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| Viscosity of engine oils is a critical property that relates to the fuel economy and durability of an engine. The drivers behind lowering HTHS viscosity are new global governmental regulations to improve fuel economy (FE) and lower greenhouse gases (GHG) in new vehicles. Lower HTHS viscosity tends to improve FE and lower GHG and higher HTHS viscosity affords better wear protection. Sufficient HTHS viscosity is critical in preventing engine wear in the critical ring/liner interface area by maintaining a protective oil film between moving parts. HTHS viscosity by ASTM D4683 has been found to relate to the viscosity providing hydrodynamic lubrication in light duty and heavy duty engines. HTHS viscosity has also been found to relate to fuel economy. Think of the protective oil film as if you are trying to swim. If the film is too thick like molasses you can barely move and have to expend a lot of energy; too thin and you sink to the bottom. What you want is the right balance of support and ease of movement. The oil has to be thick enough to maintain separation of the critical moving parts but thin enough to allow for fuel efficient operation. ((http://hddeo.com/hthsarticle.html)) | Viscosity of engine oils is a critical property that relates to the fuel economy and durability of an engine. The drivers behind lowering HTHS viscosity are new global governmental regulations to improve fuel economy (FE) and lower greenhouse gases (GHG) in new vehicles. Lower HTHS viscosity tends to improve FE and lower GHG and higher HTHS viscosity affords better wear protection. Sufficient HTHS viscosity is critical in preventing engine wear in the critical ring/liner interface area by maintaining a protective oil film between moving parts. HTHS viscosity by ASTM D4683 has been found to relate to the viscosity providing hydrodynamic lubrication in light duty and heavy duty engines. HTHS viscosity has also been found to relate to fuel economy. Think of the protective oil film as if you are trying to swim. If the film is too thick like molasses you can barely move and have to expend a lot of energy; too thin and you sink to the bottom. What you want is the right balance of support and ease of movement. The oil has to be thick enough to maintain separation of the critical moving parts but thin enough to allow for fuel efficient operation. ((http://hddeo.com/hthsarticle.html)) | ||
| ===== Viscosity Index (VI) ===== | ===== Viscosity Index (VI) ===== | ||
| + | The relationship between a fluid’s viscosity and temperature. Fluids with a higher viscosity index change their viscosity to a lesser degree due to the change of temperature.((http://www.oilspecifications.org/articles/lubrication-glossary.php)) | ||
| The viscosity index was developed by E. Dean and G. Davis in 1929. It is an empirically derived, unitless number. Based on the methodology, Pennsylvania crude (paraffinic) was set as a benchmark at one extreme, representing low viscosity changeability relative to temperature. At the other extreme was Texas Gulf crudes (naphthenic). If a lubricant was similar to the Pennsylvania crude, it was assigned a VI of 100. If it was similar to Texas Gulf crude, it was assigned a VI of 0. Halfway in between was a VI of 50, and so forth. The higher the VI, the more stable the viscosity across a range of temperatures (more desirable). The temperatures used to determine the VI are 40 degrees C to 100 degrees C. ((http://www.machinerylubrication.com/Read/28956/lubricant-viscosity-index)) | The viscosity index was developed by E. Dean and G. Davis in 1929. It is an empirically derived, unitless number. Based on the methodology, Pennsylvania crude (paraffinic) was set as a benchmark at one extreme, representing low viscosity changeability relative to temperature. At the other extreme was Texas Gulf crudes (naphthenic). If a lubricant was similar to the Pennsylvania crude, it was assigned a VI of 100. If it was similar to Texas Gulf crude, it was assigned a VI of 0. Halfway in between was a VI of 50, and so forth. The higher the VI, the more stable the viscosity across a range of temperatures (more desirable). The temperatures used to determine the VI are 40 degrees C to 100 degrees C. ((http://www.machinerylubrication.com/Read/28956/lubricant-viscosity-index)) | ||
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| ===== Viscosity Kinematic Values ===== | ===== Viscosity Kinematic Values ===== | ||
| Kinematic viscosity is a measure of the resistive flow of a fluid under the influence of gravity. This measurement is generally displayed in most oil manufacturers respective TDS and/or SDS information data. When two fluids of equal volume are placed in identical capillary viscometers and allowed to flow under the influence of gravity, a viscous fluid takes longer than a less viscous fluid to flow through the tube. ((http://physics.info/viscosity/)) | Kinematic viscosity is a measure of the resistive flow of a fluid under the influence of gravity. This measurement is generally displayed in most oil manufacturers respective TDS and/or SDS information data. When two fluids of equal volume are placed in identical capillary viscometers and allowed to flow under the influence of gravity, a viscous fluid takes longer than a less viscous fluid to flow through the tube. ((http://physics.info/viscosity/)) | ||
| The most common unit of measure for kinematic viscosity is the square millimeter per second [mm2/s] or the centistokes [cSt]. One square meter per second is equal to one million centistokes. 1 mm2/s = 1 cSt ((http://physics.info/viscosity/))The standard evaluating temperature set for comparison is 40°C (104°F) and 100°C (212°F); example (<wrap hi>Viscosity at 40°C</wrap> ASTM D445 <wrap hi>18.1 mm²/s</wrap>)Therefore, viscosity cSt @ 40°C is 18.1 mm²/s. | The most common unit of measure for kinematic viscosity is the square millimeter per second [mm2/s] or the centistokes [cSt]. One square meter per second is equal to one million centistokes. 1 mm2/s = 1 cSt ((http://physics.info/viscosity/))The standard evaluating temperature set for comparison is 40°C (104°F) and 100°C (212°F); example (<wrap hi>Viscosity at 40°C</wrap> ASTM D445 <wrap hi>18.1 mm²/s</wrap>)Therefore, viscosity cSt @ 40°C is 18.1 mm²/s. | ||
| + | ===== Viscosity Modifier ===== | ||
| + | Lubricant additive, usually a polymer that provides beneficial rheological properties to lubricating oils, such as reducing the tendency of an oil’s viscosity to change with temperature.((http://www.oilspecifications.org/articles/lubrication-glossary.php)) | ||
| ===== Viscosity SUS ===== | ===== Viscosity SUS ===== | ||
| (Saybolt Universal Seconds) are the number of seconds it takes for a fixed amount of hydraulic fluid to move through a standard-sized orifice at a fixed temperature. ((http://www.answers.com/Q/What_is_sus_viscosity))Rule of thumb conversion: SUS @ 100ºF / 5 = cSt @ 40ºC. ((http://lib.store.yahoo.net/lib/kingpumps/Viscosity-Comparison-Classification.pdf)) | (Saybolt Universal Seconds) are the number of seconds it takes for a fixed amount of hydraulic fluid to move through a standard-sized orifice at a fixed temperature. ((http://www.answers.com/Q/What_is_sus_viscosity))Rule of thumb conversion: SUS @ 100ºF / 5 = cSt @ 40ºC. ((http://lib.store.yahoo.net/lib/kingpumps/Viscosity-Comparison-Classification.pdf)) | ||
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| Vacuum Operated Electric Switch. Senses intake manifold vacuum from the carburetor and switches to one of two different spark advance curves. ((1959-1985 Clymer Sportster Repair Manual pg 230)) | Vacuum Operated Electric Switch. Senses intake manifold vacuum from the carburetor and switches to one of two different spark advance curves. ((1959-1985 Clymer Sportster Repair Manual pg 230)) | ||
| - | Research Voes: [[:how_to:electrictech:start#voes|]] | + | Research Voes: [[z-toberemoved-how_to:electrictech:start#voes]] |
| ===== Volt ===== | ===== Volt ===== | ||
| Unit for expressing 'pressure' in a circuit. Volts= Current x Ohms ((Haynes Sportster manual 1970-2010 pg REF*53)) | Unit for expressing 'pressure' in a circuit. Volts= Current x Ohms ((Haynes Sportster manual 1970-2010 pg REF*53)) | ||
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| - | [[:terminology:start|Return to Sportster Terminology Main Page]] | + | \\ |
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