Summary
Driven by the end-users requirements and needs, the main objective of the HIPERDIAS project is to demonstrate high
throughput laser-based manufacturing using high-power, high-repetition rate sub-1ps laser. Although the laser system to be
developed within HIPERDIAS can address other material processing applications, the focus here will be 3D structuring of
silicon at high-speed, precision processing of diamond material and fine cutting of metal for the watch and the medical
industry. Chirped Pulse Amplification (CPA) approach based on highly efficient compressors gratings will be implemented in
order to minimize the overall losses of the laser system. The final targets of the project are to demonstrate:
- a 10-times increase of ablation rate and productivity of large area 3D-structuring of silicon
- a 10 times increase of speed in fine cutting metals
- an increase of process speed (6-10 times) at a low processing tools cost of diamond machining
Therefore, the laser parameters, as well as the beam shaping, beam guiding (based on Kagomé fibers) and machine
systems will be developed and optimized to fulfill the above manufacturing targets. The laser architecture will be based on
fully passive amplifier stages combining hybrid (fiber-bulk) amplifier and thin-disk multipass amplifiers to achieve sub-500fs
at an average output power of 500W and sub-1ps at an average output of 1kW, at a repetition rate of 1-2 MHz. Furthermore,
second harmonic generation (SHG, 515 nm) and third harmonic generation (THG, 343 nm) will be implemented to allow
processing investigation at these wavelengths. At 515 nm (respectively 343 nm) an average power of >=250W (respectively
>=100W) shall be demonstrated.
throughput laser-based manufacturing using high-power, high-repetition rate sub-1ps laser. Although the laser system to be
developed within HIPERDIAS can address other material processing applications, the focus here will be 3D structuring of
silicon at high-speed, precision processing of diamond material and fine cutting of metal for the watch and the medical
industry. Chirped Pulse Amplification (CPA) approach based on highly efficient compressors gratings will be implemented in
order to minimize the overall losses of the laser system. The final targets of the project are to demonstrate:
- a 10-times increase of ablation rate and productivity of large area 3D-structuring of silicon
- a 10 times increase of speed in fine cutting metals
- an increase of process speed (6-10 times) at a low processing tools cost of diamond machining
Therefore, the laser parameters, as well as the beam shaping, beam guiding (based on Kagomé fibers) and machine
systems will be developed and optimized to fulfill the above manufacturing targets. The laser architecture will be based on
fully passive amplifier stages combining hybrid (fiber-bulk) amplifier and thin-disk multipass amplifiers to achieve sub-500fs
at an average output power of 500W and sub-1ps at an average output of 1kW, at a repetition rate of 1-2 MHz. Furthermore,
second harmonic generation (SHG, 515 nm) and third harmonic generation (THG, 343 nm) will be implemented to allow
processing investigation at these wavelengths. At 515 nm (respectively 343 nm) an average power of >=250W (respectively
>=100W) shall be demonstrated.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/687880 |
| Start date: | 01-02-2016 |
| End date: | 31-10-2019 |
| Total budget - Public funding: | 4 440 640,00 Euro - 3 640 307,00 Euro |
Cordis data
Original description
Driven by the end-users requirements and needs, the main objective of the HIPERDIAS project is to demonstrate highthroughput laser-based manufacturing using high-power, high-repetition rate sub-1ps laser. Although the laser system to be
developed within HIPERDIAS can address other material processing applications, the focus here will be 3D structuring of
silicon at high-speed, precision processing of diamond material and fine cutting of metal for the watch and the medical
industry. Chirped Pulse Amplification (CPA) approach based on highly efficient compressors gratings will be implemented in
order to minimize the overall losses of the laser system. The final targets of the project are to demonstrate:
- a 10-times increase of ablation rate and productivity of large area 3D-structuring of silicon
- a 10 times increase of speed in fine cutting metals
- an increase of process speed (6-10 times) at a low processing tools cost of diamond machining
Therefore, the laser parameters, as well as the beam shaping, beam guiding (based on Kagomé fibers) and machine
systems will be developed and optimized to fulfill the above manufacturing targets. The laser architecture will be based on
fully passive amplifier stages combining hybrid (fiber-bulk) amplifier and thin-disk multipass amplifiers to achieve sub-500fs
at an average output power of 500W and sub-1ps at an average output of 1kW, at a repetition rate of 1-2 MHz. Furthermore,
second harmonic generation (SHG, 515 nm) and third harmonic generation (THG, 343 nm) will be implemented to allow
processing investigation at these wavelengths. At 515 nm (respectively 343 nm) an average power of >=250W (respectively
>=100W) shall be demonstrated.
Status
CLOSEDCall topic
ICT-27-2015Update Date
27-10-2022
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Organisations
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| UNIVERSITAET STUTTGART (Coördinator)
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| Amplitude Systemes SA
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| CENTRE NATIONAL DE LA RECHERCHE SCIENTIFIQUE (CNRS)
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| CLASS 4 LASER PROFESSIONALS AG
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| ELEMENT SIX LIMITED
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| ELEMENT SIX LIMITED
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| GESELLSCHAFT FUR ANGEWANDTE MIKRO UND OPTOELEKTRONIK MIT BESCHRANKTERHAFTUNG AMO GMBH
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| GLOPHOTONICS
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| Kite Innovation (Europe) Limited
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| LASER ENGINEERING APPLICATIONS SA
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| MODUS RESEARCH AND INNOVATION LIMITED
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| ROBERT BOSCH GMBH
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| UNIVERSITE DE LIMOGES