使用NI TestStand测试手机基站

利用0racle创建一个记录测试项目和进程的数据库，使用NI TestStand、LabVIEW以及SQL Toolkit创建基于数据库的测试应用程序。为摩托罗拉各种手机基站产品开发一套独立的测试应用软件。     

Improving Electric Motors by Better Designing

Although there is a great deal of emphasis on replacement of National Electrical Manufacturers Association (NEMA) frame motors with EPAct/premium efficient motors, the vast majority of medium-voltage motors in use today fall outside the scope of EPAct. Many of these machines offer considerable opportunities to enhance performance during future rewinds. There are several ways to improve the reliability and efficiency of existing form-wound motors. Some of these opportunities can be capitalized on during the course of a repair, by optimizing the winding design, with little additional effort beyond the routine rewind. Others can be applied to in-service machines with no requirement to remove the machine from service. This study evaluated 94 sets of form coil winding data, comparing wire and slot dimensions, to assess the opportunity for magnet wire slot fill improvement. Motor ratings ranged from 200 to 5,000 hp (149 to 3730 kW), from 2 to 32 poles, 2.3 to 13.2 kV. The preponderance of data (43 motors) was for two- and four-pole machines, since those are most common in the petrochemical industry.     

Translocational pausing of apolipoprotein B can be regulated by membrane lipid composition

One potential mechanism by which apolipoprotein (apo) B secretion is regulated is via transient pausing during translocation across the endoplasmic reticulum membrane. We have previously shown that translocation and secretion of full-length and truncated variants of apoB 100 are impaired in hepatocytes in which microsomal membranes are enriched in the phospholipid phosphatidylmonomethylethanolamine (PMME). We have now investigated whether or not the decreased translocation of apoB is the result of altered membrane lipid composition having an impact on translocational pausing. Our experiments showed that less in vitro translated apoB-15 (the N-terminal 15% of human apoB-100) was translocated into the lumen of PMME-enriched microsomes than of control microsomes. Proteinase K treatment of the translocation products yielded discrete N-terminal fragments of apoB indicating that both types of microsomal membranes contained translocationally paused nascent chains. Similarly, apoB generated from a truncated mRNA lacking a stop codon was also found to be translocationally paused. However, restarting of translocation after translocational pausing was impaired in PMME-enriched, but not in control, microsomes. These data suggest that secretion of apoB-containing lipoproteins can be regulated by membrane lipid composition at the level of translocational pausing.     

Exploring Mount Erebus by walking robot

Dante is a tethered walking robot capable of climbing steep slopes. In 1992 it was created at Carnegie Mellon University and deployed in Antarctica to explore an active volcano, Mount Erebus. The Dante project's robot science objectives were to demonstrate a real exploration mission, rough terrain locomotion, environmental survival, and self-sustained operation in the harsh Antarctic climate. The volcano science objective was to study the unique convecting magma lake inside Mount Erebus' inner crater. The expedition demonstrated the advancing state-of-art in mobile robotics and the future potential of robotic explorers. This paper details our objectives, describes the Dante robot, overviews what happened on the expedition and discusses what did and didn't work.     

Highly conductive carbon nanotube buckypapers with improved doping stability via conjugational cross-linking

Carbon nanotube (CNT) sheets or buckypapers have demonstrated promising electrical conductivity and mechanical performance. However, their electrical conductivity is still far below the requirements for engineering applications, such as using as a substitute for copper mesh, which is currently used in composite aircraft structures for lightning strike protection. In this study, different CNT buckypapers were stretched to increase their alignment, and then subjected to conjugational cross-linking via chemical functionalization. The conjugationally cross-linked buckypapers (CCL-BPs) demonstrated higher electrical conductivity of up to 6200?S?cm( - 1), which is more than one order increase compared to the pristine buckypapers. The CCL-BPs also showed excellent doping stability in over 300?h in atmosphere and were resistant to degradation at elevated temperatures. The tensile strength of the stretched CCL-BPs reached 220?MPa, which is about three times that of pristine buckypapers. We attribute these property improvements to the effective and stable conjugational cross-links of CNTs, which can simultaneously improve the electrical conductivity, doping stability and mechanical properties. Specifically, the electrical conductivity increase resulted from improving the CNT alignment and inter-tube electron transport capability. The conjugational cross-links provide effective 3D conductive paths to increase the mobility of electrons among individual nanotubes. The stable covalent bonding also enhances the thermal stability and load transfer. The significant electrical and mechanical property improvement renders buckypaper a multifunctional material for various applications, such as conducting composites, battery electrodes, capacitors, etc.     

Application of response surface methodology in the optimization of laser treatment in buckypaper lighting for field emission displays

Carbon nanotube field emission backlight (CNT-BLU) is promising to replace traditional backlighting devices in liquid crystal display (LCD) industry. This study reports a laser irradiation process to enhance field emission properties of buckypaper, a thin sheet of high-loading carbon nanotube network. The scanning laser treated the selected region of buckypaper to activate CNT emitters. The improvement of phosphorescence luminance intensity, uniformity, and the reduction of turn-on field were achieved by adjusting machining parameters of laser power, laser lens motion speed, laser resolution, laser beam size, and pattern orientation. Design of experiment and response surface methodology provided ways to rapidly search the feasible laser parameter setting for processing buckypaper field emitters and improving field emission properties within fewer experimental runs. 2^5?1 Fractional fracotrial design presented the initial models of five repsponses. In addition, the face-centered central composite design is applied since the 2^5?1 factional factorial design showed curvature significance. It assisted to give the scientifical insight of the following conclusions. High-energy laser treatment damages and burns the CNTs into carbon oxide materials; furthermore, it loses the effective CNTs. Low-energy laser treatment performs CNT activation and produced low field emission performance. In this study, we succeeded to apply statistical analysis methods to understand the physics and mechanics of laser-activated buckypaper field emission and, furthermore, improve, optimize, and demonstrate performance by material selection, process development, and characterization.     

Alignment and properties of carbon nanotube buckypaper/liquid crystalline polymer composites

Carbon nanotubes (CNTs) have been recognized as a potential superior reinforcement for high‐performance, multifunctional composites. However, non‐uniform CNT dispersion within the polymer matrix, the lack of adequate adhesion between the constituents of the composites, and lack of nanotube alignment have hindered significant improvements in composite performance. In this study, we present the development of a layer‐by‐layer assembly method to produce high mechanical performance and electrical conductivity CNT‐reinforced liquid crystalline polymer (LCP) composites using CNT sheets or buckypaper (BP) and self‐reinforcing polyphenylene resin, Parmax. The Parmax/BP composite morphology, X‐ray diffraction, mechanical, thermal, and electrical properties have been investigated. SEM observations and X‐ray diffraction demonstrate alignment of the CNTs due to flow‐induced orientational ordering of LCP chains. The tensile strength and Young's modulus of the Parmax/BP nanocomposites with 6.23 wt % multi‐walled carbon nanotube content were 390 MPa and 33 GPa, respectively, which were substantially improved when compared to the neat LCP. Noticeable improvements in the thermal stability and glass transition temperature with increasing CNT content due to the restriction in chain mobility imposed by the CNTs was demonstrated. Moreover, the electrical conductivity of the composites increased sharply to 100.23 S/cm (from approximately 10^?13 S/cm) with the addition of CNT BP. These results suggest that the developed approach would be an effective method to fabricate high‐performance, multifunctional CNT/LCP nanocomposites. © 2012 Wiley Periodicals, Inc. J. Appl. Polym. Sci., 2013     

Simulations of stress-induced twinning and de-twinning: A phase field model

Twinning in certain metals or under certain conditions is a major plastic deformation mode. Here we present a phase field model to describe twin formation and evolution in a polycrystalline fcc metal under loading and unloading. The model assumes that twin nucleation, growth and de-twinning is a process of partial dislocation nucleation and slip on successive habit planes. Stacking fault energies, energy pathways (γ surfaces), critical shear stresses for the formation of stacking faults and dislocation core energies are used to construct the thermodynamic model. The simulation results demonstrate that the model is able to predict the nucleation of twins and partial dislocations, as well as the morphology of the twin nuclei, and to reasonably describe twin growth and interaction. The twin microstructures at grain boundaries are in agreement with experimental observation. It was found that de-twinning occurs during unloading in the simulations, however, a strong dependence of twin structure evolution on loading history was observed.