| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 41 | 완전 형상 성분을 형성하기 위한 미립자 금속 시트를 생산하는 장치와 방법 | KR1020097020306 | 2008-02-27 | KR1020100014654A | 2010-02-10 | 고쉬,아미트; 덱커,레이몬드,에프.; 쿨카미,산자이; 만수르,빌랄 |
| A method and apparatus for producing ultra-fine grained metal alloy preferably magnesium material sheets. The apparatus molds and rapidly solidifies a metal alloy material to form a fine grain precursor. The precursor is then subjected to deformation strains that alter the grain structure of the precursor so as to form a ultra fine grained structure in sheet form. The sheet form may then be subjected to superplastic forming to form a net shaped article. | ||||||
| 42 | 마그네슘 합금 판재의 제조방법 및 이에 따라 제조되는 마그네슘 합금 판재 | KR1020150006833 | 2015-01-14 | KR1020160087956A | 2016-07-25 | 김세종; 이영선 |
| 본발명은마그네슘합금판재의제조방법및 이에따라제조되는마그네슘합금판재에관한것으로, 구체적으로는마그네슘합금판재를용기의바닥면과판재의압연방향(Rolling Direction) 또는횡방향(Transverse Direction)이수직이되도록용기내에위치시키는단계(단계 1); 마그네슘합금판재가위치된용기내에충전재를투입하는단계(단계 2); 및상기충전재상에압력을가함으로써마그네슘합금판재에압축응력을가하는단계(단계 3);를포함하는마그네슘합금판재의제조방법을제공한다. 본발명에따른마그네슘합금판재의제조방법은, 충전재와함께판재의압연방향및 횡방향으로압축함으로써, 인장쌍정이형성되면서도지지대역할을하는충전재로인해판재의형상은유지되는효과가있다. 나아가, 얇은판재에도적용가능한장점이있다. | ||||||
| 43 | 가공송전선의 표면강화처리방법 및 이에 의해 제조된 가공송전선 | KR1020140026486 | 2014-03-06 | KR101531012B1 | 2015-06-24 | 김병걸 |
| 본발명은가공송전선의표면강화처리방법에관한것으로서, 열처리된강도가낮은알루미늄또는제조공정에의해강도가감소된알루미늄소재를가공송전선의도체로사용할경우, 가공송전선의제조나운반또는시공과정에서발생할수 있는표면스크래치를방지또는최소화될수 있도록하는가공송전선의표면강화처리방법을제공하는것을목적으로한다. 이를위한본 발명의일 실시예에따르면, 연알루미늄을적용한가공송전선의표면강화처리방법에있어서, 송전선의하중을지지하는강심의외주면에상기연알루미늄을연선하여가공송전선을제조하는단계와; 상기가공송전선을캡스턴에통과한후 연마재를일정세기로분사하여연선된연알루미늄의표면을강화처리하는단계; 및상기표면강화처리된가공송전선을드럼에권취하는단계;를포함하는것을기술적요지로한다. 이에따른본 발명에의하면, 연알루미늄도체가적용된가공송전선의표면에연마재를분사하는표면강화처리를함으로써표면강화를유도할수 있고이를통해내스크래치성을크게향상시켜강도가낮은연알루미늄의단점을보완할수 있게되는효과가있다. | ||||||
| 44 | 여러 에너지원을 이용해 응력을 경감하는 방법과 장치 | KR1020057002543 | 2003-08-01 | KR1020050050645A | 2005-05-31 | 워커도나엠 |
| Methods are presented for modifying a physical property of a structure, such as reducing or relieving remaining internal stress, in which two or more energy types are concurrently applied (140, 142) to the structure to change the physical property of interest in an accelerated fashion. A first energy type, such as heat, is applied according to time values and operational settings derived from a first order rate relationship (151) for the first energy type and from a first order rate relationship (152) for a second energy type. The second energy type, such as vibration or other time-varying energy form, is applied concurrently for the time value. Methods are also provided for determining operational settings for concurrent application of multiple energy types to a structure. | ||||||
| 45 | 자기장 공정을 이용하여 합금 입자를 정련하는 방법 | KR1020047009191 | 2002-12-10 | KR1020040061036A | 2004-07-06 | 쿠자영; 링시운; 루톤마이클존; 토만한스; 방가루나라심하-라오브이 |
| A method for refining the grain size of alloys which undergo ferromagnetic to paramagnetic phase transformation and an alloy produced therefrom. By subjecting the alloy to a timed application of a strong magnetic field, the temperature of phase boundaries can be shifted enabling phase transformations at lower temperatures. | ||||||
| 46 | 금속-세라믹 복합 재료 바디 및 그 제조 방법 | KR1020027006034 | 2000-11-06 | KR1020020073335A | 2002-09-23 | 슈텐첼,오토,베.; 체르빈스키,클라우스; 포스틀러,이리스; 라인쉬,베른트 |
| 본발명은금속(6) 및금속부품에인접한, 금속(6)에의해침투된다공성세라믹퍼스트바디(2)로이루어진복합재료바디에관한것이다. 금속에의해환원될수 있는퍼스트바디의산화물과침투된금속은금속간상 및금속산화의형성시서로부분적으로반응된다. 이경우퍼스트바디(2)의내부에서금속부품방향으로, 침투된금속(6)과환원될수 있는퍼스트바디(2)의산화물사이의불완전한화학반응에대한광범위한화학반응의기울기가형성된다. | ||||||
| 47 | ピーニング装置及びピーニング方法 | JP2012225321 | 2012-10-10 | JP6138450B2 | 2017-05-31 | 小▲崎▼ 貴史 |
| 48 | 金属部材残留応力を局部的に調整する方法及びシステム | JP2015552971 | 2013-03-11 | JP2016505856A | 2016-02-25 | 春広 徐; 文涛 宋; 勤学 潘; 定国 肖; 浪 徐; 驍 李; 海洋 劉 |
| 本件発明は、単一又は複数の超音波変換器を残留応力調整目標領域又は当該領域の付近に配置し、前記超音波変換器を固定し、超音波を発生させて、超音波の周波数や振幅や位相やエネルギーなどのパラメータを調節して、前記領域における残留応力の大きさと方向とを調節制御する残留応力調整方法及び残留応力調整システムを提供する。当該方法及びシステムによれば、金属部材局部残留応力を除去、抑制および再建することができ、構造が簡単、操作が容易、効率が高い、コストが低い、汚染が少ないという長所を有する。【選択図】図2 | ||||||
| 49 | Peening device and peening method | JP2012225321 | 2012-10-10 | JP2014076466A | 2014-05-01 | OZAKI TAKASHI |
| PROBLEM TO BE SOLVED: To perform excellent peening following to the processed surface the shape of which varies from hour to hour with the peening.SOLUTION: The peening device includes a peening impact pin which gives impact to the processed surface, a device body which makes the peening impact pin reciprocating motion to the processed surface due to vibration, servo motors 22x and 22y which regulate the inclination to the processed surface of the device body, laser displacement gauges 20A, 20B, 20C, and 20D which detect a device angle, and a vibration sensor 18 which detects the vibrational state of the device body. Moreover a control device 40 of peening device controls the servo motors 22x and 22y such that the vibrational state detected by the vibrating sensor 18 turns into a vibrational state defined beforehand. | ||||||
| 50 | Method and system for coherent imaging and feedback control for the modification of material | JP2013529519 | 2011-09-26 | JP2013545613A | 2013-12-26 | ポール ジェイ.エル. ウェブスター; ジェームズ エム. フレイザー; ビクター エクス.ディー. ヤング |
| Methods and systems are provided for using optical interferometry in the context of material modification processes such as surgical laser or welding applications. An imaging optical source that produces imaging light. A feedback controller controls at least one processing parameter of the material modification process based on an interferometry output generated using the imaging light. A method of processing interferograms is provided based on homodyne filtering. A method of generating a record of a material modification process using an interferometry output is provided. | ||||||
| 51 | Method of separating/concentrating isotopes and rotor using the method | JP2006103434 | 2006-04-04 | JP2007275725A | 2007-10-25 | MASHITA SHIGERU; ONO MASAO; KO SHINSHO; IGUCHI YUSUKE; OKAYASU SATORU; YASUOKA HIROSHI; SHIBAZAKI YASUSHI; SUEYOSHI MASANORI |
| <P>PROBLEM TO BE SOLVED: To provide a method of separating/concentrating efficiently and at low costs isotopes of condensed system (liquid or/and solid) materials constituted of two or more different isotopes. <P>SOLUTION: The method comprises the step of charging the condensed system (liquid or/and solid) materials 5 consisting of two or more isotopes into a setting tank (for example, 2) to take in an ultracentrifuge, of rotation-driving a rotor 1 of the ultracentrifuge by an ultrahigh-speed rotary power source, and of giving an acceleration field of an energy of 100,000 G or 1,500,000 G, about 100 to 800 m/s at a circumferential speed to the condensation (liquid or/and solid) materials under the temperature specified by the isotope materials to be condensed. However, a difference is given to the centrifugal force acting on each isotope of the concentration (liquid or/and solid) material consisting of at least two isotopes. The method is achieved by the separation/concentration of the isotopes by the settling with the difference, the use of effective materials, and the use of the staging rotor system. <P>COPYRIGHT: (C)2008,JPO&INPIT | ||||||
| 52 | 高強度・超塑性材料の製造方法 | JP2005506503 | 2004-05-28 | JPWO2004106577A1 | 2006-07-20 | 山本 一富; 一富 山本 |
| 本発明は、金属材料の組織が微細結晶粒からなる高強度・超塑性材料を簡便に得ることのできる高強度・超塑性材料の製造方法を提供するものである。金属材料に超音波を印加した後、この金属材料を絶対温度で表されたその融点に0.35乃至0.6を乗じた温度で加熱処理する。金属材料は固有減衰能10%以上の高減衰金属材料、特にMgまたはMg合金が最適である。 | ||||||
| 53 | Base metal surfaces, a method for producing a structured metallic surface of the substrate and use | JP2003531563 | 2002-09-19 | JP2005504173A | 2005-02-10 | ショル ハラルト; ミュックリッヒ フランク; レーバイン ペーター |
| 基体の構造化された金属表面(5)を製造する方法、又は表面近傍を構造化する方法、又は金属組織を形成する方法が提供され、この場合に、まず、第1の金属層又は第1の金属間化合物層(11)に、この金属間化合物層(11)とは異なる第2の金属層(12)又は第2の金属間化合物層を形成し、次いで、少なくとも第2の金属層(12)又は第2の金属間化合物層を次の形式で部分的に加熱する、すなわち、この場所で、第1の金属間化合物層(11)又は第1の金属層の材料と、第2の金属層(12)又は第2の金属間化合物層の材料とにより、金属間化合物(11`)を形成し、この金属間化合物(11`)内に、少なくとも主に第2の金属層(12)又は第2の金属間化合物層の材料より成る表面範囲(12`)を挿入する。 さらに、前記構造を備えた基体の金属表面(5)、特にコネクタ又は構成部材の電気的な接触又は接続のための電気的な接触エレメントの表面が提供される。 | ||||||
| 54 | Aluminum, biological action improved method for the aluminum alloy and aluminum compound | JP2001582599 | 2001-04-24 | JP2003532797A | 2003-11-05 | ニコラオウ,アタナシオス |
| (57)【要約】 アルミニウム、アルミ合金、アルミ化合物のバイオロジカル作用の改善並びに毒性中和方法が開示されている。 この方法は、対象アルミ製品に対して電磁波を照射するものであり、アルミ製品に食品及び飲料保存特性を付与し、アルミ廃棄物の毒性を中和させる。 この照射電磁波は複数の周波数の、1Hzから300GHzの範囲の周波数領域をカバーする電磁波スペクトルのものであり、パルス形態または間断形態で照射される。 | ||||||
| 55 | Metal / ceramic composite body and a method of manufacturing the same | JP2001536787 | 2000-11-06 | JP2003514122A | 2003-04-15 | ポストラー イリス; ヴェー シュテンツェル オットー; ツェルヴィンスキー クラウス; ラインシュ ベルント |
| (57)【要約】 本発明は、金属(6)と、金属部分に境を接し、金属が浸透した多孔質セラミック予備成形体(2)とからなり、その際予備成形体の、金属によって還元可能な酸化物と、浸透した金属とが相互に部分的に反応して金属間相を形成している複合材料体に関する。 該複合材料体において、予備成形体(2)の内部に金属部分への方向で、予備成形体の還元可能な酸化物と浸透した金属との十分な化学反応から不完全な化学反応への勾配が形成されていること提案する。 | ||||||
| 56 | Titanium or wear resistance for the alloy, withstand the mechanical high-load, low surface layer structure of friction and a method of manufacturing the same | JP51316098 | 1997-09-12 | JP2001500192A | 2001-01-09 | シャイベ・ハンス―ヨアヒム; ツィーゲレ・ホルガー; ブレンナー・ベルント; ボンス・シュテフェン |
| (57)【要約】 この発明は、人間の移植組織を保護するために特に有利に使用できるチタンまたはその合金に対する耐磨耗性で、機械的な高負荷に耐え、摩擦の少ない表面層構造に関する。 この発明による表面層構造では、表面層は厚さが200〜400nmの硬質の非晶質炭素層4と、厚さが50〜200nmの中間層3と、厚さが0.3〜2.0mmのガス合金化された層2とで形成され、このガス合金化された層の硬度は600HV 0.1 〜1400HV 0.1である。 この発明による表面層構造は、先ず保護すべき部品表面を溶融し、次いでN 2 /Ar雰囲気の下でガス合金化し、洗浄し、次いでレーザー制御でパルス化された真空アーク(レーザーアーク)法により最初に中間層を、次いで硬質の非晶質炭素層を析出させて作製する。 | ||||||
| 57 | Method and device for changing the physical properties of the metal substrate | JP8651183 | 1983-05-17 | JPH0613725B2 | 1994-02-23 | ARAN ETSUCHI KUROAA; BARII PII FUERANDO; SUCHIIBUN SHII FUOODO; KUREIGU TEII UORUTAAZU |
| 58 | JPH0138852B2 - | JP16904280 | 1980-11-29 | JPH0138852B2 | 1989-08-16 | BORUFU UDO TSUAMERUTO |
| 59 | Memory element | JP24470788 | 1988-09-30 | JPH01157765A | 1989-06-21 | UIRIAMU SHII MATSUKOI; FUREDERITSUKU II WANGU; JIEIMUZU II SUMOORU; GUREGORII EI KOORU |
| PURPOSE: To prevent the introduction of pollutants by providing a memory element with a first portion and second portion respectively having specific crystalline structures, interconnecting these portions and providing the element with partition means having an amorphous structure different from the specific crystalline structures of the first portion and the second portion. CONSTITUTION: Wire leads 12 of silver are connected to the memory element 10 at junction points 14 by coupling means and are partially covered with insulating materials 16. The silver leads 12 are welded or soldered by heating to the memory element 10. At this time, the streams of ion materials 8 shown by arrows 18 are generated and impurities to weaken a shape-memory effect characteristic are formed. The thermal stress partition region 26 is formed by energy streams 24 which give rise to local dissolution to fissure the crystalline structures of the alloy consisting of the memory element 20 with a laser or the like as an energy source 22, by which the memory element 20 is parted to a lead-attachment portion 28 and the shape-memory portion 30. As a result, the power is supplied to the lead-attachment portion 28 and the migration of the transmitted ion materials 18 to the shape-memory portion 30 is prohibited by the partition means 26 and the shape-memory effect characteristic is maintained. COPYRIGHT: (C)1989,JPO | ||||||
| 60 | JPS6320904B2 - | JP16494179 | 1979-12-20 | JPS6320904B2 | 1988-05-02 | TOOMASU RICHAADO ANSONII; HAABEI ERISU KURAIN |
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