To reduce the slope of the riverbed, prevent erosion in both longitudinal and transverse directions, control the flow, stabilize the slopes on both sides, and prevent the outflow of soil and debris, the groundsill has become a widely adopted engineering method both domestically and internationally. When dealing with larger conservation areas, series of river training works are commonly employed. However, the sediment transport in rivers is a dynamic process, and the implementation of series groundsills can cause discontinuities in the longitudinal corridor of the river, leading to damage to the ecological environment and landscape. The presence of groundsills, the number of works, and their spacing have become a focal point of attention in the fields of engineering and ecology. Although there is considerable consensus on various aspects of series of groundsills, current research primarily focuses on the influence of the configuration of groundsills (such as height and width) on sediment downstream. Additionally, due to the limited duration of implemented cases, there is insufficient data available to establish management and operational rules. Therefore, this project aims to estimate the trends in sediment transport through scaled physical model experiments and two-dimensional numerical simulations. Based on this, reasonable configurations of series of groundsills will be calculated, aiming to achieve proper placement of the number of groundsills and improve the ecological environment. More importantly, the proposed configuration schemes for series of groundsills are intended to ensure clear benefits to upstream and downstream water conservation facilities and ensure the safety of downstream conservation objectives by regulating sediment transport through river training works.