双变量变频器双侧供电闭环调速系统的研究

针对异步电机定子变频在解决高压电机调速时,对输出电压的等级要求高,对调速技术要求不足,在原有仅采用控制触发增量方法的基础上加入了闭环控制。在Matlab/Simulink仿真软件中,通过在仿真模型中引入S函数,建立了定转子分段变频有级调压闭环调速系统的仿真模型,并以双变量变频器为基础设计了实验电路,编写了实验程序,从仿真和实验两个方面对定转子调速系统的性能进行分析研究。得出双变量交交变频器在绕线式异步电动机转子侧供电实现调速时具有一定的可行性。     

需求侧能量共享:概念、机制与展望

分布式可再生能源的蓬勃发展为建设清洁高效智能电网提供了新途径,但同时也导致了需求侧用户行为更随机、能量管理更困难、设备利用更低效等问题。为应对这些新挑战,充分调动需求侧灵活性,能量共享作为一种分布式运营新范式应运而生。文中给出了需求侧能量共享的概念,分析了其在平抑不确定性、提升运行经济性和提高设备利用效率等方面的潜力,并对能量共享机制的设计要点及基本要求进行了详细阐述。在此基础上,从合作博弈与非合作博弈2个角度将国内外能量共享机制设计相关研究归纳为5类,总结了当前的研究进展与亟待解决的问题。最后,从需求侧能量共享市场内部设计与外部衔接2个方面,对未来的研究方向进行了展望。     

基于VERICUT的虚拟龙门加工中心建模和仿真关键技术研究

为减少零部件试切,检验数控工艺合理性,构建了虚拟龙门加工中心。研究了龙门加工中心运动,阐述了侧面铣头运动由旋转中心和换刀点控制,提出了虚拟机床侧面铣削运动构建方法,可实现各角度侧面铣。搭建了虚拟加工环境,通过零件仿真加工,完成了零件顶面及4个侧面的铣削加工,验证了数控代码的正确性,检验了数控工艺合理性,减少了零件试切,缩短了开发周期,仿真结果表明虚拟龙门加工中心的正确性。     

Friction stir welding of AZ31 magnesium alloy

Friction stir welding (FSW) is an new solid-phase joining technology which has more advantages over fusion welding methods in welding of aluminum and other non-ferrous metals. The effects of welding parameters on mechanical properties and microstructure during friction stir welding of AZ31 magnesium alloy were studied in this paper. Microstructures and mechanical properties of the joints were investigated by means of optical microscopy, scanning electric microscopy ( SEM ) , micro-hardness analysis, and tensile test. Experimental results show that the magnesium alloy can be successfully welded by FSW method, and the ultimate tensile strength (UTS) of FSW joint reaches up to 90 percent of base metal. The microstructures of welded joints exhibit the variation from dynamically recrystallized fine grains to greatly deformed grains. Hardness in nugget zone was found lower than the base metal but not too obvious.     

侧吹气流方向对大功率CO2激光焊缝成形的影响

激光深熔焊过程中会在熔池上方产生等离子体云，若该等离子体云过密，将降低激光入射到工件表面能量密度。在工业应用中，常采用侧吹辅助气体来减弱等离子体云的影响。本文通过试验，研究了在不同气体流量下，侧吹气体方向不同对焊接过程稳定性和焊缝成形的影响。结果发现：使用大功率CO2激光焊接AH32时。侧吹气体方向对焊缝成形有着明显的影响。从熔池和等离子体两个方面，解释了侧吹气体方向的影响机制。     

Effect of Al<Subscript>2</Subscript>O<Subscript>3</Subscript> particles on the microstructure and sliding wear of 7075 Al alloy manufactured by squeeze casting method

Aluminum (Al) alloy 7075 reinforced with Al₂O₃ particles was prepared using the stir casting method. The microstructure of the cast composites showed some degree of porosity and sites of Al₂O₃ particle clustering, especially at high-volume fractions of Al₂O₃ particles. Different squeeze pressures (25 and 50 MPa) were applied to the cast composite during solidification to reduce porosity and particle clusters. Microstructure examinations of the squeeze cast composites showed remarkable grain refining compared with that of the matrix alloy. As the volume fraction of particles and applied squeeze pressure increased, the hardness linearly increased. This increase was related to the modified structure and the decrease in the porosity. The effect of particle volume fraction and squeeze pressure on the dry-sliding wear of the composites was studied. Experiments were performed at 10, 30, and 50 N with a sliding speed of 1 m/s using a pin-on-ring apparatus. Increasing the particle volume fraction and squeeze pressure improved the wear resistance of the composite compared with that of the monolithic alloy, because the Al₂O₃ particles acted as load-bearing constituents. Also, these results can be attributed to the fact that the application of squeeze pressure during solidification led to a reduction in the porosity, and an increase in the solidification rate, leading to a finer structure. Moreover, the application of squeeze pressure improved the interface strength between the matrix and Al₂O₃ particles by elimination of the porosity at the interface, thereby providing better mechanical locking.     

Numerical analysis of friction stir welding process

Friction stir welding (FSW), which has several advantages over the conventional welding processes, is a solid-state welding process where no gross melting of the material being welded takes place. Despite significant advances over the last decade, the fundamental knowledge of thermomechanical processes during FSW is still not completely understood. To gain physical insight into the FSW process and the evaluation of the critical parameters, the development of models and simulation techniques is a necessity. In this article, the available literature on modeling of FSW has been reviewed followed by details of an attempt to understand the interaction between process parameters from a simulation study, performed using commercially available nonlinear finite element (FE) code DEFORM. The distributions of temperature, residual stress, strain, and strain rates were analyzed across various regions of the weld apart from material flow as a means of evaluating process efficiency and the quality of the weld. The distribution of process parameters is of importance in the prediction of the occurrence of welding defects, and to locate areas of concern for the metallurgist. The suitability of this modeling tool to simulate the FSW process has been discussed. The lack of the detailed material constitutive information and other thermal and physical properties at conditions such as very high strain rates and elevated temperatures seems to be the limiting factor while modeling the FSW process.     

LF2铝合金搅拌摩擦焊接接头的组织与性能

对10 mm厚LF2铝合金搅拌摩擦焊接进行了研究.结果表明:焊接厚板时,为防止出现隧道型缺陷,须在较低的焊速和转速下进行.当焊速为9 mm/min,转速为950 r/mln,焊接输入能量为6 230 W时,接头强度值最高,其值与母材强度值相等.接头处由平均尺寸约为15 μm的均匀细小的晶粒组成;热影响区平均晶粒尺寸较大,其最大值约为28 μm;热机械影响区内组织细长,局部区域最大长度可达到85 μm.焊核区平均硬度与母材相当,中心最高硬度可达HV95,近缝区硬度低于母材硬度.     

搅拌工具尺寸和工艺参数对塑料搅拌摩擦焊焊缝质量的影响

用不同尺寸的搅拌工具对聚氯乙烯(PVC)板材进行了搅拌摩擦对接焊工艺试验.试验证明,在搅拌工具肩部直径为30 mm,搅拌头直径为10 mm,搅拌头旋转速度为1 660 r/min,焊接速度为25 mm/min的情况下,可以得到焊缝饱满、成形美观的焊接接头.提高搅拌头的旋转速度可以成比例地提高焊接温度;焊接速度的影响较复杂,增大焊接速度一方面会降低焊接热输入,一方面又会间接地增大搅拌头的进给阻力,从而增大摩擦发热功率,提高焊接温度;搅拌工具肩部直径直接影响肩部与被焊材料表面的摩擦发热功率,增大肩部直径可以提高焊接温度,还有利于阻止焊缝材料的飞溅和外溢;而搅拌头直径的影响较复杂,增大它既可以提高搅拌头侧面与被焊材料之间的相对运动线速度,从而提高焊接温度,又会增加被焊材料的吸热功率和传热面积,从而降低焊接温度.     

ZL114A铸铝搅拌摩擦焊接头性能

研究了采用不同焊接参数时ZL114A铸铝搅拌摩擦焊接头的金相组织、硬度分布及力学性能。结果表明，ZL114A铸铝的搅拌摩擦焊焊接性良好。焊核区的微观组织是无方向性的、细小的等轴晶粒。细化的硅粒子均匀布满整个焊核区。与粗大的树枝状母材相比，焊核晶粒细小、均匀而致密，没有观察到气孔等缺陷。焊缝区硬度分布较母材稳定，变化范围小。随着焊速增加，硅粒子所占体积比逐渐下降。热一机械影响区晶粒被拉长。接头的力学性能与焊接参数的匹配有关系。采用高焊速及转速与焊速比在3左右，获得的接头抗拉强度可达到母材的91％。焊后经T6热处理，可与同炉热处理母材等强。