High Throughput Laser Array Based Additive Manufacturing
Lead Research Organisation:
University of Cambridge
Department Name: Engineering
Abstract
The early prospects of Additive Manufacturing (AM) technologies promised to provide greater design freedoms, raise productivity levels, minimise material usage, compress supply chains, and enable the producer to attain greater levels of competitiveness by delivering enhanced product capabilities. Metal based LPBF AM systems have developed steadily over the past 20 years and now represent a multibillion-pound global market in machines, materials, and software. They find niche low volume applications in many industrial sectors and somewhat wider applications in aerospace and biomedical sectors.
However LPBF AM processes are still slow compared to traditional manufacturing routes and are quite complex. They require precise focusing and manipulation of high energy laser beams over large powder beds in order to consolidate metal powder into a 3-dimensional solid through laser melting. Melting strategies play a significant role in part quality. Single laser beam melting strategies employed in all commercial systems suffer from melt instabilities, low melting efficiencies, and complex scanning strategies to reach high densities. They require a high level of labour-intensive part-specific build parameter refinement and time-consuming post processing operations. Despite the clear attractiveness of this production route, there remain several challenges in terms of build rates, process stability, part accuracy, repeatability, and part cost.
In this project we propose to investigate several technology solutions that address these fundamental problems. To improve build rate we will establish a new class of LPBF AM capability by re-configuring the laser powder interaction process away from the current single laser interaction to large scale laser arrays. This approach offers increased melting efficiencies and true power scalability in the multi-kW domain. Since laser arrays are readily scalable, a 20kW system could deliver build rates of 153 kg in 24 hours. This is some 20 times faster than current systems. Our approach could offer world leading performance figures for LPBF AM systems. The use of laser arrays enables the problematic keyholing regime to be replaced with conduction limited regime leading to dramatic increases in process stability and part densities routinely reaching 99.99%. More stable melting regimes with reduced thermal gradients and reduce residual stress, reduce part distortion, and ultimately increase part accuracy. In process metrology will be applied to detect errors in the build layers and enable corrective steps thereby increasing process repeatability and deliver a right-first-time production process. With the combined innovations cited above we estimate that part costs savings up to 80% could be achieved compared to conventional LPBF AM systems.
However LPBF AM processes are still slow compared to traditional manufacturing routes and are quite complex. They require precise focusing and manipulation of high energy laser beams over large powder beds in order to consolidate metal powder into a 3-dimensional solid through laser melting. Melting strategies play a significant role in part quality. Single laser beam melting strategies employed in all commercial systems suffer from melt instabilities, low melting efficiencies, and complex scanning strategies to reach high densities. They require a high level of labour-intensive part-specific build parameter refinement and time-consuming post processing operations. Despite the clear attractiveness of this production route, there remain several challenges in terms of build rates, process stability, part accuracy, repeatability, and part cost.
In this project we propose to investigate several technology solutions that address these fundamental problems. To improve build rate we will establish a new class of LPBF AM capability by re-configuring the laser powder interaction process away from the current single laser interaction to large scale laser arrays. This approach offers increased melting efficiencies and true power scalability in the multi-kW domain. Since laser arrays are readily scalable, a 20kW system could deliver build rates of 153 kg in 24 hours. This is some 20 times faster than current systems. Our approach could offer world leading performance figures for LPBF AM systems. The use of laser arrays enables the problematic keyholing regime to be replaced with conduction limited regime leading to dramatic increases in process stability and part densities routinely reaching 99.99%. More stable melting regimes with reduced thermal gradients and reduce residual stress, reduce part distortion, and ultimately increase part accuracy. In process metrology will be applied to detect errors in the build layers and enable corrective steps thereby increasing process repeatability and deliver a right-first-time production process. With the combined innovations cited above we estimate that part costs savings up to 80% could be achieved compared to conventional LPBF AM systems.
Organisations
- University of Cambridge (Lead Research Organisation)
- Renishaw (United Kingdom) (Collaboration, Project Partner)
- Manufacturing Technology Centre (MTC) (Collaboration)
- Boeing (Collaboration)
- Intelligens (Collaboration)
- BAE Systems (United Kingdom) (Collaboration, Project Partner)
- CamAdd (Project Partner)
- Ford Motor Company (United Kingdom) (Project Partner)
- Taraz Metrology (Project Partner)
- Intellegens (Project Partner)
- Manufacturing Technology Centre (United Kingdom) (Project Partner)
- Boeing (United States) (Project Partner)
Publications
Kuroiwa K
(2024)
Every Quantum Helps: Operational Advantage of Quantum Resources beyond Convexity
in Physical Review Letters
Lami L
(2023)
Fundamental limitations to key distillation from Gaussian states with Gaussian operations
in Physical Review Research
Description | Hight Throughput Laser Arrays |
Organisation | BAE Systems |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Provision of AM Array Data |
Collaborator Contribution | Assessment of AM array capability |
Impact | Conference paper |
Start Year | 2023 |
Description | Hight Throughput Laser Arrays |
Organisation | Boeing |
Country | United States |
Sector | Private |
PI Contribution | Provision of AM Array data and performance |
Collaborator Contribution | Provsion of machines and systems |
Impact | AM data outputs |
Start Year | 2023 |
Description | Hight Throughput Laser Arrays |
Organisation | Intelligens |
Country | United Kingdom |
Sector | Private |
PI Contribution | provison of AM array data |
Collaborator Contribution | Software and analysis tools |
Impact | NA |
Start Year | 2023 |
Description | Hight Throughput Laser Arrays |
Organisation | Manufacturing Technology Centre (MTC) |
Country | United Kingdom |
Sector | Private |
PI Contribution | Provision of AM array data |
Collaborator Contribution | Provision of AM expertise |
Impact | Assessment of AM array data |
Start Year | 2023 |
Description | Hight Throughput Laser Arrays |
Organisation | Renishaw PLC |
Country | United Kingdom |
Sector | Private |
PI Contribution | We have provided information on our AM research capabilities |
Collaborator Contribution | Information to test our results against commerciall capabilities |
Impact | Data on AM array capabilities |
Start Year | 2023 |