Determining the repair width and CNC grinding of screws of triple-screw pump

Zhao, Yongqiang; Zhao, Shengdun; Hou, Hongling; Li, Jingxiang; Wei, Weifeng

doi:10.1007/s00170-018-1943-8

Cited by 4 publications

(1 citation statement)

References 13 publications

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“…By using the sample bar function of the UG software to create the end face geometry of the pump screw, and then generate the helix lead based on the pitch, the number of helix heads, and the helix lift angle, the end face profile geometry was achieved by sweeping the function to generate the screw entity along the helix lead. Based on the established master and slave screw models with the tooth root circle as the inner boundary and the inner wall surface of the screw bushing as the outer boundary, a screw bushing model was created and then the master and slave screws and screw bushing were subjected to Boolean operations to obtain the internal flow path model of the triple screw pump [21][22][23]. Owing to the complexity of the screw surfaces, a denser mesh was formed around the screw.…”

Section: Calculation Model and Mesh Generationmentioning

confidence: 99%

Characteristics of embedded triple screw pump based on thermal-fluid-structure coupling

Zhu¹,

Zhao²,

Hou³

et al. 2021

J. vibroeng.

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To accommodate special applications where installation space is limited and noise and vibration requirements are high, a new triple screw pump structure was proposed, which was integrated into a servo motor. The design optimizes the profile of the master and slave screws of the embedded triple screw pump. The temperature and pressure fields of the embedded triple screw pump, as well as the heat transfer and pressure distribution between the fluid in the pump and the screw, were investigated through a thermal-fluid-structure approach. The deformation and stresses of the screw were compared for three operating conditions: temperature loading, pressure loading, and thermal-fluid-structure coupling. The results show that the deformation and stresses in the screw tended to increase with increasing pressure and temperature and the pressure load caused more significant deformation and stresses in the screw than the temperature load. The screw deformation caused by pressure loading was found to be the main factor affecting the thermal-fluid-structure coupling. The screw deformation after coupling was smaller than the sum of the screw deformation caused by individual temperature and pressure loads, and the stress values were the same. The results indicate that the coupling action weakens the deformation and stresses in the master and slave screws.

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Section: Calculation Model and Mesh Generationmentioning

confidence: 99%