关键词: 方向盘；怠速；振动控制；模态分析；频率响应；振动控制

Abstract: To address the excessive steering wheel vibration of a specific forklift during idle conditions, simulation and experimental analyses reveal that the proximity of the system's modal frequency to the engine's second-order ignition frequency is the primary cause of the intensified vibration. Based on the "source-path-receiver" theory and employing frequency response analysis, this study proposes an optimization scheme involving the installation of a dynamic vibration absorber on the steering column. The effectiveness of the scheme is verified through simulation, and real-vehicle test results demonstrate a 30.5% reduction in overall steering wheel vibration after optimization, effectively resolving the idle vibration issue. This research indicates that the comprehensive vibration reduction approach, which integrates modal identification with dynamic vibration absorber design, provides an effective technical pathway for the noise, vibration, and harshness (NVH) optimization of forklift-type engineering vehicles.

Key words: steering wheel; idle speed; vibration control; modal analysis; frequency response; dynamic vibration absorber