Menu

Executive Programs

Workshops

Projects

Blogs

Careers

Student Reviews



More

Academic Training

Informative Articles

Find Jobs

We are Hiring!


All Courses

Choose a category

Loading...

All Courses

All Courses

logo

Mechanical

Uploaded on

17 May 2023

How Do Turboprop Engines Work? | Skill-Lync

logo

Skill-Lync

Turboprop engines offer a unique blend of the reliability of jet engines and the efficiency of propeller-driven aircraft, making them an ideal choice for safe and efficient regional travel at low to mid altitudes. They power a range of aircraft, from single-pilot crop dusters to 50+ seat passenger planes, and are well-suited for short-haul flights between smaller airports and neighboring cities. This informative blog post delves into the fundamentals of turboprop engines. Continue reading to learn more.

Turboprop Engine

What Exactly Is Turboprop Engine?

A turboprop engine or turbo propeller is a specialized variant of a jet engine, uniquely optimized to drive a propeller. This innovation allows turboprop-equipped aircraft to operate exceptionally efficiently at lower flight speeds, typically less than Mach 0.6. Compared to turbojet or turbofan-powered aircraft of similar size, turboprops consume less fuel per seat-mile and require significantly shorter runways for takeoff and landing.

In particular, the efficiency of turboprop engines cannot be underestimated. Turboprop engines are highly advantageous for short-distance regional travel, where the lower speed is more than offset by their cost and performance benefits. As a result, turboprops have become the engine of choice for most commuter aircraft. Examples of turboprop-powered aircraft include the Alenia ATR 42, Bombardier Dash 8, and Pilatus PC-12.

Turboprop Engine: Working

The operation of a turboprop engine is similar to that of a turbojet engine, with the addition of a turbine at the back of the combustion chamber and a propeller at the front of the engine, which rotates via a speed-regulating gear and a shaft. This engine type is commonly used in small commuter and slow-transport aircraft.

The turboprop engine consists of a turbine, a propelling nozzle, a compressor, a combustion chamber, an inlet, and a reduction gear. Air is first introduced into the combustion chamber, where it is compressed. Fuel is then added to the chamber, mixing with the compressed air and igniting. The hot gas generated by the combustion process expands through the turbine, which produces energy to run the compressor. Finally, the combusted gas is expelled from the back of the engine.

However, unlike turbojet engines, the exhaust gases produced by turboprop engines do not possess sufficient power to generate a high thrust level. Instead, nearly all of the engine's power is utilized to drive the propellers.

The operation of a turboprop engine shares similarities with a gas turbine:

  • Initially, the engine draws air from the atmosphere through the inlet, which then passes through a centrifugal compressor for air compression. The air which is compressed is then directed to the combustion chamber, where it mixes with fuel.
  • Due to the high air compression, the fuel-air mixture ignites itself, increasing the mix's temperature and internal energy. The combustion process generates hot gases directed to the turbine area, where they expand and rotate the turbine blades.
  • When the high-speed air-fuel combination impacts the turbine blades, the blades take the maximum power from the air-fuel mixture to drive the compressor, with just a trace of exhaust gas energy sent out into the atmosphere.
  • The compressor is connected to the engine's propeller, which drives the propeller to generate thrust, propelling the airplane forward.

Turboprop Engine: History

Turboprop Engine: History

The history of the turbo propeller or turboprop engine dates back to the late 1930s when engineers were focused on developing more potent aircraft engines, particularly for military aircraft. In 1940, Hungarian engineer Gyorgy Jendrassik successfully tested the first-ever turboprop engine, the J-CS1. However, despite its success, the J-CS1 was never mass-produced.

During the 2nd World War, the Germans and the British developed and produced their versions of turbo propeller engines, starting in 1942. The British engine, known as the Rolls-Royce RB.50 Trent, was used in the Gloster Meteor, the war's first operational jet-powered fighter aircraft. The German engine, called the BMW 003, powered the Messerschmitt Me 262. It was the first mass-produced jet-powered fighter aircraft.

Since then, the tech behind the turbo propeller engine has evolved and improved. The application of turboprop engines is not limited to low-speed cargo planes but also developing more efficient and robust engines used in military transport planes to commuter airlines.

Turboprop Engine: Types

Turboprop engines can be broadly classified into two types:

  • Fixed Shaft Turboprop Engine

Here, the propeller turbine is directly connected to the engine compressor or gas generator section. This design makes it more challenging to control the propeller speed because the compressor stages need to be turned at a specific speed to ensure the engine operates correctly.

  • Free Turbine Turboprop Engine

The free-turbine turbo propeller engine is designed with a separate power turbine that operates independently from the gas generator or compressor assembly. This turbine, also known as the power turbine, drives the propeller without mechanical connections. Instead, it is rotated solely by the gases generated from combustion. This design provides more flexibility and control over the propeller speed, optimizing the engine's performance for different flight conditions easier.

A free turbine engine offers several advantages. At the start-up time, it requires less torque since the starter motor doesn't have to turn the prop turbine. It increases the lifespan by minimizing wear on the starter. A propeller brake can be leveraged in an engine, allowing the power turbine to be stopped with the running engine core. This feature enables the engine to act as an auxiliary power unit (APU) when an external power source is unavailable.

Advantages and Disadvantages of Turboprop Engines

Turboprop engines offer several advantages and disadvantages, as outlined below:

Advantages

  • Low weight: Turboprop engines are lighter than turbojet engines, making them ideal for takeoff and landing.
  • Fuel efficiency: Turboprop engines are highly efficient, burning less fuel per seat-mile than other types of engines.
  • High output power: Turboprop engines provide more output power than jet engines.
  • Short takeoff and landing capability: Turboprop airplanes can land on non-concrete and shorter runways, making them ideal for regional travel.
  • Cost-effective: Turboprop engines are less expensive than turbojet engines and have lower maintenance costs.
  • Reliability: Turboprop engines have fewer moving parts than other engines, making them more reliable.
  • Simple operation: Turboprop engines are easy to operate and maintain.

Moreover, turboprop engines are more efficient than turbofan engines at flight speeds of less than 725 km per hour and have unwavering mechanical properties due to their few moving parts.

Disadvantages

  • They have a lower cruising speed than other engines, which can result in longer flight times.
  • Turboprop aircraft typically can't fly at high altitudes, which can limit their range.
  • They could be better for long-distance travel.
  • At high altitudes, the propeller can lose efficiency.
  • Turboprop engines tend to have a higher vibration level, which can make passengers uncomfortable.
  • The working height of the engine can make the aircraft more susceptible to climatic turbulence, which can cause additional inconvenience for travelers.

Conclusion

Equipping an aircraft with a turbo propeller engine offers the best in every way when it comes to low-altitude regional flights. The engine compresses and combusts air, which is then converted into power to spin the propeller. Turboprops have fewer moving parts than piston aircraft, resulting in less vibration and increased reliability.

To learn more about the functioning of automotive, enroll in our Post Graduate Program in Hybrid Electric Vehicle Design and Analysis. Talk to our experts to get your free demo. 


Author

author

Anup KumarH S


Author

blogdetails

Skill-Lync

Subscribe to Our Free Newsletter

img

Continue Reading

Related Blogs

A Guide to Help FEA Engineers Get Started With Vehicle Dynamics - Part 1

Explore the fundamentals of vehicle dynamics and ultimate trends in the field from design and modeling to control with Skill Lync's exclusive course on the subject. Read about how Skill-Lync's CAE courses can help you get employed.

Mechanical

29 Jul 2020


How Using GT-Power in CFD Can Benefit the Automation Industry

In this article, we will briefly discuss the working, applications, and features of the one-dimensional systematic simulation tool, GT-Power, in Emission Control Strategy, engine calibration, hybrid vehicle modeling. Read about how Skill-Lync's CAE courses can help you get employed.

Mechanical

29 Jul 2020


Design Basics of Geometric Dimensioning and Tolerancing

This article offers a brief introduction to the globally accepted standard of Geometric Dimensioning and Tolerancing, and its importance for the entire manufacturing process. Read about how Skill-Lync's CAE courses can help you get employed.

Mechanical

29 Jul 2020


Chapter 5 – Going a step into Biomechanics

In this blog we will read about Going a step into Biomechanics and how Skill-Lync's CAE course will help you get employed.

Mechanical

10 May 2020


The Basics of the Powertrain NVH: Part 2

The powertrain is the most prominent source of vibrations that affects the driving experience for the people on board. This blog from Skill-Lync examines these vibrations to help enhance that experience.

Mechanical

22 Aug 2020



Author

blogdetails

Skill-Lync

Subscribe to Our Free Newsletter

img

Continue Reading

Related Blogs

A Guide to Help FEA Engineers Get Started With Vehicle Dynamics - Part 1

Explore the fundamentals of vehicle dynamics and ultimate trends in the field from design and modeling to control with Skill Lync's exclusive course on the subject. Read about how Skill-Lync's CAE courses can help you get employed.

Mechanical

29 Jul 2020


How Using GT-Power in CFD Can Benefit the Automation Industry

In this article, we will briefly discuss the working, applications, and features of the one-dimensional systematic simulation tool, GT-Power, in Emission Control Strategy, engine calibration, hybrid vehicle modeling. Read about how Skill-Lync's CAE courses can help you get employed.

Mechanical

29 Jul 2020


Design Basics of Geometric Dimensioning and Tolerancing

This article offers a brief introduction to the globally accepted standard of Geometric Dimensioning and Tolerancing, and its importance for the entire manufacturing process. Read about how Skill-Lync's CAE courses can help you get employed.

Mechanical

29 Jul 2020


Chapter 5 – Going a step into Biomechanics

In this blog we will read about Going a step into Biomechanics and how Skill-Lync's CAE course will help you get employed.

Mechanical

10 May 2020


The Basics of the Powertrain NVH: Part 2

The powertrain is the most prominent source of vibrations that affects the driving experience for the people on board. This blog from Skill-Lync examines these vibrations to help enhance that experience.

Mechanical

22 Aug 2020


Book a Free Demo, now!

Related Courses

https://d28ljev2bhqcfz.cloudfront.net/maincourse/thumb/matlab-python-cfd-solidworks_1612350558.png
MATLAB Python and CFD using Solidworks for Mechanical Engineering Applications
4.7
13 Hours of content
Cfd Domain
Know more
https://d28ljev2bhqcfz.cloudfront.net/maincourse/thumb/python-mechanical-engineers_1612257799.jpg
4.7
4 Hours of content
Cfd Domain
Showing 1 of 4 courses