- author = "Zewen Gu",
- title = "Static and Dynamic Analysis of Nonlinear Valve Springs Based on Finite Element Analysis and Machine Learning Algorithm",
- school = "Engineering Department, Lancaster University",
- year = "2022",
- address = "UK",
- keywords = "genetic algorithms, genetic programming",
-
URL = "
https://eprints.lancs.ac.uk/id/eprint/164746/1/2022zewenphd.pdf",
-
URL = "
https://www.proquest.com/openview/a617ff64b19c588f765378db1149dc2e/1",
-
DOI = "
doi:10.17635/lancaster/thesis/1531",
- size = "201 pages",
-
abstract = "The valve spring is a fundamental type of helical
spring which is essential for enabling the opening and
closure of a valve in a car engine. Nowadays, it is
increasingly common to use valve springs of nonlinear
geometry in high-speed car engines for better dynamic
performance. However, practical issues such as
malfunction and pre-failure are also raised by spring
researchers and manufacturers using and analysing these
nonlinear springs. It is commonly stated that existing
spring models and empirical formula do not allow for
the analysis of these nonlinear springs. To tackle such
difficulties, it is imperative that all the varied
geometric parameters of a nonlinear spring be clarified
in order to facilitate efficient and generalisable
analysis. Past research efforts have mainly emphasized
the analysis of standard valve springs of constant
geometric parameters and the development of spring
models for low-speed static conditions. However, these
models do not take into account the full breadth of
conditions and consequently are considered to be
insufficient and compromised in accuracy. Therefore, it
remains a challenge to effectively leverage such models
in the analysis and design of nonlinear valve
springs.
This thesis aims to address the existing gaps and present a comprehensive study on the analysis of nonlinear valve springs and their dynamic response in high-speed engines. An advanced spring formula is developed based on simplified curved beam theory to formulate the relationships between the nonlinear spring geometry (varied coil diameter, varied pitch and coil clash) and the mechanical properties of a beehive valve spring. These nonlinear considerations deliver a higher predictive accuracy than the existing spring formulas by comparing FE and experimental results. The new spring formula is coupled with the distributed parameter model to simulate the dynamic spring IV responses. However, whilst it accurately simulates the dynamic responses at lower engine speeds (lower 5000-rpm), it fails to simulate the significant abnormal spring forces at high engine speeds (over 8000-rpm). On the contrary, the FE springs model is developed, of which static and dynamic simulation results fit well with the experimental data at both low and high engine speeds. More importantly, analysis of the dynamic FE results explains how the violent coil clash leads to significant abnormal spring forces. In the last part, a machine learning model, based on genetic programming techniques and the FE results, is developed to aid the design of nonlinear helical springs. The model enables researchers to analyse nonlinear helical spring properties directly using information extracted from FE results data, bypassing the necessity to unravel the complex inner relationships between the nonlinear spring parameters.",
-
notes = "Also known as
\cite{7c3452eedfb94c959d8d2f253d279768}
supervisor: Jianqiao Ye",
