Contract Mechanism of Water Environment Regulation for Small and Medium Sized Enterprises Based on Optimal Control Theory

The small and scattered enterprise pattern in the county economy has formed numerous sporadic pollution sources, hindering the centralized treatment of the water environment, increasing the cost and difficulty of treatment. How enterprises can make reasonable decisions on their water environment behavior based on the external environment and their own factors is of great significance for scientifically and effectively designing water environment regulation mechanisms. Based on optimal control theory, this study investigates the design of contractual mechanisms for water environmental regulation for small and medium-sized enterprises. The enterprise is regarded as an independent economic entity that can adopt optimal control strategies to maximize its own interests. Based on the participation of multiple subjects including the government, enterprises, and the public, an optimal control strategy model for enterprises under contractual water environmental regulation is constructed using optimal control theory, and a method for calculating the amount of unit pollutant penalties is derived. The water pollutant treatment cost data of a paper company is selected to conduct empirical numerical analysis on the model. The results show that the increase in the probability of government regulation and public participation, as well as the decrease in local government protection for enterprises, can achieve the same regulatory effect while reducing the number of administrative penalties per unit. Finally, the implementation process of contractual water environmental regulation for small and medium-sized enterprises is designed.

Corrosion Mechanism of Alumina-magnesia Dry Materials for Smelting Manganese/chromium Steel in Coreless Medium Frequency Induction Furnaces

Alumina-magnesia dry materials are widely used in induction furnace linings, but they show different kinds of damage when melting different kinds of alloy steel. In this paper, the chemical composition, phase composition, and microstructure of the post-use dry materials for the working liners melting different kinds of steel were evaluated. Furthermore, the corrosion mechanism of the steel on the furnace lining materials was comprehensively analyzed. The findings reveal a significant ability of the Mn element in the molten steel to diffuse and penetrate into the refractories. Mn oxidizes to form MnO at the steel-refractory interface, and then forms a liquid phase with Al_(2)O_(3). The Cr element is dissolved into corundum and spinel of the refractories, resulting in lattice defects and structural damage of the materials. TiO2reacts with Al_(2)O_(3) to form Al_(2)TiO_(5), which plays a crucial role in preventing crack formation and propagation. Part of Ti4+dissolves into magnesia-alumina(MA), densifying the materials. TiO2also slows down the reaction between the Cr element and refractory components, further improving the corrosion resistance of the materials.

Diagnostic Analysis of Mechanical Conditions of Small-Scale Incinerators in the Healthcare Facilities in Tanzania

This paper provides analytical diagnosis of mechanical conditions of medical waste incinerators used for healthcare waste (HCW) treatment in Tanzania. The main features assessed were types of incinerators, features of incinerators and incinerator house. The assessment was conducted in three levels of health care facilities (HCFs), that is, Regional, district hospitals and health centers, existed in 26 regions of Tanzania. Questionnaires, interview and checklists were used as tools for data collection. It was observed that High-Tech incinerators are mainly used in regional hospitals, while district hospital and health center use both High-Tech and De-Montfort incinerators. About 60% of the incinerators have defective doors. More than 55% of incinerators are corroded in regional and district hospitals. The chimney, top plates and grate which are good condition are 55.6% and 60% in regional hospitals and health centers, respectively. The situation is below 50% in district hospitals. The leakage of the roof and loose structures were observed in district hospitals and health center to be more than 50% of the incinerator houses. On other hand, the performance of burners and incinerator housing cleanliness are generally good. It was concluded that the incinerators in the HCFs are in bad conditions, necessitating maintenance.

Effect of WC grain size on mechanical properties and microstructures of cemented carbide with medium entropy alloy Co-Ni-Fe binder

For developing new binder phase with high performance, Co-Ni-Fe alloy was used as binder in cemented carbides. The mechanical properties of WC-CoNiFe and WC-Co cemented carbides with different grain sizes were studied. The results show that the reprecipitation of WC-CoNiFe is inhibited compared with that of WC-Co during sintering process, and the grains in WC-CoNiFe cemented carbides are more of smooth shape, resulting in a slightly lower hardness and higher transverse rupture strength. With the increase of the grain size, the hardness of the two cemented carbides decreases, and the transverse rupture strength increases. However, the slope values of K in Hall-Petch relationship are higher in WC-CoNiFe than those in WC-Co, indicating the high toughness of medium entropy alloy Co-Ni-Fe.

Preparation of high-mechanical-property medium-entropy CrCoNi alloy by asymmetric cryorolling

In order to obtain good strength−plasticity synergy for a medium entropy alloy(MEA)CrCoNi,cold rolling,asymmetric rolling,cryorolling and asymmetric-cryorolling with subsequent annealing at different temperatures were conducted.The results showed that the asymmetric-cryorolled alloy achieved a high strength of over 1.6 GPa.After annealing at 1073 K,it retained a high strength of~1 GPa while the elongation reached nearly 60%.After annealing,the heterogeneous characteristics were formed in asymmetric-cryorolled samples,which were found to be more distinct than those of the samples subjected to asymmetric rolling.This resulted in the generation of high strength and ductility.

Influence of soaking time in deep cryogenic treatment on the microstructure and mechanical properties of low-alloy medium-carbon HY-TUF steel

The influence of soaking time in deep cryogenic treatment on the tensile and impact properties of low-alloy medium-carbon HY-TUF steel was investigated in this study. Microstructural studies based on phase distribution mapping by electron backscatter diffraction show that the deep cryogenic process causes a decrease in the content of retained austenite and an increase in the volume fraction of η-carbide with increasing soaking time up to 48 h. The decrease in the content of retained austenite from ~1.23vol% to 0.48vol% suggests an isothermal martensitic transformation at 77 K. The η-type precipitates formed in deep cryogenic-treated martensite over 48 h have the Hirotsu and Nagakura orientation relation with the martensitic matrix. Furthermore, a high coherency between η-carbide and the martensitic matrix is observed by high-resolution transmission electron microscopy. The variations in macrohardness, yield strength, ultimate tensile strength, and ductility with soaking time in the deep cryogenic process show a peak/plateau trend.

MECHANISM AND APPLICATION OF COAL DRY BENEFICIATION WITH AIR-DENSE MEDIUM FLUIDIZED BED

The mechanism of beneficiation with air dense fluidized bed has been theoretically studied in the paper. Focusing attention on the misplacing resources in separation process, the misplacing effects are divided into two parts called respectively as misplacing effect of viscosity and misplacing effect of motion. The proposed separation theory can reasonably explain the results of separation in different fluidization states. Experimental results in pilot and commercial plants showed that the air dense medium fluidized bed is a high efficiency dry cleaning technique. The dynamic stability of fluidized bed density is directly affected by the variation of fine coal content in fluidized bed and can be controlled in expected range through measurement of fluidized bed density and adjusting of split flow rate. With air dense medium fluidized bed, various coals of size 50—6 mm can be efficiently beneficiated. The separation density can be adjusted between 1.2—2.2 g/cm 3, and the probable error E p value is about 0.06.

Constitutive model for Ya'an mudstone based on mesoscopic breakage mechanism

The slope stability of Ya’an expressway in Sichuan dominated by mudstone strata,is influenced greatly by both the mechanical properties and stressstrain relationship of mudstone.In this paper,the mechanical properties of the Ya’an mudstone samples under triaxial compression conditions were studied,based on an established constitutive model under the framework of breakage mechanics to simulate the mechanical properties of mudstone.Firstly,triaxial compression tests and SEM tests at the confining pressures of 0.5 MPa,1.0 MPa,and 2.0 MPa were carried out on the mudstone samples,and it was found that the mudstone sample undergoes strain softening and dilatancy followed by the volumetric compaction.Then,based on analysis on the breakage mechanism of the above test results,we idealized the mudstone sample as a binary medium material consisting of the bonded elements and frictional elements,of which the bonded elements are composed of solid matrix and pores,and the frictional elements are composed of broken aggregates.During the loading process,the cementation between clay minerals and non-clay minerals in the mudstone sample is first destroyed,leading to the formation of micro-cracks within the particle aggregate,that is,the bonded elements are gradually damaged during the loading process and gradually turned into the frictional elements,and the two jointly bear the external load.The bonded elements are composed of mudstone matrix and pores,which have the cementitious characteristics of mudstone,and the frictional elements are composed of the broken aggregate with the frictional characteristics of the broken particles.Based on the homogenization theory,the constitutive model for the mudstone is established,and the determining method for model parameters is also given.Finally,the results of the triaxial compression tests of the mudstone samples are predicted by the constitutive model proposed here,which can reflect the main mechanical properties of the mudstone samples.

Organo-silane compounds in medium density fiberboard:physical and mechanical properties

We studied the effects of nanoparticles of organo-silane（NOS） compounds in the size range of20–80 nm on physical and mechanical properties in medium density fiberboard,and used NOS at four consumption levels of 0,50,100,and 150 g kg-1dry wood fibers.Density of all treatments was kept constant at 0.67 g cm-3.The water-repellent property of organo-silane significantly reduced water absorption（WA） and thickness swelling but mechanical properties declined due to the reduced proportion of wood-fiber as organo-silane was added to the matrix：the compression ratio of MDF panels and the integrity among wood-fibers both declined,resulting in reduced mechanical properties.We recommend use of 50 g of NOS/kg wood-fiber to improve WA and thickness swelling while retaining acceptable mechanical properties.

An Experiment on Power Properties in a Small-Scaled Wind Turbine Generator

This study configures a simple wind tunnel using a blower for generating wind energy, which is equivalent to natural wind, and a test system that measures properties of power. Also, the mechanical and electrical power in a small-scaled wind turbine are empirically measured to analyze the relationship between the mechanical and electrical power.

Mechanism of Impact of Entrepreneurial Spirit on the Development of Small and Medium-sized Private Enterprises in China

As a necessary factor for a successful business,entrepreneurial spirit is an important means for enterprises to survive in the unstable environment of fierce competition. Under the circumstance of mass entrepreneurship and innovation,a large number of small and medium-sized private enterprises have emerged in all walks of life in China. This paper examines the differences in the definition of entrepreneurial spirit by different scholars,the influence of Chinese entrepreneurship on the development of small and medium-sized private enterprises,the origin of the spirit of private entrepreneurs with Chinese characteristics,and the disadvantages of the spirit of small and medium-sized private entrepreneurs in China. It is necessary to further improve entrepreneurial spirit to contribute to the development of small and medium-sized private enterprises and help China to build the national economic system.

Ductile Fracture Characterization for Medium Carbon Steel Using Continuum Damage Mechanics

This paper presents the ductility characterization for a medium carbon steel, for two microstructural conditions, that has been evaluated using the continuum damage mechanics theory, as proposed by Kachanov and developed by Lemaitre. Tensile tests were carried out using loading-unloading cycles in order to capture the gradual deterioration of the elastic modulus, which may be linked to the ductile damage increase with increasing plastic strain. The mechanical parameters for the isotropic damage evolution equation were obtained and then used as inputs for a plasticity-damage coupled nu- merical algorithm, validated through numerical simulations of the experimental tensile tests. A comparison between the SAE 1050 steels studied and two carbon steel alloys (obtained from the literature), provided some basic understanding of the influence of the carbon level on the evolution of the damage parameters. An empiric relationship for this set of parameters, which can provide useful data for preliminary studies envisaging prediction of ductile failure in carbon steels, is also presented.

(Ti_(60)Cr_(30)Nb_(10))_(100-x)Al_(x)轻质中熵合金的力学与腐蚀性能

研究轻质(Ti_(60)Cr_(30)Nb_(10))_(100-x)Al_(x)(x=0,5,7.5,10,摩尔分数,%)中熵合金在铸态和均匀化态下的显微组织、力学性能和腐蚀行为。结果表明,随着Al含量从0增加到10%(摩尔分数),铸态合金均由相同的相组成,即体心立方(BCC)相和少量TiCr2型Laves相组成。均匀化后,所有合金均由单相BCC组成。此外,(Ti_(60)Cr_(30)Nb_(10))_(95)A_(l5)中熵合金表现出在铸态和均匀态条件下最优异的力学性能,屈服强度分别约为1048 MPa和1017 MPa,同时保持超50%压缩应变。与TC4和铸态(Ti_(60)Cr_(30)Nb_(10))_(95)A_(l5)合金相比,均匀态(Ti_(60)Cr_(30)Nb_(10))_(95)A_(l5)合金表现出更优异的耐腐蚀性能,这主要归因于均匀的显微组织与化学成分。

W-CoCrNi合金的烧结致密化及其组织与性能

本文采用粉末冶金技术制备以CoCrNi中熵合金为黏结相的W-CoCrNi高密度钨合金,研究黏结相含量和烧结温度(1300~1500℃)对合金显微组织和力学性能的影响。结果表明:烧结态合金组织由W相、CoCrNi相、Co_(7)W_(6)相和亚微米富Cr颗粒组成。随着烧结温度的升高,合金致密度随之升高。合金在1500℃以下烧结时,致密化机制主要为固相烧结机制,固相烧结驱动力主要来自于表面能的降低和Co_(7)W_(6)新相的形成。当烧结温度达1500℃时,合金致密化机制主要为液相烧结机制,致密化过程包含W向CoCrNi熔体中的溶解和扩散、Co_(7)W_(6)相析出和钨颗粒球化三个阶段。1500℃烧结温度下制备的75W-CoCrNi和95W-CoCrNi合金的压缩屈服强度分别为1060 MPa和1602 MPa,75W-CoCrNi合金在压缩应变超过50%时仍未断裂。随着CoCrNi黏结相含量的增加,合金致密度随之升高,压缩变形能力增加,但压缩屈服强度降低。

永进油田致密储集层岩石力学参数剖面构建及应用

为评价低渗致密储集层可压裂性,对准噶尔盆地沙湾凹陷永进油田Y301井和Y3井的6块岩心进行实验,获得岩心矿物组分、孔隙度、应力—应变曲线、纵波速度、横波速度等参数,实验结果与测井、录井数据基本吻合,构建了研究区岩石力学参数经验模型。同时,基于等效介质模型,考虑矿物组分和孔隙结构特征建立了一种新的岩石脆性指数计算模型。在此基础上,提出了基于测井数据的低渗致密储集层力学参数剖面构建方法,并以Y301井为例进行了计算,结果表明,Y301井齐古组可压裂性良好,为致密砂岩储集层可压裂性综合评价奠定了基础。

丁腈橡胶耐石油开采介质影响因素分析

研究了结合丙烯腈含量、硫化体系、增强体系和增塑体系对丁腈橡胶(NBR)耐石油开采领域中常见化学介质腐蚀规律的影响。结果表明,随着结合丙烯腈含量的增加,NBR硫化胶的物理机械性能及耐热空气老化性能均提高,耐煤油、海底控制液等非极性介质的性能较好,耐甲醇、蒸馏水和乙二醇水溶液的性能逐渐下降,耐酸碱盐水溶液的性能相差不大;硫化体系主要影响NBR硫化胶的物理机械性能及耐热空气老化性能,对NBR硫化胶耐各种石油开采介质的影响则相差不大;对于高硬度NBR硫化胶,当增强体系采用小粒径炭黑时,NBR硫化胶的物理机械性能最好,不同增强体系对NBR硫化胶耐热空气老化性能的影响并不明显,但当增强体系采用大粒径炭黑时,NBR硫化胶具有更好的耐甲醇和煤油的性能,同时要求选用惰性填料进行增强;添加了大分子酯类增塑剂的NBR硫化胶较添加小分子酯类增塑剂、液体NBR增塑剂的物理机械性能更为优异,耐热空气老化性能相差不大,但耐各种石油开采介质的体积变化均偏大,耐甲醇、煤油及10%氢氧化钠水溶液的性能较差,而耐其他石油开采介质的影响则较小。

变形量对(CoNiV)97Al_(3)中熵合金组织和力学性能的影响

高强度和高塑性的中熵合金,相较于传统合金能够满足更多的实际应用。通过在CoNiV合金中掺入微量Al,经过退火处理来提高其力学性能。制备了不同Al含量的铸态(CoNiV)_(100-x)Al_(x)(x为1、2、3、4、5,原子分数/%)合金。采用万能试验机、维氏硬度计、X射线衍射仪、光学显微镜、扫描电子显微镜、透射电子显微镜,研究了退火温度、Al含量及拉伸变形量对合金力学性能、显微组织的影响。实验结果表明,随着Al含量的增加,合金的伸长率提升到30%以上,维氏硬度从755.8降低到375.6。经过1000℃退火处理后的合金达到更高的强度-塑性平衡,伸长率可达到35%以上,拉伸屈服强度较高(超过950 MPa)。实验选择(CoNiV)_(97)Al_(3)(Al3)中熵合金作为研究对象,将系统分析拉伸变形量(50%、100%)对Al3合金微观组织及力学性能的影响。Al3合金在拉伸变形过程中,位错滑移主导变形,孪晶增加位错存储量,促进位错滑移堆积,该合金变形-断裂过程的主要为位错与孪晶的协同作用。

考虑多能源同台竞价的电力中长期融合交易机制设计与实践

新能源的入市可加速新型电力系统建设,针对新能源发电的随机性和波动性而导致上网电量与市场交易电量偏差较大的问题,设计了一种多能源同台竞价的融合交易机制。通过设计融合交易机制的组织流程与出清方式构建了新能源发电商(NEP)在不同交易模式下的结算模型,以江西电力中长期市场为背景设置算例参数,对NEP在几种交易模式下的收益进行分析,并对采用融合交易机制的江西电力中长期市场运行情况进行了对比分析。结果显示所提交易机制能促进新NEP达成交易,明显提升NEP的经济效益,有效推动新能源的入市进程并显著减少交易偏差率。

预热温度对激光选区熔化成形30%SiC_(p)/AlSi10Mg复合材料力学性能的影响

基板常温工况下激光选区熔化成形中等体积分数SiC_(p)/Al复合材料存在孔洞、裂纹等冶金缺陷,从而导致成形零件致密度低、力学性能差等问题。首先研究了固定优化成形工艺参数时,基板预热温度(200~400℃)对45μm的30%(质量分数,下同)SiC_(p)/AlSi10Mg成形零件表观致密度和力学性能的影响;进一步提高SiC_(p)质量分数至50%,再次评价了上述基板预热温度对成形性能的影响。结果表明,当SiC_(p)质量分数为30%时,升高基板预热温度可以减少成形零件的孔洞和裂纹,成形零件的表观致密度及力学性能显著提高;当基板预热至400℃时,成形零件表观致密度最高达到97.98%,与此同时极限抗压强度和极限抗拉强度分别为578 MPa和56 MPa;随着SiC_(p)质量分数进一步增加至50%,基板预热温度对成形零件致密化和力学性能的强化效果逐步减弱。本研究证明高温预热基板能够有效抑制激光选区熔化成形中等体积分数SiC_(p)/Al复合材料的冶金缺陷,为增材制造SiC_(p)/Al复合材料提供了工程应用解决方案。

涡轮泵用不同槽型流体动压型机械密封运行特性对比研究

针对火箭发动机低温介质涡轮泵端面密封的泄漏突增问题,基于工程经验提出激光脸(槽深3、5μm)和螺旋槽3种槽型结构,并与原使用的雷列槽进行端面流场与密封性能对比分析,同时对4种槽型结构进行密封动态追随性比较分析。结果发现:低温介质下雷列槽端面密封流体动压较弱,影响端面开启的主要因素为流体介质静压力;在转速和压力增大的条件下雷列槽存在负动态刚度系数,角向的稳定性较差,存在泄漏风险;激光脸泄漏量较低且处于混合润滑状态,不会因密封端面脱开而引起密封动态不稳定;槽深5μm与槽深3μm激光脸相比有更大的开启力与较低的相变率,综合性能更优;螺旋槽结构动压效应较强,其开启力随转速和压力的线性变化都保障了密封环的追随性;螺旋槽结构具有较强变工况适应性,但泄漏量水平始终较高。