Оптимизация схемы организации воздухообмена свинцово-плавильного производства : магистерская диссертация / Optimization of the organization of air exchange of lead-smelting production

Козырин, К. В., Kozyrin, K. V.

January 2019

The focus of the research is on the problem of ventilation on lead-melting production. The main sources of lead emissions in the refining shop are determined. The primary conditions for convective jet saving for its further removal and cleaning are defined. With COMSOL Multiphysics simulation platform the shop model is created for fluid flow analysis. The results of numerical calculation of air exchange scheme and its comparing with experimental data are shown. An own scheme of air distribution in refining shop is offered. The scheme takes into account all the requirements for saving of convective circulation, initiated by convective jets from melting pots. / Диссертация посвящена проблеме вентиляции свинцово-плавильного производства. Определены основные источники выделения аэрозолей свинца в рафинировочном цехе. Определены основные условия, и параметры сохранения конвективной струи для её дальнейшего удаления и очищения. В программе COMSOL Multiphysics® построена модель цеха для моделирования процессов течения воздуха. Представлены результаты численного моделирования организации схемы воздухообмена и их сравнение с физическим опытом. Предложена собственная схема распределения воздуха в рафинировочном цехе, в которой учитываются все требования, для сохранения естественной циркуляции, инициированной конвективными струями от котлов.

MASTER'S THESIS

VENTILATION OF THE REFINING WORKSHOP

AIR EXCHANGE SCHEME

NUMERICAL SIMULATION

HYDRODYNAMICS

COMSOL MULTIPHYSICS SOFTWARE

СХЕМА ВОЗДУХООБМЕНА

ГИДРОДИНАМИКА

ПК COMSOL MULTIPHYSICS

Multistability in microbeams: Numerical simulations and experiments in capacitive switches and resonant atomic force microscopy systems

Devin M Kalafut (11013732)

23 July 2021

Microelectromechanical systems (MEMS) depend on mechanical deformation to sense their environment, enhance electrical circuitry, or store data. Nonlinear forces arising from multiphysics phenomena at the micro- and nanoscale -- van der Waals forces, electrostatic fields, dielectric charging, capillary forces, surface roughness, asperity interactions -- lead to challenging problems for analysis, simulation, and measurement of the deforming device elements. Herein, a foundation for the study of mechanical deformation is provided through computational and experimental studies of MEMS microcantilever capacitive switches. Numerical techniques are built to capture deformation equilibria expediently. A compact analytical model is developed from principle multiphysics governing operation. Experimental measurements support the phenomena predicted by the analytical model, and finite element method (FEM) simulations confirm device-specific performance. Altogether, the static multistability and quasistatic performance of the electrostatically-actuated switches are confirmed across analysis, simulation, and experimentation. <p><br></p> <p>The nonlinear multiphysics forces present in the devices are critical to the switching behavior exploited for novel applications, but are also a culprit in a common failure mode when the attractive forces overcome the restorative and repulsive forces to result in two elements sticking together. Quasistatic operation is functional for switching between multistable states during normal conditions, but is insufficient under such stiction-failure. Exploration of dynamic methods for stiction release is often the only option for many system configurations. But how and when is release achieved? To investigate the fundamental mechanism of dynamic release, an atomic force microscopy (AFM) system -- a microcantilever with a motion-controlled base and a single-asperity probe tip, measured and actuated via lasers -- is configured to replicate elements of a stiction-failed MEMS device. Through this surrogate, observable dynamic signatures of microcantilever deflection indicate the onset of detachment between the probe and a sample.</p>

Mechanical Engineering

Microelectromechanical Systems (MEMS)

Engineering Instrumentation

Theoretical and Applied Mechanics

MEMS

AFM

COMSOL Multiphysics software

MATLAB

AUTO

Bifurcation

Boundary value problem

Numerical continuation

Multiphysics modeling

Multistability

Uncertainty quantification

Beams

Switch

Contact resonance AFM

Detachment

Nonlinear dynamics

Equilibria

Nonlinear normal modes

Microcantilever