Influence of Complex Fluid Flow on Temperature Distribution in the Rotor Region of Large Hydrogenerator Under the Rotor Rotation

Ventilation cooling design is one of the key technologies during the design of large hydrogenerator. With the increase of hydrogenerator capacity, the overheating problem of rotor region become more and more serious. In this paper, a 250 MW hydrogenerator is analyzed. The transient electromagnetic f...

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Bibliographic Details
Published inIEEE access Vol. 10; pp. 3252 - 3262
Main Authors Jichao, Han, Yutian, Sun, Ping, Zheng, Haiming, Qi, Jiechen, Dong, Yufei, Liu, Chunli, Zhang, Baojun, Ge, Weili, Li
Format Journal Article
LanguageEnglish
Published Piscataway IEEE 2022
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Damping
Design optimization
different directions
electromagnetic field
Electromagnetic fields
End rings
Excitation
Finite volume method
Flow velocity
Fluid dynamics
Fluid flow
fluid velocity
Fluids
Heat sources
Heat transfer coefficients
Hydrogenerator
Magnetic flux
Magnetomechanical effects
Mathematical models
Overheating
Rotation
rotor rotation
Rotors
Structural design
Temperature distribution
Transient electromagnetic fields
Winding
Windings
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Summary:Ventilation cooling design is one of the key technologies during the design of large hydrogenerator. With the increase of hydrogenerator capacity, the overheating problem of rotor region become more and more serious. In this paper, a 250 MW hydrogenerator is analyzed. The transient electromagnetic field of the hydrogenerator is calculated. The losses (heat sources) of rotor components in the rotor region of the hydrogenerator are determined. Three-dimensional fluid and thermal coupled mathematic model of the hydrogenerator rotor region is established. The rotor rotation of the hydrogenerator is considered. The distribution of complex fluid velocity in the rotor region is calculated using the finite volume method. The influence of fluid velocity in the different directions on the temperature of the rotor excitation winding is studied under the different flow rates in the rotor region. The surface heat-transfer coefficient distribution of the rotor components is determined. The temperature distribution of the rotor excitation winding, rotor pole body, rotor press plate, rotor damping bar, and rotor end ring is obtained. The calculated temperature results match well with test values. These provide an important reference for the rotor structural design and optimization of larger hydrogenerator.
ISSN:2169-3536
2169-3536
DOI:10.1109/ACCESS.2021.3132280