Mechanical properties of high-strength concrete subjected to high temperature by stressed test

Recently, the effects of high temperature on compressive strength and elastic modulus of high strength concrete were experimentally investigated. The present study is aimed to study the effect of elevated temperatures ranging from 20 ℃ to 700 ℃ on the material mechanical properties of high-strength concrete of 40, 60 and 80 MPa grade. During the strength test, the specimens are subjected to a 25% of ultimate compressive strength at room temperature and sustained during heating, and when the target temperature is reached, the specimens are loaded to failure. The tests were conducted at various temperatures (20-700 ℃) for concretes made with W/B ratios of 46%, 32% and 25%, respectively. The results show that the relative values of compressive strength and elastic modulus decrease with increasing compressive strength grade of specimen.

Design of the material performance test apparatus for high temperature gas-cooled reactor

Most materials can be easily corroded or ineffective in carbonaceous atmospheres at high temperatures in the reactor core of the high temperature gas-cooled reactor(HTGR).To solve the problem,a material performance test apparatus was built to provide reliable materials and technical support for relevant experiments of the HTGR.The apparatus uses a center high-purity graphite heater and surrounding thermal insulating layers made of carbon fiber felt to form a strong carbon reducing atmosphere inside the apparatus.Specially designed tungsten rhenium thermocouples which can endure high temperatures in carbonaceous atmospheres are used to control the temperature field.A typical experimental process was analyzed in the paper,which lasted 76 hours including seven stages.Experimental results showed the test apparatus could completely simulate the carbon reduction atmosphere and high temperature environment the same as that confronted in the real reactor and the performance of screened materials had been successfully tested and verified.Test temperature in the apparatus could be elevated up to 1600oC,which covered the whole temperature range of the normal operation and accident condition of HTGR and could fully meet the test requirements of materials used in the reactor.

HIGH TEMPERATURE MATERIALS AND STRENGTH STUDY IN CHINA

In the past half century China has developed and formed her own system ofhigh temperature materials for power, automobile and aero-engine industries in the temperature rangefrom 550 deg C to 1100 deg C. These high temperature materials include heat-resisting steels,iron-base, nickel-iron-base and nickel-base superalloys. Some achievements - in high temperaturestrength study, new technologies and new alloy development are also discussed.

Pt-Al₂OM₃Composite Material Designed for Cyclic Production of Optical Glasses under High Temperature Conditions

The article considers one of the possible approaches to the solution of an urgent issue of metal consumption reduction, increase of operating life and maximum operating temperature as well as reduction of irrecoverable losses of platinum products and alloys when operating under high temperature conditions, particularly for glassblowing and single crystal growing crucibles. A two-layered composite material based on platinum-group metals and corundum plasma ceramics is thoroughly investigated. A successful experience of crucibles exploitation, designed for production of high temperature optical glasses from the composite and results of the research on composite material specimens are described.

Elevated temperature endurance and creep properties of extruded 2D70 Al alloy rods

The elevated temperature performances of 2D70 Al alloy hot extrusion rods after two-stage homogenization and intensive deformation were studied by measuring the elevated temperature enduring strength and the creep ultimate strength. The fracture morphology of some selected samples after testing at different elevated temperatures was observed by scanning electron microscopy （SEM）. The results indicate that, as the test temperature increases, the elevated temperature enduring strength of 2D70 Al alloy decreases gradually. In a comparison between 150 C and 240 C, the notch enduring strength drops from 375 to 185 MPa and the smooth enduring strength drops from 337 to 130 MPa. Enduring strength is not sensitive to the notch. The notch sensitivity ratio （NSR） coefficient is in the range of 1.119 to 1.423 from 150 C to 240 C. The creep test results show that, as the test temperature increases from 150 C to 240 C, the creep ultimate strength of 2D70 Al alloy rods drops gradually from 312 to 117 MPa.

Experimental study on stress-strain-temperature models for structural steel

For the research on steel structure in fire,it is very important to determine the properties of structural steel at elevated temperature.Up to now,the high-temperature properties of material is believed to be related to only temperature state,which is not precise enough to simulate the behavior of steel structures under different combinations of heating,cooling,loading,and unloading.To analyze the influence of the temperature-load history on the steel properties,a series of tests were carried out under different temperature-load paths about steel Q235,which is widely used in steel structures in China.In this paper,the method to set the temperature-load paths was introduced;the variety regulation of steel properties changing with temperature was analyzed under different paths;according to experimental results,the formulas of elastic modulus and yield strength at elevated temperature were fitted,and the stress-strain-temperature 3D relationships of structural steel under different paths were presented.

气体封隔器密封单元的增强方法与安全分析

气体封隔器胶筒是实现气井分层分段开采的关键部件。常规三胶筒结构在坐封时易发生初始破坏,导致胶筒整体应力水平降低,密封安全性储备不足。为此,提出一种多材料组合式密封单元的增强方法,用于HPHT105-232-V0型含硫化氢高温高压气体封隔器密封单元的设计;基于拉伸试验和Yeoh理论获得橡胶的本构模型参数;在温度204℃、坐封力200 kN和环空压力70 MPa下,分析了胶筒的应力和变形规律;试验测试了增强单元的密封安全性。分析结果表明:HPHT105-232-V0型封隔器密封单元胶筒的最大变形量为94.785 mm,最大接触应力为240 MPa,位于金属护环与套管接触区域。根据API标准,对HPHT105-232-V0型封隔器实物进行测试试验,坐封时胶筒未发生初始破坏,密封单元的整体应力水平提高;稳压过程胶筒压降幅度小于1%;整个试验测试过程中,密封单元无气泡溢出,封隔器卸载后胶筒结构无明显的塑性变形。研究结果表明,采用该增强方法所设计的多材料组合式密封单元具有良好的密封性能,满足极端环境下的密封安全性要求。

高硅高强钢氧化铁皮高温剥离试验与分析

通过Gleeble热模拟试验机对高硅高强钢热轧板进行了不同加热温度高温加热试验,模拟“一次氧化铁皮”生成,并对试样进行高温拉伸与空气喷气快冷,模拟实际生产时除鳞状态,考察残留氧化铁皮形貌与结构特点。发现:1200℃以上明显出现了氧化铁皮的液化情况,氧化铁皮剥离量大,1150℃氧化铁皮呈现较为平整形貌,剥离量少;在当前试验条件下,1150℃残留铁橄榄石层最薄,其残留氧化铁皮结构更易清除。

纳米SiO_(2)增强高强套筒灌浆料及高温后性能试验研究

研究了常温下不同纳米SiO_(2)(NS)掺量(0、0.4%、0.8%、1.2%、1.6%、2.0%)对高强套筒灌浆料流动度和强度的影响,以及不同高温温度(150、200、250℃)下NS掺量对高强套筒灌浆料质量损失和强度的影响,并进行了微观机理分析。结果表明:常温下,NS的掺入降低了灌浆料的流动度,灌浆料的强度随NS掺量的增加先增大后降低;高温后,灌浆料的质量损失率随温度的升高逐渐增大,抗折强度逐渐降低,抗压强度先增大后降低;NS的掺入能够降低灌浆料的质量损失率和抗折强度损失率,提高抗压强度,且随着NS掺量的增加,质量损失率和抗折强度损失率先降低后增大;NS能够改善灌浆料的内部孔结构;随着温度的升高,灌浆料的内部结构先密实后疏松。

铝合金铆接结构高温热暴露强度影响研究

针对高温热暴露对飞机常用铝合金铆接结构强度性能的影响,以2024-T3板材和NAS1097KE5铆钉组成的连接件为对象,开展室温、高温以及高温热暴露后的有限元分析和试验研究。材料非线性和高温性能衰减的精细有限元模型可以准确地模拟该类铝合金铆接结构在室温和不同高温热暴露环境下的强度性能,得出的分析结果与试验结果的差异不超过5%;基于有限元分析拟合的公式对高温热暴露状态下连接强度的预测结果与试验结果的误差不超过4%,经过保守性修正后可应用于工程实际。所建立的高温热暴露状态下铝合金铆接结构连接强度的计算方法可推广到其他类似结构。

煤矿巷道断层滑移型冲击地压试验系统研制与试验验证

断层滑移型冲击地压是煤矿冲击地压的主要类型,目前对其发生全过程缺乏系统研究,其机理与防控仍是根本难题。为实现断层滑移型冲击地压的试验模拟,研制了煤矿巷道断层滑移型冲击地压试验系统,开发了低强高脆相似模拟材料,制备了包含断层与巷道的大尺寸相似模型,开展了一系列验证试验,实现了巷道冲击破坏模拟与断层剪切滑移模拟。煤矿巷道断层滑移型冲击地压试验系统具备三向六面加载功能,竖向加载能力为20 MPa,模型尺寸为1.50 m×0.75 m×0.75 m;主体框架创新采用键板连接,确保了主体框架的高刚度;发明了蜂窝加载壳结构,实现了密集油缸群加载,能够满足断层滑移型冲击地压试验模拟的要求。开发了适用于断层滑移型冲击地压模拟的相似材料,材料以水玻璃为胶结物、以氟硅酸钠为固化剂、以滑石粉为骨料,单轴抗压强度介于3.44~7.81 MPa,冲击能指数为9.2,弹性能指数为8.83,兼具低强高脆特性。基于试验系统和低强高脆材料实现了静载巷道冲击破坏模拟,验证了低强高脆相似材料模拟巷道冲击破坏的可行性,获得了巷道极限平衡状态的加载条件,巷道帮部连续片落为巷道冲击破坏的显著前兆特征。实现了粗糙锯齿断层的剪切滑移模拟,证实粗糙断层剪切滑移会对巷道形成动载扰动,获得了断层剪切滑移的合理加载方式,采用动区顶部先加载、底部后卸载的方式能够实现断层的瞬间滑移,并能消除对静区应力状态的影响。

高强度等四面体树脂固结堵漏剂的研制及应用

川渝地区在钻井过程中井漏频发,部分区域钻遇复杂地层发生恶性漏失,常常需要多次堵漏或多种堵漏工艺才能封堵成功,严重增加了钻井成本。通过对现有堵漏工艺进行分析,针对裂缝架桥填充原理,通过将高强度等四面体树脂作为主架桥材料、片状树脂及热固性树脂作为充填材料、纤维材料进行缠绕交联后研制成一种一袋式温控胶凝树脂固结堵漏材料YDFD。针对小裂缝,溶洞类、失返性(大裂缝)、呼吸性地层漏失情况,分别选用小、中、大3个型号的一袋式胶凝树脂固结堵漏剂进行级配,通过温控剂调节堵漏浆的固化时间保障施工安全、实现对漏层的精准封堵,在川渝油气井区处理井漏复杂过程中获得93%的一次堵漏成功率,达到了很好的应用效果,该工艺技术在油气田处理井漏难题时可推广应用。

900 MPa级管线钢热处理工艺优化及韧性波动分析

通过三因素三水平正交热处理试验,探索新型900 MPa级低合金高强韧管线用钢的最优热处理工艺,借助OM、SEM、TEM等手段,对管线钢韧性波动原因进行了全面分析。结果表明,各因素(淬火温度、回火温度、回火时间)对钢的力学性能(冲击功、强度性能和延伸率)的影响具有不同优先级,确认了最优工艺参数为淬火温度890℃、回火温度590℃、保温时间60 min。随着回火温度的升高和保温时间的延长,析出物数量增多且趋于球化,同时组织软化,位错密度降低,这些因素是管线钢韧性提高的主要原因。相比之下,细小弥散分布的夹杂物对韧性的提升贡献较小。尽管回火温度升高和保温时间延长也会导致析出相尺寸增大和组织粗化,使管线钢韧性降低,但这种降低效果远小于前述增韧因素带来的正面影响。

定载荷条件下树脂基材料高温收缩量实时测量

为研究树脂基材料高温收缩量,提出一种测量定载荷条件下复合材料高温收缩量的方法,根据此方法自行设计搭建了复合材料高温收缩过程试验测量装置。以不同树脂基复合材料为研究对象,进行定载荷条件下树脂基复合材料高温收缩过程试验测量,获得碳板热面处及压头冷面处位移变化,得出树脂基复合材料的高温收缩量及冷却后收缩量。研究结果表明:试验装置能够实现定载荷条件下树脂基材料高温收缩量实时测量;无论加热过程或冷却后,试验件最大变形绝对量不超过0.37 mm;加热过程中编织石英酚醛复合材料最大变形率不超过6.43‰,石英杂化酚醛复合材料最大变形率不超过3.76‰;冷却后编织石英酚醛复合材料最大变形率不超过4.57‰,石英杂化酚醛复合材料不超过6.87‰;试验结果验证了该测量方法的正确性及有效性,并为该类材料的高温收缩及匹配分析提供了基础物性数据。

空间站高温材料科学实验系统热控设计及验证

中国空间站高温材料科学实验系统(HTMSES)是中国新一代的可长期在轨运行的综合型多功能空间材料实验装置,其组成复杂、布局紧凑、实验温度高、部组件散热困难,使热控设计难度较大。基于液冷主动控温、辐射间接控温、结构热控一体化协同优化设计等多种思路对热控组件进行设计,有效解决热控难题。利用有限元分析软件计算科学实验系统热设计的温度结果;然后开展加热实验对热设计方案进行验证。数据显示HTMSES在提供材料制备所需要的最严苛实验工况(1200℃)情况下,各关键部件处于友好的温度范围内,其中电机最高温度为42.2℃,编码器最高温度为40.6℃,丝杠最高温度为62.4℃,滑块最高温度为59.6℃,导轨最高温度为57.3℃,科学实验系统皮肤可触及部位最高温度为31.6℃,各温度结果均满足热控指标要求,表明设计方案合理可行,为同类型设备热设计提供了一种设计思路和参考依据。

700℃实炉验证试验平台过热试件热流密度测量及壁温分布研究

随着锅炉主蒸汽参数的提高,炉内受热面壁温的监测对于安全运行日益重要,并且有利于根据壁温分布进行选材,降低造价。南京电厂700℃验证试验平台炉内过热试件分布着12个牌号的材料,掌握锅炉管壁温分布及其随负荷变化的规律,是准确分析材料验证情况的基础。采用火焰强度热流计对炉内热流密度的空间分布进行实际测量,结合受热面进出口蒸汽参数的实际测量结果,对炉内壁温分布进行计算,结果表明:过热试件不同方向的热流密度在15~180kW/m^(2)范围内,并呈现明显的规律性,其中收到来自前方的热流密度最大、下方的热流密度其次,并且屏底热流密度最高、炉顶位置热流密度最低,屏底水平管平均热流密度约为垂直管的1.3倍。根据热流密度空间分布测量结果计算的过热试件壁温沿着蒸汽流程方向快速增加,在屏底位置出现一个小的峰值,然后增速放缓、最后在靠近管屏出口处略有下降;而管壁和蒸汽温差呈现先增加后减少、并在屏底出现明显峰值的现象,最外侧管屏底最大温差达到约88℃,屏顶温差则降低到约25℃。锅炉负荷越高,热流密度越大,同时壁温沿程增长速率越高。炉内壁温测量元件与壁温计算结果的最大温度偏差小于2%,两者具有良好的一致性。根据壁温计算结果对过热试件进行选材,约有51.2%的锅炉管须采用镍基合金材料,相比全部采用镍基合金材料可大幅降低成本。

海洋超高温高压油气钻井关键设备技术研究

为了提升我国海洋超高温高压钻井设备的国产化水平,对海洋超高温高压钻井主要设备进行了简要介绍,分析了海洋超高温高压钻井设备的国内外技术现状,重点阐述了海洋超高温高压钻井设备的关键技术及其研发思路。分析结果表明:钻井防喷器及控制系统、井口装置、泥线悬挂装置及井下工具等为当前急需攻关突破的超高温高压钻井关键设备;我国在这些关键设备的设计、制造和试验等多方面与国外存在差距,主要体现在高强度金属材料开发、密封设计制造、控制元器件开发和系统设备海试等4项关键技术方面。就这些关键技术提出了比较详细的研发思路,以期推动超高温高压钻井关键装备的国产化进程,增强我国海洋超高温高压油气田的勘探开发能力。

高温环境下低损耗材料电磁参数测试系统设计

为了准确评估低损耗材料在1200℃高温环境下的电磁性能,基于波导传输反射法构建低损耗材料电磁参数测试系统,实现宽频带变温特性的测试。采用磁控管微波加热技术快速且精准控制变温环境,通过精确测量波导中电磁波的传输特性,实现了对低损耗材料在高温环境下宽频带介电常数和磁导率的准确测量。高温实验以熔融石英为被测件得到的介电常数和磁导率相比标准值的测试误差小于2%,损耗角正切测试误差小于0.003+10%tanσ_(ε),结果表明所设计系统具有高测量精度、强抗干扰能力和鲁棒性,能够实现对低损耗材料的高温电磁参数性能测试。

高强度钢材低温力学性能试验研究与预测模型

在极地严寒地区工程中应用高强钢可节省用钢量,减少低温严酷环境下钢结构制作、运输和安装成本.为研究HG785高强钢在极地低温环境下的力学性能,对考虑2种厚度和5种低温环境的高强钢试样开展单轴拉伸试验.试验结果表明,极地低温环境下HG785高强钢的弹性模量、屈服强度和极限抗拉强度相较于其在25℃常温环境下有所提高,失效模式均为颈缩延性破坏并无脆断倾向.采用全子集法对试验结果进行回归分析,建立极地低温环境下高强钢力学性能指标预测模型,可指导高强钢在结构构件、节点与体系中的合理高效应用,为高强钢结构在极地低温地区服役与结构设计优化策略决策提供理论依据.

基于压痕法对高温合金GH3536单轴拉伸性能的评估研究

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