Implementation of an ISO 50001 energy management system using Lean Six Sigma in an Irish dairy: a case study

3.1 The case study methodology

The research methodology of this paper is case research using the DMAIC methodology. As the RQs in this study are based on “how to use LSS methodology to improve energy management”, Yin (2014) recommends that this “how” research question lends itself to the case study approach. Many studies utilising DMAIC methodology to solve problems and answer “how” and “why” RQs have utilised the case study approach to aid understanding of the problem and its context (Sony, 2019; Li et al., 2019). Based on the research type and conditions and using DMAIC, a mix of qualitative and quantitative tools, the authors use a single-case study approach utilising a dairy. The single case approach focusing on a single phenomenon aids understanding of the areas being studied in the context of RQs (Lee, 1999). Yin (1981, 2009) defined the case study as an empirical investigation of a contemporary phenomenon in a real-life context. The extent to which one can generalise from a single case study is limited, but each case adds to the state of the art available for future practitioners and researchers (Antony et al., 2012).

3.2 Roadmap and DMAIC

The team at the Lakeland dairy plant in Killeshandra has identified energy as the second-largest overhead on-site, just behind labour spend; electricity is equivalent to 30% of total kWh use, 70% being the site thermal load. Electricity, in 2019, accounted for 52% of the energy spend, i.e. although 30% of the kWh total for the site. Electricity in 2019 was considerably more expensive than the thermal sources of Heavy Fuel Oil (HFO) and Liquid Petroleum Gasoline (LPG). Due to its relatively remote location, Killeshandra dairy is “off-grid” when it comes to meeting its thermal load, there is no accessible natural gas line and there is none planned in the foreseeable future. Relatively expensive HFO was the fuel burned to produce steam to provide the heat for all parts of the factory. Not unlike most dairies, the processes utilised in Killeshandra are very energy-intensive with considerable heating and cooling loads. For the basis of this project, 2019 was chosen as the base year and any savings in 2022 will compare against 2019 energy consumption. This project coincided with the COVID-19 pandemic, 2020/21 are considered abnormal years with much reduced volumes in some areas, thus a unique product mix across the facility. The optimisation of the energy use, i.e. the electrical and thermal loads at the dairy plant, is performed using the DMAIC methodology, as shown in Figure 1.

This was planned to design a roadmap for reducing energy consumption and further process accreditation according to ISO 50001 standard. The energy management system to be awarded ISO 50001 accreditation must meet the pre-requisites whilst demonstrating the annual improvement in energy efficiency at the dairy plant. The energy management team was familiar with the DMAIC concept through completed projects as part of Lean Six Sigma green belt training.

3.3 Define the project goals and customer deliverables

The Define phase in the problem-solving approach scoped the problem statement and gathered the voice of the organisation and customer. In this case, the team captured the problem statement in the form of a project charter that outlines the scope of the DMAIC project. This team charter, which feeds into an energy policy for the site, was created and agreed by the energy management team, as shown in Figure 2.

The charter calls out the objective, stakeholders, risks etc (see Figure 3). The Voice of the Customer (VOC) is also sought and an overall SIPOC is created to ensure that the project charter and scope meet the needs of the various stakeholders within the business. Stakeholder analysis is vital as the goals and objectives of the project should be supported by the stakeholders, that is, those who will be either impacted by the project or who may influence the project (Taghizadegn, 2014).

Step two of the Define phase consisted of a stakeholder analysis formulated in line with a communication plan to engage and communicate with the stakeholders throughout the project lifetime and became a part of the project charter. It has been shown in the previous studies that the charter defines the communication plan and tools, which are the key parameters throughout the life of the project. It enables employees and cross-functional stakeholders to understand how their operating environment performs and how it may transform in the future.

3.4 Measure current performance

In the Measure phase, the team collect available data by observing and recording the selected processes. The data collection plan was subsequently developed that identifies how the data would be collected and analysed. As the data is collected, it allows the team to develop descriptive statistics of the actual performance in the area. First, the energy metering strategy was refined so that a Pareto analysis of energy could be performed to allow the Significant Energy Users (SEUs) to be identified and analysed. In the present case study, SEU was categorised into groups such as (1) Steam Boilers; (2) Compressed air; (3) Refrigeration; (4) Separation and Evaporator; (5) UHT; (6) Casein; (7) Lactose; and (8) WWTP. During the Measure phase, JMP software (version 16.0, JMP Germany) allowed the energy management team to put quantifiable data to back up their hypotheses of SEU definitions. The Measure phase has also highlighted other less considered areas in the past to identify a saving potential with the energy-efficient use at the dairy plant. Regression analysis was performed to give specific energy performance for the distinct business units and typically measured kWh/unit of production.

3.5 Analyse and determine root cause of defects

Implementing a LSS approach, as done in this case study, allows an organisation to focus on both Lean and Six Sigma simultaneously, providing the best results for improved quality and process efficiency (Plenert and Cluley, 2012). The analyse phase consisted of both Lean and Six Sigma tools.

Once the project team identified the appropriate data sets, a detailed analysis of the data was performed. For the majority of SEUs, this typically involved further regression analysis to determine if there was any relationship and, if so, the derivation of a prediction equation and key performance indicators (KPIs) for each SEU. In addition, other Six Sigma tools were used during the Measure phase, such as Cause-Effect and C_pk studies, to identify factors that may have a significant effect on energy consumption. Following statistical analysis and brainstorming through the fishbone exercise, the team then evaluated each primal under the following conditions to identify the waste generated by categorising the value-added and non-value added activities.

3.6 Improve the process

Brainstorming exercises with a broad workforce sample were carried out to identify energy-saving projects that were added to an energy “opportunities register”, essentially a large list of possible projects that, if implemented, might reduce either the electrical or thermal load on-site. Capital expenditure and resultant savings were estimated to give an initial idea of project payback. This process was carried out with specialist external energy consultants and met an “External Energy Audit” requirement, a distinct clause of the ISO 50001 standard. Tools such as a prioritisation matrix were incorporated into the opportunities register to help identify those projects that should be progressed. The dairy management and consultancy defined the weightings in the prioritisation matrix. The most significant features from the opportunities register were further screened in the prioritisation matrix using “easy wins”, “high potential”, “low priority” and “long game” solutions in relation to the energy upgrade at the dairy plant.

3.7 Control future process performance

Monitoring, measurement and continual analysis is a key requirement of ISO 50001. Prediction expressions were used to compare actual energy consumption versus target and control charts were used to satisfy the energy team that a particular process is in control and at target. The pre-thermal transformation process is relatively simple by representing steam boilers as suppliers of a few heat sinks which contain a minimal number of outliers. From June 2022 onwards, it will be a much more complex system after fully implementing the LNG thermal transformation project. JMP software will be a key tool to ascertain relationships between variables (factors), e.g. heat recovery average temperature or run time on a UHT steriliser and affects such as the LNG usage by the three new LPHW boilers and CHP engine. The prediction profiler function may be used to optimise process settings and the prediction equation is used to set targets and annual energy budgets.

4.1 Define phase

During the Define phase of the project, an energy management team was first formed. This core team, selected by the author and the sponsor, took part in a one-day workshop event to define the expectations of the project with a view to the development of a project charter and an energy policy, a key requirement and initial deliverable for ISO 50001 accreditation. The site manager signed the energy policy and was the project’s sponsor. The energy policy fed into the project charter, which defined the business case, problem statement, scope, milestones, deliverables and overall DMAIC timeline.

As part of the one-day workshop, a SIPOC was created to define the project scope and help the energy management team clarify the inputs and outputs for the remainder of the DMAIC project, as illustrated in Figure 3. The outputs defined in the SIPOC ensure that the objectives and targets for the project were relevant and appropriate.

The define step was deemed essential by the energy management team as it helped to develop a common understanding of the problem and the objectives which are necessary to implement as a part of a benchmark energy management system. It was agreed that failure to define the scope properly and the vision for the project increased the risk of scope creep later in the project. By identifying the critical few SEUs, the team could ensure that they worked on the right projects.

The ISO 50001 framework stipulates that Significant Energy Users (SEUs) was defined for the site, which were further brought forward through the DMAIC project steps. To ascertain the SEUs, the site metering strategy for both electricity and steam was optimized according to the results from the Pareto analysis, as shown in Figure 4.

4.2 Measure phase

During the Measure phase of the project, the team aligned on the key objectives, gathered the data and quantified energy performance using various statistical and Six Sigma tools for the site and SEUs using the categorisation from the Define phase. This part of the project again went hand in hand with the ISO 50001 implementation and an annual company energy review.

Current results in the Measure phase show a steady increase in energy consumption from 14,205 MWh in 2013 to 21,123 MWh in 2019. This increase can be attributed to an increase in volume rather than a decline in energy efficiency and a CUSUM analysis reinforces this hypothesis. CUSUM analysis compares two separated periods of data to each other, in this case, to assess electrical performance in 2019 Vs 2018. Figure 5 illustrates the results of the CUSUM analysis of entire site electrical consumption for 2019 vs 2018.

It can be seen that the site CUSUM follows the same pattern as the CUSUM for the casein plant, i.e. the site electricity will go up and down with the casein production profile. Regression analysis on both overall site electricity and casein electricity is performed later. The variation of production volumes through each food ingredient and food service business meant that an overall KPI for site electricity consumption was initially difficult to define. Therefore, a multi-variant regression analysis was performed to ascertain the resultant energy consumption with changes in site product mix. The two key effects identified were skim processed through the casein plant and the UHT plant production output. Figure 6 shows the response, including the prediction equation.

The response variability was determined with an R² value of 0.98 and a p-value of less than 0.0001 for both skim throughput in the casein plant. The UHT plant volume was characterised as significant, demonstrating a linear relationship. The total site electricity in KWh was calculated to be 348,459 + (0.055 × litres of skim throughput in casein) + (0.237 × litres produced in the UHT plant). To satisfy the ISO 50001 standard, a similar regression analysis was carried out for each of the SEUs, where the prediction equation could then be used to set a monthly target KPI and consequently predict monthly manufacturing volumes. These equations will be further used to quantify the baseline performance for each SEUs and to make suggestions for the project improvement.

Both the electricity and thermal load are significant in dairy processing facilities. Steam use (tonnes) and electricity demand were converted to kWh and using JMP software, a model for the total site steam consumption and electricity demand was established, as shown in Figure 6. Whole milk intake (litres), skimmed milk processed (litres), casein (tonnes), UHT production (litres), ice cream production (aerated litres) and lactose (tonnes) volumes were initially selected as possible model effects. Effects with a p-value greater than 0.03 were removed, leaving the model in a form as shown in Figure 7.

The R² value is 0.97, indicating a very good linear relationship and the low p-values for UHT (litres) and lactose (tonnes) show that these two factors are significant. Predicted steam consumption in kWh is therefore −584015 + (1.267 × UHT production, litres) + (4576.80 × Lactose production tonnes). It should be noted that, unlike a typical spray dryer that uses steam, the casein dryers are attrition type that burns liquefied natural gas (LPG) to create a stream of hot air. Thus, the model presented in Figure 7 includes the dryers’ thermal load.

In Lakeland Dairies Killeshandra, 8 bar (g) compressed air is generated using 160 kW and 200 kW fixed drive machines and a 250 kW variable speed drive compressor. When reviewing compressed air system performance, there are two main KPIs to be measured, total electricity used to generate compressed air (a direct measure of the quantity of compressed air used) and the specific energy consumption of the air compressors, i.e. the quantity of compressed air (output) for every kWh of electricity (input) to the three air compressors. Electrical consumption used to make compressed air can be 12,208 − (0.084 × aerated litres of ice cream) + (0.124 × UHT litres) – (0.010 × whole milk intake) + (434 × casein tonnes). The corresponding R² is 95% which emphasises the high quality of the established JMP model. Using regression analysis, the actual efficiency of the air compressors is calculated as 6.23 m³ pro kWh, i.e. for every kWh of electricity input, we obtain 6.23 m³ of compressed air. With the R² of 0.96, the model indicates that the specific energy consumption does not change with a corresponding volume change. The high thermal loads could cause high cooling loads, which are generated by the chilled water at 2°C from an ammonia refrigeration plant. This can be calculated as equivalent kWh of chilled water divided by the kWh of electricity used to chill that water. Only the skim processed through the casein plant was significant in terms of variation and there is a baseload of 118,209 kWh pro month through the UHT and ice cream departments when casein production is zero. Steam boiler efficiency is essentially a measure of the energy out (heat in the form of steam) divided by the total available kWh in the fuel. The average monthly efficiency of the steam and oil flow meters was calculated at just 53%. In practice, the steam system efficiency is less than 50% as steam is used for hot well heating (boiler feed water) and heating required to maintain the HFO at a temperature where it will flow from HFO tanks to the boiler burners.

When “whole” milk is first delivered to the site, it is sent through a separation process to give cream and skim milk. These two product streams are then pasteurised before the skim is sent to other production departments for processing. The cream is cooled to 6°C and sent to other sites in the group to be processed, e.g. for the churning of butter. Whey streams from the casein are sent through a series of membrane plants to give whey protein concentrate (WPC) and lactose-containing permeate is put through an evaporator, increasing solid content before sending it to crystallisation tanks at the lactose plant. Milk separators, pasteurisers and the steam evaporator are identified as one SEU, including electrical and thermal use in the area. Steam use is predominantly affected by the lactose production volume. In addition, the evaporator is part of the lactose manufacturing process, which is known as a very energy-intensive process. The model showed the R² of 0.97, which indicates a good fit for the predicted steam usage described by the equation of 126,224 + (2921 × lactose tonnes) in kWh. The regression analysis for electricity gave an R² value of 0.95 when kWh of electricity is plotted against skim processed using the equation of 12,856 +(0.0030 × skim throughput litres) in kWh. The electrical consumption at the evaporator was shown to be less than that in the separation area using the equation of 3,096 + (97 × Lactose tonnes) in kWh.

The SEU defined by the energy team for the UHT department includes all the electrical equipment and process steam used in the production of both UHT products and ice cream. There are two different types of sterilising plant used, infusion plant versus tubular, but it was observed from the JMP modelling that sterilising plant is not significant in this case study. The number of CIPs (Clean in Process) carried out at the dairy plants was significant, approximating 1.2 tonnes of steam for each CIP performed. The level of the variation in ice cream volume observed by the team is not significant for the steam used during operation. This is because there is a constant steam baseload in ice cream manufacturing. Product mix and changes in volume output for each of the main product families (production lines) were considered when the initial model for UHT/HIC electricity was established. The high p-values did not highlight any significant effects. Thus, simple regression analysis for electricity was predicted to be 60,886 + (0.0665 × UHT litres) in kWh.

The casein plant is the largest energy user on-site, including a series of pasteurisers, coagulation plants (with hydraulic acid), membrane plants and dryers. The regression analysis for electricity and steam determined the R² values of 0.91 and 0.98 for steam and electricity, respectively, indicating that the regression model fits the data. Steam usage is estimated to be 135,012 + (2.12 × casein tonnes) kWh and electricity consumption is 55,967 + (909 × casein tonnes) kWh. Chilled water energy use is not included in this electricity number. LPG (propane) is the fuel used in the two casein burners that feed hot air to each casein dryer. The regression analysis indicates that this energy use can be quantified as 71,644 + (633 × Casein tonnes) kWh. Steam consumption for the lactose plant can be approximated as 14,614 + (668 × lactose tonnes) in kWh, whereas electricity can be approximated as 8,172 + (192 × lactose tonnes) in kWh.

4.3 Analyse

Once the Measure phase was completed, the energy management team could evaluate a baseline performance and potential improvements with the quantified project savings. After several brainstorming exercises and with the help of an external energy consultant, a register of opportunities was created by the energy management team, as shown in Figure 8.

The Lakeland Dairies site in Killeshandra is off-grid in terms of thermal energy supply. Thus, other energy demands associated with HFO, such as preheating of oil, tank heating and technical inability to use flue gas economisers on HFO boilers (due to generation of sulphuric acid during condensing), indicated that HFO steam boilers might not be the optimum technology for optimal generation of the site’s thermal needs. The purchasing department informed the energy team that HFO will be phased out from 2024. A reduction in supply may result in a higher fuel cost. Excess hot water and steam are pumped to the WWTP. Typically, this is perfectly clean, warm water, but because there were no heat sinks for the heat to be used, the water is pumped to the WWTP and thus, increasing costs.

4.4 Improve

Following the detailed design and definition of savings in the Analyse phase of the project, the Improve phase was initiated using thermal reconfiguration of the dairy plant. This was achieved through the integration of heat recovery instead of the previously used waste heat systems, the use of LPHW instead of steam in all viable processes and the improvement of the total dairy plant efficiency concerning the combined use of steam and hot water systems, as shown in Figure 11.

Three 1,000 kW Hot Water Boilers will supply LPHW and a LPHW distribution network will be installed on-site. The heat load for each user was calculated so that the hot water boilers could be sized accordingly. Two new 10 tonne pro hour LNG steam boilers will be installed in the current steam boiler house and sized according to the case scenario that if LPHW is not available, the manufacturing departments can revert to steam, thus offering full duty standby and business continuity. On the advice of the external consultants, a new “deaerator” will be installed to treat boiler feed water. The deaerator is essentially a large kettle that is designed to remove corrosive gases, dissolved oxygen and carbon dioxide to a level where corrosion is minimised. In addition, the storage capacity for recovered heat will be increased with a new 300 m³ heat recovery tank which will be a source of heat from the evaporator condensate, the CHP intercooler, oil cooler and UHT cooling water (Brush et al., 2011). This tank will then supply domestic hot water (DHW) to all CIP centres and wash water stations on site. It is envisaged that a CHP unit will generate 1,000 kW of electricity and 1,078 kW of thermal energy (to heat water for the LPHW system) with an electrical efficiency of 40.9% and a thermal efficiency of 46.4% by giving an overall system efficiency of 97.3%.

Other benefits of the thermal reconfiguration project have emerged, including the overall energy use minimisation at the dairy plant. The total volume of flue gases will be improved by reducing the gross CO₂ emissions of the facility by 9,531 tonnes (46%). The change of fuel from HFO to LNG will reduce the harmful emissions associated with the burning of high sulphur HFO.

NO_x will be reduced by 75%, whereas SO_x emissions will be eliminated. Business continuity will be enhanced due to the installation of new steam boilers, which will have full N + 1 redundancy, which are currently not available at the peak loads. The high quantity of LNG that is defined as a hazardous substance must be safely stored on-site at the dairy plant with the preliminary safety assessment according to Controls of Major Accident Hazards (COMAH) regulations. To the authors’ best knowledge, the Lakeland Diaries facility in Killeshandra will become the first site in Ireland to meet the national LNG storage regulations.

In the next steps of the Improve phase, Gantt charts will be actively used to define the roadmap for the thermal transformation program. Inputs for the roadmap will be sourced from the stakeholder analysis, managers and supervisors, including capacity planning, timing and individual measures of success. In the form of design reviews and construction reviews facilitated by the project team, workshops took place to understand the most optimal sequencing of project actions. Risk assessment exercises were undertaken as part of these reviews to identify and manage potential risks during the Improve phase of the project. In addition, change and communication plans will be completed and verified with the project team, contractors and sponsor prior to implementing the Improve phase.

4.5 Control

After installing equipment and processes in the Improve phase, all new energy systems will be commissioned using a structured process following commissioning protocols. The Control phase is important for the project certification according to ISO 50001 standard. Statistical analysis using X bar and R charts and control charts are used to control how the developed model will be continuously followed to meet the requirements of ISO 50001 standard. The thermal process became more complex with the introduction of heat recovery and CHP to provide hot water at the dairy plant. Therefore, the variant analysis should be performed to optimise process settings, e.g. water temperatures or flows, to obtain an optimum energy performance. A full MV (measurement and verification) report will be written to confirm all savings identified in the Improve phase. This MV report will be approved by an independent external consultant to maintain impartiality and give confidence to the actual savings declared by the energy management team. The team will essentially repeat the Measure phase, using JMP variant analysis (ANOVA), multi-variant regression analysis and other tools to compare baseline usage for the savings quantification. Process control charts are used to review weekly energy consumption by each SEU with action limits set at ±10% from the target. The site metering strategy is integrated into the control chart to track each energy meter and will be further updated when a new meter is added to the dairy plant facility. The data from the meters on the consumption of electricity, steam, compressed air and chilled water is given in a kWh pro unit for each SEU. ISO 50001 standard requires a defined internal auditing process whereby each SEU is reviewed annually by a trained auditor and non-conformances are captured in a non-conformance register. When a KPI is outside target limits for more than 3 consecutive weeks, a non-conformance is also raised and added to the register. This will lead to a change in a statistical model, including the eight tests as special causes.