WO2017026031A1 - 球形ダイヤモンドおよびその製造方法 - Google Patents
球形ダイヤモンドおよびその製造方法 Download PDFInfo
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- WO2017026031A1 WO2017026031A1 PCT/JP2015/072639 JP2015072639W WO2017026031A1 WO 2017026031 A1 WO2017026031 A1 WO 2017026031A1 JP 2015072639 W JP2015072639 W JP 2015072639W WO 2017026031 A1 WO2017026031 A1 WO 2017026031A1
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- C—CHEMISTRY; METALLURGY
- C30—CRYSTAL GROWTH
- C30B—SINGLE-CRYSTAL GROWTH; UNIDIRECTIONAL SOLIDIFICATION OF EUTECTIC MATERIAL OR UNIDIRECTIONAL DEMIXING OF EUTECTOID MATERIAL; REFINING BY ZONE-MELTING OF MATERIAL; PRODUCTION OF A HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; SINGLE CRYSTALS OR HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; AFTER-TREATMENT OF SINGLE CRYSTALS OR A HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; APPARATUS THEREFOR
- C30B29/00—Single crystals or homogeneous polycrystalline material with defined structure characterised by the material or by their shape
- C30B29/02—Elements
- C30B29/04—Diamond
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B24—GRINDING; POLISHING
- B24B—MACHINES, DEVICES, OR PROCESSES FOR GRINDING OR POLISHING; DRESSING OR CONDITIONING OF ABRADING SURFACES; FEEDING OF GRINDING, POLISHING, OR LAPPING AGENTS
- B24B11/00—Machines or devices designed for grinding spherical surfaces or parts of spherical surfaces on work; Accessories therefor
- B24B11/02—Machines or devices designed for grinding spherical surfaces or parts of spherical surfaces on work; Accessories therefor for grinding balls
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B24—GRINDING; POLISHING
- B24B—MACHINES, DEVICES, OR PROCESSES FOR GRINDING OR POLISHING; DRESSING OR CONDITIONING OF ABRADING SURFACES; FEEDING OF GRINDING, POLISHING, OR LAPPING AGENTS
- B24B37/00—Lapping machines or devices; Accessories
- B24B37/02—Lapping machines or devices; Accessories designed for working surfaces of revolution
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B24—GRINDING; POLISHING
- B24B—MACHINES, DEVICES, OR PROCESSES FOR GRINDING OR POLISHING; DRESSING OR CONDITIONING OF ABRADING SURFACES; FEEDING OF GRINDING, POLISHING, OR LAPPING AGENTS
- B24B9/00—Machines or devices designed for grinding edges or bevels on work or for removing burrs; Accessories therefor
- B24B9/02—Machines or devices designed for grinding edges or bevels on work or for removing burrs; Accessories therefor characterised by a special design with respect to properties of materials specific to articles to be ground
- B24B9/06—Machines or devices designed for grinding edges or bevels on work or for removing burrs; Accessories therefor characterised by a special design with respect to properties of materials specific to articles to be ground of non-metallic inorganic material, e.g. stone, ceramics, porcelain
- B24B9/16—Machines or devices designed for grinding edges or bevels on work or for removing burrs; Accessories therefor characterised by a special design with respect to properties of materials specific to articles to be ground of non-metallic inorganic material, e.g. stone, ceramics, porcelain of diamonds; of jewels or the like; Diamond grinders' dops; Dop holders or tongs
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B30—PRESSES
- B30B—PRESSES IN GENERAL
- B30B11/00—Presses specially adapted for forming shaped articles from material in particulate or plastic state, e.g. briquetting presses, tabletting presses
- B30B11/004—Presses specially adapted for forming shaped articles from material in particulate or plastic state, e.g. briquetting presses, tabletting presses involving the use of very high pressures
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B30—PRESSES
- B30B—PRESSES IN GENERAL
- B30B3/00—Presses characterised by the use of rotary pressing members, e.g. rollers, rings, discs
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B30—PRESSES
- B30B—PRESSES IN GENERAL
- B30B3/00—Presses characterised by the use of rotary pressing members, e.g. rollers, rings, discs
- B30B3/005—Roll constructions
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B30—PRESSES
- B30B—PRESSES IN GENERAL
- B30B9/00—Presses specially adapted for particular purposes
- B30B9/28—Presses specially adapted for particular purposes for forming shaped articles
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- C—CHEMISTRY; METALLURGY
- C30—CRYSTAL GROWTH
- C30B—SINGLE-CRYSTAL GROWTH; UNIDIRECTIONAL SOLIDIFICATION OF EUTECTIC MATERIAL OR UNIDIRECTIONAL DEMIXING OF EUTECTOID MATERIAL; REFINING BY ZONE-MELTING OF MATERIAL; PRODUCTION OF A HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; SINGLE CRYSTALS OR HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; AFTER-TREATMENT OF SINGLE CRYSTALS OR A HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; APPARATUS THEREFOR
- C30B29/00—Single crystals or homogeneous polycrystalline material with defined structure characterised by the material or by their shape
- C30B29/60—Single crystals or homogeneous polycrystalline material with defined structure characterised by the material or by their shape characterised by shape
- C30B29/66—Crystals of complex geometrical shape, e.g. tubes, cylinders
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- C—CHEMISTRY; METALLURGY
- C30—CRYSTAL GROWTH
- C30B—SINGLE-CRYSTAL GROWTH; UNIDIRECTIONAL SOLIDIFICATION OF EUTECTIC MATERIAL OR UNIDIRECTIONAL DEMIXING OF EUTECTOID MATERIAL; REFINING BY ZONE-MELTING OF MATERIAL; PRODUCTION OF A HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; SINGLE CRYSTALS OR HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; AFTER-TREATMENT OF SINGLE CRYSTALS OR A HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; APPARATUS THEREFOR
- C30B33/00—After-treatment of single crystals or homogeneous polycrystalline material with defined structure
Definitions
- the present invention is a method of diamond processing for promoting and expanding the industrial application of artificial single crystal diamond, and the object is mass production of industrially valuable diamond sphere particles.
- this method can be applied to single crystal diamonds of any size, but in this specification, details of a true spherical processing method for micro single crystal diamond particles having a size of mm or less, in particular, ⁇ m size. Describe.
- the molding process of industrial materials uses physical properties inherent to materials such as thermoplasticity and photo-curing properties to give physical deformation or use external stimuli such as sublimation, vaporization, dissolution, melting, and chemical reactions.
- the object is achieved by forcibly performing operations such as cutting and polishing using a material harder than the material as a tool.
- crystal diamond not only accepts no physical deformation or phase change at all, but also has the highest hardness and Young's modulus on earth, so it cannot be applied with forced processing with a material harder than itself. , Processability is completely lacking. For this reason, in the application of diamond, there is an inconvenient restriction that “the shape at the time of generation is the final applied shape”. For this reason, the use of artificial single crystal diamond has been extremely limited.
- This is a method of self-wearing that is, a method in which the diamond is worn by exerting an action such as strong collision and pressing with the diamond.
- a disk embedded with diamond grit has been rotating at high speed for a long time, and the contact surface is worn by self-wearing by pressing the rough stone strongly against the rotating surface, and any reflection angle Polishing the surface to give (cut).
- This chamfering method can increase the collision energy between the diamond crystals by increasing the rotation speed of the disk, and it is efficient for the polishing craftsman to select and grind the crystal face that is easy to wear. Has been used for hundreds of years.
- Non-patent Document 1 Non-patent Document 1
- Spherical diamonds are rarely produced as natural diamonds, but are unknown as artificial single crystal diamonds and are expected to have a wide range of applications as will be described later. From an academic point of view, the diamond sphere is unknown and deviates from the definition of crystal form (polyhedron surrounded by crystal planes), so it can be said to be a new substance that does not fall within the category of ordinary crystals.
- spherical diamond From a practical standpoint, the greatest merit of spherical diamond is that the spheres do not aggregate. Since contact between spheres is point contact, van der Waals type suction interaction cannot be sufficiently obtained like surface contact and line contact, and self-aggregation is inhibited. This feature is expected to work very favorably in systems where self-aggregation is very prominent due to the large specific surface area, especially polyhedral nanodiamond particles. For example, spherical nanodiamonds will flow like a liquid.
- a suitable amount of diamond particles are filled between two concentric disks stacked horizontally, and the disks are pressed against each other by applying a load from above. It would be technically simplest to rotate the pair horizontally in opposite directions. However, it is necessary to attach a side wall along the circumference of the lower disk to prevent the diamond particles from falling to the outside of the tank along with the pressure rotation.
- the principle of the millstone is to collect the particles that fall down and return them to the self-wearing field.
- the inner wall of the spheroidizing device is expected to be severely worn because it is in direct contact with diamond particles that rotate and roll at high speed and is subjected to strong sliding stress.
- an iron material such as SUS reacts with the surface of the diamond particles to produce iron carbide and contaminates the diamond. Therefore, the inner wall must be lined beforehand with a CVD diamond film or the like.
- the lining as described below, since the homoepitaxial CVD diamond thin film manufacturing method is progressing, it is not impossible to implement, but technically still becomes a big barrier, so in the preliminary experiment in the present invention. For the time being, implementation will be omitted.
- the raw material of spherical diamond is single-crystal artificial diamond particles, and the shape is generally irregular polyhedron, but since artificial diamond crystals are originally equiaxed cubic system, the sphericity is quite high from the beginning, originally spherical It can be said that it is a material suitable for conversion.
- the production base of micro diamond has recently moved from the United States and Europe to China, and the production cost has been reduced by a factor of 20.
- the market for polyhedral micro diamond particles has not grown correspondingly. It is in an excessive situation and is in an advantageous situation for users as an industrial material. In the present invention, imported microdiamond from China was used.
- spheroidizing device a diamond spheroidizing device (hereinafter abbreviated as spheroidizing device) and repeated trial run, improvement, redesign, trial run retry ...
- a plan was made to improve performance and reach a practical spheroidizer.
- a wear tank with a mortar-shaped lid with two circular plates stacked horizontally was prototyped.
- the principle of the stone spheroid spheroidizing device is shown in FIG. 1, but the circular side wall is stretched vertically along the circumference of the lower disk, and the diameter of the upper disk is slightly smaller than that of the lower disk. Designed to prevent particle dissipation.
- a cylinder with a bottom surface and an inscribed disk were cut out separately from a thick SUS material using a lathe to form a wear tank and an upper lid, respectively.
- a commercially available electric brush (left in Fig. 2) was used for functions such as pressurization, rotation, and horizontal holding.
- the round rotator was removed, the wear tank was attached, and the upper lid was hung using the ink scumming function (center of FIG. 2).
- a simple fine adjustment mechanism for the position of the upper disk was attached to make the second machine (right of FIG. 2).
- a pressurizing method and a rolling method can be easily devised, it is not necessarily limited to the method described above.
- Heating or cooling It is desirable to heat at least 100 to 300 ° C. in order to promote CC bond cleavage of the diamond surface. However, in order to keep the temperature of various sensors, motors, etc. that will be attached later close to room temperature, it is desirable to limit the heating area to the wear tank / top cover. For this purpose, it is necessary to examine the latter material. As will be described below, the heating / cooling portion is lined with a polycrystalline diamond thin film, so that it has a precondition that it has good bondability with a diamond crystal growth nucleus (described later) in addition to heat resistance. Since the self-wearing method was unexpectedly powerful and efficient, we will reconsider whether or not to install a heating and cooling device after the design of the spheroidizing device has been decided.
- the cooling operation refers to the spheroidizing device in which the diamond particle self-wearing space is cooled to a temperature below room temperature, for example, ⁇ 70 ° C., for example, to form a diamond sphere.
- room temperature for example, ⁇ 70 ° C.
- the heating / cooling method can be easily devised, it is not necessarily limited to the method described above.
- Diamond Lining Fortunately, technology has been developed to produce high-quality polycrystalline diamond ultra-thin films using 3 nm diamond dispersed particles, which have been exclusively produced by our company in recent years, as homoepitaxial crystal growth nuclei of CVD diamond thin films. It's getting on. Since a polycrystalline diamond thin film having a Young's modulus comparable to that of natural diamond has already been successfully synthesized (Non-Patent Documents 2 and 3), the Williams method will eventually be adopted. In addition, since other lining methods can be devised, the method is not necessarily limited to the method described above.
- Non-Patent Document 2 Williams, O. A. et al. Size dependent reactivity of diamond particles, ACS Nano, 2010, 4, 4824-4830.
- Non-Patent Document 3 Williams, O. A. et al. High Young's modulus in ultrathin nanocrystalline diamond, Chem. Phys. Lett, 2010, 495, 84-89.
- micro diamond MMP made in China had a nominal size of 22-36 ⁇ m, a measured Heywood diameter of 29.15 (5.65) ⁇ m, and a circularity factor of 0.78 (0.10) (the standard deviation is the parenthesis, the total number of samples is 119).
- the microdiamond used this time contains coarse particles with a very large number of lattice defects in a certain proportion, and the coarse particles have voids inside the crystal, so the particle size is larger than the excellent crystal with few defects, Specific gravity is considered to be small. If you look closely at the particle size distribution ⁇ (upper part of FIG. 5) of the commercially available microdiamond before processing, there is a small large particle peak centering on the particle size of 40 ⁇ m, and the particle size distribution curve is generally swollen on the right side. In this batch, assuming that large particles of 37.5 ⁇ m or larger are coarse particles, the number-based fraction is 9.32%. Since HTHP synthetic microdiagrams complete crystal growth in an extremely short time, the possibility of containing such a large amount of coarse particles has not been pointed out until now, but it cannot be denied.
- the self-wearing spheronization process of diamond particles can be made more efficient and spherical diamond can be mass-produced, it will be a much more useful industrial material compared to currently produced imperfect polyhedral artificial diamonds.
- Spherical diamond is not easily cleaved because the crystal face is not exposed entirely.
- the contact area of the sphere is small, it is expected that the sphere is not easily worn. Since the contact between the spherical particles is a point contact with a very small area, self-aggregation hardly occurs. This effect is considered to be noticeable for nanodiamonds. Since the method according to the present invention can be applied to any size artificial diamond in principle, the range of application is expanded when an mm size artificial diamond can be made spherical.
- the present invention can be applied to replacement of a ball of a steel ball bearing, a ball-type lens, an artificial jewel, a tip ball of a ballpoint pen, a spherical semiconductor, and the like (Non-Patent Document 5).
- the optical lenses required for night-time spectacles and telescopes with built-in infrared sensors are not considered to be superior to spherical diamonds, so they are expected to be widely used for military or night-drive spectacles.
- Non-patent document 5 Junji Shibata “Hall of the Sphere”, Gihodo Publishing, 2011, 166 pages.
- the original object of the present invention is to produce true spherical nanodiamond using true spherical single crystal micro diamond as Attrition milling Attritter, and use the latter as “roller” in nano roller lubrication (Patent Documents 1 and 2). That is.
- roller lubrication is expected to correct the greatest “necessary evil” in the modern industry, which has so far used almost no lubricant as the only lubricant.
- superlubrication with virtually zero friction coefficient is possible, resulting in a significant reduction in fuel consumption and a significant reduction in carbon dioxide generation. Is expected to help reduce global warming.
- Patent Document 1 “Nano Koro Lubricating” Eiji Osawa, Masayuki Mori, translation date March 1, 2013, application number PCT ⁇ JP2010 / 065671, claim of priority: WO / 2012/029191, published patent 2013-538274 Announced on October 10, 2013.
- Patent Document 2 “Nanospacer lubrication,” International Application No .: PCT / JP2010 / 065671, International Filing Date: 03.09.2010, Priority Date: 03.09.2010, Publication No: WO / 2012/029191, Publication Date: 2012.03. 08.
- the basic concept figure of a pressure rolling self-wear apparatus The diamond particles are sandwiched between two hard concentric discs, and the upper and lower discs are rotated in opposite directions while pressing the particles from above to bring the particles into strong contact, thereby rolling all the particles simultaneously.
- Left A commercially available electric brush, rotating a cylinder with water, rotating the ink from above, pressing the ink vertically into the ink brush, fixing it by screwing from the side, and automatically applying ink Polish.
- Center No. 1 spheronizer.
- a SUS304 bottomed cylindrical tank with an inner diameter of 103 mm, a depth of 30 mm, and a thickness of 6 mm is attached to the bowl rotating mechanism and rotated at a speed of about 30 rpm.
- microdiamond powder About 20 g of microdiamond powder is put into a cylindrical tank, and a SUS304 lid with a diameter of 100 mm, a thickness of 5 mm, and a weight of 620 g is inserted into the cylindrical tank from the top, and pressurization is performed with its own weight (FIG. 4).
- Example 4 the digital micrograph of the micro diamond particle which received flattening.
- micro diamond powder was taken out from several places in the center of the wear tank and observed using a digital microscope (Tokyo HIROX, KH3000 type). There was no change except for a slight darkening, and it was unclear whether it was close to a sphere. However, 119 particles that do not overlap or contact other particles within the field of view of the digital microscope are selected, and the Heywood diameter and circularity coefficient are calculated using commercially available particle image analysis software (MacView 4th edition, manufactured by Tokyo Mountaintech). As a result of calculation and drawing a histogram regarding the distribution of both, compared with before processing, a distinct difference appeared (FIGS. 5 and 6).
- Example 2 Using the No. 2 spheroidizing device, the experiment was repeated for a long time under the same conditions as in Example 1 with the aim of realizing a high circularity coefficient. In some cases, the rotation continued for several hours while making a squeaking noise. When the diamond was removed, the black color became stronger, and it was clear that the SUS inner wall surface was partially scraped and mixed. Looking at the digital micrograph, a large amount of micro diamond fragments were mixed (FIG. 7).
- Example 2 As in Example 1, as a result of examining the distribution of Heywood diameter for 177 specimens, about 30% of the whole was crushed, and the fragment peak was centered at a diameter of 14 ⁇ m and was roughly divided into two equal parts. Is the main pulverization pattern (FIG. 8). The peak positions of the whole unground particles are not changed as compared with those before the treatment and are not worn. Interestingly, the circularity coefficient was 0.78 (0.07), the same value as before. This means that bisection grinding does not affect the average circularity.
- Example 4 The experimental results that gave particularly interesting results along with Example 1 are taken up here. After the fine adjustment of the parallel arrangement of the wear tank and the inner wall of the upper lid, when operated continuously for 5 days under the same conditions as in Example 1, the strange result that the average particle diameter slightly increases and the average circularity decreases slightly. was gotten. Furthermore, when the diamond particles after the treatment were observed with a digital microscope, it was mysterious that the particle diameter increased to nearly 50 ⁇ m, and the particles that looked plate-like were observed several times (FIG. 9). The interpretation of the results of Example 4 was described in detail in (Specific Presentation of Invention).
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Abstract
Description
上に述べた考察に基づいて、ダイヤモンド球形化装置(以下球形化装置と略)を設計し、試運転、改良、再設計、試運転再試行・・・を繰り返して、性能を向上し、実用的な球形化装置に到達する計画を立て、まず始めに円板を2枚水平に重ねた石臼型蓋付摩耗槽を試作した。石臼型球形化装置の原理を図1に示したが、下円板の円周に沿って円形側壁を垂直に張り巡らせ、上円板の直径を、下円板より僅かに小さくして、ダイヤモンド粒子の散逸を防ぐように設計した。実際には厚いSUS素材から、旋盤を使って底面付き円筒と、内接円板を別々に切り出して、それぞれ摩耗槽および上蓋とした。
なお、他にも加圧方法や転動方法は容易に考案することが出来るので、必ずしも上に述べた方法に限定するものではない。
ダイヤモンド表面部のC-C結合開裂を促進するためには、少なくとも100~300℃に加熱することが望ましい。しかし、後に取り付けを予定している各種センサーやモーターなどの温度を室温近くに保つためには、加熱領域を摩耗槽・上蓋に限定することが望ましい。そのためには後者の材質を吟味しておくことが必要である。加熱冷却部分は、下で述べるように内側を多結晶ダイヤモンド薄膜で内張りするので、耐熱性以外にダイヤモンド結晶成長核(後述)との結合性の良いことが前提条件となる。
自己摩耗方式が予想外に強力で効率が良いことが解ったので、加熱冷却装置を取り付けるかどうかは球形化装置のデザインが決まってから、再考する。ただし、mmあるいはcm大のダイヤモンドを球形化する場合には、摩耗量も増えるので、加熱する必要があると考えられる。
また、冷却操作とは、上記球形化装置の内、ダイヤモンド粒子の自己摩耗処理を行う空間を、必要に応じて、同上空間を室温以下の温度、例えば-70℃に冷却してダイヤモンド球形化を減速する処理を謂う。
なお、他にも加熱冷却方法は容易に考案することが出来るので、必ずしも上に述べた方法に限定するものではない。
幸運なことに、近年当社で独占的に生産している3nmダイヤモンド分散粒子を、CVDダイヤモンド薄膜のホモエピタキシャル結晶成長核に用いて、高品質多結晶ダイヤモンド超薄膜を製造する技術が進行しつつある。すでに天然ダイヤモンドと同等程度のヤング率をもつ多結晶ダイヤ薄膜の合成に成功している(非特許文献2、3)ので、最終的には、Williams法を採用する予定である。
なお、他にも内張り方法は考案することが出来るので、必ずしも上に述べた方法に限定するものではない。
(非特許文献3)Williams, O. A. et al. High Young’s modulus in ultrathin nanocrystalline diamond, Chem. Phys. Lett, 2010, 495, 84-89.
ここでは、第2号球形化装置(図2右と図4)を用いて、約10回の予備実験を行った中から、4例を選んで説明する。実験操作の詳細に関しては、実施例1~4に記述した。
粗悪粒子の板状変形が目立つような長時間処理においても、格子欠陥の少ない優良粒子の間の自己摩耗は進行し、その結果として優良粒子に限ると円形度が向上している筈であるが、粗悪板状粒子の増加に妨げられて、全体の平均円形度は向上しなかったと解釈することができる。
(1)加圧転動自己摩耗におけるダイヤモンド粒子間の衝突は予想外に強く、負荷、回転速度、摩耗時間などの条件が適切であれば、短時間で球形化を達成できることを示唆する結果が得られた。
(2)ただし、多くの要因の水準を適切に選択しないと、ダイヤモンド粒子の劈開、融合が顕著に起きたり、あるいは何も起きなかったりと様々な障害が起きる。
(3)従って、摩耗装置の設計・製作に当たっては、摩耗室の回転速度、水平保持などに関して高い精度が要求されるので、各種計測器を備え付けることが必要である。
(4)高い円形度係数を達成するためには、とくに負荷を精密に調整することが求められる。ダイヤモンド粒子の大きさに応じて、最適条件を適切に調節することが重要である。
(5)使用する人工単結晶ダイヤモンド粒子の品質に対しても、厳しい条件を課すべきであろう。特に、平均値よりも大きな直径と、異常に低い円形度をもつ粒子が混入していないことが望ましい。その意味では、Heywood直径および円形度係数のヒストグラムは有効な評価手段である。
本発明にかかる方法は、原理的に如何なるサイズの人工ダイヤにも、適用可能であるので、mmサイズの人工ダイヤも球形化可能とすると、応用範囲が広がる。例えば、鋼鉄製ボールベアリングのボールの置換え、ボール型レンズ、人工宝石、ボールペンの先端ボール、球形半導体などに適用することができる(非特許文献5)。とくに赤外線センサーを内蔵する夜間用眼鏡・望遠鏡などに必要な光学レンズとしては、球形ダイヤモンドに優る材料は無いと考えられるので、軍事用あるいは夜間ドライブ用眼鏡など、広い応用が期待される。
(特許文献2)“Nanospacer lubrication,” International Application No.: PCT/JP2010/065671, International Filing Date: 03.09.2010, Priority Date: 03.09.2010, Publication No: WO/2012/029191, Publication Date: 2012.03.08. Applicants/Inventors: NCRI, OSAWA Eiji, MORI Shigeyuki.
Claims (8)
- 単結晶ダイヤモンド粒子の集合体を、繰り返し改良自己摩耗操作に掛けて、多面体の頂点、稜などの突起部を、優先的に損耗することによって球形化することを特徴とする球形ダイヤモンドの製造方法。
- ダイヤモンド粒子同志の自己摩耗による球形化を加速あるいは減速する補助手段として加圧、(2)転動、(3)加熱または冷却、および(4)容器内壁の多結晶ダイヤモンド薄膜内張り、の4操作うち1つ或いは複数を加えた改良自己摩耗操作を有することを特徴とする請求項1記載の球形ダイヤモンドの製造方法。
- 請求項2記載の球形ダイヤモンドの製造方法によって製造され、既知のダイヤモンド結晶構造から成る内部、および極めて多数のダイヤモンド結晶面断片からなる球表面から構成される球形ダイヤモンドであって、適切な真球度指標、またはミクロン以下の大きさの場合には2次元画像から求める円形度係数によって、球形度が90%以上、好ましくは95%以上であることを特徴とする球形ダイヤモンド。
- 球形ダイヤモンドの表面は、安定化のために、摩耗操作によって生じた未配位炭素原子価に、水素、フッ素、酸素、水などを付加して飽和させておくことを特徴とする請求項3記載の球形ダイヤモンド。
- 単結晶ダイヤモンド粒子の球形化補助手段の内、前記加圧の操作が、球形化処理装置内部に、容易に転動できる程度に充填した単結晶ダイヤモンド粒子群に対して、上蓋を通して垂直荷重をかけ、摺動あるは接触に際して接触点にかかる力を増大させ、接触部先端の破壊を加速することによって達成することができる操作であることを特徴とする請求項2記載の球形ダイヤモンドの製造方法。
- 単結晶ダイヤモンド粒子の球形化補助手段の内、前記転動の操作が、自己摩耗および加圧による球形化が粒子全体にむらなく万遍に起きて、最短時間で求める円形度に到達するために処理装置の上蓋および容器を反対方向に水平回転させて、個々のダイヤモンド粒子を常に回転させる操作であって、上蓋および容器の何れか一方が回転せずに静止している場合を含む操作であることを特徴とする請求項2記載の球形ダイヤモンドの製造方法。
- 単結晶ダイヤモンド粒子の球形化補助手段の内、前記加熱または冷却の操作が、球形化装置の内、ダイヤモンド粒子の自己摩耗処理を行う空間を、100ないし300℃に加熱してダイヤモンド球形化を加速、或いは前記空間を室温以下の温度に冷却してダイヤモンド球形化を減速する処理であることを特徴とする請求項2記載の球形ダイヤモンドの製造方法。
- 単結晶ダイヤモンド粒子の球形化補助手段の内、前記容器内壁の多結晶ダイヤモンド薄膜内張りの操作が、球形化処理によって容器内壁が単結晶ダイヤモンド粒子によって損耗、または容器材質が鋼鉄の場合、炭化反応を起こして変質することを防ぐための処置であって、3nmダイヤモンドを結晶成長核とするCVD法によってなされることを特徴とする請求項2記載の球形ダイヤモンドの製造方法。
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JP2015000814A (ja) * | 2013-06-12 | 2015-01-05 | 国立大学法人京都大学 | 発光ダイヤモンドナノ粒子及びその製造方法 |
JP6381230B2 (ja) * | 2014-02-27 | 2018-08-29 | 国立大学法人信州大学 | 銅−ダイヤモンド複合材及びその製造方法 |
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JPH04132606A (ja) * | 1990-09-25 | 1992-05-06 | Nec Corp | ダイヤモンド微粉末の製造法と製造装置 |
JP2012502812A (ja) * | 2008-09-16 | 2012-02-02 | ダイヤモンド イノベイションズ インコーポレーテッド | 特有の形態を有する砥粒 |
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