Förenklad reologimätare för betong : Mätning av PWM-signal / Simplified rheology meter for concrete

Pirkhdrie, Awara

January 2022

Cement has a large climate footprint through the release of carbon dioxide in the manufacturing process. Rheometers, that measure the flow resistance in concrete, are available on the market today. They have very high accuracy but are also complex and expensive. There is a need for a simpler and cheaper measurement tool that complements existing, manual methods. Against this background, two research questions were created: • RQ1: How can a measuring paddle be rotated and the flow resistance be measured in a cost-effective way? • RQ2 - How can one build a machine without too expensive components with results similar to commercial rheometers? A prototype for measuring device, measuring electrical power, was designed and built based on the above research questions. The prototype was evaluated with two different liquids with known viscosity and two different concrete mixtures with different types of sand. The result is positive and shows a relation between flow resistance and used electrical power. However, additional tests and also calibration are needed.

PWM-signal

motor-styrning

mätning av effekt

Computer Sciences

Datavetenskap (datalogi)

Design and Analysis of Switching Circuits for Energy Harvesting in Piezostrutures

Kim, Woon Kyung

21 August 2012

This study deals with a general method for the analysis of a semi-active control technique for a fast-shunt switching system. The benefit of the semi-active system is the reduction in power consumption, which is a significant disadvantage of a fully active system compared with a passive system. A semi-active system under consideration is a semi-actively shunted piezoelectric system, which converts the strain energy into electrical energy through strong electromechanical coupling achieved though the piezoelectric phenomenon. Our proposed semi-active approach combines a PZT-based energy harvesting with a fast switching system driven by a Pulse-Width Modulated (PWM) signal. The fast switching system enables continuous adaptation of vibration energy control/harvesting by varying the PWM duty cycle. This contrasts with a conventional capacitance switching system that can only change the capacitance at discrete values. The analysis of the current piezoelectric system combined with a fast-switching system poses a considerable challenge as it contains both continuous and discrete characteristics. The study proposes an enhanced averaging method for analyzing the piecewise linear system. The simulation of the averaged system is much faster than that of the time-varying system. Moreover, the analysis derives error bounds that characterize convergence in the time domain of the averaged system to the original system. The dissertation begins with the derivation of the equations governing the physics of a piezostructure combined with an electrical switching shunt network. The results of the averaging analysis and numerical simulation are presented in order to provide a basis for estimating the structural responses that range between open- and short-circuit conditions which constitutes two limiting conditions. An experimental study demonstrates that the capacitive shunt bimorph piezostructure coupled with a single switch can be adjusted continuously by varying the PWM duty cycle. And the behavior of such hybrid system can be well predicted by the averaging analysis. / Ph. D.

PWM signal

averaging method

switching circuit systems

energy harvesting

piezoelectric material

hybrid continuous-discrete system