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Compensation Design Network System For Electrical Lab Training

Compensation Design Network System For Electrical Lab Training....

Compiler for Microchip For Electrical Lab Training

Compiler for Microchip For Electrical Lab Training....

Complex Grinder of Mill & Drill

Complex Grinder of Mill and Drill Ministerial Tender Board Equipment, Ministry of Education and Vocational Training Lab Tenders Suppliers India....

Complex Grinder of Mill & Drill

Complex Grinder of Mill and Drill Ministerial Tender Board Equipment, Ministry of Education and Vocational Training Lab Tenders Suppliers India....

Complex Grinder of Mill & Drill

Complex Grinder of Mill and Drill Ministerial Tender Board Equipment, Ministry of Education and Vocational Training Lab Tenders Suppliers India....

Composite Wall Apparatus

Composite Wall Apparatus....

Composite Walls Apparatus

Composite Walls Apparatus Ministerial Tender Board Equipment, Ministry of Education and Vocational Training Lab Tenders Suppliers India....

Composite Walls Apparatus for Research Institutes

Composite Walls Apparatus for Research Institutes....

Compound Bar

Compound Bar....

Compound Color Demonstrator

Compound Color Demonstrator....

Compound Lever- Engineering Lab Training Systems

Compound Lever- Engineering Lab Training Systems....

Compound Or Facet Eye

Compound Or Facet Eye....

Compound Pendulum Apparatus- Engineering Lab Training Systems

Compound Pendulum Apparatus- Engineering Lab Training Systems....

Compound Pendulum- Engineering Lab Training Systems

Compound Pendulum Engineering Lab Training Systems....

Compound Screw Jack- Engineering Lab Training Systems

Compound Screw Jack- Engineering Lab Training Systems....

Compound Screw Jack- Engineering Lab Training Systems

Compound Screw Jack- Engineering Lab Training Systems....

Compound Wheel And Axle- Engineering Lab Training Systems

Compound Wheel And Axle- Engineering Lab Training Systems....

Compound Wires Apparatus- Engineering Lab Training Systems

Compound Wires Apparatus- Engineering Lab Training Systems....

Comprehensive Flywheel Apparatus- Engineering Lab Training Systems

Comprehensive Flywheel Apparatus Engineering Lab Training Systems....

Compressible Flow Unit

Compressible Flow Unit....

Compressible Flow Unit- Engineering Lab Training Systems

Technical Description The unit is a table model with a powerful radial fan and various flow models.....

Compressible Flow Bench

Compressible Flow Bench Ministerial Tender Board Equipment, Ministry of Education and Vocational Training Lab Tenders Suppliers India....

Compression Of Springs Apparatus- Engineering Lab Training Systems

Compression Of Springs Apparatus- Engineering Lab Training Systems....

Compression Resistance Tester (for footwear) For Testing Lab

Compression Resistance Tester (for footwear) For Testing Lab Workshop....

Compression Set Apparatus

Compression Set Apparatus from India....

Compression Set Apparatus Constant Stress For Testing Lab

Compression Set Apparatus Constant Stress For Testing Lab Workshop....

Compression Set Apparatus Constant Stress Type For Testing Lab

Compression Set Apparatus Constant Stress Type For Testing Lab Workshop....

Compression Set Apparatus For Testing Lab

Compression Set Apparatus For Testing Lab Workshop....

Compression Strength Tester For Testing Lab

Compression Strength Tester....

Compression Strength Tester For Transport Packages For Testing Lab

Compression Strength Tester For Transport Packages....

Compression Test Machine

Compression Test Machine....

Compression Tester For Electrical Lab Training

Compression Tester For Electrical Lab Training....

Compression Tester For Rigid Non-Metallic Conduits For Electrical Lab Training

Compression Tester For Rigid Non-Metallic Conduits For Electrical Lab Training....

Compression Tester For Testing Lab

Compression Tester For Testing Lab Workshop....

Compression Testers

Compression Testers from India....

Compression Testing Machine

Compression Testing Machine from India....

Compression Testing Machine 1000 KN (Hand Operated) - 02 For Testing Lab

The machine is designed for portability, operating convenience and accuracy. It is a compact and self contained. Unit ideally suited for mobile and field laboratories.....

Compression Testing Machine 2000 KN (Electrically Operated) For Testing Lab

Compression Testing Machine (Electrically Operated) - Four Pillar type It is an electric cum hand operated for compression tests on concrete specimens up to 20cm dia and 30 cm in height.....

Compressive & Bending Strength Of Structural Materials For Testing Lab

Compressive and Bending Strength Of Structural Materials....

Compressometer Concrete Specimen- Engineering Lab Training Systems

Compressometer Concrete Specimen- Engineering Lab Training Systems....

Compressor

Compressor....

COMPRESSOR

Compressor....

Compressor Analyzer

Compressor Analyzer....

Compressor Controls

Compressor Controls....

Compressor Controls Trainer- Engineering Lab Training Systems

Compressor Controls Trainer- Engineering Lab Training Systems....

Computed Radiography

Computed Radiography....

Computer

Computer....

Computer based e-Learning System

Computer based e-Learning System....

Computer Compatible Manometer Bank

Computer Compatible Manometer Bank Electronic multiple channel pressure measurement system designed to replace liquid manometer banks.....

Computer Controlled Aerodynamic Tunnel- Engineering Lab Training Systems

EXERCISES AND PRACTICAL POSSIBILITIES Some Practical Possibilities of the Unit: 1.-Comprehensive study of subsonic aerodynamics and air flow studies. 2.-Flux in a nozzle. Determine the characteristics of the pressures field in a nozzle. 3.-Flux in an nozzle. To observe the local characteristics, depending on whether the walls have a curvature or not, as well as what happens in the inlet and outlet  areas of the contraction. 4.-Flow of an uniform current around a cylinder. 5.-To determine the form of the field of pressures around a cylinder on  which a perpendicular to the axis current impacts. 6.-To  determine,  by  the  detachment  type,  if  the  boundary  layer  finally becomes turbulent or remains laminar. 7.-To determine the coefficient of resistance of the cylinder, for the described situation of flow. 8.-To relate all the above mentioned with the Reynolds’s number. 9.-Flow of an uniform current around a concave and a convex semi-cylinder. 10.-To determine the field or pressures in the two semi-cylinders,the concave one and the convex one. 11.-To determine the coefficients of aerodynamic resistance in the concave and the convex semi-cylinders. 12.-Aerodynamics forces due to the wind on house. 13.-Measurement of pressure distribution around body two-dimensional. 14.-Flow visualization studies. 15.-Velocity and pressure distribution measurement using a Pitot’s Tube. 16.-Sensors calibration. Practices to be done by PLC Module (PLC-PI)+PLC Control Software: 17.-Control of the unit process through the control interface box without the computer. 18.-Visualization of all the sensors values used in the unit process. 19.-Calibration of all sensors included in the unit process. 20.- Hand on of all the actuators involved in the unit process. 21.-Realization of different experiments, in automatic way, without having in front the unit.  (This experiment can be decided previously). 22.-Simulation of outside actions, in the cases do not exist hardware elements. (Example: test of complementary tanks, complementary industrialenvironment to the process to be studied, etc). 23.-PLC hardware general use and manipulation. 24.-PLC process application for unit. 25.-PLC structure. 26.-PLC inputs and outputs configuration. 27.-PLC configuration possibilities. 28.-PLC program languages. 29.-PLC different programming standard languages (literal structured, graphic, etc.). 30.-New configuration and development of new process. 31.-Hand on an established process. 32.-To  visualize  and  see  the  results  and  to  make  comparisons  with  the  unit process. 33.-Possibility of creating new process in relation with the unit. 34.-PLC Programming Exercises. 35.-Own PLC applications in accordance with teacher and student requirements     Fluid Mechanics Lab Equipments manufacturers....

Computer Controlled Aerodynamic Tunnel- Engineering Lab Training Systems

DESCRIPTION Aerodynamic Tunnel of 1200*1200mm, principal characteristics: * Adequate size for demostration tests and teaching. * Suitable for three-dimensional models. * Test Chamber builts with transparent materials. * Low operation and maintenance cost. * Suitable for smokes visualization test. * AC motor-ventilator gropu, monophasic, with frequency variator. SPECIFICATIONS  *The Aerodynbamic Tunnel of 1200*1200 mm section for testing, witha longitude of 2000 mm is of the Eiffeltype, aspirate and of open circuit, and allows us to carry out tests of measuring formces and aerodynamic field on models of structures, construcitons, land vehicles and small planes. * Its power plant, formed by 4 standard type ventilators, of 10 CV of power each one and 900 mm in diameter, has kept the final cost of the product low, while at the same time that assuring a simple and economicmaitenance. Nevertheless, this aspect does not prejudice the quality of the vein, of great uniformity and low turbulence level, thanks also to the adequate design of the contraction, neither does it affect the speed that is reached, this being about 36m/s in a vacuum. *The tunnel is built basically of wood, with a steel support structure, and windows for viewing inside the test chamber. Its wood panels are easilyreplaceable, if through wear and tear, or for any other motive, its aspect or mechanical capacity should make it necessary. This has the additional advantage of the ease with which new instrumentation can be added, since the corresponding supports and leads and conduit passes are easily made. *It has a Pitot pipe for measuring the speed of the incident flow. To this instrumentation, a multimanometer or a scanner system for the simultaneous measurement of pressures can be added, as well as a small scale of six components for measuring forces. A smoke generator can also be connected for flow visualization Fluid Mechanics Lab Equipments manufacturers....

Computer Controlled Axial Fan Teaching Trainer- Engineering Lab Training Systems

EXERCISES AND PRACTICAL POSSIBILITIES Some Practical Possibilities of the Unit: 1.Measurement of overall efficiency and estimation of impeller power efficiency. 2.Measurement of performance at constant speeds. 3.Study of the axial fan regulation varying its turning speed. 4.Measurement of inherent-speed machine performance in terms static and total pressure, rotor speed and motor input power, as an inlet flow function. 5.Introduction to similarity laws for scale-up. 6.Obtaining of the characteristic curves of an axial fan. 7.Calculation of the Flow on a Hole Plate.. 8. Calculation of the Flow through a Symmetrical Seal. Test with an Outlet Duct and a Nozzle. 9.Calculation of the Fan Output. 10.Introduction to the Scaling Similitude Law. 11.Flow calculation through a measurement of the static, dynamic and total pressure.. 12.Typical curve calculation of a fan with a constant turning speed depending on the flow used by the symmetrical seal.                                                                                            Fluid Mechanics Lab Equipments manufacturers....

Computer Controlled Axial Flow Turbine- Engineering Lab Training Systems

EXERCISES AND PRACTICAL POSSIBILITIES Some Practical Possibilities of the Unit: 1.-Determination of the nozzle discharge coefficient. 2.-Determination of operating characteristics of the Axial Turbine at different speed values (20º nozzle). 3.-Determination of operating characteristics of the Axial Turbine at different speed values (30º nozzle). 4.-Determination of the Axial Turbine characteristic curves (20º nozzle). 5.-Determination of the Axial Turbine characteristic curves (30º nozzle). 6.-Determination of torque, efficiency and power curves at a constant value (20º nozzle). 7.-Determination of torque, efficiency and power curves at a constant value (30º nozzle). 8.-Determination of curves in relation to the turning speed (20º nozzle). 9.-Determination of curves in relation to the turning speed (30º nozzle). 10.-Determination of curves in relation to the flow (20º nozzle). 11.-Determination of curves in relation to the flow (30º nozzle). 12.-Adimensionalization. 13.-Flow calculation. Other possible practices: 14.-Pressure Sensors Calibration. 15.-Flow Sensor Calibration. Practices to be done by PLC Module (PLC-PI)+PLC Control Software: 16.-Control of the TFAC unit process through the control interface box without the computer. 17.-Visualization of all the sensors values used in the TFAC unit process. 18.-Calibration of all sensors included in the TFAC unit process. 19.-Hand on of all the actuators involved in the TFAC unit process. 20.-Realization of different experiments, in automatic way, without having in front the unit. (This experiment can be decided previously). 21.-Simulation of outside actions, in the cases do not exist hardware elements. (Example: test of complementary tanks, complementary industrial environment to the process to be studied, etc). 22.-PLC hardware general use and manipulation. 23.-PLC process application for TFAC unit. 24.-PLC structure. 25.-PLC inputs and outputs configuration. 26.-PLC configuration possibilities. 27.-PLC program languages. 28.-PLC different programming standard languages. 29.-New configuration and development of new process. 30.-Hand on an established process. 31-To visualize and see the results and to make comparisons with the TFAC unit process. 32.-Possibility of creating new process in relation with the TFAC unit. 33.-PLC Programming Exercises. 34.-Own PLC applications in accordance with teacher and student requirements.   Fluid Mechanics Lab Equipments manufacturers....

Computer Controlled Axial Pump Bench- Engineering Lab Training Systems

Exercises and Practical Possibilities to be done with Main Items 1.-Determination of the Q vs. r.p.m. curve for an axial pump. 2.-Determination of the H vs. Q curve for different r.p.m. of an axial pump. 3.-Determination of the mechanical power vs flow for different r.p.m. of an axial pump. 4.-Determination of the h vs flow curve for different r.p.m. of an axial pump. 5.-Determination of an axial pump’s map. Other additional practical possibilities: 6.-Sensors calibration. 7.-Obtaining the H(n) and N(n) curves. 8.-Study of the influence of pressure at the outlet. 9.-Calculation of the axial pump efficiency. Other possibilities to be done with this Unit: 10.-Many students view results simultaneously. To view all results in real time in the classroom by means of a projector or an electronic blackboard. 11.- Open Control, Multicontrol and Real Time Control. This unit allows intrinsically and/or extrinsically to change the span, gain; proportional, integral, derivate parameters; etc, in real time. 12.-The Computer Control System with SCADA allows a real industrial simulation. 13.-This unit is totally safe as uses mechanical, electrical and electronic, and software safety devices. 14.-This unit can be used for doing applied research. 15.-This unit can be used for giving training courses to Industries even to other Technical Education Institutions. 16.-Control of the PBAC unit process through the control interface box without the computer. 17.-Visualization of all the sensors values used in the PBAC unit process. - By using PLC-PI additional 19 more exercises can be done. - Several other exercises can be done and designed by the user.                                 Fluid Mechanics Lab Equipments manufacturers....

Computer Controlled Centrifugal Compressor Demonstration Unit- Engineering Lab Training Systems

Exercises and Practical Possibilities to be done with Main Items 1.-Performance of a compressor. 2.-Demonstration of the phenomenon of air compression, after passage through the compressor impeller. 3.-Study of the variation of compressor performance with speed. 4.-Measurement of compressor efficiency and estimation of impeller power efficiency. 5.-Measurement of constant-speed machine performance in terms of static and total pressures, rotor speed and motor shaft power, as a function of inlet flow. 6.-Introduction to similarity laws for scale-up. 7.-Measurement of performance at constant speeds. 8.-Compressor curve for different stages. 9.-Calculation of the flow by means of the orifice plate. 10.-Calculation of the characteristic curve of a centrifugal compressor at a constant turn speed according to the flow used by the symmetrical stopper. 11.-Study and comparison of the computer results with the students calculations. Additional practical possibilities: 12.-Sensors calibration. Other possibilities to be done with this Unit: 13.-Many students view results simultaneously.  To view all results in real time in the classroom by means of a projector or an electronic blackboard. 14.-Open Control, Multicontrol and Real Time Control. This unit allows intrinsically and/or extrinsically to change the span, gains; proportional, integral, derivate parameters; etc in real time. 15.-The Computer Control System with SCADA allows a real industrial simulation. 16.-This unit is totally safe as uses mechanical, electrical and electronic, and software safety devices. 17.-This unit can be used for doing applied research. 18.-This unit can be used for giving training courses to Industries even to other Technical Education Institutions. 19.-Control of the HCCC unit process through the control interface box without the computer. 20.-Visualization of all the sensors values used in the HCCC unit process. - By using PLC-PI additional 19 more exercises can be done. - Several other exercises can be done and designed by the user.                               Fluid Mechanics Lab Equipments manufacturers....

Computer Controlled Centrifugal Fan Teaching Trainer- Engineering Lab Training Systems

EXERCISES AND PRACTICAL POSSIBILITIES Some Practical Possibilities of the Unit: 1.-Measurement of constant-speed fan performance in terms of static and total pressures, rotor speed and motor shaft power, as a function of inlet flow. 2.-Calculation of flow with and orifice plate. 3.-Calculation of the fan efficiency. 4.-Introduction to similarity laws for scale-up. 5.-Calculation of the flow by static pressure measurement, dynamic pressure measurement and total pressure depending of the test. 6.-Practices with the different of turbines: with the blades forwards, with the blades backwards and with flat blades. 7.-Determination of the fan characteristics curves. 8.-Calculation of the typical curve of a fan at a constant turning speed (turbine with blades forwards). 9.-Calculation of the typical curve of a fan at a constant turning speed (turbine with blades backwards). 10.-Calculation of the typical curve of a fan at a constant turning speed (turbine with flat blades). 11.-Measurement of performance at constant speeds. 12.-Static pressure increasing. 13.-Sensors calibration. Other possible practices (with the optional Set of Accessories): 14.-Calculation of flow. Test with discharge duct and nozzle. 15.-Calculation of flow. Test with aspiration duct and nozzle. 16.-Calculation of the differential flow according to the turbines position in the discharge duct. 17.-Calculation of the differential flow according to the turbines position in the aspiration duct. 18.-Determination of the fan characteristics curves (with the optional Set of Accessories). 19.-Measuring a cooling curve. 20.-Determination of the coefficient of heat transfer from the cooling curve. 21.-Measurement of the pressure distribution around a cylinder in a transverse flow. 22.-Measurements behind a cylinder in a transverse flow. 23.-Pressure loss measurements at a bend. 24.-Pressure loss measurements on pipe sections. 25.-Pressure loss measurements at an elbow. 26.-To investigate the influence of different shaped pipe inlets. Practices to be done by PLC Module (PLC-PI)+PLC Control Software: 27.-Control of the HVCC unit process through the control interface box without the computer. 28.-Visualization of all the sensors values used in the HVCC unit process. 29.-Calibration of all sensors included in the HVCC unit process. 30.-Hand on of all the actuators involved in the HVCC unit process. 31.-Realization of different experiments, in automatic way, without having in front the unit. (This experiment can be decided previously). 32.-Simulation of outside actions, in the cases do not exist hardware elements. (Example: test of complementary tanks, complementary industrial environment to the process to be studied, etc). 33.-PLC hardware general use and manipulation. 34.-PLC process application for HVCC unit. 35.-PLC structure. 36.-PLC inputs and outputs configuration. 37.-PLC configuration possibilities. 38.-PLC program languages. 39.-PLC different programming standard languages. 40.-New configuration and development of new process. 41.-Hand on an established process. 42.-To visualize and see the results and to make comparisons with the HVCC unit process. 43.-Possibility of creating new process in relation with the HVCC unit. 44.-PLC Programming Exercises. 45.-Own PLC applications in accordance with teacher and student requirements.  Fluid Mechanics Lab Equipments manufacturers....

Computer Controlled Centrifugal Pump Bench- Engineering Lab Training Systems

Exercises and Practical Possibilities to be done with Main Items  1.-Demonstration of a centrifugal water pump in operation. 2.-Introduction to pump speed laws. 3.-Obtaining of curves H(Q), N(Q) and Eff%(Q). 4.-Simultaneous representation of H(Q), N(Q) and Eff%(Q). 5.-Obtaining the map of a centrifugal pump. 6.-Adimensional study of magnitudes H *, N * and Q *. 7.-Cavitation test and obtaining of curves NPSHr. Additional practical possibilities: 8.-Sensors calibration. Other possibilities to be done with this Unit: 9.-Many students view results simultaneously. To view all results in real time in the classroom by means of a projector or an electronic blackboard. 10.-Open Control, Multicontrol and Real Time Control. This unit allows intrinsically and/or extrinsically to change the span, gains; proportional, integral, derivate parameters; etc in real time. 11.-The Computer Control System with SCADA allows a real industrial simulation. 12.-This unit is totally safe as uses mechanical, electrical and electronic, and software safety devices. 13.-This unit can be used for doing applied research. 14.-This unit can be used for giving training courses to Industries even to other Technical Education Institutions. 15.-Control of the PBCC unit process through the control interface box without the computer. 16.-Visualization of all the sensors values used in the PBCC unit process. - By using PLC-PI additional 19 more exercises can be done. - Several other exercises can be done and designed by the user.....

Computer Controlled Electronic Universal Testing Machine For Testing Lab

Computer Controlled Electronic Universal Testing Machine....

Computer Controlled Experimental Impulse Turbine- Engineering Lab Training Systems

EXERCISES AND PRACTICAL POSSIBILITIES Some Practical Possibilities of the Unit: 1.-Visual examination of a small turbine. 2.-Comparison of turbine performance, including specific consumption, when using: Throttle control. Nozzle control. 3.-Production of torque/speed and power/speed curves. 4.-Determination of the isentropic efficiency of a turbine and plotting the end states on a temperature/entropy diagram. 5.-Application of the First Law to a simple open system undergoing a steady flow process. 6.-Construction of retardation curve and the determination of resisting torques due to bearing frictions, disc friction and windage, at different speeds. 7.-Demonstration of cooling by expansion. Other possible practices: 8.-Sensors calibration. Practices to be done by PLC Module (PLC-PI)+PLC Control Software: 9.-Control of the HTIC unit process through the control interface box without the computer. 10.-Visualization of all the sensors values used in the HTIC unit process. 11.-Calibration of all sensors included in the HTIC unit process. 12.-Hand on of all the actuators involved in the HTIC unit process. 13.-Realization of different experiments, in automatic way, without having in front the unit. (This experiment can be decided previously). 14.-Simulation of outside actions, in the cases do not exist hardware elements. (Example: test of complementary tanks, complementary industrial environment to the process to be studied, etc). 15.-PLC hardware general use and manipulation. 16.-PLC process application for HTIC unit. 17.-PLC structure. 18.-PLC inputs and outputs configuration. 19.-PLC configuration possibilities. 20.-PLC program languages. 21.-PLC different programming standard languages. 22.-New configuration and development of new process. 23.-Hand on an established process. 24.-To visualize and see the results and to make comparisons with the HTIC unit process. 25.-Possibility of creating new process in relation with the HTIC unit. 26.-PLC Programming Exercises. 27.-Own PLC applications in accordance with teacher        and student requirements Fluid Mechanics Lab Equipments manufacturers....

Computer Controlled Experimental Reaction Turbine- Engineering Lab Training Systems

EXERCISES AND PRACTICAL POSSIBILITIES Some Practical Possibilities of the Unit: 1.-Visual examination of a small reaction turbine. 2.-Production of torque/speed and power/speed curves. 3.-Evaluation of specific air consumption at a range of speeds and  pressures. 4.-Application of the First Law to a simple open system undergoing a steady flow pressure. 5.-Determination of the isentropic efficiency of a reaction turbine and plotting the end states on a temperature/entropy diagram. 6.-Construction of retardation curve and the determination of resisting torques due to bearing friction, disc friction and windage, at different speeds. 7.-Obtaining the inlet pressure effect on the outlet power and effectiveness of the turbine, as well as torque, speed and power curves. Other possible practices: 8.-Sensors calibration. Practices to be done by PLC Module (PLC-PI)+PLC Control Software: 9.-Control of the HTRC unit process through the control interface box without computer. 10.-Visualization of all the sensors values used in HTRC unit process. 11.-Calibration of all sensors included in HTRC unit process. 12.-Hand on of all the actuators involved in the HTRC unit process. 13.-Realization of different experiments, in automatic way, without having in front the unit. (This experiment can be decided previously). 14.-Simulation of outside actions, in the cases do not exist hardware elements (Example: test of complementary tanks, complementary industrial environment to the process to be studied, etc). 15.-PLC hardware general use and manipulation. 16.-PLC process application for the HTRC unit. 17.-PLC structure. 18.-PLC inputs and outputs configuration. 19.-PLC configuration possibilities. 20.-PLC program languages. 21.-PLC different programming standard languages. 22.-New configuration and development of new process. 23.-Hand on an established process. 24.-To visualize and see the results and to make comparisons with the HTRC unit process. 25.-Possibility of creating new process in relation with the HTRC unit. 26.-PLC Programming Exercises. 27.-Own PLC applications in accordance with teacher   and student requirements.  Fluid Mechanics Lab Equipments manufacturers....

Computer Controlled Flow Channels- Engineering Lab Training Systems

Computer Controlled Flow Channels (section: 80 x 300 mm).(several lengths) Exercises and Practical Possibilities to be done with Main Items 1.-    Measurement of the water height and the velocity along the channel. 2.-    Measurement of the flow with weirs of thin wall. 3.-    Measurement of flow with changes in the channel section. 4.-    Measurement of flow using Venturi flume. 5.-    Control of the flow by gates. 6.-    Level control using syphons. 7.-    Flow on overflow dams. 8.-    Flow among the pillars of a bridge. 9.-    Connection of a channel to a culvert. 10.-  Characterization of the hydraulic jump. 11.-  Profiles of the water free surface. 12.-  Investigation of flow and supercritical flow states. 13.-  Measurement of water levels. 14.-  Discharge processes on an underwater weir. 15.-  Amount of energy in flows in open channels. 16.-  Function of a syphon weir. 17.-  Flow rate and drain coefficients of a syphon weir. 18.-  Pipe flows. 19.-  Comparison of overflow and syphon weirs. 20.-  Observation of the throw of the water. 21.-  Generation of different flow states by damming the down-stream water. 22.-  Observation of the flow under an undershot weir:          -Observation of hydraulic motion on discharge. 23.-  Relationship between dam height and   discharge. 24.-  Observation of discharges under a radial gate:          -Observation of hydraulic motion on discharge. 25.-  Hydrostatic pressure on a weir. 26.-  Investigations on waves. 27.-  Behaviour of structures in rough sea. 28.-  Applying and understanding Manning’s formula. 29.-  Understanding sub- and super-critical flow. 30    Learning how to apply force-momentum and steady flow energy equations to simple flow situations. 31.-  Investigation of the transition from running to shooting flow. Additional practical possibilities: 32.-  Sensors calibration. 33.-  Filling of the Pitot tube. 34.-  Filling of the venturi meter with analog output. 35.-  Calculation of water flow. 36.-  Use of level gauge for measurement of the water height. Other possibilities to be done with this Unit: 37.-  Many students view results simultaneously.         To view all results in real time in the classroom by means of a projector or an electronic blackboard. 38.-  Open Control, Multicontrol and Real Time Control. This unit allows intrinsically and/or extrinsically to change the span, gains; proportional, integral, derivate parameters; etc in real time. 39.-  The Computer Control System with SCADA allows a real industrial simulation. 40.-  This unit is totally safe as uses mechanical, electrical and electronic, and software safety devices.                                                                                                   Fluid Mechanics Lab Equipments manufacturers....

Computer Controlled Flow Channels- Engineering Lab Training Systems

Computer Controlled Flow Channels (section: 300 x 450mm). (several lengths) EXERCISES AND PRACTICAL POSSIBILITIES Some Practical Possibilities of the unit: (in function of the accessories used) 1.-Measurement of the water height and the velocity along the channel. 2.-Measurement of the flow with weirs of thin wall. 3.-Measurement of flow with changes in the channel section. 4.-Measurement of flow using Venturi flume. 5.-Control of the flow by gates. 6.- Level control using syphons. 7.-Flow on overflow dams. 8.- Flow among the pillars of a bridge. 9.- Connection of a channel to a culvert. 10.-Characterization of the hydraulic jump. 11.-Profiles of the water free surface. 12.-Investigation of flow and supercritical flow states. 13.-Measurement of water levels. 14.-Discharge processes on an underwater weir. 15.-Amount of energy in flows in open channels. 16.-Function of a syphon weir. 17.-Flow rate and drain coefficients of a syphon weir. 18.-Pipe flows. 19.-Comparison of overflow and syphon weirs. 20.-Observation of the throw of the water. 21.-Generation of different flow states by damming the down-stream water. 22.-Observation of the flow under an undershot weir:  -Observation of hydraulic motion on discharge. 23.-Relationship between dam height and discharge. 24.-Observation of discharges under a radial gate -Observation of hydraulic motion on discharge. 25.-Hydrostatic pressure on a weir. 26.-Investigations on waves. 27.-Behaviour of structures in rough sea. 28.-Applying and understanding Manning’s formula. 29.-Understanding sub- and super-critical flow. 30.-Learning how to apply force-momentum and steady flow energy equations to simple flow situations. 31.-Investigation of the transition from running to shooting flow. Other possible practices: 32.-Filling of the Pitot tube. 33.-Filling of the venturi meter with analog output. 34.-Calculation of water flow. 35.- Use of level gauge for measurement of the water height.                                  Fluid Mechanics Lab Equipments manufacturers....

Computer Controlled Fluid Friction in Pipes, with Hydraulics Bench- Engineering Lab Training Systems

EXERCISES AND PRACTICAL POSSIBILITIES Some Practical Possibilities of the Unit: 1.-  Load loss by friction in a rough pipe of 17 mm of interior diameter. 2.-  Load loss by friction in a rough pipe of 23 mm of interior diameter. 3.-  Load loss by friction in a smooth pipe of 6.5 mm of interior diameter. 4.-  Load loss by friction in a smooth pipe of 16.5 mm of interior diameter. 5.-  Load loss by friction in a smooth pipe of 26.5 mm of interior diameter. 6.-  Influence of the diameter in the load loss by friction in rough pipes. 7.-  Influence of the diameter in the load loss by friction in smooth pipes. 8.-  Load loss by friction in smooth and rough pipes. 9.-  Friction coefficient in a rough pipe of 17 mm of interior diameter. 10.-Friction coefficient in a rough pipe of 23 mm of interior diameter. 11.-Friction coefficient in a smooth pipe of 6.5 mm of interior diameter. 12.-Friction coefficient in a smooth pipe of 16.5 mm of interior diameter. 13.-Friction coefficient in a smooth pipe of 26.5 mm of interior diameter. 14.-Influence of the diameter in the friction coefficient in rough pipes. 15.-Influence of the diameter in the friction coefficient in smooth pipes. 16.-Friction coefficient in smooth and rough pipes. 17.-Load losses in the inclined seat valve. 18.-Load losses in the floodgate valve. 19.-Load losses in the filter. 20.-Load losses in the membrane valve. 21.-Load losses in an abrupt broadening. 22.-Load losses in the venturimeter 23.-Load losses in the diaphragm. 24.-Load losses in an abrupt contraction. 25.-Load losses in the accessories. 26.-Flow measurements by load loss in a venturimeter. 27.-Flow measurements by load loss in a diaphragm. 28.-Flow measurements by means of load loss. 29.-Load losses in a symmetrical bifurcation. 30.-Load losses after two 90º elbows. 31.-Load losses in a T-junction. 32.-Load losses for a 90º elbows. 33.-Load losses on the ball valve. 34.-Load losses for an elbow of 45º. 35.-Load losses in a inclined T-junction. 36.-Study of laminar regime. 37.-Study of turbulent regime. Other possible practices: 38.-Sensors calibration. Practices to be done by PLC Module (PLC-PI)+PLC Control Software: 39.-Control of the AFTC unit process through the control interface box without the computer. 40.-Visualization of all the sensors values used in the AFTC unit process. 41.-Calibration of all sensors included in the AFTC unit process. 42.-Hand on of all the actuators involved in the AFTC unit process. 43.-Realization of different experiments, in automatic way, without having in front the unit. (This experiment can be decided previously). 44.-Simulation of outside actions, in the cases do not exist hardware elements. (Example: test of complementary tanks, complementary industrial environment to the process to be studied, etc). 45.-PLC hardware general use and manipulation. 46.-PLC process application for AFTC unit. 47.-PLC structure. 48.-PLC inputs and outputs configuration. 49.-PLC configuration possibilities. 50.-PLC program languages. 51.-PLC different programming standard languages (literal structured, graphic, etc.). 52.-New configuration and development of new process. 53.-Hand on an established process. 54.-To visualize and see the results and to make comparisons with the AFTC unit process. 55.-Possibility of creating new process in relation with the AFTC unit. 56.-PLC Programming Exercises. 57.-Own PLC applications in accordance with teacher and student requirements.   Fluid Mechanics Lab Equipments manufacturers....

Computer Controlled Fluid Friction in Pipes, with Hydraulics Bench- Engineering Lab Training Systems

EXERCISES AND PRACTICAL POSSIBILITIES Some Practical Possibilities of the Unit: 1.-  Load loss by friction in a rough pipe of 17 mm of interior diameter. 2.-  Load loss by friction in a rough pipe of 23 mm of interior diameter. 3.-  Load loss by friction in a smooth pipe of 6.5 mm of interior diameter. 4.-  Load loss by friction in a smooth pipe of 16.5 mm of interior diameter. 5.-  Load loss by friction in a smooth pipe of 26.5 mm of interior diameter. 6.-  Influence of the diameter in the load loss by friction in rough pipes. 7.-  Influence of the diameter in the load loss by friction in smooth pipes. 8.-  Load loss by friction in smooth and rough pipes. 9.-  Friction coefficient in a rough pipe of 17 mm of interior diameter. 10.-Friction coefficient in a rough pipe of 23 mm of interior diameter. 11.-Friction coefficient in a smooth pipe of 6.5 mm  of interior diameter. 12.-Friction coefficient in a smooth pipe of 16.5 mm of interior diameter. 13.-Friction coefficient in a smooth pipe of 26.5 mm of interior diameter. 14.-Influence of the diameter in the friction coefficient in rough pipes. 15.-Influence of the diameter in the friction coefficient in smooth pipes. 16.-Friction coefficient in smooth and rough pipes. 17.-Load losses in the inclined seat valve. 18.-Load losses in the floodgate valve. 19.-Load losses in the filter. 20.-Load losses in the membrane valve. 21.-Load losses in an abrupt broadening. 22.-Load losses in the venturimeter 23.-Load losses in the diaphragm. 24.-Load losses in an abrupt contraction. 25.-Load losses in the accessories. 26.-Flow measurements by load loss in a venturimeter. 27.-Flow measurements by load loss in a diaphragm. 28.-Flow measurements by means of load loss. 29.-Load losses in a symmetrical bifurcation. 30.-Load losses after two 90º elbows. 31.-Load losses in a T-junction. 32.-Load losses for a 90º elbows. 33.-Load losses on the ball valve. 34.-Load losses for an elbow of 45º. 35.-Load losses in a inclined T-junction. 36.-Study of laminar regime. 37.-Study of turbulent regime. Other possible practices: 38.-Sensors calibration. Practices to be done by PLC Module (PLC-PI)+PLC Control Software: 39.-Control of the AFTC unit process through the control interface box without the computer. 40.-Visualization of all the sensors values used in the AFTC unit process. 41.-Calibration of all sensors included in the AFTC unit process. 42.-Hand on of all the actuators involved in the AFTC unit process. 43.-Realization of different experiments, in automatic way, without having in front the unit. (This experiment can be decided previously). 44.-Simulation of outside actions, in the cases donot exist hardware elements. (Example: test of complementary tanks, complementary industrial environment to the process to be studied, etc). 45.-PLC hardware general use and manipulation. 46.-PLC process application for AFTC unit. 47.-PLC structure. 48.-PLC inputs and outputs configuration. 49.-PLC configuration possibilities. 50.-PLC program languages. 51.-PLC different programming standard languages (literal structured, graphic, etc.). 52.-New configuration and development of new process. 53.-Hand on an established process. 54.-To visualize and see the results and to make comparisons with the AFTC unit process. 55.-Possibility of creating new process in relation with the AFTC unit. 56.-PLC Programming Exercises. 57.-Own PLC applications in accordance with teacher and student requirements.   Fluid Mechanics Lab Equipments manufacturers....

Computer Controlled Francis Turbine- Engineering Lab Training Systems

EXERCISES AND PRACTICAL POSSIBILITIES Some Practical Possibilities of the Unit: 1.-To determine the operating characteristics of a Francis turbine at different speeds. 2.-Determination of typical turbine curves. 3.-Determination of the Francis turbine’s power N(n), Torque Mm(n) and efficiency  h(n) curves at constant flow with guide vanes open. 4.-Determination of the Francis turbine’s power N(n), Torque Mm(n) and efficiency  h(n) curves at constant flow with guide vanes closed. 5.-Determination of the power N(Q), Head H(Q) and efficiency h(Q) curves at constant rotation speed and guide vanes opened. 6.-Determination of the power N(Q), Head H(Q) and efficiency h(Q) curves at constant rotation speed and guide vanes closed. 7.-Turbine power output versus speed and flow rate at various heads. 8.-Effect of guide vane setting on the turbine performance. 9.-Investigation of the conversion of hydraulic energy into mechanical energy. 10.-Adimensional analysis. 11.-Calculating the turbine power. 12.-Determining the turbine hydraulic efficiency. 13.-  Determining the torque and speed of the turbine. 14.-Flow calculation. Other possible practices: 15.-Sensors calibration. Practices to be done by PLC Module (PLC-PI)+PLC Control Software: 16 -Control of the TFC unit process through the control interface box without the computer. 17.-Visualization of all the sensors values used in the TFC unit process. 18.-Calibration of all the sensors included in the TFC unit process. 19.-Hand on of all the actuators involved in the TFC unit process. 20.-Realization of different experiments, in automatic way, without having in front the unit. (This experiment can be decided previously). 21.-Simulation of outside actions, in the cases do not exist hardware elements. (Example: test of complementary tanks, complementary   industrial environment to process to be studied, etc). 22.-PLC hardware general use and manipulation. 23.-PLC process application for TFC unit. 24.-PLC structure. 25.-PLC inputs and outputs configuration. 26.-PLC configuration possibilities. 27.-PLC program languages. 28.-PLC different programming standard languages. 29.-New configuration and development of new process. 30.-Hand on an established process. 31.-To visualize and see the results and to make comparisons with the TFC unit process. 32.-Possibility of creating new process in relation with the TFC unit. 33.-PLC Programming Exercises. 34-Own PLC applications in accordance with teacher and student requirements.    Fluid Mechanics Lab Equipments manufacturers....

Computer Controlled Gear Pump Bench- Engineering Lab Training Systems

EXERCISES AND PRACTICAL POSSIBILITIES

Some Practical Possibilities of the Unit:

1.-Demonstration of a gear pump in operation.

2.-Obtaining of curves H(Q), N(Q), Efficiency (Q) of the gear pump.

3.-Simultaneous representation of H(Q), N(Q) and Efficiency (Q).

4.-Adimensional study of magnitudes H*, N* and Q*.

5.-Determination of the curve H vs Q at different r.p.m.

6.-Determination of the mechanical power vs flow at different r.p.m.

7.-Determination of the efficiency curve vs the flow at different r.p.m.

8.-Determination of the map of a gear pump.

Other possible practices:

9.-Sensors Calibration.

Practices to be done by PLC Module (PLC-PI)+PLC Control Software:

10.-Control of the PBEC unit process through the control interface box without the computer.

11.-Visualization of all the sensors values used in the PBEC unit process.

12.-Calibration of all sensors included in the PBEC unit process.

13.-Hand on of all the actuators involved in the PBEC unit process.

14.-Realization of different experiments, in automatic way, without having in front the unit. (This experiment can be decided previously).

15.-Simulation of outside actions, in the cases do
not exist hardware elements. (Example: test of complementary tanks, complementary industrial environment to the process to be studied, etc).

16.-PLC hardware general use and manipulation.

17.-PLC process application for PBEC unit.

18.-PLC structure.

19.-PLC inputs and outputs configuration.

20.-PLC configuration possibilities.

21.-PLC program languages.

22.-PLC different programming standard languages.

23.-New configuration and development of new process.

24.-Hand on an established process.

25.-To visualize and see the results and to make comparisons with the PBEC unit process.

26.-Possibility of creating new process in relation with the PBEC unit.

27.-PLC Programming Exercises.

Computer Controlled Hydrologic Systems, Rain Simulator and Irrigation Systems Unit- Engineering Lab Training Systems

EXERCISES AND PRACTICAL POSSIBILITIES Some Practical Possibilities of the Unit: 1.-      Determination of the superficial dragging. 2.-      Hydrograph curve, strong storm. 3.-      Calculation of concentration time for a shortstorm. 4.-      Storm hydrographs from single or multiple storms. 5.-  Storm hydrograph from a previously saturated catchment. 6.-       Storm runoff from an impermeable catchment. 7.-       Drainage density determination. 8.-       Effect of a moving storm flood hydrograph. 9.-      Effect of a reservoir  storage on flood hydrograph. 10.-    Effect of land drains on flood hydrograph. 11.-    Reservoir filling and flooding. 12.-    Gravity force of water. 13.-    Fluvial-mechanical experiments. 14.-    Model stream flow in alluvial material. 15.-    Sediment transport in river models. 16.-     Formation and development of river features over time. 17.-     Meandering river. 18.-     Erosion on river beds and current speed. 19.-  Sediment transport, bedload motion, scour and erosion. 20.-     Underground water capture studies. 21.-     Well depression cone. 22.-   Interaction of depression cones by two adjoining wells. 23.-     Well in the centre of a circular island. 24.-  Draw-down curves for one well and two wells systems. Other possible practices: 25.-     Sensors calibration. Practices to be done by PLC Module (PLC-PI)+PLC Control Software: 26.-  Control of the ESHC unit process through the control interface box without the computer. 27.-   Visualization of all the sensors values used in the ESHC unit process. 28.-   Calibration of all sensors included in the ESHC unit process. 29.-    Hand on of all the actuators involved in the ESHC unit process.                    Fluid Mechanics Lab Equipments manufacturers....

Computer Controlled Hydrologic Systems, Rain Simulator and Irrigation Systems Unit- Engineering Lab Training Systems

EXERCISES AND PRACTICAL POSSIBILITIES Some Practical Possibilities of the Unit: 1.-       Determination of the superficial dragging. 2.-       Hydrograph curve, strong storm. 3.-       Calculation of concentration time for a short storm. 4.-       Storm hydrographs from single or multiple storms. 5.-  Storm hydrograph from a previously saturated catchment. 6.-       Storm runoff from an impermeable catchment. 7.-       Drainage density determination. 8.-       Effect of a moving storm flood hydrograph. 9.-       Effect of a reservoir  storage on flood hydrograph. 10.-    Effect of land drains on flood hydrograph. 11.-    Reservoir filling and flooding. 12.-    Gravity force of water. 13.-    Fluvial-mechanical experiments. 14.-    Model stream flow in alluvial material. 15.-    Sediment transport in river models. 16.-  Formation and development of river features over time. 17.-    Meandering river. 18.-    Erosion on river beds and current speed. 19.- Sediment transport, bedload motion, scour and erosion. 20.-    Underground water capture studies. 21.-    Well depression cone. 22.-  Interaction of depression cones by two adjoining wells. 23.-    Well in the centre of a circular island. 24.-  Draw-down curves for one well and two wells systems.                                     Fluid Mechanics Lab Equipments manufacturers....

Computer Controlled Kaplan Turbine- Engineering Lab Training Systems

EXERCISES AND PRACTICAL POSSIBILITIES Some Practical Possibilities of the Unit: 1.-   To determine the operating characteristics of a Kaplan turbine at different velocities. 2.-   Determination of the typical turbine curves. 3.-   Turbine power output versus speed and flow rate at various heads. 4.-   Effect of guide vane setting on turbine performance. 5.-   Flow calculation. 6.-   Adimensional analysis. 7.-   Investigation of the conversion of hydraulic energy into mechanical energy. 8.-   Determining the hydraulic turbine efficiency. 9.-   Calculating the turbine power. 10.- Determining the hydraulic turbine efficienciy. Other possible practices: 11.- Sensors calibration. Practices to be done by PLC Module (PLC-PI)+PLC Control Software: 12.- Control of the TKC unit process through the control interface box without the computer. 13.- Visualization of all the sensors values used in the TKC unit process. 14.- Calibration of all sensors included in the TKC unit process. 15.- Hand on of all the actuators involved in the TKC unit process. 16.- Realization of different experiments, in automatic way, without having in front the unit. (This experiment can be decided previously) 17.- Simulation of outside actions, in the cases do not exist hardware elements. (Example: test of complementary tanks, complementary industrial environment to the process to be studied, etc) 18.- PLC hardware general use and manipulation. 19.- PLC process application for TKC unit. 20.- PLC structure. 21.- PLC inputs and outputs configuration. 22.- PLC configuration possibilities. 23.- PLC program languages. 24.- PLC different programming standard languages (literal structured, graphic, etc.). 25.- New configuration and development of new process. 26.- Hand on an established process. 27.- To visualize and see the results and to make comparisons with the TKC unit process. 28.- Possibility of creating new process in relation with the TKC unit. 29.- PLC Programming Exercises. 30.- Own PLC applications in accordance with teacher and student requirements.  Fluid Mechanics Lab Equipments manufacturers....

Computer Controlled Multipump Testing Bench- Engineering Lab Training Systems

Exercises and Practical Possibilities to be done with Main Items  1.-Determination of the flow by a weir of thin wall in a U-shape. 2.-Determination of the unloading coefficient of a weir of thin wall in a U-shape. 3.-Determination of the curve Q vs r.p.m. for the centrifugal pump. 4.-Determination of the curve Q vs r.p.m. for the gear pump. 5.-Determination of the curve H vs Q for different r.p.m. for the centrifugal pump. 6.-Determination of the curve H vs Q for different r.p.m. for the gear pump. 7.-Determination of the mechanical power vs flow for different r.p.m. for the centrifugal pump. 8.-Determination of the mechanical power vs flow for different r.p.m. for the gear pump. 9.-Determination of the curve h vs the flow for different r.p.m. for the centrifugal pump. 10.-Determination of the curve h vs the flow for different r.p.m. for the gear pump. 11.-Determination of the map of a centrifugal pump. 12.-Determination of the map of a gear pump. 13.-Determination of the adimensional characteristic curves for the different pumps. 14.-Determination of the specific speed for the different pumps. 15.-Verification of the similarity rules for pumps of different geometry. Additional practical possibilities: 16.-Sensors calibration. Other possibilities to be done with this Unit: 17.-Many students view results simultaneously. To view all results in real time in the classroom by means of a projector or an electronic blackboard. 18.-Open Control, Multicontrol and Real Time Control. This unit allows intrinsically and/or extrinsically to change the span, gains; proportional, integral, derivate parameters; etc in real time. 19.-The Computer Control System with SCADA allows a real industrial simulation. 20.-This unit is totally safe as uses mechanical, electrical and electronic, and software safety devices. 21.-This unit can be used for doing applied research. 22.-This unit can be used for giving training courses to Industries even to other Technical Education Institutions. 23.-Control of the PB2C unit process through the control interface box without the computer. 24.-Visualization of all the sensors values used in the PB2C unit process. - By using PLC-PI additional 19 more exercises can be done. - Several other exercises can be done and designed by the user.                                Fluid Mechanics Lab Equipments manufacturers....

Computer Controlled Multipump Testing Bench.- Engineering Lab Training Systems

Exercises and Practical Possibilities to be done with Main Items 1.-Determination of the flow by a weir of thin wall in U-shape. 2.-Determination of unloading coefficient of a weir of thin wall in a U-shape. 3.-Determination of the curve Q vs r.p.m. for the centrifugal pump. 4.-Determination of the curve Q vs r.p.m. for the peripherical pump. 5.-Determination of the curve Q vs r.p.m. for the gear pump. 6.-Determination of the curve Q vs r.p.m. for the axial pump. 7.-Determination of the curve H vs Q for different r.p.m. for the centrifugal pump. 8.-Determination of the curve H vs Q for different r.p.m. for the peripherical pump. 9.-Determination of the curve H vs Q for different r.p.m. for the gear pump. 10.-Determination of the curve H vs Q for different r.p.m. for the axial pump. 11.-Determination of the mechanical power vs flow for different r.p.m. for the centrifugal pump. 12.-Determination of the mechanical power vs flow for different r.p.m. for the gear pump. 13.-Determination of the mechanical power vs flow for different r.p.m. for the peripherical pump. 14.-Determination of the mechanical power vs flow for different r.p.m. for the axial pump. 15.-Determination of the curve h vs the flow for different r.p.m. for the centrifugal pump.           16.-Determination of the curve h vs the flow for different r.p.m. for the peripherical pump. 17.-Determination of the curve h vs the flow for different r.p.m. for the gear pump. 18.-Determination of the curve h vs the flow for different r.p.m. for the axial pump. 19.-Determination of the map of a centrifugal pump. 20.-Determination of the map of a peripherical pump. 21.-Determination of the map of a gear pump. 22.-Determination of the map of an axial pump. 23.-Determination of the adimenssional characteristic curves for different types of pumps. 24.-Determination of the specific speed of different types of pumps. 25.-Verification of the similarity rules for pumps of different geometry. Additional practical possibilities: 26.-Sensors calibration. Other possibilities to be done with this Unit: 27.-Many students view results simultaneously. To view all results in real time in the classroom by means of a projector or an electronic blackboard. 28.-Open Control, Multicontrol and Real Time Control. This unit allows intrinsically and/or extrinsically to change the span, gains; proportional, integral, derivate parameters; etc in real time. 29.-The Computer Control System with SCADA allows a real industrial simulation. 30.-This unit is totally safe as uses mechanical, electrical and electronic, and software safety devices. 31.-This unit can be used for doing applied research. 32.-This unit can be used for giving training courses to Industries even to other Technical Education Institutions. 33.-Control of the PBOC unit process through the control interface box without the computer. 34.-Visualization of all the sensors values used in the PBOC unit process. - By using PLC-PI additional 19 more exercises can be done. - Several other exercises can be done and designed by the user.                            Fluid Mechanics Lab Equipments manufacturers....

Computer Controlled Pipe Network Unit, with Hydraulics Bench- Engineering Lab Training Systems

EXERCISES AND PRACTICAL POSSIBILITIES Some Practical Possibilities of the Unit: 1.-  Head losses in a PVC pipe. 2.-  Head losses in an aluminium pipe. 3.-  Head losses in a methacrylate pipe. 4.-  Study of head losses in pipes of the same material. 5.-  Study of head losses in function of the material. 6.-  Friction coefficient in a PVC pipe. 7.-  Friction coefficient in an aluminium pipe. 8.-  Friction coefficient in a methacrylate pipe. 9.-  Study of the friction coefficient in function of the material. 10.- Study of the friction coefficient in function of the diameter. 11.- Parallel network configuration for pipes of same material and different diameter. 12.- Parallel network configuration for pipes of different material and same diameter. 13.- Series network configuration for pipes of different material and different diameter. 14.- Series network configuration for pipes of different material and same diameter. 15.- Characteristics of a circular circuit. 16.- Double piping circuit. Other possible practices: 17.- Sensors calibration. Practices to be done by PLC Module (PLC-PI)+PLC Control Software: 18.- Control of the AMTC unit process through the control interface box without the computer. 19.- Visualization of all the sensors values used in the AMTC unit process. 20.- Calibration of all sensors included in the AMTC unit process. 21.- Hand on of all the actuators involved in the AMTC unit process. 22.- Realization of different experiments, in automatic way, without having in front the unit. (This experiment can be decided previously). 23.- Simulation of outside actions, in the cases do not exist hardware elements. (Example: test of complementary tanks, complementary industrial environment to the process to be studied, etc). 24.- PLC hardware general use and manipulation. 25.- PLC process application for AMTC unit. 26.- PLC structure. 27.- PLC inputs and outputs configuration. 28.- PLC configuration possibilities. 29.- PLC program languages. 30.- PLC different programming standard languages. 31.- New configuration and development of new process. 32.- Hand on an established process. 33.- To visualize and see the results and to make comparisons with the AMTC unit process. 34.- Possibility of creating new process in relation with the AMTC unit. 35.- PLC Programming Exercises. 36.- Own PLC applications in accordance with teacher and student requirements.  Fluid Mechanics Lab Equipments manufacturers....

Computer Controlled Piston Pump Bench- Engineering Lab Training Systems

EXERCISES AND PRACTICAL POSSIBILITIES Some Practical Possibilities of the Unit: 1.- Demonstration of a piston pump in operation. 2.-  Measurement of plunger displacement. 3.-  Measurement of cylinder pressure. 4.-  Measurement of pump outlet pressure. 5.-  Measurement of the volumetric efficiency. 6.-  Obtain the curves of the pump H(n), N(n). 7.-  Obtain the pump map. 8.-  Study of safety valve for overpressure in operation. 9.-  Study of the pressures influence at the exit when the piston pump works with a damping chamber. 10.-Pump efficiency calculation. 11.-Study of the effect to incorporate the damping chamber. Other possible practices: 12.-Sensors calibration. Practices to be done by PLC Module (PLC-PI)+PLC Control Software: 13.-Control of the PBRC unit process through the control interface box without the computer. 14.-Visualization of all the sensors values used in the PBRC unit process. 15.-Calibration of all sensors included in the PBRC unit process. 16.-Hand on of all the actuators involved in the PBRC unit process. 17.-Realization of different experiments, in automatic way, without having in front the unit. (This experiment can be decided previously). 18.-Simulation of outside actions, in the cases do not exist hardware elements. (Example: test of complementary tanks, complementary industrial environment to the process to be studied, etc). 19.-PLC hardware general use and manipulation. 20.-PLC process application for PBRC unit. 21.-PLC structure. 22.-PLC inputs and outputs configuration. 23.-PLC configuration possibilities. 24.-PLC program languages. 25.-PLC different programming standard languages (literal structured, graphic, etc.). 26.-New configuration and development of new process. 27.-Hand on an established process. 28.-To visualize and see the results and to make comparisons with the PBRC unit process. 29.-Possibility of creating new process in relation with the PBRC unit. 30.-PLC Programming Exercises. 31.-Own PLC applications in accordance with teacher and student requirements.  Fluid Mechanics Lab Equipments manufacturers....

Computer Controlled Radial Flow Turbine- EngineeringTraining Systems Lab

EXERCISES AND PRACTICAL POSSIBILITIES Some Practical Possibilities of the Unit....

Computer Controlled Series/Parallel Pumps Bench- Engineering Lab Training Systems

Exercises and Practical Possibilities to be done with Main Items 1.-Obtaining of curves H (Q), N (Q), Eff% (Q). 2.-Three simultaneous representatios of H (Q), N (Q) and Eff% (Q). 3.-Obtaining of the map of a centrifugal pump. 4.-Adimensional study of magnitudes H*, N* and Q*. 5.-Cavitation test and obtaining of curves NPSHr. 6.-Series coupling of two pumps with same characteristics. 7.-Series coupling of two pumps of different characteristics. 8.-Parallel coupling of two pumps with same characteristics. 9.-Parallel coupling of two pumps of different characteristics. Additional practical possibilities: 10.-Sensors calibration. Other possibilities to be done with this Unit: 11.-Many students view results simultaneously. To view all results in real time in the classroom by means of a projector or an electronic blackboard. 12.-Open Control, Multicontrol and Real Time Control. This unit allows intrinsically and/or extrinsically to change the span, gains; proportional, integral, derivate parameters; etc in real time. 13.-The Computer Control System with SCADA allows a real industrial simulation. 14.-This unit is totally safe as uses mechanical, electrical and electronic, and software safety devices. 15.-This unit can be used for doing applied research. 16.-This unit can be used for giving training courses to Industries even to other Technical Education Institutions. 17.-Control of the PBSPC unit process through the control interface box without the computer. 18.-Visualization of all the sensors values used in the PBSPC unit process. - By using PLC-PI additional 19 more exercises can be done. - Several other exercises can be done and designed by the user.                              Fluid Mechanics Lab Equipments manufacturers....

Computer Controlled Water Hammer Unit- Engineering Lab Training Systems

Exercises and Practical Possibilities to be done with Main Items 1.-    Characterization of the water hammer phenomenon in pipes. 2.-    Subduing the water hammer effects. 3.-    Calculation of energy losses in pipes. 4.-    Influences of  the pipe diameter on the speed propagation. 5.-    Subduing of the effects of the water hammer through abrupt expansions. Additional practical possibilities: 6.-     Sensors calibration. Other possibilities to be done with this Unit: 7.-    Many students view results simultaneously.         To view all results in real time in the classroom by means of a projector or an electronic blackboard. 8.-    Open Control, Multicontrol and Real Time Control.         This unit allows intrinsically and/or extrinsically to change the span, gain; proportional, integral, derivate parameters; etc in real time. 9.-    The Computer Control System with SCADA allows a real industrial simulation. 10.-  This unit is totally safe as uses mechanical, electrical and electronic, and software safety devices. 11.-  This unit can be used for doing applied research. 12.-  This unit can be used for giving training courses to Industries even to other Technical Education Institutions. 13.-  Control of the EGAC unit process through the control interface box without the computer. 14.-  Visualization of all the sensors values used in the EGAC unit process. - By using PLC-PI additional 19 more exercises can be done. - Several other exercises can be done and designed by the user.                              Fluid Mechanics Lab Equipments manufacturers....

Computer Controlled Water Tunnel- Engineering Lab Training Systems

DESCRIPTION Water tunnel of 500*500mm, principal characteristics: * Adequate Size for flow visualizations on standard models of planes. * Useful for teaching and development projects. * Top quality vein, uniformity and low turbulence level. * Low operation and maintenance cost.  SPECIFICATIONS  *The water tunnel of 500*500 mm, of low turbulence level, is specifically designed for carrying out visualization tests on threedimensional models, though, of course, they can also be used on two-dimensional models. *As it is a closed circuit, it operates continuously and uses the same water, although it may be necessary to renew it once it has lost its transparency due to the use of colorings. However, if the technique of the hydrogen bubble is used as tracer this problem can also be avoided. *Its dimensions and low operating costs make it suitable for teaching as well as for research or industrial use. Assorted systems for registering images and taking measurements can be incorporated when necessary.                                                  Fluid Mechanics Lab Equipments manufacturers....

Computer Determination of Gravitational Constant Via Cavendish Balance

Computer Determination of Gravitational Constant Via Cavendish Balance Ministerial Tender Board Equipment, Ministry of Education and Vocational Training Lab Tenders Suppliers India....

Computer Integrated Manufacturing (CIM) upgrade to the CNC machine

Computer Integrated Manufacturing (CIM) upgrade to the CNC machine....

Computer Interfaced Fluid Machines

Computer Interfaced Fluid Machines....

Computer Interfacing Board Trainer

Computer Interfacing Board Trainer....

Computer Maintenance Tool Kit

Computer Maintenance Tool Kit....

Computer Servor

Computer Servor....

Computer with CAD Software

Computer with CAD Software....

Computerised System for Electrical Measurement

Computerised System for Electrical Measurement....

Computerized Brinell Hardness Testing Machine For Testing Lab

Computerized Brinell Hardness Testing Machine....

Computerized Electrical Measurement System Complete With Software

Computerized Electrical Measurement System Complete With Software....

Computerized Embroidery Machine

Computerized Embroidery Machine....

Computerized embroidery machine

Computerized embroidery machine....

Computerized Hardness Testing Machine

Computerized Hardness Testing Machine from India....

Computerized Servo Control Version For Testing Lab

Computerized Servo Control Version....

Computerized Single Cylinder Diesel Engine Test Setup

Computerized Single Cylinder Diesel Engine Test Setup....

Computerized Tensile Testing Machine

Computerized Tensile Testing Machine from India....

Computerized Universal Testing Machine

Computerized Universal Testing Machine from India....

Computerized Universal Testing Machine For Testing Lab

Computerized Universal Testing Machine....

Computerized Wheel Balancing Machine

Computerized Wheel Balancing Machine....

Concatenation globe

Concatenation globe....

Concave Mirror Glass

Concave Mirror Glass....

Concentric Tube Heat Exchanger PC- Engineering Lab Training Systems

Concentric Tube Heat Exchanger PC- Engineering Lab Training Systems....

Conch

Conch....