The purpose of this paper is to investigate the possibility of manufacturing a digital hydraulic valve system using additive manufacturing (AM) and to identify the challenges and benefits of doing so. In this study, an existing hydraulic valve manifold, operating at pressures up to 25 MPa, was redesigned for selective laser melting (SLM) and further optimized with computational fluid dynamics. Certain dimensioning challenges were encountered because laser melting is not yet accurate enough for some features but these challenges were circumvented. The manifold was successfully manufactured from tool steel and tested for maximum operating pressure and flow capacity. Due to the improved flow channels, the selective laser melted manifold provided up to 44% reduction in the energy losses caused by flow resistance. This paper demonstrates that SLM can be used to improve the performance of hydraulic valves and that the cost of SLM manifolds is feasible for high-end valve assemblies.
and Hydraulic engineering (aut), tampere university of technology (tut), tampere, finland; b department of engineering design and Production, aalto university, espoo, finland
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