Willingness to Pay for Renovation of Multi-Flat Buildings and to Share the Costs of Renovation

Streimikiene, Dalia; Balezentis, Tomas

doi:10.3390/en13112721

Open AccessArticle

Willingness to Pay for Renovation of Multi-Flat Buildings and to Share the Costs of Renovation

by

Dalia Streimikiene

^1,*

and

Tomas Balezentis

^2,*

¹

Lithuanian Energy Institute, Breslaujos 3, LT-44403 Kaunas, Lithuania

²

Lithuanian Institute of Agrarian Economics, A. Vivulskio g. 4A-13, 03220 Vilnius, Lithuania

^*

Authors to whom correspondence should be addressed.

Energies 2020, 13(11), 2721; https://doi.org/10.3390/en13112721

Submission received: 4 May 2020 / Revised: 22 May 2020 / Accepted: 24 May 2020 / Published: 28 May 2020

(This article belongs to the Special Issue Energy Efficiency and Shadow Pricing)

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Abstract

:

The paper deals with the problems linked to the energy renovation of multi-apartment buildings and developed a case study in Lithuania with the aim to assess the household’s willingness to pay for energy renovation and to define the main barriers preventing the households from making decisions to renovate their apartments in residential buildings. Energy renovation provides huge energy savings and greenhouse gas emissions reduction potential and though policies and measures exist to promote large scale energy renovation, there are still many barriers and the pace of energy renovation is still very slow, especially in new EU member states and former Soviet Union members. These countries have inherited old, energy inefficient residential buildings from their Soviet past, and their inhabitants are locked in energy poverty because of their inability to renovate their apartments. This paper analyzed the current situation in the selected country and presents the results of a case study on willingness to pay (WTP) for energy renovation in Lithuanian residential buildings. The survey of 104 Lithuanian households living in unrenovated multi-flat buildings was conducted. The 39 multiple choice questions were asked in order to define the main barriers and drivers of energy renovation. The main results of this pilot study indicated that there are several important organizational and economic barriers for energy renovation in multi-flat buildings and current policies and support schemes have not addressed them in a proper way. The high heating bills and low heat comfort in apartments were the main drivers of energy renovation decision-making for households, however, inadequate state support, reluctance to take a loan due to low income, and inability to make collective decisions on renovation due to the lack of cooperation and housing association were the main barriers that prevented them from this step. New innovative schemes like the Energy Service Companies ESCO model with consolidated billing can be applied to address the identified barriers.

Keywords:

energy; renovation; multi-flat buildings; barriers; willingness to pay; state polices

Graphical Abstract

1. Introduction

Though there are huge energy savings in residential buildings in Lithuania, which has a large stock of old and poorly constructed multi-flat buildings, the process of refurbishment is very slow. Lithuania has set ambitious energy and climate targets for 2020, 2030, and 2050. The main directions and measures of energy efficiency improvement have been established in the updated National Energy Independence Strategy, National Climate Change Management Policy Strategy, and integrated into the National Energy and Climate Action Plan of the Republic of Lithuania 2021–2030.

The country has implemented various policies and measures to promote the renovation of multi-flat buildings; however, these measures have not provided the expected results (Streimikiene, Balezentis, 2019 [1]).

There are several studies that have analyzed the drivers and barriers of energy renovation in Eastern Europe and post-Soviet countries (Dabija, 2010 [2]; Hernández and Bird, 2010 [3]; Herrero, Urge-Vorsatz, 2012 [4]; Boute, 2012 [5]; Bouzarowski, 2013 [6]; Bouzarowski, Petrova, 2015 [7]; Janda et al. 2014 [8]; Labanaca et al. 2015 [9]; Weinsziehr et al. 2017 [10]; etc.), however, there have been no studies addressing these issues in Lithuania. Zoric et al. (2012) [11] stated that the age of the apartment owner was an important barrier, whereas inconvenience was identified as the main barrier by Karvonen (2013) [12]. The under-studied barrier of energy renovation is the failure of owners of multi-apartment buildings to achieve common agreement on the renovation. As most of the studies have been concentrated on the economic barriers of energy renovation and the low incomes of households (Herrero, Urge-Vorsatz, 2012 [4]; Boardman, 2010 [13]), this paper aimed to overcome this gap and analyzed the main drivers and barriers of energy renovation in Lithuania and assessed willingness to pay for energy renovation.

The main input of the paper is the development of a case study to assess willingness to pay for energy renovations in multi-flat buildings and the identification of the main barriers and problems hampering energy renovation in the selected former Soviet Union country and recent EU Member State, Lithuania.

Section 2 presents the literature review; Section 3 introduces the current situation of Lithuania in terms of energy renovation; Section 4 establishes the study framework; Section 5 discusses the results and findings of the conducted case study, and Section 6 presents our conclusions.

2. Literature Review

There are several studies dealing with willingness to pay (WTP) for energy efficiency improvements in households. Poortinga et al. (2003) [14], in his study of WTP for energy renovation, analyzed the impact of socio-economic variables and environmental attitudes, while analyzing the United Kingdom (UK) household priorities for efficient heating systems and insulation measures.

Jakob (2006) [15] and Grosche and Vance (2009) [16] examined the influence of social-economic household profile and their property characteristics on the adoption of different efficiency measures in Switzerland and Germany, respectively. These studies also modeled heating system purchase decisions as a function of property and household characteristics, but expanded the set of control variables to include location and home. Michelsen and Madlener (2012) [17] modeled the technologies for renewable heating systems in Germany as well as home and space features to define the WTP for energy efficiency improvements such as education, household composition, and certain property characteristics like type, age, and size. Banfi et al. (2008) [18] and Phillips (2012) [19] used different choice experiments to explore the tenants’ preferences for specific combinations of energy efficiency investments in Switzerland and New Zealand, respectively, and received mixed results. For example, Banfi et al. (2008) [18] found that the WTP for Swiss tenants for energy efficiency measures such as window replacement and the installation of a ventilation system was usually higher than the associated investment costs. The study by Wilhelmsson (2002) [20] assessed the average non-marginal WTP for a 25 per cent increase in a given housing attribute level and found that WTP for all renovation attributes were higher for environmentally aware households. On average, environmentally aware households had non-marginal WTP about 2–4% higher for insulation, solar energy, and waterborne distribution system, etc. In addition, it was found that households with a high income were willing to pay more for all attributes, but the difference between environmentally aware households and those not aware were the same as for all households. The study by Phillips (2012) [19] assessed the willingness to accept rent increases in exchange for energy efficiency improvement of the heating system and showed that while improved comfort played an important role, tenants were not well informed about the financial savings associated with their investments.

Several studies (Glumac et al. 2013 [21]; Hope, 2012 [22]; Galvin, 2014 [23]) have analyzed the irrationality of behavior in specific renovation projects in the Netherlands and other countries and showed that the increase in rents is an important engine of the acceptability of deep energy retrofitting.

The study by Carroll et al. (2016) [24] showed that information plays an important role in WTP for energy renovation. The other study by Lang and Lance (2018) [25] confirmed these results and found that the tenants’ WTP increased with the implementation of a set of informational interventions.

Energy poverty was found to be an important problem due to the low income population living in poorly insulated buildings in Eastern European countries where low-income households in these countries could not afford better housing or renovation upgrades (Hernández and Bird, 2010 [3]; Bouzarovski and Petrova, 2015 [7]). In Germany, the problem of energy poverty has also been observed in recent decades (Herrero, Urge-Vorsatz, 2012 [4]; Weinsziehr et al. 2017 [10]). Therefore, it is necessary to stress that Eastern European countries face additional barriers, and targeted policies and measures are necessary to overcome barriers of energy renovation in these countries (Streimikiene, Balezentis, 2019 [1]).

The main measures to promote the renovation of multi-flat buildings are the following: information dissemination and advice; energy and CO₂ taxes; financial incentives; access to capital; and minimum standards. Information dissemination is an important measure in which to overcome information failures, as due to incomplete or asymmetric information, households are reluctant to make decisions on energy renovations, however, for households experiencing energy poverty, this information is not as useful as they are often experiencing other problems. Taxes on energy or CO₂ that raise the cost of energy, sending price signals to households to save energy, can also be considered as important measures, however, for low income populations, it does not provide any solutions. Financial incentives such as tax incentives, grants, and soft loans provide some incentives for consumers to renovate their homes, however, these schemes are not always useful for low income populations (Janda, Parag, 2013 [26]). Minimum performance standards or building codes that are widely used to regulate the standards to which buildings must comply also do not provide appropriate initiatives for solutions to the energy poverty problem.

The Energy Supply Companies Obligations (ESCO) scheme requires energy suppliers or utilities to attain energy efficiency improvements in residential and other buildings. The system of ESCO established in the UK obliges energy utilities to achieve energy efficiency improvements in residential buildings. The ESCO scheme was implemented together with the Green Deal arrangement. The main purpose of the Green Deal is to support vulnerable low-income households make energy efficiency improvements by renovating their apartments. The Green Deal, implemented together with the ESCO scheme, provides opportunities for low income households to pay their renovation costs, not upfront, but placing them on their monthly utility energy bills (Christensen et al. 2011 [27]). This also allows low income households to avoid loans in order to pay for their energy renovation costs.

Based on the literature review, there is no clear evidence for the effectiveness of these policies to date [28,29,30,31,32,33,34,35,36,37,38,39,40].

3. Energy Renovation Situation in Lithuania

The main goals for energy efficiency and housing renovation in Lithuania are detailed in the National Energy Independence Strategy [41], Energy and Climate Action Plan [42], and National Climate Change Management Policy Strategy [43]. These documents set targets for energy efficiency and housing renovations in various detail. Renovation programs for apartment buildings and public buildings must generate 2.67 TWh of energy savings by 2020. At the end of 2016, 2.1 TWh were saved by the end of the 2019 [44]. One of the most serious reasons for inefficient energy consumption in Lithuania is the very poor thermal properties of most public buildings, which require a lot of energy for heating. Energy renovation of multi-flat buildings would save a lot of energy and significantly reduce greenhouse gas emissions, but despite many years of efforts, renovation in Lithuania has not become massive.

By 2020, Lithuania is planning to save about 11 TWh of energy. It is expected that renovation of apartment buildings will provide for 2.7 TWh of energy savings and renovation of public buildings of 0.4 TWh. It is also planned to save 2.4 TWh of energy until 2020 by better informing consumers about the energy saving opportunities. According to the Energy and Climate Action Plan, the biggest problems related to multi-flat building renovation in Lithuania are the long payback period of the renovation, the lack of Unified Urban Quarterly Renovation Plans, the volatile project flow, and insufficient funds for the renovation [45].

The multi-apartment building renovation (modernization) program, approved in 2015, set energy savings targets for 2020 and aimed to ensure that soft loans and other statutory state support for apartment owners were available to promote apartment owners to implement energy saving measures and develop public information, education and training on energy efficiency issues in buildings, their renovation (modernization) opportunities, and possible energy and cost savings [46].

The results of the multi-apartment building renovation (modernization) program showed that by 2020, the implemented renovation projects will reach 75% of the original targets. Many projects are ongoing and scheduled for completion in 2021. Following the implementation of the program, the implementation of the renovation project will have to reach a 19% surplus, albeit a year later than planned. It can therefore be said that the program is successful, however, the problems still exist.

As part of the multi-apartment house renovation program, more than 300 multi-apartment buildings or 9000 apartments were renovated in Lithuania last year. From 2013, when municipalities were involved in the renovation process to 2019, more than 24,000 apartment buildings or 700,000 apartments were renovated. Detailed quarterly plans combined with mobility plans for the development and renovation of public buildings and infrastructure when planning cities can provide buildings whose useful area could be increased, or where new buildings could be erected, etc. [46].

Renovation, according to detailed quarterly plans, can achieve economies of scale by reducing the cost of renovation and having a positive external impact on other areas. In Lithuania, in most cases, apartment buildings are only partially renovated, as residents independently implement the most important and energy-efficient measures such as the replacement of windows and doors. Meanwhile, performing a complex renovation on the house increases the payback time. The average payback period of one renovation project is over 15 years. Usually, commercial banks in Lithuania provide investment loans for a maximum period of 10 years. As the duration of the loan is shorter than the payback period of the project, commercial banks do not provide such a loan, or the borrower has to find other sources to service the loan as the energy cost savings are not enough [44].

Research in Lithuania has shown that irrational consumer behavior in the field of energy efficiency is widespread, and the general public perception of the importance of energy savings and energy efficiency is not yet fully formed. Additionally, due to their low financial education, energy consumers often misjudge their energy consumption and savings and payback period, and are more inclined to avoid investing and continue to pay more for energy consumption than to take appropriate action. Since 2013, when measures were initiated for the renovation of multi-apartment buildings, although the population has used public investments more actively, it has not been determined whether the attitude of Lithuanian residents to energy efficiency investments has changed.

In Lithuania, energy consumers often do not have enough information and do not know about the existing technologies for energy saving. Insufficient investment in energy efficiency measures can also be attributed to the lack of information that is due to a lack of energy literacy and motivation to acquire it. Residents who are the final beneficiaries of apartment building modernization projects are often unaware of the benefits of introducing energy efficiency measures, and the overall consensus process among apartment building residents can be very lengthy, sometimes that consensus is not reached at all. Residents of apartment buildings in Lithuania, for many other reasons, have low motivation to initiate energy efficiency projects themselves.

More than 1.3 billion LTL will be needed for the renovation of residential buildings in Lithuania during the 2014–2020 programming period. However, given all the sources of funding available on the market including the EU Structural Funds, co-financing for the renovation of multi-apartment buildings is insufficient. From 2014 to 2020, about 2809 million euros were allocated for the renovation of apartment buildings, which was later increased to 314 million euros. However, even then, the necessary investments were more than several times higher [46].

Given the total number of apartment buildings that still need to be refurbished, there are a number of areas for improvement in the implementation of the current program. For example, assessing the quality of renovations requires better maintenance, better, and more reliable data on energy use (consumption) for energy efficiency audits, and a wider range of financial support measures to encourage more homeowners to undertake renovations.

4. The Background for Willingness to Pay (WTP) Study and Framework

The main energy policy document, the Lithuanian National Energy Independence Strategy, (2018) states that more than 70% of apartment buildings in Lithuania are currently inefficient in heat consumption and requires deep energy renovation [41].

As most (66%) Lithuanians live in multi-apartment buildings and about 96% of multi-flat apartment buildings in Lithuania were built before 1993, the assessment of renovation barriers and households willingness to pay for energy renovation is crucial in the sense of promoting energy renovation and implementing new innovative schemes to hasten the process as since 2013 in Lithuania, more that 2000 apartment buildings have been renovated or on average 500 buildings are being renovated per year. As there is a total of 35,500 multi-flat buildings in Lithuania requiring energy renovation, if this pace is maintained, all apartment buildings will be renovated in about 65 years [45,46].

Therefore, due to a very slow pace of energy renovation, which satisfies neither the policy makers nor the residents of these buildings, the main drivers and barriers should be identified in order to find better solutions. Assessment of WTP for renovation will provide more insights into the problem.

The main hypotheses were developed for the case study of WTP for the energy renovation of multi-flat buildings in Lithuania.

The main organizational barriers of renovation are linked to reaching common agreement on renovation between apartment owners and one body is necessary to take all responsibility for organizational issues linked to the renovation of multi-flat buildings.
The main economic barriers of energy renovation are linked with the reluctance to take out loans and the low income of the households.
Governmental support for energy renovation is not enough to generate initiatives for the renovation of multi-flat buildings.
The WTP for renovation by monthly energy bills have a higher acceptance among households than paying the total costs of renovation upfront before it starts.
Low income households are not able to pay for renovations and higher income households are willing to share the costs with them in order to hasten the renovation processes.

The data for WTP assessment were collected in September 2019 by means of a standardized telephone survey (N = 104).

There were 1,321,000 households in Lithuania in 2019 and 792,600 lived in multi-flat buildings. A total of 90% of these buildings were built up to 1991, therefore 713,340 households lived in old multi-apartment buildings in 2019. In one such type of building, there are on average 60 apartments. As 2430 multi-flat buildings had already been renovated during the 2013–2019 period, therefore 145,800 households lived in renovated apartments and 567,540 households lived in energy inefficient and unrenovated apartments. Therefore, our general sample was 567,540. The sample size ensures the respondents were representing all the major strata of the social status and living conditions.

The survey included 39 multiple choice questions. The questionnaire consisted from several parts: in the first part, the demographic data of the respondents were collected (Table 1); in the second part, the housing conditions were assessed (Table 2); in the third part, the drivers (Table 3 and Table 4) and barriers (Table 5) of renovation were identified by asking specific questions; in the fourth part, willingness to pay for energy renovation (Table 6) and to share costs with low income neighbors (Table 7) were assessed by providing several multiple choice questions.

Approximately 1000 phone calls were made and the response rate was 10%. The data were obtained by a professional polling agency. Hierarchical sampling was applied in order to guarantee a representative sample from 10 Lithuanian regions based on statistics published by the Statistical Office. The respondents were also screened by multi-family apartment type (built before 1993) and by age (lower threshold was 18 years of age) by taking into account the responsibility of being the head of the household and paying the household’s energy bills.

Demographic data of the sample are provided in Table 1.

As can be seen from the information in Table 1, 46% of respondents were women and 53.8% were men. About 70% of the respondents were married. The majority of households (over 40%) were 35–44 years old, of which only about 8% were unemployed and about 4% were retired, while 44.2% of respondents were employed in the private sector and 35.6% were employed in the public sector. The majority of respondents (34%) had a monthly income of between €500 and €1000. Only about 6% of households had an income in excess of €2000/month. About 10% of households had incomes below €300 per month. Another 14% of households had incomes ranging from €1500 to €2000/month. As many as 77% of households had a tertiary education.

The housing conditions are addressed in Table 2.

As one can see from Table 2, households consisting of two, three, and four persons accounted for a similar share, which was about 30% of all households. One person households accounted for only 5% of all respondents. The majority of the surveyed households (89%) lived in multi-flat apartment buildings, of which as many as 87% were built in 1961–1993. A total of 90% of respondents lived in 3–4-room apartments. An equal share of respondents (-40%) lived in apartments of 20–50 m² and 51–70 m² in size. More than 50% of households lived in five story buildings.

More than 70% of households owned their apartments. Only 40% of households lived in multi-apartment buildings with housing associations. The latter indicator suggests that renovation can be problematic in many apartment buildings due to administrative barriers.

The vast majority of respondents (90%) did not know the energy class of their house. This shows that it is important to develop a certification of buildings in Lithuania. More than 70% of respondents made decisions with regard to renovation in consultation with other family members.

In next section, a discussion of the survey results is provided including the assessment of willingness to pay for energy renovation and to share the costs of energy renovation with low income neighbors.

5. Discussion

The main drivers and barriers of renovation summarized from the survey are analyzed in Table 3 and Table 4.

As can be seen from the data presented in Table 3, in the cold season, about 60% of households paid between 21 and 50 euro/month and over 30% paid from 51 to 100 euro/month for electricity, and in the warm season, 51% of respondents paid from 21 to 50 euro/month and 30% from 51 to 100 euro/month.

Meanwhile, in the cold season, as many as 50% of the surveyed households paid on average 101–200 euro/month for heating and 33% of the respondents from 51 to 100 euro/month. In the warm season, 51% paid up to 20 euro/month and 39% of respondents paid for heating from 21 to 50 euro/month.

Household electricity costs did not change when comparing the cold and warm periods: in both cases, more than 50% of respondents stated that the cost of electricity was 21–50 euro/month. Heating costs increased from 21 to 50 euro/month in most of the households surveyed in the warm period (51%) to 101–200 euro/month in the cold period (50%). The majority (57%) of respondents stated that the average cost of energy was 1010–200 euro/month. In order to estimate the changes in costs and the ratio to the area of apartments, the grouped data were used to calculate the averages of the variables. The average area of the respondents’ apartments was 53.3 m² and in the cold season, the total energy costs of one household amounted to 187 euro/month, and in the warm season from 77 euro/month. The costs per m² are given in Table 4.

As can be seen from the figures provided in the tables, heating costs in Lithuania are very high compared to the monthly income of households, and as many as 90% of households were not satisfied with the thermal comfort of their apartments, and 100% of respondents stated that heating bills did not correspond to the thermal comfort of their homes. Additionally, over 90% of respondents considered housing renovation options, but did not use them. Over 90% of respondents believed that their home needed renovation: 10% of households replaced windows, 26% of households replaced exterior doors, and 9% of households had their roof repaired. A total of 56% of households had not undergone any partial renovation. As can be seen from Table 3, although all respondents said that they had enough information about state support for apartment building renovations, as many as 85% of respondents said that the state support did not motivate them to renovate their housing.

Therefore, the main barriers of renovation are identified in Table 5.

The main obstacles to renovation identified by the population (55%) were the absence of a household community and the reluctance to take out a loan for housing renovation, which households cannot do without (35%). More than 90% of respondents thought that the availability of one body taking on all responsibility for the renovation of multi-flat building would have an impact on their decision to start renovations on their apartment.

Assessment of willingness to pay for renovation is given in Table 6.

As one can see from Table 6, 46% of the surveyed households were willing to pay up to 10 euro/month for housing renovations and 42% of respondents from 11 to 50 euro/month.

Meanwhile, 61% of the respondents’ WTP for the whole renovation was in the range between 2001 and 3000 euros; 10% of the respondents’ WTP for the energy renovation was in the range between 1001 and 2000 euros; 10% of respondents were willing to pay from 3001 to 4000 euros; and 12% of the surveyed respondents were willing to pay from 4001 to 5000 euros.

A total of 27% of the respondents’ WTP for energy renovation, if the renovation costs were distributed and included in their monthly heating bills, was in the range between 31 and 40% of the increased monthly heating bill; 15% of households’ WTP for housing renovation was in the range between 41 and 60% of the increased monthly heating bill; 20% of the households’ WTP was from 51 to 60% of the increased monthly heating bill; and 14% of respondents’ WTP was from 61 to 70% of the increased monthly heating bill. Given that the average heating bill in the cold season is about 155 euro/month (Table 4), the WTP for energy renovation of the surveyed households in Lithuania to pay for housing renovation under such a financing scheme is quite high and is about 55 euro/month.

It is also necessary to stress that over 90% of households would choose to pay for energy renovation by including renovation costs in their monthly heating bills. Only about 10% of the surveyed households would like to pay for the full costs of energy renovation immediately before initiating renovation. In Table 7, the results of the willingness to share renovation costs with lower income neighbors are presented.

All respondents admitted that their apartment building was inhabited by households who could not afford to renovate their apartments by themselves, but almost 90% of respondents did not express a desire to share renovation costs with poorer neighbors and cover part of their renovation costs, thus speeding up the whole building’s renovation process, although, all respondents agreed to accept help from other households to cover part of their renovation costs.

Over 90% of respondents admitted that the presence of one responsible person or institution who would bear all the organizational costs of renovation would motivate them to renovate their apartments, while as many as 87% of respondents said that they did not communicate with their neighbors for various reasons like dissatisfactions with the neighborhood (27%) or the lack of common interests.

Hypotheses 1–4 were not rejected. It was found that the absence of housing association and inability to agree on the decision to renovate the building among households in multi-flat buildings were the main barriers to energy renovation. In addition, over 90% of respondents thought that the availability of a responsible person or organization that took all responsibility for all organizational issues related to the renovation would influence their decision to renovate their house. Moreover, over 30% of respondents did not want to take out a loan, which is necessary to pay for the full energy renovation of the building, and over 80% of respondents thought that the government support did not create adequate incentives to renovate their houses. The study found that 90% of respondents would prefer to pay for renovation by increasing their heating bills per month, instead of paying the total costs of the renovation.

Hypothesis 5 was rejected as over 90% of respondents were not willing to share the renovation costs with low-income neighbors.

The performed cross-tabulation indicated that income and gender have an impact on WTP to pay for the full renovation before the starting process. The rest of the demographic variables had no relationship with this WTP. Higher income provided for a higher WTP for renovation. Women also tended to have higher a WTP for renovations.

The ownership and size of the apartment also had an impact on the WTP for the full renovation in total immediately before the starting process. The owners of apartments had a higher WTP for renovation, as did the owners of larger sized apartments.

Work and income had a relationship with the decision to share costs with neighbors who had a lower income. Therefore, the decision to share costs was due to the working situation and income of the respondents and the remaining demographic variables had no relationship. Higher income households were more willing to share the costs of renovation. The participants employed in the private sector tended to have a higher willingness to share renovation costs with low income neighbors.

The results of the study are summarized in Figure 1.

As one can see from the summarized results, the study identified the main drivers of the energy renovation of multi-flat buildings and also assessed the impact of demographic characteristics on the willingness to pay for energy renovation. The income, gender, and work status were found to have an impact on WTP.

The survey showed that low heat comfort and high heating bills not corresponding to the heat comfort were the main stimuli for households to start renovations and the significant share of respondents indicated that their house required energy renovation, however, the current state support is inadequate to create initiatives for energy renovation. Nevertheless, the most important barriers of energy renovation in Lithuania are organizational and behavioral. The absence of housing associations and lack of communication between households creates a significant barrier in making decisions on renovations. In addition, the low income of a household and their reluctance to take out loans created additional financial barriers that have also been identified in other studies. Other scholars have identified a variety of interlinked barriers to energy renovation: household values and attitudes [2]; high price [3]; poor organization and inconveniences [4,5]; low-skilled, untrustworthy, or overpriced professionals [8]; and difficulties in making a decision for all apartment homeowners [9]. Several studies have identified similar barriers to the energy renovation of multi-flat buildings: weak political incentives and frequently changing public policies and incentives; lack of appropriate targeted information and household awareness; inadequate motivation of households; major inconveniences; and low affordability [9,10].

The current study did not find a relationship between age and education and WTP for renovation, however, income, ownership, size of apartment, and gender were found to be important drivers of WTP for renovation in Lithuania.

The study found that new policies and measures are necessary to overcome the identified energy renovation barriers in residential buildings. These policies should be better shaped to address barriers identified in the current study: financial, organizational, and behavioral. Innovative policy support schemes like the ESCO model application in the residential sector might be useful as this model allows the three identified barriers to be overcome together: it proposes a consolidated billing approach that is very useful for overcoming financial barriers and provides a solution to organizational barriers by introducing a responsible organization for dealing with all organizational issues of renovation. The behavioral and psychological barriers like limited cognition and decision-making heuristics will also be better addressed by the ESCO model with consolidated billing.

For Lithuanian municipalities, the implementation of the ESCO model, which features a wide variety of designs, can be useful. The UK ESCO model was set up in 2013 to decrease energy consumption and combat fuel poverty [1]. It is possible, based on the example of the UK, to set legal obligations for energy suppliers in municipalities to implement advanced energy efficiency measures in households and to support the energy renovation of multi-flat buildings by making it possible to not to have to pay for renovation costs in advance, but to cover these costs in the monthly utility bills for energy. The ESCO model needs to be adapted to the national circumstances of Lithuania as Lithuania is distinguished by a shrinking and aging society and “empty nest” syndrome. Another specific issue is that the large stock of inefficient multi-apartment buildings usually have one to four room apartments and diverse households in terms of size, income, education, and age. This creates additional problems that need to be addressed.

6. Conclusions and Policy Implications

There are many barriers preventing the energy renovation of multi-flat buildings: a lack of access to capital and lack of knowledge as well as split initiatives and the difficulties of households in reaching a collective decision on building renovations due to the difference in incomes, professions, size of apartments, etc.

While other studies of WTP for the energy renovation of multi-apartment buildings have found that income, age, gender, education, ownership of an apartment, and environmental awareness are the key factors influencing household WTP for energy renovation, the current study did not find a relationship between age and education and WTP for energy renovation, but income, ownership, apartment size, and gender were identified as important determinants of WTP for energy renovation in Lithuania.

The study on WTP for energy renovation revealed that the absence of a housing association and the inability of neighbors to agree on the renovation of a multi-apartment buildings are the main organizational barriers to energy renovation in residential buildings of Lithuania.

In addition, the study demonstrated that more than 90% of households believed that a person or organization responsible for all organizational issues related to the energy renovation would have a significant impact on the decisions of households to undertake renovations of their apartment.

The study indicated that state support is not appropriate to initiate the energy renovation of residential buildings as more than 80% of respondents believed that government support for apartment building renovations was insufficient. More than 30% of households are reluctant to take a loan for energy renovation;

The results of the survey showed that more than 90% of respondents would not want to share the renovation costs of their low-income neighbors and thus speed up the renovation processes in this way. This was linked with the context of Lithuania as, in general, the income of households is low, and is too low to cover the costs of the renovations of their lower income neighbors.

An important result of the performed study was the evaluation of WTP for energy renovation of multi-flat buildings. The WTP for energy renovation of surveyed households in Lithuania was about 55 euro/month. It is also necessary to stress that over 90% of households would choose to pay for energy renovation by including the renovation costs in their monthly heating bills. Only about 10% of the surveyed households would like to pay for the full costs of energy renovation immediately before initiating renovation.

The main policy implication of the conducted study is the development of the ESCO model for energy renovation in Lithuania. This model will ensure that the costs of renovation will be included in the monthly heating bill, and most importantly, that the energy company will take all responsibilities for organizing the renovation of the multi-apartment building including the negotiation with households and reaching common decisions on energy renovation. The ESCO model would allow three major energy renovation barriers identified in Lithuania to be overcome: lack of capital and reluctance to take out a loan (economic–financial barrier); inability to reach agreement (organizational) among owners of apartments in multi-flat buildings; and behavioral and psychological barriers linked to limited cognition and decision-making heuristics.

The conducted study also has some limitations. Due to the quite limited sample of the study, this research can be treated as a pilot study. More sophisticated techniques like choice experiment should be applied to define WTP for energy renovation. An increased sample and more advanced econometric techniques like Data Envelopment Analysis DEA can allow more robust results to be obtained and to deliver policy recommendations on a more global scale.

Author Contributions

All authors contributed equally to the manuscript. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by a grant (No. S-MIP-17-131) from the Research Council of Lithuania.

Conflicts of Interest

The authors declare no conflicts of interest.

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Figure 1. Results of the study.