An implementation model for digitisation of visual management to develop a smart manufacturing process

2.1 Implementation model

This project applied the PDCA (Plan, Do, Check, Act) methodology which is a cycle of a continuous loop of planning, checking and acting. DMADV (Define, Measure, Analyse, Design, Validate) has not been considered here, as it is mostly focused on the design and development of new products or services which do not exist (Trubetskaya and Muellers, 2021). In the present work, PDCA methodology is preferred over DMAIC (Define, Measure, Analyse, Improve, Control) due to simplicity and potential to solve many problems at every level of the organisation using daily reporting (Eaidgah et al., 2016). Both PDCA and DMAIC methodologies aim to improve processes within organisations, but each methodology focuses on different aspects of process improvement. PDCA is focused on measuring performance to identify problems and take corrective action as a comprehensive approach by focusing on the overall process. DMAIC’s main goal is measuring performance as well as analysing data from various sources to find the root causes of problems to prevent them or fix them effectively by focusing on specific areas and monitoring results (Henrique, 2018). Building the PDCA cycle into the digital twin system, particularly the checking and acting mindset, helps VM platform to be more effective through continuous improvement.

To the knowledge of authors, this is the first work that investigates the integration of PDCA methodology into digital twin concept. Digitisation is not restricted to purely Lean tools, but it can appear as a starting point to begin a transformation with pre-defined parameters (Sartal et al., 2022). In this work, digitisation includes the define and measure elements of DMAIC methodology, so that the continuous improvement teams start at the analysis phase. The control phase of digitisation includes trending data that is typically collected over long period of time to be able to monitor KPIs, and to create sustainability within a process. This allows not only the process to mature but also the control systems. Thus, when digital twins of maturity level higher than 3 will be considered, it will be of interest to integrate DMAIC methodology (D’Orazio et al., 2020).

The rationale for using PDCA in implementing the model was due to the iterative nature of the PDCA cycle (Isniah et al., 2020). The proposed implementation model will include the creation of a digital twin of each machine. Creating a digital twin requires specialised technical knowledge. To assemble the project team, selection was based on individuals’ technical knowledge and skills to solve problems, as well as members who use and work with OEE in the department each day, and the team selection was agreed with management. Communication, as always, in a project is key and weekly meetings were held to update all stakeholders on progress.

The model proposes to take the traditional Lean tool OEE and digitally transform it in the context of I4.0. Identifying and describing the Lean concept forms the Plan phase of the PDCA cycle, creating the digital twin forms the Do phase, developing the VM system forms the Check phase and digitising the VM system forms the Act phase (see Figure 1). The concept of digitisation is a key development brought about by I4.0. By demonstrating the digitisation of both OEE and the VM system, the organisations’ goal of developing an I4.0 transformation will be satisfied.

2.2 Return to purpose

OEE is a best practice metric that identifies the percentage of planned production time that is truly productive. OEE is made up of three elements, Availability (A), Performance (P) and Quality (Q). Equation (1) is used to calculate OEE, and the result is expressed as a percentage (Sohal et al., 2010):

Each element of OEE was listed and defined within the OEE calculations, see Figure 2. Availability is the percentage of time a machine is running for during the available time. Performance is the percentage of parts produced versus the target production. Quality is the percentage of good parts versus the total parts produced.

2.3 Developing the digital twin

A digital twin in the case of this project means describing the CH machines in terms of OEE in a digital manner. The process of creating a digital twin required the OEE elements to be captured at the machine and described in terms of the machine status, production pieces and scrap product and then used to calculate the OEE value. Table 1 formed the basis of the digital twin structure, whereby OEE elements were digitally represented at the machine by a status code. The status of each machine was captured using a programmable logic controller (PLC), which are commonly used in industry. The PLC programme monitored the machine signals and reported a status code that depends on the state of the logic within the PLC programme. The status codes are a digital representation of all required elements to calculate OEE as per equation (1) and Figure 2. A code was created for each status, and linked to the OEE descriptors (see Table 1). A Status code 0 was added to monitor the communication status of the system, and alert users if there was an interruption to the data.

The availability element of OEE is known to require the recording of how much time the machine spends in run mode producing parts. In this instance, the PLC programme captures when the machine is in run mode producing parts and indicates a Status 1 signal. This is logged in the data base for as long as the machine status remains at Status 1, thus giving a time for the running time element. Status codes 2–8 are defined as downtime. The preference was to automate data collection, but this is not always possible so some manual interaction from the operator was necessary to capture downtime reason codes, and this was accomplished using a human machine interface (HMI) connected to the PLC, whereby when prompted, the operator enters data by pressing the appropriate downtime reason button on the touchscreen HMI (see Figure A-1 in Appendix A). A database was set up to store the data as it was captured by the PLC and HMI.

Manual inputs can be missed or forgotten, and to overcome this a Poke Yoke was introduced. Once the machine stops making parts, the PLC programme recognises this new status as downtime, regardless of operator interaction. The machine returns to Status 1 once the operator has resolved the issue that caused the stoppage and restarts the machine so that it is once again running and making parts. At this point, the HMI will prompt the operator to enter a reason for the downtime. The HMI will remain on this screen until a code is entered, so the operator cannot move to a new screen until he chooses a reason for the downtime. This method proved effective in accurately capturing reason codes for down time. The remaining status codes, total machine cycles Status 10, target run rates Status 11 and Scrap Status 12, provided values for Performance and Quality elements in Figure 2. The PLC and HMI continuously logged data to a database, providing automated OEE data, which was easily accessible to the core team, and created a more efficient means of reporting OEE for 16 machines each day.

2.4 Development of a VM system

Capturing data in terms of I4.0 is carried out with the purpose of providing a single source of truth and empowering an organisation to make data-based decisions. However, capturing data is wasteful if it is not utilised. The digitised OEE data needed to be integrated into the cadence of the department’s daily activities if it was going to be utilised and make the OEE reviews more efficient. The operators were trained for two weeks on how to use the new data entry system, whereas the core team was learning about the new OEE database.

VM requires the sharing of information on standards and can warn about abnormalities and stop the manufacturing process if the abnormalities are identified. A series of OEE charts were developed from the new database, printed and displayed on KPI boards in the department. The benefits of displaying the OEE information are ease of understanding, as visual information is more easily understood, and speed of communication; the new data was readily available in a format to automatically generate OEE calculations. The daily meetings were changed from a system of reviewing data to action-based meetings, whereby abnormal conditions required an action which would be reviewed the following day. As part of the organisations’ continuous improvement programme, projects such as single-minute exchange of dies (SMED), total preventative Maintenance and changeover training were implemented quickly after the start of the new daily review meetings, that will not be discussed as part of this research. The focus for the team then shifted to digitising the VM system.

2.5 Digitisation of the visual management system

Providing the right information to the right people at the right time is a key element of digitisation in I4.0. The digital VM system was designed using four levels of information, based on end user requirements (see Figure 3). Level 1 displays OEE information at each machine for the operator (see Figure B-1 in Appendix B).

Level 2 provides summary information for all machines to the core team. This allows the team to monitor all machine statuses and performance in one place (see Figure B-2 in Appendix B).

Level 3 provides historical data for management review. OEE for each machine for the previous 24 h is provided as well as each element of OEE, A, P and Q. In addition, Level 3 also provides a visual of the downtime for each machine and indicates which downtime reason contributed most to the downtime (see Figure B-3 in Appendix B).

Finally, Level 4 provides high level departmental information of each machine status. The status of all 16 machines will be shown, to allow anyone walking through the department to know how many machines are running and how many are down. If a machine is not running the reason is displayed and the length of time it has been in this status is also displayed (see Figure B-4 in Appendix B).

Digitisation of the VM system was carried out using the data analytics and visualisation software Qlik®. For Level 1, a 22-inch display was mounted at each machine to visualise OEE data. Apps were created within Qlik® for the supervisor and management displays: Levels 2, 3 and 4. Level 4 information was displayed on two 60-inch TV screens mounted on walls each side of the department. The purpose of Level 4 is to alert the supervisor and team lead when machine stoppages occur, and concurrently to provide the information on how long each machine was out of service. The supervisors and team leads can then react and get the machines running again, or allocate resources required to resolve the issue.

3.1 Establishment of a digital twin

The fundamental aim of the research was to establish a digital twin of each machine. A digital twin of each machine is presented, providing a visual representation of the behaviour of each machine in terms of OEE, that is, how much time it is in run mode producing good product versus how much time it is not running and therefore not producing product (see Figure 4).

Each machine is represented digitally in two ways for live visualisation of machine behaviour. On the top graph in Figure 4, the quantity of pieces which are manufactured each hour are blue marked. The red section on top or bottom of each bar indicates the delta between actual pieces produced versus the ideal target quantity. The bottom graph in Figure 4, shows a ticker tape type visualisation of the machine. The colour-coded chart allows the user to quickly determine the machine behaviour over time, with each colour representing a machine status. When the machine is in production and producing parts, plotted points in time are green marked. In instances where production is stopped, the chart colour changes to red. The purple colour marking is used for unscheduled, and the yellow identification is used to illustrate changeovers. A supervisor, during chart reviews, wants to see large sections of green. Large red areas are used to indicate extended downtime, while frequent small red lines represent intermittent recurring issues.

The digital twin illustrates a quick visualisation of the machine performance over time, bringing together sensing inputs, computing power, always on connectivity and data analytics, all of which work on an I4.0 platform to develop smart manufacturing. An individual chart for any machine can be readily produced from the data to indicate which element of OEE contributes most to the OEE losses, (see Appendix C, Figure C-1). Users can then quickly identify, using the digital twin, which of the six big losses typically associated with OEE elements (see Appendix C, Figure C-2), are the main contributors to downtime, and implement projects as part of the continuous improvement programme.

Two scenarios were observed, and further discussed, which may not have been otherwise observed if the digital twin was not in place. Firstly, erratic production performance, whereby the actual pieces produced may show a small delta to the target, but the total production (actual pieces produced plus the delta), resembles a staircase, (see Appendix D, Figure D-1). This behaviour indicates unplanned interruptions at the machine.

Secondly, consistent performance was observed whereby, both the pieces produced and a small delta to the target were similar over a period of hours, indicating that the target production value was correct. Conversely on some equipment, consistent pieces per hour were observed with a large delta to the target over a period of hours (see Appendix D, Figure D-2). Further analysis revealed that the target pieces in place was not realistic for the part being produced due to the difficulties associated with processing the material in use, resulting in a consistent low performance, giving a false low OEE. Once corrected true OEE illustration was produced, a more realistic indication of issues affecting OEE performance appeared.

Both charts, shown together, allows the user to see which down time reason was responsible for the reduction in manufacturing performance. The charts were designed as part of Level 2 for the core team. A team meeting identified that using the charts over a shorter period of 4 h and visualised on the Level 1 operator screen, would allow the operator of each shift to review how the machine had performed on the previous shift.

3.2 Developing and digitising the VM system

The results of this work indicated that the digital VM system had an overall positive impact on the departmental OEE in a relatively short period of time. Initially, OEE charts were displayed on departmental KPI boards as part of the VM system, however, results were not consistent indicating that there were additional factors contributing to low OEE.

Once the digital VM system was introduced an increase in the departmental OEE was observed. The introduction of the digital VM system required the core team to review instances of high OEE loses each day and to act. This involved going to the operator of the machines and discussing the issues, before introducing improvements. Of the 16 machines in the department, 88% showed a positive improvement in OEE performance, as shown in Figure 5. The remaining two machines which showed a 3.1% and 6.5% decrease in OEE performance, had an adjustment made to the target performance values based on the digital VM data. Analysis of the data for these two machines had shown that the performance element of OEE was always greater than 100%, indicating that the target production value was under rated. The target values were corrected to give a more reflective OEE result, which resulted in the OEE decrease.

One of the difficulties with any transformation programme is related to sustainability. Sustainability barriers for OEE systems are related to difficulties in generating, analysing, and displaying results which can cause a loss of momentum and engagement. The digital twin concept meant that OEE data was always readily available to the core team. Furthermore, the digitisation of the VM system resulted in all the daily meeting spent discussing results and actions rather than data integrity. The digital VM system became integrated in the cadence of the department daily activities right after positive results were observed. As such the digital VM system becomes self-sustaining, as the department core team become reliant on the information and found new ways to utilise and analyse the data.

A key objective of the research was to enhance the performance of OEE within the CH department. Enhancing the performance of any Lean tool is reliant on a stable process, which is critical to sustainability. The daily production meetings and improvement actions resulted in the department OEE becoming more consistent. Overall, a 10% increase in the department OEE was observed since the introduction of the digital VM system, contributing significantly to the productivity of the department, and more importantly the OEE increase has been sustained over a long period of time (see Figure J–1, Appendix J).

3.3 I4.0 and digitisation

Development of I4.0 within the organisation will be a determining factor for the success of the research. While OEE results have been excellent and sustained over a long period, the model proposes to develop I4.0 by focusing on digitising traditional Lean tools. To demonstrate I4.0 there must be evidence of innovation and digitisation. Furthermore, there must be evidence of a synergy between I4.0 and Lean.

As mentioned in Section 2.5, data analysis from the digital VM system indicated that changeovers were having a significant impact on lost production time. An SMED project was ongoing within the CH department to reduce lost time to changeovers. In spite of the project successfully, identifying and segregating internal and external factors required for a changeover, produced an ideal target changeover time, and setting up visual aids within the department, changeovers continued to account for 20% of the downtime for some machines. SMED was proposed for digitisation as per the implementation model used in the case study. As part of the digital twin development an HMI was used at each machine. The internal factors required for the changeover process were digitally displayed on the HMI as a series of steps (see Figure E-1 in Appendix E). The operators were required to select each step in sequence so that the designed changeover process was followed. In addition, for longer changeovers it provided a record for operators if the changeover crossed shifts, which steps were completed and what stage the changeover was at. In addition, a video of each step is available to view on the HMI, as a reference of how to complete the step.

Process observations revealed that the internal elements of the changeover were followed and met the designed time. However, by analysing the raw data generated from the machine it was observed that some machines were stopped for up to 40 min before the changeover started. This was valuable information provided by the digital VM system to enhance SMED. Two further improvements were added to the HMI. A visual alert appears on the HMI 2 h prior to the work order completion, to prompt the operator to start preparing the external elements required for the changeover. Once the target work order quantity is reached the machine automatically stops, preventing over production of pieces. Data analysis showed that lost time due to changeovers reduced from 20% to 12% of the total downtime after integration of SMED to the digital VM system, see Figure 6. Additional improvement projects were identified from the digital VM data and decreases in downtime for tool change, problem solving and thread roller were also achieved.

The OEE and SMED digitisations were carried out within the CH department. An organisations I4.0 transformation cannot be demonstrated by limiting it to one department. As part of the CH digitisation, knowledge and skills have been developed within the organisation. Over the course of 12 months, the organisation has become more efficient at identifying and affecting digital transformations. A replicate of the CH digital VM system has since been introduced at the cold forming department. The team have identified additional equipment across the value stream that are judged to be ready for connectivity increasing both the vertical and horizontal integration of equipment in the organisation (see Figure F-1 in Appendix F). A programme is in place in the screw machine department to add PLCs and HMIs to older mechanical equipment that will generate OEE data (see Figure F-2 in Appendix F). The pace of digitisation has increased, 16 machines had digital twins created in 2021, by the end of 2022 a further 31 pieces of equipment will have digital twins created.

An additional objective of the research was to demonstrate that focusing I4.0 transitions on Lean concepts will simplify the transition from regional smart manufacturing concepts to larger modelling platforms such as big data and artificial intelligence. Regional smart manufacturing improvement has been successfully implemented in terms of vertical integration, digital twins and the introduction of digital VM systems. All data that is generated from digitisation is stored in a cloud-based data lake. The implementation model has also been applied to the organisation’s transactional processes, focusing on the enterprise resource planning (ERP) system. A complete set of process maps have been generated for all transaction processes (see Figure G-1 in Appendix G). The maps have identified dysfunctionality across the processes and made waste visible within the system. By mapping the information flow, opportunities for automation have been identified and completed. Furthermore, a digital map of all work orders across the value stream is in the DO phase of the model, whereby a digital twin of the work in progress will be generated (see Figure G-2 in Appendix G). This will allow analysis of product flow across the value stream.