Smart sensors for utility assets

Moghe, Rohit

15 May 2012

This dissertation presents the concept of a small, low-cost, self-powered smart wireless sensor that can be used for monitoring current, temperature and voltage on a variety of utility assets. Novel energy harvesting approaches are proposed that enable the sensor to operate without batteries and to have an expected life of 20-30 years. The sensor measures current flowing in an asset using an open ferromagnetic core, unlike a CT which uses a closed core, which makes the proposed sensor small in size, and low-cost. Further, it allows the sensor to operate in conjunction with different assets having different geometries, such as bus-bars, cables, disconnect switches, overhead conductors, transformers, and shunt capacitors, and function even when kept in the vicinity of an asset. Two novel current sensing algorithms have been developed that help the sensor to autonomously calibrate and make the sensor immune from far-fields and cross-talk. The current sensing algorithms have been implemented and tested in the lab at up to 1000 A. This research also presents a novel self-calibrating low-cost voltage sensing technique. The major purpose of voltage sensing is detection of sags, swells and loss-ofpower on the asset; therefore, the constraint on error in measurement is relaxed. The technique has been tested through several simulation studies. A voltage sensor prototype has been developed and tested on a high voltage bus at up to 35 kV. Finally, a study of sensor operation under faults, such as lightning strikes, and large short circuit currents has been presented. These studies are conducted using simulations and actual experiments. Based on the results of the experiments, a robust protection circuit for the sensor is proposed. Issues related to corona and external electrical noise on the communication network are also discussed and experimentally tested. Further, optimal design of the energy harvester and a novel design of package for the sensor that prevents the circuitry from external electrical noise without attenuation of power signals for the energy harvester are also proposed.

Current sensing

Voltage sensing

Wireless sensor networks

Optimal design

Energy harvesting

Electric utilities

Maintenance

Detectors

Study and Implementation of An Active Power Factor Correction AC/DC Converter With No Sensing of Input Voltage

Chang, Chia-Jung

20 October 2006

The traditional AC/DC rectifier usually results in low power factor and serious harmonic distortion and it will bring about the serious pollution to power system. This thesis proposes boost power factor correction technique to solve these problems. First, we aim at power factor correction circuit which need input voltage sensing, to study its operating principle and design consideration, then design applicable voltage compensator by the frequency analysis and perform the simulation and implementation using the developed criterion. In order to prevent the shortcoming that power factor correction circuits with input voltage sensing and complexity is raised for a multiplier must be added to controller, we develop the power factor correction circuit without input voltage sensing. We perform the operating principle and control function by simulation, develop hardware scheme by analog components and place load variation to measure power factor and total harmonic distortion. According to experimental results and simulation, we confirm the new power factor correction circuit. When the full load is placed, the power factor can achieve 0.99 and the total harmonic distortion is lower than 8%.

without input voltage sensing

boost

AC/DC converter

active power factor correction

Étude structurale et fonctionnelle du canal potassium dépendant du voltage KvAP

Faure, Elise

09 1900

Les canaux ioniques dépendants du voltage sont responsables de l'initiation et de la propagation des potentiels d'action dans les cellules excitables. De nombreuses maladies héréditaires (channelopathies) sont associées à un contrôle défectueux du voltage par ces canaux (arythmies, épilepsie, etc.). L’établissement de la relation structure-fonction exacte de ces canaux est donc crucial pour le développement de nouveaux agents thérapeutiques spécifiques. Dans ce contexte, le canal procaryote dépendant du voltage et sélectif au potassium KvAP a servi de modèle d’étude afin d’approfondir i) le processus du couplage électromécanique, ii) l’influence des lipides sur l’activité voltage-dépendante et iii) l’inactivation de type closed-state. Afin de pallier à l’absence de données structurales dynamiques du côté cytosolique ainsi que de structure cristalline dans l’état fermé, nous avons mesuré le mouvement du linker S4-S5 durant le gating par spectroscopie de fluorescence (LRET). Pour ce faire, nous avons utilisé une technique novatrice du contrôle de l’état conformationnel du canal en utilisant les lipides (phospholipides et non phospholipides) au lieu du voltage. Un modèle dans l’état fermé a ainsi été produit et a démontré qu’un mouvement latéral modeste de 4 Å du linker S4-S5 est suffisant pour mener à la fermeture du pore de conduction. Les interactions lipides - canaux jouent un rôle déterminant dans la régulation de la fonction des canaux ioniques mais ne sont pas encore bien caractérisées. Nous avons donc également étudié l’influence de différents lipides sur l’activation voltage - dépendante de KvAP et mis en évidence deux sites distincts d’interactions menant à des effets différents : au niveau du senseur de voltage, menant au déplacement de la courbe conductance-voltage, et du côté intracellulaire, influençant le degré de la pente de cette même courbe. Nous avons également démontré que l’échange de lipides autour de KvAP est extrêmement limité et affiche une dépendance à l’état conformationnel du canal, ne se produisant que dans l’état ouvert. KvAP possède une inactivation lente particulière, accessible depuis l'état ouvert. Nous avons étudié les effets de la composition lipidique et de la température sur l'entrée dans l'état inactivé et le temps de récupération. Nous avons également utilisé la spectroscopie de fluorescence (quenching) en voltage imposé afin d'élucider les bases moléculaires de l’inactivation de type closed-state. Nous avons identifié une position à la base de l’hélice S4 qui semble impliquée à la fois dans le mécanisme responsable de ce type d'inactivation et dans la récupération particulièrement lente qui est typique du canal KvAP. / Voltage-gated ion channels are responsible for the initiation and propagation of action potentials in excitable cells. Several hereditary diseases (channelopathies) are associated with a defective voltage control by these channels, leading to arrhythmias, epilepsy, etc. Hence, establishing the exact structure/function relation for ion channels is crucial for the development of new specific therapeutic agents. Here, the bacterial voltage-gated potassium channel KvAP served as a model to study i) electromechanical coupling, ii) influence of lipids on the voltage dependent activity and iii) closed-state inactivation. To overcome the lack of structural information on the cytosolic side and of crystal structure in the closed state, we determined the S4-S5 linker movement during gating using fluorescence spectroscopy (LRET). We were able to control the conformational state of the channels by using lipids (phospholipids and non phospholipids) instead of voltage clamp. Based on these experimental constraints, a model in the closed state was produced, showing that a small 4Å radial displacement of the S4-S5 linker is sufficient to close the conduction pore. Interactions between lipids and membrane proteins play an important role in the regulation of ion channels activity but are not well characterized. We studied the influence of different lipids on KvAP voltage-dependent activation and showed two distinct effects related to different interactions sites: one bound to the voltage sensor, leading to a shift of the conductance-voltage curve, and another at the intracellular side near the pore region, affecting the steepness of this curve. We also showed that the exchange of lipids is very limited around KvAP and seems to be state dependent, occuring only when the channels are kept in the open state. KvAP has a slow inactivation atypical, accessible from the open state. We studied the effects of lipid composition and temperature on entry into inactivation and recovery. We also used voltage-clamp fluorometry in bilayers to investigate closed-state inactivation molecular basis. We identified a position at the bottom of the S4 helix that seems involved in the mechanism for slow inactivation and the extremely slow recovery from inactivation typically displayed by KvAP.

canaux ioniques

Kv

KvAP

LRET

fluorescence en voltage imposé

domaine senseur de voltage

DOTAP

couplage électromécanique

ion channel

voltage-clamp fluorometry

electromechanical coupling

voltage sensing domain

inactivation

lipides

lipids

Autonomní záložní zdroj 230V/50Hz/300VA s bateriovým napájením 12V / Back-up power supply 230V/50Hz/300VA with a battery supply 12V

Snítilý, David

January 2008

The aim of this project is to describe, design and create a converter from 12V DC to 230 VRMS. The power of this device is about 500W. The device consists of two main converters. The first one is step-up DC/DC converter and the other is DC/AC inverter. Step-up converter is designed as a resonant converter. It is useful for pushing down losses in semiconductors and inceasing efficiency. The inverter is changing DC voltage from the first converter to AC voltage. Control of this device is realized with DSP Motorola. This device should be used mainly for supply common devices up to 500W. Main usage is planed in a car or to another place where is not posible to connect some device to plug.

Digitálně řízený vícekvadrantový zdroj / Digitally controlled multi-quadrant power supply

Chytil, Jiří

January 2013

This thesis deal with design of multi-quadrant power supply in linear and switching mode. In the case of the switching mode energy recuparation is also considered as well as optimalization of change of load response over time. Power supplies are designed as general purpose laboratory and process power supplies. Power supplies are designed so that they can be connected via galvanic insulated USB interface with a PC