Non-Newtonian Temperature and Pressure Effects of a Lubricant Slurry in a Rotating Hydrostatic Step Bearing

The purpose of this research was to investigate the pressure and temperature effects of graphite powder lubricant when added to a Newtonian carrier fluid and applied in a rotating hydrostatic step bearing. Temperature and pressure profiles were determined both analytically and experimentally. The rh...

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Veröffentlicht in:	ASLE Transactions 1994, Vol.37 (4), p.857-863
Hauptverfasser:	Peterson, J., Finn, W. E., Dareing, D. W.
Format:	Artikel
Sprache:	eng
Schlagworte:	BEARINGS ENERGY CONSERVATION, CONSUMPTION, AND UTILIZATION FRICTION Hydrostatic Bearings HYDROSTATICS LUBRICANTS MATHEMATICAL MODELS Non-Newtonian Behavior TEMPERATURE DEPENDENCE
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container_title	ASLE Transactions
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creator	Peterson, J. Finn, W. E. Dareing, D. W.
description	The purpose of this research was to investigate the pressure and temperature effects of graphite powder lubricant when added to a Newtonian carrier fluid and applied in a rotating hydrostatic step bearing. Temperature and pressure profiles were determined both analytically and experimentally. The rheological behavior of the non-Newtonian lubricant was modeled using a power law model previously shown to approximate experimental data for this fluid. Ethylene glycol was used as the Newtonian lubricant, providing a check on the test apparatus and a base line for comparison with the non-Newtonian graphite slurry. Data revealed a temperature increase with bearing rotational speed for both fluids and compared favorably with the mathematical predictions. A significantly higher temperature rise was seen in the non-Newtonian lubricant due to the higher shear rates. The pressure profile was not directly dependent on bearing rotational speed in the mathematical model, but experimental data demonstrated a reduction in pressure at higher rotation speeds. This loss was greater for the non-Newtonian lubricant and attributed to temperature dependence of power law constants. It was concluded that the effects of operating speed and temperature on a non-Newtonian lubricant should be considered as well as their greater load-carrying capacity.
doi_str_mv	10.1080/10402009408983369
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The pressure profile was not directly dependent on bearing rotational speed in the mathematical model, but experimental data demonstrated a reduction in pressure at higher rotation speeds. This loss was greater for the non-Newtonian lubricant and attributed to temperature dependence of power law constants. 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A significantly higher temperature rise was seen in the non-Newtonian lubricant due to the higher shear rates. The pressure profile was not directly dependent on bearing rotational speed in the mathematical model, but experimental data demonstrated a reduction in pressure at higher rotation speeds. This loss was greater for the non-Newtonian lubricant and attributed to temperature dependence of power law constants. It was concluded that the effects of operating speed and temperature on a non-Newtonian lubricant should be considered as well as their greater load-carrying capacity.</description><subject>BEARINGS</subject><subject>ENERGY CONSERVATION, CONSUMPTION, AND UTILIZATION</subject><subject>FRICTION</subject><subject>Hydrostatic Bearings</subject><subject>HYDROSTATICS</subject><subject>LUBRICANTS</subject><subject>MATHEMATICAL MODELS</subject><subject>Non-Newtonian Behavior</subject><subject>TEMPERATURE DEPENDENCE</subject><issn>1040-2004</issn><issn>0569-8197</issn><issn>1547-397X</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>1994</creationdate><recordtype>article</recordtype><recordid>eNp1kclOHDEQhlsRSGx5AG6GQ25NvHbbUi7JiECkEaAAEjfL47aDSY89lN1C8_Zxazglyqm2769F1TSnBF8QLPFngjmmGCuOpZKMdepDc0gE71um-qe96td6WwF-0Bzl_IIxEYSww-b3TYrtjXsrKQYT0YNbbxyYMoFDJg7oDlzOc3DpvbMlo-SRQctpBcGaWND9OAFsUYg1-zMVU0L8ha63A6Q8BxbdF7dB35yBWjhp9r0Zs_v4bo-bx--XD4vrdnl79WPxddlaJnFpO8vliinaM2aEYhYrwrtOSmfoQD0lhmLJeoIFwzVlB6uc7XrGxcrLGWbHzdmub10i6GxDcfbZphjrBZpgooSozKcds4H0Orlc9Dpk68bRRJemrGnHe94TXsHzv8CXNEGs-2tKBRM9VzNEdpCth2dwXm8grA1s6zg9_0f_85-q-bLThOgTrM1bgnHQxWzHBB5MtCFr9n_5H3duk_k</recordid><startdate>1994</startdate><enddate>1994</enddate><creator>Peterson, J.</creator><creator>Finn, W. 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Ethylene glycol was used as the Newtonian lubricant, providing a check on the test apparatus and a base line for comparison with the non-Newtonian graphite slurry. Data revealed a temperature increase with bearing rotational speed for both fluids and compared favorably with the mathematical predictions. A significantly higher temperature rise was seen in the non-Newtonian lubricant due to the higher shear rates. The pressure profile was not directly dependent on bearing rotational speed in the mathematical model, but experimental data demonstrated a reduction in pressure at higher rotation speeds. This loss was greater for the non-Newtonian lubricant and attributed to temperature dependence of power law constants. It was concluded that the effects of operating speed and temperature on a non-Newtonian lubricant should be considered as well as their greater load-carrying capacity.</abstract><cop>Philadelphia</cop><pub>Taylor & Francis Group</pub><doi>10.1080/10402009408983369</doi><tpages>7</tpages></addata></record>
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subjects	BEARINGS ENERGY CONSERVATION, CONSUMPTION, AND UTILIZATION FRICTION Hydrostatic Bearings HYDROSTATICS LUBRICANTS MATHEMATICAL MODELS Non-Newtonian Behavior TEMPERATURE DEPENDENCE
title	Non-Newtonian Temperature and Pressure Effects of a Lubricant Slurry in a Rotating Hydrostatic Step Bearing
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