Overview

Electrification is the process of powering by electricity, is usually associated with changing over from another power source, and has been regarded as "the greatest engineering achievement of the 20th Century". This module is intended to provide module participants with the new knowledge and competency in modern electrification techniques and applications in built environment and land transportation. Real life applied research projects will be demonstrated to give students first-hand information on electrification technologies. The contents of this module are delivered in three focused areas

  • Modern Electrification Technologies
    Electrification is currently spearheaded by advanced new technologies in both AC and DC power systems which allowed greater resilience, flexibility and safety while meeting new forms of electric demand. Game-changing technologies include the advent of energy storage systems and smart power devices.

  • Advanced Electrification for Land Transportation
    To reduce carbon footprint and pollution in the cities, the growth of electrified urban rail systems has been increasing tremendously in recent years. Advance railway electric power systems and electric propulsion are essential to the sustained growth and operation of urban railways. There is also very strong interest in various forms of electric vehicles and their charging infrastructure and alternative fuel supply.

  • Advanced Electrification for Built Environment
    Distributed energy resources such as solar photovoltaic systems, tri-generation and energy storage systems are increasingly incorporated into urban electrification. There have also been many efforts made in achieving higher energy efficiency and demand management in urban electrification through advanced energy optimisation techniques. Data-driven solutions are increasingly value-adding to traditional control strategies

Teaching Team

What You’ll Learn

Fundamentals of Electric Railway Transportation
  • An overview of railway electrification and traction power supply systems
  • Technical and design aspects of railway electrification.
  • Project engineering a major electrification project.
  • Rails and propulsion mechanics.
  • Overview of permanent way systems in the context of Singapore.

Electrical Railway Traction and Railway Electrical Power Supply
  • AC/DC traction motors and their applications in railway electrification; Traction system control; Traction converters/inverters.
  • Different types of DC/AC railway electrical power supply systems.
  • Contact lines and current collectors; protection and feed systems; Stray current
  • Design considerations for DC railway systems.
  • Demonstration of applied research projects in railway electrification.
  • An invited industry lecture around the theme of transportation electrification with contents varying from year to year.
  • Software-based hands-on group design projects for AC and DC railway electrification systems.

Distributed Energy Resources in the Built Environment
  • Distributed generation (DGs) including Micro-turbine, Combined cooling, heating and power generation (CCHP), Rooftop PV, Fuel cell, Solar thermal, Bioenergy; Integration of DGs and challenges
  • Energy storage technologies including electrochemical, chemical, electrical, mechanical and thermal, demonstration; Demonstration of the instructor’s applied research on energy storage modelling (model based and data-driven) and machine-learning based online monitoring
  • Applications of energy storage systems including load levelling, microgrid operation, demand response and others; Demonstration of the instructor’s applied research on planning and operation optimisation of energy storage systems.

Advances in Electrification in the Built Environment
  • AC/DC urban microgrids; Multi-energy microgrids; Transactive energy and energy internet; Demonstration of the instructor’s applied research on operation and planning of multi-energy systems
  • Data-driven planning and operation of urban microgrids: a real-life applied research project at SIT@NYP “Immersive Energy Monitoring, Forecasting, Planning and Operation with Uncertainty Level Management” led by the instructor
  • Software-based hands-on group projects which target at urban microgrid design optimisation

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Who Should Attend

  • Engineers working in power and energy sector;
  • Railway electrical power supply and propulsion professionals;
  • Electrical and electronic engineering professionals;
  • Researchers and educators in electrical engineering and urban sustainability-related areas


SITizens Learning Credits (SLC) - Eligible Course

SIT Alumni: Before registering for courses, please activate your SITizens Learning Credits via the email sent by SIT Alumni Team, on behalf of SITLEARN Professional Development.

Registration Closed
 

Prerequisites

  • Bachelor degree in Engineering
  • At least one year of relevant working experience
 

Certificate and Assessment

A Certificate of Participation will be issued to participants who
  • Attend 75% of the workshop.
  • Undertake the Continuous Assessment 

A Certificate of Attainment will be issued to participants who:
  • Attend at least 75% of the programme, and
  • Participants who pass the Continuous Assessment and Exam Paper will earn 6 ECTS credits, which are stackable for PGCert or MSc qualifications.
 

Continuing Professional Development

This module is eligible for the following continuing professional development units:

Schedule

Lesson Class Timings
(Wednesdays, 7pm to 10pm)
Lesson 1 9 Sep 2020
Lesson 2 16 Sep 2020
Lesson 3 23 Sep 2020
Lesson 4 30 Sep 2020
Lesson 5 7 Oct 2020
Lesson 6 14 Oct 2020
Lesson 7 28 Oct 2020
Lesson 8 4 Nov 2020
Lesson 9 11 Nov 2020
Lesson 10 18 Nov 2020
Lesson 11 25 Nov 2020
Lesson 12 2 Dec 2020
Exam Week 13 & 14

Fees

Category Full Fee After SF Funding After SF Mid-Career
Enhanced Subsidy
Singapore Citizen (Below 40) / Singapore PR $3,447.54 $1,034.26 Not Eligible
Singapore Citizen (40 & above) $3,447.54 $1,034.26 $389.86
Non-Singaporeans $3,447.54 Not Eligible Not Eligible

Note:
  • All figures include GST. GST applies to individuals and Singapore-registered companies.
  • You can opt for either SF Series Funding or Mid-Career Enhanced Subsidy. Both cannot be combined.

» Learn more about funding types available

Terms & Conditions:

SkillsFuture Funding
To be eligible for the 70% training grant awarded by SkillsFuture, applicants (and/or their sponsoring organisations where applicable) must:
  1.  Be a Singaporean Citizen or Singapore Permanent Resident
  2.  Not receive any other funding from government sources in respect of the actual grant disbursed for the programme

SkillsFuture Mid-Career Enhanced Subsidy To be eligible for the 90% enhanced subsidy awarded, applicants (and/or their sponsoring organisations where applicable) must:
  1.  Be a Singaporean Citizen
  2.  Be at least 40 years old
  3.  Not receive any other funding from government sources in respect of the actual grant disbursed for the programme
 

Union Training Assistance Programme (UTAP)

This is a Union Training Assistance Programme (UTAP) supported course. If you are an NTUC member, you can enjoy 50% unfunded course fee support for up to $250 each year for courses supported under UTAP. Terms and conditions apply.


SIT reserves the right to collect the balance of the programme fees (i.e. the potential grant amount) directly from the applicants (and/or their sponsoring organisations where applicable) should the above requirements not be fulfilled.

SIT reserves the right to make changes to published course information, including dates, times, venues, fees and instructors without prior notice.


What Industry Experts Say?

Extract from preface of an official reference book for this module:
“A railway is a complex distributed engineering system and thus the construction of a new railway or the modernisation of a existing railway requires a deep understanding of the constitutive components and their interaction - with themselves and with systems (or installations) external to the railway. This interaction requires a system-thinking approach, in which the overall functionality (or set of functions) can be demonstrated to have been achieved. The said functions are themselves requirements and the requirements covered in this book relate to electromagnetics. The railway electromagnetic environment is characterised by a complex mix of high power sources, sensitive safety critical systems, intentional transmitters in close proximity to each other and distributed over the entire length of the railway line. As a distributed complex system, it has the additional complexities of the propagated field being dependent, somewhat, on the position and current loading capability of the load (train) that is in motion.” – [Ade Ogunsola and Andrea Mariscotti, “Electromagnetic Compatibility in Railways - Analysis and Management”, Springer-Verlag, 2013.]

 

Extract from preface of an official reference book for this module:
“This book has evolved from the lecture series “Elektrische Bahnen” (“Electric Railways”) which has been held at Ruhr-Universität Bochum since 1996. Its primary audience are students of electrical energy technologies, control engineering and mechanical engineering as well as young engineers of electrical engineering, especially in the fields of power electronics, in railway industry and in railway-operating companies…Following constant interest from practitioners’ circles, now, six years after the initial publication of this book, the need has arisen to produce a 2nd, revised and extended edition under the same title. This enables both author and publishing house to include major developments which, by now, have become accepted practice in traction and railway industry. In particular, these developments include the permanent-magnet synchronous motor technology as well as the inverter-fed medium-frequency transformer, which is aimed to replace the main transformer, proving too heavy for 16 2/3-Hz traction frequency. Furthermore, new dualpower and hybrid vehicles as well as the new Modular Multilevel Converter topology for 16 2/3‑Hz traction power supply will be covered.” – [Andreas Steimel, “Electric Traction – Motive Power and Energy Supply Basics and Practical Experience | 2nd edition”, DIV Deutscher Industrieverlag, 2014.]

Course Series

Find out more about the Modular Certification Courses - Electrical Power Engineering (EPE)

These modules are stackable towards a Postgraduate Certificate in Electrical Power Engineering (PGCert EPE) or can be taken individually as a single module as follows:

  • EEE6001 Power Systems Analysis and Control
  • EEE6002 Power Electronic Conversion
  • EEE6003 Electrification for Transportation and Built Environment
  • EEE6004 Power Systems Fault Analysis and Protection
  • EEE6005 Power Quality and Reliability 
  • EEE6006 Smart Grids and Cyber Security 
  • EEE6007 Analysis and Design of Electrical Machine Systems 
  • EEE6008 Condition Monitoring in Power Engineering 
  • EEE6009 Energy Resources, Market and Economics 
  • EEE6010 Professional Practices in Power Engineering

Each module carries 6 ECTS credits which are stackable for graduate qualification of PGCert EPE. Candidates who pass any of the above 4 modules (totalling 24 credits) with a CGPA of 2.5 or more will be awarded the Postgraduate Certificate in Electrical Power Engineering (PGCert EPE) by SIT. All the above modules are subsidised by SkillsFuture Singapore. Eligible individual may enjoy up to a maximum of 5 subsidised modules

The above modules have been renamed from EPE60XX to EEE60XX for modules starting from Sep 2019. There is otherwise no change in stackability towards the Postgraduate Certificate in Electrical Power Engineering

Key Info

Venue SIT@NYP Building 172 Ang Mo Kio Avenue 8, 567739
Time 07:00 PM to 10:00 PM
Date 09 Sep 2020 (Wed) to
16 Dec 2020 (Wed)
Registration is Closed.

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