A Transient Thermal Model for Friction Stir Weld. Part I: The Model

Abstract: Current analytical thermal models for friction stir welding (FSW) are mainly focused on the steady-state condition. To better understand the FSW process, we propose a transient thermal model for FSW, which considers all the periods of FSW. A temperature-dependent apparent friction coefficient solved by the inverse solution method (ISM) is used to estimate the heat generation rate. The physical reasonableness, self-consistency, and relative achievements of this model are discussed, and the relationships between… Show more

“…[16] and [11]. These results can be summarized by the following two chains based on the chain rule I with negative feedback mechanism: [29] x ":…”

“…Other parameters can be found in Part I. [29] III. COMPUTED RESULTS A complete FSW process includes plunge, first dwell, weld, second dwell, and cool periods.…”

“…[26] So the shoulder heat generation and the pin heat generation described in Part I [29] may be rewritten as…”

“…By defining a tool friction factor, [29] while experimental results are reported by Liu and Ma. [12] Fig.…”

“…Part I [29] has built a transient thermal model that considers the entire FSW process. It has been proved to be self-consistent, and its calculated results correspond well with the experimental results reported by Liu and Ma [12] and Sato et al [5] In Part II, the model is used to study the relationship between welding conditions, heat generation, temperature, and friction coefficient.…”

A Transient Thermal Model for Friction Stir Weld. Part II: Effects of Weld Conditions

“…[16] and [11]. These results can be summarized by the following two chains based on the chain rule I with negative feedback mechanism: [29] x ":…”

“…Other parameters can be found in Part I. [29] III. COMPUTED RESULTS A complete FSW process includes plunge, first dwell, weld, second dwell, and cool periods.…”

“…[26] So the shoulder heat generation and the pin heat generation described in Part I [29] may be rewritten as…”

“…By defining a tool friction factor, [29] while experimental results are reported by Liu and Ma. [12] Fig.…”

“…Part I [29] has built a transient thermal model that considers the entire FSW process. It has been proved to be self-consistent, and its calculated results correspond well with the experimental results reported by Liu and Ma [12] and Sato et al [5] In Part II, the model is used to study the relationship between welding conditions, heat generation, temperature, and friction coefficient.…”

A Transient Thermal Model for Friction Stir Weld. Part II: Effects of Weld Conditions

Developing a Finite Element Model for Thermal Analysis of Friction Stir Welding by Calculating Temperature Dependent Friction Coefficient

A study of the temperature field during ultrasonic-assisted friction-stir welding