This project is co-funded

by the European Union

Energy Management for Sustainable Action Plans, Brussels, 18 June 2015

Siegfried Zoellner, Coordinator, ICLEI European Secretariat

Optimising Energy Use in Cities through Smart Decision Support Systems

And with 6 out of 10 people expected to live in cities by

2030, urban energy demands are continuously growing

(WHO).

The challenge: cities are increasingly hungry for energy

• Cities consume over 2/3rds of the world’s energy;

• they are the largest emitters of greenhouse gases;

• and can influence over 70 % of the total ecological footprint.

Local authorities are uniquely placed to play a key role in the

European and national goals of developing a low-carbon economy:

• have a huge sphere of influence and a duty to promote the social,

economic and environmental well-being of their community.

• as permanent bodies that plan for the long term

• a number of data sets available

• portfolios include many types of building,

each which use significant amounts of energy

Using city data to make smart energy decisions

Energy is one of the largest

controllable overheads in many

local authority buildings

The OPTIMUS approach

The OPTIMUS project aims to design, develop and deliver an integrated ICT platform

that will collect & structure open data sets to recommend the best energy-saving

opportunities available in public buildings.

Savona, Sant Cugat,

Zaanstad DSS

…. using city data to make smart energy-saving decisions in public buildings

The city assessment

framework

Developing the

Decision Support

System (DSS)

Piloting the DSS

three cities

Training sessions

for other cities to

implement the DSS

1. 2. 3. 4.

The SCEAF Model Smart City Energy Assessment Framework

General characteristics

Political Field of Action

1.1 Degree of ambition

1.2 Efficiency at

fulfilling targets

1.3 Asset Management

Energy & Environmental

Profile

2.1 Energy

Consumption Intensity

2.2 Energy production

via Renewable

Technology

2.3 Energy

Conservation

Issues

2.5 Ambient Air

Pollution

2.4 Network Efficiency

Related Infrastructure

Energy & ICT

3.1 Monitoring Systems

BEMS

3.2 Levels of

integration of

automations, Mart

meters & ICT solutions

3.3 Forecasting

systems

3.4 Exploitation of

Social Media

http://sceaf.optimus-smartcity.eu

Political Field of

Action

Energy &

Environmental Profile

Related

Infrastructures & ICT

OPTIMUS City

City under Evaluation

Highest score in

every indicator

Specific score in

each indicator

Scaling

Calculated score per axis

OPTIMUS Rating Chart

OPTIMUS Decision Support System (DSS)

Weather

forecasting De-centralized

data

Social

Feedback

Energy

pricing

Renewable

energy sources

Developing the DSS (1/8) …an overview of the architecture

OPTIMUS DSS will be fed with data sources from multiple domains and it

will support the short-term energy action plans of municipal buildings.

Developing the DSS (2/8) Module 1: Weather Forecasting

Weather can heavily affect energy consumption in a city

(e.g. heating/cooling in public buildings, energy use in

public venues and stadiums, etc.).

By collecting data from weather forecasting we can develop accurate energy-demand

models and map consumer behaviour related to the selected public buildings, which in

turn can be used to help plan and optimise the energy use in the future.

Some of the most relevant parameters that will be taken into account include:

Temperature

Humidity

Wind speed & direction

Solar irradiation

Period of irradiation

Sky coverage

DSS

Developing the DSS (3/8) Module 2: De-centralized Data

Energy monitoring requires a clear definition of the

boundaries of the considered systems and a proper

classification of the captured energy data.

Static data

• Building dimensions;

• Building materials;

• Building destination;

• Occupancy;

• Appliances consuming electricity;

• Instrumentations (e.g. light sensors);

Dynamic data

• Indoor temperature from thermostats;

• Indoor humidity from psychrometers;

• Electricity consumption from counters;

• Natural Gas consumption from counters;

• Thermal flows from calorimeters or other flow meters;

• Occupancy from presence detectors.

Data considered within this module can be distinguished in two main categories:

DSS

Developing the DSS (4/8) Module 3: Social Feedback

Information provided by building occupants can assist the

energy managers in adjusting thermal comfort parameters,

in order to optimize energy use and maintaining comfort

levels in accepted ranges.

The idea is to use input from occupants of the building, reflecting their opinion about

comfort levels in the buildings to help decide what action needs to be taken.

Thermal Comfort Validator, a tool that evaluates thermal comfort at a 7-level scale.

DSS

http://validator.optimus-smartcity.eu

Developing the DSS (5/8) Module 4: Energy Prices

This data- capturing module extracts real-time data on

energy prices available from energy providers within

the local markets.

Prices will be evaluated for the following energy types:

• Thermal energy (Solar Thermal Energy, District Heating, Natural Gas, Biomass, LPG, others);

• Electricity (PV Energy Production, Wind Energy Production, National Grid Electricity, others).

DSS

Developing the DSS (6/8) Module 5: Energy Production

This module will collect data on the production of energy

from renewable energy facilities available in the city and

will match them with the energy demand profiles in order

to propose the optimal energy management solution.

The energy production is classified according to the kind of source (solar, wind, water

power, renewed biomass, etc.) and the kind of energy produced (electricity, heat).

DSS

User requirements

methods:

• User/group interviews

• Prototyping

• Use cases

• Brainstorming

Sant Cugat

Buildings: 2

Total surface: 18.593m2 Renewable generation: PV plant (23 MWh) Thermal power: 850 kW Electrical power: 440 kW Total energy consumption: 2157kWh/m2

CO2 emissions: 86kgCO2/m2

Logged as: David Hernández Log out

Building description

Building use: Office Address: Plaça de la Vila, 1 Year of construction: 2007 Surface: 8.593m2 Floors: 6 Occupation: 350 employees, 400 visitors

Configuration

Town hall Status: No action required Last action: 15 / 04 / 2014 8:00

Building description

Building use: Cultural Address: Plaça de la Vila, 1 Year of construction: 2010 Surface: 9.593m2 Floors: 6 Occupation: 35 employees, 800 visitors

OPTIMUS DSS – Sant Cugat

Sant Cugat > List of buildings

Partitions

23 Sensors

23 Action plans

3

Configuration

Partitions

8 Sensors

11 Action plans

2

Theatre Status: Action required Last action: 15 / 03 / 2014 8:00

Developing the DSS (7/8) The user interface

Developing the DSS (8/8) The user interface

Logged as: David Hernández Log out

OPTIMUS DSS – Sant Cugat

Sant Cugat > Town Hall > Action Plan: Optimum start/stop of the heating/cooling system

Town Hall

Building use: Office Address: Plaça de la Vila, 1 Year of construction: 2007

Surface: 8.593m2 Floors: 6 Occupation: 350 employees, 400 visitors

Energy rating: D Renewable generation: PV plant (23 MWh) Thermal power: 850 kW Electrical power: 440 kW Total energy consumption: 357kWh/m2

CO2 emissions: 86kgCO2/m2

Action Plan: Optimum start/stop of the heating/cooling system

Description: Control of pre-heating/cooling of the rooms based on schedules and

weather forecasts

Last forecast calculated: 9 / 11 / 2014 8:00

Piloting the DSS (1/2) Meet the three pilot cities

Savona (Italy)

Zaanstad

(Netherlands)

Sant Cugat del Vallès

(Spain)

This web-based decision support system

(DSS) will be tested and validated through

pilot applications in three different cities:

• Savona (Italy),

• Sant Cugat del Vallès (Spain)

• and Zaanstad (The Netherlands).

OPTIMUS will have, by design, the

necessary degree of generalisation so as

to be easily adapted to cities with different

characteristics.

Zaanstad Sant Cugat Savona Campus

Proposed actions for energy optimisation

Baseline review using SCEAF

Piloting the DSS (2/2) The process

Meetings with:

The Energy Manager of Savona Municipality

ARE Project Manager –in charge of Savona SEAP

School Director

School Thermal Plant Manager

Information Collection:

Municipality’s energy profile & targets set

Technical characteristics of installed equipment

School’s operating schedule

Pilot site visits – Savona (1/2)

Participation from:

NTUA, D’APPOLONIA, POLITO, IPS

Checklist of documents:

Colombo-Pertini school energy profile summary

A version of Savona’s SEAP

Energy bills and records, thermal and electricity, past 3 years

Energy Certificate and building plans of school

Operating schedule of school and gym

Technical datasheets of boilers, heating pump, A/C, PV plant

Task 4.1

Application of Smart City ex-ante Assessment

Framework on the cities

Pilot site visits – Savona (2/2)

Detected possibilities to improve energy efficiency

Space heating

Domestic Hot Water (DHW) Production

Lighting system

PV system maintenance

Action Plan Idea Involved equipment Output of the system

Programming of the space heating

system according to the real energy

needs, to propose an operational

schedule

Sectioning the 4 main heat distribution lines,

installation of thermostatic valves and

variable flow rate distribution pumps.

Schedule for switching on and

off the boilers, definition of

duration and distribution lines to

be switched on and off.

Optimal management of DHW

Production according to the real use of

the school

Use of the main gas boiler, instead of

electricity, installation of timer-driven switches

on remaining electric boilers to operate only

during low tariff times.

A weekly schedule of switching

on/off the boilers

Optimally maintaining the PV of the

school, by comparing the observed

energy production with the expected

Exploitation of the Savona Campus DEMS

that predicts PV energy production

Weekly indication of expected

production

Indicative possible DSS action plans

Task 4.1

Application of Smart City ex-ante Assessment

Framework on the cities

Meetings with:

Key staff members of the Zaanstad municipality

BMS company representatives

Town Hall Thermal Plant Manager

Information Collection:

Building’s energy profile

Technical characteristics of installed equipment

Town Hall’s operating schedule

Occupancy levels

Pilot site visits – Zaanstad (1/2)

Checklist of documents:

Electricity and gas records for 2013 and previous years

Energy Certificate and building schematics

Operating schedule of the Town Hall

Technical data sheets of heating pump, ventilation

system, cassette units

Participation from:

NTUA, D’APPOLONIA, POLITO

Task 4.1

Application of Smart City ex-ante Assessment

Framework on the cities

Pilot site visits – Zaanstad (2/2)

Detected possibilities to improve energy efficiency

Action Plan Idea Involved equipment Output of the system

Programming of the space heating

system according to humidity and

temperature levels

Adjustment of the BEMS accepted levels

of relative humidity and temperature

Passage to a HVAC regulation system

allowing variable flow rate in ventilation

Weekly indication of accepted levels

of relative humidity and

temperature

Change of staff’s working places

according to the cool and the hot areas

of the building

Tracking of employees working positions

via the Flexwhere system

Weekly suggestions of working

places

Change of the base temperature, which

is set at 22o Celsius throughout the

whole year

Adjustment of the BEMS temperature set-

point

Suggestion for setting higher or

lower base temperature

Space heating

Domestic Hot Water (DHW) Production

Occupancy

Indicative possible DSS action plans

Task 4.1

Application of Smart City ex-ante Assessment

Framework on the cities

Meetings with:

The Environmental Manager of Sant Cugat’s

Municipality

Building Maintenance Technicians

Energy, Land and Urban Quality Managers

Technical personnel of the Town Hall and Theatre

Information Collection

Municipality’s energy profile and targets set

Technical characteristics of equipment

Pilot site visits – Sant Cugat (1/2)

Checklist of documents:

Electricity and gas records and bills of previous years

Operating schedule and building schematics

Technical data sheets of equipment

Samples files of the database from the Flexwhere system

Energy production records of the Town Hall’s PV system

Funds spent on purchasing EnEf and RES equipment

Participation from:

NTUA, FUNITEC, D’APPOLONIA, POLITO

Task 4.1

Application of Smart City ex-ante Assessment

Framework on the cities

Pilot site visits – Sant Cugat (2/2)

Detected possibilities to improve energy efficiency

Space heating and cooling

Lighting system

PV system (Town Hall)

Occupancy

Indicative possible DSS action plans

Action Plan Idea Involved equipment Output of the system

To

wn

Hall

Optimization of air-conditioning

profiles using free cooling instead of

the heat pump

Update of the BMS (Desigo system)

Adaptation of air-conditioning electric

load to the present and foreseen

production of the PV plant

Weekly schedule of switching on/off

the air-conditioning system

Scheduling of pre-heating and cooling

of the rooms, according to occupancy Adaptation of the BMS

Weekly schedule of switching on/off

the respective systems

Th

ea

tre

Optimal use of electrical equipment

according to measured and forecast

occupancy (which is highly variable)

Operating Schedules

Installation of BEMS

A weekly schedule based on

upcoming scheduled rehearsals,

past occupancy data, approximate

durations, employees’ habits

Change of staff’s working places

according to the colder and hotter

areas of the building

Operating Schedules

A weekly schedule of working

places based on temperature,

humidity and lighting conditions

Task 4.1

Application of Smart City ex-ante Assessment

Framework on the cities

Stay in touch For the latest news and updates you can join us online

Website: www.optimus-smartcity.eu

Twitter: @OPTIMUS_EU

Newsletter: sign up by visiting our website

YouTube: Optimus-Smarcity.eu

Facebook: OPTIMUS

LinkedIN: OPTIMUS

OPTIMUS Web-based Tools

Thermal Comfort Validator

OPTIMUS SCEAF Tool

http://sceaf.optimus-smartcity.eu/

http://validator.optimus-smartcity.eu/

Assess the performance of a building in

terms of energy optimization, CO2

emissions reduction and energy cost

minimization.

Declare your thermal sensation

inside a building

Contact:

Siegfried Zoellner

Coordinator, Sustainable Resources, Climate & Resilience

ICLEI European Secretariat GmbH (ICLEI Europe)

Leopoldring 3

D-79098 Freiburg

Germany

Tel.: +49-761 - 3 68 92-0

Email: siegfried.zoellner@iclei.org

This project has received funding from the European Union’s Seventh Programme for Research, Technological Development and Demonstration under Grant Agreement No. 608703.

Thank you for your attention! www.optimus-smartcity.eu