A deep dive into Formula 1's MGU-K system and how it utilises polymers.

A deep dive into Formula 1's MGU-K system and how it utilises polymers.

The MGU-K (Motor Generator Unit - Kinetic) is a key component of the hybrid power unit used in modern Formula 1 cars. As part of the Energy Recovery System (ERS), the MGU-K captures kinetic energy during braking and stores it in the car's battery, later deploying it to provide additional power to the engine. This system allows F1 cars to recover energy that would otherwise be lost and use it to enhance performance and efficiency, aligning with Formula 1’s push toward sustainability and energy efficiency. Polymers play a crucial role in the construction and functionality of the MGU-K system, particularly in areas such as electrical insulation, thermal management, and structural integrity. Let’s take a deep dive into how the MGU-K system works and where polymers are employed.

Overview of the MGU-K System

The MGU-K functions as both a generator and a motor. When the car decelerates, the MGU-K acts as a generator, converting the car’s kinetic energy into electrical energy. This energy is stored in the Energy Store (ES), a high-performance battery pack. During acceleration or high-speed driving, the MGU-K switches to motor mode, using the stored energy to provide extra power to the engine, improving performance while reducing fuel consumption.

The MGU-K is connected to the crankshaft of the engine and can harvest up to 120 kW (161 bhp) of power during braking. It is a high-speed, high-stress component that operates in extreme thermal and mechanical environments, making the use of advanced materials, including polymers, essential for its efficiency and reliability.

How Polymers are Utilised in the MGU-K System

1. Electrical Insulation

The MGU-K, being an electrically driven system, relies heavily on high-performance polymers for electrical insulation. The system includes a stator and rotor, where the movement of the rotor generates electricity. To prevent short circuits and ensure efficient energy transfer, insulating materials like PTFE (Polytetrafluoroethylene) and polyimide (PI) are used to insulate the electrical windings within the motor and generator units.

  • PTFE is used for wire insulation and coating the windings in the motor and generator due to its excellent electrical insulating properties and ability to withstand high temperatures. It also offers resistance to chemicals and fuels, which is critical in the harsh environment of a Formula 1 engine bay.
  • Polyimide films, such as Kapton, are also used as insulation around critical electrical components. These films can withstand extreme temperatures (up to 400°C) and offer excellent dielectric strength, ensuring that electrical currents flow safely through the system without causing damage.

2. Thermal Management

One of the greatest challenges in the MGU-K system is thermal management. The constant switching between motor and generator modes, combined with the high energy throughput, generates significant heat. To ensure that the MGU-K operates efficiently and reliably under these conditions, polymers with excellent heat resistance are used in various parts of the system.

  • PEEK (Polyether Ether Ketone) is often used for components that need to withstand high temperatures and mechanical stress, such as housings, connectors, and internal supports within the MGU-K. PEEK’s thermal stability ensures that it can endure the heat generated during energy recovery and deployment without deforming or losing strength. Additionally, PEEK’s excellent resistance to wear and chemical exposure makes it ideal for these high-stress environments.

  • Thermal insulation layers made from polymer foams or silicone-based polymers are also used in and around the MGU-K to manage heat dissipation. These materials help protect sensitive electronic components and prevent heat from radiating to other critical systems in the car, such as the battery pack and power electronics.

3. Weight Reduction

The performance of an F1 car is highly dependent on weight, and every gram counts. Polymers are often chosen for their high strength-to-weight ratio, allowing engineers to reduce the weight of the MGU-K system without compromising durability or performance. Lightweight polymers such as carbon fiber-reinforced polymers (CFRP) are used in the structural components of the MGU-K, such as housings and mounting brackets.

  • CFRP components provide the necessary strength and rigidity to protect the internal mechanisms of the MGU-K while keeping the overall weight of the system low. This is crucial, as reducing the weight of the MGU-K not only improves the car’s acceleration and cornering capabilities but also allows for better energy efficiency.

4. Durability and Vibration Resistance

The MGU-K system is subjected to significant mechanical stresses, including vibrations, high rotational speeds, and the forces generated during braking and acceleration. Elastomeric polymers, such as silicone and fluoroelastomers, are used in components like seals and gaskets to absorb vibrations and maintain the structural integrity of the MGU-K.

  • Silicone seals are used in the MGU-K to provide flexibility and ensure that critical components remain protected from dirt, dust, and fluid ingress. These seals must be able to withstand high temperatures and pressures while maintaining their elasticity over time.
  • Vibration damping materials made from elastomeric polymers are also integrated into the MGU-K system to protect sensitive components from the intense vibrations that occur during racing. This prevents premature wear and tear on internal parts and extends the lifespan of the unit.

5. Cooling Systems and Fluids

Efficient cooling is essential for the operation of the MGU-K system, as overheating can lead to loss of power and potential failure of the component. Polymer-based coolant hoses and fluid lines are used to transport coolant to and from the MGU-K. These hoses are often made from materials such as PTFE or EPDM (Ethylene Propylene Diene Monomer rubber), which offer flexibility, heat resistance, and chemical durability.

  • PTFE coolant lines are favored for their ability to withstand high temperatures and their resistance to the chemicals found in modern cooling fluids. These hoses are essential for maintaining the optimal operating temperature of the MGU-K, ensuring that it functions efficiently throughout the race.

Benefits of Using Polymers in the MGU-K System

  • High Performance in Extreme Conditions: The use of advanced polymers allows the MGU-K system to operate efficiently in the extreme heat, pressure, and electrical demands of Formula 1 racing. Materials like PEEK and PTFE provide the necessary thermal and chemical resistance to withstand the challenging environment of the engine bay.

  • Weight Reduction: By replacing traditional materials with lightweight polymers like CFRP and PEEK, engineers can reduce the overall weight of the MGU-K system, improving the car’s performance without sacrificing durability.

  • Improved Durability and Reliability: Polymers such as fluoroelastomers and silicone help protect the system from wear and tear, vibrations, and environmental contaminants, ensuring that the MGU-K performs reliably throughout the race.

  • Electrical Efficiency: High-performance insulating materials like polyimide films and PTFE ensure that electrical currents flow smoothly and safely, reducing the risk of electrical failure and maximizing energy recovery and deployment.

Conclusion

The MGU-K system in Formula 1 cars represents a critical component of the car’s hybrid power unit, capturing and deploying energy to enhance performance and efficiency. Polymers play a vital role in the construction and functionality of this system, contributing to electrical insulation, thermal management, weight reduction, and durability. By leveraging the unique properties of materials like PEEK, PTFE, and CFRP, F1 teams are able to optimize the performance of the MGU-K, ensuring that it operates reliably under the intense conditions of Formula 1 racing. As F1 technology continues to evolve, the use of advanced polymers in energy recovery systems will remain a key factor in pushing the limits of performance and efficiency.