公开(公告)号：US09039849B2

公开(公告)日：2015-05-26

申请号：US13394195

申请日：2009-11-30

申请人： Chan Hee Park ,  Chong Soo Lee ,  Sung Hyuk Park ,  Young Soo Chun

发明人： Chan Hee Park ,  Chong Soo Lee ,  Sung Hyuk Park ,  Young Soo Chun

IPC分类号： C22C14/00

CPC分类号： C22C14/00

摘要： Provided is a method of preparing a nanocrystalline titanium alloy at low strain to have better strength. The present invention is characterized in that an initial microstructure is induced as martensites having a fine layered structure, and then a nanocrystalline titanium alloy is prepared at low strain by optimizing process variables through observation of the effects of strain, strain rate, and deformation temperature on the changes in the microstructure.

摘要翻译： 提供了一种在低应变下制备纳米晶体钛合金以具有更好的强度的方法。 本发明的特征在于，作为具有细小层状结构的马氏体而引起初始微结构，然后通过观察应变，应变速率和变形温度的影响来优化工艺变量，在低应变下制备纳米晶体钛合金 微观结构的变化。

公开(公告)号：US20120160378A1

公开(公告)日：2012-06-28

申请号：US13394195

申请日：2009-11-30

申请人： Chan Hee Park ,  Chong Soo Lee ,  Sung Hyuk Park ,  Young Soo Chun

发明人： Chan Hee Park ,  Chong Soo Lee ,  Sung Hyuk Park ,  Young Soo Chun

IPC分类号： C22F1/18

CPC分类号： C22C14/00

摘要： Provided is a method of preparing a nanocrystalline titanium alloy at low strain to have better strength. The present invention is characterized in that an initial microstructure is induced as martensites having a fine layered structure, and then a nanocrystalline titanium alloy is prepared at low strain by optimizing process variables through observation of the effects of strain, strain rate, and deformation temperature on the changes in the microstructure.

摘要翻译： 提供了一种在低应变下制备纳米晶体钛合金以具有更好的强度的方法。 本发明的特征在于，作为具有细小层状结构的马氏体而引起初始微结构，然后通过观察应变，应变速率和变形温度的影响来优化工艺变量，在低应变下制备纳米晶体钛合金 微观结构的变化。

公开(公告)号：US20120128524A1

公开(公告)日：2012-05-24

申请号：US13270856

申请日：2011-10-11

申请人： Young Soo CHUN ,  Chong Soo LEE ,  You Hwan LEE ,  Kyung Tae PARK ,  Tae Kyung LEE ,  Sung Hyuk PARK ,  Chan Hee PARK ,  Ji Soo KIM ,  Young Kook LEE

发明人： Young Soo CHUN ,  Chong Soo LEE ,  You Hwan LEE ,  Kyung Tae PARK ,  Tae Kyung LEE ,  Sung Hyuk PARK ,  Chan Hee PARK ,  Ji Soo KIM ,  Young Kook LEE

IPC分类号： C21D8/06 ,  C22C38/04 ,  C22C38/06 ,  C21D8/00

CPC分类号： C21D6/005 ,  C21D8/065 ,  C21D9/0093 ,  C21D9/54 ,  C22C38/04 ,  C22C38/06

摘要： Provided are a high-strength, high-manganese steel wire rod having excellent cold heading quality and not requiring spheroidizing and quenching-tempering treatments during manufacturing a bolt and a method of manufacturing a bolt using the steel wire rod. The method of manufacturing a steel wire rod includes heating a steel containing 12 to 25 wt % of Mn within a temperature range of 1100° C. to 1250° C., hot rolling the heated steel within a temperature range of 700° C. to 1100° C., and cooling the hot rolled steel to a temperature of 200° C. or less and cold caliber rolling or drawing to manufacture a steel wire rod.

摘要翻译： 本发明提供一种具有优良的冷镦品质的高强度高锰钢线材，并且在制造螺栓期间不需要球化和淬火回火处理以及使用该钢丝线制造螺栓的方法。 钢线材的制造方法包括在1100℃〜1250℃的温度范围内加热含有12〜25重量％的Mn的钢，将加热后的钢在700℃的温度范围内热轧至 1100℃，将热轧钢冷却至200℃以下的温度，冷口径轧制或拉伸，制造钢丝。

公开(公告)号：US06863596B2

公开(公告)日：2005-03-08

申请号：US09865947

申请日：2001-05-25

申请人： Peter J. Fritz ,  Chong Soo Lee ,  James W. Malaske

发明人： Peter J. Fritz ,  Chong Soo Lee ,  James W. Malaske

IPC分类号： B24D13/04 ,  B24D13/16 ,  B24D13/20 ,  B24B1/00

CPC分类号： B24D13/20 ,  B24D13/16

摘要： Abrasive article including a backing plate. Backing plate has a first major surface and a second opposite major surface. A central aperture extends through backing plate. An abrasive layer is secured to the first major surface of backing plate. A fastener is press fit to backing plate so as to define the central aperture.

摘要翻译： 包括背板的磨料制品。 背板具有第一主表面和第二相对主表面。 中心孔延伸穿过背板。 研磨层固定在背板的第一主表面上。 紧固件压配合到背板以限定中心孔。

公开(公告)号：US10144982B2

公开(公告)日：2018-12-04

申请号：US14399515

申请日：2012-08-17

申请人： Tae Kyung Lee ,  Chong Soo Lee ,  Seok Weon Song ,  Jae Hyung Kim ,  Kaneaki Tsuzaki ,  Motomichi Koyama

发明人： Tae Kyung Lee ,  Chong Soo Lee ,  Seok Weon Song ,  Jae Hyung Kim ,  Kaneaki Tsuzaki ,  Motomichi Koyama

IPC分类号： C21D8/00 ,  C22C38/04 ,  C21D6/00 ,  C21D8/02 ,  C21D8/06

摘要： Provided is a Fe—Mn—C-based twinning-induced plasticity (TWIP) steel which includes 13 wt % to 24 wt % of manganese (Mn), 0.4 wt % to 1.2 wt % of carbon (C), and iron (Fe) as well as other unavoidable impurities as a remainder, is manufactured by caliber rolling, has a microstructure including elongated grains that are elongated in a rolling direction, and has an average grain size of the elongated grains in a direction perpendicular to the rolling direction of 1 μm or less.

公开(公告)号：US09435017B2

公开(公告)日：2016-09-06

申请号：US13879206

申请日：2012-03-19

申请人： Chan Hee Park ,  Chang Seok Oh ,  Jong Taek Yeom ,  Jae Keun Hong ,  Chong Soo Lee ,  Yong Taek Hyun

发明人： Chan Hee Park ,  Chang Seok Oh ,  Jong Taek Yeom ,  Jae Keun Hong ,  Chong Soo Lee ,  Yong Taek Hyun

IPC分类号： C22F1/18 ,  C22C14/00

CPC分类号： C22F1/183 ,  C22C14/00

摘要： A method of manufacturing a titanium alloy with high strength and high formability, the method including preparing a titanium alloy material and equipment for manufacturing the titanium alloy, manufacturing the titanium alloy having a lamellar structure (martensite structure) by cooling the prepared titanium alloy material with water after performing heat treatment at the beta transformation temperature or more, and rolling that makes ultrafine grains by finishing forming of the titanium alloy at a plastic instability temperature or less of an initial lamellar structure by gradually decreasing the forming temperature in accordance with an increase of a strain after starting the forming at the plastic instability temperature or more of an initial lamellar structure, under a condition of a low strain in which the strain is 2.5 or less, after the manufacturing of a titanium alloy having a lamellar structure.

摘要翻译： 一种制造具有高强度和高成形性的钛合金的方法，其包括制备钛合金材料和钛合金制造设备的方法，通过将制备的钛合金材料冷却制备具有层状结构（马氏体组织）的钛合金， 在β相变温度以上进行热处理之后的水，以及通过根据初始层状结构的塑性不稳定温度或更低而通过逐渐降低成形温度来完成钛合金的成型而制成超细晶粒的轧制 在制造具有层状结构的钛合金之后，在应变为2.5以下的低应变的条件下，在塑性不稳定温度以上的初始层状结构的开始成形后的应变。

公开(公告)号：US20150114526A1

公开(公告)日：2015-04-30

申请号：US14399515

申请日：2012-08-17

申请人： Tae Kyung Lee ,  Chong Soo Lee ,  Seok Weon Song ,  Jae Hyung Kim ,  Kaneaki Tsuzaki ,  Motomichi Koyama

发明人： Tae Kyung Lee ,  Chong Soo Lee ,  Seok Weon Song ,  Jae Hyung Kim ,  Kaneaki Tsuzaki ,  Motomichi Koyama

IPC分类号： C21D8/00 ,  C21D8/06 ,  C22C38/04 ,  C21D6/00

CPC分类号： C21D8/005 ,  C21D6/005 ,  C21D8/0231 ,  C21D8/0236 ,  C21D8/065 ,  C21D2201/03 ,  C21D2201/05 ,  C21D2211/001 ,  C21D2211/005 ,  C22C38/04

摘要： Provided is a Fe—Mn—C-based twinning-induced plasticity (TWIP) steel which includes 13 wt % to 24 wt % of manganese (Mn), 0.4 wt % to 1.2 wt % of carbon (C), and iron (Fe) as well as other unavoidable impurities as a remainder, is manufactured by caliber rolling, has a microstructure including elongated grains that are elongated in a rolling direction, and has an average grain size of the elongated grains in a direction perpendicular to the rolling direction of 1 μm or less.

摘要翻译： 本发明提供一种Fe-Mn-C系的孪晶诱导塑性（TWIP）钢，其含有13重量％〜24重量％的锰（Mn），0.4重量％〜1.2重量％的碳（C），铁 ）以及作为其余部分的其他不可避免的杂质通过口径轧制制造，具有包括在轧制方向上伸长的细长晶粒的微结构，并且在垂直于轧制方向的方向上具有细长晶粒的平均晶粒尺寸 1μm以下。

公开(公告)号：US20120111081A1

公开(公告)日：2012-05-10

申请号：US13384441

申请日：2009-08-12

申请人： Sung-Hyuk Park ,  Chong-Soo Lee ,  Seong-gu Hong ,  Byoung-Ho Lee

发明人： Sung-Hyuk Park ,  Chong-Soo Lee ,  Seong-gu Hong ,  Byoung-Ho Lee

IPC分类号： B21B23/00 ,  B21D31/00

CPC分类号： C22F1/06

摘要： The present invention relates to a method of manufacturing magnesium alloy processing materials capable of improving low cycle fatigue life. The manufacturing method for magnesium alloy processing materials with improved low cycle fatigue life comprises pre-straining a magnesium alloy processing material which is processed.

摘要翻译： 本发明涉及能够改善低循环疲劳寿命的镁合金加工材料的制造方法。 具有改善的低循环疲劳寿命的镁合金加工材料的制造方法包括预处理被加工的镁合金加工材料。

公开(公告)号：US20060213592A1

公开(公告)日：2006-09-28

申请号：US11169068

申请日：2005-06-28

申请人： Young-Gun Ko ,  Chong-Soo Lee ,  Dong-Hyuk Shin

发明人： Young-Gun Ko ,  Chong-Soo Lee ,  Dong-Hyuk Shin

IPC分类号： C22C14/00

CPC分类号： C22C14/00 ,  B21C23/001 ,  B22F2998/00 ,  C22C1/0458

摘要： A method and apparatus for manufacturing a nanocrystalline titanium alloy by performing an equal channel angular pressing process to a titanium alloy material, and a nanocrystalline titanium alloy manufactured using the method and apparatus. The method for manufacturing the nanocrystalline titanium alloy includes steps of preparing a titanium alloy material, and performing an equal channel angular pressing process on the titanium alloy material at an isothermal condition of 575° C. to 625° C. The nanocrystalline titanium alloy according to has a grain size of 300 nm.

摘要翻译： 一种通过对钛合金材料进行等通道角压制来制造纳米晶体钛合金的方法和装置，以及使用该方法和装置制造的纳米晶体钛合金。 制造纳米晶体钛合金的方法包括制备钛合金材料的步骤，并在575℃至625℃的等温条件下对钛合金材料进行等通道角压制。根据本发明的纳米晶体钛合金 具有300nm的粒度。

公开(公告)号：US20140305554A1

公开(公告)日：2014-10-16

申请号：US13879206

申请日：2012-03-19

申请人： Chan Hee Park ,  Chang Seok Oh ,  Jong Taek Yeom ,  Jae Keun Hong ,  Chong Soo Lee ,  Yong Taek Hyun

发明人： Chan Hee Park ,  Chang Seok Oh ,  Jong Taek Yeom ,  Jae Keun Hong ,  Chong Soo Lee ,  Yong Taek Hyun

IPC分类号： C22F1/18 ,  C22C14/00

CPC分类号： C22F1/183 ,  C22C14/00

摘要： A method of manufacturing a titanium alloy with high strength and high formability includes preparing a material and equipment for manufacturing a titanium alloy, manufacturing a titanium alloy having a lamellar structure (martensite structure) by cooling the prepared material with water after performing heat treatment at the beta transformation temperature or more, and rolling that makes ultrafine grains by finishing forming of the titanium alloy at a plastic instability temperature by gradually decreasing the forming temperature in accordance with an increase of a strain after starting the forming at the plastic instability temperature of more, under a condition of a low strain in which the strain is 2.5 or less, after the manufacturing of a titanium alloy having a lamellar structure.

摘要翻译： 一种制造具有高强度和高成形性的钛合金的方法包括制备钛合金的材料和设备，制备具有层状结构（马氏体组织）的钛合金，通过在水处理后进行热处理，将制备的材料用水冷却 β相变温度以上，通过在塑料不稳定温度下，在塑性不稳定温度下开始成型后的应变增加逐渐降低成型温度，在塑性不稳定温度下，通过整理钛合金成型而制成超细晶粒， 在制造具有层状结构的钛合金之后，在应变为2.5以下的低应变条件下进行。