28 research outputs found
A conceptual design of a MeV-energy ion microprobe with an immersion probe-forming system
The authors propose a new design for a MeV-energy ion microprobe based on the immersion probe-forming system that employs the accelerating tube at an early stage of beam focusing. The final probing beam formation on the target is provided by a separated Russian quadruplet of magnetic quadrupole lenses. As follows from the calculations, the length of this setup along the beamline (from the ion source to the target) does not exceed 4 m, but the resolution may be higher than that of most operating facilities of conventional design
Design of inorganic polymer composites for electromagnetic radiation absorption using potassium titanates
This paper investigated the synthesis of inorganic polymer composites for electromagnetic radiation
absorption using potassium titanates. The selected polyamide 6 and potassium polytitanate materials contain TiО2,
K2СО3, and KCl obtained by charge sintering. Results showed that modification of polyamide 6 with sintering
products in the form of a fine powder of potassium polytitanate that contains different phases K2O × 2TiO2,
K2O × 4TiO2, and K2O × 6TiO2 which increased their strength properties. With increased potassium titanates (PTT)
synthesis, a gradual transition from di to potassium hexatitanates occurs K2O × 2TiO2 – K2O × 4TiO2 – K2O × 6TiO2.
The optimal content of potassium polytitanate was over 20 % by mass. To fully ensure the reinforcing effect due to
the filling of potassium polytitanate polyamide 6, it is necessary to use whiskers K2O × 6TiO2, which can be
collected by the additional crystallization of the amorphous charge sintering product. By designing experimentalstatistical mathematical models in equal regressions, mathematical optimization of inorganic polymer composites for
electromagnetic radiation absorption using PTT was carried out
Investigation of a turbogenerator based on the vortex expansion machine with a peripheral side channel
The creation of energy-saving turbogenerators is an essential component of the development of small
energy systems. The gradual growth of interest in distributed electricity generation necessitates the constant
improvement of these units. Moreover, they implement a more environmentally friendly generation method than when
using microturbine units that use fuel to carry out the work process. Nowadays, turbogenerators are created based on
different types of expansion machines, which have their advantages and disadvantages, given in this article. Compared
to competitors, vortex expansion machines have good prospects and the necessary potential to expand their research
and produce turbogenerators. An experimental vortex expansion machine with a peripheral-lateral channel and ability
to change the geometric parameters of its flowing part was created to meet these needs. Experimental studies of the
machine were performed on a special stand with air as a working fluid. As a result of the tests, the data were successfully
obtained and processed. They are presented in the form of tables and graphical dependencies. The nature of the
influence of thermodynamic parameters and geometric parameters of the flow part on the efficiency of the vortex
expansion machine and turbogenerator based on it to further improve and create new turbogenerators is clarified