Maintenance work management process model: incorporating system dynamics and 4IR technologies

2.1 Maintenance management

Maintenance management may simply be defined as a consolidation of technical, administrative, activities and management measures during the operational phase of the equipment life cycle to sustain that equipment's intended function (Algabroun et al., 2022). Maintenance management is a framework for maintenance work execution. Maintenance management in most organizations has proven to be one of the most important aspects of asset management due to its complexity, requirements, and widespread use in all equipment employed for productivity (Naji et al., 2019).

Maintenance management remains a challenge as companies are presented with cost reduction pressure (such as maintenance labor cost) and/or constraints to realize good profit margins. Maintenance management system is a pivotal tool to ensure system's availability and reliability. Planning and scheduling processes are part of improving maintenance work management performance (Palmer, 2013; Ismail, 2022). Maintenance managers require decision-making tools and models to plan resources effectively and efficiently to support physical assets. Effective planning and scheduling are viewed as part of the maintenance work management process (Sedghi et al., 2021; Naji et al., 2019; Palmer, 2013).

Several scholars modelled different elements of maintenance management aiming at cost reduction gains. Babaeimorad et al. used joint optimization approach to model the integrated maintenance scheduling inventory policy adjustment (Babaeimorad et al., 2022). Furthermore, the mathematical model of Babaeimorad et al. determined the inventory level and preventive maintenance planning for a single equipment production system with increasing random failures. The scholars highlight that decision-makers can minimize the total operating cost using decision variables such as production capacity quantities, maintenance costs, and machine failure distribution (Babaeimorad et al., 2022). Zul-Altfi Ismail conducted a case study on the requirements of maintenance management systems to improve ineffective maintenance management systems. Zul-Altfi Ismail's study suggests that conventional maintenance management methods lack defect diagnosis tools and strategic decision-making for information analysis in maintenance-related project outcomes. The proposed maintenance management system aimed at reducing the number of overhauls and repairs, thereby reducing cost (Ismail, 2022). Pant and Singh modeled a system subjected to random inspections with hidden failures (Pant and Singh, 2022). The study highlights the determination of the system availability and long-run average cost rate. The optimal inspection period is obtained thereby reducing costs (Pant and Singh, 2022).

2.2 System time model for physical assets

The system's time model assists in the maintenance work management process, particularly when equipment is frequently taken down for both planned and unplanned maintenance (scheduled and unscheduled maintenance or maintenance index) (Manenzhe, 2018). The system time model is a systematic way of measuring the reliability of assets. In the digital transformation lens, enabling industry 4.0 technologies such as cloud computing combined with data analytics enables accurate measurements of asset reliability (García and García, 2019; Tortorella et al., 2021; Zhe et al., 2016).

Figure 2 represents some of the reasons why artisans' actual time to perform a task (wrench time) is low, suggested to be 3.5 h on a 10-h shift without the benefit of a planner (Palmer, 2013). Figure 2 illustrates that there is time allocated for the preparation and/or delay after the equipment is switched off before active maintenance time (wrench time or tool time) and a further waiting and/or delay towards the end of the downtime (Ghani et al., 2012). The time of failure in Figure 2 may also be viewed as the time to run down equipment for scheduled maintenance.

2.3 4th industrial revolution

The past three industrial revolutions are characterized by the mechanization of manufacturing and the use of a steam engine, mass production and the use of electrical power, the use of electronics, information technology, and automation (García and García, 2019; Richardson et al., 2022). The Fourth Industrial Revolution (4IR) is characterized by a combination of digital or cyber systems with physical systems. This combination produces intelligent systems or “agents” that can autonomously perform activities that in the past were primarily performed by humans (Balamurugan et al., 2019; García and García, 2019; Tortorella et al., 2021).

In maintenance management, cyber-physical systems can be used to monitor equipment conditions in real-time and eliminate equipment health status subjectivity, where for instance, an artisan would have been required to perform regular inspections (García and García, 2019; Tortorella et al., 2021; Vaidya et al., 2018).

Based on the abilities of industry 4.0 technologies and the study referenced in (García and García, 2019), the operative level of maintenance management can mostly be supported by these technologies as compared to tactical and strategic levels. Industry 4.0 technologies support manufacturing processes, processing, and/or condition monitoring. García S.G. and García M.G. (García and García, 2019) further argue that maintenance costs and system availability, seen as maintenance targets, are impacted by industry 4.0 technologies.

2.4 Business process modeling in maintenance

A business process may simply be perceived as a logical and systematic way of working activities to achieve sustainable results, through a logical organization of people, equipment, energy, materials, and procedures (Zakarian and Kusiak, 2000; Entringer et al., 2019; De Nicola et al., 2007). A business process can be divided into three categories, namely, managing process focusing on strategy and direction setting to enhance business planning and control, operating process focusing on work execution, and supporting process mainly for support of both managing and operating processes. The maintenance work management process can be pinned from a point of the operating process. A flow chart is defined as a graphic presentation of the manufacturing process, program logic sequence, and/or organization chart (Cheng and Chiu, 2004; Zakarian and Kusiak, 2000).

Flow charts are characterized by flexibility and communication ability (De Nicola et al., 2007; Cheng and Chiu, 2004). Although there are various modeling techniques such as data flow diagrams, action diagrams, role interaction diagrams, and colored Petri-net, this study aims at using flow charts to develop a maintenance work Management process model based on its simplicity and fit for purpose for the intended process model.

The work of Ghani et al. (2012) outlines the maintenance management process in two parts: strategy with objectives as input from a business plan. The maintenance management process can be used to determine the effectiveness of its department. The second part of the maintenance management process is the implementation of the maintenance strategy. The study of Ghani et al. (2012) further highlighted that process modeling of maintenance management is critical for determining both efficiency and effectiveness within a maintenance department.

There is a need to develop a process that is dynamically tested (system behavior testing) using empirically supported evidence and/or real-world data (organizational documents) and from literature findings particularly in maintenance management (Sterman et al., 2015; Ghani et al., 2012).

2.5 System dynamics: system thinking tool

Systems thinking is used for identifying interrelationships to determine patterns of change. In system thinking literature, systems thinking is explained as the understanding of a system and is the ability to determine how subsystems work together as one system (Mella and Gazzola, 2019). Most of the decision-makers in operations systems are boundedly rational, and at times irrational, influenced by stress levels and emotions, omitting interactions for system behavior and most feedback (Sterman, 2002; Marwala, 2013a, b; Sterman et al., 2015).

Systems thinking is an effective tool for problem investigation, modeling, and simulating the dynamics of systems such as maintenance work management (Sterman, 2002). System dynamics (SD) modeling and simulation process consist of five stages, namely, problem identification and definition, system conceptualization, model formulation, model testing and evaluation, and policy analysis and design (Mella and Gazzola, 2019). SD represent the behavior of a system based on its structure. SD model encompasses feedback loops, stocks and flows, and nonlinearities because of the interaction between the physical and institutional structure of the model with the decision-making processes of the agents acting within a system (Sterman, 2002; Forrester, 2009; Sterman et al., 2015). System dynamics, therefore, have commonalities with models in traditional operation behavior (Sterman et al., 2015).

According to Sterman et al. (2015), SD have been used in project management, supply chain management, and human resources, process management, and the dynamics of improvement. This research study is in line with process management and the dynamics of improvement. The study of Sterman et al. (2015) suggests that scholars and practitioners are challenged in operations management because of challenges of continuous improvement. The role of workloads motivation is examined by several scholars using system dynamics according to Sterman et al. (2015). Scholars empirically identified (using system dynamics) nonlinear relationships between workload and performance over extended time in the context of quality improvement (Sterman et al., 2015). In line with this research study, (Sterman et al., 2015) further outlines that SD is used to determine a major line of work on capability traps in oil and chemical industries with an observation to reinforcing dynamics on short-run pressure to drive work output and found to lead to longer hours, taking short cuts, less maintenance, and bad safety record. The study referenced in Ghani et al. (2012) used SD modeling to evaluate maintenance work outsourcing and analyzed outsourcing profitability.

3.1 Research technique: process modeling and simulation

Research methods are reinforced by techniques and/or step-by-step procedures on how each research question is answered (Borrego et al., 2009). In this research study, the mixed method is reinforced by process modeling and simulation. Data is collected from current best practices in maintenance work management systems, captured from a combination of literature findings and two companies' documents in maintenance work management, and using systems thinking. In conceptual modeling terminology (qualitative modeling), this research study captures relevant data from literature findings and empirical observation (reviewed from organizational documents in maintenance work management), where for instance a subjective model could have been used particularly in maintenance work management (Martinez‐Moyano and Richardson, 2013; Sterman, 2002; Chitongo and Pretorius, 2018). For this research study, two steps reinforcing the research method are discussed below.

• Step 1: formulates a process model for maintenance work management (qualitative modeling) using Microsoft Visio as part of a subjective model caption to an extent recommended by Sterman (2002) and Martinez‐Moyano and Richardson (2013). This model formulation captures key findings from literature and information from company documents to systematically address a way to effectively manage maintenance work to support overall gain in asset management and performance. According to Sterman (2002), Martinez‐Moyano and Richardson (2013), Forrester (2009), unless the process model is simulated and validated, that model is considered subjective.

• Step 2: formulates a Stock and flow diagram (quantitative modeling) using Vensim DSS to examine the dynamics of a system (maintenance work management) and analyze the effects of state variables together with flows, also recommended by Sterman (2002) and Martinez‐Moyano and Richardson (2013).

This technique corroborates with five stages of system dynamics modeling suggested by Sterman (2002), Martinez‐Moyano and Richardson (2013), Chitongo and Pretorius (2018), Forrester (2009):

1. Problem identification and definition;

2. System conceptualization;

3. Model formulation;

4. Model testing and validation; and

5. Policy analysis and design.

This research study technique follows the first four stages (mentioned above) of system dynamics modeling incorporated in the system modeling of the maintenance work management process. The four stages considered for this research study are discussed below:

• Stage 1: reviews (using critical thinking) existing literature and company documents to identify key elements affecting variables in maintenance work management;

• Stage 2: captures concepts of maintenance work management from a combination of literature review and empirical observation (on company documents) and using system thinking, and conceptually models a maintenance work management process (system conceptualization);

• Stage 3: makes use of Vensim DSS software to develop stock and flow diagram for model formulation with a lens to 4IR technologies identified as part of literature findings to formulate the provisional model; and

• Stage 4: uses real-world data for model validation using calibration techniques and analysis on the impact made by 4IR technologies in the maintenance work management model on Vensim DSS software.

Figure 3 presents both qualitative data/information collection and quantitative data collection methods. Figure 3 illustrates a systematic research method process flow (summary of preceding paragraphs) depicting data collection for mixed method (both qualitative and quantitative) modeling.

3.2 Research data collection overview: triangulation

The term triangulation is first used by Denzin in 1978; Denzin outlined using complementary methods or data sources to offset weaknesses amongst data sources (Borrego et al., 2009).

Figure 4 outlines data sources for this research study, aiming at triangulating between the literature reviewed, retrieved organizational documents addressing business processes, and real-world maintenance data both in maintenance work management to offset weaknesses, particularly in model validation (Forrester, 2009; Borrego et al., 2009). The data sources referred to in Figure 4 are used either as a combination and/or individually for process model and simulation formulation and system behavior analysis. The maintenance real-world quantitative data is retrieved from two maintenance departments from company A, both for a period of 24 months, representing years 2017 and 2018. The maintenance quantitative data retrieved represent six various types of equipment used at underground Mines. The maintenance management qualitative data (organizational documents) in maintenance management are retrieved from company A and company B. Company A is a global mining industry, and company B is a global manufacturing industry.

4.1 Maintenance work management process model overview

Figure 5 represents formulated maintenance work management conceptual process flow using Microsoft Visio from a combination of literature findings and organization documents. Figure 5 outlines that for any maintenance work to be executed, identification and approval of that work is the initial step, this is conducted to prioritize work that is critical over work that may be executed in the next maintenance window, thereafter, step by step on how a task should be executed, a good way to benchmark on this is through maintenance manuals supplied by the original equipment manufacturer, in digital technologies context, cloud computing can accelerate this step. Thirdly, detailed planning commences with a lens on the specification of tools, special skills required, and any additional time or cost that would be required. Once the work is effectively planned, a schedule can be drafted covering at least 5–7 weeks of the forecast.

No work can be completed without the required resources as specified in the panning step, work resourcing aims at the effective acquisition of these resources to eliminate time wastage on the day of execution, this research study suggests that tool time or wrench time for artisans is mainly affected by upfront preparations and/or delays just before task execution (Ghani et al., 2012), such delays include but not limited to the acquisition of tools or parts on the day of work execution. Work may effectively be executed with a minimal safety risk, and in this study, it is also found that detailed planned work yields safe and quality execution. The findings of this research study suggest that breakdown work may not be executed through WIA to WSR. These tasks move from WIA to WE and hence a maintenance index of 85/15 is critical. In simpler terms, minimization of unscheduled downtime supports unnecessary time wastage reduction. In the 4IR, the maintenance strategy is predictive. 4IR technologies yield an overall best practice maintenance mix, and more tasks are performed as planned work than unplanned work.

The next subsections discuss each step of the maintenance work management process as per Figure 5. Sections 4.2 and 4.3 discuss work identification and approval and task planning execution with respective formulated process model flow diagrams, as an example of how each step as per Figure 5 is modeled. Sections 4.4 to 4.7 discussions are without respective formulated process models and hence Figure 5 is used as a reference point.

4.2 Work identification and approval (WIA)

Figure 5 represented an overall formulated maintenance work management process model, illustrating both steps from WIA to WE overview, and is based on findings from data sources presented in Figure 4. Figure 6 illustrates details of the first step (Work Identification and Approval). In line with Figure 6, any maintenance task to be performed, and in line with equipment inspection, task identification and approval as an initial step are crucial for validation of that task allocation. In Figure 6, work identification is seen as an activity predominantly captured by online condition monitoring using online sensors such as vibration, temperature, etc. (4IR support). Furthermore, Virtualization technologies are seen as another 4IR technology that can be employed for the effective handling of equipment parameters as presented in Table 1 of this journal.

Visualization technologies can inform the prediction of the exact time for ad hoc maintenance activity before equipment failure at the most opportune time for that equipment restoration. The findings of this research study suggest that should work be triggered by these 4IR technologies, an interface between these technologies and Computerized Maintenance Management System (CMMS) be implemented to support the automatic creation of work/task notification (Raouf et al., 1993; García and García, 2019; Tortorella et al., 2021). Based on the criteria set (i.e., Priority 1 tasks for illustrate stopper equipment and safety-related equipment, and Priority 2 for the second type of equipment), the system can be equipped with a tool for task/notification validation with a lens on labor compliment for that equipment.

In maintenance work management literature, there is evidence of some ineffective maintenance work management because of failure to categorize tasks thereby misusing human resources (also suggested by (Ensafi and Thabet, 2021)). Thus, the maintenance index (85/15 best practice) is somewhat to be desired in the industry. For tasks accepted through notification validation, the system can use data analytics technique to classify whether that notification constitute emergency work or not. Emergency work is seen as either breakdown work or health, safety, or environment threat avoidance or mitigation. This approach discussed herein is centered around cyber-physical systems (4IR enabling technology) (García and García, 2019). Figure 6 is a graphical representation of Work Identification and Approval.

4.3 Task planning execution (TPE)

Figure 7 unpacks the process developed for task planning execution. It starts with a need for defect elimination, which could be achieved through failure mode and effects analysis (FMEA) or failure mode, effects, and criticality analysis (FMECA). These processes assist in identifying potential problems that can occur and the effects thereof on the system. Secondly, for tasks required but no functional location is registered on the CMMS, the execution of maintenance tactics can only be done after such functional location is registered. Thereafter, system identifies tasks steps required for the task initiated; in the 4IR context, this is known as data mining through cloud computing. To put this into context, a similar task can be executed in one of the sister operations. Architecturally, there is a need for the information hub/data hub to reduce time wastage on developing tactics that already exist.

A high-level determination of labor requirements, time estimation, and potential delays can be specified. If functional location is registered in the CMMS, assets can be registered and confirmation of maintenance strategy, task tactics, and the approval thereof can then be executed, this includes additional changes to maintenance tactics (Palmer, 2013).

4.4 Work planning (WP)

The work planning step begins with scoping the work, addressing the maintenance task list, and required resources, and matching that against cost. Planned work can only be approved as such if the following criterion is met; the works order needs to be compiled and well understood by the executor, the upper-cost limit needs to be known and approved by the cost center owner, the specification of resources such as special tools, required tradesman and the specification of cranage.

As an example, consider three artisans working without the benefit of work planning, in a high-production environment. According to Palmer (2013), (a maintenance management handbook), combined productivity is equivalent to one artisan working without any time wastage.

i.e. 3 × 35% = 105% total productivity (Without planning).

One planner, two artisans: 1 × 0% + 2 × 55% = 110%

Ratio planner to artisans (1:20–30 artisans).

Therefore, 55%/35% = 1.57 (This is a 57% improvement).

Thus, 30 artisans X1.57 = 47 artisans.

The example above represents the importance of work planning, reinforcing that at least 85% of work should be executed under scheduled work conditions.

4.5 Work scheduling (WS)

Work can only be scheduled once the plan is confirmed by both the maintenance and production departments. The findings of this research study suggest that a schedule should cover at least four weeks to allow the effective use of human resources, in this case, prioritization takes precedence. In the context of 4IR, data analytics and the Internet of things can assist in adequately predicting critical tasks that should be executed first.

4.6 Work resourcing (WR)

This research study found in the literature that an artisan's tool time in a 10-h shift is only 3.5 h, this is due to ineffective planning leading to failure to specify resources required for the task, this section looks at mitigating some of the time that can be wasted during execution stage (known as time optimization) (Palmer, 2013).

Artisans spend more time looking for spares, and special tools and figuring out how to execute the task adequately. This study proposes a need for work resourcing so that all required resources are acquired beforehand thereby eliminating time wastage, particularly when executing tasks.

4.7 Work execution (WE)

There is great emphasis in the literature in line with maintenance activities that, the right work should be done at the right time, by the right skilled person the right way. This can only be achieved should WIA to WR discussed in preceding subsections are executed effectively. Nonetheless, this study considers emergency work as any work emanating from a breakdown or deterioration of any health and safety equipment. Such work need not be taken through WIA to WR due to the requirement of restoring that equipment timely. In this study and according to the literature (Planned Maintenance Percentage), such work should not exceed 15% of the total work.

The next section discusses the dynamic behavior of the maintenance system incorporating the formulated maintenance work management process using system dynamics modeling and simulation. Forrester suggested that the system dynamics model's source of information must consider available databases from any institution, including modeled business processes just like the process model in this research study by Forrester (2009).

5.1 Model formulation and simulation overview

This section converts the formulated qualitative maintenance work management formulated model in the preceding section to a quantitative system dynamics model. The conceptual model developed and represented in Figure 5 consists of six steps, namely, work identification and approval, task planning execution, work planning, work scheduling, work resourcing, and work execution. These steps are converted to a quantitative model with unintended effects and incorporating 4IR technologies.

5.2 System dynamics model formulation

Figure 8 is a graphical illustration of a stock and flow diagram (SFD), representing discrete events for maintenance tasks processed through the formulated maintenance work management process. For preventative tasks, programmed works orders, condition monitoring, and inspections are viewed as the drivers for work identification. This follows through to a point where tasks are executed with a defined maintenance department capacity. In SD terms, identified and approved tasks are seen as stock accumulation reinforced by inspections, condition monitoring, and programmed works orders (reinforcing loop). Activities in the planning phase, resourcing, scheduling, and task execution balance or deplete identified and approved tasks (balancing loop) (Sterman, 2002). The model conforms with extant literature in that it allocates one planner per 20 artisans with a wrenching time of 3.5 h per 9-h shift (Palmer, 2013), allowing tasks identified to undergo planning and scheduling processes.

In Figure 8, although tasks identified in any given month may exceed the work capacity in the maintenance department in that month, the only tasks that can be planned by the maintenance department capacity at a level of planning and scheduling. Furthermore, prioritization for tasks to be planned is given to critical equipment and that on its present subjectivity without the benefit of 4IR technologies. Unintendedly, some of these critical tasks are omitted and end up resulting in a breakdown, and dynamically reinforcing corrective maintenance tasks in execution (reinforcing loop). Subsequently, tasks that are left out in the planning phase due to capacity constraints and that have resulted in breakdowns unintendedly impact the intended maintenance mix negatively. Another unintended effect resulting from tasks that are omitted in the planning phase due to constraints increases the maintenance backlog as per the illustration in Figure 8. Table 4 encompasses key mathematical model equations for the formulated system dynamics simulation with subscripts “[Maintenance]”.

Figure 8 is a partial representation of the system dynamics model structure, with mathematical formulas presented in Table 4. In Figure 8, no 4IR technologies have been implemented, and simulations and system behavior are executed as the first step for analysis.

To control the complex phenomenon discussed in the preceding paragraph, the second part of the formulated model in Figure 9 incorporates 4IR technologies as a balancing loop for critical assets. The study referenced in García and García (2019) suggested that virtual reality (VR) and augmented reality (AR) offer a unique opportunity in critical asset inspections to detect defects and adapted as such in this research study. This alleviates time spent by artisans on the inspection with overall gain to hands-on tasks rather than on inspections. Another subjectivity is observed particularly when artisans are to judge whether a defect requires work to be executed timeously. Using cyber-physical systems (CPS), equipment deterioration or degradation is detected, analyzed (using data analytics), planned, and scheduled digitally and in real-time without human intervention as per Figures 5 and 7 (recommended by (Tortorella et al., 2021)). Digital planning and scheduling add to tasks that are planned and scheduled manually for assets not deemed critical. Table 4 details mathematical equations used for key stocks and flows represented in Figures 8 and 9.

Figure 10 is a graphical representation of the overall model for maintenance work management (a combination of Figures 8 and 9).

6.1 Model validation and testing overview

Figure 11 is an overview of this research study model validation and testing. Step 1 involves importing real-world data from a Microsoft Excel data file named “data.xlsx” to Vensim DSS software (Sterman, 2002; Ventana Systems, 2022; Martinez‐Moyano and Richardson, 2013), and (Chitongo and Pretorius, 2018). The baseline model for this study captured subscripts named [Maintenance] to ease simulation iterations rather than having each model simulation for each equipment type (Ventana Systems, 2022; Chitongo and Pretorius, 2018). Vensim DSS software automatically appends subscripts to model variables and/or parameters (Ventana Systems, 2022). Step 2 captures the optimization setting using the model error function “payoff” and defines model parameter weighting. Step 3 captures behavior reproduction test measuring “Mean Absolute Percentage Error (MAPE)” for calibration error descriptive statistic (Ventana Systems, 2022). Step 4 determines the model's real-world scenario best fit, or replication based on equipment type captured on the model subscripts (Ventana Systems, 2022; Sterman, 2002; Martinez‐Moyano and Richardson, 2013; Chitongo and Pretorius, 2018). Lastly, step 5 uses experiments to analyze the impact of 4IR technologies on the model structure in line with sensitivity analysis (Christopher Frey and Patil, 2002; Hekimoğlu and Barlas, 2010; Kleijnen, 1995).

6.2 Model validation and testing

Model calibration forms part of system dynamics model testing and validation. According to Sterman (2002), Martinez‐Moyano and Richardson (2013), and Forrester (2009), model constants may be altered manually to achieve the best fit between real-world data and simulation output. Using optimization, Vensim DSS automatically varies chosen constants for the best fit between simulation output and real-world data. This study adapts this concept of model validation using calibration techniques as part of model validation as suggested by Sterman (2002) and Martinez‐Moyano and Richardson (2013). This research study uses six different types of production equipment (M1 to M6 discussed below) for analysis of the impact of the maintenance work management process (WIA to WE) from experiments simulation.

The intent for six different types of equipment is to enhance model validity and conclusions derived therefrom. Real-world data is retrieved from two unique maintenance departments managing production machines that comprise Continuous Miners (M1), Shuttle Cars (M2), Feeder Breakers (M3), Roof Bolters (M4), Section Conveyor Belts (M5), and Trunk Conveyor Belts (M6). Data is imported to Vensim DSS as M1 to M6 and is defined as such in the subscripts of the model simulation. This way of calibration conducted for this study model provides a novel extension to the extant system dynamics simulation model testing and validation body of knowledge, more so because the extant literature reviewed is limited to either a generic maintenance model with just one type or class of equipment or machine. Furthermore, the extant literature in maintenance system dynamics modeling is limited in modeling a process for work management (WIA to WE) viewed as discrete events (Karnon et al., 2012). Lastly, the experimental simulation of this study enhances future system dynamics modeling and physical asset management research studies. Most importantly, it can be used as a provisional answer to challenges encountered in complex maintenance work management systems.

The problem for this research study model calibration is expressed by a single optimization problem having an error function known as the objective function or payoff. This model calibration starts by setting the initial payoff; secondly, real-world data is imported to the model for comparison purposes, thereafter, model calibration is executed.

Key maintenance management system parameters used for payoff settings are Maintenance Index (MI) and Maintenance Availability (MA) both weighted at 0.4985 and CM tasks in execution (CM) weighted at 0.003 (weight setting recommended by Ventana Systems (2022)). These three parameters a chosen because they represent a discrete event of the model (from task identification to execution). Equations (2) and (3) are mathematical expressions of payoff calculation used for this study (adapted from Ventana Systems (2022)). According to Vensim Ventana systems, the payoff is defined as a comparison of model variables with actual data, or as a combination of model variables. Two types of payoffs are calibration payoff and policy payoff. This research study used calibration payoffs for model validation (Ventana Systems, 2022).

• wMI= weight for the maintenance index component;

• MIsim,m= simulated maintenance index for equipment type m;

• MIact,m= actual maintenance index for equipment type m;

• wMA= weight for the maintenance availability component;

• MAsim,m= simulated maintenance availability for equipment type m;

• MAact,m= actual maintenance availability for equipment type m;

• wCM= weight for the correct maintenance component;

• tsim,m= simulation final time for equipment type m;

• CMsim,m(t)= simulated corrective maintenance for equipment type m; and

• CMact,m(t)= actual corrective maintenance for equipment type m.

• n = number of equipment types considered.

In line with recommendations from Sterman (2002) and Martinez‐Moyano and Richardson (2013), the calibration used payoff optimization in Vensim DSS using Powell conjugate search algorithm for parameters estimation as first step of the calibration (Ventana Systems, 2022). A total of 432 real-world data points is used for parameters estimation purposes. Thereafter optimization for all equipment type, class, or group (M1 to M6) is conducted and the payoff for all equipment type is calculated as the objective function for minimization similarly to the study of Chitongo and Pretorius (2018).

The second step of calibration for this study is also in line with both (Sterman, 2002) and (Martinez‐Moyano and Richardson, 2013). Behavior reproduction test measure known as the mean absolute percentage error (MAPE) is used for calibration error descriptive statistic for this study (Ventana Systems, 2022). Four calibration errors are deduced for each equipment type (MI, MA, CM as discussed in preceding section), thus determining MI MAPE (Maintenance Index calibration error), MA MAPE (Maintenance Availability calibration error) and CM MAPE (Corrective Maintenance in Execution calibration error) using equation (4) for this study.

O MAPE (Overall calibration error) is calculated using equation (5) with weighted MA, MI, and CM (depicted as W_MI, W_MA, and W_CM in equation 5) the same as when used to calculate equipment type payoff (equation 2). This approach is supported by Ventana Systems (2022).

• n = number of iterations considered (n = 24 for both MI MAPE, MA MAPE, and CM MAPE).

• WMI= weight for maintenance index component;

• WMA= weight for maintenance availability component; and

• WCM= weight for corrective maintenance.

The dataset used in the calibration consists of actual maintenance availability, actual maintenance index, and actual corrective maintenance tasks in execution (all per time series data of 24 months).

6.3 Model validation results (maintenance work management process)

Table 5 is a representation of calibration results; four different calibration errors denoting dimensionless MAPE values for each equipment type with an O MAPE viewpoint are discussed. Equipment type M4 and M6 are the best fit for real-world data both with least overall calibration error (O MAPE) of 0.065, followed by equipment type M2 at O MAPE of 0.071. M3 is observed with the largest overall calibration error of O MAPE accounting for 0.098, denoting the worst fit.

Table 5 summarizes key results of system dynamics simulation model after calibration, illustrating the unintended effect of random equipment breakdowns on intended overall maintenance index of a world class 85/15 ratio is unavoidable with just a subjective model alone. Nonetheless, this study reveals great insights due to its control in mapping out a process model for maintenance work management. This research study observed from CM MAPE in Table 5 that due to randomness of breakdown events, modeling random breakdowns is complex and is not easy to replicate real-world scenarios. Thus, the focus for this research study is more on what can be done to produce industry benchmark on maintenance work management process that accounts for a dynamic maintenance complexity presented by random equipment breakdowns. MI MAPE and MA MAPE denote best fit between model parameters and real-world parameters, thus representing an overall mean percentage error supporting the validity of the model and random breakdown events controls.

6.4 4IR technologies sensitivity analysis on validated system dynamics model

Sensitivity analysis is used to understand the effects and/or impact of input variables in system dynamics models (Kleijnen, 1995). The preceding section illustrated system dynamics simulation to solve real-world maintenance work management complex phenomenon. Simulations are based on experimentation of modeling real-world scenarios (Christopher Frey and Patil, 2002; Kleijnen, 1995). Statistical design of experiments (DOE) is adopted in this research study in the attempt to investigate the optimization of maintenance work management using 4IR technologies (Kleijnen, 1995).