Assessing maintenance budget elements for building maintenance management in Nigerian built environment: a Delphi study

Introduction

Maintenance is an action carried out to restore or retain a structure to an acceptable standard through combining all management, technical and administration in the maintenance process and operations (EN 13306, 2001). Regardless of the required budget for maintenance operations, it cannot be abandoned (Ogunbayo and Aigbavboa, 2019). According to Mohd-Noor et al. (2011), budgeting for successful MM operations is a key factor of progression in maintenance organisations. Like other key performance indicators of MM, budgeting supports all maintenance operations and processes (Ahzahar et al., 2011; Omar et al., 2017). Omar et al. (2017) observed that the success of maintenance operations could be affected by lack of budget. Srivastava et al. (2020) stated that a proper budget is crucial for maintenance organisations to sustain operational effectiveness. In this study, MM is proxies by several variables – namely organisational maintenance policy, human resources management, personnel training, monitoring and supervision, task planning and scheduling, maintenance information system, maintenance approach, spare part management, outsourcing strategy and continuous improvement benchmarks against maintenance (Pantzartzis et al., 2016; Srivastava et al., 2020).

MB, according to Srivastava et al. (2020), is a driver for maintenance operations and processes. It is an estimate for maintenance operations in advance of the period which it applies (Srivastava et al., 2020). As one of the core elements of MM, MB guides required estimates for manpower, spare parts, consumables and other operations expenses towards bringing efficiency and economy in the maintenance operations (Hastings, 2015; Arumsari and Rarasati, 2017). In this study, MB encapsulates the prioritisation of maintenance financing, valuation of maintenance operation budget, maintenance operation financing and other activities undertaken by the maintenance department of the public organisation that deals with financial planning for maintenance operations and execution.

According to Alsyouf (2006), an adequate MB will impact the building maintenance process. Srivastava et al. (2020) postulated that a well-defined MB ensures optimal maintenance operation and process towards efficient productivity and profitability. It is worthy of note that there were fewer studies carried out focussing on the scope of MB elements for the MM of buildings in developing countries, including Nigeria (Alsyouf, 2006, Ling and Formoso, 2014; Hastings, 2015). Hence, this study aims to affirm whether the elements of MB found in other countries (developed) that influence MM of buildings are significant in the maintenance of buildings within the developing countries using the Nigerian Built Environment (NBE) as a case study. It is important to note that MB elements are industry, organisational and country context. Therefore, depending on the laws, economic, political factors and organisational system, different information procedures might or might not be relevant in MB development in a particular country. Equally, depending on the elements of MB that impacted maintenance of buildings, assuming some industries, organisations and national settings to be in the same direction with the NBE will be a great distortion. However, some developed countries' organisations and industries still share a resemblance with developing countries' context. As a result, it is essential to empirically ascertain the elements of the MB that influence the MM of buildings in developing countries. Therefore, the main objective of this study is to identify elements of the MB that influence MM of buildings in developing countries and determine the extent to which each element influences building MM using the NBE as a case study.

Literature review

Methodology

In assessing the elements of MB for the MM of buildings in Nigeria's built environment, this study adopted the Delphi survey technique (Aigbavboa, 2014; Ameyaw et al., 2016). According to Linstone and Turoff (1975), the Delphi method is a structured communication method developed as a systematic, interactive forecasting method that depends on a panel of experts. Rowe and Wright (2001) postulated that the Delphi method believes that forecasts from a structured group are more accurate than those from unstructured groups. Ameyaw et al. (2016) believed that Delphi's group judgement output is more accurate than individual judgements. Tilakasiri (2015) recommended the Delphi technique for the development of concepts, standards, frameworks or models for a study. With contemporary construction management literature, this method has been used extensively within the built environment studies, for instance, by Aghimien et al. (2021) to assess challenges applicable to the South Africa construction industry; Aliu et al. (2021a) examine undergraduate courses relevant to the built environment in the Fourth Industrial Revolution (4IR) era and Aliu et al. (2021b) used it to examine the 21st-century employability skill improvement framework for the construction industry. As demonstrated by the body of knowledge, the Delphi survey techniques adopted for this study provide a robust epistemology approach and consist of a more accurate group judgement output than individual judgements. However, the study employed the Delphi technique to collect and analyse primary data from an operational perception. As affirmed by Rowe and Wright (2001) and Fletcher and Marchildon (2014) and Somiah et al. (2020), Delphi is useable for both qualitative and quantitative studies and includes the use of structured questionnaires to solicit views from panellists. According to Leung (2001), this will be achieved through iterative rounds until saturation occurs, at which point participants converge on the correct (most exact) response. Also, Aigbavboa (2014) asserted that Delphi survey usage is effective, robust and suitable tool for capturing vital data in qualitative studies. Hence, this qualitative study adapted and employed the Delphi process as described in Figure 3.

The first step of the Delphi in this study was reviewing the relevant literature, through which relevant MB elements that influenced MM of buildings were identified. For Delphi's survey of this study, the second step was the expert selection. The experts were prudently selected based on recommendations of (Loo, 2002; Somiah et al., 2020), and their opinion represents a broad spectrum on the subject being assessed. Thus, for this study, experts were mainly drawn from both industry and academia. Also, the selection criteria of experts for this study were based on Aigbavboa (2014) suggestion, which detailed that experts' practical experience and theoretical knowledge are significant in their selection. At the beginning of the study, 30 experts freely responded to be part of the Delphi study through emails. These emails were gotten through their related professional bodies and online academic profiles. However, 15 experts could not continue with the study due to their busy schedules and other personal commitments. This was written in their response to the author during round one of the Delphi study. In all, for both rounds one and two of the Delphi study, only 15 experts partook. Nonetheless, the Delphi process ended after round two when a strong consensus was achieved. In the Delphi study, according to Hsu and Sandford (2007), the sample size as a representation of a population is not reliant on a statistical sample but on bringing together experts to share their knowledge and experience in the study area. Therefore, as guided by previous studies within the subject under study (Hsu and Sandford, 2007; Aigbavboa, 2014), a sample size of 15 experts was used for this study due to the heterogeneous nature of the selected panellists. Delbecq et al. (1975) noted that expert panellists of between 10 and 15 are adequate for a Delphi study provided the background of the expert panellists is homogeneous. Subsequently, for rounds one and two of the Delphi survey, instructions and questionnaires were sent to the 15 expert panellists selected. Table 2 showed clearly that the demographic profile of the expert in relation to MB development for MM of buildings had the required essential knowledge and experience.

Also, a checklist was developed for the study, and this helped in creating a benchmark for the panel of experts' selection for the Delphi study (see Appendix). Through the checklist designed, an expert panel member for the study must obtain a minimum of five points to qualify to join the Delphi study. However, all the selected 15 panels of experts obtained the minimum requirement of five points required for this study, and they were considered fit for the study. Additionally, in developing the questionnaire for the Delphi study, a rigorous literature review was carried out. Moreover, the questionnaire quality (clarity, transparency and completion period amongst others) was tested through a pilot study.

Similarly, feedbacks gotten from the pilot study was incorporated before the final questionnaire was produced. As postulated by Pallant (2007) and Rehbinder (2011), in order to create a reliable construct of multiple variables, a scale with a Cronbach's alpha higher than 0.7 is required; hence, a Cronbach alpha test was carried out on all the MB elements to determine their level of reliability. The Cronbach's alpha value for all the MB elements was 0.719. This shows that the data collection instrument is reliable, and the responses obtained from it can be relied upon to be valid (Pallant, 2007). Likewise, the use of a combination of the mean (M), median (x¯), interquartile deviation (IQD) and standard deviation (σx) based on RII earlier used in similar studies such as Aigbavboa (2014) and Somiah et al. (2020) were employed in the analysis and determining consensus in responses of experts. Therefore, the consensus for the study was measured as detailed in Table 3.

As shown in Table 3, the consensus for the Delphi study was based on 10-points impact scale where 1 to 2 signify no influence; 3 to 4 signify low influence; 5 to 6 signify medium influence; 7 to 8 signify high impact and 10 signify very high impact. In addressing the issue of generalisation, reliability and validation of results, the Delphi findings for this study are all-encompassing theoretical reasoning and rigorousness of the data collection process (Sarantakos, 2005; Somiah et al., 2020). As shown in Figure 4, the methodological structure this study adopted was underpinned by the input-output MM model (Visser, 1998) and the decision-making MM model (Pintelon and Gelders, 1992). Similarly, through the chance provided for the experts to maintain or freely effect changes to their response based on good reasons for the latter, and through tenacious individual communication with experts, internal validity for the study was asserted. Further, as theorised by Ameyaw et al. (2016), structured questionnaires were used in soliciting data from the panellist for this study. Also, through the use of IQD, mean, median and σx for the study was calculated and analysed for each Delphi survey round based on the estimated statistical view of the expert panellist. In line with the ethical consideration for the study, throughout the Delphi study process, the experts' identity was kept confidential.

Results

Discussions

The study aimed to establish whether the elements of the MB found in other countries that influence the MM relevant to the maintenance of buildings in the NBE. In total, 21 elements of the MB were found to influence the MM of buildings in NBE. Though the level of consensus amongst the elements varies, the IQD scores indicated consensus for 15 of the elements, with the 1QD being ≤1 or ≥1, 1 ≤ 2, respectively. Similarly, (σx) of the 15 elements indicated consistency in the experts' responses, as their σx values were at most 1.

Of the top ten elements that recorded (VHI: 9.00–10.00), six elements are similar to findings of the studies by Visser (1998) and Pinjala et al. (2006). These include MB implementation, corruption-free maintenance process, maintenance financial plan, maintenance funding, cash flow index and the prioritisation of maintenance financing. These were the elements of the MB that influence the effectiveness of MM of buildings. The findings are also in line with the study of (Omar et al., 2017). Equally, the other four elements, namely reduction in maintenance expenditure, cost implication for maintained asset maintenance funding, incorporation of financial indicators and audit for the operational maintenance cost aligns with the studies by Ahzahar et al. (2011) and also affirmed by the study of Mohd-Noor et al. (2011) who highlighted the elements for MB. The study's finding based on the RII for measuring consensus in the Delphi study outcomes showed that strong consensus was achieved for all the ten elements. Their median (M) score is between 9 and 10 and RII is between 0.80 and 1.0, with IQD ≤1. Comparatively, of the five elements that recorded (HI: 7.00–8.99), three of the elements were consistent with the studies by Campbell (1995) and Wireman (2005) that focussed on yearly MBs certainties, optimisation of finance outsourcing and valuation of MB as elements of the MB that influence the effectiveness of MM of buildings. The findings are comparable with Flores-Colen and de Brito (2010) study, which listed the various MB elements influencing MM of buildings. The other two elements, namely market and financial terms of operations and maintenance operation financing aligns with the study of Pintelon and Gelders (1992) and Puķīte and Geipele (2017) on various MB elements for the effectiveness of MM of buildings. Based on the RII for measuring consensus in the Delphi study outcomes, the study's finding showed that good consensus was achieved for all five elements. As their M scores are between 7 and 8.99, RII scores are between 0.60 and 0.79, with IQD ≥1, 1 ≤ 2.

The 15 elements' respective scores indicate consistency in the expert panellists' response as their σx values were between 0.00 and 1.00. Additionally, the Cronbach's alpha value for the 15 elements was 0.719. This agreed with Pallant (2007) and Rehbinder (2011) that a scale with a Cronbach's alpha higher than 0.7 is required to create a reliable construct of multiple variables. Thus, in this study, a Cronbach's alpha value of 0.7 and above is considered reliable and indicative of internal consistency amongst the variables of MB elements.

Lastly, the remaining six elements, namely the optimisation of business profitability, maintenance materials assessment, asset maintenance prioritisation, maintenance operation system improvement, optimising maintenance resources and planning for future asset replacement based on the study findings, all recorded weak consensus. The RII for measuring consensus in the Delphi study outcomes showed that weak consensus was achieved for all the six elements as their M scores is ≤ 6.99 and RII scores is ≤ 0.59, with IQD ≥2, 1 ≤ 3. Also, the 6 elements' respective scores for standard σx indicate inconsistency and variability in the expert panellists' response as their σx values were above 1. Moreover, the Cronbach's alpha value for the six elements with the IQD of ≥2, 1 ≤ 3 were found to be 0.719, which is within the acceptable 0.7 required to create a reliable construct of multiple variables. However, with the low IQD score, it is thus considered that the elements were unindicative of internal consistency. This indicates that the six elements cannot be incorporated into MB standards for maintenance operations in developing countries. Thus, they do not influence MB for MM of buildings within the NBE.

Practical and theoretical implications of this work

The critical outcome of this study shows it has theoretical, practical and policy implementations. Empirically, the study affirms that elements of MB are required for effective MM of buildings in the NBE. The identified elements of MB will assist maintenance organisations in the NBE in preparing an accurate maintenance cost and estimate for maintenance activities. The study theoretically advances that MB for MM of buildings represents 15 essential elements. Amongst these vital elements were MB implementation and corruption-free maintenance process, indicating that MB is the key to effective maintenance and corruption-free maintenance. On a practical note, the study establishes the relative influence of each validated element to guide stakeholders in the built environment in preparing an operational estimate for required consumables, spare parts, human resources and other expenses. It ought to guide the stakeholders in the planning and controlling the use of available resources towards achieving the maintenance set objectives.

Similarly, in preparing an operational estimate, the findings of this study will assist built environment professionals in designing a good MB for preventive maintenance with a better MB recording. It will also help to develop a financial plan when considering seasonal maintenance need. Moreover, the findings of this study will assist built environment professionals in guiding against inaccurate financial planning for maintenance operations. Finally, the findings of this study will help the built environment professionals reduce wastage, improve the maintenance process and increase productivity amongst maintenance personnel.

Conclusions and recommendations

This study was carried out to establish whether the element of MB found in other countries that influence MM of buildings are relevant in the maintenance of buildings in the NBE. The expert panellists appraised a total of 21 MB elements that were perceived to have influenced MM. However, out of the total elements validated, 15 elements of the MB were found to have influenced MM of buildings in NBE industry. Moreover, these elements were consistent with MB elements that have been identified by earlier studies in some international and national contexts.

In conclusion, the study's findings indicated that 15 out of the identified elements of MB from developed countries are valid for developing countries and are effective for MM in the NBE. These elements will help the built environment in organising maintenance activities in such a way as to make the best use of limited resources by providing an objective basis for decisions such as which components should be encompassed in maintenance activities. Therefore, the objectives of the study were achieved. Based on the study's findings, it is thus recommended that in preparing MB for MM of buildings in the NBE, the validated elements of MB should be sought since these elements are vital to the built environment industry toward MM of buildings.

The study also recommends that the MB elements identified from this study should guide industry practitioners in the maintenance practice. However, due to time constraints, the study was limited to build environment professionals within Southwestern Nigeria, which interprets to show that the findings cannot be entirely generalised for the NBE. However, it is pertinent to know that professionals in Southwestern Nigeria used for this study account for the significant professional activities in the NBE. Conversely, future studies can be carried out to test the MB elements in practice to ensure the study's findings apply to the built environment practically. This can be done by incorporating all built environment practitioners who have first-hand experience with day-to-day maintenance activities.