Simulation of hybrid propulsion system using LSRG and single cylinder engine

Ablative-cooled hybrid rockets could potentially combine a similar versatility of a liquid propulsion system with a much simplified architecture. These characteristics make this kind of propulsion attractive, among others, for applications such as satellites and upper stages. In this paper, the use of hybrid rockets for those situations is reviewed. It is shown that, for a competitive implementation, several challenges need to be addressed, which are not the general ones often discussed in the hybrid literature. In particular, the optimal thrust to burning time ratio, which is often relatively low in liquid engines, has a deep impact on the grain geometry, that, in turn, must comply some constrains. The regression rate sometime needs to be tailored in order to avoid unreasonable grain shapes, with the consequence that the dimensional trends start to follow some sort of counter-intuitive behavior. The length to diameter ratio of the hybrid combustion chamber imposes some packaging issues in order to compact the whole propulsion system. Finally, the heat soak-back during long off phases between multiple burns could compromise the integrity of the case and of the solid fuel. Therefore, if the advantages of hybrid propulsion are to be exploited, the aspects mentioned in this paper shall be carefully considered and properly faced.

Download Full-text

Mathematical modelling of a gas turbine engine based hybrid propulsion system for regional airplanes

Journal of Physics Conference Series ◽

10.1088/1742-6596/1891/1/012001 ◽

2021 ◽

Vol 1891 (1) ◽

pp. 012001

Author(s):

Y A Ravikovich ◽

A B Agulnik ◽

D P Kholobtsev ◽

D A Borovikov

Keyword(s):

Mathematical Modelling ◽

Gas Turbine ◽

Gas Turbine Engine ◽

Propulsion System ◽

Hybrid Propulsion ◽

Turbine Engine

Download Full-text

A novel hybrid aircraft propulsion based on the DEA compressor—Part A: Design

Proceedings of the Institution of Mechanical Engineers Part G Journal of Aerospace Engineering ◽

10.1177/09544100211025349 ◽

2021 ◽

pp. 095441002110253

Author(s):

Babak Aryana

Keyword(s):

High Performance ◽

Static Condition ◽

Propulsion System ◽

Hybrid Propulsion ◽

Pulse Detonation ◽

Low Emission ◽

Wide Range ◽

Exit Nozzle ◽

Distributed Propulsion ◽

Detonation Process

This two-part article introduces a novel hybrid propulsion system based on the DEA compressor. The system encompasses a Pulse Detonation TurboDEA as the master engine that supplies several full-electric ancillary thrusters called DEAThruster. The system, called the propulsion set, can be categorized as a distributed propulsion system based on the design mission and number of ancillary thrusters. Part A of this article explains the design process comprising intake, compressor, detonation process, diffuser, axial turbine, and the exit nozzle. The main target is to design a high-performance low emission propulsion system capable of serving in a wide range of altitudes and flight Mach numbers that covers altitudes up to 20,000 m and flight Mach number up to the hypersonic edge. Designing the propulsion set, the design point is considered at the static condition in the sea level. Design results show the propulsion set can satisfy all requirements necessary for its mission.

Download Full-text

A Transient Single Cylinder Test System for Engine Research and Control Development

Dynamic Systems and Control, Parts A and B ◽

10.1115/imece2005-81323 ◽

2005 ◽

Cited By ~ 3

Author(s):

John L. Lahti ◽

Matthew W. Snyder ◽

John J. Moskwa

Keyword(s):

Test System ◽

Intake Manifold ◽

Test Accuracy ◽

Test Configuration ◽

Single Cylinder ◽

Cylinder Test ◽

Single Cylinder Engine ◽

Wide Range ◽

Reduce Development Time ◽

High Bandwidth

A transient test system was developed for a single cylinder research engine that greatly improves test accuracy by allowing the single cylinder to operate as though it were part of a multi-cylinder engine. The system contains two unique test components: a high bandwidth transient hydrostatic dynamometer, and an intake airflow simulator. The high bandwidth dynamometer is used to produce a speed trajectory for the single cylinder engine that is equivalent to that produced by a multi-cylinder engine. The dynamometer has high torque capacity and low inertia allowing it to simulate the speed ripple of a multi-cylinder engine while the single cylinder engine is firing. Hardware in loop models of the drivetrain and other components can be used to test the engine as though it were part of a complete vehicle, allowing standardized emissions tests to be run. The intake airflow simulator is a specialized intake manifold that uses solenoid air valves and a vacuum pump to draw air from the manifold plenum in a manner that simulates flow to other engine cylinders, which are not present in the single cylinder test configuration. By regulating this flow from the intake manifold, the pressure in the manifold and the flow through the induction system are nearly identical to that of the multi-cylinder application. The intake airflow simulator allows the intake runner wave dynamics to be more representative of the intended multi-cylinder application because the appropriate pressure trajectory is maintained in the intake manifold plenum throughout the engine cycle. The system is ideally suited for engine control development because an actual engine cylinder is used along with a test system capable of generating a wide range of transient test conditions. The ability to perform transient tests with a single cylinder engine may open up new areas of research exploring combustion and flow under transient conditions. The system can also be used for testing the engine under conditions such as cylinder deactivation, fuel cut-off, and engine restart. The improved rotational dynamics and improved intake manifold dynamics of the test system allow the single cylinder engine to be used for control development and emissions testing early in the engine development process. This can reduce development time and cost because it allows hardware problems to be identified before building more expensive multi-cylinder engines.

Download Full-text