The present invention relates to a method of manufacturing a transfer molding roll having a fine periodic structure, and a transfer molding roll having a fine periodic structure.
When an elongated film is continuously subjected to embossing using a hologram or an optical interference color, there has hitherto been used an embossing roll, for example, an embossing cylinder.
Such an embossing roll is manufactured as described below. First, a hologram pattern is generated on a photosensitive film through use of a laser. Then, a master is created with a peeling layer formed by chemical plating and electrocasting. The created master is reproduced, and the reproduced masters are arrayed to obtain an original plate. The original plate is bonded to a roll. A method of manufacturing such a master is disclosed, for example, in Patent Document 1.
In the above-mentioned related-art method of manufacturing an original plate by reproducing the master, there has been a problem in that a joint is generated when the masters are reproduced and are arrayed. In a product transferred from the original plate, a joint portion cannot be used, and hence the yield is deteriorated. Further, in the related-art method, a continuous elongated pattern cannot be formed without a joint.
The present invention has been made in view of the related-art problem, and an object of the present invention is to provide a method of manufacturing a transfer molding roll having a fine periodic structure and a transfer molding roll, with which a continuous elongated pattern can be seamlessly formed on an object to be transferred, for example, a film.
In order to solve the above-mentioned problem, a method of manufacturing a transfer molding roll having a fine periodic structure according to the present invention includes: preparing a cylindrical metal base material; irradiating an outer circumferential surface of the cylindrical metal base material with an ultrashort pulse laser; and forming a seamless circulating nano-periodic structure on the outer circumferential surface of the cylindrical metal base material through irradiation of the ultrashort pulse laser to form a seamless circulating pattern configured to generate an optical interference color with the seamless circulating nano-periodic structure.
It is preferred that the ultrashort pulse laser be a femtosecond laser or a picosecond laser, and it is more preferred that the ultrashort pulse laser be a femtosecond laser.
It is preferred that the cylindrical metal base material have a rotation axis in a longitudinal direction of the cylindrical metal base material, and that the outer circumferential surface of the cylindrical metal base material be irradiated with the ultrashort pulse laser while the cylindrical metal base material is rotated about the rotation axis.
It is preferred that the ultrashort pulse laser be emitted from a fine processing device including: a circular wavelength plate arranged in parallel to the outer circumferential surface of the cylindrical metal base material; and a rotation controller configured to rotate the circular wavelength plate in a circumferential direction of the circular wavelength plate.
A transfer molding roll having a fine periodic structure according to the present invention includes a seamless circulating pattern configured to generate an optical interference color with a seamless circulating nano-periodic structure formed on an outer circumferential surface of a cylindrical metal base material.
The present invention exhibits a significant effect of being able to provide the method of manufacturing a transfer molding roll having a fine periodic structure and the transfer molding roll, with which a continuous elongated pattern can be seamlessly formed on an object to be transferred, for example, a film.
Now, an embodiment of the present invention is described.
However, the embodiment is described only for illustrative purposes, and needless to say, the embodiment can be modified without departing from the technical concept of the present invention. Like members are denoted by like reference symbols.
In
The fine processing device 10 includes an ultrashort pulse laser oscillator 12 configured to oscillate an ultrashort pulse laser. As the ultrashort pulse laser oscillator 12, any known ultrashort pulse laser oscillator can be used as long as the ultrashort pulse laser oscillator is configured to oscillate a femtosecond laser or a picosecond laser, which is an ultrashort pulse laser.
The fine processing device 10 further includes an optical wavelength converter 14, an optical attenuator 16, a first mirror 18, a second mirror 20, a wavelength plate 22, and an objective lens 24. Laser light oscillated from the ultrashort pulse laser oscillator 12 passes through the optical wavelength converter 14, the optical attenuator 16, the first mirror 18, and the second mirror 20, and is polarized by the wavelength plate 22. The polarized laser light passes through the objective lens 24, and an outer circumferential surface 30 of a cylindrical metal base material 28 is irradiated with an ultrashort pulse laser 32. As the optical wavelength converter 14, the optical attenuator 16, the first mirror 18, the second mirror 20, the wavelength plate 22, and the objective lens 24, those which are known can be employed.
The cylindrical metal base material 28 has a rotation axis O in a longitudinal direction thereof. It is preferred that the outer circumferential surface 30 of the cylindrical metal base material 28 be irradiated with the ultrashort pulse laser while the cylindrical metal base material 28 is rotated about the rotation axis O.
As a material for the cylindrical metal base material 28, it is only required that the surface be made of metal. Therefore, any known metals can be employed. It is preferred that the cylindrical metal base material 28 be made of, for example, at least one kind of material selected from the group consisting of Ni, stainless steel, brass, Fe, Cr, Zn, Sn, Ti, Cu, and Al. The cylindrical metal base material 28 is made of at least one kind of material, and hence may be made of alloy.
As the wavelength plate 22, a ½ wavelength plate (½λ plate) can be suitably used, and in the configuration diagram of
Further, the wavelength plate 22 is provided with a rotation controller 26 configured to rotate the circular wavelength plate 22 in a circumferential direction P thereof, and hence the wavelength plate 22 can be rotated in the circumferential direction. Specifically, the fine processing device 10 includes the circular wavelength plate 22 arranged in parallel to the outer circumferential surface 30 of the cylindrical metal base material 28, and the rotation controller 26 configured to rotate the wavelength plate 22 in the circumferential direction P. With this, the laser light can be polarized in various directions. Therefore, when a seamless circulating nano-periodic structure is formed on the outer circumferential surface of the cylindrical metal base material, various nano-periodic structures can be formed. As the wavelength plate 22 and the rotation controller 26, a known ½ wavelength plate provided with a rotation controller can be used, for example.
In the present invention, through irradiation of a picosecond laser to a femtosecond laser with a low fluence, a nano-periodic structure serves as a diffraction grating, and an iridescent optical interference color like a hologram can be exhibited. Herein, the term “seamless” means that there is no joint between patterns.
In the nano-periodic structure, a fine groove is formed in a direction perpendicular to a plane of linearly polarized laser light. In order to change a direction of the groove in the nano-periodic structure, the direction can be changed by changing a wave front of polarization. When a roll surface is processed a plurality of times while the angle of a (½)λwavelength plate arranged in an optical system is changed, an embossing roll, which is a transfer molding roll in which a groove in each direction is arranged, can be manufactured.
A pattern 34a of (a) of
Further, for example, the pattern 34a of (a) of
Now, the present invention is described in more detail with Examples, but needless to say, Examples are only illustrative and not intended to be interpreted in a limited way.
A transfer molding roll having a fine periodic structure described below was manufactured through use of a laser of a femtosecond pulse.
An outer circumferential surface of a cylindrical metal base material was irradiated with a femtosecond laser through use of the fine processing device illustrated in the configuration diagram of
As a femtosecond laser oscillator, Satsuma HP2 manufactured by Amplitude Systems was used. Laser light having a wavelength of 515 nm, an irradiation energy of 0.21 J/cm2, a pulse width of 400 fsec, and a repetition frequency of 1 MHz was radiated to a roll surface while both ends of the roll having a diameter of 140 mm with the surface being plated with copper were held by rotatable chuck cones, and the roll was rotated by 28 turns per minute, to thereby form a seamless circulating nano-periodic structure having no joint. Thus, a transfer molding roll having a fine periodic structure was manufactured.
Next, a transfer molding roll having a fine periodic structure described below was manufactured through use of a laser of a picosecond pulse.
An outer circumferential surface of a cylindrical metal base material was irradiated with a picosecond laser through use of the fine processing device illustrated in the configuration diagram of
As a picosecond laser oscillator, Pharos-20 W-1 MHz manufactured by Light Conversion Ltd. was used. Laser light having a wavelength of 515 nm, an irradiation energy of 0.09 J/cm2, a pulse width variable from 400 fsec to 3 psec, and a repetition frequency of 600 kHz was radiated to a roll surface while both ends of the roll having a diameter of 140 mm with the surface being plated with chrome were held by rotatable chuck cones, and the roll was rotated by 17 turns per minute, to thereby form a seamless circulating nano-periodic structure having no joint. Thus, a transfer molding roll having a fine periodic structure was manufactured.
10: fine processing device, 12: ultrashort pulse laser oscillator, 14: optical wavelength converter, 16: optical attenuator, 18: first mirror, 20: second mirror, 22: wavelength plate, 24: objective lens, 26: rotation controller, 28: cylindrical metal base material, 30: outer circumferential surface of cylindrical metal base material, 32: ultrashort pulse laser, 34a, 34b, 34c: pattern production examples of seamless circulating pattern, 36: seamless circulating pattern of Example 1, 38: seamless circulating pattern of Example 2, O: rotation axis, P: circumferential direction, A: portion in which iridescent optical interference color was observed.
Number | Date | Country | Kind |
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2016-235226 | Dec 2016 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2017/039224 | 10/31/2017 | WO | 00 |