Optimum Range for Prop-Driven Aircraft in Cruising Phase Solution

STEP 0: Pre-Calculation Summary
Formula Used
Optimum Range of Aircraft = (Propeller Efficiency*Maximum Lift-to-Drag Ratio of Aircraft)/Power Specific Fuel Consumption*ln(Weight of Aircraft at Beginning of Cruise Phase/Weight of Aircraft at End of Cruise Phase)
Ropt = (η*LDmaxratio)/c*ln(Wi/Wf)
This formula uses 1 Functions, 6 Variables
Functions Used
ln - The natural logarithm, also known as the logarithm to the base e, is the inverse function of the natural exponential function., ln(Number)
Variables Used
Optimum Range of Aircraft - (Measured in Meter) - Optimum Range of Aircraft is defined as the total distance (measured with respect to ground) traversed by the aircraft on a tank of fuel.
Propeller Efficiency - Propeller Efficiency is defined as power produced (propeller power) divided by power applied (engine power).
Maximum Lift-to-Drag Ratio of Aircraft - Maximum Lift-to-Drag Ratio of Aircraft refers to the highest ratio of lift force to drag force. It represents the optimal balance between lift and drag for maximum efficiency in level flight.
Power Specific Fuel Consumption - (Measured in Kilogram per Second per Watt) - Power Specific Fuel Consumption is a characteristic of the engine and defined as the weight of fuel consumed per unit power per unit time.
Weight of Aircraft at Beginning of Cruise Phase - (Measured in Kilogram) - Weight of Aircraft at Beginning of Cruise Phase is the weight of the plane just before going to cruise phase of the mission.
Weight of Aircraft at End of Cruise Phase - (Measured in Kilogram) - Weight of Aircraft at End of Cruise Phase is the weight before the loitering/descent/action phase of the mission plan.
STEP 1: Convert Input(s) to Base Unit
Propeller Efficiency: 0.93 --> No Conversion Required
Maximum Lift-to-Drag Ratio of Aircraft: 19.7 --> No Conversion Required
Power Specific Fuel Consumption: 0.6 Kilogram per Hour per Watt --> 0.000166666666666667 Kilogram per Second per Watt (Check conversion ​here)
Weight of Aircraft at Beginning of Cruise Phase: 514 Kilogram --> 514 Kilogram No Conversion Required
Weight of Aircraft at End of Cruise Phase: 350 Kilogram --> 350 Kilogram No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
Ropt = (η*LDmaxratio)/c*ln(Wi/Wf) --> (0.93*19.7)/0.000166666666666667*ln(514/350)
Evaluating ... ...
Ropt = 42243.4747386756
STEP 3: Convert Result to Output's Unit
42243.4747386756 Meter -->42.2434747386757 Kilometer (Check conversion ​here)
FINAL ANSWER
42.2434747386757 42.24347 Kilometer <-- Optimum Range of Aircraft
(Calculation completed in 00.011 seconds)

Credits

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Created by Vedant Chitte
All India Shri Shivaji Memorials Society's ,College of Engineering (AISSMS COE PUNE), Pune
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Verified by Anshika Arya
National Institute Of Technology (NIT), Hamirpur
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Preliminary Design Calculators

Optimum Range for Jet Aircraft in Cruising Phase
​ LaTeX ​ Go Range of Aircraft = (Velocity at Maximum Lift to Drag Ratio*Maximum Lift-to-Drag Ratio of Aircraft)/Power Specific Fuel Consumption*ln(Weight of Aircraft at Beginning of Cruise Phase/Weight of Aircraft at End of Cruise Phase)
Preliminary Take Off Weight Built-up for Manned Aircraft
​ LaTeX ​ Go Desired Takeoff Weight = Payload Carried+Operating Empty Weight+Fuel Weight to be Carried+Crew Weight
Preliminary Take off Weight Built-Up for Manned Aircraft given Fuel and Empty Weight Fraction
​ LaTeX ​ Go Desired Takeoff Weight = (Payload Carried+Crew Weight)/(1-Fuel Fraction-Empty Weight Fraction)
Fuel Fraction
​ LaTeX ​ Go Fuel Fraction = Fuel Weight to be Carried/Desired Takeoff Weight

Optimum Range for Prop-Driven Aircraft in Cruising Phase Formula

​LaTeX ​Go
Optimum Range of Aircraft = (Propeller Efficiency*Maximum Lift-to-Drag Ratio of Aircraft)/Power Specific Fuel Consumption*ln(Weight of Aircraft at Beginning of Cruise Phase/Weight of Aircraft at End of Cruise Phase)
Ropt = (η*LDmaxratio)/c*ln(Wi/Wf)

What is Range of Aircraft?

The maximal total range is the maximum distance an aircraft can fly between takeoff and landing, as limited by fuel capacity in powered aircraft, or cross-country speed and environmental conditions in unpowered aircraft. The range can be seen as the cross-country ground speed multiplied by the maximum time in the air. The fuel time limit for powered aircraft is fixed by the fuel load and rate of consumption. When all fuel is consumed, the engines stop and the aircraft will lose its propulsion.

How to Calculate Optimum Range for Prop-Driven Aircraft in Cruising Phase?

Optimum Range for Prop-Driven Aircraft in Cruising Phase calculator uses Optimum Range of Aircraft = (Propeller Efficiency*Maximum Lift-to-Drag Ratio of Aircraft)/Power Specific Fuel Consumption*ln(Weight of Aircraft at Beginning of Cruise Phase/Weight of Aircraft at End of Cruise Phase) to calculate the Optimum Range of Aircraft, The Optimum Range for Prop-Driven Aircraft in Cruising Phase refers to the maximum distance the aircraft can travel while minimizing fuel consumption, it represents the most fuel-efficient flight regime where the aircraft achieves the greatest distance for a given amount of fuel. Optimum Range of Aircraft is denoted by Ropt symbol.

How to calculate Optimum Range for Prop-Driven Aircraft in Cruising Phase using this online calculator? To use this online calculator for Optimum Range for Prop-Driven Aircraft in Cruising Phase, enter Propeller Efficiency (η), Maximum Lift-to-Drag Ratio of Aircraft (LDmaxratio), Power Specific Fuel Consumption (c), Weight of Aircraft at Beginning of Cruise Phase (Wi) & Weight of Aircraft at End of Cruise Phase (Wf) and hit the calculate button. Here is how the Optimum Range for Prop-Driven Aircraft in Cruising Phase calculation can be explained with given input values -> 42243.47 = (0.93*19.7)/0.000166666666666667*ln(514/350).

FAQ

What is Optimum Range for Prop-Driven Aircraft in Cruising Phase?
The Optimum Range for Prop-Driven Aircraft in Cruising Phase refers to the maximum distance the aircraft can travel while minimizing fuel consumption, it represents the most fuel-efficient flight regime where the aircraft achieves the greatest distance for a given amount of fuel and is represented as Ropt = (η*LDmaxratio)/c*ln(Wi/Wf) or Optimum Range of Aircraft = (Propeller Efficiency*Maximum Lift-to-Drag Ratio of Aircraft)/Power Specific Fuel Consumption*ln(Weight of Aircraft at Beginning of Cruise Phase/Weight of Aircraft at End of Cruise Phase). Propeller Efficiency is defined as power produced (propeller power) divided by power applied (engine power), Maximum Lift-to-Drag Ratio of Aircraft refers to the highest ratio of lift force to drag force. It represents the optimal balance between lift and drag for maximum efficiency in level flight, Power Specific Fuel Consumption is a characteristic of the engine and defined as the weight of fuel consumed per unit power per unit time, Weight of Aircraft at Beginning of Cruise Phase is the weight of the plane just before going to cruise phase of the mission & Weight of Aircraft at End of Cruise Phase is the weight before the loitering/descent/action phase of the mission plan.
How to calculate Optimum Range for Prop-Driven Aircraft in Cruising Phase?
The Optimum Range for Prop-Driven Aircraft in Cruising Phase refers to the maximum distance the aircraft can travel while minimizing fuel consumption, it represents the most fuel-efficient flight regime where the aircraft achieves the greatest distance for a given amount of fuel is calculated using Optimum Range of Aircraft = (Propeller Efficiency*Maximum Lift-to-Drag Ratio of Aircraft)/Power Specific Fuel Consumption*ln(Weight of Aircraft at Beginning of Cruise Phase/Weight of Aircraft at End of Cruise Phase). To calculate Optimum Range for Prop-Driven Aircraft in Cruising Phase, you need Propeller Efficiency (η), Maximum Lift-to-Drag Ratio of Aircraft (LDmaxratio), Power Specific Fuel Consumption (c), Weight of Aircraft at Beginning of Cruise Phase (Wi) & Weight of Aircraft at End of Cruise Phase (Wf). With our tool, you need to enter the respective value for Propeller Efficiency, Maximum Lift-to-Drag Ratio of Aircraft, Power Specific Fuel Consumption, Weight of Aircraft at Beginning of Cruise Phase & Weight of Aircraft at End of Cruise Phase and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
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