• DocumentCode
    2508845
  • Title

    Driving energy efficiency with design optimization of a centrifugal fan housing system for variable frequency drives

  • Author

    Morris, Garron K. ; Weiss, Bruce W.

  • Author_Institution
    Rockwell Autom., Mequon, WI, USA
  • fYear
    2012
  • fDate
    May 30 2012-June 1 2012
  • Firstpage
    1312
  • Lastpage
    1319
  • Abstract
    Increasing demands for electrical equipment efficiency has renewed interest in improving the electrical and thermal efficiency of industrial equipment. Variable speed drives are typically air-cooled and fall under recent international standards for improved fan efficiency. This paper details the modeling, design optimization, and experimental verification approaches used to optimize blower housing designs for variable speed drives. The design of the blower housing is just as important as the blower selection. By modifying the housing dimensions, the shape and quantity of flow exiting the housing can be controlled. First, the impeller and inlet ring geometry was directly imported into Icepak from a CAD model provided by the manufacturer. Moving Reference Frame and multi-level meshing techniques were used to provide an accurate representation of the air flow. Next, a flow-pressure curve was created by varying the outlet pressure. The blower performance curve was found to follow, but consistently under-predict the empirical fan curve data given by the manufacturer. Using fan laws and a multi-objective optimization approach, a model fan speed that was 2.4% higher than the operating speed was found to make the predicted and manufacturer performance data agree with less than a 3% error. Next, a parametric model of the blower housing was created in Icepak using the tuned blower model. Four parametric variables included the distance from the impeller to the front, bottom, side, and back of the housing was chosen. A fifth variable, pressure was chosen so that the effect of outlet pressure on flow could be extracted. The blower housing was optimized using a Design of Experiments (DoE) technique where the geometry of housing was varied in a structured manner to capture expected second order behavior. The 27-run DoE was performed in Icepak and the volumetric flow through discretized portions of the outlet were recorded. The DoE data for each section of the outlet were fit to e- uations using a backward regression technique. A genetic algorithm-based optimization technique was used to create housing designs for two different variable frequency drives. Prototypes of the housings were constructed for each design and flow-pressure curves for three samples of each design were measured on a flow bench. The measured curves were found to agree with the predicted blower performance in each housing design to within 7%. Design curves that could be used for other housings were also generated.
  • Keywords
    design of experiments; electronics packaging; energy conservation; fans; genetic algorithms; mesh generation; regression analysis; variable speed drives; CAD model; DoE technique; air flow; backward regression technique; blower housing designs; blower performance curve; blower selection; centrifugal fan housing system; design of experiment technique; design optimization; electrical efficiency; electrical equipment efficiency; empirical fan curve data; energy efficiency; experimental verification approach; flow-pressure curves; genetic algorithm-based optimization technique; impeller; industrial equipment; inlet ring geometry; model fan speed; moving reference frame; multilevel meshing techniques; multiobjective optimization approach; outlet pressure; parametric variables; thermal efficiency; tuned blower model; variable frequency drives; volumetric flow; Atmospheric modeling; Data models; Impellers; Mathematical model; Predictive models; Solid modeling; Variable speed drives; centrifugal fan; design of experiments; fan housing; moving reference frame; optimization;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Thermal and Thermomechanical Phenomena in Electronic Systems (ITherm), 2012 13th IEEE Intersociety Conference on
  • Conference_Location
    San Diego, CA
  • ISSN
    1087-9870
  • Print_ISBN
    978-1-4244-9533-7
  • Electronic_ISBN
    1087-9870
  • Type

    conf

  • DOI
    10.1109/ITHERM.2012.6231572
  • Filename
    6231572