K Sridhara scite author profile

K Sridhara

5Publications

22Citation Statements Received

19Citation Statements Given

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Affiliations

Turbo Power Systems (United Kingdom)

Publications

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A comparative study of the performance of the mixed flow and radial flow variable geometry turbines for an automotive turbocharger

Ramesh

Prasad

Sridhara³

2018

Proceedings of the Institution of Mechanical Engineers, Part C:

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A new design of a mixed flow variable geometry turbine is developed for the turbocharger used in diesel engines having the cylinder capacity from 1.0 to 1.5 L. An equivalent size radial flow variable geometry turbine is considered as the reference for the purpose of bench-marking. For both the radial and mixed flow turbines, turbocharger components are manufactured and a test rig is developed with them to carry out performance analysis. Steady-state turbine experiments are conducted with various openings of the nozzle vanes, turbine speeds, and expansion ratios. Typical performance parameters like turbine mass flow parameter, combined turbine efficiency, velocity ratio, and specific speed are compared for both mixed flow variable geometry turbine and radial flow variable geometry turbine. The typical value of combined turbine efficiency (defined as the product of isentropic efficiency and the mechanical efficiency) of the mixed flow variable geometry turbine is found to be about 25% higher than the radial flow variable geometry turbine at the same mass flow parameter of 1425 kg/s √K/bar m2 at an expansion ratio of 1.5. The velocity ratios at which the maximum combined turbine efficiency occurs are 0.78 and 0.825 for the mixed flow variable geometry turbine and radial flow variable geometry turbine, respectively. The values of turbine specific speed for the mixed flow variable geometry turbine and radial flow variable geometry turbine respectively are 0.88 and 0.73.

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Numerical analysis and experimental verification of the radial growth of a turbocharger centrifugal compressor impeller

Subramani¹,

Ramamurti

Sridhara³

1997

The Journal of Strain Analysis for Engineering Design

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Steady state stress analysis was carried out on a typical automotive turbocharger centrifugal compressor impeller using the finite element method and the concept of cyclic symmetry. Since the rotational speed of the impeller is very high and the size of the impeller is quite small, experimental verification of the stresses is extremely difficult. A novel method of measuring the radial growth of the impeller tip has been presented and a suitable instrumentation was designed and developed. This paper describes the numerical and experimental work carried out on a centrifugal compressor impeller

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Performance Evaluation of a Small Agricultural Engine Operated on Dual Fuel (Diesel + Natural Gas) System

Balasubramanian¹,

Sridhara²,

Ganesan

1995

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Transient performance of the mixed flow and radial flow variable geometry turbines for an automotive turbocharger

Kannan

Prasad

Sridhara³

2020

Proceedings of the Institution of Mechanical Engineers, Part C:

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In our previous paper, the steady-state test results of a mixed flow turbine with variable nozzle vanes for a turbocharger are reported. In this paper, the transient response of the same mixed flow turbine along with that of a similarly sized radial flow turbine is presented. The turbine size is suitable for handling the flow capacity of the diesel engines with swept volume up to 1.5 L. The previous experimental test set up is modified by adding a quick-release valve – actuation system before the turbine inlet to obtain a transient response. The radial and mixed flow turbines are tested for different turbine inlet pressures and for various opening positions of the nozzle vanes while matching the turbine mass flow parameters between radial and mixed flow turbines. Typically at nozzle vane openings corresponding to 50% mass flow parameter and 1.5 bar (abs) pressure at the inlet to the turbine, the transient response time for the turbine with mixed flow variable nozzle vanes configuration is about 0.770 s, as compared to 0.858 s for the turbine with radial flow variable nozzle vanes configuration.

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Free vibration analysis of a turbocharger centrifugal compressor impeller

Ramamurti

Subramani²,

Sridhara³

1995

Mechanism and Machine Theory

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K Sridhara

A comparative study of the performance of the mixed flow and radial flow variable geometry turbines for an automotive turbocharger

Numerical analysis and experimental verification of the radial growth of a turbocharger centrifugal compressor impeller

Performance Evaluation of a Small Agricultural Engine Operated on Dual Fuel (Diesel + Natural Gas) System

Transient performance of the mixed flow and radial flow variable geometry turbines for an automotive turbocharger

Free vibration analysis of a turbocharger centrifugal compressor impeller

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