Credits:2 Lecture Hours:0 Lab Hours:4 Practicum Hours:0 Work Experience:0 Course Type:Voc/TechThe basic principles of fluid power and the operation and application of fluid power components are introduced. In the lab we will evaluate valves along with linear and rotary actuators. Corequisite:ELT 791 Competencies
Operate and troubleshoot hydraulic and pneumatic circuits. PERFORM THE FOLLOWING TASKS FOR EACH OF THE LAB EXPERIMENTS AS INSTRUCTED
Observe and practice safety precautions
Interpret a given circuit plumbing diagram
Draw a schematic diagram when given the plumbing diagram using standard American National Standards Institute (ANSI) symbols
Connect the circuit using either the plumbing diagram or the schematic diagram
Make settings and adjustments
Record settings and measurements
Analyze and evaluate circuits and recorded data
Calculate circuit parameters
Compare and list similarities/differences between circuits
Predict results/outcomes when circuit variables are changed
Complete check-out activities at the end of each lab exercise
Set maximum pump pressure to safely limit system pressure
Operate hydraulic components within manufacturer’s specified limits
Identify a pump which is experiencing cavitation (true cavitation
Demonstrate true pump cavitation
Recognize sounds associated with true cavitation
List causes and effects of true cavitation
Identify a pump which is experiencing pseudo-cavitation
Demonstrate pseudo-cavitation
Recognize sounds associated with pseudo-cavitation
List causes and effects of pseudo-cavitation
Measure pump flow rate
Describe how to test a new or rebuilt pump
Control cylinder position and movement
Observe how valve spool variations effect double acting cylinder behavior in different applications
Verify that cylinder entering and discharge flow rates are not the same
Determine the size of system components
Use hydraulic cylinders which employ cushions
Explain why cylinder cushions are used
Observe how cylinder cushions function
Describe cushion limitations
Perform cushion adjustments
Use a 2:1 cylinder to increase rod velocity when approaching the work load
Show how a cylinder of the correct proportion (rod to bore) can be used to obtain a rod speed twice the normal speed that pump flow alone would normally dictate
Describe how cylinder regeneration works
Illustrate how to automatically take a cylinder out of regeneration when it contacts the work load
Operate a hydraulic circuit employing meter-in speed control
Observe how Meter-In speed control effects all of the components in the interacting hydraulic circuit
Explain why and when Meter-In control is used
Determine repeatability for a given pressure setting
Summarize the effects of system pressure variations and work load variations in determining actuator speed for hydraulic circuits employing ‘non-compensated’ flow control valves
Determine how flow varies with pressure change using a noncompensated needle valve
Observe cylinder action during cylinder extension and retraction
Observe how a needle valve combined with a reverse free flow check valve effects cylinder operation in both Meter-In and Meter-Out modes
Verify that non-compensated flow control valves are good metering devices as long as pressure differential across the valve remains relatively constant
Summarize the effects of system pressure variations and work load variations in determining actuator speed for hydraulic circuits employing ‘pressure compensated’ flow control valves
Demonstrate the conditions under which a pressure compensated flow control valve is effective
Describe the limitations of a P.C.F.C. valve in controlling actuator speed
Compare the action of Meter-Out with Meter-In flow control using the pressure compensated type flow control valve
Determine the effectiveness of the P.C.F.C. valve in Meter-Out mode with sudden changes in work load resistance
Observe that cylinder rod end pressure intensification can occur with Meter-Out flow control unless proper precautions are taken
Compare bleed-off flow control with series flow control as they effect circuit operation
Analyze a hydraulic circuit which employs a pressure compensated flow control valve in a bleed-off circuit configuration
Determine how and when to use Bleed-Off flow/speed control
Compare 3-port with 2-port pressure compensated flow control valves
Observe how a bypass (3-port) flow control valve functions
Determine the applications which use a bypass flow control valve
Determine 3-port flow control valve limitations
Use Accumulators in hydraulic circuits
List safety precautions associated with accumulators and accumulator circuits
Determine how accumulators interact with other circuit components
Identify the limitations of accumulator circuits
Use pilot operated check valves in hydraulic circuits
List the safety precautions associated with P.O.C.V.s.
Observe P.O.C.V. action in a hydraulic circuit
Identify proper applications and limitations of P.O.C.V.s
Describe variations of P.O.C.V.s for special applications
Operate hydraulic motors connected for Meter-In configurations
Identify applications and limitations of Meter-In circuits
Discuss malfunctions and troubleshooting related to hydraulic motors
Observe operation for constant and variable loads
Compare circuit operation when hydraulic motors are connected for Meter-Out vs. Meter-In configurations
Operate hydraulic motors connected for Meter-Out configurations
Determine if more accurate speed control can be obtained with Meter-Out flow control
Gather data on non-pressure and pressure compensated flow control Meter-Out performance
Use Brake Valves to stop hydraulic motors
Observe how the hydraulic actuated brake valve is applied to a hydraulic motor circuit
Observe the interaction between components
Use Cross-Over Relief Valves to stop hydraulic motors.
Operate and adjust the Cross-Over Relief valve for various circuit conditions
Observe cross-over relief valve behavior and limitations
Summarize applications, advantages, and disadvantages of compressed air
Outline safety practices associated with compressed air operations
Describe 13 safety rules necessary to use compressed air or gas
List devices or methods used to safely apply compressed air or gas
Use pneumatic symbols in pneumatic circuit schematic drawings
Identify and group the symbols used for pneumatic fluid power components
Explain the need for symbol use in everyday fluid power work
Draw commonly used pneumatic symbols
Measure pressures in pneumatic circuits
Use the draft gauge (manometer)
Explain how higher pressures are commonly measured
Relate volume and pressure
Observe the effect of moving a ‘piston’ on the internal gas pressure of a tube or cylinder as a demonstration of force transmission through a fluid by Pascal’s law
Differentiate gage pressure vs. absolute pressure
Measure Flow and Pressure Drop
Show the behavior of fluid gas (or compressed air) during transmission from point of generation (or storage) to point of use
Adjust flow and pressure to obtain desired results
Adjust a typical Pressure Switch Control
Draw a pressure switch symbol
Explain terms and definitions for pressure switch adjustments
Set desired cut-in and cut-out pressures
Use Safety Relief Valves in pneumatic circuits
Actuate the compressed air safety relief valve
Set safety relief valve trip pressure
Test a safety relief valve
Operate Pressure Regulators in pneumatic circuits
Draw the schematic symbol for a vented type pressure regulator
Explain pressure regulator behavior
Describe the reaction of the pressure regulator during adjustment and under flow conditions
Use Directional Control Valves in pneumatic circuits
Draw the schematic symbols for directional control valves
Describe how directional control is achieved in pneumatic systems
Explain the three major valve classifications
Relate force, area, and pressure in pneumatic cylinders
Demonstrate use of the force triangle
Calculate annular areas of cylinder pistons and rods
Determine the behavior of different types of linear actuators
Demonstrate force/area/pressure results of friction using linear actuators
Summarize Linear Actuator operation
Analyze linear actuator behavior under load
Explain linear actuator behavior as affected by
Determine actuator air consumption
Use Rotary Actuators in pneumatic circuits
Describe the CRAM
List the advantages of continuous rotation air motors (CRAM).
Define torque and how it applies to air motors
Describe operation and performance characteristics
Control actuators with 3-Way Directional Control Valves
Demonstrate 3-way DCV operation in several circuits with actuators
Show manual valve metering
Control actuators with 4-Way Directional Control Valves
Operate linear actuators with 4-way manual valve
Describe common industrial applications for air bearings
Show the behavior of equal bore and unequal bore cylinders operating in parallel
Calculate air bearing lifting force
Compare action of pressure regulator speed control to that of valve metering control
Determine operating pressures and clearances on different work surfaces
Show control of pilot operated directional control valve using 3-way valves
Demonstrate limits of pilot pressure shifting
Relate air flow velocity to air pressure
Demonstrate the relationship between air flow velocity and pressure
Explain how the air flow velocity-pressure relationship makes pneumatic devices such as a lubricator function