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Compressible Flow Unit Didactic Equipment Vocational Training Equipment Fluid Mechanics Lab Equipment

Item No.: C1MKIII
Compressible Flow Unit Didactic Equipment Vocational Training Equipment Fluid Mechanics Lab Equipment
Description
C1MKIII Compressible Flow Unit Didactic Equipment Vocational Training Equipment Fluid Mechanics Lab Equipment

DESCRIPTION
The C1-MkIII equipment comprises a single-stage air compressor, complete with a test section and a throttling valve, plus an electronics console containing the necessary controls and instrumentation.
The single-stage compressor is driven by an integral three-phase AC motor. The compressor speed can be varied using an advanced torquevector frequency inverter, which gives stable and accurate speed control plus direct electronic read-out of the torque produced by the motor.
The compressor is fitted with an outlet duct incorporating a throttling valve, which allows the flow to be varied independent from compressor speed.
The equipment is supplied with a convergent-divergent test section, fitted at the compressor inlet, designed to produce Mach-1 velocity at the throat. The duct is fabricated from clear acrylic, enabling the student to see the construction and the proffles. A pressure-sensing ring tapping is provided at the inlet, at the throat and at the discharge end of the diffuser. This duct allows all the major concepts of compressible flow to be demonstrated.
The electronics console includes two high-range and two low-range differential pressure sensors plus a control for motor speed and displays for the compressor speed, the pressures and the motor torque.
TECHNICAL SPECIFICATIONS
Compressor speed: 3,300rpm (max)
No. stages: 1
Motor Power: 0.55kW
Sensors:
+/- 103.4 kPa x1
+/- 34 kPa x1
+/- 1744 Pa x2


EXPERIMENTAL CONTENT
Demonstrate the phenomenon of ‘choking’ in a convergent/divergent duct
Investigate the validity of the isentropic flow equations for compressible flow in a convergent duct
Demonstrate the effect of compressibility on flow equations for a convergent duct
To deduce a value of Specific Heat Ratio (γ) for air using the equation for isentropic flow in a convergent duct
Investigate pressure recovery along a divergent duct by measuring duct efficiency
Investigate the relation between friction loss & velocity for incompressible flow and to find an approximate value for the friction coefficient
To investigate the relation between the friction coefficient and the Reynolds number for a given pipe
Determine the friction coefficient for a case of compressible flow
Investigate the relation between the pressure recovery across a sudden enlargement and upstream flow velocity, assuming incompressible flow
To determine the coefficient of discharge
Investigate the validity of the formula for the pressure rise across a sudden enlargement for compressible flow
To investigate, for incompressible flow, the relation between the flow rate through and the pressure drop across, a pipeline orifice.
To determine the relationship between the coefficient of discharge and the ratio (n) for the pipeline orifice
Investigate the effects of compressibility on discharge coefficients
To investigate the variation of pressure rise, power input and isothermal efficiencies of a centrifugal compressor with mass flow rate at constant speed
Produce a performance characteristic using mass flow rate and pressure rise as parameters, with contours of constant speed and constant efficiency
Account for the energy provided by the compressor driving motor
To investigate the relationship between fluid velocity and pressure drop (head loss) along a 90° smooth bend
Investigate whether the pressure varies radially across a bend