Public Funding for Hexagon Metrology Limited

This is a two year programme of work that is aligned to the ATI strategy to Protect, Exploit and Position UK key Aerostructures companies that brings together a consortium of Prime and leading supply chain companies within the civil aerospace sector with the following aim: “To maintain and strengthen UK Aerostructures manufacturing capability for conventional and next generation airframe structures in support of maintaining complete wing capability for UK manufacturing.” This proposal is an integrated part of a seven year strategic target to generate a future factory vision that enables component manufacture, assembly and equipping to be developed and proven in a safe environment in a novel way, before it is applied to the production line, differentiating the future facility from any other global benchmark. The strategic vision will develop a number of key outputs that will define a world class manufacturing facility: Vertical and horizontal integration of the supply chain in the virtual environment to manage logistics, zero variation, and product customisation Low energy facility and technologies to minimise operational costs within the plant A reconfigurable industrial facility to meet operational needs such as surge capacity, rate fluctuation and product mix variation A high level of automated activities to minimise variation, eliminate repetitive and unwieldy tasks, qualify processes and equipment, and realise measurement assisted manufacture to optimise product quality. The project will also generate spin off technologies virtually from the start that can be transferred to production as soon as they are mature enough to begin to deliver benefit on today’s products.

This project will devise and verify new automated manufacturing technologies that will enable effective mass production of high-end (high performance) optics. The project will realise new UK-designed and built automated manufacturing technologies appropriate for defence and commerial sector optics. Today, leading companies producing high-end optics employ very precise machines which are manually loaded/unloaded and have separate post-production inspection requiring manual operation. This project will develop and verify new automation methods that are functional for delicate optical workpieces and integrate a new in-situ measurement technique that can improve production rate and yield. The project will advance research outputs of a previous research council funded project (which created a highly novel compact machine concept) and apply to that concept new automation techniques for loading/unloading and in-situ measurement appropriate for both infrared and visible optics. This type of automation has previously not been applied. Today, demand for reduced size optics is common, and production batch sizes are increasing. These two factors raise the importance of automation. Significantly, the load/unload times are becoming a greater % of overall cycle times in optics production. The project partners include the UK's leading optical systems manufacturer and a spin-out company from the UK's leading Precision Engineering research institute.

This project will devise and verify new automated manufacturing technologies that will enable effective mass production of high-end (high performance) optics. The project will realise new UK-designed and built automated manufacturing technologies appropriate for defence and commerial sector optics. Today, leading companies producing high-end optics employ very precise machines which are manually loaded/unloaded and have separate post-production inspection requiring manual operation. This project will develop and verify new automation methods that are functional for delicate optical workpieces and integrate a new in-situ measurement technique that can improve production rate and yield. The project will advance research outputs of a previous research council funded project (which created a highly novel compact machine concept) and apply to that concept new automation techniques for loading/unloading and in-situ measurement appropriate for both infrared and visible optics. This type of automation has previously not been applied. Today, demand for reduced size optics is common, and production batch sizes are increasing. These two factors raise the importance of automation. Significantly, the load/unload times are becoming a greater % of overall cycle times in optics production. The project partners include the UK's leading optical systems manufacturer and a spin-out company from the UK's leading Precision Engineering research institute.

This project will devise and verify new automated manufacturing technologies that will enable effective mass production of high-end (high performance) optics. The project will realise new UK-designed and built automated manufacturing technologies appropriate for defence and commerial sector optics. Today, leading companies producing high-end optics employ very precise machines which are manually loaded/unloaded and have separate post-production inspection requiring manual operation. This project will develop and verify new automation methods that are functional for delicate optical workpieces and integrate a new in-situ measurement technique that can improve production rate and yield. The project will advance research outputs of a previous research council funded project (which created a highly novel compact machine concept) and apply to that concept new automation techniques for loading/unloading and in-situ measurement appropriate for both infrared and visible optics. This type of automation has previously not been applied. Today, demand for reduced size optics is common, and production batch sizes are increasing. These two factors raise the importance of automation. Significantly, the load/unload times are becoming a greater % of overall cycle times in optics production. The project partners include the UK's leading optical systems manufacturer and a spin-out company from the UK's leading Precision Engineering research institute.

This project will devise and verify new automated manufacturing technologies that will enable effective mass production of high-end (high performance) optics. The project will realise new UK-designed and built automated manufacturing technologies appropriate for defence and commerial sector optics. Today, leading companies producing high-end optics employ very precise machines which are manually loaded/unloaded and have separate post-production inspection requiring manual operation. This project will develop and verify new automation methods that are functional for delicate optical workpieces and integrate a new in-situ measurement technique that can improve production rate and yield. The project will advance research outputs of a previous research council funded project (which created a highly novel compact machine concept) and apply to that concept new automation techniques for loading/unloading and in-situ measurement appropriate for both infrared and visible optics. This type of automation has previously not been applied. Today, demand for reduced size optics is common, and production batch sizes are increasing. These two factors raise the importance of automation. Significantly, the load/unload times are becoming a greater % of overall cycle times in optics production. The project partners include the UK's leading optical systems manufacturer and a spin-out company from the UK's leading Precision Engineering research institute.

This project will devise and verify new automated manufacturing technologies that will enable effective mass production of high-end (high performance) optics. The project will realise new UK-designed and built automated manufacturing technologies appropriate for defence and commerial sector optics. Today, leading companies producing high-end optics employ very precise machines which are manually loaded/unloaded and have separate post-production inspection requiring manual operation. This project will develop and verify new automation methods that are functional for delicate optical workpieces and integrate a new in-situ measurement technique that can improve production rate and yield. The project will advance research outputs of a previous research council funded project (which created a highly novel compact machine concept) and apply to that concept new automation techniques for loading/unloading and in-situ measurement appropriate for both infrared and visible optics. This type of automation has previously not been applied. Today, demand for reduced size optics is common, and production batch sizes are increasing. These two factors raise the importance of automation. Significantly, the load/unload times are becoming a greater % of overall cycle times in optics production. The project partners include the UK's leading optical systems manufacturer and a spin-out company from the UK's leading Precision Engineering research institute.

This project will devise and verify new automated manufacturing technologies that will enable effective mass production of high-end (high performance) optics. The project will realise new UK-designed and built automated manufacturing technologies appropriate for defence and commerial sector optics. Today, leading companies producing high-end optics employ very precise machines which are manually loaded/unloaded and have separate post-production inspection requiring manual operation. This project will develop and verify new automation methods that are functional for delicate optical workpieces and integrate a new in-situ measurement technique that can improve production rate and yield. The project will advance research outputs of a previous research council funded project (which created a highly novel compact machine concept) and apply to that concept new automation techniques for loading/unloading and in-situ measurement appropriate for both infrared and visible optics. This type of automation has previously not been applied. Today, demand for reduced size optics is common, and production batch sizes are increasing. These two factors raise the importance of automation. Significantly, the load/unload times are becoming a greater % of overall cycle times in optics production. The project partners include the UK's leading optical systems manufacturer and a spin-out company from the UK's leading Precision Engineering research institute.

This project will devise and verify new automated manufacturing technologies that will enable effective mass production of high-end (high performance) optics. The project will realise new UK-designed and built automated manufacturing technologies appropriate for defence and commerial sector optics. Today, leading companies producing high-end optics employ very precise machines which are manually loaded/unloaded and have separate post-production inspection requiring manual operation. This project will develop and verify new automation methods that are functional for delicate optical workpieces and integrate a new in-situ measurement technique that can improve production rate and yield. The project will advance research outputs of a previous research council funded project (which created a highly novel compact machine concept) and apply to that concept new automation techniques for loading/unloading and in-situ measurement appropriate for both infrared and visible optics. This type of automation has previously not been applied. Today, demand for reduced size optics is common, and production batch sizes are increasing. These two factors raise the importance of automation. Significantly, the load/unload times are becoming a greater % of overall cycle times in optics production. The project partners include the UK's leading optical systems manufacturer and a spin-out company from the UK's leading Precision Engineering research institute.

This project will devise and verify new automated manufacturing technologies that will enable effective mass production of high-end (high performance) optics. The project will realise new UK-designed and built automated manufacturing technologies appropriate for defence and commerial sector optics. Today, leading companies producing high-end optics employ very precise machines which are manually loaded/unloaded and have separate post-production inspection requiring manual operation. This project will develop and verify new automation methods that are functional for delicate optical workpieces and integrate a new in-situ measurement technique that can improve production rate and yield. The project will advance research outputs of a previous research council funded project (which created a highly novel compact machine concept) and apply to that concept new automation techniques for loading/unloading and in-situ measurement appropriate for both infrared and visible optics. This type of automation has previously not been applied. Today, demand for reduced size optics is common, and production batch sizes are increasing. These two factors raise the importance of automation. Significantly, the load/unload times are becoming a greater % of overall cycle times in optics production. The project partners include the UK's leading optical systems manufacturer and a spin-out company from the UK's leading Precision Engineering research institute.

This project will devise and verify new automated manufacturing technologies that will enable effective mass production of high-end (high performance) optics. The project will realise new UK-designed and built automated manufacturing technologies appropriate for defence and commerial sector optics. Today, leading companies producing high-end optics employ very precise machines which are manually loaded/unloaded and have separate post-production inspection requiring manual operation. This project will develop and verify new automation methods that are functional for delicate optical workpieces and integrate a new in-situ measurement technique that can improve production rate and yield. The project will advance research outputs of a previous research council funded project (which created a highly novel compact machine concept) and apply to that concept new automation techniques for loading/unloading and in-situ measurement appropriate for both infrared and visible optics. This type of automation has previously not been applied. Today, demand for reduced size optics is common, and production batch sizes are increasing. These two factors raise the importance of automation. Significantly, the load/unload times are becoming a greater % of overall cycle times in optics production. The project partners include the UK's leading optical systems manufacturer and a spin-out company from the UK's leading Precision Engineering research institute.

This project will devise and verify new automated manufacturing technologies that will enable effective mass production of high-end (high performance) optics. The project will realise new UK-designed and built automated manufacturing technologies appropriate for defence and commerial sector optics. Today, leading companies producing high-end optics employ very precise machines which are manually loaded/unloaded and have separate post-production inspection requiring manual operation. This project will develop and verify new automation methods that are functional for delicate optical workpieces and integrate a new in-situ measurement technique that can improve production rate and yield. The project will advance research outputs of a previous research council funded project (which created a highly novel compact machine concept) and apply to that concept new automation techniques for loading/unloading and in-situ measurement appropriate for both infrared and visible optics. This type of automation has previously not been applied. Today, demand for reduced size optics is common, and production batch sizes are increasing. These two factors raise the importance of automation. Significantly, the load/unload times are becoming a greater % of overall cycle times in optics production. The project partners include the UK's leading optical systems manufacturer and a spin-out company from the UK's leading Precision Engineering research institute.

This project will devise and verify new automated manufacturing technologies that will enable effective mass production of high-end (high performance) optics. The project will realise new UK-designed and built automated manufacturing technologies appropriate for defence and commerial sector optics. Today, leading companies producing high-end optics employ very precise machines which are manually loaded/unloaded and have separate post-production inspection requiring manual operation. This project will develop and verify new automation methods that are functional for delicate optical workpieces and integrate a new in-situ measurement technique that can improve production rate and yield. The project will advance research outputs of a previous research council funded project (which created a highly novel compact machine concept) and apply to that concept new automation techniques for loading/unloading and in-situ measurement appropriate for both infrared and visible optics. This type of automation has previously not been applied. Today, demand for reduced size optics is common, and production batch sizes are increasing. These two factors raise the importance of automation. Significantly, the load/unload times are becoming a greater % of overall cycle times in optics production. The project partners include the UK's leading optical systems manufacturer and a spin-out company from the UK's leading Precision Engineering research institute.

This project will devise and verify new automated manufacturing technologies that will enable effective mass production of high-end (high performance) optics. The project will realise new UK-designed and built automated manufacturing technologies appropriate for defence and commerial sector optics. Today, leading companies producing high-end optics employ very precise machines which are manually loaded/unloaded and have separate post-production inspection requiring manual operation. This project will develop and verify new automation methods that are functional for delicate optical workpieces and integrate a new in-situ measurement technique that can improve production rate and yield. The project will advance research outputs of a previous research council funded project (which created a highly novel compact machine concept) and apply to that concept new automation techniques for loading/unloading and in-situ measurement appropriate for both infrared and visible optics. This type of automation has previously not been applied. Today, demand for reduced size optics is common, and production batch sizes are increasing. These two factors raise the importance of automation. Significantly, the load/unload times are becoming a greater % of overall cycle times in optics production. The project partners include the UK's leading optical systems manufacturer and a spin-out company from the UK's leading Precision Engineering research institute.

This project will devise and verify new automated manufacturing technologies that will enable effective mass production of high-end (high performance) optics. The project will realise new UK-designed and built automated manufacturing technologies appropriate for defence and commerial sector optics. Today, leading companies producing high-end optics employ very precise machines which are manually loaded/unloaded and have separate post-production inspection requiring manual operation. This project will develop and verify new automation methods that are functional for delicate optical workpieces and integrate a new in-situ measurement technique that can improve production rate and yield. The project will advance research outputs of a previous research council funded project (which created a highly novel compact machine concept) and apply to that concept new automation techniques for loading/unloading and in-situ measurement appropriate for both infrared and visible optics. This type of automation has previously not been applied. Today, demand for reduced size optics is common, and production batch sizes are increasing. These two factors raise the importance of automation. Significantly, the load/unload times are becoming a greater % of overall cycle times in optics production. The project partners include the UK's leading optical systems manufacturer and a spin-out company from the UK's leading Precision Engineering research institute.

This project will devise and verify new automated manufacturing technologies that will enable effective mass production of high-end (high performance) optics. The project will realise new UK-designed and built automated manufacturing technologies appropriate for defence and commerial sector optics. Today, leading companies producing high-end optics employ very precise machines which are manually loaded/unloaded and have separate post-production inspection requiring manual operation. This project will develop and verify new automation methods that are functional for delicate optical workpieces and integrate a new in-situ measurement technique that can improve production rate and yield. The project will advance research outputs of a previous research council funded project (which created a highly novel compact machine concept) and apply to that concept new automation techniques for loading/unloading and in-situ measurement appropriate for both infrared and visible optics. This type of automation has previously not been applied. Today, demand for reduced size optics is common, and production batch sizes are increasing. These two factors raise the importance of automation. Significantly, the load/unload times are becoming a greater % of overall cycle times in optics production. The project partners include the UK's leading optical systems manufacturer and a spin-out company from the UK's leading Precision Engineering research institute.

This project will devise and verify new automated manufacturing technologies that will enable effective mass production of high-end (high performance) optics. The project will realise new UK-designed and built automated manufacturing technologies appropriate for defence and commerial sector optics. Today, leading companies producing high-end optics employ very precise machines which are manually loaded/unloaded and have separate post-production inspection requiring manual operation. This project will develop and verify new automation methods that are functional for delicate optical workpieces and integrate a new in-situ measurement technique that can improve production rate and yield. The project will advance research outputs of a previous research council funded project (which created a highly novel compact machine concept) and apply to that concept new automation techniques for loading/unloading and in-situ measurement appropriate for both infrared and visible optics. This type of automation has previously not been applied. Today, demand for reduced size optics is common, and production batch sizes are increasing. These two factors raise the importance of automation. Significantly, the load/unload times are becoming a greater % of overall cycle times in optics production. The project partners include the UK's leading optical systems manufacturer and a spin-out company from the UK's leading Precision Engineering research institute.

This project will devise and verify new automated manufacturing technologies that will enable effective mass production of high-end (high performance) optics. The project will realise new UK-designed and built automated manufacturing technologies appropriate for defence and commerial sector optics. Today, leading companies producing high-end optics employ very precise machines which are manually loaded/unloaded and have separate post-production inspection requiring manual operation. This project will develop and verify new automation methods that are functional for delicate optical workpieces and integrate a new in-situ measurement technique that can improve production rate and yield. The project will advance research outputs of a previous research council funded project (which created a highly novel compact machine concept) and apply to that concept new automation techniques for loading/unloading and in-situ measurement appropriate for both infrared and visible optics. This type of automation has previously not been applied. Today, demand for reduced size optics is common, and production batch sizes are increasing. These two factors raise the importance of automation. Significantly, the load/unload times are becoming a greater % of overall cycle times in optics production. The project partners include the UK's leading optical systems manufacturer and a spin-out company from the UK's leading Precision Engineering research institute.