«ÉÏһƪ/Previous Article|±¾ÆÚĿ¼/Table of Contents|ÏÂһƪ/Next Article»

Öйú²ÄÁϽøÕ¹[ISSN:1674-3962/CN:61-1473/TG]

¾í:

ÆÚÊý:

2016ÄêµÚ3ÆÚ

Ò³Âë:

025-30

À¸Ä¿:

ÌØÔ¼Ñо¿ÂÛÎÄ

³ö°æÈÕÆÚ:

2016-03-30

ÎÄÕÂÐÅÏ¢/Info

Title:

Microstructural Design and Property Optimizationof Mo Alloys with High Performance

×÷Õß:

 Áõ¸Õ1; ÕŹú¾ý1; 2; ½­·å1; ¶¡Ïò¶«1; ËïÔº¾ü3; ÍõÁÖ3; ÂÞ½¨º£3; Ëï¾ü1

 £¨1. Î÷°²½»Í¨´óѧ ½ðÊô²ÄÁÏÇ¿¶È¹ú¼ÒÖصãʵÑéÊÒ, ÉÂÎ÷ Î÷°² 710049£©
£¨2. Î÷°²Àí¹¤´óѧ ²ÄÁÏ¿ÆѧÓ빤³ÌѧԺ, ÉÂÎ÷ Î÷°² 710048£©
£¨3. ½ð¶Ñ³ÇîâÒµ¼¯ÍÅÓÐÏÞ¹«Ë¾£¬ÉÂÎ÷ Î÷°² 710077£©

Author(s):

LIU Gang1;  ZHANG Guojun1; 2;  JIANG Feng1; DING Xiangdong1; SUN Yuanjun3; WANG Lin3; LUO Jianhai3; SUN Jun1

 £¨1. State Key Laboratory for Mechanical Behavior of Materials, Xi¬ðan Jiaotong University, Xi¬ðan 710049, China£©
(2. School of Materials Science and Engineering, Xi¬ðan University of Technology, Xi¬ðan 710048, China)
(3. Jinduicheng Molybdenum Group Coª±,LTD£¬Xi¬ðan 710077, China)

¹Ø¼ü´Ê:

îâºÏ½ð; Ç¿ÈÍ»¯; ÄÉÃ×Ï¡ÍÁÑõ»¯Îï; ÒºÒº²ôÔÓ; ¶à²ã¼¶Î¢¹Û½á¹¹; ¸ßÑÓÐÔ

DOI:

10.7502/j.issn.1674-3962.2016.03.06

ÎÄÏ×±êÖ¾Âë:

A

ÕªÒª:

´«Í³·½·¨ÖƱ¸µÄÏ¡ÍÁÑõ»¯ÎïÃÖɢǿ»¯îâºÏ½ð(ODSîâºÏ½ð)Ç¿¶ÈÓÐÏÞÇÒËÜÐԽϲµ¼ÖÂÆä±äÐÎÉî¼Ó¹¤ÄÜÁ¦²»×㣬ÑÏÖØÖÆÔ¼ÁËÆ乤ҵӦÓ᣷ÖÎöÁËODSîâºÏ½ðÖƱ¸¹¤ÒÕ-΢¹Û×éÖ¯-Á¦Ñ§ÐÔÄÜÖ®¼äµÄÒò¹û¹Øϵ£¬Ìá³öÁËîâºÏ½ðÄÉÃײôÔÓÇ¿ÈÍ»¯µÄÐÂ˼·£¬¼´ÄÉÃ׳߶ÈÏ¡ÍÁÑõ»¯Îï¿ÅÁ£¾ùÔÈÃÖÉ¢·Ö²¼ÔÚϸ¾§îâ»ùÌ徧Á£ÄÚ²¿¡¢Í¬Ê±²¿·Ö¿ÅÁ£·Ö²¼ÔÚ¾§½çÉϵĶà²ã¼¶Î¢¹Û½á¹¹ÓÅ»¯Ô­Ôò£¬·¢Õ¹ÁËÖƱ¸¸ÃÀàÐÂÐÍîâºÏ½ðµÄÒºÒº²ôÔÓ·½·¨£¬ËùµÃµ½µÄ¸ßÐÔÄÜîâºÏ½ðÔÚÀ­ÉìÇü·þÇ¿¶È´ïµ½800 MPaÁ¿Ê±£¬À­ÉìÑÓÉìÂÊÈÔ½ü40%£¬Ó봫ͳ·½·¨ÖƱ¸µÄODSîâºÏ½ðÏà±È£¬Çü·þÇ¿¶ÈÌá¸ßÁËÔ¼15%£¬À­ÉìÑÓÉìÂÊÌá¸ßÁËÓâ160%£¬ÊµÏÖÁËÇ¿¶ÈºÍÑÓÐÔµÄͬ²½ÌáÉý¡£½øÒ»²½½¨Á¢ÁËÇ¿ÈÍ»¯ÀíÂÛÄ£ÐÍ£¬¶ÔÇ¿¶ÈºÍÑÓÐԵĸÄÉƽøÐÐÁËÁ¿»¯ÃèÊö¡£ÕâÖÖ¸ßÐÔÄÜîâºÏ½ðÓÉÓÚÁ¦Ñ§ÐÔÄÜÓÅÒì¡¢¼Ó¹¤ÐÔÄܺã¬ÒÑ»ñµÃÁ˹¤ÒµÓ¦Óã¬Æä΢¹Û×éÖ¯µ÷¿ØÔ­ÔòÒÔ¼°ÖƱ¸·½·¨¶ÔÆäËüÄÑÈÛ½ðÊô½á¹¹²ÄÁϵĸßÐÔÄÜ»¯Í¬Ñù¾ßÓнè¼øÒâÒå¡£

Abstract:

The highª²temperature stability and mechanical properties of refractory molybdenum alloys are highly desirable for a wide range of critical applications. But molybdenum (Mo) alloys are also a wellª²known example of bodyª²centeredª²cubic materials that suffer from low ductility and limited formability. In this paper, we firstly discuss the microstructureª²property relationships in traditional oxide dispersionª²strengthened Mo alloys and analyze the fracture mechanisms. Based on these understandings, we propose a new nanostructuring strategy to solve the longª²standing lowª²ductility problem by optimizing the distribution of the grains, strengthening dispersions and solutes. In particular, a simple and costª²effective molecularª²level liquidª²liquid mixing/doping technique is developed to achieve ultrafine submicronª²sized grains with nanosized oxide particles uniformly distributed in the grain interior. The resulting nanostructured Mo alloys boast not only a high yield strength of over 800 MPa but at the same time an extraordinary tensile elongation as large as ~40% at room temperature, which is increased by about 15% and above 160%, respectively, when compared with the ODS Mo alloys prepared by conventional methods. The new processing route can be readily adapted for largeª²scale industrial productions of ductile Moalloys that can be extensively processed and shaped, including deep drawing, at low temperatures. Our findings represent a pathway towards engineering dispersionª²strengthened materials with simultaneously high strength and ductility, a combination beyond conventional trends and expectations, which should be applicable to refractory metals such as tungsten.

³£Óù¦ÄÜ

¸üÐÂÈÕÆÚ/Last Update: 2016-03-31