On the influence of helix angle and face width on gear windage losses

This paper investigates the windage power losses generated by helical gears rotating in pure air based on experimental results and a computational fluid dynamic code. It is found that the simulated flow patterns are totally different from those calculated for spur gears and that both tooth face width and helix angle are influential. The windage losses derived from Dawson’s and Townsend’s formulae are critically assessed using computational fluid dynamic results thus highlighting the limits of a unique formulation for accurate windage loss prediction. Finally, an analytical approach is suggested which gives good results providing that the flow rates at the boundaries of the inter-tooth domains can be estimated.

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Comparison of power losses in intra-atrial and extra-cardiac total cavo-pulmonary connections using computational fluid dynamic techniques

10.17918/etd-2936 ◽

2021 ◽

Author(s):

Ravi S. Doddasomayajula

Keyword(s):

Computational Fluid Dynamic ◽

Fluid Dynamic ◽

Power Losses ◽

Dynamic Techniques

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Effects of Carburized Part, Helix Angle and Face Width on Residual Stresses of Case-Hardened Helical Gears

The Proceedings of the Machine Design and Tribology Division meeting in JSME ◽

10.1299/jsmemdt.2004.4.63 ◽

2004 ◽

Vol 2004.4 (0) ◽

pp. 63-66

Author(s):

Kouitsu MIYACHIKA ◽

Wei-Dong XUE ◽

Takao KOIDE ◽

Satoshi ODA ◽

Hiroshige FUJIO

Keyword(s):

Residual Stresses ◽

Helix Angle ◽

Helical Gears ◽

Face Width

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Analysis of time-varying friction excitations in helical gears with refined general formulation

Proceedings of the Institution of Mechanical Engineers Part C Journal of Mechanical Engineering Science ◽

10.1177/0954406215583886 ◽

2015 ◽

Vol 229 (13) ◽

pp. 2467-2483 ◽

Cited By ~ 2

Author(s):

Hanjun Jiang

Keyword(s):

Friction Force ◽

Contact Line ◽

Sliding Friction ◽

Helix Angle ◽

Universal Method ◽

Time Varying ◽

Contact Ratio ◽

Friction Forces ◽

Helical Gears ◽

Face Width

Time-varying sliding friction force and friction torque are regarded as non-negligible excitation sources of vibration and noise in gears. The sliding friction force primarily excites the motion along the off-line-of-action direction, which transmits vibration to the housing through shafts and bearings and then radiates noise. Since the contact line intersects with the pitch line, and the directions of the friction forces are opposite on both sides of the pitch line, the calculation of the friction excitations in helical gears becomes more difficult, especially in the high contact ratio helical gears. However, there is no universal method for calculating the friction excitations in helical gears with different range of contact ratio. The changes of friction excitations in helical gears are highly dependent on the geometric parameters such as helix angle and face width among others. Yet, there exist very limited studies on these topics. In this study, a refined general formulation for the calculation of time-varying contact line and friction excitations is proposed by assuming uniform load distribution along the contact lines with time-varying normal force and friction coefficient. Key gear parameters such as modification coefficient, helix angle, and face width are analyzed to illustrate their effects on the time-varying contact line and friction excitations. The results demonstrate that the refined general formulation is effective for the calculation of the friction excitations in helical gears with different range of contact ratio, and the parametric analysis could supply some guidance for choosing gear parameters in the design of helical gears to reduce the friction excitations.

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Application of Computational Fluid Dynamic for Hydraulic Design

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.121-126.578 ◽

2011 ◽

Vol 121-126 ◽

pp. 578-582

Author(s):

Li Ying Wang ◽

De Hua Wei

Keyword(s):

New Product Development ◽

Computational Fluid Dynamic ◽

Design Method ◽

Fluid Dynamic ◽

New Product ◽

Actual Condition ◽

Hydraulic Machinery ◽

Traditional Design ◽

Hydraulic Design ◽

Simulated Flow

This paper studies the modern design methods of hydraulic machinery by the use of Computational Fluid Dynamic (CFD), the design method not only makes up the shortcomings of the traditional design method, but also can be compared on the computer which can save a lot of trial and testing costs in new product development. Form the velocity distribution and pressure distribution of turbine, the example shows, the simulated flow field using CFD software is in agreement with the actual condition and it basically meets the requirements of design.

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Influence of Profile Modification and Lubricant Viscosity on Scoring of Helical Gears

Journal of Engineering for Industry ◽

10.1115/1.3438332 ◽

1974 ◽

Vol 96 (1) ◽

pp. 71-77

Author(s):

T. Matsunaga

Keyword(s):

Testing Machine ◽

Normal Pressure ◽

Helix Angle ◽

Power Circuit ◽

Helical Gears ◽

Profile Modification ◽

Face Width ◽

Carburized Steel ◽

Load Carrying ◽

Lubricant Viscosity

Scoring limit of helical gears made of carburized steel is investigated experimentally. Gear testing machine used for the tests is a closed power circuit type and designed for operation up to 23,000 rpm. All tests are made with pairs of 14 and 141-tooth gears of 3-module, 20-deg normal pressure angle, 29.066-deg helix angle, and 30-mm face width. The effect of profile modification on the scoring limit is investigated, and the effects of lubricant viscosity and location of oil supply nozzle are investigated in connection with the effect of profile modification. Three kinds of lubricants of various viscosity ordinarily used in a gear system are tested (lubricant viscosity: 32, 53, 70 cSt at 40 C). Load carrying capacity of the lubricant of the highest viscosity is higher by 25 percent than that of the lowest one. But the effect of modification is much larger than that of lubricant viscosity.

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Efficiency of Nonstandard and High Contact Ratio Involute Spur Gears

Journal of Mechanisms Transmissions and Automation in Design ◽

10.1115/1.3260774 ◽

1986 ◽

Vol 108 (1) ◽

pp. 119-126 ◽

Cited By ~ 20

Author(s):

N. E. Anderson ◽

S. H. Loewenthal

Keyword(s):

Prediction Method ◽

Spur Gears ◽

Contact Ratio ◽

Oil Viscosity ◽

Proper Selection ◽

Face Width ◽

Loss Prediction ◽

Gear Geometry ◽

Center Distance ◽

Selection Of

A power loss prediction method previously developed by the authors was extended to include involute spur gears of nonstandard proportions. The method can now be used to analyze the effects of modified addendum, tooth thickness, and gear center distance in addition to the parameters previously considered which included gear diameter, pitch, pressure angle, face width, oil viscosity, speed, and torque. Particular emphasis is placed on high contact ratio gearing (contact ratios greater than two). Despite their higher sliding velocities, high contact ratio gears can be designed to levels of efficiency approaching those of conventional gears while retaining their advantages through proper selection of gear geometry.

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