The document provides performance indicators for an Italian project called BUILD UP Skills I-TOWN that aims to train construction workers on energy efficiency. It estimates training 2,000 workers by the end of the project, increasing to 150,000 total trained workers by 2020. This is expected to result in over 600 energy efficient building interventions by the end of the project, increasing to over 50,000 total interventions by 2020, saving an estimated 261 toe of primary energy and reducing greenhouse gas emissions by over 1,000 tons of CO2 at the end of the project.
Capgemini's European Energy Markets Observatory is an annual report that was initiated in 2002. It tracks the progress of two subjects: the establishment of an open and competitive electricity and gas market in EU-27 (plus Norway and Switzerland) and the reaching of the EU's 3x20 climate change objectives. The report looks at all segments of the value chain and analyzes leading-edge energy themes — digital revolution, customer experience, smart grids and demand response management — to identify key trends in the electricity and gas industries.
The 15th edition of the report covers the whole year 2012 and winter 2012/13 on the following areas: Energy Regulation, Electricity Markets, Gas Markets, Customer Transformation, Renewable Energy Sources & Local Energy Transitions and Companies’ Overview.
SESEC Training Module 14: Self-Assessment Tool (SAT)DITF Denkendorf
This is a training module developed in the European project SESEC. More information and the full training can be found here: www.sesec-training.eu
The SESEC project is designed to address the energy efficiency needs of the EU clothing industry. The Consortium relies on outstanding competences of the partners, spread over 6 countries (Bulgaria, Romania, Portugal, Italy, Germany, Belgium) to provide the missing energy efficiency benchmarks and ready-to-use solutions for the large number of SMEs as well as larger companies. The SESEC project has 4 major objectives:
• To develop, test and offer an Energy Efficiency tool for clothing production, made up of guidelines and web-based applications, suitable for SMEs and large companies
• To transfer the project results to the sector, EURATEX members and interested companies
• To offer training and support to companies to implement energy-saving measures considering cost-effectiveness
• To improve opportunities for energy-efficiency for the whole European clothing industry
This is a training module developed in the European project SESEC. More information and the full training can be found here: www.sesec-training.eu
The SESEC project is designed to address the energy efficiency needs of the EU clothing industry. The Consortium relies on outstanding competences of the partners, spread over 6 countries (Bulgaria, Romania, Portugal, Italy, Germany, Belgium) to provide the missing energy efficiency benchmarks and ready-to-use solutions for the large number of SMEs as well as larger companies. The SESEC project has 4 major objectives:
• To develop, test and offer an Energy Efficiency tool for clothing production, made up of guidelines and web-based applications, suitable for SMEs and large companies
• To transfer the project results to the sector, EURATEX members and interested companies
• To offer training and support to companies to implement energy-saving measures considering cost-effectiveness
• To improve opportunities for energy-efficiency for the whole European clothing industry
Capgemini's European Energy Markets Observatory is an annual report that was initiated in 2002. It tracks the progress of two subjects: the establishment of an open and competitive electricity and gas market in EU-27 (plus Norway and Switzerland) and the reaching of the EU's 3x20 climate change objectives. The report looks at all segments of the value chain and analyzes leading-edge energy themes — digital revolution, customer experience, smart grids and demand response management — to identify key trends in the electricity and gas industries.
The 15th edition of the report covers the whole year 2012 and winter 2012/13 on the following areas: Energy Regulation, Electricity Markets, Gas Markets, Customer Transformation, Renewable Energy Sources & Local Energy Transitions and Companies’ Overview.
SESEC Training Module 14: Self-Assessment Tool (SAT)DITF Denkendorf
This is a training module developed in the European project SESEC. More information and the full training can be found here: www.sesec-training.eu
The SESEC project is designed to address the energy efficiency needs of the EU clothing industry. The Consortium relies on outstanding competences of the partners, spread over 6 countries (Bulgaria, Romania, Portugal, Italy, Germany, Belgium) to provide the missing energy efficiency benchmarks and ready-to-use solutions for the large number of SMEs as well as larger companies. The SESEC project has 4 major objectives:
• To develop, test and offer an Energy Efficiency tool for clothing production, made up of guidelines and web-based applications, suitable for SMEs and large companies
• To transfer the project results to the sector, EURATEX members and interested companies
• To offer training and support to companies to implement energy-saving measures considering cost-effectiveness
• To improve opportunities for energy-efficiency for the whole European clothing industry
This is a training module developed in the European project SESEC. More information and the full training can be found here: www.sesec-training.eu
The SESEC project is designed to address the energy efficiency needs of the EU clothing industry. The Consortium relies on outstanding competences of the partners, spread over 6 countries (Bulgaria, Romania, Portugal, Italy, Germany, Belgium) to provide the missing energy efficiency benchmarks and ready-to-use solutions for the large number of SMEs as well as larger companies. The SESEC project has 4 major objectives:
• To develop, test and offer an Energy Efficiency tool for clothing production, made up of guidelines and web-based applications, suitable for SMEs and large companies
• To transfer the project results to the sector, EURATEX members and interested companies
• To offer training and support to companies to implement energy-saving measures considering cost-effectiveness
• To improve opportunities for energy-efficiency for the whole European clothing industry
The Economic Research Institute for ASEAN and East Asia (ERIA), together with the Ministry of Electricity and Energy of the Union of Myanmar, launched Myanmar National Energy Statistics 2019 in Nay Pyi Taw on 11 March 2019.
in his presentation, Mr Shigeru Kimura, ERIA’s Special Adviser to the President on Energy Affairs, discussed the basic concept of energy balance tables, analysis of the energy demand supply situation in Myanmar, as well as the key findings and policy implications of the study.
Green performs better! - Economic impact of energy performance certificates i...Dr. Marcelo Cajias
The purpose of this paper is to investigate the effect of energy consumption on the financial performance of German residential buildings in a large panel framework. The authors provide evidence that energy efficiency in the residential sector is a relevant factor affecting both tenant investment decisions and consequently the performance of investor portfolios.
SkyAI heat detection whitepaper: Europes plans to reduce heat wasteJoost van Oorschot
This whitepaper provides an overview of the current heat network in Europe as well as the policies and goals of the EU to reduce its heat waste. The paper finalises with SkyAI's perspective on how to effectively reduce heat waste in the EU
Role of Building Automation related to Renewable Energy in nZEB’sLeonardo ENERGY
Building automation has a key role to play in the implementation of nearly zero-energy buildings (nZEB). Building automation is the connector of all the single requirements for nZEB, such as a well-insulated and airtight building shell, efficient HVAC system and a high share of renewable energy. That is the main conclusion of this study, prepared by Ecofys for the Leonardo ENERGY initiative.
Main functions of building automation
The study identifies the most important building automation functions in an nZEB as follows:
1. Central, concerted control of all energy related components
Building automation taps all internal saving potential and assures that the whole system can work with highest efficiency. While sophisticated central systems with producer-independent compatibility are commonly available, they need to be developed and supported further to arrive at a necessary standard requirement for nearly zero-energy buildings.
2. Monitoring and providing feedback
Building automation guarantees that the demanded and calculated (low) energy demand of the nearly zero-energy is met. That is one of the key aspects in meeting climate goals.
Next to that, building automation encourages users to save energy. The expected saving potential of this indirect efficiency measure are estimated to be up to 30%.
3. Load shifting and storage management
Building automation increases the coverage rates of renewable energy on site (mainly PV). The expected increase of total coverage rate by building automation without additional storage is estimated to be up to 5% in southern European regions.
Also, building automation increases free cooling potentials in central and southern European regions. Free cooling potentials are often still untapped, but necessary to reduce cooling demand significantly.
Thirdly, building automation increases grid stability. The challenge to maintain grid stability will become larger with increased penetration of renewable energies.
4. Ensuring the thermal comfort
Ensuring thermal comfort is especially important at highly efficient but slow reacting systems, like concrete activation or floor heating. Industry needs to develop and improve control mechanisms, which are specialized to control slow reacting systems in nearly zero-energy buildings (e.g. by using weather forecasts).
Action required
To ensure that the indicated potentials of building automation are achieved different actions from different stakeholders will be necessary. As indicated in chapter 6 some of those need to originate from policies, e.g. to develop an adequate regulatory basis or to create awareness. Others need to come from industry to provide suitable products.
Finally, many aspects of building automation will need to be further investigated before their full benefits can be reaped. Testing and monitoring of realized nearly zero energy buildings with inte-grated building automation systems wi
The Economic Research Institute for ASEAN and East Asia (ERIA), together with the Ministry of Electricity and Energy of the Union of Myanmar, launched Myanmar National Energy Statistics 2019 in Nay Pyi Taw on 11 March 2019.
in his presentation, Mr Shigeru Kimura, ERIA’s Special Adviser to the President on Energy Affairs, discussed the basic concept of energy balance tables, analysis of the energy demand supply situation in Myanmar, as well as the key findings and policy implications of the study.
Green performs better! - Economic impact of energy performance certificates i...Dr. Marcelo Cajias
The purpose of this paper is to investigate the effect of energy consumption on the financial performance of German residential buildings in a large panel framework. The authors provide evidence that energy efficiency in the residential sector is a relevant factor affecting both tenant investment decisions and consequently the performance of investor portfolios.
SkyAI heat detection whitepaper: Europes plans to reduce heat wasteJoost van Oorschot
This whitepaper provides an overview of the current heat network in Europe as well as the policies and goals of the EU to reduce its heat waste. The paper finalises with SkyAI's perspective on how to effectively reduce heat waste in the EU
Role of Building Automation related to Renewable Energy in nZEB’sLeonardo ENERGY
Building automation has a key role to play in the implementation of nearly zero-energy buildings (nZEB). Building automation is the connector of all the single requirements for nZEB, such as a well-insulated and airtight building shell, efficient HVAC system and a high share of renewable energy. That is the main conclusion of this study, prepared by Ecofys for the Leonardo ENERGY initiative.
Main functions of building automation
The study identifies the most important building automation functions in an nZEB as follows:
1. Central, concerted control of all energy related components
Building automation taps all internal saving potential and assures that the whole system can work with highest efficiency. While sophisticated central systems with producer-independent compatibility are commonly available, they need to be developed and supported further to arrive at a necessary standard requirement for nearly zero-energy buildings.
2. Monitoring and providing feedback
Building automation guarantees that the demanded and calculated (low) energy demand of the nearly zero-energy is met. That is one of the key aspects in meeting climate goals.
Next to that, building automation encourages users to save energy. The expected saving potential of this indirect efficiency measure are estimated to be up to 30%.
3. Load shifting and storage management
Building automation increases the coverage rates of renewable energy on site (mainly PV). The expected increase of total coverage rate by building automation without additional storage is estimated to be up to 5% in southern European regions.
Also, building automation increases free cooling potentials in central and southern European regions. Free cooling potentials are often still untapped, but necessary to reduce cooling demand significantly.
Thirdly, building automation increases grid stability. The challenge to maintain grid stability will become larger with increased penetration of renewable energies.
4. Ensuring the thermal comfort
Ensuring thermal comfort is especially important at highly efficient but slow reacting systems, like concrete activation or floor heating. Industry needs to develop and improve control mechanisms, which are specialized to control slow reacting systems in nearly zero-energy buildings (e.g. by using weather forecasts).
Action required
To ensure that the indicated potentials of building automation are achieved different actions from different stakeholders will be necessary. As indicated in chapter 6 some of those need to originate from policies, e.g. to develop an adequate regulatory basis or to create awareness. Others need to come from industry to provide suitable products.
Finally, many aspects of building automation will need to be further investigated before their full benefits can be reaped. Testing and monitoring of realized nearly zero energy buildings with inte-grated building automation systems wi
Ministry of Economics of Latvia, as EU SBSR Policy Area ‘Energy’ coordinator, is organizing a series of online discussions on the topic "Financing renovation project: mapping roles and responsibilities".
On November 19th, 2020 from 11 am to 13.30 pm Riga time (GMT+2) we are holding the first discussion round - Financing renovation project: stakeholders, decision-making process, project management, and documentation.
In cooperation with the Swedish Institute, we have already established a strong network of experts in the field of energy efficiency by successfully establishing a Baltic Leadership Programme on Energy Efficiency.
With the new series of discussions, we aim to discuss associated funding structures, project implementation, execution, main obstacles, and how to overcome them. The ultimate aim is to continue building a macroregional flagship process on exchanging experiences and sharing competencies on Energy Efficiency.
Financing renovation project: mapping roles and responsibilities discussion GER
This technical and macro-economic study focuses on light duty vehicles -- cars and vans. It has been advised by a broad group of stakeholders in the move to low-carbon transport, including auto producers, technology suppliers, labour groups, energy providers and environmental groups. The resulting fact-base is anticipated to serve as a reference point for discussions around the low-carbon transition.
The model results show that a shift to low-carbon cars and vans increases spending on vehicle technology, a sector in which Europe excels, therefore generating positive direct employment impacts. This shift will also reduce the total cost of running Europe’s auto fleet, leading to mildly positive economic impacts including indirect employment gains.
The analysis showed that a shift to low-carbon vehicles would increase spending on vehicle technology, therefore generating positive direct employment impacts, but potentially adding €1,000-€1,100 to the capital cost of the average new car in 2020. However, these additional technology costs would be offset by fuel savings of around €400 per year, indicating an effective break-even point for drivers of approximately three
years. At the EU level, the cost of running and maintaining the European car fleet would become €33-35 billion lower each year than in a “do nothing scenario” by 2030, leading to positive economic impacts including indirect employment gains.
Energy efficiency trends in buildings in the EU (update)Leonardo ENERGY
(This is an updated version of the slides used during the 11th webinar in the Odyssee-Mure on Energy Efficiency Academy at 08 Dec 2020. This version addresses pending questions with some more details and references.)
What has been the overall trend in final energy consumption of buildings in the EU since 2010?
What are the main drivers of the energy consumption variation, and in particular energy savings, for residential and service buildings?
These are the key questions answered during this (11th) webinar in the Odyssee-Mure on Energy Efficiency Academy.
Highlights from their research:
➢The energy consumption of buildings has steadily decreased since 2010 despite GDP growth.
➢There are large disparities in building performances across countries.
➢Since 2015, the rate of household energy efficiency improvements has dropped by 50% (compared to 2000-2014).
➢Energy efficiency of large electrical appliances, which has largely improved in the past, does not counterbalance anymore the rapid growth of the consumption of small appliances.
Ya os hemos hablado en diferentes ocasiones de Renovate Europe, entre cuyos promotores se encuentra PU Europe, la asociación europea que promueve el uso del Poliuretano como solución eficiente en la construcción sostenible, y de la que IPUR es miembro activo.
Sus objetivos son claros y contundentes:
Triplicar la tasa de rehabilitación de los edificios existentes en 2020
Mejorar la eficiencia energética de los edificios existentes en un promedio del 80% sobre los niveles actuales de rendimiento
Recomendar soluciones efectivas como la financiación, la formación, etc.
Renovate Europe fomenta la rehabilitación del parque de edificios existentes europeo, a través de acciones de concienciación y diferentes programas de acción tanto a nivel nacional, regional y de políticas locales. Sus argumentos son claros y contundentes, y los encontramos condensados y recogidos en un decálogo que debería de convertirse en el manual que los principales responsables europeos deberían tener en la mesita de noche, 'It Pays to Renovate' ('Merece la pena rehabilitar')
Germany has continued to improve its environmental performance over the past decade. It has ambitious climate targets with the aim to reach climate neutrality by 2045 and achieve negative emissions after 2050. Nevertheless, Germany will need to further accelerate climate action, particularly in the buildings and transport sectors, and address the triple crisis of energy, climate and biodiversity in an integrated and holistic manner. As part of its energy crisis response, Germany has taken a series of measures, which are historic in size and scope. They are set to massively accelerate its green energy transition in the coming years. It is also scaling up its engagement on climate change adaptation across all government levels and has initiated an ambitious programme to foster investments in nature-based solutions. This is the fourth OECD Environmental Performance Review of Germany. It provides 28 recommendations to help Germany further improve its environmental performance.
The proposal of this project was to study the energy consumption of three residential buildings in Mosegårdsparken, Odense. In order to reduce the energy consumption of the old buildings, it had to be compared the different materials, construction solutions and energy resources, following the Danish building regulation.
All the materials and energy systems will be conscientiously analyse and afterwards will renew, change or add them. To develop the purpose, several solutions will be studied in each building typology, choosing the most suitable one according to their properties.
As a result, they were transformed into friendly environmental and low energy new buildings.
Employment benefits from stimulation of demand for building automation and co...Leonardo ENERGY
Highlights:
* 1.3 to 2.1 million jobs will be created under an incentivizing policy framework for EU-wide BACS deployment
* Half of this growth in jobs can be created over a course of only 10 years
* The employment impact is expected to be situated almost entirely in the EU, with a strong benefit for national economies
Electric Vehicles - State of play and policy frameworkLeonardo ENERGY
The objective of this report is to contribute to a better understanding of the potential impact of a transition to electric vehicles (EVs) in Europe and of the barriers that currently impede the realization of this potential. The research and analysis contained in this document indicates that the EV holds enormous environmental, social and economic benefits for Europe. However, it also shows that despite some progress in the right direction, we are currently a long way from realizing it. For this potential to be unlocked to a material extent within a 2050 horizon, a series of barriers need to be surpassed through collaboration by all stakeholders. Details of these findings are provided and recommendations on how to increase EV market uptake and to leverage the potential of EV benefits are presented.
From Ugly Duckling to Superstar: how energy efficiency (almost) got to the to...FTI Consulting FR
Energy efficiency has long been promoted at European level. The European Commission has certainly made great efforts to support it and to ensure that energy savings can contribute to the EU’s energy priorities, namely reduction of carbon emissions, lowering of energy costs and increase of energy independence. The EU has introduced energy efficiency targets, created a regulatory framework to support energy efficiency and the uptake of energy efficient products and provided significant funding. However, so far energy efficiency has not lived up to its expectations, which is disappointing considering the huge amount of resources spent to promote it.
In this Energy Flash we look why the EU’s policies have so far have not had the desired effect, what is being done to change this and which sectors are best placed to benefit from the renewed efforts.
SINERGIE's profile with a specific focus on experience on EU research and innovation projects.
The presentation covers EU projects realised in the period 2010-2017 within the topics:
- Horizon 2020;
- Erasmus+
- CIP Intelligent Energy Europe;
- CIP Eco-Innovation;
- Life Long Learning Programme.
SINERGIE is an accredited VET and Research centre located in Northern Italy.
H2020 MAESTRI Project - Kick off meeting @ BrusselsGiovanni Pede
Presentation of the WP on dissemination activities of the project MAESTRI "Total resource and energy efficiency management system for process industries" funded by the Horizon 2020 SPIRE-06 programme of the European Commission
Presentazione progetti europei Sinergie (Convegno Tecnopolo di Reggio Emilia ...Giovanni Pede
Presentazione tenuta nell'ambito del convegno "Fondi Europei: 7 miliardi di opportunità" organizzato da SINERGIE presso il Tecnopolo di Reggio Emilia l'08/05/2015
Presentazione dei progetti IEE di cui Sinergie è partner: EMPOWERING e BUILD UP SKILLS I-TOWN
1. http://www.bus-itown.eu/
Italian Training qualificatiOn Workforce in buildiNg
BUILD UP Skills I-TOWN
Contract n° IEE/13/BWI/721/SI2.680178
WP: EU EXCHANGE ACTIVITIES AND MONITORING
Deliverable: D7.1 Report with set of updated performance indicators including their baseline and
assumption for calculation
Dissemination Level: PU
Language(s): EN
The sole responsibility for the content of this document lies with the authors. It does not necessarily reflect the opinion of the European Union.
Neither the EASME nor the European Commission are responsible for any use that may be made of the information contained therein.
2. Author(s)
Name Partner
Giovanni Carapella FORMEDIL
Giovanni Pede, Alessandro Rizzo SINERGIE
Mariapia Martino POLITO
Francesco Minichiello, Concetta Marino UNINA
Francesco De Falco, Nicola Massaro ANCE
Giuliana La Spada ECIPA
Mariolina Pastore RENAEL
Revision(s) Tracking
Version. Date Author Partner Object of the revision
0.1 14/11/2014
Giovanni Carapella
Giovanni Pede
FORMEDIL
SINERGIE
First draft
0.2 20/01/2015
Francesco
Minichiello
UNINA Minor corrections and revision
0.3 29/01/2015 Mariolina Pastore RENAEL Revision
0.4 29/01/2015
Giovanni Carapella
Giovanni Pede
FORMEDIL
SINERGIE
Final version
3. Impacts and performance indicators
Common indicators
The methodology to be used to quantify the Common Indicators takes into account the emission/energy
saved ensured by recurring to the new skills taught within the courses object of the current project.
The main assumption is that the qualified workers can ensure a major use and a better installation of
environmental and energy efficiency systems and facilities. On the basis of its historical data, Formedil has
trained in the period 2009-2012 more than 500.000 persons within the national network of 104 building
schools. These 104 schools trained only in the year 2012 an amount of 132.126 persons, providing them
370.970 training hours. The blue collars are the 80,53% of the trained workers (419.706 for the period
2009-2012). Assuming this trend is confirmed for the period 2016-2020 and assuming that a minimum
amount (average of 30% per year) of the total beneficiary workers will be enrolled in the training courses of
the building schools network, we expect to train on the innovative contents of the BUILD UP SKILLS I-TOWN
150.000 workers by the year 2020. At the end of the project (2017) we expect to train 2.000 workers after
the ending of the pilot courses and the replication of the courses that will be carried out by the network of
building schools. This amount will increase during the subsequent years reaching a cumulative amount of
150.000 in 2020. According to the ODYSSEE database1
, the average building energy consumption for the
period 2000-2012 is 1,171 toe/dwelling. In Italy the average number of employees in the enterprises of the
building sector is 2,92
. Assuming that the total number of trained workers can be traced back to a number
of businesses/enterprises given by the ratio between total target workers and average number of
employees for the building sector and assuming that each business/enterprise will carry out one
intervention on buildings, we can evaluate the indicators provided in the table below:
At the end of
project
Cumulative data to
2020
Number of trained workers 2.000 150.000
Average employees in Italy (building sector) per
enterprise
2,9 2,9
Interventions on buildings 689 51.724
The following table shows the categories of interventions (source: SAIE 2014 Dati 2013 del settore
costruzioni)
% on the total of
interventions
average value of energy
saving
(MWh/year)
average value of energy
saving
(toe/year)
Fixtures replacement 64 2,6 0,22
Plant replacement 24 8,4 0,72
Solar Thermal for water
heating
9 2,8 0,24
Building Envelope 3 17 1,89
1
http://www.odyssee-indicators.org/online-indicators/
2
BUILD-UP Skills Italy National Roadmap
4. On the basis of the figures above, it is possible to assume that the category of interventions will be the
subsequent as showed by the table below:
n. of
interventions
at the end of
the project
Average value of
energy savings
(toe/year) At the
end of the project
Cumulative n. of
interventions at the
end of the project
to 2020
Cumulative value of
energy savings
(toe/year) to 2020
Fixtures replacement 440,96 97,0112 33.103 7.282,74
Plant replacement 165,36 119,0592 12.414 8.937,91
Solar Thermal for water
heating 62,01 14,8824 4.655 1.117,24
Building Envelope 20,67 30,1782 1.552 2.265,51
The following graph shows the contribution of the Build Up Skills I-TOWN to the energy requalification
interventions that will be implemented by 2020
The baseline has been calculated using the historical series of the demand of incentives for energy
qualification submitted in Italy from 2007.3
At the end of project Cumulative data to 2020
Energy consumption without interventions (toe) 806,86 60.568,80
Primary energy saving (toe) 261,13 19.603,40
Regarding the number of interventions, it is reasonable to assume that the 3%4
of interventions for plant
replacement will be related to the installation of a RES system. This, added to the number of interventions
3
Terzo Rapporto dell’Osservatorio congiunto Legambiente - Fillea Cgil - Filca Cisl - Feneal Uil – Innovazione e
sostenibilità nel settore edilizio”Costruire il Futuro”, 2014
4
Percentage given by the Italian objective on RES production towards 2020 strategy (17%) and percentage of energy
requirements for buildings (~80%)
2017 2018 2019 2020
with the project i-town 478010 509386 549210 601964
without the project itown -
baseline
477321 506800 536279 565757
450000
470000
490000
510000
530000
550000
570000
590000
610000
Contribution of I-TOWN respect to the
baseline (n. of interventions)
5. for the installation of solar thermal for water heating, provides us an estimation of the number of
interventions for the installation of RES. According to data provided by the IEE project TRAINREBUILD, a
typical indicator unit for the Renewable Energy production triggered is 0,3 toe per intervention per year5
.
At the end of project Cumulative data to 2020
Interventions for RES installation 67 5.028
Renewable Energy production triggered (toe) 20 1.508
With reference to the reduction of GHG emissions, the main assumption is based on the typical energy
requirements of a building which are 2/3 for heating and 1/3 for electricity. The estimation on primary
energy saved at the end of the project and by 2020 has been converted in MWh using the IEA converter
(http://www.iea.org/STATS/unit.asp). The emission factor used for the estimation of GHG reduction related
to the Primary Energy savings has been calculated as weighted average between the average emission
factor for natural gas in Europe (0,237 tCO2eq/MWh) and the Italian emission factor for electricity (0,708
tCO2eq/MWh), it is assumed as a constant for the whole period 2017-2020 and it has been quantified as
0,394 tCO2eq/MWh6
.
The emission factor for the conversion of the Renewable energy production triggered has been chosen
assuming that interventions are based on solar energy for both electricity (0,0667 tCO2eq/MWh) and
heating by combustion (0,028 tCO2eq/MWh)7
. The emission factor has been calculated using the weights
defined above and has been quantified as 0,0409 tCO2/MWh.
At the end of
project
GHG
reduction
(tCO2eq)
Cumulative data to
2020
GHG
reduction
(tCO2eq)
Primary energy saving (MWh) 3.036,94 1.196,55 227.987,54 89.827,16
Renewable energy production
(MWhe)
232,60 9,51 17.538,04 717,03
The expected GHG reduction related to the primary energy saving is 1.196,55 tCO2eq at the end of the
project and will reach the cumulative value of 89.827,16 tCO2eq in 2020 (on average it means a saving of
22.456 tCO2eq per year during the period 2017-2020).
The figures to 2020 depend on the commitment of the building schools to replicate the BUILD UP SKILLS I-
TOWN courses and/or include their contents in the existing training courses for workers both for initial
training and upgrading.
5
IEE/09/741/SI2.576295 TRAINREBUILD, study based on: Energy Saving Trust “Sustainable Refurbishment:
Towards 80% Reduction in C02 Emissions, Water Efficiency, Waste Reduction and Climate change adaptation” and
E3G “Financing the green deal”
6
http://www.eumayors.eu/IMG/pdf/technical_annex_en.pdf, weights: 2/3 heating and 1/3 electricity
7
ECOINVENT DATABASE – SIMA PRO
6. Performance Indicators Target within the action
duration:
Target by 2020:
Common Indicators
Number of training courses triggered by the
action
Total number for the whole
action: 100 (assumption:
classes of 20 workers)
Total number by 2020:
7500 (assumption: classes of 20
workers)
Number of people that will be trained 2.000 (total workers at the end
of the project)
150.000 (cumulative amount on
2020)
Number of hours taught in the frame of the
courses triggered
Total number for the whole
action: 1.400
Total number by 2020: 105.000
Estimated specific cost to qualify each trainee 280 Euro/trainee 280 Euro/trainee
Renewable Energy production triggered 20 Toe (at the end of the
project)
377 Toe/year on average for
the period 2017-2020
1.508 Toe (Cumulative amount
on 2020)
Primary energy savings compared to projections 261,13 Toe (at the end of the
project)
4.900 Toe/year on average for
the period 2017-2020
19.603,40 Toe (Cumulative
amount on 2020)
Reduction of greenhouse gas emissions 1.196,55 tCO2eq (at the end of
the project)
22.456 tCO2eq/year on average
for the period 2017-2020
89.827,16 tCO2eq (Cumulative
amount on 2020)
Specific indicators for your action
Quality of the training courses Satisfaction indicator
(SERVQUAL or similar
methodology)
Objective: 𝑄 ≥ 0
Objective: to maintain 𝑄 ≥ 0