板料激光弯曲过程的数值模拟

采用MSC.Marc非线性有限元软件,对板料激光弯曲过程进行了数值模拟.试验与数值模拟的相互印证表明:数值模拟的模型正确,计算过程可靠,计算结果可为板料激光弯曲工艺参数的选择提供依据.通过模拟多道次直线照射的过程可知,变形效果受照射路径次序的影响很大,应选择从固定端向自由端方向交替的双向照射路径,以保证板料在宽度方向上变形的均匀.模拟结果可为带筋结构壁板激光弯曲成形提供实用方案.     

The exploration of halley''s comet: An example of international cooperation

During its present appearance, Comet Halley is the focus of an unparalleled global scientific effort of exploration from the ground; from Earth orbit; from Venus orbit; from interplanetary space; and from within the comet itself.

The various activities in space are coordinated by the four space agencies — the European Space Agency (ESA), Intercosmos of the USSR Academy of Sciences, the Japanese Institute of Space and Astronautical Science (ISAS), and the National Aeronautics and Space Administration (NASA) — through the Inter-Agency Consultative Group (IACG). Coordination of the activities of the ground-based observers is provided through the International Halley Watch (IHW). The IHW was established in 1980, the IACG in 1981.

The single goal of both, IHW and IACG is to maximize the overall scientific results of all efforts in the exploration of Comet Halley from the ground and from space. The obvious success of this unique endeavor might serve as example for future cooperative scientific programs.     

板料激光弯曲试验

针对大飞机壁板用的铝合金板料AA6056进行激光弯曲过程的试验研究.试验选用厚度为1.0 mm和2.5 mm的薄板,采用多组不同的工艺参数进行对比分析.采用直径0.1 mm的镍铬-镍硅热电偶作为温度传感器,YOKOGAWA MV200型便携式记录仪测量板料表面的温度;使用MV-1300UM CCD拍摄板料激光弯曲变形的过程,通过自行开发的实时采集软件记录并进行图像处理,最终得到了板料激光弯曲变形过程的实测曲线.试验结果为该过程的数值模拟提供了更为精确的验证依据,为深入研究板料激光弯曲过程奠定了试验基础.     

Mechanosensing and signal transduction in tendrils.

The perception of thigmic stimuli is a widespread phenomenon among plants with decisive meaning for the ability to survive. Beside a general sensitivity for mechanical stimuli many plants have evolved specialized organs with highly developed mechanisms to perceive and transduce the applied forces. Tendrils of Bryonia dioica and Pisum sativum have been chosen to study the effects of mechanical stimulation on plant physiology. Both types of tendrils, although exhibiting different morphology, respond to such a stimulus with a rapid coiling response to the dorsal side of the organ within minutes. The actual perception of the stimulus is most likely coupled to the cytoskeleton serving as the mediator between the physical stimulus and the biochemical response. Drugs affecting the status of the cytoskeleton were used to get more insights into this specific process. The results indicate that microtubuli (MT) play the most important role in the perception of thigmic stimuli in tendrils. Colchicine-mediated disruption of MT lead to total inhibition of the response to the thigmic stimulus in tendrils of Pisum and to a reduced response in Bryonia. Alamethicin, an ionophore that can mimic action potentials in membranes, was able to bypass this inhibition suggesting a direct involvement of MT in depolarization of the membranes. Auxin, however, which is also supposed to be involved in the regulation of the coiling response, failed to bypass colchicine-dependent inhibition. Vinblastine, another microtubule depolimerizing agent, did induce tendril coiling in Pisum without further stimulation. Application of taxol and other MT-stabilizing drugs as well as disruption of the actin network did not affect the coiling response of tendrils. In Pisum indole-3-acetic acid (IAA) is induced after mechanical stimulation during the coiling response, but not jasmonic acid. A further consequence of mechanical stimulation is the induction of an oxidative burst and an increase in soluble sugar. A model is presented integrating these results and might serve as a common basis for the understanding of the perception of mechanical stimuli.