Affiliations: Charles L. Brown Department of Electrical and Computer
Engineering, University of Virginia, Charlottesville, VA 22904-4743, USA | Commissioning & Testing Section, Power Plant
Construction Department, Takasago Machinery Works, Mitsubishi Heavy Industries,
Ltd., 2-1-1 Shinhama Arai-cho Takasago Hyogo, 676-8686, Japan | Department of Mechanical and Aerospace Engineering,
University of Virginia, Charlottesville, VA 22904-4746, USA
Abstract: Rotor vibrations caused by rotor mass unbalance distributions are a
major source of maintenance problems in high-speed rotating machinery.
Minimizing this vibration by balancing under practical constraints is quite
important to industry. This paper considers balancing of two large industrial
rotor systems by constrained least squares and min-max balancing methods. In
current industrial practice, the weighted least squares method has been
utilized to minimize rotor vibrations for many years. One of its disadvantages
is that it cannot guarantee that the maximum value of vibration is below a
specified value. To achieve better balancing performance, the min-max balancing
method utilizing the Second Order Cone Programming (SOCP) with the maximum
correction weight constraint, the maximum residual response constraint as well
as the weight splitting constraint has been utilized for effective balancing.
The min-max balancing method can guarantee a maximum residual vibration value
below an optimum value and is shown by simulation to significantly outperform
the weighted least squares method.
