The tightness behaviour of pressurised joints with and without seals

带密封件和不带密封件的受压接头的密封性能

• 批准号: 239166-2011
• 负责人: Bouzid, Hakim
• 金额: $ 2.91万
• 依托单位: École de technologie supérieure
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2014
• 资助国家: 加拿大
• 起止时间: 2014-01-01 至 2015-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=547227
• 关键词: tightness; behaviour; pressurised; joints; without

This research proposal deals with pressurised joints that require to seal. Pressurised joints can be categorized into two types: those that have a sealing element such as bolted flange connections and stuffing box packings and those that do not have a sealing element such as expanded joints. It is well established that the major cause of failure of pressurised joints is leakage. Worldwide surveys show that an important amount of fugitive emissions and contamination are produced from these joints. The sealing elements such as gaskets, compression packings and mechanical seals together with their structural assembly in which they are mounted are not the only parameters to blame. Assembly procedures, fabrication processes, design procedures and operating conditions are just to name a few. Even though a substantial effort has been put towards reducing fugitive emissions, preventing leakage remains one of the most challenging tasks. A fundamental understanding of the general behaviour of pressurised joints and their leakage controlling parameters has been gained through previous funding. The proposed continuing research project put emphasis towards simulating pressurized joint behaviour and developing analytical models for the purpose of improving their performance and developing accurate design procedures. In parallel, the use of newly developed test rigs will allow a valuable experimental validation of the developed models. Of particular importance are measurements of mechanical strength, leakage, contact stresses, creep-relaxation and buckling of spiral wound gaskets. It is our goal to extend the gained knowledge to the study of the residual stresses in tube-to-tubesheet joints, a new research activity that has recently been launched in our Static and Dynamic Sealing Laboratory. Although different in concept, expanded joints need to be tight to avoid mixture of fluids in heat exchangers and steam generators and in particular when welding is not performed or a second reliable leakage barrier is required in case of weld failure. Finally an important part of the work will be devoted towards experimental validation of the developed analytical and numerical FEM models.

这项研究建议涉及需要密封的承压接头。承压接头可分为两种类型：一种是带有密封元件的接头，如螺栓法兰连接和填充盒填料；另一种是没有密封元件的接头，如膨胀接头。众所周知，承压接头失效的主要原因是渗漏。世界各地的调查显示，这些接头产生了大量逃逸排放和污染。密封元件，如垫片、压缩填料和机械密封，以及它们安装在其中的结构组件，并不是唯一的原因。组装程序、制造过程、设计程序和操作条件仅是其中的几个例子。尽管已经为减少逃逸排放做出了大量努力，但防止泄漏仍然是最具挑战性的任务之一。通过以前的资助，已经对受压接头的一般行为及其泄漏控制参数有了基本的了解。拟议的继续研究项目侧重于模拟受压连接行为和开发分析模型，以改进其性能并制定准确的设计程序。同时，使用新开发的试验台将允许对开发的模型进行有价值的实验验证。尤其重要的是螺旋缠绕垫片的机械强度、泄漏、接触应力、蠕变松弛和屈曲的测量。我们的目标是将所获得的知识扩展到管子与管板连接的残余应力的研究中，这是我们的静态和动态密封实验室最近启动的一项新的研究活动。虽然在概念上不同，但膨胀接头需要紧密，以避免在热交换器和蒸汽发生器中混合流体，特别是在不进行焊接或需要第二个可靠的泄漏屏障以防止焊接失败的情况下。最后，重要的工作将致力于对所开发的分析和数值有限元模型进行实验验证。