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Fluid Energy
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Fluid Power - Definitions
Fluid power is energy that is transmitted by pressurizing and controlling a contained fluid Hydraulics: Use of liquids to perform mechanical tasks Pneumatics: Use of pressurized gas (air) to perform mechanical tasks
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Pressure Force Area Pressure is a force acting on a unit of area of a
surface. Atmospheric Pressure is the weight of a column of air pushing down through miles of atmosphere on a measured area of the earth surface. Force Pressure = Area In the metric system pressure is measured in Newtons/area
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Open and Closed Fluid Systems
Open systems vent or the fluid does not return to the starting point. Examples are irrigation systems, forced hot air heating systems, air compressors. Close systems are designed to have the fluid return to the start or do not allow the fluid to escape or the system. Examples would be a hot water heating systems and hydraulic brake system.
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Pressure in a confined vessel
Pascal’s Law states that pressure applied to a confined fluid is transmitted equally in all directions. If the stopper of a flask, which is full of a liquid, is pushed in with a Pressure of 100N/cm2 then the pressure will be the same on all sides of the flask.
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Pressure in a confined vessel
If the flask has an internal surface area of 20 cm2, and the force is 100 N, what is the total pressure in the flask? Force Total Pressure = Area = 100 N / 20 cm2 Total Pressure = 5 N/cm2
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Hydraulic Systems Two Pistons That Are The Same Size
A hydraulic system has two or more pistons and the pressure per area inside the system is the same. Two pistons with the same diameter have the same surface area. Piston 1 travels a certain distance as indicated by the dotted line. Piston 2 will correspond and travel the same distance in the opposite direction with the same lifting force as the applied force. Link
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Hydraulics Two Different Size Pistons
When force is applied to piston C, it will move nine units for every one unit that piston D moves, and the force is multiplied nine times on piston D. Piston D is 9 times larger than Piston C. Therefore the resultant force is 9 times more than the input piston. Or the resultant force on Piston D is 900 lbs. The Trade-off is the distance on Piston D is 1/9th the applied distance on Piston C. C D (900 lbs) Piston D is 9 times larger
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Hydraulic Applications
Car brakes – Step on the brake and piston in the master cylinder pushes the brake fluid down to the wheel cylinder that pushes the pistons that expand the brake pads. Caliper Disc Brakes Link Drum Brakes Bucket loaders, snow plows, wood splitter also use Hydraulic rams to apply a force to do work.
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Pneumatic System Use of pressurized gas (air) to transmit and control power Uses air as the working fluid: Air is safe for disposal or in case of leaks Low cost Readily available Lower frictional pressure and power losses Low pressure applications when compared to hydraulic systems (high pressure applications). Usually less than 300 psi for pneumatics while for hydraulics can go as high as 12,000 psi.
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Pneumatics What is the difference between a gas and a liquid?
When pressure is put on a gas it will compress. Liquids can not compress which means more force but need to be closed systems. Pneumatics systems are fast acting and clean air systems do not need a return (vent at work area) A device that operates using compressed gas is called a Pneumatics. Vent or Exhaust Single acting (spring return) Reciprocal or Double acting (air return)
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Pneumatic Applications
Pneumatic Clamps or vices Air operated tools: Paint sprayer, pneumatic wrench, Nail guns, etc. A force provided by an air compressor Although the pressure is the same it is exerted over a larger area of the large piston thus the force is multiplied. Car lifts in garage (pneumatic and Hydraulic) Pressure is exerted equally in an enclosed static fluid: Pascal’s Law The force in the small cylinder must be exerted over a large distance. A small force over a large distance is a tradeoff for a larger force with a short distance.
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Boundary layer buildup in a pipe
Because of resistance and surface tension along the walls of a pipe the flow of a fluid will be slower near the wall and faster in the center. v v Pipe Entrance v
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Flow rates in relation to diameter changes
Bernoulli's Principle states that as the speed of a moving fluid increases, the pressure within the fluid decreases. • Speed changes as diameter changes • Pressure decreases with increasing speed High Pressure Low Pressure Venturi Effect An area of low pressure will draw a liquid up a tube.
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Elbow Loss in a Pipe A piping system may have many minor losses of flow rates on elbows. As a fluid flows around the elbow it causes a area of turbulence just after the turn. In rivers this often leads to a sandbar. 45° elbows would have less turbulence than 90°
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