{"title":"New Breech-Lock Exchanger Design to Ensure Gasket Sealing Under All Conditions","authors":"Roberto Groppi, R. Jibb, D. Creech","doi":"10.1115/pvp2022-84713","DOIUrl":null,"url":null,"abstract":"\n High pressure threaded closures designed to ASME VIII Div.1 and Div. 2 are used extensively in heat exchangers in the hydroprocessing industry, where design conditions in excess of 100 bar and 450 °C may be required. When there is a requirement to open for inspection and maintenance, the breech-lock or screw-plug design offers a cost-effective alternative to TEMA channel closure types because it eliminates the large cover flange and bolting (often associated to welded diaphragms), allows for sealing adjustments without being dismantled and provides quicker opening and closing operations. For services designed to operate with a pressure differential between circuits that cannot be isolated (High-High type) an internal assembly must be designed such that the sealing of the tubesheet gasket is maintained under all possible operating conditions. The assembly must transfer the loads from the bolts to the tubesheet gasket but also remain elastic over a range of operating conditions.\n The past work on this assembly type is reviewed and root causes of exchanger leaks reported in the literature are discussed. A finite element analysis study showed that typical designs for the internal load-carrying components undergo plastic deformation due to thermal expansion under certain operating conditions, leading to a loss of gasket seal. While sealing may be temporarily restored by acting on external bolts, for example by hot torquing, subsequent thermal cycles can result in further deformation such that the assembly may require unplanned maintenance or repair.\n The results of the study were used to guide development of a new closure concept using a conical disc spring to ensure adequate gasket stress for sealing of the tubesheet while maintaining elastic behavior of components under load for all anticipated operating conditions, including upsets. Finite element models were used to compare the new approach to the existing practice and to design a demonstration unit, which has since been fabricated. The conical disk spring for the demonstration unit was tested, confirming the elastic behavior over the anticipated load range and enabling calibration of strain gauges. The complete prototype was tested with mechanical and thermal loads to validate analysis results and confirm ease of assembly and disassembly. The new closure design can reduce plant shutdown time by eliminating leaks and damage during operation of screw-plug exchangers.","PeriodicalId":23700,"journal":{"name":"Volume 2: Computer Technology and Bolted Joints; Design and Analysis","volume":"28 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2022-07-17","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Volume 2: Computer Technology and Bolted Joints; Design and Analysis","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1115/pvp2022-84713","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
High pressure threaded closures designed to ASME VIII Div.1 and Div. 2 are used extensively in heat exchangers in the hydroprocessing industry, where design conditions in excess of 100 bar and 450 °C may be required. When there is a requirement to open for inspection and maintenance, the breech-lock or screw-plug design offers a cost-effective alternative to TEMA channel closure types because it eliminates the large cover flange and bolting (often associated to welded diaphragms), allows for sealing adjustments without being dismantled and provides quicker opening and closing operations. For services designed to operate with a pressure differential between circuits that cannot be isolated (High-High type) an internal assembly must be designed such that the sealing of the tubesheet gasket is maintained under all possible operating conditions. The assembly must transfer the loads from the bolts to the tubesheet gasket but also remain elastic over a range of operating conditions.
The past work on this assembly type is reviewed and root causes of exchanger leaks reported in the literature are discussed. A finite element analysis study showed that typical designs for the internal load-carrying components undergo plastic deformation due to thermal expansion under certain operating conditions, leading to a loss of gasket seal. While sealing may be temporarily restored by acting on external bolts, for example by hot torquing, subsequent thermal cycles can result in further deformation such that the assembly may require unplanned maintenance or repair.
The results of the study were used to guide development of a new closure concept using a conical disc spring to ensure adequate gasket stress for sealing of the tubesheet while maintaining elastic behavior of components under load for all anticipated operating conditions, including upsets. Finite element models were used to compare the new approach to the existing practice and to design a demonstration unit, which has since been fabricated. The conical disk spring for the demonstration unit was tested, confirming the elastic behavior over the anticipated load range and enabling calibration of strain gauges. The complete prototype was tested with mechanical and thermal loads to validate analysis results and confirm ease of assembly and disassembly. The new closure design can reduce plant shutdown time by eliminating leaks and damage during operation of screw-plug exchangers.
设计符合ASME VIII Div.1和Div. 2的高压螺纹密封件广泛应用于加氢工业的热交换器中,其设计条件可能需要超过100 bar和450°C。当需要打开进行检查和维护时,后锁或螺塞设计是TEMA通道关闭类型的一种经济有效的替代方案,因为它消除了大型盖板法兰和螺栓(通常与焊接隔膜相关),允许在不拆卸的情况下进行密封调整,并提供更快的打开和关闭操作。对于设计用于在不能隔离的电路之间的压差(高-高型)下运行的服务,必须设计一个内部组件,以便在所有可能的操作条件下保持管板垫圈的密封性。总成必须将载荷从螺栓转移到管板垫片上,同时还要在一系列操作条件下保持弹性。回顾了过去对这种组合类型的工作,并讨论了文献报道的交换器泄漏的根本原因。一项有限元分析研究表明,典型的内部承载部件设计在一定的工作条件下,由于热膨胀而发生塑性变形,导致垫片密封失效。虽然可以通过作用于外部螺栓(例如热扭矩)暂时恢复密封,但后续的热循环可能会导致进一步的变形,从而需要对总成进行计划外的维护或维修。研究结果用于指导开发一种新的封闭概念,该概念使用锥形圆盘弹簧,以确保有足够的垫圈应力来密封管板,同时在所有预期的操作条件下保持组件的弹性行为,包括扰动。利用有限元模型将新方法与现有实践进行比较,并设计了一个示范装置,该装置已制作完成。对示范装置的锥形圆盘弹簧进行了测试,确认了其在预期载荷范围内的弹性行为,并能够对应变片进行校准。完整的原型进行了机械和热负荷测试,以验证分析结果,并确认装配和拆卸的便利性。新的关闭设计可以通过消除螺塞交换器运行过程中的泄漏和损坏来减少工厂停机时间。