Vibration and sound transmission loss characteristics of porous foam functionally graded sandwich panels in thermal environment

This study investigates the vibration and acoustic properties of porous foam functionally graded(FG)plates under the influence of the temperature field.The dynamics equations of the system are established based on Hamilton's principle by using the higher-order shear deformation theory under the linear displacement-strain assumption.The displacement shape function is assumed according to the four-sided simply-supported(SSSS)boundary condition,and the characteristic equations of the system are derived by combining the motion control equations.The theoretical model of vibro-acoustic coupling is established by using the acoustic theory and fluid-structure coupling solution method under the simple harmonic acoustic wave.The system's natural frequency and sound transmission loss(STL)are obtained through programming calculations and compared with the literature and COMSOL simulation to verify the validity and reliability of the theoretical model.The effects of various factors,such as temperature,porosity coefficients,gradient index,core thickness,width-to-thickness ratio on the vibration,and STL characteristics of the system,are discussed.The results provide a theoretical basis for the application of porous foam FG plates in engineering to optimize vibration and sound transmission properties.

Vibration analysis of foam plates based on cell volume distribution

In this paper, vibration analysis of irregular-closed-cell foam plates is per- formed. A cell volume distribution coefficient is introduced to modify the original Gibson- Ashby equations of effective Young＇s modulus of foam materials. A Burr distribution is imported to describe the cell volume distribution situation. Three Burr distribution pa- rameters are obtained and related to the cell volume range and the diversity. Based on the plate theory and the effective modulus theory, the natural frequency of foam plates is calculated with the change of the cell volume distribution parameters. The relationship between the frequencies and the cell volumes are derived. The scale factor of the average cell size is introduced and proved to be an important factor to the performance of the foam plate. The result is shown by the existing theory of size effects. It is determined that the cell volume distribution has an impact on the natural frequency of the plate structure based on the cell volume range, the diversity, and the average size, and the impact can lead to optimization of the synthesis procedure.

基于ASPEN软件的戊烷发泡剂生产实践及增产措施

炼化企业中,戊烷发泡剂可以利用预加氢装置拔出的轻石脑油组分进行生产,而国家标准GB T 22053—2020对发泡剂质量要求更加严格。通过构建预加氢装置汽提塔、分馏塔及脱戊烷塔的ASPEN PLUS模型,对戊烷发泡剂生产流程的控制参数进行分析测算,制定了生产调整方案。工业试验结果表明:戊烷发泡剂组成与脱戊烷塔塔顶灵敏板温度密切相关,保证塔顶发泡剂组分质量分数差值范围为±2%,其塔顶温度变化需控制±0.3℃。同时,从汽提塔操作、产品牌号、加工原油种类等方面入手,对戊烷发泡剂增产效果进行分析,提高企业的经济效益。

泡沫铝夹芯板重复击穿塑性响应及失效破坏

文中基于泡沫铝夹芯板的重复冲击实验,研究了冲头形状对夹芯板塑性响应及失效破坏的影响,并分析了其变形累积和能量耗散特性.结果表明:冲头直径与夹芯板边长比α直接影响夹芯板的变形模式,进而影响夹芯板的失效破坏模式.当α为0.2时,夹芯板主要产生局部凹陷,芯层通过局部压缩耗散能量,正面板首先发生破坏;当α达到0.4时,夹芯板主要产生整体弯曲和拉伸,芯层通过整体压缩耗散能量,背面板首先发生破坏.α越大,碰撞力峰值越大,碰撞时间越短,夹芯板的抗击穿次数越大.冲击能量越大,夹芯板在重复冲击下的能量恢复系数越小.

高速磁浮列车泡沫三明治板在冲击载荷下的吸能特性与参数优化

建立模拟高速磁浮列车泡沫三明治裙板冲击的有限元模型,基于搭建的钢球冲击试验装置验证模型的有效性,研究冲击速度、前后金属面板厚度和支撑间距对泡沫三明治板吸能量和冲击载荷的影响。采用响应面法建立泡沫三明治板内能和初始峰值载荷的代理模型,基于遗传算法提出冲击速度、前后面板厚度和支撑间距等参数的优化方法。研究结果表明:在低速(8 m/s)冲击下,泡沫三明治板具有更好的吸能效率,吸能效率能达到90%以上;随着冲击速度增加,吸能效率显著下降;增加冲击间距不仅能延长冲击作用时间,也能显著降低冲击载荷峰值力,降幅达到13.59%;针对高速磁浮列车泡沫三明治板的吸能设计要求,通过调整前、后金属面板的厚度可有效改善其吸能效果。内能和峰值力的预测值与其真实值之间的最大相对误差分别为4.14%和0.96%,满足高速磁浮列车泡沫三明治板吸能特性预测的精度要求。

光纤泡沫铝板施工技术研究与应用

光纤泡沫铝板属于新型材料,凭借自重轻、强度高、隔声效果好、耐火耐高温、易加工切割开孔等优势,受到广泛关注。目前光纤泡沫铝板施工尚无操作规程和技术标准,常规的安装方式难以满足需求。本技术通过采用镶嵌安装工艺,有效解决光纤泡沫铝板安装的难题,保证了光纤泡沫铝板安装的稳定可靠性。

桥梁薄壁空心墩横隔板施工技术应用研究

横隔板的设置对于空心薄壁高墩墩身的稳定起着至关重要的作用,本研究通过对喀斯特地貌区域桐木河特大桥矩形薄壁空心墩横隔板的施工难点、施工工艺、方法等方面进行了分析研究,优化传统横隔板施工工艺,并对变截面薄壁空心墩高墩横隔板的施工方法、质量控制措施、安全保证措施进行了总结,为今后高墩横隔板施工技术提供借鉴。

Electroless copper plating on microcellular polyurethane foam

In order to obtain substrates with good conductive foam for high porosity foam metal materials used in the metal electrodes,the technique of electroless copper plating on the microcellular polyurethane foam with pore size of 0.3 mm was investigated.The main factors affecting the deposition rate such as the solution composition,temperature,pH value and adding ultrasonic were explored.The results show that the optimum process conditions are CuSO4 16 g/L,HCHO 5 mL/L,NaKC4H4O6 30 g/L,Na2EDTA 20 g/L,K4Fe(CN)6 25 mg/L,pH value of 12.5-13.0 and temperature of 40-50℃.Under these technical conditions, the process has excellent bath stability.Adding ultrasonic on the process can elevate the deposition rate of copper by 20%-30%.The foam metal material with a porosity of 92.2%and a three-dimensional network structure,was fabricated by electro-deposition after the electroless copper plating.

Removal of nickel from spent electroless nickel-plating bath with nickel foam cathode

The electrochemical method was used to remove nickel ion from spent electroless nickel plating bath (pH=5 3). An electrolytic cell was composed of a porous nickel foam cathode and an inert RuO 2/Ti anode. Nickel ions were reduced and deposited on the surface of the nickel foam cathode. The effect of current density (i), linear velocity of wastewater(v), gap between cathode and anode(d C/A) and reaction time(t) on nickel removal rate and current efficiency were studied. As reaction time prolonged, nickel removal rate increased while current efficiency decreased. And larger v and smaller d C/A can enhance nickel removal rate and increase current efficiency by promoting mass transfer and dropping concentration polarization. The effect of current density on nickel removal by electrochemistry was related to other parameters. After three hours’ electrolysis with i=1 0 A/dm2, v=18 5 cm/min and d C/A=0 5 cm, nickel removal rate and current efficiency reached 85 6% and 29 1%, respectively.

High-temperature Compressive Performance of Mg Alloy Foams Coated with Ni-P Layer

Mg/Ni hybrid foams were fabricated by the electroless method.The Ni-P(Nickel-Phosphorous)coatings were deposited on the surface of closed-cell Mg alloy foams.The composition,microstructure and phases of the Ni-P coatings were characterized by scanning electron microscopy(SEM),energy-dispersive X-ray spectroscopy(EDS)and X-ray diffraction(XRD),respectively.The compressive tests were performed on the Mg/Ni hybrid foams at 400℃using the Mg alloy foams as a reference.The experimental results show that the yield strength,plateau stress and energy absorption capacity of the closed-cell Mg alloy foams at high temperature were improved by the Ni-P coating.And there are four main modes for the Mg/Ni hybrid foam failure at 400℃,i e,shearing in cell wall,bending in cell edge,shedding and cracking in Ni-P coating.

冷弯薄壁C型钢与泡沫混凝土的界面抗剪性能及规律研究

为研究泡沫混凝土密度和横向肋板个数对冷弯薄壁C型钢与泡沫混凝土之间界面抗剪性能的影响,制作了24个试件进行推出试验,其中泡沫混凝土的密度分别为800、1000、1200、1600kg/m^(3),并在型钢翼缘处设置横向肋板,横向肋板数量分别为0、1、2。观察试件破坏情况后得出结论,即在一定的范围内,界面抗剪强度随泡沫混凝土密度的增大而增大,超过一定范围后强度增长缓慢;界面抗剪强度随着横向肋板个数的增加而增加。根据试验得出的数据,统计归纳出特征抗剪强度计算公式,对比计算结果与试验结果,确认公式拟合程度良好,最后得出抗剪强度-滑移本构方程,为完善轻钢-泡沫混凝土组合结构的设计提供理论基础。

电沉积制备Cu-Ni-Mo三元电极及其析氢性能

目的制备一种在碱性溶液中具有高效、低成本等优点的铜基析氢阴极材料。方法在35℃下采用直流电沉积法,在泡沫镍(NF)表面分别沉积Cu-Ni、Cu-Ni-Mo镀层,制备Cu-Ni/NF、Cu-Ni-Mo/NF析氢电极。利用X射线衍射分析仪(XRD)、扫描电镜(SEM)和能谱仪(EDS)表征电极的表面形貌、结构元素含量及物相。通过电化学阻抗技术(EIS)、线性扫描伏安法(LSV)、循环伏安法(CV)测定电极的析氢性能和催化活性。结果经Mo掺杂后,Mo在Cu-Ni-Mo三元合金中以置换型固溶体的形式存在,与二元镀层相比,增大了镀层的晶格常数。Cu-Ni-Mo/NF三元电极在电流密度10 mV/cm^(2)下,过电位仅为116 mV,塔费尔斜率为104 mV/dec,电荷转移电阻为15.34Ω,电化学活性比表面积(ECSA)为22.33,相较于Cu-Ni/NF二元电极,分别降低了68 mV、27 mV/dec、15.48Ω,ECSA值提高了7.95,且循环稳定性较好。结论引入第3种元素Mo,改变了Cu-Ni二元电极的镀层形貌,使晶粒细化,表现为微粒紧密堆积而成的球胞状结构,从而提升了电极材料的比表面积,为析氢反应提供了更多的活性位点,有助于提高析氢反应效率。由于三金属间的协同作用,与Cu-Ni二元电极相比,Cu-Ni-Mo三元电极显示出更优异的析氢催化性能。

泡沫铝夹芯板重复击穿响应及冲头形状影响研究

在船舶与海洋工程领域,重复冲击是较为常见的载荷工况,船体结构在重复冲击载荷作用下会出现变形和损伤累积,导致结构失效甚至破坏。本文开展了泡沫铝夹芯板重复击穿实验,研究了重复击穿过程中夹芯板的失效破坏以及能量耗散特性;同时分析了冲头形状对泡沫铝夹芯板重复击穿动态响应和能量吸收的影响机理。研究表明:上面板出现裂纹之后,夹芯板仍具有较强的剩余承载能力;根据面板、芯层失效破坏特性可以将泡沫夹芯板的击穿过程划分为三个典型阶段,即上面板破裂、芯层压缩和下面板撕裂,三个阶段的动态响应和吸能机理存在较大区别;对于楔形冲头和柱形冲头重复冲击而言,夹芯板的上面板失效主要是剪切破坏,而对于球形冲头则主要是拉伸导致破坏;在球形冲头冲击作用下,泡沫铝夹芯板塑性能耗散最多,其抗击穿次数最大。

陶粒泡沫混凝土夹层叠合板受弯性能研究

传统混凝土叠合板保温效果差且自重较大,现有夹芯叠合板夹层有机材料易燃且强度较低,和上下层混凝土协同工作能力较差。本文提出了保温承重一体化的夹层叠合楼板,将叠合板中和轴附近受力较小的部分替换为具有减重保温效果的陶粒泡沫混凝土。为研究陶粒泡沫混凝土夹层叠合板的抗弯性能,进行了3块楼板的静力加载试验。结果表明:陶粒泡沫混凝土夹层叠合板与普通混凝土现浇板的受弯过程相似,裂缝发展规律和分布较为一致,呈典型的单向板破坏现象,且剪跨比较小的叠合板截面所能承受的最大弯矩略高于整浇板。陶粒泡沫混凝土夹层叠合板具有良好的工作性能,未出现局部破坏导致的承载力突降现象。本文提出的建模方法与试验拟合较好,结合ABAQUS有限元分析结果,该设计在大幅减轻自重增强保温效果的同时可以满足承载力要求。

装配式轻钢-尾砂微晶发泡板组合墙抗震性能试验研究

研发了一种轻钢-尾砂微晶发泡板组合墙,为研究该组合墙抗震性能,进行了4个足尺试件的低周反复荷载试验。分析了不同参数试件的破坏特征、承载力、滞回性能、刚度退化和耗能能力。进行了有限元数值模拟,计算结果与试验结果吻合较好。研究表明:轻钢-尾砂微晶发泡板组合墙的轻钢龙骨、钢筋和尾砂微晶发泡板受力时协同工作。尾砂微晶发泡板强度的提升,增强了对轻钢龙骨的约束作用,提高了试件的抗震性能。在龙骨间填充粉煤灰砌块后,增强了对龙骨的约束作用,改变了组合墙破坏形态,并显著提高了组合墙的抗震性能。当尾砂微晶发泡板采用拼板时,由于拼板墙体整体性较差,对轻钢龙骨约束能力减弱,其承载力、刚度以及耗能能力均较大程度被减弱,在考虑抗震设计时不宜采用拼板的构造形式。

球墨铸铁重型辅板的消失模试制工艺

介绍了球墨铸铁重型辅板铸件的结构及技术要求,详细阐述了该铸件的生产工艺:采用半开放式浇注系统、倾斜侧浇工艺,在铸件的顶部设置溢流冒口,吸纳充型过程中前沿的低温铁液,消除铸件顶部表面积碳或皱皮;采用共聚料STMMA3A#材料进行珠粒预发泡,选用新型SZ-1型消失模干粉涂料进行涂料混制,波美度控制在63~65°Bé。生产结果显示:铸件外形轮廓清晰,表面没有出现渣孔、皱皮类铸造缺陷,内浇道位置没有出现缩孔缺陷,重型辅板轮缘的不平整度<3 mm,铸件加工后,加工面没有出现黑皮,铸件的整体质量达到了技术要求。

带拼缝陶粒泡沫混凝土夹层叠合板抗弯性能研究

提出3种陶粒泡沫混凝土夹层叠合板拼缝形式,在实现叠合板保温减重的前提下,优化叠合板拼缝构造。对5块叠合板进行静力加载试验,对比采用不同拼缝构造的叠合板的破坏形态、承载力及受力筋、拼缝连接件的受力规律。结果表明:3种拼缝构造可以实现正常传力;整体式拼缝的叠合板,拼缝区域对应的中间层混凝土种类对此拼缝形式的抗弯性能无明显影响;采用密拼式拼缝的叠合板,密拼式拼缝的预埋钢筋、预埋钢板会和周围的底部受拉钢筋共同受力,密拼式拼缝-钢板搭接式的附加钢板及底部钢板主要起到传力的作用;在叠合面未发生明显滑移前,各带拼缝叠合板的承载力、刚度与无拼缝叠合板接近。有限元软件ABAQUS模拟结果表明:采用整体式拼缝的叠合板可以实现与无拼缝叠合板承载力“等强”的效果,采用密拼式拼缝-钢筋焊接式、密拼式拼缝-钢板搭接式的叠合板承载力大于无拼缝叠合板。

肌电监测泡沫/镀银针织物复合干电极的制备及性能评价

通过热压工艺将3种商业化镀银针织物(经绒镀银织物、经平镀银织物、双罗纹镀银织物)电极布与泡沫结合,制备泡沫/镀银针织物复合干电极,并评价复合干电极的电气性能及肌电监测性能。研究结果显示:布面平整且厚重的经绒泡沫/镀银针织物复合干电极的方阻、交流阻抗及皮肤-电极接触阻抗值均最小,其电气性能优于其他2种泡沫/镀银针织物复合干电极;3种泡沫/镀银针织物复合干电极均能分辨不同肌力下的肌电信号,且在哑铃锤式弯举测试中,它们的肌电监测性能与传统电极相当,表明泡沫/镀银针织物复合干电极能够用于日常动态肌电监测。

混凝土坡瓦屋面构造优化设计

简要分析了传统混凝土坡瓦屋面夹芯饼式构造存在的弊端;提出一种新的优化构造,将压型钢板坡屋面防水保温紧密系统移植到混凝土坡瓦屋面上,以一改传统夹芯饼式不合理构造;同时也指出了该优化构造存在继续改进的空间。

林州钾砂页岩生产釉面发泡陶瓷砖试验

笔者以河南安阳林州市任村镇牛岭山钾砂页岩为主体原料,研制出釉面发泡陶瓷仿岩面陶瓷砖。该釉面发泡陶瓷砖,具有较高的力学性能、隔音声学性能和隔热热学性能,可广泛应用于内外墙隔音保温装饰,高速、高铁、学校等隔音屏障声学隔音装饰等场所,是绿色节能建筑和宁静社区建设的关键材料。