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HYDRAULICS & PNEUMATICS
Actuators Presented by: Dr. Abootorabi
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Hydraulic Cylinders Actuators are the components used in a hydraulic system to provide power to a required work location. Cylinders are the hydraulic system components that convert fluid pressure and flow into linear mechanical force and movement.
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Hydraulic Cylinders A basic cylinder consists of: Piston Piston rod
Barrel The piston forms sealed, variable-volume chambers in the cylinder. System fluid forced into the chambers, drives the piston and rod assembly.
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Hydraulic Cylinders Seals prevent leakage between:
Piston and cylinder barrel Piston rod and head Barrel and its end pieces Wiper seal, or scraper, prevents dirt and water from entering the cylinder during rod retraction.
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Hydraulic Cylinders Various seals are used in a cylinder
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Hydraulic Cylinders Various seals are used in a cylinder
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Hydraulic Cylinders Various seals are used in a cylinder
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Hydraulic Cylinders Various seals are used in a cylinder
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Hydraulic Cylinders Cylinders are typically classified by operating principle: Single-acting Double-acting Single-acting Double-acting
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Hydraulic Cylinders Single-acting cylinder exert force either on extension or retraction: They require an outside force to complete the second motion (either by a spring or by the weight load). Double-acting cylinder generate force during both extension and retraction: Directional control valve alternately directs fluid to opposite sides of the piston Force output varies between extension and retraction
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Hydraulic Cylinders Single-acting cylinder
hydraulic ram (or plunger cylinder): piston and rod form one unit
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Hydraulic Cylinders Single-acting cylinder Scissor lifting table:
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Hydraulic Cylinders Double-acting cylinder
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Hydraulic Cylinders Double-acting cylinder
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Hydraulic Cylinders Double-acting cylinder types:
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Hydraulic Cylinders Double-acting cylinder types:
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Hydraulic Cylinders Double-acting cylinder types:
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Hydraulic Cylinders Effective piston area is reduced on retraction due to the rod cross section.
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Hydraulic Cylinders Telescoping cylinders are available for applications requiring long extension distances: Rod is made up of several tubes of varying size nested inside of the barrel Each tube extends, producing a rod longer than the cylinder barrel Typical example is the actuator that raises the box on a dump truck
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Hydraulic Cylinders Telescoping cylinders:
The maximum force is at the collapsed position The speed will increase at each stage, but will not allow much force
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Hydraulic Cylinders Cylinders often use hydraulic cushions (to brake high stroke speeds): Provide a controlled approach to the end of the stroke Reduces the shock of the impact as the piston contacts the cylinder head
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Hydraulic Cylinders Cylinders with end position cushioning:
Cushioning is not required for speeds of v<6 m/min. This type of end position cushioning is used for stroke speed between 6 m/min and 20 m/min. At higher speed, additional cushioning or braking devices must be used.
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Hydraulic Cylinders A variety of mounting configurations are used to attach the cylinder body and rod end to machinery: Fixed centerline Fixed noncenterline Pivoting centerline Expected cylinder loading is the major factor in the selection of the mounting style.
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Hydraulic Cylinders Head-end (Fixed centerline) flange mount
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Hydraulic Cylinders Fixed-noncenterline mount
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Hydraulic Cylinders Pivoting-centerline, clevis mount
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Hydraulic Cylinders Pivoting-centerline, trunnion mount
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Hydraulic Cylinders Types of mounting:
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Hydraulic Cylinders The force generated by a cylinder is calculated by multiplying the effective area of the piston by the system pressure. F=p.A By consideration of mechanical efficiency:
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Hydraulic Cylinders Cylinder characteristics
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Hydraulic Cylinders Cylinder characteristics dp: cylinder dia.
Ap: cylinder area dST: piston rod dia.
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Hydraulic Cylinders Q [m3/s] = A [m2] × [m/s]
Speed at which the cylinder extends or retracts is determined by: Flow Rate (Q) Effective Area (A) Piston velocity Effective area Q [m3/s] = A [m2] × [m/s]
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Hydraulic Cylinders Buckling resistance
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Hydraulic Cylinders Selecting a cylinder (Example)
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Hydraulic Cylinders Selecting a cylinder (Example)
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Hydraulic Cylinders Selecting a cylinder (Example)
Buckling resistance diagram: Reference: Festo Didactic Hydraulic
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Hydraulic Cylinders Selecting a cylinder (Example)
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Hydraulic Cylinders Selecting a cylinder (Example)
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Hydraulic Cylinders Selecting a cylinder (Example)
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Hydraulic Cylinders
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Hydraulic Cylinders Hydraulic cylinder manufacturers provide detailed specifications and basic factors such as: Bore Stroke Pressure rating Other details, such as service rating, rod end configurations, and dimensions
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Hydraulic Cylinders Typical manufacturer’s catalog page
Bailey International Corporation
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Limited-Rotation Hydraulic Actuators
Limited-rotation devices (swivel drive) are actuators with an output shaft that typically applies torque through approximately 360° of rotation. Models are available that are limited to less than one revolution, while others may produce several revolutions.
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Limited-Rotation Hydraulic Actuators
Most common designs of limited-rotation actuators are: Rack-and-pinion Vane Helical piston and rod
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Limited-Rotation Hydraulic Actuators
Rack-and-pinion limited rotation actuator Here maximum angle may be larger than 360°.
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Limited-Rotation Hydraulic Actuators
Vane limited-rotation actuator
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Limited-Rotation Hydraulic Actuators
Helical piston and rod limited-rotation actuator
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Limited-Rotation Hydraulic Actuators
Helical piston and rod limited-rotation actuator
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Limited-Rotation Hydraulic Actuators
Limited-rotation actuators are used to perform a number of functions in a variety of industrial situations: Indexing devices on machine tools Clamping of workpieces Operation of large valves Limited-rotation actuators are used in this robotic arm:
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Limited-Rotation Hydraulic Actuators
Operation of large valves
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Hydraulic Motors Hydraulic motors are called rotary actuators.
They convert fluid pressure and flow into torque and rotational movement.
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Hydraulic Motors System fluid enters the housing and applies pressure to the rotating internal parts. This, in turn, moves the power output shaft and applies torque to rotate a load. Primary parts that produce the rotating motion in most hydraulic motors are either: Gears Vanes Pistons
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Hydraulic Motors The external gear hydraulic motor is the most common and simplest of the basic motor types: Unbalanced load on the bearings
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Hydraulic Motors External gear hydraulic motor:
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Hydraulic Motors The most common internal gear motor has a gerotor design
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Hydraulic Motors Basic vane motor (unbalanced)
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Hydraulic Motors A basic, balanced vane motor
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Hydraulic Motors Axial piston motors are available in two configurations: Inline Bent axis
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Hydraulic Motors Inline piston motor
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Hydraulic Motors Inline piston motor
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Hydraulic Motors Inline piston motor
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Hydraulic Motors Bent-axis piston motor
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Hydraulic Motors Radial piston motor
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Hydraulic Motors Radial piston motor
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Hydraulic Motors Hydraulic motors may be incorporated into circuits using series or parallel connections: Series circuits: total system pressure is determined by adding the loads placed on each unit Parallel circuits: each motor receives full system pressure; loads must be matched or equal flow supplied to each motor if constant speed is desired from each unit
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Hydraulic Motors Motors in series
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Hydraulic Motors Motors in parallel
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Hydraulic Motors Motors in parallel with flow control
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Hydraulic Motors Hydraulic motor formulas: Power:
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The end.
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