容器泄漏检测中的橡胶圈氦渗透

摘要/Abstract

摘要： 放射性物品运输容器通常使用O型橡胶密封圈来实现对内容物的包容和气密性要求,在气密性定量检测方法中最常用的是以氦气作示踪气体,搭配氦质谱仪作气体探测器,使用包层充气法或包层抽真空法进行检测。在泄漏检测时,除了由于端盖与密封圈之间的裂隙或缺陷造成的氦泄漏,氦气还会经由橡胶圈内部向压差小的一侧进行渗透,从而对真实泄漏率造成干扰。氦气渗透过程经过了溶解、扩散和解吸三个过程,衡量橡胶透气性的参数是渗透系数,由溶解系数和扩散系数组成,均会受到气体种类、橡胶种类和环境温度影响。实测过程中氦气渗透导致的泄漏率大小还会受到橡胶两侧压差、裸露面积、厚度、压缩率和压差存在时间等因素影响。本文从减小压差存在时间的角度出发,提出了一种采用氦质谱仪进行泄漏检测的方法,可用于密封容器的气密性定量检测,检测步骤主要分为管路连接系统的定性检漏、测量前仪器本底表征、测量前仪器校准、实际漏率测量、测量后仪器校准和测量后仪器本底表征共六步。在某容器出厂前泄漏检测充氦后8 min观察到了明显的氦渗透,泄漏率达1.2×10^-7 Pa·m³/s,更换被氦沾污的密封圈后采用本文所述方法再次检测,因减少了氦渗透泄漏率,相同容器情况下测得泄漏率为7×10^-10 Pa·m³/s。

关键词: 泄漏检测, 渗透, 氦气, 橡胶

Abstract: The O-ring sealing rubber is usually used in container for radioactive material transport to achieve the containment of the contents and air-tightness requirements. Among the quantitative gas-leakage testing methods, the most commonly used one is gas filled envelope or evacuated envelope method by using helium as the tracer gas and helium mass spectrometer as the gas detector. During leakage testing, in addition to helium leakage caused by cracks or defects between the cap and the O-ring, helium will also permeate through the O-ring to the side with smaller pressure, thus interfering with the true leakage rate. The helium permeation process goes through three processes: dissolution, diffusion and desorption. The permeability of rubber is composed of dissolution and diffusion coefficient. Both of them can be affected by the type of gas, rubber and environmental temperature. Actually, the leakage rate caused by helium gas permeation is also affected by the pressure difference, exposed area, thickness, compression rate of rubber and the existence time of pressure difference, etc. This paper proposes a gas filled envelope method using helium mass spectrometer as gas detector, hoping to decrease the existence time of pressure difference, which can be used in quantitatively testing for sealed containers. Testing is divided into six steps: qualitative leakage detection of pipeline connection systems, background characterization before measurement, measuring instrument calibration before measurement, the actual leakage rate measurement, measuring instrument calibration after measurement and background characterization after measurement. Obvious helium permeation has been observed after helium is pumped into the envelope 8 minutes later during the delivery inspection of a container, and the leakage rate reaches 1.2×10^-7 Pa·m³/s. After replacing the contaminated O-ring, this method is used to test the same container again. As a result, helium permeation is largely reduced and the leakage rate goes down to 7×10^-10 Pa·m³/s.

Key words: leakage testing, permeation, helium, rubber

中图分类号:

TL93+2

王鹏毅, 庄大杰, 陈磊, 孙洪超, 李国强. 容器泄漏检测中的橡胶圈氦渗透[J]. 辐射防护, 2023, 43(S1): 78-83.

WANG Pengyi, ZHUANG Dajie, CHEN Lei, SUN Hongchao, LI Guoqiang. Helium permeability in rubber rings during container leakage testing[J]. RADIATION PROTECTION, 2023, 43(S1): 78-83.

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