Abstract
The mining of polymetallic nodules from the seafloor at depths down to 6000m requires the excavation of nodules with a seafloor mining tool, the transport of nodules as a slurry through a jumper hose connecting the mining tool to a vertical hydraulic transport system and the transport of the nodules through the vertical lifting pipe. We focus on a concept with conventional hydraulic transport, using a series of centrifugal pump booster stations. The nodules will be transported in different flow regimes, ranging from a sliding bed (in the jumper hose) to a homogeneous suspension (vertical flow). Each regime gives rise to degradation of the nodules in a different way. It is important to understand the degradation mechanisms in detail in order to predict the particle size distribution of the slurry leaving the riser. This particle size distribution is a key design parameter for design of processing equipment and for environmental impact assessment. In this article we present the results of experimental work on abrasive wear (particle-wall interaction) and attrition (particle-particle interaction) of polymetallic nodules from the Clarion Clipperton Zone and we discuss its applicability to engineering practice.
Highlights
The mining of polymetallic nodules from the seafloor at depths down to about 6000 m requires the excavation of nodules with a seafloor mining tool (SMT), the transport of nodules as a slurry through a jumper hose connecting the mining tool to the vertical hydraulic transport system (VTS) and the transport of the nodules through the riser
In this article we present the results of experimental work on abrasive wear and attrition of polymetallic nodules from the Clarion Clipperton Zone and we discuss its applicability to engineering practice
We focus on a concept with conventional hydraulic transport, using a series of centrifugal pump booster stations, see Fig. 1
Summary
The mining of polymetallic nodules from the seafloor at depths down to about 6000 m requires the excavation of nodules with a seafloor mining tool (SMT), the transport of nodules as a slurry through a jumper hose connecting the mining tool to the vertical hydraulic transport system (VTS) and the transport of the nodules through the riser. We focus on a concept with conventional hydraulic transport, using a series of centrifugal pump booster stations, see Fig. 1. In this concept pre-sizing of the nodules is not necessary and any size reduction could be attributed to degradation induced by interaction with pumps, pipelines and other nodules. This work aims to provide an experimental methodology of which the results can be used for engineering purposes. This is achieved by investigating the extremes of degradation encountered in various parts of the transport system, to create a bandwidth of possible degradation rates and a conservative estimate of nodule degradation under operational conditions
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