Fluid-solid Interaction Model for Hydraulic Reciprocating O-ring Seals

Elastohydrodynamic lubrication characteristics of hydraulic reciprocating seals have significant effects on sealing and tribology performances of hydraulic actuators, especially in high parameter hydraulic systems. Only elastic deformations of hydraulic reciprocating seals were discussed, and hydrodynamic effects were neglected in many studies. The physical process of the fluid-solid interaction effect did not be clearly presented in the existing fluid-solid interaction models for hydraulic reciprocating O-ring seals, and few of these models had been simultaneously validated through experiments. By exploring the physical process of the fluid-solid interaction effect of the hydraulic reciprocating O-ring seal, a numerical fluid-solid interaction model consisting of fluid lubrication, contact mechanics, asperity contact and elastic deformation analyses is constructed with an iterative procedure. With the SRV friction and wear tester, the experiments are performed to investigate the elastohydrodynamic lubrication characteristics of the O-ring seal. The regularity of the friction coefficient varying with the speed of reciprocating motion is obtained in the mixed lubrication condition. The experimental result is used to validate the fluid-solid interaction model. Based on the model, The elastohydrodynamic lubrication characteristics of the hydraulic reciprocating O-ring seal are presented respectively in the dry friction, mixed lubrication and full film lubrication conditions, including of the contact pressure, film thickness, friction coefficient, liquid film pressure and viscous shear stress in the sealing zone. The proposed numerical fluid-solid interaction model can be effectively used to analyze the operation characteristics of the hydraulic reciprocating O-ring seal, and can also be widely used to study other hydraulic reciprocating seals.

Influence Analysis of Secondary O-ring Seals in Dynamic Behavior of Spiral Groove Gas Face Seals

The current research on secondary O-ring seals used in mechanical seals has begun to focus on their dynamic properties. However, detailed analysis of the dynamic properties of O-ring seals in spiral groove gas face seals is lacking. In particular a transient study and a difference analysis of steady-state and transient performance are imperative. In this paper, a case study is performed to gauge the effect of secondary O-ring seals on the dynamic behavior（steady-state performance and transient performance） of face seals. A numerical finite element method（FEM） model is developed for the dynamic analysis of spiral groove gas face seals with a flexibly mounted stator in the axial and angular modes. The rotor tilt angle, static stator tilt angle and O-ring damping are selected to investigate the effect of O-ring seals on face seals during stable running operation. The results show that the angular factor can be ignored to save time in the simulation under small damping or undamped conditions. However, large O-ring damping has an enormous effect on the angular phase difference of mated rings, affecting the steady-state performance of face seals and largely increasing the possibility of face contact that reduces the service life of face seals. A pressure drop fluctuation is carried out to analyze the effect of O-ring seals on the transient performance of face seals. The results show that face seals could remain stable without support stiffness and O-ring damping during normal stable operation but may enter a large-leakage state when confronting instantaneous fluctuations. The oscillation-amplitude shortening effect of O-ring damping on the axial mode is much greater than that on the angular modes and O-ring damping prefers to cater for axial motion at the cost of angular motion. This research proposes a detailed dynamic-property study of O-ring seals in spiral groove gas face seals, to assist in the design of face seals.

Effect of nitrile butadiene rubber hardness on the sealing characteristics of hydraulic O-ring rod seals

The nitrile butadiene rubber(NBR)hardness effect on the sealing characteristics of hydraulic O-ring rod seals is analyzed based on a mixed lubrication elastohydrodynamic model.Parameterized studies are conducted to reveal the mechanism of the influence of rubber hardness on the static and dynamic behavior of seals.The optimized selections of rubber hardness are then investigated under different conditions.Results show that the low hardness seal is prone to stress concentration due to the extrusion effect under high pressure conditions;it is also more prone to leaking.A high hardness seal can better prevent leakage by reducing film thickness but it will cause large frictional power loss and increase the probability of wear failure.The choice of low hardness is recommended to reduce friction with the premise that leakage requirements are met.

Experimental study on the failure factors of the O-ring for long-term working

The O-ring in the rotary dynamic sealing system of gas meters should have outstanding long-term sealing performance under the conditions of high and low temperature,which can ensure the safety of gas meters.In this paper,based on the O-ring sealing mechanism,taking the compression set as the main sealing index,a finite element simulation method is used to analyze the failure charac-teristics under different conditions according to the constitutive relation of nitrile rubber.Then,using the orthogonal test method for the O-ring sealing performance index,the main factors which affect the law of long-term test are analysed,and the orthogonal regression mathematical model that can predict the compression set is obtained.Finally,the O-ring is improved according to the model,and the test results show that the performance of the new O-rings with high and low temperature resistance is greatly improved and meets the expected target requirements.

Sealing properties and structure optimization of packer rubber under high pressure and high temperature

During hydraulic fracturing operations of low-permeability reservoirs,packers are the key component to ensure the success of multistage fracturing.Packers enable sections of the wellbore to be sealed off and separately fractured by hydraulic pressure,one at a time,while the remainder of the wellbore is not affected.However,reliable sealing properties of the packer rubber are required to meet the high-pressure and high-temperature(HPHT)conditions of reservoirs(such as 70 MPa and 170 ℃).In this study,the structures of the packer rubber with two different materials are optimized numerically by ABAQUS and validated by experiments.The optimization process starts from the packer rubber with a conventional structure,and then,the weakest spots are identified by ABAQUS and improved by slightly varying its structure.This process is iterative,and the final optimized structure of a single rubber barrel with expanding back-up rings is achieved.For the structure of three rubber barrels with metallic protective covers,both HNBR and AFLAS fail under HPHT conditions.For the final optimized structure,the packer rubber made of AFLAS can work better under HPHT than that made of HNBR which ruptures after setting.The results show that the optimized structure of a single rubber barrel with expanding back-up rings and the material AFLAS are a good combination for the packer rubber playing an excellent sealing performance in multistage fracturing in horizontal wells.

Synergistic Antiflaming of Expandable Graphite on the Sealing Silicone Rubber

To study the effects of different proportions of aluminum hydroxide and expandable graphite （EG） composites on flame retardation, sealing, mechanical, electrical and other properties of RTV- 1, aluminum hydroxide/expandable graphite （ATH/EG） and silicone rubber composites were prepared by the compression molding method. The experimental results show that heat resistance improves with the increase of proportion of EG. Although the resistance coefficient changes, the composite materials still keep good electrical insulating property. Moreover, oxygen index and expansion index rise first then fall. When ATH/EG is 1：1, the oxygen index reaches the highest; the mechanical property of the silicone rubber is not affected under various environments such as acid, alkali, oily, artificial sea water environments, etc.

Characteristics of seal shell body's rubber ring with bionic dimpled surfaces of aerodynamic extinguishing cannon

To solve the problem of sealing between the barrel and the rubber ring of shell body during an launching process of aerodynamic extinguishing cannon, a rubber sealing model with bionic dimpled characteristics was established based on the theory of bionic dimpled drag reduction and the principle of rubber sealing. In condition that the bionic dimpled characteristic diameters were 1, 2, 3, 4, and 5 mm, respectively, by numerical simulation, the influence of the installing compression of the rubber sealing ring on its surface stress and deformation was analyzed, and sealing performance of the rubber ring with different diameters of bionic dimpled was studied. The results show that the deformation of rubber ring appears prominent nonlinear characteristics when compression is increased from 1.5 mm to 2.5 ram. When the compression is 2.5 mm, the equivalent compression stress on the sealing areas of both sides of the rubber seal is greater than the working pressure of aerodynamic extinguishing cannon, which could meet the sealing requirement and would not cause leakage. So the rubber sealing ring with bionic dimpled surface possesses a good sealing characteristic and has no negative effect on the sealing of shell body; When the compression is 2.5 mm, the larger equivalent stress on the edge of sealing ring and the more even stress distribution in the high pressure area are generated due to the smaller compressive stress on the bionic dimple areas, which lays a foundation for the drag reduction characteristics of the shell body＇s rubber ring with bionic dimpled surface.

EXPERIMENTAL STUDY ON THE LOAD DECAY AND ITS EFFECT ON LEAK RATE OFO-RING

Experimental studies on load decay and leak rate of O-rings made of two kindsof silicone rubber are conducted. The results show that the characteristic of load decay isrelative to the material and temperature of O-rings; the rate of load decay increases with the riseof temperature; the effects of load decay on leak rate of O-rings are negligible at roomtemperature, but they are notable at high temperature, and they are related to the material ofO-rings. On the basis of study on the theory of load decay and analysis to the results ofexperiments, a theoretical model is developed to describe the load decay characteristic of O-rings,and it matches the experimental data very well. By the study of time-temperature equivalence of loaddecay, the interconvertting equation of test data of load decay at different temperatures isobtained.

Analysis and optimization of nitrile butadiene rubber sealing mechanism of ball valve

An approach for analyzing and optimizing sealing mechanism of ball valve made of nitrile butadiene rubber(NBR) with finite element method was presented. The Mooney-Rivlin hyperelastic material model was chosen to characterize NBR sealing, as it has been recommended in the similar applications. That is, NBR sealing was modeled as incompressible hyperelasticity, as well as the assumption of isotropic flow. The results illustrate the structural pressure and contact pressure on the contact surface, which shows that the NBR sealing mechanism is very suitable for sealing after dimension optimization.

O-ring橡胶密封圈的耐老化性能研究

通过自然老化、加速老化和介质老化对手表丁腈橡胶O-ring密封圈的耐老化性能进行研究。结果表明,经过40个月常温下自然老化后,O-ring密封圈老化性能未完全失效;在60℃、85℃和100℃三种温度下的加速老化下,24h内对老化性能影响较大,随着加速老化时间的延长,开始进入缓慢老化阶段;其耐盐雾腐蚀性能较好,此外,酒精浸泡30min,对O-ring密封性能无影响。

Study on Production of Rubber Sealing Strips with Steel Bones

Rubber sealing strips with steel bones are used in car manufacturing that produced in large quantities. Cutting processes, such as milling and punching, are needed when the strips are produced. Accuracy, smoothness and flatness of the machined surface have to be guaranteed in the cutting process; moreover, deformation of the steel bone and peeling-off of the rubber must be avoided. Therefore cutting action of rubber/steel strips differs from that of rubber or metal workpiece separately. In this paper, milling and punching of rubber/steel strips were studied with the aim to increase the part quality of a production line for sealing strips of cars. Suitable cutting tools and fixtures are both necessary for cutting of the strips. The teeth of the milling saw should be made knife-edged and the cutting edge of the punching tool be inclined. Fixtures should be used to sustain the workpiece and resist deformation. By using of suitable tools and fixtures, high quality of rubber/steel sealing strips is achieved in the production line.

Thermal-Mechanical Coupled FE Analysis for Rotary Shaft Seals

The aim of this paper is to model the steady-state condition of a rotary shaft seal (RSS) system. For this, an iterative thermal-mechanical algorithm was developed based on incremental finite element analyzes. The behavior of the seal’s rubber material was taken into account by a large-strain viscoelastic, so called generalized Maxwell model, based on Dynamic Mechanical Thermal Analyses (DMTA) and tensile measurements. The pre-loaded garter spring was modelled with a bilinear material model and the shaft was assumed to be linear elastic. The density, coefficient of thermal expansion and the thermal conductance of the materials were taken into consideration during simulation. The friction between the rotary shaft seal and the shaft was simplified and modelled as a constant parameter. The iterative algorithm was evaluated at two different times, right after assembly and 1 h after assembly, so that rubber material’s stress relaxation effects are also incorporated. The results show good correlation with the literature data, which state that the permissible temperature for NBR70 (nitrile butadiene rubber) material contacting with ~80 mm shaft diameter, rotating at 2600/min is 100°C. The results show 107°C and 104°C for the two iterations. The effect of friction induced temperature, changes the width of the contact area between the seal and the shaft, and significantly reduces the contact pressure.

小行星样品密封设计及验证

中国计划开展探测编号为2016H03的近地小行星并采集样品返回地面,测定小行星样品的物理性质、化学成分与矿物成分,为小行星起源与演化、太阳系的形成与演化过程提供科学依据。针对中国首次近地小行星采样封装任务,设计多种样密封方案,综合考虑密封力、密封面样品颗粒污染物防护等因素,采用双弹性体径向密封方案,并开展密封方案验证工作,通过高温、低温及模拟尘埃污染漏率试验,密封漏率优于5×10^(-6)Pa·m^(3)·s^(-1),满足小行星样品密封要求。

考虑蠕变特性的橡胶微凸体与金属表面接触特性分析

金属-橡胶接触广泛存在于密封结构中,密封接触表面上微凸体间的相互作用会直接影响整个密封界面的接触特性,进而影响其密封性能。基于粗糙密封界面的单个微凸体,考虑橡胶的蠕变特性,采用理论分析和仿真研究相结合的方式研究橡胶微凸体与金属表面的接触特性。通过橡胶蠕变特性的实验结果,构建橡胶蠕变计算模型;构建半球微凸体与金属平板间的有限元模型,进行考虑蠕变特性的仿真,分析其接触特性,并与Hertz接触理论的计算值进行对比。结果表明:在蠕变阶段,接触半径、法向变形量和最大等效蠕变应变均随蠕变时间的增加而增大,最大接触压力随蠕变时间增大而减小,这均可能导致密封性能的下降;随压力载荷的增大,接触半径、法向变形量、最大接触压力和最大等效蠕变应变均增大,但增大的趋势逐渐减小;橡胶微凸体与金属表面间的等效模量随蠕变时间的增加而减小,随压力载荷增大而增大。

油罐车自主加注臂密封圈响应面优化及分析

为了提高油罐车自主加注臂前端快接装置的密封性能,设计了一种内胀式橡胶密封圈,并结合响应面法和有限元法对密封圈进行了优化和分析。首先,基于有限元软件ANSYS Workbench对密封圈进行建模和仿真,研究了密封圈的倒圆半径、厚度和压缩量对密封圈性能的影响;然后,将密封圈与管壁的接触面积、接触压力和所受等效应力作为优化目标,利用Design⁃Expert软件建立了密封结构的优化模型,并通过多目标优化获得最优设计方案;最后,进行了密封圈优化前后的性能对比和分析。数值测试表明,在最大3 MPa介质压力下,优化后密封圈的接触压力提升了1.3 MPa,有效接触面积更大,且接触带更加集中,有利于实现快接装置和油罐车加注口的有效密封,同时等效应力降低了4.3%,有助于延长密封圈的使用寿命。

Y形组合密封的密封性能研究

应用ABAQUS软件建立YO组合密封的有限元模型,分别比较Y形组合密封与Y形密封、聚氨酯和丁腈橡胶2种材料的Y形组合密封,在密封区域的静态接触压力和Mises应力分布,分析O形圈截面直径对2种材料Y形组合密封性能的影响规律。结果表明:Y形组合密封在密封区域的接触压力和Mises应力均大于相同规格、材料的Y形圈,且外行程时Y形组合密封接触压力增大更明显,应力分布更均匀,验证了Y形组合密封的双重密封和改善根部抗撕裂的特性;在O形圈截面直径相同的情况下,聚氨酯组合密封外行程与内行程的最大接触压力差值远远高于丁腈橡胶组合密封,而丁腈橡胶组合密封Mises应力分布更均匀;随着O形圈截面直径的增大,聚氨酯组合密封的最大接触压力呈现先增大后减小的趋势,丁腈橡胶组合密封呈现逐渐减小的趋势,但两者的Mises应力均呈现逐渐增大的趋势,且丁腈橡胶组合密封增大更显著。研究结果为不同工作条件下密封件的选择提供了参考依据。

油田在用封隔器胶筒密封材料的老化行为

选择在用的丁腈橡胶(NBR)、氢化丁腈橡胶(HNBR)以及HNBR/氟橡胶(FKM)5种封隔器胶筒的橡胶材料作为研究对象,分别研究了其热稳定性、玻璃化转变温度以及在热空气介质和矿化水介质中的耐老化行为。结果表明,受FKM的作用,HNBR/FKM共混胶试样D表现出最好的热稳定性,同时差示扫描量热分析表明HNBR和FKM具有较好的相容性;在热空气介质中,试样D具有最高的拉伸强度保持率以及扯断伸长率保持率,表现出最好的耐老化性能,在矿化水介质中,水介质明显抑制了热氧老化反应,在100~120℃的矿化水中5种橡胶材料的扯断伸长率随老化时间延长变化率均较小,表现出较好的抗老化能力。然而在150℃的矿化水中,NBR试样E的扯断伸长率衰减较快,试样D的扯断伸长率保持率最佳,可作为油田分层注采井高温长效密封材料使用。

端部弹簧式封隔器胶筒的密封性能仿真分析

端部弹簧式封隔器胶筒作为一种新型设计的井下密封工具,为验证该工具能否达到40 MPa的密封设计要求,得到该工具在不同环境围压和坐封载荷下对胶筒密封性能的影响规律进行了仿真分析。仿真分析采用有限元分析的理论,借助物理实验确定弹簧和橡胶的仿真参数,采用轴对称的分析方法对建立的简化等效有限元模型进行分析计算。分析结果表明,在10~50 MPa环境围压载荷下,中胶筒的密封压力变化量只有0.27 MPa,环境围压载荷对胶筒密封性能影响很小。通过分析计算4个不同的坐封载荷得到坐封载荷和胶筒密封压力的关系曲线,并得到坐封载荷在大于8 t的情况下能够达到密封40 MPa设计要求的结论,为后续的现场试验施工和结构优化提供了理论支撑依据。

3种汽车密封条用TPV的性能研究

研究了3种国产汽车密封条用热塑性硫化橡胶(TPV)产品(TPV-1,TPV-2,TPV-3)的力学性能、耐热性能、微观形貌和热氧老化性能。结果表明:3个产品的树脂相可能均为嵌段共聚聚丙烯(PP)。3个产品中,TPV-3的拉伸强度、断裂伸长率和撕裂强度均最大,TPV-1的拉伸强度和断裂伸长率均最小,TPV-1和TPV-2的撕裂强度相当,TPV-1的耐热性能和热氧老化性能均最好,TPV-3的耐热性能最差,TPV-2和TPV-3的热氧老化性能相当,在温度70℃、时间22 h、压缩率25%下,TPV-1的压缩永久变形最大,TPV-3最小,在温度23℃、时间72 h、压缩率25%下,TPV-1和TPV-3的压缩永久变形相当,TPV-2的压缩永久变形最小。

温度及其波动对橡胶密封硫化过程影响的仿真分析

硫化是橡胶密封成型过程的关键工艺,对橡胶密封产品性能有决定性影响。目前橡胶行业多采用经验式硫化成型方法,对橡胶密封硫化演变过程缺乏理解,难以理论指导橡胶密封实际生产过程。针对这一制约橡胶密封质量提升的薄弱环节,开展了橡胶密封硫化成型过程数值仿真研究。基于胶料的积分型反应动力学模型与变物性参数传热控制方程,建立了橡胶制品热-化学耦合的瞬态仿真模型,实现了橡胶制品成型过程时变温度场及硫化程度场的实时预测,并通过试验验证了模型及求解方法的正确性。进而,仿真分析了典型结构密封件的硫化过程,探讨了模具温度、胶料预热温度和温度波动行为对橡胶密封硫化成型过程的影响规律,最后为橡胶密封实际硫化生产提供了参考。