Brayton Cycle Efficiency Calculator
Find the ideal thermal efficiency of a gas turbine (Brayton cycle) engine from its pressure ratio, η=1-(1/rp)^((γ-1)/γ).
✈️ What is the Brayton Cycle Efficiency Calculator?
This Brayton cycle efficiency calculator finds the ideal thermal efficiency of a gas turbine from η=1−(1/rp)^((γ−1)/γ). Enter the pressure ratio and heat capacity ratio, and it returns the theoretical maximum efficiency.
With a pressure ratio of 10 and γ=1.4 (air), this calculator gives about 48.21% ideal efficiency, in the commonly cited range for gas turbine Brayton cycle calculations.
Unlike the piston-based Otto and Diesel cycles, the Brayton cycle describes continuous-flow turbomachinery, the basis for jet engines, industrial gas turbines, and combined-cycle power plants.
This calculator is useful for thermodynamics and aerospace/mechanical engineering students studying gas turbine cycles and pressure ratio design tradeoffs.
📐 Formula
📖 How to Use This Calculator
Steps
💡 Example Calculations
Example 1 - Typical gas turbine
Example 2 - Smaller turbine, lower pressure ratio
Example 3 - Modern high-pressure-ratio turbine
❓ Frequently Asked Questions
🔗 Related Calculators
What is the Brayton cycle?
The Brayton cycle is the idealized thermodynamic cycle that models gas turbines and jet engines, consisting of adiabatic compression, constant-pressure heat addition (combustion), adiabatic expansion (through the turbine), and constant-pressure heat rejection.
What is the formula for Brayton cycle efficiency?
η = 1 − (1/rp)^((γ−1)/γ), where rp is the pressure ratio (compressor outlet pressure divided by inlet pressure) and γ is the heat capacity ratio of the working gas.
What is pressure ratio in a gas turbine?
Pressure ratio rp is the ratio of the pressure at the compressor's outlet to the pressure at its inlet, a key design parameter for gas turbines that directly determines the ideal Brayton cycle efficiency.
Why does Brayton cycle efficiency depend only on pressure ratio, not temperature?
In the idealized Brayton cycle, the temperature ratio across each adiabatic process is fixed entirely by the pressure ratio (via the adiabatic relation), so the efficiency formula reduces to depend only on rp and γ, though a higher peak temperature does increase the actual work output per cycle even though it doesn't change the ideal efficiency ratio.
What pressure ratios do real gas turbines use?
Modern industrial gas turbines and jet engines commonly operate with pressure ratios from about 15 up to 40 or higher, giving high ideal Brayton efficiency, though real turbines achieve less due to compressor and turbine inefficiencies and other losses.
How is the Brayton cycle different from the Otto and Diesel cycles?
The Otto and Diesel cycles model piston (reciprocating) engines with intermittent combustion, while the Brayton cycle models continuous-flow turbomachinery (compressor-combustor-turbine), with fluid continuously flowing through the system rather than being compressed and expanded in a single cylinder.
What is a combined-cycle power plant?
A combined-cycle plant pairs a Brayton cycle gas turbine with a Rankine cycle steam turbine, using the gas turbine's hot exhaust to boil water and drive a second turbine, capturing energy that would otherwise be wasted and achieving significantly higher overall efficiency than either cycle alone.
Does higher combustion temperature improve Brayton cycle efficiency?
In the idealized cycle, no, ideal efficiency depends only on pressure ratio and γ. In practice, higher turbine inlet temperature increases the actual net work output per unit of airflow, which is why advances in high-temperature turbine blade materials and cooling are a major focus of real gas turbine engineering.
What is a typical ideal efficiency for a modern gas turbine?
At a pressure ratio of 15, the ideal Brayton cycle efficiency is about 53.9%, rising further at higher pressure ratios used in modern high-performance turbines, real achieved efficiency is lower due to component losses.
Is the Brayton cycle used for anything besides jet engines?
Yes, it describes the thermodynamics of industrial gas turbines used for electricity generation (standalone or in combined-cycle plants), as well as some auxiliary power units and marine propulsion systems.