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ISSN (Print: 2357-0849, online: 2357-0857)

International Journal on:

Environmental Science and Sustainable Development

DOI: 10.21625/essd.v4i1.490

Energy Rehabilitation of Social Housing in Vulnerable Areas
Case study: a 1950s Building in a Medium-sized Mediterranean City

Ruá Marı́a José1, Huedo Patricia1, Cabeza Manuel2, Saez Beatriz2, Civera Vicente1
1Mechanical Engineering and Construction Department

2Industrial Systems Engineering and Design Department. Jaume I University

Abstract
In the urban context, buildings play a key role as they are energy consumers. In well-established cities with a
high percentage of aged building stock, the focus should lie on sensitive urban areas where the weakest population
sectors and the worst physico-economic conditions are usually encountered. In this work, the energy refurbishment
of social housing is proposed. A block of municipally owned buildings is selected as a case study to consider that
public buildings play an exemplary role according to Directive 2012/27/EU. The group is formed by 12 buildings,
which account for 120 dwellings.

This study is grounded on two levels. First the urban level. The building is located in a prioritised urban Area
of Rehabilitation, Renovation and Urban Regeneration (ARRU), according to the new local Land Plan. This area
presents multidimensional vulnerability and considers urban, building, socio-demographic and socio-economic
features. Second, the building presents very low energy performance. It was built in 1959 when a high demand of
dwellings and the economic resources then available led to low-quality buildings that are far from meeting today’s
standards.

Some proposals are made, having in mind the specific features of the urban context. The energy refurbishment
of the building is proposed, selecting the optimal solution, considering technical, environmental and economic
criteria. The energy performance simulation shows a remarkable improvement of the energy performance, resulting
in an improvement of the thermal comfort of the dwellers. Besides, a reduction in the energy consumption is
reached, which would reduce the energy bills and, on the other hand, a reduction of the carbon emissions to the
atmosphere, contributing to a better environment quality. Having in mind that the building is intended for social
housing, energy poverty situations could be avoided, as dwellings are inhabited by low-income dwellers.

© 2019 The Authors. Published by IEREK press. This is an open access article under the CC BY license
(https://creativecommons.org/licenses/by/4.0/). Peer-review under responsibility of ESSD’s International Scien-
tific Committee of Reviewers.

Keywords

Rehabilitation; Social Housing; Energy Performance; Vulnerability; Urban Areas

1. Introduction

Cities and urban settlements consume lot of resources and generate emissions and waste, which spells detrimental
environmental effects. Buildings have a strong impact as they consume resources such as land, water and energy.
They are also responsible for one third of the green gases emissions that reach the atmosphere. However, buildings

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are necessary to live in and to conduct human activities.

According to the 11th Sustainable Development Goal (SDG) of the United Nations, for sustainable cities and
communities, the objective is “to make cities inclusive, safe, resilient and sustainable”. This implies urban sustain-
ability involving social inclusion. Within this new framework, distressed areas should be firstly observed as they
present high physical and social vulnerability. The latter implies the incapacity of some groups and individuals to
solve their housing needs. Therefore, these areas should be prioritised by the authorities to undertake urban plan
actions.

Hence the building should be analysed from a holistic perspective by considering its urban context and interactions
with citizens. The well-established urban areas with many initial limitations are especially challenging because
very often they present old obsolete buildings inhabited by vulnerable populations.

This work proposes the energy refurbishment of social housing. The selection of the building was based on a
threefold perspective. On the one hand, the typology of the block of buildings, together with the constructive
analysis, show a low-quality building with a typology dating back to a time where resources were scarce and, con-
sequently, energy performance was very poor. Earlier studies have identified urban areas in Spain with inefficient
buildings, which have been linked with their construction period (Martı́n-Consuegra, Hernández-Aja, Oteiza &
Alonso, 2016).

Second, social housing is intended for low-income people at risk of social exclusion. Last, but not least, the
building is a municipal property, so its refurbishment should reinforce the exemplary role that the authorities play
(Energy Efficiency Directive, EDD 2012/27/EU) regarding the renovation of existing buildings.

2. Methodology

Some stages were followed (see Figure 1) to undertake this work. First, the case study was selected according to
three main pillars. On the one hand, the urban area was selected based on a previous work in which vulnerable
urban areas of the city were defined. On the other hand, the building’s poor energy performance was the main
observed feature. Finally, the building’s social housing condition guaranteed vulnerable dwellers, e.g., low-income
citizens.

Figure 1. Methodology

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Once the building was selected, a diagnosis of its current state was made by analysing the scarce available project
information and visiting the site to collect complementary and necessary information. This permitted the building
to be simulated in officially recognised software to determine its energy performance. The third stage consisted in
analysing the refurbishment solutions and selecting the optimal solution according to a multicriteria analysis after
bearing in mind the actual conditions the building was in by looking for a real applicable one.

The fourth stage consisted in determining the building’s energy performance after refurbishment. Finally, economic
feasibility was estimated by the cost-optimal method to acquire an order of magnitude of the investment and other
costs.

3. Background

3.1. Vulnerable urban areas

The definition of Areas of Rehabilitation and Urban Renovation and Regeneration (ARRU) is included in new
Spanish urban plans to contribute to sustainable development by structurally intervening in the city (LOTUP, 2014).
This intends to support those responsible for local administration decision making by selecting the urban areas that
require priority interventions and to undertake durable actions over time. Therefore, the buildings included in an
ARRU would be prioritised when addressing potential refurbishment subsidies. Moreover, considering the most
vulnerable areas will affect the whole city’s substantial improvement.

3.2. Social Housing

One of the first obligations that Franco’s Government had to face after the end of the Spanish Civil War was to
reconstruct the country. One major part of this work was to recover urban areas, which entailed not only repairing
destroyed heritage, but also constructing new housing that could accommodate a population with scarce resources.

To fulfil this purpose, immediately after the Civil War was over the first law for low-income housing was in-
troduced, as was the government institution responsible for ensuring the promotion and control of building such
housing all over the country, the National Housing Institute (Law 19 April 1939). In this way, apart from updating
the legislation on such interventions, governmental institutions sought to tightly control the promotion of public
housing, so it was left as a private initiative on the sidelines (Gómez, 2004).

However, the economic precariousness that the country was in during the first post-war period years did not allow
the agreed quantitative targets for the building stock in successive National Housing Plans to be achieved. During
the first two decades of Franco’s Government, countless laws were introduced (see Table 1) to promote building
stock growth rather than regulate housing.

Table 1. Main Legislation on Social Housing during Franco´s Government. 1939 -1975

Date Introduced Legislation Repealed Legislation
19 April 1939 Law on Protection for a Low-Income

Housing System and establishing the Na-
tional Housing Institute

Law of 12 June 1911
(Law on Cheap Houses)

23 February 1944 Order regulating Basic Hygienic Conditions
for Housing

25 November 1944 Law on contributions and tax reduction to
Build Income Housing for the Middle
Class.

Continued on next page

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Table 1 continued
19 November 1948 Decree-Law that amended Law 25 Novem-

ber 1944 on Protection for a Low-Income
Housing System

Law of 25 November 1944

29 May 1954 Decree-Law to build Social Housing: Low-
Income and Minimum-Income Housing

15 July 1954 Law on Protection of Limited-Income
Housing

Law of 19 April 1939
Law of 25 November 1944
Decree-Law of 19 November 1948

12 July 1955 Order introducing the text of Technical
Ordinances and Building Standards for
Limited-Income Housing

24 January 1958 Decree extending the new type of Subsidised
Housing throughout Spain

24 July 1963 Decree introducing the Revised Text of So-
cial Housing legislation

All previous legislation

20 May 1969 Order introducing the adjustment of Techni-
cal Ordinances and Building Standards to
Social Housing

This objective would definitely not be met until the beginning of the 1960s, in 1963 with the last social housing
legislation of Franco’s Government. Governmental institutions would lose the strong interventionist character they
held thereafter to behalf of the private promoter who was consolidated as a preferred agent in the building of this
type of housing.

Apart from the limited implementation of successive Housing Plans, the economic shortage led to restrict the use
of materials in the building, especially iron (Decree 11 March 1941), to avoid increasing the construction cost of
housing buildings. Consequently for housing, builders were forced to use building systems from the beginning of
the century and use alternative materials in those elements in which steel had become the most suitable option.

This meant a delay in the building technology progress made in Spain as social housing built during the first two
decades of Franco’s Government brings to light. After the Spanish economy opened out to the international scene
and thanks to the Stabilisation Plan of the late 1950s, it managed to overcome years of shortage and, thus, the
liberalisation of building stock, which would lose the tight constructive control normalisation by governmental
institutions (Sambricio, 2004).

4. Case study

4.1. The urban scale

The development of the new Land Use Plan of the city of Castellón de la Plana (Spain) needs to define ARRU.
This definition was created by using 29 ad hoc selected indicators of vulnerability. They were grouped into four
categories: urban (4), building (4), socio-demographic (16) and socio-economic indicators. The ARRU were those
areas where all the categories concurred, so they presented multidimensional vulnerability. As a result, 17 ARRU
were defined in the city (Garcı́a Bernal et al., 2017; Ruá et al., 2017). The building used as a case study in this work
is included in one of the ARRU. The defined ARRU are indicated in Figure 2. The selected block of buildings is
included in ARRU 01. The location of the block is indicated in the top-right corner of Figure 2.

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Figure 2. Situation

4.2. The block of buildings

The block of buildings was built in 1959 as social housing by Ministry of Housing subsidy. The group is formed
by 12 buildings, the north façade, with odd numbers 1 to 11, to Huesca Street, and opposite the Castalia football
stadium. The south façade is in Martı́nez Tena Street, numbers 2 to 12. Figure 3 shows a general view of the block
of buildings. The block forms an internal courtyard and each building is formed by one ground floor and four
upper floors, with two dwellings per floor, which means 10 houses per block and 120 houses in all, which account
for 2339 m2.

Figure 4 shows the front side view and the side elevation plan, section and roof plan. Figure 5 represents a 3D
image of the block using the Revit software, drawn after the visits made to the site.

Figure 3. General view

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Figure 4. Front side view, side elevation, section and roof plans

Figure 5. 3D image of the block

4.3. The building’s energy performance

There are four buildings in the corners of the block, while the rest are terraced buildings which present better
energy performance as they are less exposed to the outer environment. The building located in the north-west
corner (357º north) is the worst in energy performance terms. In order to simplify simulation, only this building
was simulated. There are three types of housing, as seen in the original plans presented in Figure 6, where the
selected building is indicated. Figure 7 shows the floor plan, with dwellings types I and II, included in the building
selected in the block. Dwelling type III is included in the terraced buildings in the block.

Figure 6. Second Floor (Original plans)

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Figure 7. Floor plan of dwellings types I and II

In order to analyze the building’s thermal performance, some starting conditions need to be considered. Regarding
external conditions, and according to Spanish Regulation for Energy Saving, CTE DB-HE1, Appendix D, the
building is located in climatic zone B3 (winter severity B on a scale from A to E, from the warmest to the coldest;
summer severity 3 on a scale from 1 to 4, from the least to the most severe). The thermal envelope characteristics are
summarised in Table 2, where the layers of the constructive solutions are represented, together with the exposed
area and the thermal transmittance data. All this, plus the facilities used to obtain domestic hot water (DHW),
heating and cooling services, in this case electric appliances, will be the starting data to simulate the building to
estimate its energy performance in its current state:

Table 2. Original thermal envelope

Thermal envelope Constructive solution Transmittance U (W/m2K) Figure
Façade 1 Bearing wall formed by double

leaf brick: exterior masonry wall
of ceramic solid brick of 1 foot-
thick with cement mortar joints
+ inner skin of hollow ceramic
brick, 4-cm thick, with cement
mortar joints + plastering.
Exposed area: N 93.41 m2; W
78.93 m2

1.44 Figure 8

Continued on next page

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Table 2 continued
Façade 2 Bearing wall formed by double

leaf brick: continuous outer coat-
ing with cement mortar + ex-
terior masonry wall of ceramic
solid brick of 1 foot-thick with
cement mortar joints + inner skin
of hollow ceramic brick 4 cm-
thick with cement mortar joints +
plastering.
Exposed area: N 190.64 m2; W
100.63 m2; E 57.84 m2; S 169.51
m2

1.29 Figure 8

Windows Wood carpentry with single glaz-
ing.

Carpentry: 2.20
Glazing: 5.50

Figure 9

Roof 1 Flat roof ventilated, trafficable:
Finishing ceramic tiles + mortar
layer 5 cm + bituminous sheet
+ ventilated air chamber + rein-
forced concrete one-way slab 30
cm, ceramic hollow plot + plas-
tering.
Exposed area: 38.83 m2.

1.37 Figure 10

Roof 2 Gable sloping roof ventilated
16º: finishing ceramic gables +
mortar layer + ceramic tiles for
roof slope + ventilated air cham-
ber + reinforced concrete one-
way slab 30 cm, ceramic hollow
plot + plastering.
Exposed area: 116.03 m2.

1.05 Figure 11

Figure 8.

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Figure 9.

Figure 10.

Figure 11.

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To evaluate the building’s energy performance in its current state, the CE3x software was used, the official software
for energy certification in Spain (the open access so

ftware provided by the Ministry of Industry). Using CE3x permits energy demand to be known, energy use and
carbon emissions associated with the building’s use. The software estimates the annual energy demand linked to
heating and cooling in kWh/m2, and the annual CO2 emissions due to heating, cooling and DHW in kg CO2/m2.
The sum of emissions will evaluate energy performance using a scale from A to G, with the best and the worst
energy performance, respectively. This software is widely used professionally, but has also been included in
research works (Alguacil, Lufkina, Reya & Cuchı́, 2018; De Ayala, Galarraga & Spadaro, 2016), specifically to
social housing (Escandón, Suárez & Sendra, 2016) to obtain simulation energy performance values.

The input data in the software result in the energy performance presented in Figure 12. According to the simulation,
the building emits 29.5 kg CO2/m2 due to heating, cooling and DHW, with 15.98, 5.09 and 8.41 kg CO2/m2, re-
spectively. Altogether, the building obtains an E energy label, where DHW presents the worst energy performance,
with F, followed by heating with E and a medium D for cooling.

Figure 12. Energy certification label for the current building

4.4. Energy refurbishment proposal

The next stage consists in analysing some refurbishment solutions to improve the building’s energy performance
and to select the optimal one. To do so, four perspectives are observed: technical, environmental, economic and
heritage. The technical perspective analyses the advantages and disadvantages of actually implementing the con-
structive solution. The environmental perspective is based mainly on the resulting transmittance of the refurbished
solution, together with the reduction of thermal bridges. The economic perspective examines the viability of refur-
bishment. Finally, the building’s heritage value is considered by looking at the aesthetic variation of the building’s
external envelope as it can be representative of the building type built at a particular socio-economic period of time,
as explained in Section 3.2.

Regarding the thermal envelope, the refurbishment aimed to add insulation layers that did not exist in the original
building’s state. Insulation material is generally the most cost-effective solution when buildings are refurbished
(Hamdy, Hasan & Siren, 2011; Ruá & López-Mesa, 2012). This should be done on façades together with im-
provements to carpentries, with double glazing solutions, and also in roofs. Adding insulation on façades and roofs
could be done basically in two ways: on the outer or the inner layer.

Table 3 shows some constructive solutions (Huedo, Mulet & López-Mesa, 2016), along with their advantages,
disadvantages and features by bearing in mind the technical, environmental, economic and heritage perspectives.
The selected solutions are shaded in grey in Table 3 and represented in Figure 13. For façades, inner insulation
(FI) was ruled out because of the dimensions of rooms. It would mean reducing the areas of rooms as they could
not fulfil the minimum required dimensions according to new standards. Therefore, the outer solution with the
External Insulation System was adopted in this case because it was more convenient than the ventilated façade,

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and fell in line with different criteria. The convenience of this solution is supported by other studies (Sierra-Pérez,
Boschmonart-Rives & Gabarrell, 2016) and can be applied to both façade types.

For roofs, the inner solution proved more convenience when looking at advantages and disadvantages. The same
solution involving mineral wool and finishing plaster board could be applied to roof 1(SRI) and roof 2 (FRI).

Figure 13. Façade, sloping roof and flat roof refurbishment solutions

Table 3. Multicriteria analysis of the constructive solutions for the thermal envelope

Thermal
Envelope

Criteria Technical Environmental Economic Aesthetic

Solution Advantages-
disadvantages

U Thermal
bridges

C/m2 Time External variation

Façades
FO1.
Ventilated
façade

Medium-high
level of difficulty
Requires scaffold-
ing
Does not interfere
with users
High embedded
energy due to
the aluminium
substructure

0.49 Reduced 158.50 Medium High

FO. Ex-
ternal
Insulation
System

Medium-low level
of difficulty
Requires scaffold-
ing
Does not interfere
with users

F1:
0.49

F2:
0.47

Reduced 90.35 Medium Medium

FI. Inner
mineral
wool and
plaster
board

Low level of
difficulty
Interferes with
users
Does not ful-
fil minimum
dimensions

0.48 Equal 27.99 Short None

Continued on next page

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Table 3 continued
Sloping
Roof

SRO. XPS
(extruded
polystyrene)
under the
finishing
layer

High level of diffi-
culty, the finishing
roof layers are re-
moved to add in-
sulation
Requires scaffold-
ing
Does not interfere
with users

0.44 Equal 93.47 Long None

SRI. Inner
mineral
wool and
plaster
board

Low level of
difficulty
Interferes with
users

0.44 Equal 27.99 Short None

Flat roof FRO. XPS
and gravel
over the
finishing
layer

Adds loads to
slab. It requires a
structural analysis

Does not interfere
with users

0.49 Equal 75.08 Short None

FRI. Min-
eral wool
and plaster
board

Low level of
difficulty
Interferes with
users
The same solution
for the two roof
types

0.44 Equal 27.99 Short None

Theoretically, other measures can be proposed. For example, solar energy to cover a high percentage of DHW
demand could have been proposed. However, this would need a further structural analysis to check that the structure
would support the new load added by fitting solar energy. The presented proposal is intended mainly to be realistic
and economically viable by considering the building’s socio-economic features.

4.5. Energy performance after refurbishment

The selected construction solutions, together with improved facilities, by going from electrical new boilers to
condensed natural gas ones, shows a relevant improvement in energy performance and reduced annual carbon
emissions from 29.5 to 15.3 kg CO2/m2. Table 4 shows the heating and cooling demands, together with emissions,
due to different facilities and the savings made after refurbishment.

Table 4. Improvement of energy performance and savings in emissions obtained by the CE3x software

Current state Refurbished Saving %
Heating demand kWh/m2 64.5F 17.5C 72.8
Cooling demand kWh/m2 17.8D 14.7D 17.3
Heating emissions 16.0E 4.3C 72.8
Cooling emissions 5.1D 4.2D 17.3

Continued on next page

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Table 4 continued
DHW emissions 8.4G 6.7G 19.9
Global emissions 29.5E 15.3D 48.1

4.6. Economic viability of refurbishment

To analyze the economic viability of refurbishment, the guidelines of Commission Delegated Regulation (EU)
No. 244/2012, of 16 January 2012, which supplements Directive 2010/31/EU of the European Parliament and the
Council on the energy performance of buildings by establishing a comparative methodology framework to calculate
cost-optimal levels of minimum energy performance requirements for buildings and building elements, was used.
According to this methodology, energy performance measures are considered an investment and the Net Present
Value is used. This indicator is appropriate for long-term investments. Buildings are products of a long service life
that require maintenance, replacing certain elements, etc. Therefore, the global cost, referred to as starting year
τ 0, was calculated using the following equation (1) over calculation period , for a set of measures j during year i:

Cg(τ) = CI + ∑ j
[
∑

τ
i=1 (Ca,i( j)Rd(i)+Cc,i( j))−Vf ,τ ( j)

]� (1)
Table 5 presents details for each term of Equation 1 and the estimated values using the macroeconomic perspective
by considering the carbon cost.

The graphic represented in Figure 8 shows the accumulated NPV for two discount rates, r1% and r4%. NPV is
C53,184.12 for 1% and is C4,736.1 for 4%. With the starting hypothesis of Table 5, we can see that the investment
starts to be positive from year 20 and 28 for the 1% and the 4% discount rate, respectively. This is not a surprising
result if we consider the private costs and only the carbon price a social cost.

Some subsidies can be considered in the calculations, if we bear in mind that the building is included in an ARRU,
as mentioned in Section 3.1. This would result in a more optimistic scenario with a shorter payback, as calculated
in previous studies (Alguacil et al., 2017). For example, estimating a hypothetical subsidy of C5,000.00/dwelling,
the investment would be returned in less time, as seen in Figure 14.

Table 5. Terms for the global cost and hypothesis used for estimations

Term Meaning Estimated value and source
τ Calculation period

Starting year τ 0 2018
30 years
R244/2012 suggests 30 years for residential and
public buildings

CI initial investment cost for measure or set of
measures j

Cost of refurbishment of façades, windows, roof
and replacing boilers (price database)
C10,5195.64 in τ 0 ( C10,519.56/dwelling)

Ca,i(j) annual cost during year i for measure or set
of measures j

Cost of electricity: C0.24/kWh (savings from
the original to the refurbished building: 35.16
kWh/m2.year): C6416.70/year
Maintenance cost: inspection of boiler, manda-
tory every 5 years: C50/dwelling
Replacement cost: boiler 15 years of service life:
C1800/dwelling
Maintenance cost: to inspect boilers, mandatory
every 5 years, estimated at C50/dwelling.
Replacement cost: boiler ,15 years of service life

Continued on next page

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Table 5 continued
Cci(j) carbon cost for measure or set of measures j

during year i
Values recommended by the R244/2012 (savings
from the original to the refurbished building: 14.2
kg CO2/m2.year). Prices CO2: C20/ton until
2025; C30/ton until 2030; C50/ton from 2030

V f ,τ (j) residual value of measure or set of measures
j at the end of the calculation period (dis-
counted from the starting year τ 0)

The residual value is considered zero

Rd (p) discount factor for year i calculated as

Rd(p) =


 1

1+
r

100


p

where p: number of years from τ 0
r: real discount rate

A sensitivity analysis must be performed with at
least two rates. From a macroeconomic perspec-
tive of 4% (according to the Commission 2009’s
Impact Assessment guidelines). Sensitivity anal-
ysis: r1: 1%; r2: 4%

Figure 14. Façade, sloping roof and flat roof refurbishment solutions

5. Conclusions

In this work, the refurbishment of a block of buildings located in Castellón de la Plana (East Spain) is proposed.
The selection of this building was based on various criteria: first, it is located in a vulnerable area of the city, as the
new land plan reflects. Second, the year of construction is characterised by socio-economic circumstances, which
represents a building typology that entails a heritage value. The scarce economic resources at that time led to poor
quality dwellings that can still be found in many Spanish cities today. These buildings very often present low
energy performance and obsolete quality standards. Moreover, in this case, the selected building is the property of
the Municipality and is intended for social housing.

The refurbishment proposal requires a previous diagnosis being made according to its current state. Data were
collected using the original project, visiting the site for measures, employing first-hand information and drawing
new plans.

Some refurbishment solutions were analysed after bearing in mind the particularities of the case to select the

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optimal solution. The selected refurbishment solution is based on different criteria. Although other solutions
could have been proposed, the adopted solution was adapted to a realistic scenario by considering the building’s
specificities. The energy performance estimation shows major savings in both energy and carbon emissions.

The economic analysis conducted by the cost-optimal method shows an initial investment of C10,519.56/dwelling.
With the starting hypothesis, the NPV is positive. The cumulative NPV shows that, in both cases, the NPV is over
zero after 20 years. This term would be shorter if subsidies could address the building. Its location in an ARRU
means that it is an area that should be prioritised to address potential subsidies. Refurbishment would also benefit
users’ quality of life by improving the thermal comfort of their dwellings as it would make the energy poverty
situation more unlikely. Besides it would increase the market price of dwellings, which is an aspect that the
economic analysis does not consider.

6. Acknowledgments

The research for this work was carried out in the framework of the Project GV/2017/110, Diagnosis and proposals
for the regeneration of public housing buildings for social inclusion purposes (VIVINSO), within the Research,
Development and Innovation projects developed by emerging research groups GV-2017, funded by the Valencian
Autonomous Government.

7. References

1. Alguacil, S., Lufkina, S., Reya, E. & Cuchı́, A. (2017). Application of the cost-optimal methodology to
urban renewal projects at the territorial scale based on statistical data. A case study in Spain. Energy and
Buildings,144, 42-60.

2. De Ayala, A., Galarraga, I. & Spadaro, JV. (2016). The price of energy efficiency in the Spanish housing
market. Energy Policy,94, 16-24.

3. Hamdy, M., Hasan, A. & Siren, K. (2011). Applying a multi-objective optimization approach for Design of
low-emission cost-effective dwellings. Building and Environment, 46, 109-123.

4. Decree 11 March 1941, on restriction on the use of iron in buildings. Official Spanish Gazette 71, 12 March
1941.

5. Escandón, R., Suárez, R. & Sendra, JJ. (2016). Protocol for the energy behaviour assessment of social
housing stock: the case of southern Europe. Energy Procedia,96, 907-915.

6. Garcı́a-Bernal, D., Huedo, P., Babiloni, S., Braulio, M., Carrascosa, C., Civera, V., Ruá, MJ. & Agost-Felip,
MR. (2017). Estudio y propuesta de áreas de rehabilitación, regeneración y renovación urbana, con motivo
de la tramitación del Plan General Estructural de Castellón de la Plana. Retrieved from: https://s3-eu-west-
1.amazonaws.com/urbanismo/TOMO I.pdf https://s3-eu-west-1.amazonaws.com/urbanismo/TOMO II.pdf,
https://s3-eu-west-1.amazonaws.com/urbanismo/TOMO III.pdf; and https://s3-eu-west-1.amazonaws.com/
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7. Gómez-Jiménez, ML., (2004). La intervención administrativa en el sector de la vivienda (Doctoral disser-
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8. Huedo, P., Mulet, E. & Lopez-Mesa, B. (2016). A model for the sustainable selection of building envelope
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9. Law 19 April 1939, on Protection to Low-Income Housing System and establishment of National Housing
Institute. Official Spanish Gazette 110, 20 April 1939

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10. Law 5/2014, 25 July 2014, on Territorial Planning, Urban Planning and Landscape, Valencian Community,
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pg. 59


	Introduction
	Methodology
	Background
	Vulnerable urban areas
	 Social Housing

	 Case study
	The urban scale
	The block of buildings
	The building's energy performance
	Energy refurbishment proposal 
	 Energy performance after refurbishment
	Economic viability of refurbishment

	Conclusions
	Acknowledgments
	References