Orbital rockets are designed to reach the velocity required for an object to stay in orbit around a celestial body, such as Earth. The efficiency of a specific orbital rocket can be influenced by design parameters, operating conditions, and other factors. Achieving high propulsive efficiency is crucial for maximizing payload capacity and achieving mission objectives.
The propulsive efficiency is a crucial parameter in evaluating the performance of a rocket engine, indicating how well it converts propellant energy into useful thrust. Practical rocket engines often have propulsive efficiencies less than 100% due to factors like incomplete combustion, heat losses, and other inefficiencies in the propulsion system.
The propulsive efficiency () is defined by the following formula:
where,
- is the propulsive efficiency,
- is the thrust produced by the rocket engine,
- is the effective exhaust velocity of the rocket,
- ṁp is the mass flow rate of the propellants,
- is the specific impulse of the rocket engine,
- g0 is the acceleration due to gravity (approximately 9.81 m/s²).