The emergence rate and vitality of maize are directly affected by the sowing depth, and the uniformity of this depth is an important performance indicator of a planter, while the effective soil surface height information acquisition is the prerequisite for ensuring the accuracy of sowing depth control. The soil surface height variation acquisition system of a precision corn planter often produces profiling errors when performing active profiling due to interference from ground debris. In this study, a multipoint soil surface height variation information acquisition system was investigated, which consists of a ranging sensor group and a microcontroller unit (MCU) using a data comparison and screening method. The structure and specifications of the ranging sensors were determined according to the soil surface height variation and debris size, and a nonessential profiling control program was developed. Performed tests on the information acquisition system indicated that the measurement accuracy of the system was 3 mm, and when advancing at a speed of 8 km/h, the accuracy of the profiling decision and the system stability were 97.1% and 94.1%, respectively, indicating that the system was capable of nonessential profile control. The designed ranging system could provide a reference for the design of a ground information acquisition system of precision planters with an active profiling mechanism.
Keywords: corn, precision planter, information acquisition system, seeding unit, profiling mechanism, active profiling, soil surface height variation
DOI: 10.25165/j.ijabe.20181106.4037

Citation: Zhang B, Zhang W, Qi L Q, Fu H B, Yu L J, Li R, et al. Information acquisition system of multipoint soil surface height variation for profiling mechanism of seeding unit of precision corn planter. Int J Agric & Biol Eng, 2018; 11(6): 58–64.

corn, precision planter, information acquisition system, seeding unit, profiling mechanism, active profiling, soil surface height variation

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