\n A. Ball Viscometer or Falling sphere viscometer.<\/strong><\/span>
\n<\/strong> Kenematik large viscosity is as high as the speed of the ball falling h divided by the density of the liquid being measured.<\/span> (See figure 1)<\/span>
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![\"image\"](\"https:\/\/www.tneutron.net\/mesin\/wp-content\/uploads\/sites\/4\/2016\/12\/image-8.png\" "\\"image\\"")
<\/a>\n Figure 1. Falling sphere viscometer<\/span><\/p>\n
B. Viscosity margins.<\/strong><\/span> Table limits are ideal viscosity<\/span> C. capillary viscometer<\/strong><\/span> Equality between the fourth unit system<\/span><\/a>
\n Figure 2. Capilary viscometer<\/span><\/p>\n
\n The purpose of viscosity margins are the boundaries of the upper and lower need to know.<\/span> Due to the viscosity is too low will result in a small lubricating power, power is small so easily leak sealing.<\/span> Whereas if the viscosity is too high will also increase friction in the liquid so that it requires a higher pressure.<\/span><\/p>\n
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\n And measures are as follows: (see figure 2) hydraulic fluid to be measured is poured through a hole to the container E in which the temperature is set.<\/span> C through capillary liquid is sucked up to ride on a pumpkin D until the line L1, then all the holes closed.<\/span> To measure it, go together holes A, B and C and calculate the time taken by the fluid to go down to L2.<\/span> The time indicates the viscosity of the fluid.<\/span> The more viscous hydraulic fluid will be more time to get down and mean greater viscosity.<\/span><\/p>\n
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