Factors Influencing High Temperature Thermo Plasticity of BNbRE Steel at the Third Brittle Zone

In view of fine cracks occurred on the surface of BNbRE continuous casting slabs for heavy rail in the practical production, the effect of two factors, i.e. deformation temperature, deformation velocity, on thermo plasticity of BNbRE steel at the third brittle zone was quantitatively investigated on GLEEBLE-1500D thermal-mechanical simulator after measuring the RA-T curve of BNbRE steel. The results provide experimental data for optimizing the technology of continuous casting secondary cooling zone and avoiding the occurrence of fine surface cracks.

Thermo-sensitive polymer nanospheres as a smart plugging agent for shale gas drilling operations

Emulsifier-free poly（methyl methacrylate-styrene） [P（MMA-St）] nanospheres with an average particle size of 100 nm were synthesized in an isopropyl alcoholwater medium by a solvothermal method. Then, through radical graft copolymerization of thermo-sensitive mono- mer N-isopropylacrylamide （NIPAm） and hydrophilic monomer acrylic acid （AA） onto the surface of P（MMA- St） nanospheres at 80 ℃, a series of thermo-sensitive polymer nanospheres, named SD-SEAL with different lower critical solution temperatures （LCST）, were prepared by adjusting the mole ratio of NIPAm to AA. The products were characterized by Fourier transform infrared spectroscopy, transmission electron microscopy, thermogravimetric analysis, particle size distribution, and specific surface area analysis. The temperature-sensitive behavior was studied by light transmittance tests, while the sealing performance was investigated by pressure transmission tests with Lungmachi Formation shales. The experimental results showed that the synthesized nanoparticles are sensitive to temperature and had apparent LCST values which increased with an increase in hydrophilic monomer AA. When the temperature was higher than its LCST value, SD- SEAL played a dual role of physical plugging and chemical inhibition, slowed down pressure transmission, and reduced shale permeability remarkably. The plugged layer of shale was changed to being hydrophobic, which greatly improved the shale stability

THERMAL AND THERMO-ELASTIC-PLASTIC RESPONSE OF CERAMIC-METAL FUNCTIONALLY GRADED MATERIALS—THERMAL SHOCK PROBLEM

The thermal and thermo-elastic-plastic response of newly developed ceramic-metal functionally graded materials under a thermal shock load is studied. The materials are heated at the ceramic surface with a sudden high-intensity heat flux input, and cooled at the metal surface with a flowing liquid nitrogen. Emphasis is placed on two aspects: (1) the influence of the graded composition of the materials on the temperature and stress response; and (2) the optimum design of the graded composition from a unified viewpoint of the heat insulation property and stress relaxation property. Moreover, a comparison between the thermoelastic stress and the thermo-elastic-plastic stress is also made to indicate the plasticity effect.

Preliminary study of the effects of EVA coupling agents on properties of wood-plastic composites

As a hot-melt adhesive, ethylene-vinyl-acetate （EVA） has been used in many industrial applications. But studies of the application of EVA in wood-plastic composites （WPC） are relatively few, so we have investigated the proposition of whether EVA is a suitable coupling agent for WPC or not. The results show that EVA with 8% VA is not a suitable coupling agent, because it reduces the mechanical properties of WPC without any significant effect on its physical properties. With an increase in the amount of wood powder, the mechanical properties of WPC decrease and the ability of water absorption of WPC increases.

A bull-heading water control technique of thermo-sensitive temporary plugging agent

Aimed at the disadvantages of secondary damage to oil layers caused by the conventional bull-heading water control technique, a thermo-sensitive temporary plugging agent for water control was synthesized by water solution polymerization and applied in the field with a new secondary temporary plugging technique. The optimization and performance evaluation of thermo-sensitive temporary plugging agent were carried out through laboratory experiments. The optimized formula is as follows:(6%-8%) acrylamide +(0.08%-0.12%) ammonium persulfate +(1.5%-2.0%) sepiolite +(0.5%-0.8%) polyethylene glycol diacrylate. The thermo-sensitive temporary plugging agent is suitable for formation temperatures of 70-90 ?C, it has high temporary plugging strength(5-40 k Pa), controllable degradation time(1-15 d), the apparent viscosity after degradation of less than 100 m Pa?S and the permeability recovery value of simulated cores of more than 95%. Based on the research results, secondary temporary plugging technique was used in a horizontal well in the Jidong Oilfield. After treatment, the well saw a drop of water cut to 27%, and now it has a water cut of 67%, its daily increased oil production was 4.8 t, and the cumulative oil increment was 750 t, demonstrating that the technique worked well in controlling water production and increasing oil production.

Coupled Thermo-Mechanical Modeling of Long Cone-Shaped Forging Based on Rigid Visco-Plastic FEM

Based on synthetically considering the coupled thermo mechanical relations between temperature and deforming, a numerical simulation of the forging process for the special long cone shaped workpiece of Al 5.44Mg 2.15Li 0.12Zr alloy at high temperature was conducted by using the rigid visco plastic finite element method. The relations between the total load and the displacement during the forging, and the distributions of stress, strain, temperature and strain rate, which can provide useful information for the process design, are obtained.

RUDIMENTAL EQUATIONS FOR THERMO－ELASTO－PLASTIC STRESS ANALYSIS DURING CONTINUOUS CASTING WITH PHASE CHANGE

Coupled relations among temperature, phase transformation and stress have beendiscussed here in the present paper. Thermo-elasto-plastic constitutive equationsincluding creep and iterative finite element formulation during continuous casting withphase change have also been presented.

THERMO ELASTO—PLASTIC OPTIMUM DESIGN OF CERAMIC—METAL FUNCTIONALLY GRADED MATERIALS-Ⅰ.MICROMECHANICAL AND GEOMETRICAL EFFECTS

The thermo elasto-plastic optimum design of ceramic-metal functionally graded materials (FGMs)was investigated in this paper. The inelastic properties were first evaluated using micromechanical approaches, then an elasto-plastic finite element model was used to calculate the thermal stress in the material . The effects of micromechanical approaches, plasticity and graded interlayer thickness on the thermal stress relaxation characteristics and stress distributions were studied. The results show that: (1) the macro elas-to-plastic response given by the mean-field micromechanics and self-consistent micromechanics is nearly the same but the response given by the rule of mixture is different; (2)the thermo elasto-plastic behavior must be considered to realistically evaluate stress reduction, and the elasto-plastic optimum design can get helpful information to determine the graded interlayer thicknesses;and(3) to optimize the microstructure of the graded material achieves reductions in critical stress components and rational stress distributions.

A new thermo-elasto-plasticity constitutive theory for polycrystalline metals

In this study, the behavior of polycrystalline metals at different temperatures is investigated by a new thermo-elasto-plasticity constitutive theory. Based on solid mechanical and interatomic potential, the constitutive equa- tion is established using a new decomposition of the deformation gradient. For polycrystalline copper and magnesium, the stress-strain curves from 77 to 764 K （copper）, and 77 to 870 K （magnesium） under quasi-static uniaxial loading are calculated, and then the calculated results are compared with the experiment results. Also, it is determined that the present model has the capacity to describe the decrease of the elastic modulus and yield stress with the increasing temperature, as well as the change of hardening behaviors of the polycrystalline metals. The calculation process is simple and explicit, which makes it easy to implement into the applications.

复合生物再生沥青及混合料路用性能

环己烷1,2-二甲酸二异壬基酯(DINCH)增塑剂与餐厨废弃油脂共混,制成复合生物再生剂,通过三大指标及布氏黏度实验确定复合沥青再生剂的最佳配比。在掺加再生剂与未掺再生剂的条件下,分别制备不同RAP(Reclaimed Asphalt Pavement)掺量的再生沥青混合料并进行车辙实验、低温弯曲破坏实验、浸水马歇尔实验和冻融劈裂实验。结果表明,DINCH增塑剂与餐厨废弃油脂配比为0.4∶1时,再生沥青常规性能恢复至原样沥青水平。再生沥青混合料在RAP掺量为30%~50%的条件下,未掺加复合生物再生剂的沥青混合料低温抗裂性及水稳定性均不满足规范要求;掺加再生剂后,随着RAP掺量的增加,再生沥青混合料的低温抗裂性及水稳定性降低,高温稳定性能提高,当RAP掺量为30%时,再生沥青混合料的低温抗裂性及水稳定性与新拌混合料相当,高温稳定性能优于新拌沥青。

加工因素对HDPE基木塑复合材料静曲强度的影响

为了研究木塑复合材料加工因素对复合材料力学性能的影响,采用正交实验法以静曲强度为评价标准,利用极差分析和方差分析法分析了螺杆转速、造粒温度、偶联剂质量分数和木粉含量等加工因素对力学指标静曲强度影响的顺序及各因素的最佳水平,确定了木塑复合材料静曲强度的各加工因素的最佳参数组合;系统地分析了各加工参数对木塑复合材料力学性能指标静曲强度的影响。结果表明,影响木塑复合材料静曲强度的主要加工因素由大到小依次为偶联剂质量分数>木粉含量>转速>造粒温度;得到最佳静曲强度的加工因素参数组合为转速150 r/min、造粒温度145℃、偶联剂质量分数为5%、木粉含量为60%;木粉含量及偶联剂质量分数对材料的静曲强度具有显著性影响,转速和造粒温度对材料静曲强度影响的显著性较低,其中,随着偶联剂含量的增加,静曲强度呈明显上升的趋势;当木粉含量从30%增大至70%时,材料的静曲强度呈先增加后减小的趋势。

组合膨胀剂对风电灌浆料早期膨胀性能的影响

基于改进的竖向膨胀率(εv)测试方法,获得了高强风电灌浆料0~24 h、1~7 d的εv发展全曲线;并研究了掺合料比例及组合膨胀剂比例对灌浆料εv、流动度、力学强度的影响.结果表明:灌浆料0~24 h竖向膨胀率曲线呈“四阶段”特征;在0%~20%掺量范围内提高硅灰掺量,灌浆料流动度下降,0~24 h内εv曲线峰值先增大后减小;塑性膨胀剂(PEA)对24 h内εv发展起主导作用,复掺氧化钙-硫铝酸钙双源膨胀剂(HP-CSA)后,εv峰值减小,24 hεv下降、3 hεv增大,有利于控制24 h与3 h的εv差值;在1~7 d内,0.03%掺量的PEA即可促进HP-CSA膨胀效能的发挥,6%以上掺量的HP-CSA可较好补偿竖向自收缩变形而获得净膨胀灌浆料;PEA与HP-CSA组合,可发挥时间上接力、效果上协同的膨胀调控作用,可分阶段、按需设计,从而实现对灌浆料7 d内竖向膨胀率的精细调控;随组合膨胀剂掺量增加,灌浆料初始和30 min流动度无明显变化,28 d抗压强度先增大后减小;在本文研究范围内,0.06%PEA+6%HP-CSA是最优掺量组合.

温敏水凝胶的改性及其在正渗透工艺中的应用

温敏水凝胶是一种能够响应外界温度变化的聚合物材料。由于温敏水凝胶具一定的渗透压与易于脱水特性,因此可作为汲取剂应用于正渗透(FO)工艺中。但传统温敏水凝胶的溶胀能力较弱,导致FO工艺的水通量较低。因此需要对温敏水凝胶进行改性,从而获得更高的溶胀性能和渗透压,使温敏水凝胶在FO工艺中具有更广阔的应用前景。介绍了几种通过无机、有机改性的温敏水凝胶,以及其在FO中的应用情况。研究表明:通过添加具有亲水性物质(如无机物污泥灰、氧化石墨烯等,有机物如丙烯酸钠、聚乙二醇等)可有效提高水凝胶的溶胀性能,从而在FO工艺中获得更多的水通量;此外,添加碳颗粒、γ-Fe_(2) O_(3) 等材料可以提高水资源回收率,降低回收能耗。因此,改性后的温敏水凝胶在FO工艺中具有更广阔的应用前景。

解淀粉芽孢杆菌W48对大蒜产量品质及土壤质量提升效果研究

为明确微生物菌剂改善大蒜产地环境、提升产量品质的效果,利用常规施肥结合解淀粉芽孢杆菌W48发酵液进行大蒜田土壤处理,测定大蒜产量和品质相关指标,监测土壤理化性质及生物转化相关酶活性变化,定量分析菌剂处理后土壤和大蒜中邻苯二甲酸酯类塑化剂(PAEs)含量差异。结果表明,W48菌株具有分泌吲哚乙酸的能力,同时具备溶磷和产铁载体的潜力。施用W48微生物菌剂显著增加了植物根际土壤有机质、碱解氮、有效磷和速效钾含量,改善根际区域营养环境,提高了土壤碱性磷酸酶、蔗糖酶和脲酶等生物转化相关酶活性,提高了土壤氮、磷元素利用效率;与对照相比,微生物菌剂处理的小区大蒜增产10%,可溶性糖和维生素C含量等品质指标均有提高,其中可溶性糖显著增加了30%;邻苯二甲酸二正丁酯(DBP)和邻苯二甲酸二(2-乙基)己酯(DEHP)是土壤和大蒜中PAEs的主要检出类型,土壤中的平均浓度分别达到1874.05和337.12μg/kg,大蒜中几种PAEs残留量普遍较高,DBP最高为666.57μg/kg,其次为邻苯二甲酸二异丁酯(DIBP)409.93μg/kg和邻苯二甲酸丁苄酯(BBP)433.65μg/kg。菌剂对PAEs具有显著的体外降解能力,土壤处理后能够显著降低土壤中PAEs浓度,对DBP、DEHP和邻苯二甲酸二甲酯(DMP)的去除率分别为25.5%、76.1%和48.4%,但对大蒜中的PAEs含量影响不显著。以上结果为大蒜产地土壤污染物修复及改良提供了技术支撑。

热−力耦合作用下垃圾土体积变形特性和模型研究

城市生活垃圾填埋场因有机质降解产热导致其内部温度长期高于环境温度,引发工程运维问题。垃圾土温控三轴试验结果发现,温度变化引起的垃圾土体积应变与应力水平有关,且弹性体积应变占比较大,影响以塑性体积应变为硬化参数的弹塑性本构模型研究。在前期试验基础上,采用GDS温控应力路径三轴仪,研究了排水条件下温度对垃圾土中黏土体积变形特性和压缩特性的影响,并与相同条件下垃圾土体积变形特性进行比较,揭示了温度变化对垃圾土体积变形特性的影响机制。基于垃圾土温控三轴试验结果,推导了垃圾土热弹塑性压缩指数λT和热弹性压缩指数κT的确定方法;采用等效应力原则,假设温度变化引起的弹塑性体积应变等于某一等效应力增量引起的弹塑性体积应变,建立了垃圾土在热−力耦合作用下的体变计算模型,并对模型进行了验证分析。研究结果表明,孔隙比是影响垃圾土温度体积应变的主要因素;垃圾土的λT和κT随初始固结应力的增加而减小,比黏土高一个数量级;选取常温下相应固结应力水平的回弹指数κ和压缩指数λ比例值(κ/λ)能够较好地模拟热−力耦合作用下垃圾土的体积变形特性。

天然气水合物注热分解诱发储层变形破坏的正交数值模拟研究

针对天然气水合物热分解而引起的储层失稳破坏机理及影响因素不明确的问题,考虑因水合物热分解引起的地层传热、孔隙流体渗流和固体骨架的变形破坏,建立了水合物沉积层的热-流-固耦合模型及其作用下储层固体骨架的弹塑性本构模型。基于ABAQUS软件的USDFLD子程序进行二次开发,开展正交实验数值模拟,分析注热温度差、水合物沉积层的绝对渗透率和有效主应力差对水合物沉积层近井储层变形破坏影响的敏感性及影响机理。结果表明:对近井储层变形破坏影响的敏感程度由大到小依次为有效主应力差、绝对渗透率、注热温度差;水合物热分解引起的近井储层力学性质劣化和有效应力下降是导致其发生变形破坏的主要原因;有效主应力差越大,等效塑性应变最大值越大,并且受水平地应力非均匀性的影响,近井储层变形破坏最严重的位置始终位于井眼最小水平地应力方向上。该研究成果可为热激法开采天然气水合物或含水合物地层的钻井作业提供借鉴。

氧化羟丙基淀粉基保鲜膜的制备与性能研究

本文以氧化羟丙基淀粉为成膜基材,制备综合性能优良的绿色环保保鲜膜。分别研究了以不同增塑剂(甘油、山梨醇),交联剂(三偏磷酸钠、柠檬酸、CaCl2)对氧化羟丙基淀粉进行改性。分析不同助剂对保鲜膜性能的影响和保鲜膜对圣女果保鲜效果的影响。研究结果表明,甘油与山梨醇的比例为5:3,保鲜膜增塑时的断裂伸长率对比纯淀粉膜提升了32倍;交联剂改性后的淀粉膜相对未改性淀粉膜的性能均有不同程度的提升,其中三偏磷酸钠交联改性的淀粉膜效果明显,其拉伸强度提高了4倍,耐水性提高了1.5倍,透湿性降低了74%。改性后的保鲜膜具有耐水性高、透湿性低的特点更有利于保鲜,8天后与空白组对比失重率降低了77%。保鲜效果得到了改善。

高强钢激光熔透焊接接头残余应力数值分析

为探究高强钢大功率激光单道熔透焊接接头中的残余应力及塑性应变分布规律,基于峰值指数递增双锥体热源模型对焊接接头进行热-弹-塑性有限元分析,发现采用该热源模型仿真计算的温度场与实际焊缝轮廓吻合较好,关键参数对比最大误差为-3.45%;焊接接头残余应力沿着焊缝中心至两边呈对称分布,沿路径L2在起焊与止焊处的应力分布波动较大,这与节点温度历程曲线相一致;焊接接头在焊缝区发生了塑性应变,而远离焊缝区范围内未发生塑性应变。沿路径L1的焊缝区最大塑性应变峰值及峰值梯度均为等效塑性应变;沿路径L2在起焊及止焊处的纵向、横向及等效塑性应变波动幅值较大,且等效塑性应变峰值最高,横向塑性应变峰值梯度最大,它们的值分别为0.064及0.079。

悬浮法低聚合度聚氯乙烯树脂的孔隙调控

研究了主分散剂、辅助分散剂、链转移剂的种类和用量对低聚合度聚氯乙烯树脂孔隙率的影响规律,对比了采用恒温聚合和变温聚合工艺制备的低聚合度聚氯乙烯树脂的性能。结果表明,采用较低醇解度的聚氯乙烯醇和羟丙基甲基纤维素作为主分散剂,再加入一定量的辅助分散剂可以提升孔隙结构;变温聚合工艺和链转移剂的加入均能提升孔隙率。

Computer Aided Composition Design of Prehardened-Mould Steel for Plastic

The improvement of machining behavior of prehardened-mould steel for plastic is realized by using computer-aided composition design in this work. The results showed that the matrix composition of large sectional prehardened mould steel for plastic markedly influences the precipitation of non-metallic inclusion and the control of composition aided by Thermo-Calc software package minimizes the amount of detrimental oxide inclusion. In addition the modification of calcium is optimized in the light of composition design.