If the skier was skiing on a lake of SAE 90/ISO 220 gear oil and all of the other conditions were exactly the same, then the amount of spray generated would be considerably less because the fluid would resist the force of the ski to a much greater degree.
We can see how much water a professional skier displaces when he runs through a ski course. Water has a viscosity measured in centistokes of 1. Think of a water-skier cutting through the water. To simplify, the oil’s viscosity represents the measure for which the oil wants to stay put when pushed (sheared) by moving mechanical components. Viscosity is the measure of the oil’s resistance to flow (shear stress) under certain conditions. You don’t have to listen very long in this field before someone says that viscosity is the most important physical property of a fluid when determining lubrication requirements.
It is known as the International Standards Organization Viscosity Grade, ISO VG for short. In 1975, the International Standards Organization (ISO), in unison with American Society for Testing and Materials (ASTM), Society for Tribologists and Lubrication Engineers (STLE), British Standards Institute (BSI), and Deutsches Institute for Normung (DIN) settled upon an approach to minimize the confusion. This points to the need for a universally accepted viscosity designation - one that can be used by lubrication practitioners, lubricant suppliers and machinery design engineers simultaneously with minimal confusion. To complicate matters, machinery designers must define the lubricant viscosity in such a way that the equipment user understands clearly what is needed without having to consult outside advice. To the new entrant into the lubrication field, the number of options can be confusing, particularly if the primary lubricant supplier does not associate one of the prominent viscosity systems to the product label.
While all of these have served useful purposes to one degree or another, most lubrication practitioners settle on and use one method as a basis for selecting products. To add to the confusion, two measures of temperature (Fahrenheit and Celsius) can be applied to most of these, not to mention that viscosity might be presented at either 40☌ (104☏) or 100☌ (212☏). There are SAE (Society of Automotive Engineers) grades for gear oils and crankcases (engines), AGMA (American Gear Manufacturers Association) grades for gear oils, SUS (Saybolt Universal Seconds), cSt (kinematic viscosity in centistokes), and absolute viscosity. The largest discharge and velocity of seepage on silty sand material from Ida Bagus Oka street, Denpasar, obtained by using Geo-Studio SEEP/W Modeling was produced by pure water (without leachate), whereas, the smallest one produced by leachate from Suwung landfill site.Through the years, lubricant users have been treated to a number of ways to designate viscosity grades of the lubricants used in manufacturing. Due to mixed with leachate, soil hydraulic conductivity decreased from 0.001949 cm/s to 0.0001029 cm/s. The viscosity of leachate from ceramic industry was 0.01366741 N s/m2 and 0.002061309 N s/m2 from Suwung Disposal Site. It was found that the leachate viscosity was different each other. Seepage modeling on Geo-Studio was conducted on saturated/unsaturated condition. Seepage modeling in Geo-Studio SEEP/W was conducted on silty sand condition using pure water (without leachate), leachate from ceramic industry, and leachate from Suwung Disposal Site. Soil samples were silty sandy taken from Ida Bagus Oka street, Denpasar, Bali. The samples of leachate were taken from ceramic industry and from Suwung landfill site. This research aims to observe the influence of leachate viscosity on seepage using Geo-Studio SEEP/W Program. The problem that is often encountered with soil is soil contamination due to the discharge of leachate into the soil. The soil is an important material for human life.