Optimizing Linear Generator Design’S Parameters For Output Power Using Mix Numerical And Analytical Technique

2020 ◽  
Author(s):  
Do Huy Diep ◽  
Nguyen Van Duc ◽  
Nguyen Xuan Quynh ◽  
Dang The Ba
Keyword(s):  
Output Power ◽  
Analytical Technique ◽  
Linear Generator

scholarly journals A Free-Piston Linear Generator Control Strategy for Improving Output Power

Energies ◽  
2018 ◽  
Vol 11 (1) ◽  
pp. 135 ◽  
Author(s):  
Chi Zhang ◽  
Feixue Chen ◽  
Long Li ◽  
Zhaoping Xu ◽  
Liang Liu ◽  
...  
Keyword(s):  
Output Power ◽  
Control Strategy ◽  
Free Piston ◽  
Linear Generator

scholarly journals Control of the Output Power and Power Factor in a Converter of a Linear Generator for the Maglev System

2004 ◽  
Vol 124 (10) ◽  
pp. 1029-1035 ◽  
Author(s):  
Takayuki Kashiwagi ◽  
Toshiaki Murai ◽  
Takamitsu Yamamoto ◽  
Hitoshi Hasegawa ◽  
Takashi Sano ◽  
...  
Keyword(s):  
Output Power ◽  
Power Factor ◽  
Linear Generator ◽  
Maglev System

Dynamics of a Linear Generator for Wave Energy Conversion

2004 ◽  
Author(s):  
Mikael Eriksson ◽  
Karin Thorburn ◽  
Hans Bernhoff ◽  
Mats Leijon
Keyword(s):  
Output Power ◽  
Wave Climate ◽  
High Rate ◽  
Theoretical Studies ◽  
Wave Energy Conversion ◽  
Piston Motion ◽  
Damping Force ◽  
Dc Voltage ◽  
Linear Generator ◽  
Flux Change

A concept is presented where the piston of a seabed based linear generator is directly driven by a buoy on the water surface. A spring is connected to the other end of the piston. Thereby the buoy absorbs energy in two ways. A large number of poles are used as an “electromagnetic gearbox” which gives a high rate of flux change in the stator despite the slow piston motion. The damping force is a function of the velocity and the electric output power. In the studied concept the power from the generator is rectified with a diode bridge. The results of theoretical studies of output power and its interaction with the dynamics of the equation of motion are presented. It is shown that the DC voltage can be tuned to optimize the power production for each wave climate.

Trends in Electron Energy Loss Spectroscopy

1977 ◽  
Vol 35 ◽  
pp. 228-229
Author(s):  
C. Colliex ◽  
P. Trebbia
Keyword(s):  
Energy Loss ◽  
Electron Energy ◽  
Electron Energy Loss Spectroscopy ◽  
Materials Science ◽  
Analytical Technique ◽  
Recent Developments ◽  
Quantitative Results ◽  
Electron Microscopes ◽  
Electron Energy Loss ◽  
Primary Electrons

The physical foundations for the use of electron energy loss spectroscopy towards analytical purposes, seem now rather well established and have been extensively discussed through recent publications. In this brief review we intend only to mention most recent developments in this field, which became available to our knowledge. We derive also some lines of discussion to define more clearly the limits of this analytical technique in materials science problems.The spectral information carried in both low ( 0<ΔE<100eV ) and high ( >100eV ) energy regions of the loss spectrum, is capable to provide quantitative results. Spectrometers have therefore been designed to work with all kinds of electron microscopes and to cover large energy ranges for the detection of inelastically scattered electrons (for instance the L-edge of molybdenum at 2500eV has been measured by van Zuylen with primary electrons of 80 kV). It is rather easy to fix a post-specimen magnetic optics on a STEM, but Crewe has recently underlined that great care should be devoted to optimize the collecting power and the energy resolution of the whole system.

Spatially Resolved Photoelectron Spectroscopy: Recent Progress and Future Plans

1990 ◽  
Vol 48 (2) ◽  
pp. 388-389
Author(s):  
A. M. Bradshaw
Keyword(s):  
Photoelectron Spectroscopy ◽  
Chemical Reactivity ◽  
Target Material ◽  
Orbital Energy ◽  
Light Sources ◽  
Analytical Technique ◽  
Hartree Fock ◽  
Spatially Resolved ◽  
Koopmans Theorem ◽  
Surface Analytical Technique

X-ray photoelectron spectroscopy (XPS or ESCA) was not developed by Siegbahn and co-workers as a surface analytical technique, but rather as a general probe of electronic structure and chemical reactivity. The method is based on the phenomenon of photoionisation: The absorption of monochromatic radiation in the target material (free atoms, molecules, solids or liquids) causes electrons to be injected into the vacuum continuum. Pseudo-monochromatic laboratory light sources (e.g. AlKα) have mostly been used hitherto for this excitation; in recent years synchrotron radiation has become increasingly important. A kinetic energy analysis of the so-called photoelectrons gives rise to a spectrum which consists of a series of lines corresponding to each discrete core and valence level of the system. The measured binding energy, EB, given by EB = hv−EK, where EK is the kineticenergy relative to the vacuum level, may be equated with the orbital energy derived from a Hartree-Fock SCF calculation of the system under consideration (Koopmans theorem).

Recent developments in low-voltage SEM of polymers

1993 ◽  
Vol 51 ◽  
pp. 866-867
Author(s):  
S.J. Krause ◽  
W.W. Adams
Keyword(s):  
Low Voltage ◽  
Chromatic Aberration ◽  
Thermal Electron ◽  
Analytical Technique ◽  
Recent Developments ◽  
Beam Currents ◽  
New Generation ◽  
First Time ◽  
Voltage Scanning ◽  
Beam Damage

Over the past decade low voltage scanning electron microscopy (LVSEM) of polymers has evolved from an interesting curiosity to a powerful analytical technique. This development has been driven by improved instrumentation and in particular, reliable field emission gun (FEG) SEMs. The usefulness of LVSEM has also grown because of an improved theoretical and experimental understanding of sample-beam interactions and by advances in sample preparation and operating techniques. This paper will review progress in polymer LVSEM and present recent results and developments in the field.In the early 1980s a new generation of SEMs produced beam currents that were sufficient to allow imaging at low voltages from 5keV to 0.5 keV. Thus, for the first time, it became possible to routinely image uncoated polymers at voltages below their negative charging threshold, the "second crossover", E2 (Fig. 1). LVSEM also improved contrast and reduced beam damage in sputter metal coated polymers. Unfortunately, resolution was limited to a few tenths of a micron due to the low brightness and chromatic aberration of thermal electron emission sources.

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