This comprehensive new manual focuses on highly-forced heat transferthe Intensive Quenching (IQ) processes, with particular attention to the replacement of relatively expensive alloyed steels with less expensive carbon steels. 13 comprehensive chapters examine:
Thermal and metallurgical design basics of high-strength steels
Transient nucleate boiling and self-regulated thermal processes
Critical heat flux densities and characteristics of heat transfer during film boiling
Convective heat transfer
Generalized equations for determination of cooling time for bodies of any shape during quenching
Regular thermal process and Kondratjev form factors
Stress state of steel parts during IQ
Steel quenching in liquid media under pressure
Steel superstrengthening phenomenon
Intensive steel quenching methods
Design of industrial quenching systems
Review of practical applications of IQ methods
Inverse problems in quench process design
With this unique manual, you are can address the following problems:
Calculate cooling time to provide optimal quenched layer after intensive quenching of steel parts
Create beneficial high compressive residual stresses at the surface of steel parts
Use the "steel super-strengthening" phenomenon to make higher power density parts
Develop synergies between the benefits from high compressive residual stresses and super-strengthening phenomenon, which significantly increases the fatigue life (and service life) of steel parts
Improve the environmental conditions in your factory by switching from oil and polymer quenching to intensive quenching by plain water.
Optimization of distortion control in the quenching of steel parts
This unique manual is intended for metallurgists and mechanical engineers to assist them in their work to design quenching systems and to implement those mechanical systems. It is also for student and post graduate students.
Critical Heat Flux Densities and Characteristics of Heat Transfer during Film Boiling
Kobasko N., Aronov M., Powell J.
Convective Heat Transfer
The Steel Superstrengthening Phenomenon
Intensive Steel Quenching Methods
Design of Industrial Quenching Systems
Kobasko N., Totten G.
Review of Practical Applications of Intensive Quenching Methods
Aronov M., Kobasko N., Powell J.
Inverse Problems in Quench Process Design
Kobasko N., Dobryvechir V.
Paper ID: MNL64-EB