Energy Recuperation of Positively Charged Ions

“…Figure 1 shows a diagram of the process of vibration anode-abrasive polishing [8]. In the processed channel of the part made of non-magnetic material 1, fixed in the device through a rubber pipe 4, ring electrode 3, negatively charged, connected through insulator 2, with a workpiece made of M0 copper, an electrolyte of 3% NaNO3 + (3-6)% Fe3C charged magnetic abrasive grains is supplied, which are affected by an oscillating magnetic field with a frequency f using a magnetic tip 6, having alternating magnetic poles, with different magnetic induction, and moving at a speed V in the longitudinal direction.…”

“…This improves the efficiency of the polishing process in the areas of the treated surface. The method also allows controlling the mechanical and electrochemical effects at a voltage of U=3-8 V, on the microroughness of the machined surface, the uniformity and magnitude of the allowance to be removed z [8].…”

Vibration anode-abrasive polishing of channels of small cross section

“…Figure 1 shows a diagram of the process of vibration anode-abrasive polishing [8]. In the processed channel of the part made of non-magnetic material 1, fixed in the device through a rubber pipe 4, ring electrode 3, negatively charged, connected through insulator 2, with a workpiece made of M0 copper, an electrolyte of 3% NaNO3 + (3-6)% Fe3C charged magnetic abrasive grains is supplied, which are affected by an oscillating magnetic field with a frequency f using a magnetic tip 6, having alternating magnetic poles, with different magnetic induction, and moving at a speed V in the longitudinal direction.…”

“…This improves the efficiency of the polishing process in the areas of the treated surface. The method also allows controlling the mechanical and electrochemical effects at a voltage of U=3-8 V, on the microroughness of the machined surface, the uniformity and magnitude of the allowance to be removed z [8].…”

Vibration anode-abrasive polishing of channels of small cross section

“…Работа космических аппаратов (КА), предназначенных для межпланетных перелетов или эксплуатируемых на высоких орбитах, сопряжена с необходимостью защиты от радиации, наряду с аппаратурой, также и солнечных элементов (СЭ) в солнечных батареях (СБ) [1][2][3][4][5]. Известны методы защиты, основанные на закреплении на поверхности СЭ специальных стекол, в том числе проводящих [6], а также на выполнении СБ КА с концентраторами солнечного излучения (КСИ), защита которых от радиации обеспечивается экранированием СЭ телом концентрирующей системы [7,8].…”

Концентраторные Солнечные Модули С Преобразователями На Основе Гранулированного Кремния