TSM 363 Applied Fluid Power

1. TSM 363 Applied Fluid Power Principle of Hydraulic Pumps

2. Goals of this Lecture • Basics of hydraulic pump • Principle of Positive displacement pumping • Key parameters • Principles of typical hydraulic pumps • Gear pumps • Vane pumps • Piston pumps

3. It’s Powerful, What Provides the Power?

4. vo, Fo • P1 Q1 • P4 Q4 • ni, Ti • M • no, To • EnergyLevel Energy Flow in a Fluid Power System

5. Positive Displacement Pumping

6. Key Hydraulic Pump Parameters • Rated discharge pressure –the maximum continuous operating pressure of a pump under normal operating condition • maximum discharge pressure • minimum discharge pressure (or margin pressure) • maximum inlet pressure • Rated speed –the speed at which the pump can continuously operate to discharge flow at the rated pressure • maximum speed • minimum speed

7. M R P M H T Pressure Rating of the Pump Pressure rating is the maximum pressure that should be encountered at the pump discharge port. Pressure is determined by Load!

8. Pump Power Output HPout = (Q·P)/1714 Q = flow rate, in gpm P = pressure, in psi Power Output from a Hydraulic Pump In a hydraulic displacement pump, the power output is determined by the setting pressure and the actual output flow rate, and the pump efficiency using the equation below:

9. Pump Capacity (flow rate) Q =D·n/k Q =flow rate, in GPM or L/min D =Displacement, in in3 or cc n =Pump shift speed, in rev/min Delivery Capacity of a Pump In practice, the pump is rated in terms of how much fluid is supplied per unit of time, and expressed in terms of: Gallons per minutes (GPM) liters per minutes (L/min) k =Unit conversion constant

10. Q = 0.641 (in3/rev) x1000(rev/min)/231(in3 /gal) Q = 2.77 (gal/min) K = unit conversion constant K = 231(gal/in3), because 1 gal = 231 in3 Example: Determination of Pump Capacity From the catalog of a hydraulic pump manufacturer, we can find the following information: Pump Delivery @ 1000 RPM & 0.641 in3/rev. Please try to determine the pump capacity: Q = D·n/K

11. Commonly Used Hydraulic Pumps • Vane Pumps • Unbalanced vane pump • Balanced vane pump • Gear Pumps • External gear pump • Internal gear pump • Piston Pumps • Radial piston pump • Axial piston pump

12. Vane Pumps • Construction with a round cam ring • Low cost • Limited pressure capability • Unbalanced hydraulic loading (side-loading) • Popular with fixed displacement pumps • Prevents side-loading • Limited pressure range • Relatively more expensive

13. Gear Pumps • Fixed displacement only • High pressure capability • Unbalanced • Available as single, multiple or through drive version • One external gear and one internal gear • fixed displacement only • Unbalanced • More compacted in size

14. Piston Pumps • Pistons arranged radially in a cylinder block • High efficient • medium-high pressure range • Rotating cylinder block (centrifugal force) • Pistons parallel to axis of the cylinder block • High efficient • medium-high pressure range • Compacted size

15. Operation Principle of Piston Pumps

16. M 1,000 psi P R H T M Needs for Variable-Displacement Pump Fixed displacement pumps discharge a set volume of fluid regardless of the system requirement. An amount of excess will generate heat to the system.

17. Power Wasted in a Fixed-Displacement Pump Pump displacement “Corner” horsepower Pump output flow Metering point Wasted Power Relief setting Useable Power Operating pressure

18. Operation of Variable Displacement

19. Variable Displacement Pump • The volume of supplying fluids may be change based on demands Key Feature of a V-Displacement Pump • Fixed Displacement Pump • A fixed volume of fluids will be provided in each revolution

20. Lecture Summary • Discussed a few basic theoretical equations, and their applications in hydraulic systems: • Principle of Positive displacement pumping • Key parameters of hydraulic pumps • Common types of hydraulic pumps • The need for variable displacement pumps