What is a manufacturing execution system (MES)?
MES software monitors, tracks, documents, and controls the process of manufacturing goods from raw materials to finished products.
Manufacturing execution system overview
A manufacturing execution system, or MES, is a comprehensive, dynamic software system that monitors, tracks, documents, and controls the process of manufacturing goods—from raw materials to finished products. Providing a functional layer between enterprise resource planning (ERP) and process control systems, an MES gives decision-makers the data they need to make their plant floor more efficient.
No matter the size of an operation, an MES can contribute to overall productivity and profitability by making the manufacturing process information-driven.
These regulated industries particularly benefit from an MES:
Pharmaceuticals
Food and beverage
Medical devices
Aeronautics and aerospace
Defence
Biotechnology
This is because regulated companies must adhere to strict regulations to ensure traceability compliance. They must make sure that appropriate procedures are in place for building compliant products, that these procedures are documented, and that the resulting products can be easily recalled if necessary.
An MES is essential to drive optimal performance in today’s competitive and rapidly changing manufacturing environment. A Fortune Business Insights report states that “the global MES market is projected to grow to US$41.78 billion by 2032.” This growth is being driven by an increase in the use of industrial automation in process and discrete industries, the growing need for regulatory compliance, and the low deployment cost of manufacturing execution systems.
Top five benefits of MES
Manufacturing execution systems track a huge amount of data, producing real-time insights that can boost production efficiency and save costs. Other benefits of an MES include:
- Improved quality control: As quality control information is transmitted in real time, companies with an MES can immediately halt production as soon as issues are identified. This reduces waste, scrap, overages, and reworking.
- Increased uptime: An MES generates realistic production schedules by balancing personnel, material, and equipment resources. It integrates scheduling and maintenance to maximise product flow and asset utilisation. All this increases uptime and improves overall equipment effectiveness (OEE).
- Reduced inventory: A manufacturing execution system updates inventory records with new production, scrap, and nonconforming material so that your purchasing, shipping, and scheduling departments know exactly what material is on hand at all times. This reduces just-in-case inventory and work-in-progress (WIP) inventory—saving money on manufacturing, transportation, storage, and inventory monitoring.
- Paperless shop floor: Eliminating paperwork means there is less chance for human error. It also means that the data recorded from the shop floor is immediately available to decision-makers across all integrated systems.
- Improved product tracking and genealogy: An MES follows the entire production cycle from beginning to end, grouping final parts or batches with the corresponding manufacturing data. This data allows for improved regulatory compliance for manufacturers that must conform to government or industry regulations.
Core MES features
In 1997, Manufacturing Enterprise Solutions Association International, or MESA, defined the 11 core manufacturing execution system functions. Although the MESA-11 model has evolved over time, those original 11 core functions provide the basis to run almost any type of plant and are integral to today’s manufacturing execution systems. They are:
Resource allocation and status: Use real-time data to track and analyse the status of resources (including machines, materials, and labour) to make allocation adjustments.
Operations/detailed scheduling: Optimise performance by scheduling, timing, and sequencing activities based on priorities and resource capacity.
Dispatching production units: Manage production data flow in real time to easily make quick, calculated adjustments in production dispatching.
Document control: Manage and distribute documents (including work instructions, drawings, standard operating procedures, batch records, and more) so they’re accessible and editable.
Data collection and acquisition: Track and collect real-time data about processes, materials, and operations and use it to improve decision-making and increase efficiency.
labour management: Track worker schedules, qualifications, and authorisations more efficiently.
Quality management: Track quality deviations and exceptions for improved quality control management and documentation.
Process management: Manage the entire production process from order release to finished goods. Gain insight into bottlenecks and points that affect quality while creating full production traceability.
Maintenance management: Use data from your MES to identify potential equipment issues before they happen. It can also be used to adjust equipment, tool, and machine maintenance schedules to reduce downtime and increase efficiency.
Product tracking and genealogy: Track the progress of your products and their genealogy for informed decision-making. Having the data of a product’s full history is extremely useful for manufacturers who must comply with government or industry regulations.
Performance analysis: Compare results and goals to identify strengths and weaknesses in the overall process and use that data to make systems more efficient.
The evolution of MES standards
In the late ‘90s, the International Society of Automation developed the ISA-95 standard. While the MESA-11 model focuses on core MES functions, ISA-95 provides a model to define and integrate the activities between enterprise and control systems. By standardising terminology, ISA-95 makes effective communication between stakeholders, like suppliers and manufacturers, easier. Consistent models also reduce the risk of error when integrating manufacturing sites with business systems.
ISA-95 defines the interface between control and enterprise functions to create levels of technology and business process. A simplified model of that hierarchy puts manufacturing execution systems at level three—between business planning and logistics and process control systems:
Level 4: ERP (business planning and logistics)
Level 3: MES (manufacturing operations management)
Level 2: Process control systems (batch control)
Level 1: Process control systems (continuous control)
Level 0: Process control systems (discrete control)
MES and ERP integration
In today’s manufacturing environment, it’s not a case of MES versus ERP. Together, MES and ERP bring operational clarity that neither system can provide on its own.
ERP focuses on creating and managing plant schedules. That includes production, material use, delivery, and shipping—as well as gathering information about your business. Manufacturing execution systems, on the other hand, focus on managing and monitoring manufacturing operations and reporting on production line activities in real time.
Together, an ERP and an MES create an integrated ecosystem, offering a holistic view of finance, procurement, supply chain management, manufacturing logistics, and more. Combining that information increases agility and provides robust data that improves forecasting on everything from sales to asset utilisation to manufacturing management.
ERP systems give you the data to determine what products to manufacture, while a MES integrates ERP data with plant floor information to determine how to produce those products with less waste and more profit.
Cloud MES: digitising shop floor operations
Fueled by advanced technologies, manufacturing execution systems are evolving to become service-oriented, modular, and connected.
Cloud connectivity is the backbone of smart factories, allowing advanced manufacturing systems, devices, products, and equipment to interact autonomously. IIoT (Industrial Internet of Things) devices and sensors across the supply chain are continually gathering and generating data. This real-time sharing of data helps smart factories automate better workflows, customise products and services, and grow smarter and more efficient over time.
MES software can also help manufacturers take advantage of a key trend in the evolution of manufacturing execution systems: customised production. Instead of mass production, your smart factory provide mass personalisation and meet the demand for less expensive, highly tailored products with speed and affordability.
While personalisation makes manufacturing more complex, advanced technologies can help manufacturing systems to react and pivot in real time. Artificial intelligence (AI) can improve production efficiency, handle predictive maintenance, and reduce waste. Tapping into machine learning capabilities, production lines can become increasingly smart and efficient. With virtual reality (VR), manufacturers can simulate processes and identify potential improvements. And they can integrate augmented reality (AR) solutions to reduce production downtime and optimise shop floor operations.
All of these advanced technologies and capabilities make it easier for companies to compete in a digital world. They can respond to demand rapidly and accurately with customised products that are lower in cost and higher in quality.
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