54

DARNIOJI ARCHITEKTŪRA IR STATYBA
2014. No. 2(7) 

JOURNAL OF SUSTAINABLE ARCHITECTURE AND CIVIL ENGINEERING
ISSN 2029–9990

Concept of Smart City: First Experience from City of Riga

Zajacs Aleksandrs*, Zemitis Jurgis ,Tihomirova Kristina, Borodinecs Anatolijs

Riga Technical University, Faculty of Civil Engineering, Institute of Heat, Gas and Water Technology, Azenes str. 16/20, 
LV-1010, Riga, Latvia. 

*Corresponding author: aleksandrs.zajacs@rs.lv

  http://dx.doi.org/10.5755/j01.sace.7.2.6932

Growing concern of smart city development and urban resilience has become increasingly embedded in urban planning, 
national security and energy policy. One of the main city documents focused on actions and measures to be implemented in 
City is Sustainable Energy Action Plan. Taking into account specifics of modern cities and future city development at Smart 
City level the existing Sustainable Energy Action Plans should be enhanced. Nowadays it is necessary to bring existing 
standalone energy actions at cross sector level in order to ensure urban resilience. Currently there are 3414 cities across 
the Europe and eastern partners which already have developed Sustainable Energy Action Plan. The paper draws attention 
to areas with high impact to smart city development. In terms of Smart Cities the most powerful actions are those which 
directly affect at least these three sectors – energy, ICT and transport.

Paper provides some Good Practice examples from city of Riga. The losses of the heat transmitted to consumers by JSC 
“Rigas Siltums” – main heat supplier of Riga have been decreased by 667 thous. MWh or 2.45 times in comparison to year 
1996/1997. Following the completion of reconstruction of the boiler houses, construction of a biofuel fired water heating 
boiler, construction of the biofuel fired cogeneration plant, installation of flue gas condensers for biofuel fired boilers at 
the DHP the share of biofuel utilisation within the fuel balance of the JSC „RĪGAS SILTUMS” will reach 20.4  % in fiscal 
year 2013/2014. The total energy produced from renewable energy sources since 01.01.1996 until 8.04.2014 is 920463.107 
MWh.

The project “Heat meters automatic remote reading system” proved to be a successful and reliable solution for the 
control and accounting of consumed heat, as well as related tasks enabling “online communication” with 8000 individual 
heating units throughout the Riga city.

Development and introduction of electric cars and filling station infrastructure in Riga was one more step on the way to 
the SMART CITY status. Despite a fairly long payback period electric cars are quite beneficial solution for some companies 
whose activities are related with vehicles’ high mileage within the city as LLC “Rigas Satiksme”.

Keywords: smart city, sustainable resources, urban resilience.

1. Introduction

During recent years, people have become aware that 
environment in the city is comprehensive resource that 
requires smart management. This has lead to increased 
need for use of sustainable resources and development 
of sustainable cities with integrated smart disciplines – 
economics, energies, technologies, architecture and politics. 
Major attention must also be paid to city resilience planning 
due to its importance for any city’s development as well as the 
national securitization process by becoming better prepared 
and more responsible for national risk management. City 
security and public resilience have become increasingly 
embedded in urban planning, national security and energy 
policy (Coaffee J., 2008). City designers should remember 
that a smart city involves not only smart technologies, 

but also smart economy, governance, mobility, living, 
environment and people (Giffinger et al., 2007). The key 
concepts of urban resilience are sustainability and adaptation 
to climate changes (Leichenko R., 2011). By words “city 
resilience” typically is understood – sustainable energy 
management, securing stable energy supply, reducing 
energy consumption, developing renewable energy sources 
(Coaffee J., 2008) and also security policy focused on 
terrorist hazards and natural disasters (Collier et al., 2013).

This paper explains the synergy between main city 
dimensions such as energy, economics and stakeholders and 
different urban sector development levels. The aim of this 
paper was to draw attention to areas with high impact to 
smart city development process.



55

2. City strategic energy action plan

Modern cities can achieve EU20-20-20 goal only 
by improvements in all major sectors such as buildings, 
energy and transport. Each European City is free to choose 
their approach for achievement of EU20-20-20 target. The 
main document which defines actions and measures to be 
implemented in each City in order to reach CO2 reduction by 
20  % is Sustainable Energy Action Plan (SEAP). According 
to Covenant of Mayor (www.covenantofmayors.eu) data 
there are 3414 cities across the Europe and eastern partners 
which already have Sustainable Energy Action Plan.

Typical Sustainable Energy Action Plan is focused on 
standalone actions such as insulation of buildings, use of 
efficient lighting, local renewable energy sources and etc. 

Nowadays the existing SEAP should be enhanced 
taking into account requirements for Smart Cities. Although 
there is no global definition of Smart City (Neirotti et al., 
2014) the Smart Cities general concept can be characterized 
as improvement of urban performance by implementation 
of information and communication technologies (ICT) and 
by engagement of stakeholders. In addition more cross-
sector energy actions should be introduced. Currently there 
are activities to start standardization activities in field of 
sustainable development and smart cities (Marsal_Llacuna 
et al., 2014). 

Efficiency and impact of each energy action should 
be evaluated on 3D scale taking into account sector, city 
dimension and implementation scale. The major city 
dimensions which characterize each energy action are 
“energy and technology”, “economics and finance” and 
“organization and stakeholders”. Interaction between 
city dimensions and scale for each sector is shown in  
Fig. 1. Each indicator impact is evaluated at implementation 
scale. This approach enables us to understand whether the 
implementation of actions is proportional to the city’s scale 
and dimension in each sector.

Fig. 1. Evaluation of dimension and scale of energy actions

For example, if city wants to realize existing building 
renovation at city scale the “economics and finance” and 

“organization and stakeholders” should be addressed at 
proper level. The public/private finances should be used 
including ESCO (Energy Service COmpany) model and 
active work with wide range of stakeholder groups is 
necessary.

Example of “energy and technology” indicator of 
building renovation process at different scale is shown in 
Fig. 2.

Fig. 2. Example of building renovation process on “energy and 
technology” dimension

In case of building renovation the component scale 
includes single building renovation. The district scale 
may include grouped building renovation. According to 
Borodinecs et al. (2013) the estimated savings can be 
about 10  % due to grouping development, compared to the 
component scale renovation. The city scale renovation can 
include analysis of different building renovation scenarios 
and future city energy flow planning.

As mentioned above, nowadays cross-sector energy 
action is one of main parts of Smart City. As a rule the cross 
sector action needs to have information and communication 
technologies. As an example of cross sector action smart 
electricity grids supporting filling of electric cars can be 
mentioned. Such solution enable charging load of electric 
vehicles (EV) to be shifted to off-peak periods, thereby 
significantly reducing both generation and network 
investment needs and enables customers to schedule 
charging intelligently (Morgan, 2012).

3. Designing of smart city

Urban growth and social changes is a rapid and never 
ending process nowadays. Adapting to the challenges require 
ways for efficient development of smart city. The models of 
smart cities should contain a lot of important compounds: 
social network, economics, community capacity, 
infrastructure, geographical location of city ecosystem 
services, political will and history also (Collier et al., 2013). 
The development process must be related to civil protection, 
risk assessment and evaluation of the post risk strategies. 
The plans should cover all city communications (heat, gas 



56

and water networks and distribution systems, starting from 
protection of the sources until the end consumer). Only the 
synergy between all compounds can guarantee resilient 
evolution of intelligent and smart environment. Of course, 
the urban communities must be central component of 
stakeholders in evolution process. 

It is essential to provide possibilities of sharing the 
experience about smart city design and planning between 
cities and communities. Most successful and beneficial 
projects have to be repeated and recreated widely in Europe 
considering local differences in technical features of 
infrastructure. In terms of Smart Cities the most powerful 
actions are those which directly affect at least these three 
sectors – energy, ICT and transport. Dissemination of such 
projects across the Europe will be possible due the fact that 
the projects have already been approved and implemented 
in other cities. Also energy saving potential can be assessed 
more accurately and possible shortcomings or limitations 
considered due to existing experience. It can be called 
Good Practice, which in the context of INTERREG IVC 
programme is defined as an initiative (e.g. methodologies, 
projects, processes, techniques) undertaken in one of the 
programme’s thematic priorities which has already proved 
successful and which has the potential to be transferred to 
a different geographic area. Proved successful is where the 
good practice has already provided tangible and measurable 
results in achieving a specific objective. The Good Practice 
examples and detailed descriptions could be found following 
the link – http://i4c.eu/ficheGoodpractices.html?id=234.

4. Cross-sector actions in district heating

District Heating network
The Joint Stock Company „RĪGAS SILTUMS” is the 

biggest District Heating Company in Latvia and in the Baltic 
countries which is engaged in the production, transmission, 
distribution and sales of heat, the simultaneous production 
of heat and generation of power in cogeneration plants, 
as well as the servicing of district heating networks and 
systems in Riga city. Heat is produced in 43 heat sources, 
including 5 District Heating Plants (DHP) and 38 automated 
gas-fired boiler houses (BH).

Security of district heating and amount of transmission 
heat losses directly depend upon the technical condition of 
heat networks and their elements. In the result of the work 
invested over a long period of time the losses of the heat 
transmitted to consumers of city of Riga have decreased 
by 667 thous. MWh or 2.45 times in comparison to year 
1996/1997 (Fig. 3.). 

During last fiscal year the Joint Stock Company 
implemented large scale reconstruction of a section of the 
district heating network main pipeline section M-1 with 
the total length of 1228 m along Brīvības street, where 
the obsolete pipelines were replaced by new 600 mm pre-
insulated pipelines, which were installed according to the 
non-channel technology and equipped with a special alarm 
system which permits to find the location of a damage in a 
fast and accurate manner and connected to the automatic 
remote reading system. Co-financing of the European Union 
Cohesion Fund was used for implementation of this project.

Fig. 3. Heat losses in district heating network [Source: ANNUAL 
REPORT, JSC „RĪGAS SILTUMS”, 2012]

Heat production from renewable energy sources
For the future sustainable development of the district 

heating system, a few important production development 
projects have been implemented during the last years, which 
will allow to achieve considerable savings of fuel and to 
diversify the fuel, thus improving security of heat supply.

The reconstruction of the boiler house at Gaileņu street 
14 was implemented in fiscal year 2011/2012. The obsolete 
water heating boilers were replaced and two water heating 
condensation type boilers with the heating capacity of 1.8 
MW were installed. Condensation type boilers provide the 
operational efficiency of boilers which is 7–15  % above that 
of traditional boilers.

The Joint Stock Company, complying with the 
principle of economic profitability and state support for 
use of renewable energy resources in energy, plans to 
expand the use of bio-fuel in heat supply and to reduce heat 
losses in the district heating transmission; co-funding of 
the European Union funds will be used for these purposes 
also in future. According to the current trends of the JSC 
„RĪGAS SILTUMS” in the upgrading of the heat sources 
the share of natural gas is to be decreased by increasing the 
share of biofuel in the fuel balance and the Technologies 
ensuring the highest possible efficiency of the operation of 
facilities are to be used.

The construction of the biofuel fired cogeneration 
plant of DHP “Ziepniekkalns” with heat capacity up to 22 
MW and the electrical capacity up to 4 MW was completed 
in February 2013. The co-financing of the Cohesion Fund of 
the European Union has been granted for the implementation 
of this project. It is planned to use biofuel, i.e. wood chips, in 
this cogeneration plant. The implementation of this project 
will result in the increase of the share of biofuel in the fuel 
balance of the JSC „RĪGAS SILTUMS” by 4.7  %.

Modernisation of the DHP „Zasulauks”, which 
includes construction of a biofuel fired water heating boiler 
with the heating capacity of 20 MW which will operate 
at a high degree of efficiency and automation, without 
permanent operating personnel was completed in May 
2013. The implementation of this project will result in the 



57

increase of the share of biofuel in the fuel balance of the JSC 
„RĪGAS SILTUMS” by 6.3  %.

The implementation of the project „Installation of 
flue gas condensers for biofuel fired boilers at the DHP 
„Vecmīlgrāvis” within the framework “Measures for 
improving efficiency of district heating systems” of the 
operational program “Infrastructure and Services” in April 
2014 will result in the increase of the share of biofuel in 
the fuel balance of the JSC „RĪGAS SILTUMS” by 1  % on 
average.

Following the completion of implementation of the 
above referred projects the share of biofuel utilisation within 
the fuel balance of the JSC „RĪGAS SILTUMS” will reach 
20.4  % in fiscal year 2013/2014 (Fig. 4.). The total energy 
produced from renewable energy sources since 01.01.1996 
until 8.04.2014 is 920463.107 MWh.

Fig.  4. The increase of the share of biofuel utilisation in heat 
sources, % [Source: ANNUAL REPORT, JSC „RĪGAS SILTUMS”, 
2012]

Heat meters automatic remote reading system in JSC 
“Rigas siltums» - Riga city. 

There are four main steps. Each building with heat 
substation and heat meter is equipped with automatic 
remote reading system, which is used for data reading of 
heat consumption (in accordance with client need, it can be 
connected to other data reading, such as cold, hot water or 
electricity). In addition, there is an antenna placed outside 
of a building. The data transfer is done by radio waves 
to special transponders and base stations (not only radio 
waves, but also GSM or fixed data connection can be used) 
Figure 5.

Further all data by fixed network is transferred to 
central data base. From this point, there are two possibilities 
how the data can be used – Web interface, where operators 
can use the information by connection points or by clients, 
for example in on-line form all heat meters can be read. 
Second option is related to commercial readings such as 
invoice preparation. Data is collected in Oracle data base 
and then after processing all the invoices can be generated. 
All data from all 8000 heat meters can be accessed in three 
hours. 

Fig. 5. Automatic remote reading system concept

Before implementation of this system employees of the 
heat supply company JSC “Rīgas siltums” had to read data 
from meters on the first day of each month directly in each 
object and form report on energy consumption. Afterwards 
employees have to enter received readings into the data base. 
Automatic meter remote reading system makes records for 
all heat meters data in a given time by writing in the current 
system, excluding human factors on current data quality 
and minimizing potential errors. Reading data at a specific 
time enables accurate heat data analysis and evaluation of 
each user’s heat consumption dynamics. This system can 
be linked to other IT systems for technical, analytical or 
customer services needs. Total contract amount was 1.87 
million LVL excluding VAT, or 2.26 million LVL with VAT.

The main benefits of implementing this practice are as 
follows:

 ▪ Operative information on heat loses and operation 
of heat meters. The potential heat problems can 
be quickly identified and remedied, improving the 
quality of services; 

 ▪ Less time-consuming billing; 
 ▪ A smaller amount of error due to automatic data 

entry; 
 ▪ Broader customer service options; 
 ▪ Optimization of human resources.
 ▪ Possibility to prevent theft of heating unit 

equipment
 ▪ Transmission of conjugate data such as state of 

alarm surveillance system of pre-insulated district 
heating pipes 

5. Cross-sector actions in transport sector

Urban growth and social changes nowadays is a rapid 
process. Adapting development and introduction of electric 
cars and filling station infrastructure in Riga was approved 
by Riga City Council in the Riga City Sustainable Energy 
Action Plan 2010–2020th (SEAP). With the acceptance 
of Riga City Council Riga Municipal Limited Liability 
Company “Rigas satiksme” has attracted on lease agreement 
basis five electric cars for use of its technical services, whose 
daily work is connected to monthly run in average 2000km. 
Because of relatively high cost of introduction of electric 
cars, it pays off only with relatively high mileage. For a 
majority of PHEV (plug-in hybrid electric vehicles) designs 
and vehicle classes, PHEVs show a payback period of less 



58

than 6 years. However, many of the common components of 
TCO (e.g. maintenance costs, title and registration renewal 
costs, and salvage value) are not represented in all studies, 
and payback period is shown to vary between 6 and 12 years 
(Baha M. Al-Alawi, Thomas H. Bradley, 2012). 

In 2013 the state was supported introduction of electric 
cars and development of filling stations infrastructure (Fig.6.) 
in co-financing from Climate Change Financial Instrument. 
After this Riga City Council has taken the next step and 
has sponsored project “Electric fast filling station placement 
schemes for the development of Riga” realization. It should 
be noted that the government is interested in promoting 
the use of electric cars, improving urban air quality and 
mitigation of global climate change.

Fig. 6. Scheme of fast charging points distribution in development 
stage in Riga.
[Source:http://www.latvenergo.lv/portal/page/portal/Latvian/
latvenergo/main_page/korp_atbildi/UZLADES_PUNKTU_
KARTE/]

Selected electronic car type is manufactured by the 
Finnish company “Valmet Automotive”, designed from 
Norway, and already passed performance tests in the Nordic 
countries. This type of car is well known in Europe as 
several thousands are already sold. These cars are front – 
wheel driven, with two front seats and 800 litres car trunk. 
With one charging time the electric car is able to go 120– 
150 km, the time spent for one charge is 6–8 hours, and this 
type of car can develop a speed of 112 km / h. The warranty 
period is two years or 150 000 km. Charging is carried out 
in the normal grid with capacity 220V.

6. Conclusions

The smart city development process is a complex 
process affected by a wide range of different factors. The 
most important parts are economic, politic and social sectors 
and the engagement of wide range of stakeholders, which 
should be dynamic, flexible and ready to changes. 

Currently there are 3414 cities across the Europe and 
eastern partners which already have developed Sustainable 
Energy Action Plan. The overall aim of these plans is to 
reduce energy demand and to provide the smart use of 
resources and make the basic contribution in advancement 
of cities environment, climate and community health. 
Taking into account the modern requirements to City energy 
consumption and CO2 emissions, the standalone energy 
actions should be integrated at cross sector level. 

In order to insure urban resilience, all energy actions 
should be adequately addressed at all city dimensions 
and scale. Only the synergy in these areas guarantees the 
evolution of intelligent and smart environment.

As an example of cross-sector actions is introduction 
of information and communication technologies in city’s 
infrastructure providing an opportunity for development of 
urban resilience.

JSC “Rigas Siltums” takes part in the development 
of “Riga City Sustainable Energy Action Plan for Smart 
Cities 2014–2020” to significantly exceed the 2020 targets: 
increase energy efficiency and share of use of renewable 
energy sources and to further reduction of CO2 emissions.

District heating network is a subject of constant 
improvement and in the result of the work invested over 
a long period of time the losses of the heat transmitted to 
consumers of city of Riga have decreased by 667 thous. 
MWh or 2.45 times in comparison to year 1996/1997. 

Following the completion of reconstruction of the 
boiler houses, construction of a biofuel fired water heating 
boiler, construction of the biofuel fired cogeneration plant, 
installation of flue gas condensers for biofuel fired boilers 
at the DHP the share of biofuel utilisation within the fuel 
balance of the JSC „RĪGAS SILTUMS” will reach 20.4  % 
in fiscal year 2013/2014. The total energy produced from 
renewable energy sources since 01.01.1996 until 8.04.2014 
is 920463.107 MWh.

The project “Heat meters automatic remote reading 
system” proved to be a successful and reliable solution for 
the control and accounting of consumed heat, as well as 
related tasks enabling “online communication” with 8000 
individual heating units throughout the Riga city. 

Development and introduction of electric cars and 
filling station infrastructure in Riga was one more step on 
the way to the SMART CITY status. Despite a fairly long 
payback period electric cars are quite beneficial solution for 
some companies whose activities are related with vehicles’ 
high mileage within the city as LLC “Rigas Satiksme”. 

Acknowledgment

This paper is prepared under EU Seventh Framework 
Programme (FP7) project “Strategies Towards Energy 
Performance and Urban Planning” http://www.
stepupsmartcities.eu/. Authors wish to thank project 
partners for contribution to project development and support 
in understanding of Smart Cities and Sustainable Energy 
Action Plan.

References

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Received 2014 04 22 
Accepted after revision 2014 05 29

Aleksandrs ZAJACS – (Mg.sc. ing.) Institute of Heat, Gas and Water Technology, Faculty of Civil Engineering, Riga 
Technical University.
Main research area: district heating.
Address:  Azenes str. 16/20 , LV – 1010, Riga, Latvia.
Tel.:  +371 29874677
E-mail:  aleksandrs.zajacs@rs.lv

Jurgis ZEMITIS – (Mg.sc. ing.) Institute of Heat, Gas and Water Technology, Faculty of Civil Engineering, Riga Technical 
University.
Main research area: energy efficiency of buildings.
Address:  Azenes str. 16/20 , LV – 1010, Riga, Latvia.
Tel.:  +371 28369940
E-mail:  Jurgis.Zemitis@rtu.lv

Kristina TIHOMIROVA – (Dr.sc.ing.) Institute of Heat, Gas and Water Technology, Faculty of Civil Engineering, Riga 
Technical University.
Main research area: water supply and purification.
Address:  Azenes str. 16/20 , LV – 1010, Riga, Latvia.
E-mail:  kristina.tihomirova@rtu.lv

Anatolijs BORODINECS – (Dr.sc.ing.) Institute of Heat, Gas and Water Technology, Faculty of Civil Engineering, Riga 
Technical University.
Main research area: energy efficiency of buildings. 
Address:  Azenes str. 16/20 , LV – 1010, Riga, Latvia.
Tel.:  +371 26079655
E-mail:  anatolijs.borodinecs@rtu.lv