Physical and Chemical Characterizations of Rubber Latex Cup Bottom Oil

Rubber latex is an important economic resource. However, the residues from its harvesting are thrown away, even though they contain lipids that can be recycled. This recovery of the residues from the bottom of the cup requires first and foremost their characterization. The aim of this study is therefore to determine the main physical and chemical characteristics of rubber latex cup bottom oil. Oil’s physical parameters determination shows that it has a density of 951 kg∙m−3, a kinematic viscosity of 48.57 cSt and a water content of 0.0845%. Chemical parameters, meanwhile, indicate that this cup bottom residue has a fat content of 95.96%, an acid number of 2.805 mg KOH/g and an iodine number of 92.42 g I2/100g. Therefore, rubber latex cup bottom oil can be used in the formulation of biofuels, biolubricants, paints, varnishes, alkyd resins, polishing oils, soaps, and insecticides.

Levels of Polycyclic Aromatic Hydrocarbons (PAHs) in Healthcare Waste Incinerators’ Bottom Ash from Five County Hospitals in Kenya

Health-care waste contains potentially harmful microorganisms and compounds which can infect and affect hospital patients, healthcare workers, the general public and environment. Therefore, management of health care waste requires safe handling, treatment and disposal procedures. While incineration reduces the volume and quantity of waste for final disposal, it leads to the production of fly and bottom ashes laden with toxic incomplete combustion products such as Polycyclic Aromatic Hydrocarbons (PAHs), dioxins, furans and heavy metals. This exposes workers who handle and dispose the bottom ashes, hospital patients, the general public and environment. The goal of this study was to determine the total and individual levels of 16 most prevalent and toxic PAHs. Bottom ash samples were collected from incinerators in five county hospitals in Kenya, namely;Moi-Voi, Narok, Kitale, Makindu and Isiolo. Bottom ash samples were collected over a period of six months from the five hospitals. The samples were then sieved, homogenised and stored at 4°C in amber coloured glass containers. The PAHs were extracted using 30 ml of a hexane-acetone solvent (1:1) mixture by ultrasonication at room temperature (23°C) for 45 minutes. The PAHs were then analyzed with a GC-MS spectrophotometer model (Shimadzu GCMS-QP2010 SE) connected to a computer work station was used for the PAHs analysis. The GC-MS was equipped with an SGE BPX5 GC capillary column (30 m × 0.25 mm × 0.25 μm) for the separation of compounds. Helium was used as the carrier gas at a flow rate of 15.5 ml/minute and 14.5 psi. 1 μl of the sample was injected at 280°C, split mode (10:1). The oven programming was set for a total runtime of 40 minutes, which included: 100°C (2-minute hold);10°C /min rise to 200°C;7°C /min rise to 249°C;3°C /min rise to 300°C (2-minute hold). The interface temperature was set at 290°C. Analysis was done in Selected Ion Monitoring (SIM) mode and the peak areas of each of the PAHs were collected from the chromatograph and used for quantification of the 16 PAHs listed by the U.S. Environmental Protection Agency (EPA) which included, BaA (benz[a]anthracene: 4 rings), BaP (benzo[a]pyrene: 5 rings), BbF (benzo [b]fluoranthene: 5 rings), BkF (benzo[k]fluoranthene: 5 rings), Chr (chrysene: 4 rings), DbA (dibenz[a,h]anthracene: 5 rings), InP (indeno[1,2,3 - cd] pyrene: 6 rings) and Acp (acenaphthene: 3 rings), Acpy (acenaphthylene: 3 rings), Ant (anthracene: 3 rings), BghiP (benzo[g,h,i]perylene: 6 rings), Flu (fluorene: 3 rings), FluA (fluoranthene: 4 rings), Nap (naphthalene: 2 rings), PhA (phenanthrene: 3 rings) and Pyr (pyrene: 4 rings). Ion source-interface temperature was set at 200°C - 250°C. Internal standards from Sigma Aldrich were used in the analysis and the acquired mass spectra data were then matched against the NIST 2014 library [1] [2]. The mean PAHs concentration in the bottom ashes of each hospital varied broadly from 0.001 mg/kg to 0.4845 mg/kg, and the mean total concentration levels of individual PAHs ranged from 0.0072 mg/kg to 1.171 mg/kg. Low molecular weight PAHs (Phenanthrene, Naphthalene and Fluorene) were predominant in all the hospital wastes whereas Kitale and Narok presented the lowest PAHs concentrations and the lowest number of individual PAHs. Moi/Voi recorded the highest total PAHs concentration at 1.3129 ± 0.0023 mg/kg from a total of 11 PAHs being detected from the bottom ash samples. Narok had only three PAHs being detected at very low concentrations of 0.0041 ± 0.00 mg/kg, 0.0076 ± 0.00 mg/kg and 0.012 ± 0.00 mg/kg for phenanthrene, anthracene and chrysene respectively. This study presents hospital incinerator bottom ash as containing detectable levels of both carcinogenic and non-carcinogenic PAHs. Continued unprotected exposure of hospital workers (waste handlers) to the bottom ash PAHs could be hazardous to their health because of their cumulative effect. Preventive measures e.g. the use of Personal protective equipment (PPE) should be prioritised to minimise direct contact with the bottom ash. The study recommends an upgrade on incinerator technology for efficient combustion processes thus for better pollution control.

Formulation of Motor Oil from Blends of Rubber Latex Cup Bottom Oil (RLBO) and Used Frying Oil (UFO)

Most motor oils are made from mineral oils derived from petroleum, the reserves of which are limited and exhaustible. The aim of this study is to produce and characterize motor oil formulations based on mixtures of rubber latex cup bottom oil (RLCBO) and used frying oil (UFO). The results show that these formulations have a density between 0.91 and 0.92. These densities evolve linearly with the proportion of cup bottom oil and temperature. Similarly, the kinematic viscosity of the blends follows an exponential relationship with temperature. By plotting the logarithm of these kinematic viscosities against the inverse of the temperature, we were able to determine the activation energy of the various blends and deduce that the formulations behave Newtonian.

Concentration of Copper, Zinc, Lead, Cadmium, and Nickel in the Incinerator Bottom Ash in Five County Hospitals in Kenya

Healthcare wastes contain potentially harmful microorganisms, inorganic and organic compounds that pose a risk to human health and the environment. Incineration is a common method employed in healthcare waste management to reduce volume, quantity, toxicity as well as elimination of microorganisms. However, some of the substances remain unchanged during incineration and become part of bottom ash, such as heavy metals and persistent organic pollutants. Monitoring of pollution by heavy metals is important since their concentrations in the environment affect public health. The goal of this study was to determine the levels of Copper (Cu), Zinc (Zn) Lead (Pb), Cadmium (Cd) and Nickel (Ni) in the incinerator bottom ash in five selected County hospitals in Kenya. Bottom ash samples were collected over a period of six months. Sample preparation and treatment were done using standard methods. Analysis of the heavy metals were done using atomic absorption spectrophotometer, model AA-6200. One-Way Analysis of Variance (ANOVA) was performed to determine whether there were significant differences on the mean levels of Cu, Zn, Pd, Cd and Ni in incinerator bottom ash from the five sampling locations. A post-hoc Tukey’s Test (HSD) was used to determine if there were significant differences between and within samples. The significant differences were accepted at p ≤ 0.05. To standardize the results, overall mean of each metal from each site was calculated. The metal mean concentration values were compared with existing permissible levels set by the WHO. The concentrations (mg/kg) were in the range of 102.27 - 192.53 for Cu, Zn (131.68 - 2840.85), Pb (41.06 - 303.96), Cd (1.92 - 20.49) whereas Ni was (13.83 - 38.27) with a mean of 150.76 ± 77.88 for Copper, 131.66 ± 1598.95 for Zinc, 234.60 ± 262.76 for Lead, 12.256 ± 10.86 for Cadmium and 29.45 ± 18.24 for Nickel across the five sampling locations. There were significant differences between levels determined by one-way ANOVA of Zn (F (4, 25) = 6.893, p = 0.001, p ≤ 0.05) and Cd (F (4, 25) = 5.641, p = 0.02) and none with Cu (F (4, 25) = 1.405, p = 0.261, p ≤ 0.05), Pb (F (4, 25) = 1.073, p = 0.391, p ≤ 0.05) and Ni (F (4, 25) = 2.492, p = 0.069). Results reveal that metal content in all samples exceed the WHO permissible levels for Cu (100 mg/kg), while those for Ni were below the WHO set standards of 50 mg/kg. Levels of Zn in three hospitals exceeded permissible level of 300 mg/kg while level of Pb exceeded WHO set standards of 100 mg/kg in two hospitals. Samples from four hospitals exceeded permissible level for Cd of 3 mg/kg. This study provides evidence that incinerator bottom ash is contaminated with toxic heavy metals to human health and the environment. This study recommends that hospitals should handle the bottom ash as hazardous wastes and there is need to train and provide appropriate personal protective equipment to healthcare workers, waste handlers, and incinerator operators and enforce compliance to existing regulation and guidelines on healthcare waste management to safeguard the environment and human health.

Deglacial change of Antarctic Bottom Water in transient simulations

本文利用气候瞬变模拟试验TraCE21k分析了末次冰消期南极底层水(Antarctic Bottom Water,AABW)的演变特征及物理机制.TraCE21k的全强迫试验复现了观测记录里现代大西洋AABW相对于冰期时变薄的特征,其强迫敏感性试验进一步指出冰期-现代AABW的差异主要由大气温室气体的升高及大陆冰川的退缩二者共同驱动.冰消期气候强迫下海洋和大气温度升高,南大洋海冰逐渐消融,后者直接调控了AABW强度和形态的演变.本文还从绝热翻转环流的观点出发,认为冰消期南大洋的气候变化潜在影响了北大西洋深层水的演变.

关于大食物安全战略背景下我国油料保障底线目标及对策的商榷

树立大食物观和实施大食物安全战略是我国新时代推动食物来源更多元、数量更充足、品质更营养、产业更高效、环境更友好、调控更自主、消费更健康、治理更有力的迫切需要。1978年我国实行改革开放以来,包括油料在内的主要农产品生产、贸易、消费发生了历史性巨变,人民生活水平不断提高,但也存在生产和消费结构失衡导致的慢性疾病增多、环境压力加大、安全风险升高等不容忽视的突出问题,其中油料和食用植物油近十多年处于既自给不足又消费超量的两难局面。基于我国自然资源禀赋和经济社会发展的实际,保障未来油料供给安全必须坚持“一靠油菜、二靠花生、多油并举、健康消费”的发展思路,通过综合施策在十年左右将国产植物油产量稳定提高到2000万吨,以确保居民食用油基本消费需求的安全自主供给底线,并不断改善油料产品质量、提高产业竞争力和促进脂质产品的科学健康消费。

新时代“枫桥经验”的实践逻辑

新时代“枫桥经验”作为中国特色基层社会治理的原创性经验,不仅充分彰显了中国人民独立自主探索解决基层矛盾冲突、化解基层矛盾纠纷的实践智慧,而且为推进基层社会治理现代化,构建基层社会治理新格局贡献了诸多有益启示,具有独特的价值意蕴和鲜明的实践特色。坚持人民至上,尊重人民主体地位,注重发挥人民群众参与基层社会治理的首创精神,坚定不移地走群众路线是新时代“枫桥经验”的价值前提;坚持“多元共治”,汇聚多方力量,注重激发多元主体协同参与基层社会治理的内在功能,以此打造“党建引领、政府负责、社会协同、群众参与”的社会治理新模式是新时代“枫桥经验”的时代特点;坚持“三治融合”,遵循治理规律,注重协调自治、德治、法治有序参与基层社会治理的重点内容是新时代“枫桥经验”的内在意蕴;坚持与时俱进,紧随时代潮流与社会变革,勇于识变,敢于求变,善于应变,注重基层社会治理的方法创新是新时代“枫桥经验”的实践诉求。

中国本土背景下可持续物流服务质量评价

自然环境恶化、资源枯竭以及公众健康公平意识的增强,导致行业组织对可持续发展的重视程度日益提高,低碳化、可持续成为物流业发展的必然趋势。但学界对可持续物流服务质量的研究较为零散,包括我国在内的新兴市场国家更缺乏关于可持续物流服务质量的评价工具及实证探索。为弥补这一缺口,首先,对国内外物流服务质量相关文献进行系统回顾,并基于TBL思维、ESG理念及专家评鉴,提出涵盖环境、经济、社会和客户4个服务可持续性因素,包括19个测量指标的可持续物流服务质量评价指标体系。其次,用灰色BWM和改进的灰色关联分析法确定该评价指标体系的指标权重,显示所有指标均具有不同的重要度排序,一级指标按照权重降序排列依次为环境可持续性、客户可持续性、经济可持续性和社会可持续性。之后,为检验所构建的评价指标体系在实践中的有效性,对我国本土两家行业领先的物流服务提供商——京东物流集团和顺丰速运公司的可持续性经营实践实施评估,依据专家评分结果,在同等情况下,建议客户优先选择京东物流集团作为物流服务提供商。最后,通过灵敏度分析,进一步验证所建立的评价指标体系的稳定性及适用性,为我国企业增强物流服务的可持续性以及提升客户满意度提供有效的评价工具。基于此,我国物流服务提供商为实现可持续性转型,应着力使用环保包装材料、更新清洁能源车辆、推动仓储绿色升级以提升环境可持续性,强化服务的及时性、响应性和灵活性以促进客户的可持续性,加强绿色技术创新和推动物流成本持续优化以进一步加强经济可持续性,并通过注重员工培训及权利保护、积极履行社会责任等努力提升社会可持续性,从而构筑可持续的物流服务竞争优势。

海藻酸钠改性垃圾焚烧底灰-矿渣基胶凝堵漏材料研究

针对传统矿用水泥基堵漏材料存在的收缩开裂、高能耗及高碳排放的问题,探索采用海藻酸钠(SA)交联金属离子,制备SA改性垃圾焚烧底灰(MSWI-BA)-粒化高炉矿渣(GBFS)基胶凝堵漏材料(SWM)。通过抗压强度和凝结时间的测试,确定了最佳水固比为0.4。通过胶凝材料在不同温度下的抗压强度、收缩率及裂缝形貌的分析,探究了SA改性对胶凝材料的耐高温性能的影响,结果表明SA改性后,胶凝材料的耐高温性得到了改善,受热后改性胶凝材料表面裂缝明显减少,收缩率较改性前最大降低了26.5%,在400℃受热后,剩余抗压强度仍高达17.25 MPa。结合微观形貌、孔结构性能和热分析实验,探究了SA改性胶凝材料的形成机理,结果表明,SA改性MSWI-BA-GBFS基胶凝堵漏材料通过SA与底物中的Ca^(2+)/Al^(3+)的配位交联与碱激发底物形成的硅铝酸盐共价网络协同作用,细化孔径,减小孔容,在受热后保持基体结构的完整性,从而改善胶凝材料的抗收缩开裂性。堵漏风模拟实验结果表明,水固比0.4的SA改性MSWI-BA-GBFS基胶凝堵漏材料的堵漏性能优于矿用水泥基材料,表现出较好的堵漏性能。SA改性MSWI-BA-GBFS基胶凝堵漏材料的研制不仅为城市垃圾焚烧底灰的资源化利用提供了有效途径,还提供了一种抗压强度高、抗收缩开裂且耐高温的可以完全替代传统矿用水泥基堵漏材料的环保防灭火材料。

基于身管应变的小口径火炮弹丸速度测试方法

针对传统火炮弹丸速度测试方法中存在难以获取整条速度曲线、易受环境影响、体积庞大、成本较高、操作复杂等问题,提出了一种基于身管应变的小口径火炮弹丸速度测试方法。基于30 mm口径火炮设计了应变测试仪,实现身管外壁应变测试。根据厚壁圆筒理论计算得出火炮膛压曲线,通过弹底压力解算模型得出弹底压力曲线,与弹载存储测试方法得到的弹底压力曲线进行对比。结合弹丸运动方程得出弹丸速度曲线,采用四阶龙格库塔算法建立弹丸速度仿真模型,将应变测试、弹载存储测试得到的弹丸速度曲线与仿真曲线进行对比。结果表明:应变测试、弹载存储测试与仿真弹丸速度曲线趋势基本吻合,最大速度误差分别为1.1%和0.5%,验证了应变测试方法的可行性,为小口径火炮弹丸测速开辟了新途径。

视觉诱发电位评估帕金森病视幻觉视觉传导通路临床价值

目的本研究旨在通过视觉诱发电位(visual evoked potential,VEP)评估帕金森病(Parkinson disease,PD)患者的视觉传导通路完整性,特别是那些伴有视幻觉的患者。方法共纳入76例PD患者,根据是否伴有视幻觉分为两组:伴有视幻觉组24例,无视幻觉组52例。为控制变量,同时选取22例性别和年龄匹配的健康对照组。所有受试者接受VEP检测,并针对PD患者进行了统一帕金森病评分量表(UPDRS)、Hoehn&Yahr分期(H-Y分期)和简易智能精神状态检查量表(MMSE)评估。结果伴有视幻觉的PD患者N75、P100、N135潜伏期(88.26±10.47)ms、(118.48±8.53)ms、(144.71±9.48)ms较无视幻觉组(79.00±6.96)ms、(108.60±7.01)ms、(135.95±8.21)ms显著延长(P均<0.001),而N75-P100、N135-P100峰峰波幅[4.35(2.73,7.30)μV]、[6.40(4.15,9.90)μV]则较无视幻觉组[7.10(5.28,9.98)μV]、[9.05(6.30,12.60)μV]显著降低,差异有统计学意义(P<0.001,P=0.037)。相关性分析发现,PD视幻觉组中P100潜伏期与H-Y分期及UPDRS-I、UPDRS-II、UPDRS-III总分呈正相关(r=0.537,P=0.007;r=0.635,P=0.001;r=0.594,P=0.004;r=0.558,P=0.005)。结论视幻觉组PD患者的视觉传导通路完整性受损,且随着疾病进展,视觉传导通路可能遭受进一步破坏,影响可能扩展至上行通路以外的脑区。

探地雷达在白洋淀湖底地层结构探测中的技术攻关与实践

白洋淀湖底地层调查对于白洋淀生态地质调查、湖底生态清淤及湿地生态保护具有非常重要的现实意义。为系统探明白洋淀湖底地层结构,从区域尺度对湖底地层实现完整刻画,为钻探调查提供精确的靶区数据支撑,创新了探地雷达应用范围,采用船载方式,透过水体开展了湖底地层勘查。剖析白洋淀湖底结构探地雷达勘探技术难点,分析了含底泥和不含底泥2种情形下水上勘探电磁波的传播特征和湖底原生地层的地球物理响应条件,建立了淀水+淤泥层+湖底原生地层的湖底简化结构模型。通过对比国内外主流探地雷达系统不同硬件设备的勘探能力与适应条件,优选出双皮划艇搭载50 MHz低频组合天线的工作模式,结合适用于水下电磁波弱信号提取的数据处理技术,获得了白洋淀湖底15 m深度范围的地层结构数据。结果表明,此种工作模式适用于湖区水深小于5 m的水域,原生地层电磁波整体呈现弱反射特征,湖底15 m深度范围内存在2~3组砂层反射界面。淤泥层会大大削弱湖底原生地层的电磁波反射强度。存在厚砂层的水域,电磁波会形成强反射波组,砂层展布形态刻画清晰,砂层厚度变化在0~3 m之间。本项研究实现了湖底地层结构建模分析、天线勘探模式优选、数据处理过程优化等技术集成。该技术成果为白洋淀淀区地下水与地表水三维地质建模提供了基础依据,为湖底地层钻探勘查提供了靶区支撑,有力推动了白洋淀湿地水-陆一体化探测技术方法体系的构建。

硬性支撑联合带蒂鼻中隔黏膜瓣技术在垂体瘤术后鞍底重建中的应用

目的探讨硬性支撑联合带蒂鼻中隔黏膜瓣技术在垂体瘤术后鞍底重建中的应用。方法采用回顾性和观察性的研究方法收集2019年8月至2023年5月西安交通大学第一附属医院神经外科完成的54例经鼻蝶垂体瘤切除患者的临床资料,依据鞍底重建方式分为硬性支撑组和软性重建组,比较两组手术时间、脑脊液漏发生及住院时间等情况。结果两组手术时间及术中出血量比较,差异无统计学意义(P>0.05)。硬性支撑组的术后脑脊液漏发生率及腰大池置管率低于软性重建组,住院时间短于软性重建组(P<0.05)。结论硬性支撑联合带蒂鼻中隔黏膜瓣技术能有效减少经鼻蝶垂体瘤术后脑脊液漏的发生。

基于光纤感测的急倾斜煤层采动围岩变形特征研究

将分布式光纤传感技术应用于急倾斜煤层采场围岩变形及应力分布特征物理相似模型试验,通过在模型中沿煤层倾向布置传感光纤与沿煤层底板铺设压力传感器,实时监测模型内部变形场与应力场,并结合数值模拟分析了急倾斜煤层顶板应变分布及演化特征。结果表明:工作面上部区域应力值小于下部和中部区域,中部区域应力值最大;随工作面推进,采空区底板应力逐渐释放,应力值不断降低,采空区两侧边界煤柱下方煤层底板应力逐渐升高,且中、下部采空区底板应力恢复程度显著高于上部底板;沿煤层倾向布置的光纤应变曲线呈三段分布,具有前后2处应变波峰区及采空区对应的中部波谷区,前波峰远高于后波峰;工作面中上部顶板变形程度大于下部顶板;数值模拟与光纤检测结果一致,均表现出中上部顶板变形显著大于下部。研究弥补了物理相似模型试验监测手段短板。

南海北部被动陆缘洋陆转换带张裂–破裂研究新进展

文章基于深地震探测数据与大洋钻探资料,研究了南海北部被动陆缘洋陆转换带张裂–破裂机制科学问题。2018-2023年在国家基金委共享航次的协助下,实施了三维深地震探测实验,共投放海底地震仪52台次,海底电磁仪2台次,放炮数量达8750炮,累积获得了294Gb的第一手数据,并取得了一系列的创新性成果:1)首次获得南海北部陆缘洋陆转换带深达上地幔的三维速度结构,精准确定了研究区洋陆转换带三维空间展布范围宽度为10~20km;2)揭示南海北部陆缘异常活跃的岩浆作用,提出了不同时间段的构造与岩浆相互作用方式,岩浆活动随着伸展作用不断向洋迁移并逐渐占据主导地位;3)建立了边缘海独特的张裂–破裂地质演化模型,最后一期强烈的岩浆活动导致岩石圈破裂,形成由玄武岩为主的“鳄鱼嘴”构造,同时张裂–破裂过程沿其陆缘走向又存在显著的构造–岩浆差异性。

井底压力下牙轮钻头浮动套轴承性能分析

为了探究井底压力下215.9 mm牙轮钻头浮动套轴承的平衡转速比、摩擦学性能、油膜压力分布随内外间隙比的变化规律,修正了考虑浮动套轴承实际井下环境压力和牙轮钻头密封压差的Reynolds边界条件,利用MATLAB中的PDE Toolbox对浮动套轴承Reynolds方程进行数值求解,分析内外间隙比对浮动套轴承平衡转速比、油膜压力及摩擦因数的影响规律,结果表明:当环境压力为60 MPa、密封压差为20 MPa时,随内外间隙比增加,浮动套平衡转速比呈现先增大后减小的趋势;以轴承的摩擦因数和油膜压力作为综合评价指标,钻头浮动套轴承内外间隙比为2.0时,轴承的摩擦因数较小,油膜压力较高,其轴承综合性能较优;而当浮动套轴承内外间隙比为2.0时,随着环境压力的升高,浮动套轴承的摩擦扭矩和摩擦因数增加,从而加剧轴承的磨损。该研究为牙轮钻头浮动套轴承的结构参数优化及性能提升提供了基础理论支撑。

光热站辅助生物质燃气炉燃烧与升负荷优化大涡模拟

生物质燃气炉设计对于提高低碳能源整合利用具有重要价值,采用LES(大涡模拟)方法,分析热管区温度分布及升负荷时出口参数变化,提出敏感温度T_(a),并分析燃料增加比b对其影响,以焓降分析底部燃烧口角度及位置的影响,得出结论:增加底部入口后,烟气流动更加顺畅,热管进、出口管温度不均情况缓解明显。在升负荷时,烟气分布更加均匀,换热均匀性提升。b=3时,流量差异较小。当底部入口角度为60°,距离热管区域距离为0.135 m时,效果最佳。整体上,增加底部燃烧口在提升设备的运行效率的同时,能够显著改善运行安全性,具有较高的应用价值。

我国共同富裕评价指标体系及测度——基于省级行政区与区域层面的探讨

扎实推动共同富裕的重要基础是科学构建评价指标体系,并准确测度共同富裕水平。本文强调整体思维、多维思维、长线思维和底线思维,系统梳理共同富裕的理论内涵与统计含义,构建由富裕性、共享性与托底性三个一级指标组成的共同富裕评价指标体系,并采用政府统计部门宏观数据与中国家庭追踪调查(CFPS)的大样本微观调查数据,在省级与区域层面测度2010—2018年共同富裕的实现程度。研究发现,从省级层面看,共同富裕指数持续向好,省级行政区之间的共同富裕指数呈收敛趋势;从一级指标看,富裕性指数与托底性指数稳步提升,但共享性指数提升乏力;省际富裕性指数与共享性指数呈比较明显的倒U型关系。从区域层面看,东部、中部、西部、东北地区之间在共同富裕指数上呈现明显的收敛趋势;南方与北方地区之间在共同富裕指数上的差距则呈加速扩大态势,但北方地区共享性维度的指数却一直高于南方地区。本文丰富了构建共同富裕评价指标体系的理论与方法,并将共同富裕的测度细化到省级与区域层面,为刻画共同富裕指数的省际差异、区域差异与时序变动,找准共同富裕的着力点并优化相关政策提供重要借鉴。

基于UNet结构生成对抗网络的海底地震勘探数据混叠噪声压制方法

本文提出一种基于UNet结构生成对抗网络(Pix2PixGAN)的海底地震勘探数据混叠噪声压制方法,该神经网络主要在于构建了一个适用于混叠噪声压制的生成器和判别器,生成器是UNet结构,可以提取和融合数据的特征映射信息,而通过加入skip-connection,可以保留更多的细节信息;判别器由两个卷积模块构成,通过PatchGAN输出多个固定大小的数据体,加入Dropout2d层,优化判别器的训练速度。通过制作的四千余个数据集对网络模型进行训练,将得到的训练参数加载到测试网络中,经过测试数据集的验证以及和常规的去噪方法相比,验证了本文采用的混叠噪声压制方法具有较高的压制精度和效率。

水压与动载耦合作用下高铁隧底结构裂损机理分析

高速铁路隧道底部结构隆起变形开裂是多方面影响因素叠加作用的结果。综合利用扩展有限元方法、流固耦合理论和现场实测结果,采用激振力荷载拟合函数施加于轨面模拟列车振动荷载作用效果,分析在水压和列车动荷载耦合作用下的高铁隧道底部结构不协调变形机理,揭示水压与动荷载作用下隧道底部结构的变形特征与水压力变化规律。研究结果表明:在既有隧底结构型式与排水条件下,水压变化是隧道底部结构变形与开裂的诱发原因,列车动荷载导致的裂缝水压交替变化是隧道底部结构持续性隆起裂损的间接原因。隧道底部结构开裂一般首先发生在仰拱填充层中央排水沟处,然后在轨道板、仰拱填充层与衬砌仰拱结构存在刚度差异的各交界面上出现裂缝。高速列车动荷载周期性的上下振动与水压力耦合作用下隧道底部结构界面和各裂缝过水处产生超静水压力,其周期性抽吸变化将对裂缝产生水力压裂效应,加剧隧道底部结构的裂损。高水压高铁隧道底部结构隆起开裂的整治措施应综合考虑泄水降压、裂缝封堵以及底部多层结构体系的层间锚固。