The role of steel chemistry on the microstructure/properties in the heat affected zone for high strength linepipe

钢化学对高强度管线管热影响区显微组织/性能的作用

• 批准号: 505656-2016
• 负责人: Poole, Warren
• 金额: $ 9.98万
• 依托单位: University of British Columbia
• 依托单位国家: 加拿大
• 项目类别: Collaborative Research and Development Grants
• 财政年份: 2018
• 资助国家: 加拿大
• 起止时间: 2018-01-01 至 2019-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=662443
• 关键词: role; steel; chemistry; microstructure; properties

Pipelines to transport energy (natural gas and liquids) are an integral part of the North American energy landscape. Canada alone has more than 75,000 km of natural gas and 25,000 km of liquids (e.g. refined oil and bitumen) pipelines. Further, there are proposals to construct new pipelines such as TransCanada Pipeline's Energy East project to deliver oil products from Alberta to refineries on Canada's east coast (4,500 km 1.1 million barrels of oil per day). The safe and economic construction and operation of this extensive pipeline network is of strategic importance to Canada. ** There is a trend towards using pipelines of larger diameter and/or increasing the operation pressure of the pipeline to improve the throughput of the system. This leads to using higher strength linepipe steel grades to avoid using thicker wall linepipe steel. The current state of the art uses X70 or X80 steel grades (yield stress of 490 and 560 MPa, respectively). Using higher strength steels translates into less material being required thereby lowering material and transportation cost. One of the engineering challenges for these materials is the development of robust manufacturing and in field joining processes, i.e. girth welds. This project addresses aspects related to the mechanical behavior of the steels used and, in particular, the effects of welding on these properties for a range of different steel chemistries. Currently, the evaluation of steels follows performance based specifications such as the yield stress, i.e. the composition of the steel is not explicitly considered. There are two fundamental challenges that face the industry. For steel producers such as Evraz, the challenge relates to chemistry optimization (in particular, the appropriate alloy additions of Cr, Mo and Nb). On the other hand, pipeline constructors/operators such as TCPL have to understand how the different steels will respond to the heat input from welding during the construction of the pipeline.** The results from this project will be i) an increased knowledge base for the microstructure/mechanical properties in the heat affected zone for advanced, ii) transfer of this knowledge to our industry partners and iii) the education of 5 high qualified personal (3 Ph.D., 2 PDFs) ****

输送能源(天然气和液体)的管道是北美能源格局的组成部分。仅加拿大就有超过75,000公里的天然气和25,000公里的液体(如成品油和沥青)管道。此外，还提议建设新的管道，如TransCanada Pipeline的Energy East项目，将石油产品从艾伯塔省输送到加拿大东海岸的炼油厂(每天输送4500公里110万桶石油)。这一广泛的管道网络的安全和经济建设和运营对加拿大具有战略重要性。**有一种趋势是使用更大直径的管道和/或增加管道的运行压力，以提高系统的吞吐量。这导致使用更高强度的管线钢牌号，以避免使用较厚的壁管线钢。目前的技术水平使用X70或X80钢种(屈服应力分别为490和560兆帕)。使用更高强度的钢可以减少所需的材料，从而降低材料和运输成本。这些材料的工程挑战之一是发展强大的制造和现场连接工艺，即环缝。该项目涉及与所用钢的机械性能有关的方面，特别是焊接对一系列不同钢的化学成分的这些性能的影响。目前，对钢的评估遵循基于性能的规范，如屈服应力，即不明确考虑钢的成分。该行业面临着两个根本性的挑战。对于Evraz这样的钢铁生产商来说，挑战涉及到化学优化(特别是添加适当的铬、钼和Nb合金)。另一方面，像TCPL这样的管道施工者/操作员必须了解不同的钢材在管道施工过程中将如何对焊接热输入做出反应。**该项目的结果将是：i)增加先进热影响区组织/机械性能的知识库；ii)将这些知识传授给我们的行业合作伙伴；iii)教育5名高素质的人员(3名博士，2名PDF)*