Study of Energy Neutrality in Kochi Metro Rail, India

Paul, Jeena

January 2021

Now a days, the society thinks about more sustainable and clean energy sources. Most of the countries in the world relay on non-renewable energy sources for the generation of electricity. This results in the scarcity of fossil fuels in future and also increases the production of carbon emissions. This thesis considers a metro system named Kochi Metro which is a rapid transit system serving in the city of Kochi in Kerala, India which uses renewable sources, mainly solar, for giving power to the Metro.In this thesis work, trying to analyze the measures adopted by Kochi Metro Rail project in potential reductions of energy consumption and energy generation both contributing to energy efficiency.With the help of Matlab, different levels of installed PV power are used to find out the possible self-usage, self-sufficiency, and energy neutrality of the system.

Solar PV panels

Traction Power

Auxiliary Power

Regenerative Braking System

Energy Neutrality

Engineering and Technology

Teknik och teknologier

Modeling, simulation and experimental verification of an electric bicycle with regenerative braking

Kalolia, Maulik Rajendrabhai

January 2012

No description available.

Mechanical Engineering

mechatronics modeling

electric bicycle

regenerative braking

bond graph modeling

pid controller

Lightweight friction brakes for a road vehicle with regenerative braking. Design analysis and experimental investigation of the potential for mass reduction of friction brakes on a passenger car with regenerative braking.

Sarip, S. Bin

January 2011

One of the benefits of electric vehicles (EVs) and hybrid vehicles (HVs) is their potential to recuperate braking energy. Regenerative braking (RB) will minimize duty levels on the brakes, giving advantages including extended brake rotor and friction material life and, more significantly, reduced brake mass and minimised brake pad wear. In this thesis, a mathematical analysis (MATLAB) has been used to analyse the accessibility of regenerative braking energy during a single-stop braking event. The results have indicated that a friction brake could be downsized while maintaining the same functional requirements of the vehicle braking in the standard brakes, including thermomechanical performance (heat transfer coefficient estimation, temperature distribution, cooling and stress deformation). This would allow lighter brakes to be designed and fitted with confidence in a normal passenger car alongside a hybrid electric drive. An approach has been established and a lightweight brake disc design analysed FEA and experimentally verified is presented in this research. Thermal performance was a key factor which was studied using the 3D model in FEA simulations. Ultimately, a design approach for lightweight brake discs suitable for use in any car-sized hybrid vehicle has been developed and tested. The results from experiments on a prototype lightweight brake disc were shown to illustrate the effects of RBS/friction combination in terms of weight reduction. The design requirement, including reducing the thickness, would affect the temperature distribution and increase stress at the critical area. Based on the relationship obtained between rotor weight, thickness and each performance requirement, criteria have been established for designing lightweight brake discs in a vehicle with regenerative braking. / Ministry of Higher Education of Malaysia

Brakes

Friction

Regenerative braking

Automotive

Modelling

Thermal

Finite element analysis

Lightweight

Hybrid electric drive

Ready, set, regenerate! : A design study about affecting driver behaviours through gamification elements. / Ready, set, regenerate! : A design study about affecting driver behaviours through gamification elements.

Qvist, Albin, Johansson Subiabre, Philip

January 2023

The automotive industry plays a significant role in global CO2 emissions. A transition towards electric vehicles is part of the solution to lower CO2 emissions. While electric vehicles are beneficial from an environmental standpoint, it generates new challenges and technology for the driver to adapt to, emphasising the importance of human interaction. A possible solution to affect drivers to adopt new behaviours is using Gamification inIn-vehicle Information Systems. This study implies that drivers do not fully see the potential of regenerative braking to extend the vehicle's range while contributing to safer and more predictable driving. Thus, this thesis explores the implementation of gamification in a vehicle context by using a prototype in a vehicle simulator environment to observe whether it affects driver behaviours to increase regenerative braking usage. This study uses a design study method with a qualitative research approach resulting in a high-fidelity prototype developed through an iterative design process. The prototype mechanics originates from the M-PM-O framework, found through an in-depth literature study. The mechanics are designed into gamification elements using established design principles for In-vehicleInformation Systems. Further, the prototype was evaluated using Volvo Cars vehicle simulators. The results demonstrated that gamification in a vehicle context is possible and that the prototype affected driver behaviours to increase regenerative braking usage. Through the analysis and discussion, four design guidelines emerged for the design of gamification elements in IVIS. However, the study also raises questions regarding the general feasibility of incorporation. Overall, this study opens for further studies regarding gamification's safety and long-term effects in a vehicle context. / Fordonsindustrin spelar en betydande roll i de globala CO2 utsläppen, ochen övergång till elektriska fordon har identifierats som en del av lösningenför att minska utsläppen. Även om elektriska fordon är fördelaktiga ur ettmiljöperspektiv, ställer de nya krav på förare och tekniken i fordon, vilketökar vikten av mänsklig interaktion. För att uppmuntra förare att anta nyabeteenden mer hållbara körbeetenden har spelifiering identifierats som enmöjlig lösning i bilens informationssystem. Studien antyder att bilförare inteser potentialen i regenerativ bromsning för att öka räckvidden i bilensamtidigt som den främjar säkrare och mer förutsägbart körande. Syftet meddenna studien är att utforska spelifiering element i bilensinformationssystem genom att utveckla och testa en prototyp i enbilsimulator för att undersöka om den kan stödja förarbeteenden att ökaregenerativ bromsanvändning. Studien använder sig utav en designstudiemetod med en kvalitativ forskningsansats som resulterar i en högtdetaljerad prototyp utvecklad genom en iterativ designprocess. I endjupgående litteraturstudie identifieras tre spelifiering element som användsi studien. Spelifiering elementen designas med hjälp av etableradedesignprinciper för bilinformationssystem. Vidare utvärderades prototypen i Volvo Cars simulatormiljö. Resultatenindikerade att spelifiering i bilens informationssystem kan stödjaförarbeteenden att öka regenerativ bromsanvändning. Genom analys ochdiskussion uppdagades tre design riktlinjer för designen av spelifieringelement i bilens informationssystem. Överlag, öppnar studien för vidarestudier gällande spelifierings säkerhet och långtidseffekter i en bilkontext.

Gamification

In-Vehicle Information Systems

IVIS

Regenerative braking

Simulator

Human Computer Interaction

Development and Validation of a Control Strategy for a Parallel Hybrid (Diesel-Electric) Powertrain

Mathews, Jimmy C

09 December 2006

The rise in overall powertrain complexity and the stringent performance requirements of a hybrid electric vehicle (HEV) have elevated the role of its powertrain control strategy to considerable importance. Iterative modeling and simulation form an integral part of the control strategy design process and industry engineers rely on proprietary ?legacy? models to rapidly develop and implement control strategies. However, others must initiate new algorithms and models in order to develop production-capable control systems. This thesis demonstrates the development and validation of a charge-sustaining control algorithm for a through-the-road (TTR) parallel hybrid (diesel-electric) powertrain. Some unique approaches used in powertrain-level control of other commercial and prototype vehicles have been adopted to incrementally develop this control strategy. The real-time performance of the control strategy has been analyzed through on-road and chassis dynamometer tests over several standard drive cycles. Substantial quantitative improvements in the overall HEV performance over the stock configuration, including better acceleration and fuel-economy have been achieved.

SOC Correction

Regenerative Braking

Control Strategy

Through-The-Road Parallel

Hybrid Electric Vehicle

Drive Cycles

Control and Drive Quality Refinement of a Parallel-Series Plug-in Hybrid Electric Vehicle

Yard, Matthew Alexander

January 2014

No description available.

Mechanical Engineering

Hybrid Vehicles

Drive Quality

AVL DRIVE

Regenerative Braking

Driveability

Tip-in

Controls

Modeling and Analysis of Crankshaft Energy Harvesting for Vehicle Fuel Economy Improvement

Grimm, Benjamin Mihuta

19 July 2012

No description available.

Mechanical Engineering

regenerative braking

ONE-PEDAL-DRIVE AND REGENERATIVE BRAKING STRATEGY: STUDY ON VEHICLE DRIVABILITY AND ENERGY EFFICIENCY

Goretti Barroso, Daniel

January 2024

The shift towards electric transportation on a global scale is being primarily driven by regulatory requirements and market demand. The impact of the COVID-19 pandemic on air pollution, energy demand, and CO2 emissions has further accelerated this transition. This transformation necessitates the development of efficient electric propulsion systems, particularly for commercial vehicles. These systems not only have a positive environmental impact but also offer significant financial advantages to fleet owners due to lower overall costs. One of the major challenges in this transition is the design and calibration of regenerative braking strategies, especially for commercial vehicles that exhibit significant variations in weight. This weight difference between curb and gross vehicle weight is a common scenario in the commercial vehicle sector. This thesis introduces the Adaptive One-Pedal Drive (A-OPD) strategy, which is specifically tailored for electric commercial vehicles with varying weight profiles and lacking advanced drive-by-wire braking systems. The thesis focuses on the development and accurate assessment of a model-centric approach for electrified propulsion systems. This approach establishes a strong correlation between the model and physical data, demonstrating its reliability in estimating critical variables such as battery state-of-charge, battery terminal voltage, system high-voltage DC, and wheel torque, even under diverse driving conditions. This model-centric approach serves as a valuable tool for optimizing design and conducting tradeoff analyses, enabling efficient evaluation of energy efficiency and drivability. Selecting the most suitable electrified propulsion system architecture is a crucial decision. The thesis categorizes electrified propulsion system architectures based on their impact on vehicle performance, energy consumption, and total cost of ownership. This selection process involves a multidisciplinary approach that takes into account both technical and business requirements. The central research focus of this thesis centers on regenerative braking systems. It compares series and parallel configurations, traditional one-pedal-drive (OPD), and introduces an innovative Adaptive One-Pedal Drive (A-OPD). The A-OPD relies on vehicle running mass identification using the Recursive Least Square Filter (RLS) and weight classification. This A-OPD strategy significantly enhances energy efficiency in urban traffic scenarios, even when vehicles are partially loaded. It outperforms parallel regenerative braking systems by up to 50% while maintaining performance levels similar to the series regenerative braking strategy. This innovation represents a significant leap in energy efficiency for electric commercial vehicles without the need for complex electronic braking systems. In summary, this thesis advances our understanding of optimizing the performance of electric commercial vehicles. The A-OPD strategy proves to be a practical and valuable tool for enhancing energy efficiency, particularly in dense urban traffic, and it outperforms parallel regenerative braking systems. Utilizing model-in-the-loop and driver-in-the-loop simulations, this thesis offers a comprehensive framework for designing efficient electrified propulsion system architectures. / Thesis / Doctor of Philosophy (PhD)

Electric Vehicle

Regenerative Braking

One Pedal Drive

Adaptative One Pedal Drive

Propulsion System

System Engineering

Projeto e dimensionamento de um sistema de tração para veículos elétricos

Wiltuschnig, Igor Pasa

January 2016

O presente trabalho tem por objetivo propor uma metodologia para o dimensionamento da potência tracionária em função do percurso percorrido por veículos elétricos, assim como realizar o projeto básico de uma máquina elétrica para suprir a carga tracionária exigida. Os cálculos foram realizados através de um algoritmo onde o usuário insere as variáveis mecânicas do veículo e recebe a potência e conjugado necessários, e o projeto elementar da máquina que deverá equipar o veículo. Realizou-se um estudo de caso a partir de uma scooter elétrica para validar os resultados, foi projetada uma máquina brushless dc com fluxo radial e rotor externo. Os resultados experimentais atenderam as espectativas de conjugado de 46 Nm, o máximo conjugado estático atingiu 48 Nm e a rotação a vazio obteve valor de 613 rpm à tensão nominal. Os ensaios de frenagem regenerativa com supercapacitores apresentaram resultados promissores com 50% da energia mecânica recebida durante a frenagem entregue na partida do veículo. / The present study aims to propose a methodology for the design of power traction depending on the distance traveled by electrical vehicles, and perform the basic design of an electrical machine to supply the traction load required. The calculations will be performed through an algorithm where the user enters the mechanical variables of the vehicle and receives the power and torque required and the basic machine design that should equip the vehicle. A case study was conducted for an electric scooter considering the designed dc brushless machine with radial flow and external rotor in order to validate the results. The experimental results met the target of 46 Nm of torque, the maximum static torque 48 Nm was reached, and the no-load rotation obtained was 613 rpm at nominal voltage. Regenerative braking tests with super capacitors showed a promising result: 50% of the received mechanical energy during braking was delivered to the vehicle starting.

Eficiência energética

Máquinas elétricas

Veículos elétricos

Electric vehicles

Automotive traction

Electrical machines

Radial flow

Regenerative braking

Energy efficiency

Projeto e dimensionamento de um sistema de tração para veículos elétricos

Wiltuschnig, Igor Pasa

January 2016

O presente trabalho tem por objetivo propor uma metodologia para o dimensionamento da potência tracionária em função do percurso percorrido por veículos elétricos, assim como realizar o projeto básico de uma máquina elétrica para suprir a carga tracionária exigida. Os cálculos foram realizados através de um algoritmo onde o usuário insere as variáveis mecânicas do veículo e recebe a potência e conjugado necessários, e o projeto elementar da máquina que deverá equipar o veículo. Realizou-se um estudo de caso a partir de uma scooter elétrica para validar os resultados, foi projetada uma máquina brushless dc com fluxo radial e rotor externo. Os resultados experimentais atenderam as espectativas de conjugado de 46 Nm, o máximo conjugado estático atingiu 48 Nm e a rotação a vazio obteve valor de 613 rpm à tensão nominal. Os ensaios de frenagem regenerativa com supercapacitores apresentaram resultados promissores com 50% da energia mecânica recebida durante a frenagem entregue na partida do veículo. / The present study aims to propose a methodology for the design of power traction depending on the distance traveled by electrical vehicles, and perform the basic design of an electrical machine to supply the traction load required. The calculations will be performed through an algorithm where the user enters the mechanical variables of the vehicle and receives the power and torque required and the basic machine design that should equip the vehicle. A case study was conducted for an electric scooter considering the designed dc brushless machine with radial flow and external rotor in order to validate the results. The experimental results met the target of 46 Nm of torque, the maximum static torque 48 Nm was reached, and the no-load rotation obtained was 613 rpm at nominal voltage. Regenerative braking tests with super capacitors showed a promising result: 50% of the received mechanical energy during braking was delivered to the vehicle starting.

Eficiência energética

Máquinas elétricas

Veículos elétricos

Electric vehicles

Automotive traction

Electrical machines

Radial flow

Regenerative braking

Energy efficiency