Finite element method simulating bursting process of multi-chamber flexible package infusion bag_Journal of Biomedical Engineering

Authors：

YUE Huaijun ^1,2 , WANG Guanshi ^1,2 ,  JIANG Wentao ^1,2 , TAN Hongbo ³ , LIU Wenjun ³ , ZHU Zhongqiang ³ , ZHU Lin ³

1. Department of Mechanics & Engineering, College of Architecture and Environment, Sichuan University, Chengdu 610065, P.R.China;
2. Failure Mechanics and Engineering Disaster Prevention and Mitigation Key Laboratory of Sichuan Province, Chengdu 610065, P.R.China;
3. Sichuan Kelun Pharmaceutical Co.Ltd, Chengdu 610500, P.R.China;

Corresponding author：

JIANG Wentao, Email: scubme@aliyun.com

Keywords：

multi chamber infusion bag; fluid cavity; finite element method; strength of weak welding

DOI：

10.7507/1001-5515.202005062

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This study aims to overcome the shortcomings such as low efficiency, high cost and difficult to carry out multi-parameter research, which limited the optimization of infusion bag configuration and manufacture technique by experiment method. We put forward a fluid cavity based finite element method, and it could be used to simulate the stress distribution and deformation process of infusion bag under external load. In this paper, numerical models of infusion bag with different sizes was built, and the fluid-solid coupling deformation process was calculated using the fluid cavity method in software ABAQUS subject to the same boundary conditions with the burst test. The peeling strength which was obtained from the peeling adhesion test was used as failure criterion. The calculated resultant force which makes the computed peeling stress reach the peeling strength was compared with experiment data, and the stress distribution was analyzed compared with the rupture process of burst test. The results showed that considering the errors caused by the difference of weak welding and eccentric load, the flow cavity based finite element method can accurately model the stress distribution and deformation process of infusion bag. It could be useful for the optimization of multi chamber infusion bag configuration and manufacture technique, leading to cost reduction and study efficiency improvement.

Citation： YUE Huaijun, WANG Guanshi, JIANG Wentao, TAN Hongbo, LIU Wenjun, ZHU Zhongqiang, ZHU Lin. Finite element method simulating bursting process of multi-chamber flexible package infusion bag. Journal of Biomedical Engineering, 2021, 38(3): 556-562. doi: 10.7507/1001-5515.202005062 Copy

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2.	Colomb V, Marlowe M L, Bonnot D, et al. Practical use of a new three-chamber bag for parenteral nutrition in pediatric patients. e-SPEN J, 2012, 7(2): e93-e99.
3.	刘志刚. 输液产品包装容器的现状及发展趋势. 中国药房, 2010, 21(21): 92-93.
4.	王锦芳, 陈国庆, 黄公敏. 软袋输液使用中漏液原因分析及处置. 海峡药学, 2011, 23(9): 189-190.
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6.	赵江. 多室输液袋关键指标的分析与检测. 机电信息, 2010, 13(8): 56-57.
7.	李继强. 非 PVC 多层共挤膜输液用袋焊接工艺优化. 济南: 山东大学, 2017.
8.	宁书慧, 方志勤, 王淼. 非 PVC 膜软袋大输液生产工艺改进. 黑龙江医药科学, 2013, 36(5): 32-33.
9.	刘稳根. 从渗漏率剖析非 PVC 膜软袋注射剂生产设备的质量问题. 医药工程设计, 2008, 29(4): 45-46.
10.	刘思川, 谭鸿波, 王利春, 等. 新型双腔室输液袋弱焊装置技术分析与探讨. 企业技术开发, 2016, 35(23): 48-50.
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15.	田洪伍, 吴艾, 姚美君, 等. 一种用于多室输液袋的弱焊条: 201721784860.4. 2017-12-19.
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17.	廖大中. 防渗漏的安全性多药室输液袋: CN200710187964.1. 2009-05-27.
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19.	唐岳, 曾凡云. 隔离带带部份弱焊结构的双室输液袋: CN200620000813.1. 2007-02-07.
20.	邓科, 郭维鹏, 朱水文, 等. 直立式聚丙烯输液袋长径比对输液性能影响的数值研究. 生物医学工程学杂志, 2014, 31(3): 606-611.
21.	刘革新, 程志鹏, 陈得光, 等. 直立式聚丙烯输液袋壁厚度对输液性能影响的数值研究. 生物医学工程与临床, 2013, 17(5): 433-438.
22.	帅进文. 直立式聚丙烯输液过程模拟及气液比优化研究. 芜湖: 安徽工程大学, 2016.
23.	赵鑫源, 李国伟, 吴会斌. 一种新的用于包装中长链脂肪乳、氨基酸和葡萄糖注射液的三室输液袋: CN201120270576.1. 2012-08-15.
24.	国家标准局轻工业部塑料加工应用科学研究所. 软质复合塑料材料剥离实验方法: GB/T 8808-1988. 北京: 中国标准出版社, 1988: 531-533.
25.	倪佳女. PVC膜材力学性能试验研究. 上海: 同济大学, 2009.
26.	王琪, 孔祥安, 朱露山, 等. 聚乙烯材料特性与摩擦系数的关系. 高分子材料科学与工程, 1995(6): 119-123.
27.	庄茁. 基于ABAQUS的有限元分析和应用. 北京: 清华大学出版社, 2009: 418-424.
28.	Pecora I, Sosa E M, Thompson G J, et al. FE simulation of ceiling deployment of a large-scale inflatable structure for tunnel sealing. Thin Wall Struct, 2019, 140: 272-293.
29.	Stewart M. 10-Pipe expansion and flexibility. Surface Production Operations. Boston: Gulf Professional Publishing, 2016: 731-812.

1. Yu Jianchun, Wu Guohao, Tang Yun, et al. Efficacy, safety, and preparation of standardized parenteral nutrition regimens: three-chamber bags vs compounded monobags—a prospective, multicenter, randomized, single-blind clinical trial. Nutr Clin Pract, 2017, 32(4): 545-551.
2. Colomb V, Marlowe M L, Bonnot D, et al. Practical use of a new three-chamber bag for parenteral nutrition in pediatric patients. e-SPEN J, 2012, 7(2): e93-e99.
3. 刘志刚. 输液产品包装容器的现状及发展趋势. 中国药房, 2010, 21(21): 92-93.
4. 王锦芳, 陈国庆, 黄公敏. 软袋输液使用中漏液原因分析及处置. 海峡药学, 2011, 23(9): 189-190.
5. 王殿林. 非 PVC 膜软袋大输液产品漏液原因分析及其解决方案. 机电信息, 2017, 29: 27-30.
6. 赵江. 多室输液袋关键指标的分析与检测. 机电信息, 2010, 13(8): 56-57.
7. 李继强. 非 PVC 多层共挤膜输液用袋焊接工艺优化. 济南: 山东大学, 2017.
8. 宁书慧, 方志勤, 王淼. 非 PVC 膜软袋大输液生产工艺改进. 黑龙江医药科学, 2013, 36(5): 32-33.
9. 刘稳根. 从渗漏率剖析非 PVC 膜软袋注射剂生产设备的质量问题. 医药工程设计, 2008, 29(4): 45-46.
10. 刘思川, 谭鸿波, 王利春, 等. 新型双腔室输液袋弱焊装置技术分析与探讨. 企业技术开发, 2016, 35(23): 48-50.
11. 王学亮. 非 PVC 膜即配型输液弱焊技术研究. 哈尔滨: 哈尔滨工业大学, 2009.
12. 刘伟强, 张爱波, 易建波, 等. 一种输液袋焊接模具: CN201520710686.3. 2015-09-15.
13. 籍文涛, 潘旭辉, 王党琪, 等. 油热式软袋输液生产线模具温控系统: CN201220198164.6. 2012-11-28.
14. 邓茂林, 何颖, 谭鸿波, 等. 一种用于输液袋体焊接的模具: CN201520058534. X. 2015-06-24.
15. 田洪伍, 吴艾, 姚美君, 等. 一种用于多室输液袋的弱焊条: 201721784860.4. 2017-12-19.
16. 刘思川, 葛均友, 谭鸿波, 等. 多腔室输液袋: CN201710585265.6. 2017-07-18.
17. 廖大中. 防渗漏的安全性多药室输液袋: CN200710187964.1. 2009-05-27.
18. Oka M, Ohnishi M, Hamazaki S, et al. Medical multi-chamber container: 76582792010. 2010-02-09.
19. 唐岳, 曾凡云. 隔离带带部份弱焊结构的双室输液袋: CN200620000813.1. 2007-02-07.
20. 邓科, 郭维鹏, 朱水文, 等. 直立式聚丙烯输液袋长径比对输液性能影响的数值研究. 生物医学工程学杂志, 2014, 31(3): 606-611.
21. 刘革新, 程志鹏, 陈得光, 等. 直立式聚丙烯输液袋壁厚度对输液性能影响的数值研究. 生物医学工程与临床, 2013, 17(5): 433-438.
22. 帅进文. 直立式聚丙烯输液过程模拟及气液比优化研究. 芜湖: 安徽工程大学, 2016.
23. 赵鑫源, 李国伟, 吴会斌. 一种新的用于包装中长链脂肪乳、氨基酸和葡萄糖注射液的三室输液袋: CN201120270576.1. 2012-08-15.
24. 国家标准局轻工业部塑料加工应用科学研究所. 软质复合塑料材料剥离实验方法: GB/T 8808-1988. 北京: 中国标准出版社, 1988: 531-533.
25. 倪佳女. PVC膜材力学性能试验研究. 上海: 同济大学, 2009.
26. 王琪, 孔祥安, 朱露山, 等. 聚乙烯材料特性与摩擦系数的关系. 高分子材料科学与工程, 1995(6): 119-123.
27. 庄茁. 基于ABAQUS的有限元分析和应用. 北京: 清华大学出版社, 2009: 418-424.
28. Pecora I, Sosa E M, Thompson G J, et al. FE simulation of ceiling deployment of a large-scale inflatable structure for tunnel sealing. Thin Wall Struct, 2019, 140: 272-293.
29. Stewart M. 10-Pipe expansion and flexibility. Surface Production Operations. Boston: Gulf Professional Publishing, 2016: 731-812.

Journal of Biomedical Engineering

Finite element method simulating bursting process of multi-chamber flexible package infusion bag

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