Inside Red Bull's Latest Tech Updates: Analyzing the innovative solutions helping the champions stay ahead

Semi-Detached Endplate Junction

The revised endplate now features a distinctive gap between the main plane and the endplate itself. This creates a small but significant pressure differential that generates a controlled vortex stream, helping to push airflow around the front tire more efficiently.

Revised Flap Curvature

The central section of the wing now features a more pronounced arch, creating a greater pressure differential between the upper and lower surfaces. This modification provides more consistent downforce across varying ride heights - particularly important with the porpoising challenges of ground effect cars.

Adjustable Slot Gap Separators

Red Bull has pioneered a new system of adjustable slot gap separators that can be quickly modified between qualifying and the race. This allows the team to run a more aggressive wing setup for qualifying before switching to a more conservative, race-oriented configuration that preserves tire life.

"Red Bull's front wing evolution is particularly impressive because it addresses multiple challenges simultaneously. They've improved downforce generation while also better managing the turbulent wake from the front wheels, which has traditionally been a problem area in this regulation set. The clever use of vortex generators on the wing elements shows the kind of thinking that has kept Red Bull at the forefront of aerodynamic innovation."

- Gary Anderson, F1 Technical Analyst

Technical Insight

In ground effect cars, the floor and diffuser can generate up to 60% of the total downforce. Managing the airflow beneath the car is critical for performance, with even small disruptions potentially causing significant losses in downforce and creating aerodynamic instability.

Venturi Tunnels Optimization

Red Bull has refined the shape of their venturi tunnels to extract maximum performance. The entry geometry has been subtly reshaped to improve airflow at varying ride heights, while the throat section has been narrowed to increase the velocity of air passing through – generating greater downforce according to Bernoulli's principle.

Diffuser Strake Architecture

The updated diffuser features revised strakes with a more aggressive curvature. These vertical elements help keep the airflow attached and organized as it exits the diffuser, increasing the effective expansion ratio of the diffuser and enhancing its efficiency. The new configuration includes seven strakes instead of the previous six, with the central strake being taller than before.

Edge Wing Elements

Following the FIA's clarification on floor edge components, Red Bull introduced small but aerodynamically significant wing elements along the floor's edge. These carefully shaped mini-wings create localized vortices that help seal the floor edge while also extracting additional downforce. The elements feature a unique curved shape that helps energize the airflow passing around the floor edge.

CFD Analysis Reveals Performance Gains

Red Bull's floor developments have provided approximately 0.35 seconds per lap in combined performance gains across various circuits. The floor's efficiency at different ride heights has been particularly improved, reducing the car's sensitivity to changes in ride height through high-speed corners.

EARLY SEASON

Initial 2025 side pod configuration - featuring the undercut design that has become Red Bull's signature.

IMOLA UPDATE

Revised side pod introduced at Imola with more aggressive contouring and expanded cooling outlets.

Extreme Undercut Architecture

Red Bull has further exaggerated the undercut beneath the side pod inlet, creating an even more dramatic channel for airflow to pass through. This creates a powerful air stream that is directed toward the coke-bottle area at the rear of the car. The undercut's geometry has been refined through multiple iterations during wind tunnel testing to optimize the flow structures it generates.

Side Impact Structure Fairing

In their Imola upgrade package, Red Bull introduced a revised fairing around the mandatory side impact structure. This area, which previously created unavoidable turbulence, has been reshaped with a more aerodynamically efficient profile. The new design includes subtle strakes that help organize the airflow passing over this area, reducing drag and improving the quality of air directed toward the rear of the car.

Expanded Cooling Exit Louvres

The cooling exit strategy has been completely reimagined with the introduction of what the team calls "waterfall" louvres on the upper surface of the side pods. Rather than routing all hot air to a single exit at the rear, these carefully shaped openings distribute the cooling air more effectively, allowing for better heat management while maintaining aerodynamic efficiency. This approach gives the team greater flexibility in managing cooling requirements across different circuits and ambient conditions.

Drag Reduction

Lower drag coefficient compared to the launch-specification side pods

Rear Downforce

Increased downforce at the rear of the car due to improved airflow quality

Cooling Efficiency

Improved cooling efficiency allowing for smaller radiator openings at high-speed circuits

Engineering Challenge

Every 1°C increase in ambient temperature typically requires approximately 5% more cooling surface area. Managing this variable requirement while maintaining aerodynamic efficiency presents one of Formula 1's great engineering challenges.

Variable Geometry Pull-Rod System

Red Bull has implemented a sophisticated front suspension geometry that subtly varies the pull-rod angle through the suspension's range of motion. This creates a progressive rate change that optimizes the suspension's behavior in different types of corners.

The system utilizes specially designed mounting points with variable-radius cam profiles that allow the effective leverage ratio to change as the suspension compresses. This provides a softer initial rate for better compliance over bumps and kerbs, transitioning to a firmer rate deeper in the suspension travel to maintain aerodynamic platform stability.

Multi-Material Wishbones

In a significant material technology breakthrough, Red Bull introduced a composite wishbone design that combines carbon fiber with titanium and aluminum inserts at strategic points. This creates components with directionally tuned flexibility - stiff in some directions while allowing controlled flex in others.

This engineered flexibility helps maintain ideal tire contact patch geometry throughout cornering, particularly beneficial in low-speed sections where maximum mechanical grip is essential. The design also incorporates internal damping layers to filter out high-frequency road inputs that could disturb aerodynamic performance.

Hydraulic Anti-Roll System

Red Bull has refined their hydraulic anti-roll system for 2025, creating a more sophisticated solution that provides variable roll stiffness depending on steering angle and vehicle speed. This system uses hydraulic channels with specially shaped orifices that change the fluid flow characteristics as the steering angle increases.

The result is a suspension system that can automatically provide different handling characteristics in different types of corners - maintaining a stable aerodynamic platform in high-speed sections while allowing greater mechanical grip in low-speed corners, all without driver intervention or complex active systems that would violate the regulations.

Max Verstappen

3-Time World Champion

" The car's behavior in slow corners has improved dramatically this year. I can attack the apex with much more confidence, especially in circuits like Monaco and Singapore. The suspension gives much better feedback, and you can feel exactly what the front tires are doing, which gives you the confidence to push harder."

Sergio Perez

Red Bull Racing Driver

" The new suspension has completely transformed how we can attack certain sections of track. In previous years, we knew we would lose a little time in the tight corners, but now we're competitive everywhere. The car maintains much better contact with the road over bumps and kerbs, which gives you more options as a driver in terms of racing lines."

Low-Speed Corner Performance

Average gain in low-speed sectors (below 125 km/h)

Kerb Ride Compliance

Improved absorption of impacts when attacking kerbs

Tire Management

Extended tire life due to improved contact patch consistency