Thermodynamics II

🧊Thermodynamics II Unit 12 – Gas Turbines & Jet Propulsion Systems

Gas turbines and jet propulsion systems are crucial in modern engineering. These powerful machines convert fuel's chemical energy into mechanical energy through combustion, operating on the Brayton cycle. They're used in various applications, from power generation to aircraft propulsion. Understanding gas turbines involves key concepts like compression ratios, turbine inlet temperatures, and component efficiencies. Different types exist, including single-shaft, multi-shaft, and aeroderivative turbines. Jet propulsion basics, thermodynamic cycles, and component functions are essential for grasping their operation and performance.

Key Concepts and Principles

  • Gas turbines convert chemical energy from fuel into mechanical energy through combustion
  • Operate on the Brayton cycle, an open, continuous combustion cycle
  • Consist of three main components: compressor, combustion chamber, and turbine
  • Compressor increases pressure and temperature of incoming air
  • Combustion chamber mixes compressed air with fuel and ignites the mixture
    • Combustion process significantly increases temperature and volume of gases
  • Turbine extracts energy from hot, high-pressure gases to drive the compressor and output shaft
  • Exhaust gases are expelled at a higher velocity than inlet air, producing thrust in jet engines
  • Efficiency depends on factors such as compression ratio, turbine inlet temperature, and component efficiencies

Types of Gas Turbines

  • Single-shaft gas turbines have compressor, turbine, and output shaft on a single shaft
    • Commonly used in power generation and mechanical drive applications
  • Multi-shaft gas turbines have separate shafts for compressor, power turbine, and output shaft
    • Allows for greater operational flexibility and improved part-load efficiency
  • Aeroderivative gas turbines are derived from aircraft jet engines and adapted for industrial use
    • Compact, lightweight, and offer high power-to-weight ratios
  • Industrial gas turbines are designed specifically for stationary power generation and mechanical drive applications
    • Larger, heavier, and optimized for longer continuous operation
  • Microturbines are small-scale gas turbines with power outputs ranging from 30 to 1,000 kW
    • Used in distributed power generation and combined heat and power (CHP) applications

Jet Propulsion Basics

  • Jet propulsion is the principle of generating thrust by ejecting a high-velocity fluid
  • In jet engines, thrust is produced by accelerating a mass of air using a gas turbine
  • Thrust is defined as the product of mass flow rate and velocity change, as per Newton's second law of motion
    • Thrust=m˙(vev0)Thrust = \dot{m} (v_e - v_0), where m˙\dot{m} is mass flow rate, vev_e is exhaust velocity, and v0v_0 is inlet velocity
  • Specific impulse (IspI_{sp}) is a measure of jet engine efficiency, representing thrust per unit mass flow rate of propellant
    • Isp=Thrustm˙gI_{sp} = \frac{Thrust}{\dot{m}g}, where gg is gravitational acceleration
  • Ramjets and scramjets are types of jet engines that rely on high vehicle speed for compression
    • Ramjets operate at supersonic speeds (Mach 1-5), while scramjets operate at hypersonic speeds (Mach 5+)

Thermodynamic Cycles

  • Gas turbines operate on the Brayton cycle, an open, continuous combustion cycle
  • Ideal Brayton cycle consists of four processes: isentropic compression, isobaric heat addition, isentropic expansion, and isobaric heat rejection
    • In reality, compression and expansion processes are non-isentropic due to irreversibilities
  • Thermal efficiency of the Brayton cycle depends on compression ratio and specific heat ratio of the working fluid
    • ηth=11rp(γ1)/γ\eta_{th} = 1 - \frac{1}{r_p^{(\gamma-1)/\gamma}}, where rpr_p is the pressure ratio and γ\gamma is the specific heat ratio
  • Combined cycle power plants integrate a gas turbine (Brayton cycle) with a steam turbine (Rankine cycle) to achieve higher overall efficiency
    • Exhaust heat from the gas turbine is used to generate steam for the steam turbine
  • Regenerative Brayton cycle incorporates a heat exchanger to preheat compressed air using turbine exhaust, improving cycle efficiency

Components and Their Functions

  • Compressor: Increases pressure and temperature of incoming air
    • Axial compressors are commonly used in gas turbines, consisting of multiple stages of rotating blades and stationary vanes
    • Centrifugal compressors are used in smaller gas turbines, utilizing centrifugal force to compress air
  • Combustion Chamber: Mixes compressed air with fuel and ignites the mixture
    • Can-annular combustors consist of multiple individual combustion cans arranged around the engine
    • Annular combustors have a single, continuous combustion zone around the engine
  • Turbine: Extracts energy from hot, high-pressure gases to drive the compressor and output shaft
    • Consists of multiple stages of rotating blades and stationary nozzles
    • High-temperature materials and cooling techniques are critical for turbine durability
  • Fuel System: Delivers fuel to the combustion chamber at the required pressure, temperature, and flow rate
    • Includes fuel pumps, valves, filters, and injectors
  • Lubrication System: Provides lubrication and cooling for bearings, gears, and other moving parts
    • Uses oil as the lubricant, with pumps, filters, and heat exchangers to maintain oil quality and temperature
  • Control System: Monitors and regulates engine operation to ensure safe, efficient, and reliable performance
    • Includes sensors, actuators, and electronic control units (ECUs) to manage fuel flow, air flow, and other parameters

Performance Analysis

  • Gas turbine performance is evaluated using key parameters such as power output, thermal efficiency, specific fuel consumption, and exhaust gas temperature
  • Power output depends on factors such as mass flow rate, turbine inlet temperature, and component efficiencies
    • Power=m˙cp(T3T4)Power = \dot{m}c_p(T_3 - T_4), where m˙\dot{m} is mass flow rate, cpc_p is specific heat capacity, T3T_3 is turbine inlet temperature, and T4T_4 is turbine outlet temperature
  • Thermal efficiency is the ratio of useful work output to heat input
    • ηth=PowerQin\eta_{th} = \frac{Power}{Q_{in}}, where QinQ_{in} is the heat input from fuel combustion
  • Specific fuel consumption (SFC) is the fuel flow rate per unit power output, a measure of fuel efficiency
    • SFC=m˙fuelPowerSFC = \frac{\dot{m}_{fuel}}{Power}, where m˙fuel\dot{m}_{fuel} is the fuel mass flow rate
  • Exhaust gas temperature is a critical parameter affecting turbine life and overall engine performance
    • Higher temperatures improve efficiency but increase thermal stress on components
  • Off-design performance analysis evaluates engine behavior under varying operating conditions (altitude, ambient temperature, load)
    • Component maps and performance curves are used to predict off-design performance

Efficiency and Optimization

  • Improving gas turbine efficiency involves optimizing cycle parameters, component designs, and operating conditions
  • Increasing turbine inlet temperature (TIT) is a key strategy for improving efficiency
    • Advanced materials, thermal barrier coatings, and cooling techniques enable higher TITs
    • Every 50°C increase in TIT yields a 1-2% improvement in thermal efficiency
  • Increasing compression ratio also improves efficiency by reducing the required heat input
    • Optimal compression ratio balances efficiency gains with increased compressor work and complexity
  • Recuperation (regeneration) can improve efficiency by preheating compressed air using turbine exhaust
    • Effectiveness of recuperation depends on heat exchanger effectiveness and pressure losses
  • Intercooling between compressor stages reduces compressor work and improves overall efficiency
    • Requires additional heat exchangers and increases system complexity
  • Advanced combustion technologies (lean premixed combustion, staged combustion) reduce emissions and improve fuel efficiency
  • Regular maintenance, including cleaning, inspection, and replacement of components, is essential for maintaining optimal performance over time

Real-World Applications

  • Power Generation: Gas turbines are widely used for electricity generation in simple cycle and combined cycle power plants
    • Simple cycle plants use a gas turbine only, while combined cycle plants integrate a steam turbine for higher efficiency
  • Mechanical Drive: Gas turbines drive compressors, pumps, and other machinery in industrial applications (oil and gas, petrochemical)
    • Offer high power density, reliability, and operational flexibility compared to other prime movers
  • Aviation: Gas turbines (jet engines) are the primary propulsion system for modern aircraft
    • Turbojets, turbofans, turboprops, and turboshafts are common types of aircraft gas turbines
  • Marine Propulsion: Gas turbines are used in naval and commercial vessels for main propulsion and auxiliary power
    • Offer high power density, compact size, and quick start-up compared to diesel engines
  • Cogeneration (Combined Heat and Power): Gas turbines generate electricity and useful heat simultaneously
    • Exhaust heat is recovered for process heating, district heating, or absorption cooling
  • Hybrid Systems: Gas turbines are integrated with other power generation technologies for improved efficiency and flexibility
    • Examples include gas turbine-fuel cell hybrids and gas turbine-solar thermal hybrids


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© 2024 Fiveable Inc. All rights reserved.
AP® and SAT® are trademarks registered by the College Board, which is not affiliated with, and does not endorse this website.