Food and drink engineer (level 5)
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Information about Food and drink engineer (level 5)
Maintaining, managing and installing a diverse range of specialist equipment and technology used in the manufacture of food and drink products.
- Knowledge, skills and behaviours
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View knowledge, skills and behaviours
Knowledge
- Legislative, regulatory and ethical requirements, such as Dangerous Substances and Explosive Atmospheres (DSEAR) and Atmospheres and Explosives (ATEX) regulations, and their application to food engineering processes; food safety, hazard analysis and critical control points (HACCP), health & safety and environmental considerations.
- Food science and technology; how engineering is used in food and drink production: heating processing, packaging, modified atmosphere packaging (MAP), preservation, chilling, freezing, sterilisation.
- Engineering processes and equipment including automation and controls to make and deliver products to market: shaping forming equipment, ovens, chillers, freezers, sterilisers, MAP packing machines, check weighers, temperers, washing/cleaning, fillers, extruders, bulk solid handling & distribution and liquid systems process validation, sieving, filtration, metal detection, bar code verification metal detection wrapping and palletising.
- Engineering theory and techniques to develop processes i.e. thermodynamic and thermo-fluid analysis heat transfer can be applied to design of baking, cooling, preserving, freezing, chilling systems.
- Hygienic engineering principles relating to type of material, machine assembly, design and practice; and their importance to delivering food hygiene and safety and employee health and safety requirements in a food and drink process.
- Packing materials in food; inter-relationships with food ingredients, final product and their effects on safety, quality and performance through the supply chain i.e. how to engineer correct seals on film, cardboard, tins, stable transportation, moisture barriers.
- Problem solving tools to analyse e.g. Define, Measure, Analyse, Improve Control (DMAIC) principles.
- Interpretation and evaluation techniques.
- Overall Equipment Efficiencies (OEE), for example Smart Reliability Driven Maintenance approaches including Reliability Centred Maintenance (RCM)/ Failure mode, effects, and critical analysis (FMECA), Condition Monitoring Techniques and applications, Single minute change of Die (SMED), Line balance.
- Risk management techniques, reliability/criticality tools and how they are used to reduce operational losses/wastage operations.
- Life Cycle Asset Management (LCAM), Criticality Analysis & Technology Selection (CATS), Intelligent Maintenance, Repair and Operations (inventory) (MRO) Optimisation.
- Product, machinery specifications: how they are used to set capability measurement, performance testing and maintenance requirements to deliver a standard set of operating conditions for consistent product delivery.
- Effective planning and scheduling, including effective communication, team working and project management techniques.
- Customer/food trade association standards, such as British Retail Consortium, Retailer and Engineering standards.
- General manufacturing services: steam, pneumatics and hydraulics, electrical supply, refrigeration, water supply and effluent.
- Manufacturing services specific to food: air filtration, oil free compressors, cleanliness of steam for food, sieving of materials, use of food grade lubricant, primary secondary cooling chemicals for food, MAP gases and generation i.e. Nitrogen.
- Factory digitisation/optimisation (Iot, Factory 2020 principles), for example principles of control engineering, logic controllers and data communication systems, sensors and devices, drives and transmissions, pumps and distribution systems, safety circuit systems, computer aided design, shop floor data gathering, PC use and computerised maintenance.
- Digitisation: 4.0, modelling of lines/process, 3d modelling scanning and printing, product dimensional measurement, rheology measurement.
- Mechanical design, mechanical analysis (static) performance of components, mechanisms and systems; study of friction wear; the science of interacting surfaces in relative motion (tribology).
- Laws of thermodynamics and its applications within a hygienic food and drink environment: the fundamentals of heat transfer, thermo-fluid analysis, entropy, energy efficiency; conservation and sustainability.
- Steam fundamentals such as fuel types, combustion, feedwater, boiler controls and instrumentation, operation of boilers, safety and legal requirements and boiler efficiency.
- Heat recovery systems and energy management including the requirements of efficient best practice.
- Legislative, regulatory and ethical requirements, such as Dangerous Substances and Explosive Atmospheres (DSEAR) and Atmospheres and Explosives (ATEX) regulations, and their application to food engineering processes; food safety, hazard analysis and critical control points (HACCP), health & safety and environmental considerations.
- Food science and technology; how engineering is used in food and drink production: heating processing, packaging, modified atmosphere packaging (MAP), preservation, chilling, freezing, sterilisation.
- Engineering processes and equipment including automation and controls to make and deliver products to market: shaping forming equipment, ovens, chillers, freezers, sterilisers, MAP packing machines, check weighers, temperers, washing/cleaning, fillers, extruders, bulk solid handling & distribution and liquid systems process validation, sieving, filtration, metal detection, bar code verification metal detection wrapping and palletising.
- Engineering theory and techniques to develop processes i.e. thermodynamic and thermo-fluid analysis heat transfer can be applied to design of baking, cooling, preserving, freezing, chilling systems.
- Hygienic engineering principles relating to type of material, machine assembly, design and practice; and their importance to delivering food hygiene and safety and employee health and safety requirements in a food and drink process.
- Packing materials in food; inter-relationships with food ingredients, final product and their effects on safety, quality and performance through the supply chain i.e. how to engineer correct seals on film, cardboard, tins, stable transportation, moisture barriers.
- Problem solving tools to analyse e.g. Define, Measure, Analyse, Improve Control (DMAIC) principles.
- Interpretation and evaluation techniques.
- Overall Equipment Efficiencies (OEE), for example Smart Reliability Driven Maintenance approaches including Reliability Centred Maintenance (RCM)/ Failure mode, effects, and critical analysis (FMECA), Condition Monitoring Techniques and applications, Single minute change of Die (SMED), Line balance.
- Risk management techniques, reliability/criticality tools and how they are used to reduce operational losses/wastage operations.
- Life Cycle Asset Management (LCAM), Criticality Analysis & Technology Selection (CATS), Intelligent Maintenance, Repair and Operations (inventory) (MRO) Optimisation.
- Product, machinery specifications: how they are used to set capability measurement, performance testing and maintenance requirements to deliver a standard set of operating conditions for consistent product delivery.
- Effective planning and scheduling, including effective communication, team working and project management techniques.
- Customer/food trade association standards, such as British Retail Consortium, Retailer and Engineering standards.
- General manufacturing services: steam, pneumatics and hydraulics, electrical supply, refrigeration, water supply and effluent.
- Manufacturing services specific to food: air filtration, oil free compressors, cleanliness of steam for food, sieving of materials, use of food grade lubricant, primary secondary cooling chemicals for food, MAP gases and generation i.e. Nitrogen.
- Factory digitisation/optimisation (Iot, Factory 2020 principles), for example principles of control engineering, logic controllers and data communication systems, sensors and devices, drives and transmissions, pumps and distribution systems, safety circuit systems, computer aided design, shop floor data gathering, PC use and computerised maintenance.
- Digitisation: 4.0, modelling of lines/process, 3d modelling scanning and printing, product dimensional measurement, rheology measurement.
- Electrical and electronic systems, design techniques and their applications to British Standards.
- Installation of systems and supply systems following food safety standards e.g. tray work.
- Advanced electrical principles (low voltage (LV) to high voltage (HV)).
- Instrumentation and calibration techniques for systems, for example thermo, weights and flow.
- Automation and control systems primarily with the following low voltage systems, i.e. building automation systems, heating, ventilation and air conditioning (HVAC) controls, access control systems, data cabling and fiber optic cable installation and termination.
- Supervisory control and data acquisition (SCADA) and network systems
- Electrical safety systems and smart solutions.
Skills
- Use engineering principles to deliver products/packaged food.
- Comply with standard operating procedures, company, legal and regulatory requirements and customer/consumer and engineering standards.
- Plan, for example labour and engineering materials.
- Influence and communicate with colleagues and others, such as engineers, other functions and teams.
- Assess team and individual performance, provide feedback to improve; coach and mentor.
- Use continuous improvement techniques, for example apply quality management principles, participate in failure investigations and contribute to and implement practical engineering solutions for efficiency and/or profitability.
- Use IT, digitisation and manual methods to collect data from systems to support engineering activity within the business.
- Use and develop planned preventative maintenance (PPM) strategies, incorporate appropriate proactive maintenance routines, such as vibration analysis, thermography, simple visual/part measurement.
- Analyse operational performance, specification and data.
- Evaluate possible failure modes and identify strategy, for example technical risk assessment methods, PPM to RCM techniques.
- Contribute to the construction and commissioning of equipment and machinery used for producing preserved/fresh and safe food and drink products.
- Design, produce, and operate mechanical machinery.
- Design power circuits, utilising software and calculation.
- Apply specialist reliability engineering techniques to prevent or reduce the likelihood or frequency of failures i.e. vibration analysis, oil sampling, heat mapping, non-destructive testing.
- Apply thermodynamic theory to more complex engineering systems, for example tempering chocolate, cleaning systems, sterilisation, vacuum cooling.
- Design and improve systems, for example steam, water or air.
- Use engineering principles to deliver products/packaged food.
- Comply with standard operating procedures, company, legal and regulatory requirements and customer/consumer and engineering standards.
- Plan, for example labour and engineering materials.
- Influence and communicate with colleagues and others, such as engineers, other functions and teams.
- Assess team and individual performance, provide feedback to improve; coach and mentor.
- Use continuous improvement techniques, for example apply quality management principles, participate in failure investigations and contribute to and implement practical engineering solutions for efficiency and/or profitability.
- Use IT, digitisation and manual methods to collect data from systems to support engineering activity within the business.
- Use and develop planned preventative maintenance (PPM) strategies, incorporate appropriate proactive maintenance routines, such as vibration analysis, thermography, simple visual/part measurement.
- Analyse operational performance, specification and data.
- Evaluate possible failure modes and identify strategy, for example technical risk assessment methods, PPM to RCM techniques.
- Contribute to the construction and commissioning of equipment and machinery used for producing preserved/fresh and safe food and drink products.
- Design and configure electrical systems i.e. add distribution boards to circuits.
- Modell dynamic systems utilising software tools.
- Design and modify electrical control engineering systems i.e.: Engineering LAN/ network.
- Diagnose faults on complex control systems.
- Decipher complex programme sequences in higher and lower level languages.
Behaviours
- Safe working, for example promotes a culture of food safety and safe working practices.
- Takes ownership of work, for example takes responsibility and ownership of decision making for good food practice; is proactive, and demonstrates initiative; plans work: dependable; works autonomously within own sphere of responsibility.
- Shows pride in work, for example strong work ethic; displays a positive mind set; pays attention to detail; looks for new ways of working that improve outcomes and results.
- Committed to self-development, for example seeks learning, drives the development of self and others; maintains and enhances own practice through continuing professional development activity.
- Shows integrity and respect, for example promotes integrity in process and site standards, respects others, promotes good communication at all levels, adapts personal style to meet work needs.
- Team player, for example drives good relationships with others, works collaboratively, contributes ideas and challenges appropriately.
- Responsive to change, for example flexible to changing working environment and demands; resilient under pressure.
- Shows company/industry perspective, for example promotes the position of the business in relation to market and competition, keeps up to date with industry and market advancement, commercially aware.
- Safe working, for example promotes a culture of food safety and safe working practices.
- Takes ownership of work, for example takes responsibility and ownership of decision making for good food practice; is proactive, and demonstrates initiative; plans work: dependable; works autonomously within own sphere of responsibility.
- Shows pride in work, for example strong work ethic; displays a positive mind set; pays attention to detail; looks for new ways of working that improve outcomes and results.
- Committed to self-development, for example seeks learning, drives the development of self and others; maintains and enhances own practice through continuing professional development activity.
- Shows integrity and respect, for example promotes integrity in process and site standards, respects others, promotes good communication at all levels, adapts personal style to meet work needs.
- Team player, for example drives good relationships with others, works collaboratively, contributes ideas and challenges appropriately.
- Responsive to change, for example flexible to changing working environment and demands; resilient under pressure.
- Shows company/industry perspective, for example promotes the position of the business in relation to market and competition, keeps up to date with industry and market advancement, commercially aware.
- Apprenticeship category (sector)
- Engineering and manufacturing
- Qualification level
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5
Equal to higher national diploma (HND) - Course duration
- 36 months
- Maximum funding
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£18,000
Maximum government funding for
apprenticeship training and assessment costs. - Job titles include
-
- Continuous improvement food and drink engineer
- Food and drink electrical engineer
- Food and drink mechanical engineer
- Food and drink reliability engineer
View more information about Food and drink engineer (level 5) from the Institute for Apprenticeships and Technical Education.