The injection hopper to be injected, a heating cylinder for melting the fiber reinforced polymer (FRP) 200 introduced into the injection hopper at a high temperature, and a fiber reinforced polymer (FRP) 200 melted by the heating cylinder And a stamper having a mold part for manufacturing the disk substrate 100 by injection molding and compression molding of the fiber-reinforced polymer (FRP) 200 by the resin injection part. (The injection molding machine not shown)

Into the resin injection unit, a fiber-reinforced polymer (FRP) 200 material is introduced into an input hopper, and a heating heater is installed around the screw to inject the molten fiber-reinforced polymer (FRP) 200 in turn. The heating cylinder provided and the nozzle which injects the fiber reinforced polymer (FRP) 200 melted in the said heating cylinder into the stamper are comprised. (Not shown).

Also, the fiber reinforced polymer (FRP) 200 is melted at a high temperature at the center of the NFR disk substrate 100 using the composite material of the fiber reinforced polymer (FRP) 200, and the molten fiber reinforced Sprue (400) is formed to guide the fiber-reinforced polymer (FRP) (200) during injection molding and compression molding after the polymer (FRP) 200 is put into the spamper.

As shown in FIG. 2, the fiber array 300 of the disk substrate 100 is radially formed with a wider gap between fibers toward the outside from the center of the disk as the sprue 400 is induced. .

The disk substrate 100 in which the fiber array 300 is radial may improve mechanical rigidity at high speed of rotation of the disk.

In addition, when using the composite material of the fiber reinforced polymer (FRP), such as Servo Mark and Land-Groove Stucture, etc. The pattern can be molded to the surface with irregularities.

Further, among the fiber materials, carbon fiber and Kevlar fiber have a coefficient of thermal expansion close to zero, and when such a fiber material is used, the size does not change due to temperature change, and the disk substrate 100 Good dimensional stability can be maintained.

In addition, the molten fiber-reinforced polymer (FRP) 200 is put into a stamper provided with a mold part, and then the disk substrate 100 is manufactured by injection molding and compression molding, and the manufactured disk substrate 100 is a fiber reinforced polymer. (FRP) (200) Due to the nature of the material, it can be processed without orthopedic processing.

As such, the disk substrate 100 for the near field recording (NFR) using the composite material of the fiber reinforced polymer (FRP) 200 has a drying time, a speed and type of screw, a temperature of the nozzle part, and a mold depending on the material injected through the nozzle. Depending on the process conditions such as temperature, manufacturing time, and injection pressure, the natural frequency (less than natural frequency, fmn), critical speed (less than or Ωcr), and elastic modulus (less than elastic modulus) of the disk substrate 100 are displayed. , E mark), vibration width (Af) can be changed.

Then, with reference to the equations such as natural frequency (fmn), critical speed (Ωcr), vibration width (Af) for the manufacturing method of the disk substrate 100 for the near-field recording (NFR) of the present invention having the configuration as described above More detailed description is as follows.

Here, the formula of the natural frequency (fmn) can be expressed by the following equation (1).

The circumference π is a constant, and the constant λmn according to the vibration mode shape of the disk substrate 100 is determined, and the thickness t of the disk substrate 100 and the disk substrate 100 are determined. The outer diameter Rο is a value that is also determined when the characteristics of the disk substrate 100 are determined.

The Poisson's ratio (ν), density (ρ), and elastic modulus (E) may be determined according to materials. That is, when the shape of the disk substrate 100 is determined, the natural frequency fmn may be increased by increasing the elastic modulus E or decreasing the Poisson's ratio ν or the density ρ.

In most cases, the Poisson's ratio (ν) or density (ρ) is not significantly different, so if the elastic modulus (E) is increased, the disk substrate 100 may have better vibration-related characteristics.

In addition, the formula of the critical speed (Ωcr) can be expressed by the following equation (2).

Here, as in Equation 1, the thickness t of the disk substrate 100, the outer diameter Rο of the disk substrate 100, and the inner diameter Ri of the disk substrate 100 are characteristics of the disk substrate 100. This value is also determined when it is determined, and the elastic modulus (E) and density (ρ) are values that can be determined by materials and the like. In other words, by increasing the elastic modulus E by Equation 2, the critical velocity Ωcr is increased, and it can be seen that it can have better operating characteristics.

In addition, the formula of the vibration width Af generated when the disk substrate 100 rotates may be expressed by Equation 3 below.

Here, the lower the outer diameter (Rο) and the rotational speed (Ω) of the disk substrate 100, and the higher the elastic modulus (E) and the thickness (t) of the disk substrate 100, the smaller the vibration width Af is the disk It can be seen that the vibration characteristics of the substrate 100 are improved.

That is, by increasing the elastic modulus through the fiber reinforced polymer (FRP) when the characteristics of the disk substrate 100 are determined by the equations (1), (2) and (3), the near-field recording disk substrate 100 having better vibration characteristics ) Can be produced.

On the other hand, as described above, the present invention is not limited to the above embodiments, and various modifications can be made without departing from the spirit and scope of the present invention.

As described above, according to the near-field recording disk substrate using the fiber-reinforced polymer according to the present invention,

By using fiber-reinforced polymer material as a disk material in manufacturing disk substrates, it is possible not only to mass-produce and supply low-cost products using low-cost materials, but also to have high rigidity and low mass compared to conventional metal alloy and glass disk substrates. It can reduce vibration, improve natural frequency, and improve critical speed. It can prevent corrosion unlike conventional metal alloy disc substrates. Also, discs using fiber materials have a coefficient of thermal expansion of fibers. Since the size of the disk board does not change due to the change of temperature, the dimensional stability can be improved. Also, since it is lighter than the basic alloy and glass disk board, it has many effects in terms of power consumption and load of the spindle motor. Also, the process of sputter etching after sputtering for the surface roughness of the disk is omitted. As a result, a desired level of surface roughness can be obtained at a fast time, thereby reducing the manufacturing time and cost of the product.

Claims (1)

In the near-field recording disk substrate which is injected into the mold of the stamper by injection of molten resin material and produced by injection molding and compression molding using the stamper, Fiber-reinforced polymer is used as a molten resin material of the disc substrate for manufacturing the disc substrate, and the fiber arrangement of the disc substrate using the fiber-reinforced polymer has a wider gap between fibers from the center of the disc substrate to the outside of the disc substrate. A disk substrate for recording near-field using fiber-reinforced polymers, characterized in that it is made radially.