Highlights:
* Distribution transformers represent an important focus for energy efficiency initiatives.
* They are a worthwhile area for R&D, demonstration and promotional effort.
* The potential for reducing losses from distribution transformers affects strategies on energy efficiency and global warming.
* An action plan should be developed to achieve these goals.
* The strategy should be carefully co-ordinated, technically sound, and involve partners from all the supply chain.
COGEN Europe presentation: Micro-CHP overview at EU levelCOGEN Europe
COGEN Europe had the pleasure to present latest micro-CHP developments at the Micro-CHP Workshop organized by The Spanish Hydrogen & Fuel Cell Technological Platform on 12 February 2016.
The Spanish Hydrogen & Fuel Cell Technological Platform (PTE HPC) and the Centre for the Development of Industrial Technology (CDTI) are organising a double event comprising the FCH JU Call2016 national InfoDay and a Workshop on m-CHP.
The document discusses the key elements of EU energy policy, which aims to ensure affordable, secure, and sustainable energy for Europeans. It outlines several major challenges, including climate change, import dependency, and the need for infrastructure investment. The policy focuses on energy efficiency, completing the internal energy market, energy security, decarbonization through emissions trading and renewable investment, and research and development including the Strategic Energy Technology Plan. The overall goals are to reduce greenhouse gas emissions 20% by 2020, increase renewable energy to 20% of consumption, and improve energy efficiency 20%, as part of a long-term strategy to transform Europe's energy system.
The need for an updated European Motor Study - key findings from the 2021 US...Leonardo ENERGY
The document calls for an updated assessment of the electric motor system market in Europe, as the existing data is over 20 years old. It notes several changes in the market since then, including new efficient motor technologies, lower costs for power electronics, and increased digitization. The document highlights findings from a recent 2021 US motor study, which found motors to be older than previously estimated and significant improvements in load factors and variable speed drive penetration compared to past studies. It concludes that a new comprehensive assessment is needed to identify large potential electricity savings and inform policies to accelerate market transformation.
GM is pursuing an electrification strategy to reduce dependence on petroleum by developing a portfolio of advanced propulsion technologies including hybrids, plug-in hybrids, extended range electric vehicles, and fuel cell EVs. A key part of the strategy is the Chevrolet Volt, an extended range electric vehicle that can drive up to 80 km on battery only but has a gas engine range extender for an overall driving range of up to 490 km. Significant technological advancements are still needed to improve electric drive systems, batteries, power electronics, and controls to make electric vehicles more affordable and appealing to mass market buyers.
Energy Sufficiency Indicators and Policies (Lea Gynther, Motiva)Leonardo ENERGY
This policy brief looks at questions ‘how to measure energy sufficiency’, ‘which policies and measures can be used to address energy sufficiency’ and ‘how they are used in Europe today’.
Energy sufficiency refers to a situation where everyone has access to the energy services they need, whilst the impacts of the energy system do not exceed environmental limits. The level of ambition needed to address energy sufficiency is higher than in the case of energy efficiency.
This is the 13th edition of the Odyssee-Mure on Energy Efficiency Academy, and number 519 in the Leonardo ENERGY series. The recording of the live presentation can be found on https://www.youtube.com/watch?v=jEAdYbI0wDI&list=PLUFRNkTrB5O_V155aGXfZ4b3R0fvT7sKz
Energy efficiency trends in transport in the EULeonardo ENERGY
After 6 years of regular decrease, the energy consumption of transport in the EU has been rising again since 2013, at the same rate as before the financial crisis. It has become the most energy-consuming end-use sector, responsible for 31% of the final energy consumption in the EU27 in 2019. The energy transition in transport lags far behind the other sectors. However, some countries are performing better than others.
During this webinar, our expert speakers present an evaluation of the energy efficiency trend in the European transport sector since 2000. The following key questions are addressed:
What has been the overall trend in transport energy consumption in the EU and other European countries since 2000?
What are the main drivers for the energy consumption variation in transport, and in particular for the energy savings?
Recordings of the webinar: https://youtu.be/3TbePJCDvgE
The Super-efficient Equipment and Appliance Deployment (SEAD) Initiative Prod...Leonardo ENERGY
The Super-efficient Equipment and Appliance Deployment (SEAD) Initiative Product Efficiency Call to Action, by Melanie Slade - IEA and Nicholas Jeffrey - UK BEIS
Energy efficiency trends in the EU: Have we got off track?Diedert Debusscher
What has been the overall trend in final energy consumption and by sector in the EU since 2000? What are the main drivers of the energy consumption variation since 2000, and what has been the impact of energy savings? What are the trends in energy efficiency at the country level?
These are the key questions that will guide you through this webinar analysing energy efficiency trends in the EU for the period 2000-2019.
This presentation deck was used during the 9th webinar in the Odyssee-Mure on Energy Efficiency Academy on 25 June 2020. Recordings are available on https://www.youtube.com/user/LeonardoENERGY/videos?view=0&sort=dd&flow=grid
The webinar is an approximately 45 min presentation, followed by a live Q&A session with the panellists.
The document discusses vehicle electrification as a trend in the automotive industry. It covers topics like why electrification is important due to issues like global warming, different types of alternative powertrains like electric vehicles and their pros and cons. It also discusses batteries as a critical component for electric vehicles and covers various battery technologies and test standards. The document provides information on regulations around the world for vehicle emissions and fuel efficiency standards.
Tesla's patent portfolio focuses heavily on batteries and charging technologies, which comprise about 60% of its patents. While Tesla has a smaller overall portfolio than large automakers like Toyota and GM, it has significant patents related to battery technology like lithium-ion batteries and fast charging. Tesla's emphasis on batteries and charging differs from other large players, which focus more broadly on technologies like hybrid vehicles, internal combustion engines, and fuel cells in addition to batteries.
Micro combined heat and power (micro CHP) simultaneously generates electricity and usable heat from a single fuel source. It provides environmental, economic and social benefits. Micro CHP systems are typically under 15 kW and use natural gas, biogas or liquid biofuels. They capture waste heat from power generation to heat spaces and water. Compared to separate electricity and heating systems, micro CHP can achieve over 70% total fuel efficiency. It offers savings on energy costs and reduced emissions. Fuel cell and internal combustion engine micro CHP are well suited to residential and small commercial applications.
Towards a systems approach in Ecodesign and Energy Labelling: How to make the...Leonardo ENERGY
This document discusses moving towards a systems approach in ecodesign and energy labelling regulations. It provides an overview of some challenges in regulating systems compared to individual products, including assessing system efficiency, identifying responsible parties, and challenges for market surveillance authorities. Examples of studies on specific systems like heating/water heating packages, lighting systems, and pumps are mentioned. Views from the EU Commission emphasize that ecodesign regulations currently apply to individual goods placed on the market, but can also cover systems if they are put together on location. Moving towards more systems approaches could increase energy savings but also introduces complexity around testing, compliance, and enforcement.
This document discusses solar energy and solar self-consumption. It begins by covering energy sources in general before focusing on renewable vs non-renewable sources. Solar energy harnesses the sun's rays and works through photovoltaic technologies. Solar self-consumption uses on-site PV generation to meet a consumer's energy needs. The document then introduces the archeliosTM Calc software, which allows for calculation, sizing and control of self-consumption PV installations.
Développement de la cogénération en europeCOGEN Europe
Presentation by COGEN Europe on the development of cogeneration and micro-cogeneration in Europe at Journée de la micro et mini-cogénération ATEE in Paris
Introduction to the Renewable Energy DirectiveLeonardo ENERGY
The document discusses the Renewable Energy Directive (RED) of the European Union. It provides:
- An overview of the historic development of renewable energy in the EU and key policies leading up to the 2009 RED.
- Details of the 2009 RED, including binding national renewable energy targets for EU member states aimed at achieving an overall 20% renewable energy share by 2020.
- Information on how the European Commission calculated varying national targets based on member states' 2005 renewable energy shares and economic potentials.
- Charts showing progress towards interim targets based on member states' national plans and Eurostat data on deployment from 2005 to 2020.
The document discusses a Euro-Mediterranean project to integrate regional energy markets and promote national plans for energy efficiency. It focuses on presenting budget allocation charts for different countries, including Egypt. The charts compare the costs of conventional energy to various renewable energy and energy efficiency technologies to help decision-makers determine the most cost-effective investment options. Methodologies are described for selecting relevant technologies and measuring their potential energy savings and generation for each country. Preliminary outputs were generated but more data is still needed, particularly for energy efficiency measures.
Boosting building renovation: what potential and value for Europe?Judit Urquijo
Renovation of buildings is key to meet the EU’s energy efficiency targets. This paper reviews the literature on the state of the building stock and assesses various policy options and their potential for boosting the energy efficient renovation of buildings in Europe.
Presentation from the 2013 Atlantic Council Energy & Economic Summit expanded ministerial meeting. Presented by Giovanni F. De Santi, director, DG Joint Research Centre, Institute for Energy and Transport (IET)
ETIP SNET: For an innovative and successful European energy transition Leonardo ENERGY
The ETIP Smart Networks for Energy Transition (SNET) role is to guide Research, Development & Innovation (RD&I) to support Europe’s energy transition, more specifically, its mission is to set-out a vision for RD&I for Smart Networks for Energy Transition and engage stakeholders in this vision.
In this webinar the ETIP SNET role and main priorities will be introduced by its chairman Konstantin Staschus. Eric Peirano will present the new 10 year ETIP SNET Research & Innovation Roadmap 2017-2026. The roadmap provides a system view and addresses a scope larger than smart electricity grids by encompassing interactions with the gas and heat networks and focuses on integration of all flexibility solutions into the power system, including energy storage technologies.
IEA Technology roadmap solar photovoltaic energy 2014 Andrew Gelston
This document provides a summary and update of the International Energy Agency's 2014 technology roadmap for solar photovoltaic energy. It envisions solar PV providing up to 16% of global electricity by 2050, compared to 11% in the 2010 roadmap. Significant cost reductions have already been achieved, with further reductions possible through targeted research and development. Large-scale integration of variable solar PV will require measures to ensure grid stability and flexibility. Clear and predictable policy support is needed to continue driving down costs and overcoming non-economic barriers to deployment in order to achieve the roadmap's vision.
EURELECTRIC is the European electricity industry trade association. In 2016, EURELECTRIC advocated for policy positions and provided recommendations on key energy issues including the electricity market design, renewable energy targets, energy efficiency, and decarbonization. EURELECTRIC organized numerous events, published several reports and papers, and engaged with stakeholders on these important energy topics to help achieve Europe's climate and energy goals in a cost-effective way. EURELECTRIC also increased its communications efforts, expanding its social media presence and issuing more press releases to disseminate its views to wider audiences.
The sEEnergies project aims to operationalize the energy efficiency first principle (EEFP) both qualitatively and quantitatively. It will develop a decision support tool combining sector-specific energy demand models to analyze EE potentials from an energy systems perspective. Bottom-up models of buildings, transport, industry and grids will provide cost curves and potentials for EE measures. Scenarios from the EU's "A Clean Planet for All" will be used as common references. Energy system modelling will assess EEFP impacts and enable scenarios assessing synergies. A spatial model will map supply and demand and efficiency potentials. Heat Roadmap Europe provides recommendations including prioritizing savings over supply, utilizing excess heat and renewable energy in district heating, and establishing
Second Stakeholder Event for the Revision of Directive (REDII) 2018/2001
Session 2 Renewable energy in Heating and Cooling, Buildings and District Heating
Professor Brian Vad Mathiesen, Aalborg University
March 22, 2021, Brussels - Online
The Strategic Energy Technology Plan: at the heart of energy R&I in EuropeNuno Quental
The Strategic Energy Technology (SET) Plan document outlines the key milestones in the 10-year history of the SET Plan, which was established to help reshape Europe's energy future and accelerate the clean energy transition. The SET Plan aims to develop new technologies through breakthrough research to meet climate change goals and reduce costs. It focuses R&I funding on priority technologies and leverages cooperation across European countries and the private sector. Over the past decade, renewable energy costs have declined significantly while deployment has increased substantially in Europe, putting the EU in a leading global position for many clean energy sectors. However, greater ambition is still needed to achieve emissions reduction targets.
Promoting an EU Agenda for Electromagnetic Processing of MaterialsLeonardo ENERGY
The document discusses promoting electromagnetic processing (EP) technologies in the EU through policy measures. It makes the following key points:
1) Heating and cooling accounts for over half of Europe's energy consumption and offers significant reduction potential through electrification of industrial processes using EP technologies like induction heating.
2) Pilot projects have demonstrated EP technologies can provide energy savings of up to 75% and reduce heating times and emissions. Full adoption across energy-intensive industries could save over 13% of annual EU energy demand.
3) Targeted policy measures are needed to strengthen drivers for EP technologies and remove barriers, such as including them in the Energy Efficiency Directive, Renewable Energy Directive, and best available techniques reference
Ensuring European Energy Transition: key research and innovation actions need...Leonardo ENERGY
Konstantin Staschus and Sophie Dourlens will present the new ETIP SNET Implementation Plan (IP) 2017-2020 which is to be released on 5 October 2017
The Implementation Plan aims at listing the short-term priorities for R&I in ETIP SNET’s scope and as defined by the action 4 of the EU’s Strategic Energy Technology Plan: Increase the resilience, security and smartness of the energy system. It is based upon the ETIP-SNET R&I roadmap 2017-2026 which specifies the long-term R&I activities for the evolution of the European energy system and published in January 2017.
The Implementation Plan is the result of a long and comprehensive stakeholders consultation process which makes it widely recognised by all the European energy transition stakeholders.
These are the supporting materials used by the different speakers of the H2020 WHY project opening session. This evento was held on September 10, 2020.
The role of electricity in heating and coolingLeonardo ENERGY
Following the European Commission’s Heating & Cooling Strategy Consultation Forum, held in Brussels on September 9th, very significant opportunities exist within the heating and cooling sector to better connect the EU’s electricity and thermal energy markets.
The use of electricity in heating and cooling helps to increase the penetration of renewables, improve efficiency, lower carbon emissions and save significant investment costs in renewables integration. However, crucial to these uses is the promotion of efficient electrothermal technologies.
This document discusses energy efficiency and smart communities from a European Union perspective. It provides background on climate and energy targets in the EU, the development of the Energy Union initiative, and key policy areas like secure energy supplies, completing the internal energy market, promoting energy efficiency, reducing emissions, and boosting research and innovation. It also examines the role of smart cities, sustainable buildings, and EU funding mechanisms like the Covenant of Mayors in supporting energy and climate goals at the local level.
The document describes the DecarbEurope initiative, which aims to engage decision-makers in reducing European greenhouse gas emissions through cost-effective technical solutions. The initiative includes 9 organizations and 2 media partners working to connect low-carbon technologies, policies, and markets. Each promoted solution is meant to reduce emissions by hundreds of millions of tons per year in a cost-effective and scalable way. The initiative seeks to encourage policies that remove barriers hindering the deployment of these emissions-reducing technologies.
This document summarizes an article about the limitations of electric vehicles for addressing transportation emissions and promoting sustainable mobility. It makes three key points:
1) Transportation emissions have increased significantly since 1990, negating reductions in other sectors, so a more radical policy change is needed. Electric vehicles alone will not solve this problem.
2) Electric vehicles still have drawbacks like high costs, heavy batteries, and short ranges of only about 200km per charge. They mainly compete with more sustainable modes like public transit rather than replacing private car use.
3) The problems with car use like emissions, noise, accidents, land use, and costs are only partly addressed by electric vehicles. More alternatives to private car ownership are needed
2016-05-03_European Energy Saving Guide 2016_finalRalf Pasker
- The document discusses the need for Europe to take more responsibility and action to increase energy efficiency in buildings through renovation programs. It notes that 40% of energy in Europe is used by buildings, and a large portion is imported from unstable regions.
- Research shows the significant potential economic benefits of a focused renovation drive for the European economy, especially in southern Europe which still suffers from the euro crisis. The "InnovationCity" project in Germany achieved a 4% annual renovation rate within years.
- Individual building owners undertaking energy renovations alone will not be enough; governments must view increasing energy efficiency as a societal challenge rather than the responsibility of individuals. The economic benefits of renovation programs accrue both
September 2019 edition of the DecarbEurope primer on electric vehicles, reviewing some of the major issues to address in the coming years:
* low-emission zones
* right-to-plug
* 150 kW network
Similar to The Scope for Energy Saving in the EU through the Use of Energy-Efficient Distribution Transformers (20)
A new generation of instruments and tools to monitor buildings performanceLeonardo ENERGY
What is the added value of monitoring the flexibility, comfort, and well-being of a building? How can occupants be better informed about the performance of their building? And how to optimize a building's maintenance?
The slides were presented during a webinar and roundtable with a focus on a new generation of instruments and tools to monitor buildings' performance, and their link with the Smart Readiness Indicator (SRI) for buildings as introduced in the EU's Energy Performance of Buildings Directive (EPBD).
Link to the recordings: https://youtu.be/ZCFhmldvRA0
Addressing the Energy Efficiency First Principle in a National Energy and Cli...Leonardo ENERGY
When designing energy and climate policies, EU Member States have to apply the Energy Efficiency First Principle: priority should be given to measures reducing energy consumption before other decarbonization interventions are adopted. This webinar summarizes elements of the energy and climate policy of Cyprus illustrating how national authorities have addressed this principle so far, and outline challenges towards its much more rigorous implementation that is required in the coming years.
Auctions for energy efficiency and the experience of renewablesLeonardo ENERGY
Auctions are an emerging market-based policy instrument to promote energy efficiency that has started to gain traction in the EU and worldwide. This presentation provides an overview and comparison of several energy efficiency auctions and derives conclusions on the effects of design elements based on auction theory and on experiences of renewable energy auctions. We include examples from energy efficiency auctions in Brazil, Canada, Germany, Portugal, Switzerland, Taiwan, UK, and US.
A recording of this presentation can be viewed at:
https://youtu.be/aC0h4cXI9Ug
Energy efficiency first – retrofitting the building stock finalLeonardo ENERGY
Retrofitting the building stock is a challenging undertaking in many respects - including costs. Can it nevertheless qualify as a measure under the Energy Efficiency First principle? Which methods can be applied for the assessment and what are the results in terms of the cost-effectiveness of retrofitting the entire residential building stock? How do the results differ for minimization of energy use, CO2 emissions and costs? And which policy conclusions can be drawn?
This presentation was used during the 18th webinar in the Odyssee-Mure on Energy Efficiency Academy on February 3, 2022.
A link to the recording: https://youtu.be/4pw_9hpA_64
How auction design affects the financing of renewable energy projects Leonardo ENERGY
Recording available at https://youtu.be/lPT1o735kOk
Renewable energy auctions might affect the financing of renewable energy (RE) projects. This webinar presents the results of the AURES II project exploring this topic. It discusses how auction designs ranging from bid bonds to penalties and remuneration schemes impact financing and discusses creating a low-risk auction support framework.
This presentation discusses the contribution of Energy Efficiency Funds to the financing of energy efficiency in Europe. The analysis is based on the MURE database on energy efficiency policies. As an example, the German Energy Efficiency Fund is described in more detail.
This is the 17th webinar in the Odyssee-Mure on Energy Efficiency Academy.
Recordings are available on: https://youtu.be/KIewOQCgQWQ
(see updated version of this presentation:
https://www.slideshare.net/sustenergy/energy-efficiency-funds-in-europe-updated)
The Energy Efficiency First Principle is a key pillar of the European Green Deal. A prerequisite for its widespread application is to secure financing for energy efficiency investments.
This presentation discusses the contribution of Energy Efficiency Funds to the financing of energy efficiency in Europe. The analysis is based on the MURE database on energy efficiency policies. As an example, the German Energy Efficiency Fund is described in more detail.
This is the 17th webinar in the Odyssee-Mure on Energy Efficiency Academy.
Recordings are available on: https://youtu.be/KIewOQCgQWQ
Five actions fit for 55: streamlining energy savings calculationsLeonardo ENERGY
During the first year of the H2020 project streamSAVE, multiple activities were organized to support countries in developing savings estimations under Art.3 and Art.7 of the Energy Efficiency Directive (EED).
A fascinating output of the project so far is the “Guidance on Standardized saving methodologies (energy, CO2 and costs)” for a first round of five so-called Priority Actions. This Guidance will assist EU member states in more accurately calculating savings for a set of new energy efficiency actions.
This webinar presents this Guidance and other project findings to the broader community, including industry and markets.
AGENDA
14:00 Introduction to streamSAVE
(Nele Renders, Project Coordinator)
14:10 Views from the EU Commission and the link with Fit-for-55 (Anne-Katherina Weidenbach, DG ENER)
14:20 The streamSAVE guidance and its platform illustrated (Elisabeth Böck, AEA)
14:55 A view from industry: What is the added value of streamSAVE (standardized) methods in frame of the EED (Conor Molloy, AEMS ECOfleet)
14:55 Country experiences: the added value of standardized methods (Elena Allegrini, ENEA, Italy)
The recordings of the webinar can be found on https://youtu.be/eUht10cUK1o
This webinar analyses energy efficiency trends in the EU for the period 2014-2019 and the impact of COVID-19 in 2020 (based on estimates from Enerdata).
The speakers present the overall trend in total energy supply and in final energy consumption, as well as details by sector, alongside macro-economic data. They will explain the main drivers of the variation in energy consumption since 2014 and determine the impact of energy savings.
Speakers:
Laura Sudries, Senior Energy Efficiency Analyst, Enerdata
Bruno Lapillonne, Scientific Director, Enerdata
The recordings of the presentation (webinar) can be viewed at:
https://youtu.be/8RuK5MroTxk
Energy and mobility poverty: Will the Social Climate Fund be enough to delive...Leonardo ENERGY
Prior to the current soaring energy prices across Europe, the European Commission proposed, as part of the FitFor55 climate and energy package, the EU Social Climate Fund to mitigate the expected social impact of extending the EU ETS to transport and heating.
The report presented in this webinar provides an update of the European Energy Poverty Index, published for the first time in 2019, which shows the combined effect of energy and mobility poverty across Member States. Beyond the regular update of the index, the report provides analysis of the existing EU policy framework related to energy and transport poverty. France is used as a case study given the “yellow vest” movement, which was triggered by the proposed carbon tax on fuels.
Watch the recordings of the webinar:
https://youtu.be/i1Jdd3H05t0
Does the EU Emission Trading Scheme ETS Promote Energy Efficiency?Leonardo ENERGY
This policy brief analyzes the main interacting mechanisms between the Energy Efficiency Directive (EED) and the EU Emission Trading Scheme (ETS). It presents a detailed top-down approach, based on the ODYSSEE energy indicators, to identify energy savings from the EU ETS.
The main task consists in isolating those factors that contribute to the change in energy consumption of industrial branches covered by the EU ETS, and the energy transformation sector (mainly the electricity sector).
Speaker:
Wolfgang Eichhammer (Head of the Competence Center Energy Policy and Energy Markets @Fraunhofer Institute for Systems and Innovation Research ISI)
The recordings of this webinar can be watched via:
https://youtu.be/TS6PxIvtaKY
Energy efficiency, structural change and energy savings in the manufacturing ...Leonardo ENERGY
- Structural changes in manufacturing have significantly reduced energy consumption in Denmark since 1990 through growth in lower intensity sectors like food production.
- Energy efficiency improvements also contributed, especially from 2010-2014, lowering consumption alongside structural changes.
- A decomposition analysis found that decreases in consumption from 2006-2014 were mainly from structural effects in the first half, and efficiency gains in the latter half.
- Reported energy savings from Denmark's energy efficiency obligation scheme align with estimated efficiency improvements, though some autonomous gains likely occurred too.
Breuckmann eMobility GmbH develops innovative rotor casting technology called Zero Porosity Rotor (ZPR) for electric vehicle induction motors. ZPR uses laminar squeeze casting to produce rotors with zero porosity, allowing for superior mechanical properties, higher electrical conductivity, and maximum process stability compared to industry standard rotors. Key advantages of ZPR rotors include up to 12.5% higher maximum rotational speed, 35% higher electrical conductivity, and ability to withstand 25% higher circumferential bursting speeds. Breuckmann has partnerships for motor testing, slot geometry design, and received EU funding to develop high-speed motor concepts using its ZPR technology.
dynamic E flow GmbH provides high-tech electric machines and solutions for extreme applications. Their capcooltech® motor features direct winding cooling that enables current densities up to 100A/mm2 and overload capacities. Testing shows the capcooltech® design maintains temperatures 40°C lower and heats 10 times faster than conventional cooling. The direct cooling test bench demonstrates capcooltech® motors can achieve maximum power density, temperature resistance, precision, and dynamics even in harsh conditions like vacuum or high temperatures.
Efficient motor systems for a Net Zero world, by Conrad U. Brunner - Impact E...Leonardo ENERGY
1) The document discusses the need for efficient electric motor systems to achieve net-zero emissions by 2050, as electricity will be the main energy supplier without fossil fuels or nuclear.
2) It provides examples of how industry can achieve efficiency savings of 50-70% through measures like downsizing components, direct drive systems, and load control.
3) A case study shows how converting an oversized 10kW system to a smaller, variable speed, direct drive setup with efficient components achieves 82% energy savings and a payback period of just one year.
Motivation, benefits, and challenges for new photovoltaic material & module d...Leonardo ENERGY
The main objective of the IEA-PVPS Task 13 Report on “Designing New Materials for Photovoltaics: Opportunities for Lowering Cost and Increasing Performance through Advanced Material Innovations” is to provide a global survey of technical efforts aimed at lowering cost and increasing performance and reliability of PV modules by employing new designs, materials and concepts. Furthermore, the report aims to (1) increase the exchange of information about promising materials and design concepts, (2) provide the means for increasing the value of PV modules, (3) provide recommendations on characterization methods for new technologies and (4) give input regarding new requirements for standardization. This paper focuses on describing the motivation, benefits, and challenges for new photovoltaic material and module developments.
Lessons learnt from the EEA catalogue of environment and climate policy evalu...Leonardo ENERGY
The EEA catalogue of environment and climate policy evaluations is a database of about 600 evaluations. This webinar will present the objectives and contents of this catalogue, how it has been developed and what lessons can be learnt from this compilation.
A brand new catalog for the 2024 edition of IWISS. We have enriched our product range and have more innovations in electrician tools, plumbing tools, wire rope tools and banding tools. Let's explore together!
Response & Safe AI at Summer School of AI at IIITHIIIT Hyderabad
Talk covering Guardrails , Jailbreak, What is an alignment problem? RLHF, EU AI Act, Machine & Graph unlearning, Bias, Inconsistency, Probing, Interpretability, Bias
A vernier caliper is a precision instrument used to measure dimensions with high accuracy. It can measure internal and external dimensions, as well as depths.
Here is a detailed description of its parts and how to use it.
20CDE09- INFORMATION DESIGN
UNIT I INCEPTION OF INFORMATION DESIGN
Introduction and Definition
History of Information Design
Need of Information Design
Types of Information Design
Identifying audience
Defining the audience and their needs
Inclusivity and Visual impairment
Case study.
An Internet Protocol address (IP address) is a logical numeric address that is assigned to every single computer, printer, switch, router, tablets, smartphones or any other device that is part of a TCP/IP-based network.
Types of IP address-
Dynamic means "constantly changing “ .dynamic IP addresses aren't more powerful, but they can change.
Static means staying the same. Static. Stand. Stable. Yes, static IP addresses don't change.
Most IP addresses assigned today by Internet Service Providers are dynamic IP addresses. It's more cost effective for the ISP and you.
Unblocking The Main Thread - Solving ANRs and Frozen FramesSinan KOZAK
In the realm of Android development, the main thread is our stage, but too often, it becomes a battleground where performance issues arise, leading to ANRS, frozen frames, and sluggish Uls. As we strive for excellence in user experience, understanding and optimizing the main thread becomes essential to prevent these common perforrmance bottlenecks. We have strategies and best practices for keeping the main thread uncluttered. We'll examine the root causes of performance issues and techniques for monitoring and improving main thread health as wel as app performance. In this talk, participants will walk away with practical knowledge on enhancing app performance by mastering the main thread. We'll share proven approaches to eliminate real-life ANRS and frozen frames to build apps that deliver butter smooth experience.
How to Manage Internal Notes in Odoo 17 POSCeline George
In this slide, we'll explore how to leverage internal notes within Odoo 17 POS to enhance communication and streamline operations. Internal notes provide a platform for staff to exchange crucial information regarding orders, customers, or specific tasks, all while remaining invisible to the customer. This fosters improved collaboration and ensures everyone on the team is on the same page.
Understanding Cybersecurity Breaches: Causes, Consequences, and PreventionBert Blevins
Cybersecurity breaches are a growing threat in today’s interconnected digital landscape, affecting individuals, businesses, and governments alike. These breaches compromise sensitive information and erode trust in online services and systems. Understanding the causes, consequences, and prevention strategies of cybersecurity breaches is crucial to protect against these pervasive risks.
Cybersecurity breaches refer to unauthorized access, manipulation, or destruction of digital information or systems. They can occur through various means such as malware, phishing attacks, insider threats, and vulnerabilities in software or hardware. Once a breach happens, cybercriminals can exploit the compromised data for financial gain, espionage, or sabotage. Causes of breaches include software and hardware vulnerabilities, phishing attacks, insider threats, weak passwords, and a lack of security awareness.
The consequences of cybersecurity breaches are severe. Financial loss is a significant impact, as organizations face theft of funds, legal fees, and repair costs. Breaches also damage reputations, leading to a loss of trust among customers, partners, and stakeholders. Regulatory penalties are another consequence, with hefty fines imposed for non-compliance with data protection regulations. Intellectual property theft undermines innovation and competitiveness, while disruptions of critical services like healthcare and utilities impact public safety and well-being.
OCS Training Institute is pleased to co-operate with
a Global provider of Rig Inspection/Audits,
Commission-ing, Compliance & Acceptance as well as
& Engineering for Offshore Drilling Rigs, to deliver
Drilling Rig Inspec-tion Workshops (RIW) which
teaches the inspection & maintenance procedures
required to ensure equipment integrity. Candidates
learn to implement the relevant standards &
understand industry requirements so that they can
verify the condition of a rig’s equipment & improve
safety, thus reducing the number of accidents and
protecting the asset.
Literature Reivew of Student Center DesignPriyankaKarn3
It was back in 2020, during the COVID-19 lockdown Period when we were introduced to an Online learning system and had to carry out our Design studio work. The students of the Institute of Engineering, Purwanchal Campus, Dharan did the literature study and research. The team was of Prakash Roka Magar, Priyanka Karn (me), Riwaz Upreti, Sandip Seth, and Ujjwal Dev from the Department of Architecture. It was just a scratch draft made out of the initial phase of study just after the topic was introduced. It was one of the best teams I had worked with, shared lots of memories, and learned a lot.
Social media management system project report.pdfKamal Acharya
The project "Social Media Platform in Object-Oriented Modeling" aims to design
and model a robust and scalable social media platform using object-oriented
modeling principles. In the age of digital communication, social media platforms
have become indispensable for connecting people, sharing content, and fostering
online communities. However, their complex nature requires meticulous planning
and organization.This project addresses the challenge of creating a feature-rich and
user-friendly social media platform by applying key object-oriented modeling
concepts. It entails the identification and definition of essential objects such as
"User," "Post," "Comment," and "Notification," each encapsulating specific
attributes and behaviors. Relationships between these objects, such as friendships,
content interactions, and notifications, are meticulously established.The project
emphasizes encapsulation to maintain data integrity, inheritance for shared behaviors
among objects, and polymorphism for flexible content handling. Use case diagrams
depict user interactions, while sequence diagrams showcase the flow of interactions
during critical scenarios. Class diagrams provide an overarching view of the system's
architecture, including classes, attributes, and methods .By undertaking this project,
we aim to create a modular, maintainable, and user-centric social media platform that
adheres to best practices in object-oriented modeling. Such a platform will offer users
a seamless and secure online social experience while facilitating future enhancements
and adaptability to changing user needs.
The Scope for Energy Saving in the EU through the Use of Energy-Efficient Distribution Transformers
1. ENERGIE
E u r o p e a n C o m m i s s i o n
E n e r g y e f f i c i e n c y
i n Tr a n s m i s s i o n &
D i s t r i b u t i o n
The scope for
energy saving
in the EU
through the use of
energy-efficient electricity
distribution transformers
3. The scope for energy saving in the EU
through the use of
energy-efficient electricity
distribution transformers
THERMIE B PROJECT Nº STR-1678-98-BE
First Published December 1999
5. 3
CONTENTS
1. EXECUTIVE SUMMARY 5
2. CONCLUSIONS AND RECOMMENDATIONS
2.1 Conclusions 6
2.2 Recommendations 6
3. INTRODUCTION
3.1 Background 7
3.2 Project Components 7
3.3 Methodology 7
4. THE ROLE OF TRANSFORMERS
4.1 Electricity Supply System Concepts 8
4.2 Distribution Transformers 8
4.3 Transformer Losses 9
5. ELECTRICITY SUPPLY AND DEMAND IN THE EU
5.1 Supply System Design 9
5.2 Power Generation and Distribution Utilities 10
5.3 Non-utility Electricity Supply 10
5.4 Production Capacity 11
5.5 Demand and Growth Rate 11
5.6 Representation 12
5.7 Regulation 12
5.8 Environmental Impact 13
5.9 Energy Losses 13
5.10 Distribution System Losses 13
6. DISTRIBUTION TRANSFORMER INSTALLATIONS
6.1 Ownership 15
6.2 Population 15
6.3 Transformer Age Profile 15
6.4 Failures 15
6.5 Investment Programmes 16
7. THE EU DISTRIBUTION TRANSFORMER MARKET
7.1 Market Size 16
7.2 Growth Rates 16
7.3 Purchasing Policies and Procedures 17
7.4 Standards and Designs 17
8. TRANSFORMER MANUFACTURE IN THE EU
8.1 Industry Overview 18
8.2 Industry Structure 19
8.3 Manufacturing Investment 19
8.4 Product Ranges 19
8.5 Exports 19
8.6 Repair and Maintenance 20
8.7 Representation 20
9. DISTRIBUTION TRANSFORMER TECHNOLOGY
9.1 Design Concepts 20
9.2 Transformer Steels 21
9.3 Grain-oriented Steels 21
9.4 Domain Refined Steels 22
9.5 Amorphous Iron 22
9.6 Future Developments 22
9.7 Conductor Developments 22
9.8 Other Materials 23
9.9 Core Fabrication and Assembly 23
9.10 Coil Winding and Assembly 23
9.11 Superconducting Transformers 25
9.12 Technology Sources 25
10. TECHNICAL AND ENGINEERING APPRAISAL
10.1 Distribution Transformer Standards 26
10.2 Rated loss levels of Standard
Distribution Transformers 27
10.3 Loss levels of Standard Distribution
Transformers when Loaded 27
10.4 Achievable Loss levels 29
10.5 Loss Levels in Practice 30
10.6 Loss Evaluation 32
10.7 Case Study 1: Replacement of Old
Transformers 34
10.8 Case Study 2: Evolution of Dutch
Transformers Specification 37
10.9 Case Study 3: Large AMDT in Europe 38
11. ECONOMIC AND MARKET ANALYSIS
11.1 Assessment of Energy-saving Potential 40
11.2 Contribution to Energy Efficiency and
Global Warming Goals 42
11.3 Characterisation of the Utility Market 42
11.4 Characterisation of the Non-Utility Market 43
11.5 National/International Policies and
Initiatives 44
11.6 Potential Mechanisms for Change 44
11.7 International Perspective 46
12. ANALYSIS, RECOMMENDATIONS, STRATEGY,
ACTION PLAN
12.1 Analysis 47
12.2 Recommendations 47
12.3 Strategy Development 48
12.4 Strategy Components 48
12.5 Action Plan 48
13. ACTIONS, PARTNERS
13.1 Examples of Proposals, Actions and Impact 49
13.2 Approach to the Non-utility Sector 50
13.3 Partners for Collaboration, Facilitators 50
13.4 Sources of Funding 50
APPENDICES:
A: Losses, EU Electricity Systems, 1980-2010
B: Members of COTREL
C: References
6. 4
LIST OF FIGURES
Figure 1 Build-up of Three-phase Distribution transformer
Figure 2 Electricity Distribution System
Figure 3 Maximum Net Generating Capacity at end-year,
European Union (MW)
Figure 4 Electricity Consumption, European Union, 1980 -
2010 (TWh)
Figure 5 System Losses - European Utilities (%)
Figure 6 Distribution losses for LV and HV Customers, United
Kingdom Distribution Utilities (%)
Figure 7 European Distribution Transformer Production
Figure 8 Typical Distribution Transformer Parameters
Figure 9 Development Stages, Transformer Steels
Figure 10 Spiral Sheet Low-voltage Winding
Figure 11 Multilayer Coil High-voltage Winding
Figure 12 Disc Coil High-voltage Winding
Figure 13 Distribution Transformer Loss Standards
Figure 14 Total Losses of a 400 kVA Transformer as
Function of the Load (12kV and 24 kV transform-
ers)
Figure 15 Dependency of Transformer Losses on Size (kVA)
for 12kV and 24kV transformers
Figure 16 Fictitious Example of Different Europ
Transformer Standards
Figure 17 Comparison of Technologies to Improve Energy
Efficiency
Figure 18 Cost comparison of typical Distribu
Transformers according to Figure 8
Figure 19 Typical transformer replaced in the context of the
Groningen Project
Figure 20 21 Transformers 400 kVA evaluated for Groningen
Project 1983 - 1999
Figure 21 Transformers 400 kVA evaluated for Groningen
Project (NL) 1982 - 1999 at peak load / rated
load = 0.6
Figure 22 Distribution System Losses
Figure 23 Savings Potential through installing Energy-effi
cient Transformers, Europe
Figure 24 Energy Saving Potential and Payback - Energy-effi-
cient transformers
7. 5
1 EXECUTIVE SUMMARY
The ultimate scope for saving energy in the EU through the use of
energy-efficient distribution transformers, is approximately
22TWh/year, worth €1,171 million at 1999 prices. Despite the
efficiency of individual units, up to 2% of total power generated
is estimated to be lost in distribution transformers, nearly one-
third of overall losses from the system. This is comparable in scope
with the energy savings potential estimated for electric motors and
domestic appliances. It is equivalent to the annual power con-
sumption of over 5.1 million homes, or the electricity produced
by three of the largest coal-burning power stations in Europe.
Because of the long life span of distribution transformers, ultimate
market penetration will only be achieved gradually. However, we
estimate that energy-efficient units could contribute 7.3TWh of
savings by 2010, representing over 1% of the European commit-
ment to reducing carbon emissions.
Europe has an urgent need to develop a strategy on existing and
future global warming actions. As far as we have been able to
ascertain, no European country has yet developed targets for the
global warming savings potential which could result from distri-
bution transformer programmes, nor has a formal estimate been
made for the EU or Europe as a whole.
Europe has considerable potential to offer world-wide in trans-
former technology and experience. However, national govern-
ments and utilities appear to lag behind the US in terms of pro-
grammes and initiatives to encourage energy efficiency. There are
no initiatives comparable to the US DOE/EPA programmes on
utility commitments, information and software dissemination.
This is despite the fact that most of the major European countries
have a very poor position on energy self-sufficiency.
There is already considerable R&D and promotional effort with-
in Europe aimed at reducing losses in small transformers, e.g. for
domestic and office equipment, and some IEA/OECD work has
been undertaken. Initiatives have included campaigns to urge con-
sumers to switch off appliances, and the use of more efficient core
materials. This could assist in focusing attention on the equally
significant target of distribution transformers.
It is apparent that both utilities and private sector purchasers are
difficult to influence. The transformer market is extremely com-
petitive, and efforts to improve energy efficiency in the past have
had limited success. However, the sector involves a limited num-
ber of professional buyers, already reasonably aware of the argu-
ments for energy efficiency, and with well-established techniques
for evaluating transformer performance. They are therefore likely
to be receptive to rational arguments, provided that benefits are
clearly demonstrated
We believe that distribution transformers represent an important
focus for energy efficiency initiatives within the EU and a worth-
while area for R&D, demonstration and promotional effort. We
therefore recommend the following:
l the potential for reducing losses from distribution transformers
should be considered as one element of EU and national strate-
gies on energy efficiency, global warming, and environmental
impact
l an action plan should be developed to achieve these goals. The
strategy and action plan need to be carefully co-ordinated, tech-
nically sound, and carry partners from all levels in the supply
chain.
8. 6
2 CONCLUSIONS AND
RECOMMENDATIONS
2.1 Conclusions
The theoretical scope for energy savings through the use of ener-
gy-efficient distribution transformers in the EU is very substantial.
Despite the efficiency of individual units, up to 2% of total power
generated is estimated to be lost in distribution transformers,
equivalent to nearly one-third of overall losses from the power sys-
tem.
The savings potential is approximately 22TWh/year, worth
€1,171 million at 1999 prices. This is comparable in scope with
the energy savings potential estimated for electric motors in the
EU (27TWh) and domestic appliances. It is equivalent to the
annual energy consumption of over 5.1 million homes, or the
electricity produced by three of the largest coal-burning power sta-
tions in Europe.
Because of the long life span of distribution transformers, ultimate
market penetration will only be achieved gradually. However ener-
gy-efficient units could contribute 7.3TWh of savings by 2010,
representing over 1% of the European commitment to reducing
carbon emissions.
As far as we have been able to ascertain, no European country has
developed targets for the global warming savings potential which
could result from distribution transformer programmes, nor has a
formal estimate yet been made for the EU or Europe as a whole.
European countries are currently developing strategies on existing
and future global warming actions. As this happens, the potential
for reducing losses from distribution transformers could be pro-
moted, to ensure that they are incorporated as a component of the
plan.
Europe has considerable potential to offer world-wide in trans-
former technology and experience. However, national govern-
ments and utilities lag behind the US in terms of programmes and
initiatives to encourage energy efficiency.
There are no initiatives comparable to the US DOE/EPA pro-
grammes on voluntary utility agreements, or information and
software dissemination. This is despite the fact that most
European countries have a poor position on energy self-sufficien-
cy. The US has also recently started a process to evaluate the role
of regulation in transformer efficiency.
There is already considerable R&D and promotional effort with-
in Europe aimed at reducing losses in small transformers, e.g. for
domestic and office equipment, and some IEA/OECD work has
been undertaken. Initiatives have included campaigns to urge con-
sumers to switch off appliances when not in use, and the adoption
of more efficient core materials. These are directed at domestic
consumers, rather than utilities and professional buyers, but could
assist in focusing attention on the equally significant target of dis-
tribution transformers.
It is apparent that both utilities and non-utility purchasers are dif-
ficult to influence. The transformer market is extremely competi-
tive, and efforts to improve energy efficiency in the past have had
limited success. However, the sector involves a limited number of
professional buyers, already reasonably aware of the arguments for
energy efficiency, and with well-established techniques for evalu-
ating transformer performance. They are therefore likely to be
receptive to rational arguments, provided that benefits are clearly
demonstrated.
2.2 Recommendations
We consider that distribution transformers should be recognised
as an important focus for energy efficiency initiatives within the
EU, and that they represent a worthwhile area for R&D, demon-
stration and promotional effort. We therefore recommend the fol-
lowing:
l as EU and national strategies on energy efficiency, global warm-
ing, and environmental impact are developed, the potential for
reducing losses from distribution transformers should be consid-
ered, to ensure that they are incorporated as a component
l a strategy should be developed to set and achieve goals for reduc-
ing losses from distribution transformers, or possibly from all
power systems transformers in the EU. The strategy needs to be
carefully co-ordinated and be both technically and commercial-
ly sound
l the main elements of an action plan to achieve the strategy
should be identified and developed.
9. 7
3 INTRODUCTION
3.1 Background
This project was undertaken to provide a detailed assessment of
the scope for installing energy-efficient distribution transformers
in both utility-operated and private electricity supply systems in
the European Union.
An estimate has been made of the contribution which they could
make to energy savings in the EU. The study has also identified
the main technical, engineering and financial barriers to their
application, and develops a suggested strategy to encourage their
introduction.
The proposed strategy relates specifically to Europe, evaluating
R&D and technical advances against factors such as the installed
age and population of distribution transformers, replacement lev-
els, utility ownership, distribution network design, operating volt-
ages, purchasing criteria and financial constraints.
The study enables the European Commission, the governments of
Member States, and regulators, to understand the current and
future scope for energy saving which is associated with energy-effi-
cient distribution transformers. It also allows to assess specific
actions taking place or planned within the Community, and its
priority compared with other sectors.
We believe that the study will also help electricity utilities and pri-
vate electricity network operators to identify and specify energy-
efficient equipment, based on a clearer understanding of available
products and concepts, ways of evaluating financial pay-backs and
life-time costs, and the use of concepts such as demand side man-
agement (DSM).
3.2 Project Components
The study has collected data from all EU countries. It takes
account of national and regional priorities, installed electricity sys-
tem networks, engineering practice. Some factors, for example the
recent change in distribution operating voltages, affects various
countries differently.
We have collected and analysed the limited amount of available
statistical and marketing data to derive estimates of distribution
transformer populations. We have also made estimates of
pole/ground-mounted ratio, total capacity in GVA, operating
voltages, unit size and rating profile, oil-filled/dry-type ratio, own-
ership, age profile, current and planned new installation rates.
The major technologies offering scope for energy efficiency in dis-
tribution transformers have been identified and appraised. These
include transformer sizing, core/coil loss ratios, materials and
components currently available and under development, such as
amorphous iron, special magnetic steels etc.
We have also collected some technical and cost data, and operat-
ing experience, from existing energy-efficient transformer installa-
tions. Their success and relevance for wider application has been
assessed, and a specific profile prepared for dissemination. An
appraisal has been made of world-wide R&D developments likely
to improve energy efficiency in distribution transformers, and the
technical and commercial barriers which they face.
We have made an estimate of the potential impact on Europe of
energy efficiency developments and initiatives in this sector, and
identified strategic plan components for Europe in this sector.
These are quantified as far as possible in terms of total energy sav-
ings, contribution to global warming goals, scope to delay or avoid
new capital investments, demand side management, etc.
3.3 Methodology
The study is based on desk and telephone interviews, combined
with a brief field programme in four key markets, France,
Germany, Italy and the UK.
Our contacts included electricity utilities, specifying authorities
such as consulting engineers, transformer manufacturers, the
European Commission, national governments and energy agen-
cies, raw materials producers and semi-fabricators, as well as indi-
viduals concerned with national and European transformer stan-
dards.
We also held discussions with the trade associations responsible for
each point of the supply chain, including utilities, transformer
manufacturers, raw materials producers and semi-fabricators.
A workshop has been organised to discuss the findings of the proj-
ect was held at Harwell, UK, on 23d September 1999. This
brought together delegates from all points of the supply chain,
including raw material producers and semi-fabricators, trans-
former manufacturers, utilities, consultants and energy agencies,
as well as a representative of the European Commission.
Participants were provided in advance with a copy of our draft
report. They confirmed the basic findings of the project, recognis-
ing the potential of energy-efficient transformers to contribute to
global warming goals, and contributed specific additional initia-
tives to overcome the barriers to change,
10. 8
4 THE ROLE OF TRANSFORMERS
4.1 Electricity Supply System
Concepts
Modern electricity supply systems depend on a number of
advances in electrical theory and engineering which were made in
the late 19th century. These include the principle of AC genera-
tion, motors and transformers, the concept of creating inter-
linked high and low voltage networks, and the use of parallel
rather than series connections to supply end-users. Their applica-
tion enabled reliable electricity supply services to be provided to
industry, commercial and domestic customers throughout Europe
and the industrialised world.
Further developments resulted in electricity being generated in
large efficient power stations, far from the point of use.
Generating stations were then linked to each other, and to urban
and industrial centres, through a country-wide network of over-
head conductors and underground cables. This improved the bal-
ance between supply and demand, and further enhanced the qual-
ity of the service. Initially electricity in Europe was produced
mainly from coal and hydro-electric power stations, but the
national networks also proved ideal when nuclear power genera-
tion became feasible.
Losses in electricity supply systems depend on the voltage level.
They are minimised by transmitting electricity at as high a voltage
as possible, consistent with demand load levels, extent of urbani-
sation, etc. Transformers, which initially step up the generation
voltage, and then reduce it to the level required by users, are there-
fore an essential component in transporting electricity economi-
cally from the power station to the final customer.
4.2 Distribution Transformers
In an electricity supply system, the high and low voltage power
networks terminate within a transformer in wound coils, of cop-
per or aluminium. The coils generate a magnetic flux, which is
contained by an iron core. Energy is then transferred between the
networks through this shared magnetic circuit.
The smallest transformers in an electricity supply system, which
provide electricity to commercial and domestic customers, are
described as distribution transformers. Figure 1 shows schemat-
ically the arrangement of the active components of a typical three-
phase distribution transformer as used in Europe. It can be seen
that the iron core of the transformer has three limbs, and that the
Figure 1 Build-up of Three-phase Distribution Transformer
11. 9
HV and LV coils of each phase are wound on the same limb, sep-
arated by insulating material.
4.3 Transformer Losses
The energy losses in electricity transformers fall into two cate-
gories:
l no-load losses or iron losses, which result from energising the
iron core. These are incurred whenever the transformer is cou-
pled to the network, even if no power is being drawn
l load losses which arise from the resistance of the windings,
when the transformer is in use, and from the eddy currents
which flow both in the windings and the transformer housing
due to stray flux. Sometimes referred to as copper losses, or
short circuit losses, as they are measured by shorting the wind-
ings.
The transformers installed in electricity supply systems are
extremely efficient when compared with other machines. There
are no moving parts, and large modern power station and trans-
mission transformers typically have an efficiency above 99.75%.
Distribution transformers are less efficient, but levels can still
exceed 99%.
Despite the high efficiency of individual units, losses occur at each
of transformation steps in an electricity supply network. Even in a
modern network, the losses arising from power transmission and
distribution can amount to as much as 10% of the total electrici-
ty generated. Losses are relatively higher when transformers are
lightly or heavily loaded. This means that there is considerable
potential for energy saving with efficient transformers.
5 ELECTRICITY SUPPLY AND DEMAND
IN THE EU
5.1 Supply System Design
Electricity supply systems are similar throughout the world,
although the voltages used for transmission and supply to the final
customer may vary. In Europe electricity is typically generated at
10-20kV AC in a power station, and stepped up to transmission
voltages of 275-400kV, for transportation by overhead transmis-
sion line or supertension power cable to regional load centres.
Within a region, electricity is transformed to lower voltages for
supply at 110-150kV. This is often the stage at which power-gen-
erating companies sell electricity to local distribution utilities.
Power at 110-150kV is also supplied directly to major industrial
customers, for example chemical works or steel producers, or car-
ried into urban areas for further reduction at system
transformation points to 10-20kV. Smaller industrial consumers
as well as commercial offices, schools, hospitals and public sector
buildings are supplied at this voltage, reducing levels within their
own premises as necessary.
Finally the voltage is further reduced at distribution sub-stations,
close to the point of use, for supplying smaller commercial and
domestic customers at national consumer mains voltages, recently
standardised in Europe at 400/230V. Figure 2 is a simplified rep-
resentation of an electricity distribution system, showing the sup-
ply to industrial, commercial, rural and domestic customers, by
either underground cable or overhead line.
The basic pattern of electricity network design, with four main
operating voltage levels, is now used throughout Europe, irrespec-
tive of the relative utilisation of overhead and underground net-
works. It has been proven to provide a good balance between sup-
ply and demand, and reduce losses to a practical minimum.
The existing systems in most European countries are however
rather more complex. They have been built up over a long period,
and there are a variety of intermediate transmission voltages, such
as 66kV, 50kV. These are slowly declining, but they represent a
considerable proportion of existing networks, and can still provide
the most economical option for system reinforcement and renova-
tion.
A large number of different classes and sizes of transformers are
therefore required in a modern electricity supply network, reflect-
ing the wide range of operating voltages and currents. In addition
to the four main operating voltages, and the intermediate voltages
which have been described above, transformers are also specified
in terms of their capacity. This is the quantity of electricity they
can handle, expressed in volts(amperes (VA). Because the flux and
12. 10
current-carrying capacities of the core and windings are limited,
heavier currents require larger transformers.
5.2 Power Generation and
Distribution Utilities
Utilities produce and distribute over 90% of the total electricity
generated in the European Union. There are approximately 2000
electricity utilities in the EU. They range in size from small town
or rural area systems, controlled by municipal and local govern-
ment, to very large state-owned bodies serving a whole country.
Considerable structural changes are now taking place in the sector,
with a transfer to private ownership, joint ventures across nation-
al boundaries and new investments in power generation as main
trends. Recent privatisation and decentralisation have left only
France and Italy among the major countries in Western Europe
following the traditional pattern of state ownership. Italy has
already started a far-reaching privatisation plan for its national
utility.
The Electricity Directive, which came into force in February
1999, is designed to create an open and competitive market for
electricity in Europe. Member States are required to open up
about 25% of their markets to free competition. These changes
have important implications for the way in which decisions are
made on investments in capital plant such as distribution trans-
formers.
5.3 Non-utility Electricity
Supply
Non-utility electricity supply systems include traction companies
operating electrified railways, metros and tramway systems, large
plants in the chemical, oil and gas and metals industry.
Organisations in this category either generate their own require-
ments, or purchase electricity at high voltage from utilities and
operate their own distribution networks. There is considerable
mining and mineral extraction in Europe, often involving the dis-
tribution of power underground.
Private generation represents less than 10% of total capacity in the
EU. However, generation of electricity on site for non-utility sys-
tems is growing rapidly, frequently using gas as a raw material.
Overall, it is estimated that private generation could reach 20% of
total capacity in the near future. Growth is being assisted by a
number of special factors, including the development of renewable
and combined heat and power technology, improved economics
for gas-based generation, the liberation of tariff controls, and
deregulation of electricity supply.
Figure 2 Electricity Distribution System
Industrial
System transformer
Commercial
Distribution
transformer
Agricultural
Domestic
13. 11
While utilities generally rely on their own engineering staff to set
standards for performance, including energy efficiency, private
sector electricity supply systems are often designed with outside
assistance. The pattern in Europe varies widely. In some countries,
this work is undertaken mainly by firms of management contrac-
tors, or the design staff of a major electrical contractor. Elsewhere,
independent professional consulting engineers are responsible for
design and project management.
5.4 Production Capacity
The installed generating capacity for electricity in the European
Union is about 550GW (Figure 3). Germany and France are by
far the largest producers, accounting for approximately 35% of the
total.
It is estimated that about 60GW of new generating capacity will
be added in the period to 2010, during which time about 15GW
will be decommissioned. Two-thirds of new investment is planned
to be based upon gas, particularly in Italy, France and the
Netherlands. Much of this will be installed by independent gener-
ators for their own use and resale, or for the co-generation of heat
and power. The remainder of the predicted capacity increase is
mostly new nuclear power stations, in France and Finland.
5.5 Demand and Growth Rate
Electricity consumption in the European Union is nearly
2,500TWh per year. Four countries, Germany, France, the UK
and Italy, account for approximately two-thirds of the total (Figure
4). Population levels, size of economy, degree of industrialisation,
the volume of heavy industry, climate, prices and competition
from other fuels all contribute to the pattern of consumption in
individual countries.
The demand for electricity in Europe grew rapidly in the 1960s
and 1970s, in line with increasing industrialisation, rapid eco-
nomic growth rates, the completion of national networks and the
development of nuclear power. The rate of increase in consump-
tion has slowed dramatically in the 1990s. The current annual
growth rate is 1.7%, compared with 4.3% in the 1970s and 2.7%
in the 1980s.
The power industry has found it difficult in the past to forecast
demand, but the International Union of Producers and
Distributors of Electrical Energy (UNIPEDE), the international
utilities’ industry association, predicts that growth in the EUR-21
(those shown in Figure 4 together with the Czech Republic,
Hungary, Norway, Poland, Slovakia and Switzerland) will be 1.7%
per year over the next 15 years.
The fastest growing end-use sector is expected to be services, aver-
aging 2.4% per year, and transport, growing at 1.6% per year.
Figure 3 Maximum Net Generating Capacity at End Year, European Union (MW)
Type of origin 1980 1990 1995 1996 2000 2005 2010
Nuclear 40.106 114.837 119.581 120.710 122.427 121.062 119.232
Subtotal 40.106 114.837 119.581 120.710 122.427 121.062 119.232
Conventional thermal
l coal 101.847 117.090 115.132 114.638 110.928 103.032 107.552
l brown coal 17.743 18.535 30.226 27.442 28.647 28.993 30.332
l oil 76.309 59.507 53.339 51.970 36.023 33.870 27.785
l natural gas 33.529 43.302 63.850 73.991 105.230 116.890 134.574
l derived gas 3.500 2.314 2.695 2.756 5.178 4.455 4.378
Subtotal 232.928 240.747 265.242 270.797 286.006 287.240 304.620
Hydro
l gravity scheme 67.846 76.902 80.064 80.387 82.985 84.225 86.755
(of which run of river) 15.470 16.945 17.648 17.746 18.075 18.261 18.666
l pumped + mixed 20.284 32.303 34.586 34.597 34.909 36.109 37.290
Subtotal 88.130 109.205 114.649 114.983 117.893 120.334 124.045
Other renewables 1.830 4.602 6.734 6.815 13.958 20.561 25.747
Gas turbines, diesel, etc. 12.922 17.297 21.208 21.632 20.824 21.306 24.067
Not specified 6.186 7.865 6.579 9.335 12.330 18.547 22.054
Subtotal 20.938 29.764 34.521 27.782 47.112 60.414 71.868
TOTAL 382.102 494.553 533.993 544.272 573.438 589.050 619.765
14. 12
Major planned investments include a US$1.3 billion HVDC
power bridge to link Western and Eastern Europe.
A number of countries in Western Europe have published formal
plans for their electricity industry. Some utilities have also pre-
pared detailed forward plans. Typically, these address issues such as
electricity consumption, maximum demand, regional trends and
growth rates, major planned generation and transmission invest-
ments.
Increasingly, national and utility plans also cover energy efficien-
cy. As far as we have been able to ascertain, there have been no
statements by organisations in the EU of targets to reduce losses
through the use of energy-efficient distribution transformers. In
practice there are considerable problems in estimating the poten-
tial for savings, discussed in Sections 10.5 and 11.
5.6 Representation
The electricity utilities in most European countries are represent-
ed by one or more industry associations. These are co-ordinated at
European level by EURELECTRIC, which was created in 1989.
EURELECTRIC has recently formed a joint secretariat with
UNIPEDE.
Technical issues, and other developments associated with the oper-
ation of electricity supply systems, are handled by a number of
international representative bodies. These include the
International Conference of High Tension Networks (CIGRE)
and the International Conference of Distribution Networks
(CIRED). A further body, the Union for the Co-ordination of the
Production and Transport of Electricity (UCPTE) helps co-ordi-
nate power transmission in Continental Western and Central
Europe.
The organisations directly responsible for the technical specifica-
tions of distribution transformers are described in Section 7.4.
5.7 Regulation
The decentralisation and privatisation of utilities in EU countries
has resulted in the creation of independent regulatory bodies at
national level. These cover issues such as price control, investment
levels for new plant and equipment, safety, environmental impact.
These responsibilities can be undertaken by a government depart-
ment, usually the ministry responsible for energy policy, or by the
creation of an independent agency.
The regulatory bodies have varying degrees of control over energy
efficiency. Some allow utilities to levy their customers to help fund
for environmental spending. Others can reward utilities with
rebates or capital allowances for energy efficiency or environmen-
tal improvements and investments.
The Electricity Directive, described above, establishes rules for the
generation, transmission and distribution of electricity. The
implementation of the Directive is contributing to the growth of
the regulating process. A further item of European Community
legislation, the Utilities Directive, covers certain aspects of the
electric power industry operations. Energy efficiency is not includ-
ed.
Figure 4 Electricity Consumption, European Union, 1980-2010 (TWh)
Actual Forecast Implied Average Annual Increase (%)
Year 1980 1990 1995 1996 2000 2005 2010 1980- 1990- 1995- 1996- 2000- 2005- 1996-
1990 1995 1996 2000 2005 2010 2010
Austria 36,3 46,9 51,0 52,3 56,6 62,1 67,3 2,60 1,69 2,55 1,99 1,87 1,62 1,82
Belgium 47,7 62,6 73,5 75,3 81,2 89,0 94,5 2,76 3,26 2,45 1,90 1,85 1,21 1,64
Germany 351,0 415,0 493,0 500,0 512,0 531,0 547,0 1,69 3,50 1,42 0,59 0,73 0,60 0,64
Denmark 23,9 30,8 33,7 34,8 35,8 36,8 37,7 2,57 1,82 3,26 0,71 0,55 0,48 0,57
Spain 102,0 145,4 164,0 169,0 188,2 218,2 246,7 3,61 2,44 3,05 2,73 3,00 2,49 2,74
Finland 39,9 62,3 69,0 70,1 78,0 85,4 92,1 4,56 2,06 1,59 2,71 1,83 1,52 1,97
France 248,7 349,5 397,3 415,2 444,0 479,0 516,0 3,46 2,60 4,51 1,69 1,53 1,50 1,56
Greece 21,9 32,5 38,8 40,5 47,2 54,2 63,4 4,03 3,61 4,38 3,90 2,80 3,19 3,25
Ireland 9,5 13,0 16,4 17,6 21,7 26,8 32,1 3,19 4,76 7,32 5,37 4,31 3,68 4,39
Italy 179,5 235,1 261,0 262,9 296,0 330,0 360,0 2,74 2,11 0,73 3,01 2,20 1,76 2,27
Luxembourg 3,7 4,4 5,1 5,1 5,6 5,9 6,3 1,75 3,00 0,00 2,37 1,05 1,32 1,52
Netherlands 59,7 78,0 89,6 93,5 101,2 110,9 121,5 2,71 2,81 4,35 2,00 1,85 1,84 1,89
Portugal 15,3 25,1 29,3 30,9 36,5 42,8 49,0 5,07 3,14 5,46 4,25 3,24 2,74 3,35
Sweden 94,1 139,9 142,4 142,7 145,5 147,8 152,3 4,05 0,35 0,21 0,49 0,31 0,60 0,47
UK 264,8 309,4 330,7 343,9 360,8 393,0 425,7 1,57 1,34 3,99 1,21 1,72 1,61 1,54
EUR 15 1.498,0 1.949,9 2.194,8 2.253,8 2.410,3 2.612,9 2.811,6 2,67 2,39 2,69 1,69 1,63 1,48 1,59
15. 13
5.8 Environmental Impact
Power generation is the largest contributor to toxic emissions and
global warming in Europe. Carbon dioxide emissions are forecast
to increase rapidly in the period to 2010, particularly in Italy,
where they are expected to rise by one-third, with investment in
gas generation plant a major contributor. Releases of sulphur and
nitrogen oxides in Europe are forecast to fall.
Initiatives to reduce toxic emissions, and meet agreed climate
change and global warming targets, are often similar to those
aimed at improving energy efficiency. There has been considerable
discussion in EU countries about the use, by the either European
Commission or national governments, of economic instruments,
e.g. taxes or levies, to regulate emissions and global warming.
These include the imposition of a carbon tax to increase the cost
of burning fossil fuels.
5.9 Ener gy Losses
Detailed figures of estimated and forecast energy losses for EU
countries in the period 1970-2010 are provided in Appendix A.
Total losses for the EU are running at about 150TWh, represent-
ing approximately 6.5% of total power generated, or the output of
15 large power stations. However, losses have fallen steadily, from
about 7.5% in 1970.
Some examples of the losses in the power systems of a number of
Western European countries are shown in Figure 5. There is a sig-
nificant variation between countries in reported electricity system
losses, ranging between 4-11%. Obviously, distribution losses
could be expected to be higher in small lightly populated rural
countries than in major industrialised countries. There is some
doubt about whether losses are always measured on a consistent
and comparable basis.
Among major countries, Germany reports exceptionally low loss
levels, has made significant progress in the period since 1970, and
set ambitious targets for the next 15 years. In contrast the UK,
France and Italy are showing persistently high loss levels, and with
no foreseen or planned improvement.
In Central Europe, losses in the system are reported to be much
higher, up to twice the average for Western Europe. Some indica-
tion of this is provided by data from Germany, where losses in the
former DDR were reported at 10.0% in 1992, compared with
4.7% for West Germany, but had improved to 9.0% by 1995.
5.10 Distribution System
Losses
It is estimated that over 40% of the total losses in an electricity dis-
tribution network are attributable to transformers (See Section
11.1). The remainder is mainly in the cable and overhead con-
ductor system.
Modern electricity supply grid networks are extremely complex.
Transformers may operate at close to full load for most of the year,
or else be very lightly loaded, either to provide spare capacity or as a
result of lower than expected growth in demand. Distribution trans-
former losses are discussed in more detail in Sections 10.1-10.4.
Figure 5 System Losses - European Utilities (%)
16. 14
There is also a need to balance the loading of the network as far as
possible, and provide alternative routes to the major points of
demand. Transformers are sometimes moved between sites to meet
changed load demands. Some techniques now used in network
management, for example deliberately running transformers at
above their rated capacity, can be expensive in terms of losses.
The lack of reliable data also applies to individual utility losses, as
well as the national loss statistics described in Section 5.9. Some
utilities produce figures for distribution system losses (See Figure
6). Utilities may be rewarded by a regulator or national govern-
ment for reducing losses, for example by environmental subsidies
or tax concessions.
Unfortunately, these loss figures are produced by various empiri-
cal calculations, and not directly by metering or data logging.
They cannot be reconciled with generation or engineering data, or
by comparing energy purchases with sales. For this reason, it is not
possible to demonstrate, for example, the incremental savings
which a utility would achieve by the installation of a single ener-
gy-efficient transformer.
Figure 6 Distribution Losses for LV and HV Customers, United Kingdom Ditribution Utilities (%)
Utility 1990/1991 1991/1992 1992/1993 1993/1994 1994/1995 1995/1996 1996/1997 1997/1998
Eastern 7,0 7,0 6,8 6,5 6,7 6,9 7,1 7,0
East Midlands 6,6 6,5 6,7 6,8 6,0 6,1 6,1 6,1
London 7,8 7,2 7,0 7,0 7,1 6,7 7,1 6,8
Manweb 9,8 9,1 8,7 8,7 8,1 8,8 8,8 9,0
Midlands 6,2 5,9 5,7 5,5 5,5 5,5 5,6 5,5
Northern 7,5 7,6 6,8 7,2 6,1 6,8 6,9 6,7
Norweb 7,1 7,1 6,3 6,3 6,4 4,8 5,0 5,7
Seeboard 7,9 7,7 7,6 7,5 7,5 7,1 7,6 7,7
Southern 7,1 7,2 7,1 7,0 7,0 7,2 7,2 7,2
Swalec 8,9 8,4 8,1 7,0 7,0 6,7 8,0 6,9
Sweb 8,6 8,5 8,5 8,3 7,3 7,2 7,9 7,3
Yorkshire 6,3 6,3 6,2 6,2 6,5 6,5 6,5 6,5
Scottish Power 8,5 7,2 7,7 8,1 8,0 6,7 7,2 7,2
Hydro-electric 9,5 8,9 9,0 9,1 9,1 9,0 9,0 9,1
Average 7,6 7,2 7,1 7,0 6,9 6,7 6,9 6,8
17. 15
6 DISTRIBUTION TRANSFORMER
INSTALLATIONS
6.1 Ownership
Electricity utilities are estimated to own and operate about 70% of
the total population of distribution transformers in the EU, and
represent a similar proportion of the market for new units. Major
utilities also control most of the larger items of installed genera-
tion and transmission plant in Europe, but the distribution trans-
formers can be owned by the host of regional and municipal dis-
tribution utilities. Changes in utility ownership, for example as a
result of privatisation, usually result in changes in the ownership
of the transformers installed in the network.
Transformer ownership outside the utility sector is shared between
the non-utility electricity supply systems, described in Section 5.3,
and the medium-sized customers for electricity. These include the
proprietors of small factories, office blocks, supermarkets, schools,
hospitals, apartments, hotels etc. They typically purchase power
from a utility at 10-20kV, and own the distribution transformer
and associated switchgear which undertakes the final step in
reducing the voltage to 400/230V.
6.2 Population
The population of distribution transformers installed in European
electricity utility and private sector networks is estimated to be
about four million units. Statistical records are poor, particularly
for privately owned installations, but the data which is available
suggests that the total is broken down by size and type of con-
struction approximately as follows:
Source: Utility statistics, ECI estimates
Non-utility distribution transformers account for about 30% of
the total population, but a much higher proportion, possibly
around 50%, of the total installed capacity. Non-utility trans-
formers tend on average to be larger than those operated by elec-
tricity utilities.
6.3 Transformer Age Profile
The distribution transformers which have been installed in the EU
in the post-War period, have shown great reliability. They have no
moving parts, and are designed for a lifetime of 20-30 years, but
have successfully operated for much longer. A rough indication
from comparing the distribution transformer annual sales esti-
mates in the EU, (approximately 150,000) with the transformer
population (approximately 4 million) suggests a lifetime for each
unit, in a market which is relatively static, of 30-40 years.
Life spans have also been extended by the fact that many trans-
formers installed in the 1960s, when the growth of demand for
electricity was at a peak, were lightly loaded to allow for future
expansion, thus reducing the effects of heating, cooling stresses
and insulation ageing. Combined with lower investment levels to
meet new demand, the result is a skewed age profile for the pop-
ulation of distribution transformers currently installed in Europe.
Although modern transformers can be more efficient in terms of
energy losses, older transformers have a reasonable performance.
Their costs are completely written off, they are compatible in engi-
neering terms with the associated circuit breakers and fuse-gear,
and provide little incentive for replacement. Cases of transformer
damage and failure, major network redesign schemes, and exces-
sive transformer noise levels, represent the main opportunities for
reinvestment.
6.4 Failures
Only limited information is available about the transformer fail-
ure pattern in Europe. Several studies have been undertaken, but
the results are rather inconclusive. A 1983 survey based on 47,000
transformer-years of service in 13 European countries estimated
the mean-lifetime-between-failures (MLBF) of installed trans-
formers to be 50 years, and showed design defects, manufacturing
problems and material defects to be the main causes of failure.
The same project identified windings and terminals to be the
components most likely to cause failure in service. Failures in coils
using jointed conductors, built in earlier years, have caused some
problems. A high proportion of failures in pole-mounted distri-
bution transformers result from lightning strikes.
Unacceptable noise levels, and incompatibility with more modern
circuit breakers and fuse-gear, are often cited as being more impor-
tant influences on renewal programmes than complete break-
down. One source reports the failure rate for installed distribution
transformers at approximately 0.2% per year.
Table A
Distribution transformer population, European Union
Category Primary No of Total
Voltage (kV) Transformers Capacity
(GVA)
Liquid-cooled, <250kVA 20,10 etc 2,000,000
Liquid-cooled, 250kVA and above 20,10 etc 1,600,000 1,600
Dry-type, cast-resin 20,10 etc 400,000
18. 16
6.5 Investment Programmes
There is evidence of considerable remaining spare capacity in the
existing population of distribution transformers in the EU. Load
diversity factors, load monitoring and overload characteristics are
now much more sophisticated than in the past. These factors tend
to depress further the installation rates for new transformers.
A number of new electronic control technologies for power sup-
ply systems are being introduced to optimise the use of existing
hardware, as an alternative to installing new plant, although these
mainly apply to the HV system rather than the distribution net-
work. Condition monitoring of transformers, to provide warnings
of overload and failure, is contributing to transformer lifetimes.
Some utilities are introducing demand side management (DSM)
techniques, to reduce the load on the generation and distribution
system. These trends tend to work against investment in new
transformers.
However, the existing population of distribution transformers is
ageing, with many transformers over 40 years old. The age profile
of the power transformer population in Europe is widely regarded
as giving cause for concern.
Some EU Member States have made attempts to direct utility
funds to distribution network renovation, but these have not been
generally successful. Newly privatised utilities are reported to show
less interest in longer-term problems, and demand more rapid
paybacks, than the public sector network operators they have
replaced. However older transformer installations are being grad-
ually renewed, and possibly 60-70% of current spending is associ-
ated with replacement.
7 THE EU DISTRIBUTION TRANS-
FORMER MARKET
7.1 Market Size
Figure 7 shows the estimated breakdown of 1997 sales of distri-
bution and smaller systems transformers in the EU by number of
units, size and sales value. Smaller transformers, below 650kVA,
account for about 85% of sales and 55% of value.
There is a sharp contrast in size and sophistication between con-
ventional distribution transformers and the larger units, between
1,600-10,000kVA, used in the primary distribution network and
for supplying larger consumers. Distribution transformers account
for about two-thirds of sales value, but represent 95% of total
numbers.
7.2 Growth Rates
The European market for distribution transformers has been
depressed since the early 1980s, and at present, the size of the mar-
ket is reported to be approximately static. This reflects the age pro-
file and investment levels discussed in Section 6.
The future impact of power industry development on distribution
transformer volumes is difficult to assess. The spare capacity in the
installed population of distribution transformers is considerable.
Electricity generation based upon natural gas or renewables,
including combined heat and power installations, at sites close to
the point of use, suggests a reducing need for transmission across
long distances, but will increase the volume of smaller transform-
ers in the network.
The age of the installed population, and the replacement of units
contaminated with toxic coolants, represents a possible opportu-
nity. Some specific programmes to replace distribution plant more
frequently have been mentioned.
On balance, we forecast that distribution transformer sales will
remain constant in Europe in the next 10 years. The increase in
private generation and the need for replacement of older units is
likely to be balanced by continuing overall low growth rates in
electricity demand, and the more sophisticated operating tech-
niques for managing the low-voltage network.
19. 17
7.3 Purchasing Policies and
Procedures
Distribution transformers are usually built against a specific cus-
tomer order. The large number of operating voltages and capaci-
ties in grid networks means that it is quite common in Europe for
a single utility to be buying 50 or more different types and sizes of
power systems transformer.Electricity utilities may place contracts
for their transformer purchases for a year or more in advance. A
typical requirement would be several hundred units. In this case,
a contract is negotiated, based on tenders received from a short-list
of approved suppliers. Public sector utilities in the European
Community must advertise major contracts Europe-wide.
In the tender, utilities either specify maximum levels for load and
no-load losses, or use loss capitalisation, leaving it to the trans-
former manufacturer to design the optimum transformer in terms
of minimum total cost (purchase price + cost of losses). The for-
mer is common practice in France, Belgium and Germany. Loss
capitalisation, on the other hand, is commonly used in UK,
Scandinavia and Switzerland, among others. The use of loss capi-
talisation tends to lead to higher efficiency transformers (cf
Scandinavia, Switzerland) but not necessarily (cf UK). These prac-
tices are further explained in sections 10.5 and 10.6.
7.4 Standards and Designs
There are European specifications for power systems transformers,
which set standards for performance, including power losses.
These have consolidated earlier national standards, and are com-
patible with International Electrotechnical Commission (IEC)
world standards. They have been developed by the European
Committee for Electrotechnical Standardisation (CENELEC), in
consultation with UNIPEDE.
The distribution transformer standards applicable within the EU
are described in detail in Section 10.1. Non-utility outdoor distri-
bution transformers are superficially very similar to utility trans-
formers, but the specifications and sizes may be different. For
example, many European railways are supplied at 15kV, 162/3Hz,
single phase. Mining transformers are often flameproof.
Distribution transformers with conventional oil cooling and
installed on indoor sites, for example the basement of a large
commercial building, are considered to pose a possible fire risk.
They are required by the building regulations in many EU coun-
tries either to use non-flammable coolants, or to be dry-type,
without coolants. Polychlorinated biphenyls (PCBs), the principal
coolant used in the past, have been linked with the production of
highly toxic chlorine compounds, mainly dioxins, at high temper-
atures. Non-toxic coolants are now available, and cast resin clad
transformers offer an alternative to dry-type construction.
Figure 7 European Distribution Transformer Production
20. 18
Reliability is reported to be the main factor influencing the way in
which distribution transformers are chosen by consulting engi-
neers and non-utility sector customers. Their installations are rel-
atively small in scale, and unlike utility networks may have only
limited back-up in the case of transformer failure.
8 TRANSFORMER MANUFACTURE IN
THE EU
8.1 Industr y Over view
The EU electricity systems transformer industry is an important
component of the electrical engineering sector, with an output
valued at approximately €3 billion per year. The European trans-
former manufacturers are major exporters of transformers world-
wide, and the leading producers have established a number of
overseas manufacturing operations. These factories mainly supply
local markets, and replace earlier export business, but in some
cases are capable of building transformers for sale world-wide,
complementing the resources of the parent company. EU manu-
facturers have moved rapidly to establish a position in Central
Europe, mainly by the acquisition of existing companies.
Following substantial growth in post-war years, the industry has
been forced to contract and rationalise in the period since 1980,
in the face of slowing growth rates in electricity demand, the com-
pletion of national electricity supply grid networks, and the long
installed life span of transformers in service.
Since 1990 transformer demand in Europe has stabilised and
remained reasonably steady, although at lower levels, and compe-
tition is still intense. This is reflected in selling prices, continuing
losses by some companies, further closures and mergers, and a
Figure 8 Typical Distribution Transformer Parameters
RATING kVA 100 400 1600
HV kV 20 10 20
LV V 400 400 690
LOSS-LEVEL HD428 A-A' C-C' A-AMDT C-AMDT A-A' A-A' C-C' C-C' A-AMDT C-AMDT A-A' A-A' C-C' C-C' A-AMDT C-AMDT
NO-LOAD LOSSES W 320 210 60 60 930 930 610 610 150 160 2.600 2.600 1.700 1.700 380 420
LOAD LOSSES W 1.750 1.475 1.750 1.475 4.600 4.600 3.850 3.850 4.600 3.850 14.000 14.000 17.000 17.000 17.000 14.000
TOTAL MASS kg 520 650 740 770 1.190 1.200 1.300 1.400 1.590 1.750 3.300 3.240 3.370 3.680 4.310 4.550
CORE MASS kg 150 220 220 225 435 440 450 540 570 600 1.100 1.210 1.200 1.460 1.400 1.550
FLUX DENSITY T 1,83 1,45 1,35 1,35 1,83 1,84 1,65 1,6 1,35 1,35 1,84 1,84 1,7 1,6 1,35 1,35
CONDUCTOR MATERIAL Cu/Al Cu Cu Cu Cu Cu Al Cu Al Cu Cu Cu Al Cu Al Cu Cu
WINDING MASS kg 85 115 130 155 203 145 350 220 360 450 505 295 725 465 1.120 1.225
CURRENT DENSITY A/mm2 2,9 2,3 2,35 2 2,9 1,55 2,1 1,1 2,3 1,85 3,65 2 2,75 1,4 2,45 2,1
HEIGHT mm 1.300 1.300 1.300 1.300 1.330 1.420 1.350 1.550 1.400 1.400 1.890 1.820 1.860 2.000 1.870 1.900
LENGTH mm 890 830 1.050 1.100 1.320 1.100 1.010 1.130 1.340 1.240 1.820 2.000 1.710 1.850 1.770 1.770
WIDTH mm 600 560 620 620 800 840 800 780 770 800 1.180 1.280 1.100 1.020 1.320 1.200
EFFICIENCY (*) % 97,94 98,32 98,19 98,46 98,62 98,62 98,89 98,89 98,81 99,00 98,78 98,78 99,02 99,02 98,91 99,10
SOUND POWER dB(A) 57 36 59 59 61 68 56 58 68 68 68 72 63 63 76 76
UNIT COST BEF 102.400 112.900 139.400 143.900 176.900 172.900 196.900 189.800 257.100 274.200 391.000 373.200 415.800 408.200 607.100 626.500
UNIT COST % 90,7 100 123,5 127,5 93,2 91,1 103,7 100 135,5 144,5 95,8 91,4 101,9 100 148,7 153,5
(*) at full load and cos phi = 1
21. 19
determination on the part of companies to secure orders, even at
very low margins, in order to survive.
Competition from companies in Central, Eastern and Southern
Europe, where labour costs are lower and home markets are
depressed, is adding to the pressure, as is the business in second-
hand and refurbished transformers. There are however some signs
that volumes may be beginning to improve.
8.2 Industr y Structure
Distribution transformers, together with special transformers of
similar size used for applications such as power rectification, elec-
tric furnaces, electrolytic refineries etc, are produced by about 200
companies in the Europe. A considerable number of additional
companies work only on transformer repair and refurbishment,
although they have the skills to build new units.
We estimate that over 200 transformer factories have closed since
the mid-1960s. Increased productivity, combined with pressure
from imports and moderate forecasts for growth, mean that fur-
ther rationalisation can be expected.
Following a major merger in 1999, creating a clear leader in the
sector, the European market is now dominated by 6 producers.
Two of these are part of major electrical engineering groups,
organisations manufacturing a comprehensive range of products
and systems for power supply and heavy electrical engineering,
including steam and gas turbines, generators, transformers and
motors, switchgear and transmission equipment.
Together the major producers account for over 50% of the total
EU output of distribution transformers. Additional three compa-
nies, all capable of building both distribution transformers and
larger units, are responsible for a further 10% of output.
8.3 Manufacturing Investment
Sophisticated mechanised or flow-line production is not usual in
distribution transformer factories, except for the smallest sizes of
pole-mounted units. There are, however, some examples in
Europe of high levels of investment and automation. Ground-
mounted distribution and larger transformers are mostly built in
bays or on stands, reflecting the very wide range of standards and
sizes involved.
Utility customers often let an annual contract for a number of dis-
tribution transformers, typically several hundred units. Labour
content and skill levels are high, with a great deal of specialised
knowledge and experience associated with design and testing.
This pattern of manufacture and ordering is reflected in the struc-
ture of the industry. The larger companies, which dominate the
sector, have been built up partially by acquisition and rationalisa-
tion, but they continue to operate a number of separate trans-
former factories. Each of these will have its own product range,
specialist skills and customer base. Typically an independent
power systems transformer producer, or a transformer factory
within a large group, has a volume of output in the range €20-100
million per year.
8.4 Product Ranges
An example of the product range of a typical major European
transformer manufacturer is as follows:
l oil-filled distribution transformers from 15kVA to
3,150kVA/36kV
l cast resin transformers up to 10MVA/36kV
l power transformers from 4MVA to 500MVA/500kV
l autotransformers up to 400MVA/500kV
l HVDC transformers up to 275MVA/500kV.
An overview of typical parameters for the distribution transform-
ers used in European electricity supply networks is shown in
Figure 8. This provides a further indication of the wide range of
products manufactured, in terms of physical size, use of materials
and price.
A standard ground-mounted distribution transformer costs about
€10,000 and weighs four tonnes. A typical distribution trans-
former factory could build a few thousand of these units per year.
Distribution transformers factories are usually dedicated to manu-
facturing these products for electricity supply industry and non-
utility customers. Manufacturers do not normally build other
equipment, such as large power systems transformers or small
transformers, on the same site. Some smaller companies produce
only pole-mounted transformers. Non-standard power transform-
ers, such as flameproof units, electric locomotive transformers or
marine power supplies are often produced in specialist facilities.
8.5 Expor ts
Exports by European transformer manufacturers are running at
about €1000 million per year. Export volumes help to balance the
workload of transformer factories, and are particularly important
when domestic demand is depressed.
22. 20
Trade within Europe is increasing as the power supply industry is
progressively deregulated. This new competition is often not wel-
comed by those manufacturers who have had to face the decline in
industry size, but were previously protected in their home markets
by utility purchasing policies and national specifications.
Exports to non-European destinations account for over one-quar-
ter of the total output. The main overseas markets for power sys-
tems transformers manufactured in Europe are the United States,
India, Saudi Arabia, Indonesia and China. A proportion of this is
associated with turnkey projects undertaken by major electrical
engineering groups.
8.6 Repair and Maintenance
Repair and maintenance now represent a considerable proportion,
up to 20%, of the activities of some transformer manufacturers.
This ratio is increasing as the population ages. Rebuilding pro-
vides an opportunity to improve efficiency at a lower cost than
purchasing new machines.
Special skills are required to deal with the PCB contamination
which affects many older transformers installed in the EU, even
those using mineral oil as the coolant. It is not clear in some cases
how this contamination has occurred, but it may result from poor
housekeeping in past manufacturing or maintenance routines.
8.7 Representation
There are national trade associations representing the transformer
manufacturers in larger European countries, usually linked to the
national electrical engineering trade body. The trade association
for the European transformer industry is the Committee of
Associations of European Transformer Manufacturers
(COTREL), which links the national trade associations. The
members of COTREL are shown in Appendix B.
Non-members of COTREL could represent a further 20-30% of
total production volume. COTREL also takes responsibility for
transformer industry relationships with the European
Commission, through the national association in Belgium
(Fabrimetal).
COTREL meets three times per year, when an agenda of issues is
discussed by the executive and members. Statistics are also collect-
ed on transformer production. COTREL report that 2-3 years ago
a working group was set up to consider the problem of older trans-
formers and possible replacement initiatives. It was however aban-
doned.
9 DISTRIBUTION TRANSFORMER
TECHNOLOGY
9.1 Design Concepts
Transformer design is extremely specialised, and requires a capable
and experienced design team. Transformers are manufactured
against specific customer invitations to tender, taking into account
the following basic parameters:
l flux density (or induction), a measure of the loading of the iron
core. Each magnetic steel has its typical inherent core loss, direct-
ly related to its flux density. Once above the saturation induction
of the steel, the flux will leave the core and no-load losses are no
longer under control. Maximum flux density should therefore be
limited to well below this saturation point. Energy-efficiency can
be improved by selecting better performing, lower core loss
steels, or by reducing flux density in a specific core by increasing
the core size
l current density in the copper windings. Increasing conductor
cross-section reduces the current density. This will improve ener-
gy efficiency, but also result in higher cost. Because copper loss-
es are dependent on the loading of the transformer, it is neces-
sary to consider how the unit is to be installed and used in prac-
tice
l iron/copper balance. The balance between the relative quanti-
ties of iron and copper in the core and windings. A “copper-rich”
unit has a high efficiency across a wide range of load currents. An
“iron-rich” unit has a lower initial cost price, and may be more
economical when transformers are expected to be lightly loaded.
These basic considerations must then be combined with a wide
range of other factors, to enable a competitive tender to be sub-
mitted to the customer. Copper and iron prices are continually
changing, and this can affect the balance between the two materi-
als.
A variety of proprietary steels are available for building the core,
and the techniques to be used for the construction of the trans-
former core, windings, insulation and housing need to be decid-
ed. Alternative materials, such as aluminium coils or pre-formed
copper windings, could be considered.
The energy efficiency of a distribution transformer, in terms of
losses, is usually specified by the customer. These, and other fac-
tors directly associated with energy efficiency, are discussed in
Sections 10.1-10.4.
23. 21
9.2 Transformer Steels
The energy efficiency of distribution transformers is fundamental-
ly dependent on the type of steel used for building the transformer
core. More specialised steels, particularly suitable for distribution
and larger transformers, have developed in a number of stages.
(Figure 9).
Thin hot-rolled steel sheet, with a silicon content of about 3%,
became the basic material for fabricating electromagnetic cores in
about 1900. Individual sheets were separated by insulating layers
to combine low hysteresis losses with high resistivity. Cold rolling
and more sophisticated insulation techniques were progressively
developed.
Grain-oriented silicon steels, in which the magnetic properties
of transformer steels are improved by rolling and annealing, to
align the orientation of the grains, became available in the mid-
1950s.
Various processing and coating techniques, combined with a
reduced silicon content, were incorporated into high permeabili-
ty grain-oriented steels, about 10 years later. During the 1980s,
techniques were introduced for domain refinement, reducing
domain width by mechanical processes, principally laser-etching.
A recently developed core material, amorphous iron, represents a
significant new advance in transformer steels. Amorphous iron is
produced by rapidly cooling molten metal into a very thin ribbon
with a non-crystalline structure.
At the same time other technology advances have progressively
improved the performance of the steel used in distribution trans-
former manufacture. These include rolling and coating technolo-
gy, reduced gauge (thickness), material purity, dimensional toler-
ances, internal and surface stresses and tension. The various mate-
rials, their properties, and the extent to which they are used, are
described in more detail in Sections 9.3-9.6.
9.3 Grain-oriented Steels
Conventional grain-orientated (CGO) steels are rolled from sili-
con-iron slabstock, and coated on both sides with a thin layer of
oxide insulating material to reduce eddy-currents. They are sup-
plied in Europe in about 10 standard thickness. The European
standard, EN10107, reflects the international IEC 60404 stan-
dard, and describes a range of gauges from 0.23-0.50mm (previ-
ously M3-M7, a nomenclature which is recognised world-wide).
Figure 9
Development Stages, Transformer Steels
24. 22
CGO steels remain the standard raw material for distribution
transformer manufacture in Europe. They are estimated to account
for over 70% of the total steel consumption in distribution trans-
former production, estimated at about 100,000 tonnes per year.
Demand is still very much skewed to the thicker gauges. Thinner
gauge CGO and other more sophisticated raw materials are con-
siderably more expensive, reflecting higher capital investment and
technology levels, as well as additional processing steps. Core pro-
duction costs are also higher.
High permeability steels are manufactured to the same European
Standard as CGO, and are available in about five gauges ranging
from 0.23-0.30mm. They account for about 20% of total con-
sumption in transformer manufacture.
9.4 Domain Refined Steels
A further reduction of losses is achieved by domain limitation.
Domain refined steels are produced mainly by proprietary laser
etching processes. Together with grain-oriented steel, they offer
material with specific losses ranging from about 0.85-1.75W/kg at
1.7T/50Hz for distribution transformer manufacture.
Commercially available domain-refined steel is typically 0.23mm
thick. Together with amorphous iron, see below, it has a market
share in Europe for transformer manufacture of about 10%.
9.5 Amorphous Iron
Distribution transformers built with amorphous iron cores can
have more than 70% reduction in no-load losses compared to the
best conventional designs. There is only one known producer
world-wide of amorphous iron material suitable for distribution
transformer manufacture.
Amorphous iron became commercially available in the early
1980s. It is reported to have been used in the construction of sev-
eral hundred thousand distribution transformers in the US, Japan,
India and China.
European experience of manufacturing and installing amorphous
iron distribution transformers in the EU has been very limited
(See Section 10.5) This is partly due to network design character-
istics which differ from US and Japanese practice. However a very
large (1,600kVA) amorphous iron three-phase distribution trans-
former has recently been built and installed in the EU.
9.6 Future Developments
Research and development on magnetic steels is vigorously pur-
sued world-wide. The licensing of new processes has been
extremely prevalent in this sector for many years.
Distribution transformers appear to represent a poor return on
recent development effort, with the possible exception of amor-
phous iron, because of the competitive nature of the market.
However new magnetic steel developments also benefit from other
applications, notably electric motors and small transformers.
Future emphasis on energy efficiency and environmental impact
could change this picture.
Among areas of interest are:
l the ending of certain patents on amorphous iron processes,
which could encourage other producers to enter the market
l the adoption of the design of amorphous iron transformers to
European practice (i.e. use a three legged Evans-core design for
Dy-connected transformers, resulting in reduced length, cost
and noise)
l mechanical or thermal processes other than laser etching for
domain limitation
l the use of thinner steels. Magnetic steels with gauges as low as
0.05mm are being offered in narrow strip for small transformers
and coils. For larger transformers 0.18mm steel is available, but
both raw material and core fabrication costs rise very rapidly as
the gauge is reduced.
9.7 Conductor Developments
The conductor materials for winding the coils of distribution
transformers are supplied in the form of wire, narrow strip or
sheet. They have not experienced the same significant step changes
in recent years as core steels. The main developments have been:
l the availability of copper and aluminium wire-rod produced by
continuous casting and rolling (CCR) processes, combined with
mechanised handling techniques. This has enabled semi-fabrica-
tors to offer wire and strip in much longer lengths than was pre-
viously possible, increasing transformer reliability. The welded or
brazed joints in strip, which were inevitable in rod produced
from wire-bar, created weak points in the finished coils
l both copper and aluminium are now available in wide sheet and
foil form with high dimensional tolerances. Sheet has extensive-
ly replaced strip for the LV windings of distribution transform-
ers
25. 23
l continuous cold rolling processes are now being introduced for
conductor strip production. This potentially offers better avail-
ability, and more consistent quality, than is available from drawn
strip.
Potential developments include the shaping of conductors to
improve the mechanical strength of the completed coil, and more
compact fabrication of coils.
9.8 Other Materials
Developments have also taken place in the other components used
in distribution transformer manufacture. The most significant are
the development of flame-proof coolants to replace PCBs, and the
use of cast resin encapsulation as an alternative to dry construction
in non-liquid cooled transformers (See Section 7.4)
More sophisticated insulating papers and boards, including syn-
thetic and self-bonding papers, are also available.
9.9 Core Fabrication and
Assembly
The way in which distribution transformer cores are designed, cut,
fabricated and assembled, plays an important part in energy effi-
ciency. The cost of a completed core is also affected by these fac-
tors. Various levels of mechanisation and automation are available
for the cutting and stacking processes.
There is a specific problem of the capacity of European trans-
former manufacturers to handle and process magnetic steel at
gauges below 0.23mm, and to fabricate amorphous iron in-house.
It seems likely that the steel suppliers will attempt to extend their
capability to supply built cores and semi-fabricated components.
9.10 Coil Winding and
Assembly
The processes of winding the conductor coils and then fitting
them onto the assembled core are labour-intensive, and require
skilled workers. Again the performance and energy efficiency of a
distribution transformer greatly depends on these steps.
Mechanised winding, under operator control, is increasingly used
Figure 10
Spiral Sheet Low-voltage Winding
27. 25
for producing coils based upon copper wire, wide strip and alu-
minium foil.
The main types of coil which are now used in distribution trans-
formers are:
l spiral sheet windings, using wide copper strip or aluminium foil
(Figure 10). A relatively recent development, used in place of
helical coils for the LV windings of distribution transformers,
particularly where there are only a small number of turns
required in the coil
l multilayer coils for HV windings (Figure 11). The complete
winding is a single unit, wound in wire, consisting of several lay-
ers and a number of turns per layer
l disc coils, particularly for the HV windings of dry-type trans-
formers (Figure 12). A number of radially wound discs produced
from a single length of conductor, separated from one another by
insulating spacers.
There is also an established coil-winding industry in the EU,
which mainly offers windings for smaller transformers, and spe-
cialist products such as current transformers. These companies fre-
quently have encapsulation capabilities, and are able to supply
ready-built coils for dry-type transformers.
9.11 Superconducting
Transformers
A number of superconducting distribution transformers have been
built. One company has developed a nitrogen-cooled 630kVA
high temperature superconductor (HTS) transformer, which was
installed in the Swiss electricity supply network in 1997. This is a
single-phase transformer, and considerable engineering problems
are reported in producing three-phase versions.
It is widely agreed that superconductivity will always remain much
more expensive for power distribution transformers than conven-
tional technology. The most promising areas appear to be in spe-
cialist applications, particularly traction transformers, where
increasingly large transformers are required for train motors in
railway networks.
9.12 Technology Sources
Power systems transformers are very specialised products, and
R&D activities outside the major transformer manufacturing
companies are limited. Even here most effort is centred on practi-
cal product development, together with the testing and evaluation
of new materials. Only a few distribution transformer manufac-
turers in Europe have significant fundamental R&D capabilities
dedicated to transformer research.
Much of the recent work on the steels used in distribution trans-
formers has originated from Japan and the United States, although
European companies have a world reputation for the steels and
non-ferrous alloys used in smaller transformers. Some of the tech-
nology for adding value to conductors and coils, such as the con-
tinuous cold rolling of narrow strip, has also been imported.
However there are a number of centres of excellence in Europe,
with a capability for R&D and demonstration of distribution
transformers or component materials. Many European universities
have a capability in magnetic materials within their electrical engi-
neering or materials departments.
28. 26
10 TECHNICAL AND ENGINEERING
APPRAISAL
10.1 Distribution Transformer
Standards
Most of the characteristics of distribution transformers are speci-
fied in national or international product standards. The applica-
tion of standards can be legally require, or by specific reference in
the purchase contract.
Generally, the purpose of standards is to facilitate the exchange of
products in both home and overseas markets, and to improve
product quality, health, safety and the environment. International
standards are also of importance in reducing trade barriers.
For distribution transformers purchased in the European Union,
three levels of standards are applicable:
l world-wide standards (ISO, IEC)
l European standards and regulations (EN, HD)
l national standards (e.g. BSI, NF, DIN, NEN, UNE, OTEL).
European Harmonisation Documents are initiated if there is a
need for a European standard. The draft HD is a compilation of
the different national standards on the subject. The HD is
finalised by eliminating as many national differences as possible.
When a harmonisation document (HD) has been issued, conflict-
ing national standards have to be withdrawn within a specified
period of time, or modified to be compatible with the HD.
Usually, the HD is the predecessor of an European standard (EN),
which must be adopted as a national standard in the EU member
countries. Thus, purchase orders which refer to national standards
are compatible with European standards (EN) and/or harmonisa-
tion documents (HD).
Among the many international standards for distribution trans-
formers, two main European Harmonisation Documents specify
energy efficiency levels:
l HD428: Three-phase oil-immersed distribution transformers
50Hz, from 50 to 2,500kVA with highest voltage for equipment
not exceeding 36kV
l HD538: Three-phase dry-type distribution transformers 50Hz,
from 100 to 2,500kVA, with highest voltage for equipment not
exceeding 36 kV.
A separate HD is under consideration for pole-mounted trans-
formers.
In the next Section, the efficiency limits defined in these standards
are discussed. The standards however leave considerable freedom
for local deviations in energy efficiency, which implies that energy
loss levels may (and do) still vary across European countries. This
is also discussed in the next Section.
Figure 13 Distribution Transformer Loss Standards
Load Losses for Distribution Transformers No-Load Losses for Distribution Transformers
RATED OIL-FILLED (HD428) UP TO 24kV2) DRY TYPE OIL-FILLED (HD428) UP TO 24kV2) DRY TYPE
POWER (HD538) (HD538)
LIST A LIST B LIST C 12kV LIST A’ LIST B’ LIST C’ 12kV
PRIMARY 3) PRIMARY 3)
kVA W W W W W W W W
50 1,100 1,350 875 N/A 190 145 125 N/A
100 1,750 2,150 1,475 2,000 320 260 210 440
160 2,350 3,100 2,000 2,700 460 375 300 610
250 3,250 4,200 2,750 3,500 650 530 425 820
400 4,600 6,000 3,850 4,900 930 750 610 1,150
630 /4%1) 6,500 8,400 5,400 7,300 1,300 1,030 860 1,500
630 /6% 6,750 8,700 5,600 7,600 1,200 940 800 1,370
1000 10,500 13,000 9,500 10,000 1,700 1,400 1,100 2,000
1600 17,000 20,000 14,000 14,000 2,600 2,200 1,700 2,800
2500 26,500 32,000 22,000 21,000 3,800 3,200 2,500 4,300
Notes: 1. The short-circuit impedance of the transformers is 4% or 6%, in most cases.This technical parameter is of importance to a utility for designing and dimensioning the low-voltage network fed by the transformer.Transformers with the same rated power but with dif-
ferent short-circuit impedance have a different construction and therefore slightly different losses. For HD428 / HD538 compliant distribution transformers, the preferred values for the short-circuit impedance are 4% for transformers up to and including 630kVA,
and 6% for transformers of 630kVA and above.
2. For 36kV transformers, different values apply.
3. For 24 and 36kV transformers, different values apply.
29. 27
10.2 Rated loss levels of
Standard Distribution
Transformers
Distribution transformers built to HD428 and HD538 have a
limited number of preferred values for rated power (50, 100, 160,
250, 400, 630, 1,000, 1,600 and 2,500kVA). Intermediate values
are also allowed. The two key figures for energy efficiency, the load
losses and the no-load losses, are specified for each rated power.
Figure10 gives the limits for load losses (often called “copper loss-
es”) for some important types of oil-filled and dry-type distribu-
tion transformers according to HD428.1 and HD538.1 for the
preferred rated power range of the transformers. For oil-filled dis-
tribution transformers, the HD allows a choice of energy efficien-
cy levels, A, B and C.
Loss values for transformers are usually, declared as maximum val-
ues with a specified tolerance. If higher losses are found at the fac-
tory acceptance test, the transformer may be rejected or a financial
compensation for exceeding the loss limit may be agreed between
client and manufacturer. In the same way, a bonus may be award-
ed to the manufacturer, mainly for large transformers, for a trans-
former with losses lower than the limits agreed.
The no-load losses (iron losses) for the same range of transformers
are given below. For oil-filled distribution transformers, the HD
offers a choice between three efficiency levels, A’, B’ and C’ (Figure
13).
HD428 therefore allows customers to choose between three levels
of no-load losses and three levels of load losses. In principle, there
are 9 possible combinations, ranging from the lowest efficiency,
(B-A’) to the highest, (C-C’), which may be regarded as providing
a high practical standard of energy efficiency for a distribution
transformer.
HD428 defines five preferred combinations of these losses. These
combinations are shown below in Table B, where the combination
A-A’ is chosen as the base case (shown as a bold line - the per-
centages refer to this combination).
There is a significant difference in total no-load and load losses
between A-A’ and C-C’ distribution transformers, approximately
1.5kW for a 630kVA unit.
The freedom for choosing different levels of energy efficiency is
increased by the fact that transformer buyers can comply with
HD428/538 through the use of a capitalisation formula, rather
than the tabulated losses shown in the standard. In this, they are
free to insert their own capitalisation values, to which no restric-
tions are imposed. This process of loss capitalisation is described
in Section 10.6.
If high capitalisation values for losses are chosen, transformers
with low losses but with higher investment cost tend to be
favoured. If however capitalisation values are set to zero, a pur-
chaser effectively eliminates energy loss evaluation from the pur-
chase decision, which favours the cheapest transformer.
HD428.1 (part 1: general requirements and requirements for
transformers with highest voltage for equipment not exceeding 24
kV) as well as other HD sections also contain phrases such as “(...)
in the case of established practice in the market (...) the trans-
formers can be requested and, by consequence, offered, with loss-
es differing from the tabled losses”, which indicates some freedom
to national or local deviations.
As stated before, HD428 and HD538 represent a compilation
and/or compromise on the various old standards which were used
in European countries. It appears to be rather unambitious in
terms of the standards set, and by allowing capitalisation formulas
to be used.
10.3 Loss levels of Standard
Distribution Transformers
when Loaded
The losses of a transformer show considerable dependence on the
actual load. At no-load, the no-load losses are still present. At full
load, the load losses are added to the no-load losses. For less than
full load, the load losses decrease proportional to the square of the
load.
For example, the total losses of a 400kVA oil-insulated trans-
former are shown opposite as a function of the transformer load,
for the different loss combinations mentioned above.
The transformer efficiency can be calculated by dividing the loss-
es by the power transferred. Here, the effects of reactive power
should be accounted for, as reactive power causes current to flow,
with its associated losses. This causes the efficiency of the trans-
former to decrease. By multiplying the transformer load (in kVA)
by the so-called power factor (usually designated cos (), this effect
is accounted for, showing the net power transformed.
Figure 14 shows the relative transformer loss as a function of the
load. The relative transformer loss is equal to 100% minus trans-
former efficiency. Clearly, the relative losses follow a U-shaped
curve, and transformers are typically at maximum efficiency when
Table B
30. 28
50% loaded. The figure also shows that B-B’ transformers have
less loss than A-A’ transformers in the lower load region, while the
A-A’ transformers show lower loss in the region above 40% load.
Which transformer is best with regard to energy efficiency thus
depends on the application. C-C’ transformers have 20-30%
lower loss than the A-A’ and the B-B’ types.
Figure 15 shows how efficiency at full load varies with the size of
the transformer, and includes dry-type transformers. The graph
shows efficiency of the transformers of various sizes at full load.
Clearly, economies of scale apply to the oil-filled distribution
transformer and, to a stronger extent, to the dry-type transformer.
Because energy efficiency varies with load, the calculation of the net
efficiency of a transformer over a year or over its lifetime is rather
complex. Due to the square relationship between losses and load,
the average load of a transformer is not an adequate parameter to
calculate the annual energy losses or the average efficiency directly.
There are, however, some empirical formulae available to estimate
the annual transformer losses from the average annual load.
Figure 14
Total Losses of a 400 kVA Transformer as a Function of the Load (12kV and 24 kV Transformers
Figure 15
Dependendy of Transformer Losses on Size (kVA) for 12kV and 24kV transformers
31. 29
10.4 Achievable Loss Levels
The HD428 C-C’ loss level for oil-filled distribution transformers
may, as mentioned before, be regarded as providing a high practi-
cal standard of energy efficiency for a distribution transformer.
There is no internationally agreed definition of an “energy-effi-
cient” transformer. It is proposed to use the term “energy-effi-
cient” transformer for the following transformers:
l oil-filled transformers: range C-C’ (HD428.1) and D-E’
(HD428.3)
l dry-type transformers up to and including 24kV: 20% lower
than specified in HD538.1. HD538 mentions one list of pre-
ferred values, but explicitly allows the possibility for national
standards to specify a second series with load and/or no-load
losses at least 15% lower. Some transformer manufacturers offer
dry-type transformers in normal and low-loss versions
l dry-type transformers 36kV: 20% better than specified in
HD538.2, analogous to the previous category.
An important reason for choosing the values suggested above is
the fact that these levels are entirely feasible within the current
“state of the art” of nearly all transformer manufacturers. In the
remainder of this report, the class of energy-efficient transformers
is often referred to as C-C’, as the oil-filled transformers form the
majority of the transformers, and, among these, units up to 24kV
are the most numerous.
An alternative way of defining “energy-efficient transformers”
would be to by considering the energy-efficiency levels of the
transformers sold on the market. This is be analogous to the con-
cept of the US “energy star” transformer program (see Section 11).
Here transformers with energy efficiency equal to or above that of
the most efficient 35% being currently sold meet the requirement
for Energy Star rating.
Figure 16 gives an impression of the way in which the distribution
transformer population varies in Europe. It can be seen that refer-
ence to the population per country or for the European Union as
a whole will produce different results. However, it seems prefer-
able to address losses more absolutely.
Another way to define “energy-efficient transformers” would be
the application of special windings, advanced steels or amorphous
iron. An argument against this definition is that there are a num-
ber of practical considerations involved in deciding on the opti-
mum choice of transformer for installation into a network.
Moreover, the energy loss level is the key performance indicator of
each transformer design with respect to energy efficiency and
would consequently the fairest benchmark.
As expected, the loss level of “energy-efficient transformers” as
defined above does not represent the maximum efficiency which
is technically possible. Both load and no-load losses may be
reduced significantly.
Load losses may be reduced beyond the levels mentioned above by
following technical design measures:
l increasing the conductor section of the transformer windings,
which reduces conductor resistance and thus load losses. To a
lesser extent, the application of ribbon or sheet conductors also
contributes to reducing load losses. The disadvantage of increas-
ing the conductor section is the higher investment cost. Another
disadvantage is the larger size of the transformer, which may
exceed the maximum sizes specified by the purchaser. This is
Figure 16
Fictitious Example of Different European Transformer Standards
32. 30
partially offset by the reduction of heat production in the trans-
former, which lowers the need for cooling
l application of superconductor material for the windings, elimi-
nating load losses. This technology is not yet mature and still
very expensive. The main application will lie in larger trans-
formers. Another drawback of superconducting transformers is
the inability to withstand short-circuit currents of the level that
are common in medium-voltage networks. These problems need
to be solved before the superconducting transformer will become
a viable option.
No-load losses may be reduced beyond the levels mentioned above
by following technical design measures:
l increasing the core section, which reduces the magnetic field in
the transformer core and thus the no-load losses. However, this
results in higher investment cost. Another disadvantage is the
larger size of the transformer, which may exceed the maximum
sizes specified by the purchaser
l application of high-grade modern transformer core steel, see
Section 9. It should be noted that the C-C’ level can be reached
without applying laser-etched transformer steel, the latter being
regularly used in large transformers
l reduction of the thickness of the core laminations, see Section 9
l application of amorphous core material, see Section 9. The sav-
ing potential with respect to no-load losses is high, as shown in
the table below, where the amorphous transformer is compared
to the conventional types according to HD428.
The conclusion is that transformer efficiency may be raised well
beyond the current level of energy-efficient transformers by using
existing technology.
There are, however, some other important technical aspects that
are essential to the adoption of energy-efficient distribution trans-
formers and critical to some technologies:
l dimensions. Distribution transformers need to be aligned to
switchgear, fit into enclosures or go through doorways. For larg-
er transformers, the mass may also be a critical parameter. Many
dimensional features are still defined at national level or even
utility level
l noise level. Distribution transformers are often sited in buildings
or residential areas, where strict limits on acoustic noise emission
apply
l absence of technological risk. The distribution transformers cur-
rently in use are extremely reliable. Furthermore, the conse-
quences of failure are severe, as most distribution networks are
operated in radial configurations. Many networks have no back-
up for a distribution transformer failure, with the consequence
that a transformer outage will affect customers until the trans-
former has been replaced. For this reason, utilities tend to be very
careful when adopting new technologies (see Section 11) unless
a new design has unequivocally proven its reliability (preferably
at another utility).
The options are compared qualitatively in Figure 17 (+ indicates a
favourable score).
10.5 Loss Levels in Practice
In practical installations, the loss levels of transformers are deter-
mined by three factors, the efficiency class specified, the load pro-
file of the transformer and deviations from the standard loss val-
ues. The three factors will each be discussed below.
The efficiency class specified
There appears to be a “league table” of standards for distribution
transformer losses specified by the electricity utilities of the vari-
ous European countries. Switzerland, Scandinavian countries are
said to set the highest standards, with France and Italy amongst
the lowest (A-A’) with France particularly keen to reduce no-load
(source: EDON)
Table C
Figure 17 Comparison of Technologies to Improve Energy Efficiency
Absence of Dimensions Noise Cost compared Energy saving Energy saving
technological risk to C-C’ @ light load @ heavy load
Increased conductor section ++ 0/- 0 - 0 +
Superconducting windings -- variable 0 --- - +
Increased core section ++ 0/- 0 - + 0/+
Modern core material,
Thin laminations ++ 0 + - ++ 0/+
Amorphous metal core + - - -- +++ 0/+
33. 31
losses rather than load losses. Others are somewhere in the middle.
Among values reported in the project were (oil-filled transform-
ers):
As indicated above, the UK does not apply the HD428/538 loss-
es table. Each utility uses its own values to capitalise losses, in
accordance with the alternative approach permitted by HD428.
The capital value of losses is normally assessed annually.
There is quite a lot of movement at present in the loss standards
which are currently being applied. Newly decentralised and priva-
tised utilities are changing earlier procurement standards for dis-
tribution transformers, and placing first cost above energy effi-
ciency, either as a conscious action or as the result of reducing pay-
back periods. German utilities are said to be reducing previous
higher standards. However Belgium has recently raised its nation-
al procurement standard to C-C’.
Energy-efficient transformers are generally regarded by European
customers as technically sound but uneconomic (but see Section
10.7 and Section 11). The number of extremely energy-efficient
transformers (beyond the C-C’ level) operating in Europe is quite
low, compared with a.o. the United States. We estimate that about
200 amorphous distribution iron transformers have so far been
installed, many of which are very small, and probably a slightly
larger number using laser-etched domain-refined steel. The amor-
phous iron installations we have identified are as follows:
The load profile of the transformer
Although transformer efficiencies can be measured accurately in
the test house, the load profile and hence the efficiency differs for
every transformer in the field. The dependency of the efficiency of
the transformer on the load profile was mentioned in Section
10.4.
The table below gives an idea of the load profiles involved:
The terms in the table are defined as follows:
l yearly peak load: the highest load of the transformer as a per-
centage of its rated power. This load is only present for a small
part of the year
l running time: the ratio of energy transmitted during a year
[kWh] and the yearly peak load [kW] - physically, this figure
indicates how much time it would take to transmit the yearly
energy at a power equal to the yearly peak load. A low value indi-
cates strong fluctuations of the load, a high value a relatively con-
stant load. The average transformer load is the yearly peak load,
multiplied by the running time over 8760 hours
l loss time: the ratio of the yearly energy loss [kWh] and the max-
imum losses occurring in a year [kW] - this figure indicates how
much time it would take for the transformer to lose the yearly
energy loss when loaded at the maximum load occurring in the
year.
The data above result into the following data for an A-A’ and a C-
C’ transformer with an “average” load profile as indicated above:
Table D
Utility Distribution Transformer Loss Levels in Europe
Country Utility Distribution Transformer Loss Levels
Belgium C-C’
France A-A’ and B-B’ and B-C’
Germany A-C’ and B-A’ and C-C’
Netherlands C-C’
Spain 50% meet C-C’
UK Uses capitalisation values
Table E
Amorphous Iron Distribution Transformers, Europe
Location Number Total kVA
Belgium 10 4,000
Germany 1 500
Ireland 101 3,100
Netherlands 3 1,200
Slovakia 2 800
Spain 14 8,330
Switzerland 5 1,540
UK 25 2,390
Total 161 21,860
Table F
Typical Load profiles, Distribution Transformers, Europe
Transformer Yearly Running Loss Power
peak time, average time factor
load load (cos j)
100kVA (small, rural) 1,500 h 750 h 0.95
q lightly loaded 10% 1.6%
q average loaded 40% 6.5%
q heavily loaded 120% 20%
400kVA (average) 2,500 h 1,500 h 0.95
q lightly loaded 20% 5.5%
q average loaded 55% 15%
q heavily loaded 110% 30%
1,600kVA (industrial) 3,500 h 2,500 h 0.8
q lightly loaded 30% 9.5%
q average loaded 50% 16%
q heavily loaded 110% 32%