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Roof flap

A roof flap is an aerodynamic safety device mounted on the roof of NASCAR stock cars, designed to deploy automatically during high-speed spins or slides to disrupt airflow, generate downforce, and prevent the vehicle from lifting off the track.^[1] These flaps, typically consisting of two hinged metal panels flush with the roof when inactive, emerged as a critical response to airborne crashes that posed risks to drivers and spectators in the early 1990s.^[2] The development of roof flaps stemmed from a series of high-profile incidents at superspeedways like Daytona and Talladega, where cars frequently became airborne due to lift generated by their high, boxy designs during spins.^[3] In response, NASCAR's Winston Cup Director Gary Nelson, along with engineer Gary Eaker, conceived the concept in late 1993 after unsuccessful tests with pop-up trunk lids and other drag-inducing ideas.^[2] Team owner and engineer Jack Roush fabricated the first prototype, which was successfully tested at Darlington County Airport in December 1993 using a jet engine to simulate forces, proving the flaps could withstand extreme conditions without failure.^[2] Roof flaps became mandatory for all NASCAR Winston Cup cars starting with the 1994 Daytona 500, marking a pivotal advancement in motorsport safety that avoided the need for further speed restrictions like smaller engines.^[2] In operation, the flaps deploy passively when the car spins, as air pressure builds under them and forces them upward to act as air deflectors or spoilers.^[1] This deployment includes attached fabric "parachutes" on the underside that further increase drag and downforce, effectively increasing the critical speed threshold for liftoff, with early tests showing they could keep cars grounded up to around 180 mph.^[4] Wind tunnel testing and on-track incidents, such as a 2013 Daytona crash test involving 12 cars, have validated their effectiveness in keeping vehicles grounded even during multi-car pileups at restrictor-plate tracks.^[1] Over time, roof flaps have evolved with NASCAR's car generations to address ongoing aerodynamic challenges. The 2013 Generation-6 cars featured larger flaps—measuring about 24 inches wide by 16 inches deep—to accommodate sleeker body styles while enhancing stability, as demonstrated in restrictor-plate racing.^[1] In the 2022 Next Gen car, the system was refined with a cable linking the roof flaps to a rear diffuser flap, ensuring synchronized activation for better control during backward slides, following extensive wind tunnel validation across four testing phases.^[5] In October 2024, NASCAR mandated additional enhancements, including fabric beneath the right-side roof flap and extended rocker panel skirts, to further mitigate airborne risks at superspeedways.^[6] Recent additions, such as a 2024 right-side rear-window air deflector and a 2025 A-post flap, complement the roof flaps by further mitigating lift on the car's sides, reflecting NASCAR's continuous commitment to safety amid speeds exceeding 200 mph.^[7]^[8]

Overview

Definition

A roof flap is a passive aerodynamic safety device mounted on the roof of race cars, particularly in stock car racing series like NASCAR, consisting of hinged panels that deploy upward to function as an emergency spoiler.^[9] These panels, typically constructed from lightweight carbon fiber composites, remain flush with the vehicle's roof under normal conditions but activate automatically through a passive pressure differential mechanism when the car experiences significant yaw or reverse airflow, creating low pressure over the roof.^[10] The primary role of the roof flap is to prevent lift-off during high-speed instability by disrupting airflow over the roof, thereby increasing drag and generating additional downforce to push the vehicle back toward the track surface.^[11] When deployed, the flaps create a high-pressure area in front of them and slow the air passing over the smooth roof surface, counteracting the low-pressure lift that could otherwise cause the car to become airborne, especially in backward spins.^[10] This deployment increases the vehicle's lift-off speed by 10-20%, enhancing stability without requiring active electronic controls.^[12] Unlike fixed spoilers or diffusers, which provide continuous aerodynamic effects to optimize performance under standard racing conditions, roof flaps are dynamic elements that only engage under specific emergency scenarios, such as excessive yaw angles, ensuring they do not compromise the car's speed or handling during normal operation.^[9] This passive, condition-triggered design distinguishes them as safety-focused interventions rather than permanent aerodynamic modifications.^[13]

Purpose

The primary purpose of roof flaps in motorsport vehicles, particularly in NASCAR, is to counteract aerodynamic lift that develops at high speeds, preventing cars from becoming airborne and losing control. At high speeds exceeding approximately 180 mph (290 km/h), the shape and orientation of race cars can generate significant upward lift, especially when airflow is disrupted, potentially causing the vehicle to lift off the track surface.^[10]^[1] Roof flaps deploy automatically in critical scenarios such as spins, backward travel, or impacts that alter forward airflow, thereby reversing the lift generated by the car's underbody ground effect. When a car yaws or reverses direction, the smooth underbody flow that normally produces downforce is interrupted, transforming it into lift; the flaps activate to mitigate this reversal and maintain downward pressure.^[9]^[14] Prior to their mandatory introduction in 1994, NASCAR vehicles frequently experienced lift-off during high-speed incidents on oval tracks, substantially elevating the risk of catastrophic rollovers and endangering drivers and spectators. These pre-flap era accidents, often triggered by spins at restrictor-plate tracks like Daytona and Talladega, prompted the development of roof flaps as a safety measure to keep cars grounded. Roof flaps consist of hinged panels that deploy automatically due to pressure differentials from altered airflow during spins or backward motion, serving as an emergency aerodynamic stabilizer.^[15]^[1]^[10]

History

Development

The development of roof flaps began in late 1993, when NASCAR Winston Cup Series Director Gary Nelson, along with engineer Gary Eaker, conceived the concept in response to a series of dangerous airborne incidents, including the high-profile crash at Talladega Superspeedway during the Winston 500, where Rusty Wallace's car lifted off after a last-lap contact with Dale Earnhardt, tumbling multiple times across the infield. This event, one of over 15 rollovers in the early 1990s, underscored the risks of aerodynamic lift during high-speed spins, prompting NASCAR to prioritize anti-lift technologies to enhance driver safety.^[15] Team owner and engineer Jack Roush fabricated the first prototype, which was successfully tested at Darlington Raceway in December 1993 using jet engines to simulate forces, proving the flaps could withstand extreme conditions without failure.^[2] NASCAR formed a collaborative effort with General Motors (GM), Ford Motor Company, and Roush Industries to engineer an effective solution, focusing on aerodynamic devices to counteract lift without compromising straight-line performance. Extensive wind tunnel testing at GM's Aero Lab evaluated various prototypes, confirming that roof flaps, when integrated with complementary features like roof rails and right-side window deflectors, significantly reduced extreme yaw-induced lift—by approximately 30% in critical scenarios—helping prevent vehicles from becoming airborne during spins at high speeds. These tests, conducted in the fall of 1993, validated the flaps' ability to deploy passively during spins, creating turbulence to increase downforce and maintain tire contact with the track.^[16]^[4] Key milestones included prototype testing in early 1994, which demonstrated the system's near-total elimination of aerodynamic lift-off under simulated race conditions, leading to its mandatory implementation starting February 1994 at tracks one mile or longer. NASCAR filed a patent application for the aerodynamic stabilizer system with priority date January 14, 1994 (U.S. Patent No. 5,374,098), assigned to the organization and invented by Gary Nelson, describing the roof-mounted flaps and their deployment mechanism to generate downward force during yaw angles of 70° to 150°. A related patent (U.S. Patent No. 5,544,931) further detailed enhancements, solidifying the technology's role in modern stock car safety.^[16]^[17]^[18]

Introduction

Roof flaps were mandated by NASCAR for the 1994 Winston Cup Series season, requiring installation on all Cup cars ahead of the Daytona Speedweeks events. This decision followed successful prototype testing that demonstrated the flaps' effectiveness in preventing cars from becoming airborne during high-speed spins, a response to incidents like Rusty Wallace's dramatic 1993 Talladega flip.^[15]^[2] The rapid adoption extended the requirement to the Busch Grand National Series (now Xfinity) by the same 1994 season, covering NASCAR's primary stock car divisions. This swift rollout across divisions marked a pivotal shift in NASCAR's aerodynamic safety protocols.^[2] Early implementation revealed minor deployment reliability issues, including unauthorized modifications by teams that affected flap performance. These were addressed through 1996 adjustments to flap angles and materials, enhancing deployment consistency and overall system durability as detailed in technical analyses of the era.^[19]^[20]

Design

Components

The roof flap system in NASCAR vehicles primarily comprises two hinged flaps constructed from carbon fiber composite materials for lightweight strength and durability. These flaps, typically measuring about 10 inches wide by 18 inches long in modern designs, are mounted centrally on the roof and connected via a framework that includes a central spine partitioning the assembly into two openings.^[10]^[17] Supporting elements include pivotable hinges along the front edges of the flaps, allowing rotation from a stowed position flush with the roof to a deployed state, and helical torsion springs that bias the flaps toward the stowed position for passive operation.^[17] Additional components consist of cables or tethers made of high-strength polymers like Vectran to limit upward flap rotation, along with fabric covers—often described as canvas parachutes—that stretch between the flaps and roof to minimize drag when stowed and enhance effectiveness when deployed.^[10]^[1] In the Next Gen car introduced in 2022, a cable links the roof flaps to a rear diffuser flap for synchronized activation.^[5] The overall design uses lightweight composites engineered to withstand impacts at speeds exceeding 200 mph, ensuring reliability in high-velocity crash scenarios.^[21]

Deployment

Roof flaps deploy passively through an aerodynamic mechanism that responds to changes in airflow during vehicle yaw or spin-out conditions. When reverse or sideways airflow occurs over the roof—typically during uncontrolled spins—a low-pressure region forms above the flaps, creating a pressure differential that overcomes the spring bias holding the flaps flush against the roof surface. This causes the flaps to pivot upward along their hinges to a raised position, where cables limit further rotation to prevent detachment.^[17] The system relies entirely on mechanical components without electronic intervention in its standard NASCAR implementation, ensuring reliable activation solely based on airflow dynamics. Deployment is calibrated to trigger at high backward speeds, such as 140 mph or greater, where the reverse airflow generates sufficient force against the spring tension.^[17] Once forward airflow resumes and the pressure differential equalizes, the springs automatically return the flaps to their lowered, flush position, restoring the vehicle's normal aerodynamic profile. This reset process is inherent to the design, allowing the flaps to remain operational without manual intervention during a race. In the Next Gen car, deployment synchronizes with the rear diffuser flap via the connecting cable.^[17]^[5]

Aerodynamics

Mechanism

When roof flaps deploy on a stock car, they disrupt the smooth airflow over the vehicle's roof, particularly during high-yaw-angle conditions such as spins, where low pressure typically forms above the car due to accelerated airflow.^[17] This disruption slows the air velocity on the roof surface, creating a high-pressure zone that counters the lift generated by faster-moving air underneath the vehicle.^[10] According to Bernoulli's principle, the total pressure along a streamline remains constant, expressed as P + \frac{1}{2} \rho v^2 = \text{constant}, where P is static pressure, \rho is air density, and v is velocity; thus, reducing v over the roof increases P, while the higher v beneath the car (due to ground effect) maintains low pressure there, converting potential lift into downforce.^[20]^[10] The deployed flaps act passively without active controls, generating additional downward force by inducing drag that presses the car toward the track, enhancing stability during emergency conditions.^[12] Roof flaps are strategically positioned on the rear roofline to integrate with the car's bodywork and rear spoiler, ensuring the disrupted airflow contributes to balanced aerodynamic stability rather than uneven loading, and are effective at yaw angles up to 160 degrees.^[17]^[20]^[22]

Effects

The activation of roof flaps in NASCAR vehicles during spins yields significant stability gains by mitigating the nose-up pitch that can lead to flips. Wind tunnel data indicate that these devices reduce nose-up pitch, primarily through the disruption of airflow over the roof, which keeps the vehicle's tires grounded and enhances overall control. This effect indirectly boosts cornering grip by ensuring better tire contact with the track surface, allowing drivers to steer more effectively out of uncontrolled rotations.^[23] A key aerodynamic outcome is the substantial reduction in lift, as demonstrated by wind tunnel testing showing a decrease in the lift coefficient following deployment. This generates downforce, counteracting the upward forces that cause lift-off at high yaw angles. The net result is improved vehicle stability during spins compared to unflapped configurations.^[24]^[25] While effective for stability, roof flap deployment introduces trade-offs, including an increase in straight-line drag, which functions similarly to an air brake by slowing the vehicle. This drag penalty is minimal and negligible during emergency activations, where the priority is preventing airborne incidents rather than maintaining speed. The airflow principles enabling these effects, such as pressure buildup over the roof, are detailed in the mechanism of operation.^[26]^[12]

Applications

NASCAR

Roof flaps have been a standard safety feature in NASCAR vehicles since their mandate following high-speed flips in the early 1990s, designed to deploy during spins and increase drag to prevent cars from becoming airborne.^[11] In the Cup Series, they became integral to the Gen-6 car design in 2013 with larger dimensions—approximately 10 inches by 18 inches compared to the previous 8 by 12—to enhance effectiveness at restrictor-plate tracks like Daytona and Talladega, where speeds can exceed 200 mph in drafting packs.^[1]^[27] With the introduction of the Next Gen car in the 2022 Cup Series season, roof flaps were seamlessly integrated into the composite body structure, maintaining their core function while complementing a new lower diffuser flap for added downforce during slides.^[28] This integration uses the symmetric composite roof produced by suppliers like Five Star Fabricating, ensuring durability and consistent deployment without altering the lower roofline.^[5] Roof flaps remain mandatory across all three national series—Cup, Xfinity, and Craftsman Truck—with variations in configuration: Cup and Xfinity cars typically feature two flaps near the rear, while Trucks use a single roof flap, implemented in the series' early years in the mid-1990s to match safety standards.^[1]^[29] For superspeedway packages, NASCAR adapted the flaps further by enlarging them specifically for restrictor-plate racing, where qualifying and pack speeds at Daytona have reached up to 205 mph, necessitating quicker deployment to counter the increased lift forces from side-to-side drafting.^[1]^[27] These adaptations include canvas "parachutes" attached beneath the flaps to trap more air, proven effective in incidents like the 2013 Daytona Preseason Thunder testing crash, where a car remained grounded after a 190-plus mph impact.^[1] Maintenance protocols emphasize rigorous pre-race inspections, focusing on spring tension to ensure proper latching and deployment thresholds, as flaps are spring-loaded to activate at yaw angles exceeding 45-60 degrees.^[30]^[31] Failures, such as improper tension or unauthorized modifications like machined spacers, trigger immediate confiscation and can lead to penalties; for instance, in 2013 at Daytona, 31 teams across Cup and then-Nationwide Series had flaps seized for further scrutiny, though no fines were issued after review, highlighting NASCAR's deterrence system for repeated infractions.^[32] Similar inspection lapses in 2015 contributed to broader enforcement under the updated penalty guidelines, where multiple warnings escalated to P1-level fines and points deductions.^[33]^[34]

Other Series

The concept of roof flaps, originally developed for NASCAR, has influenced safety features in other motorsport series, particularly those involving high-speed oval racing. In the IndyCar Series (formerly IRL), similar passive aerodynamic devices known as rear wing beam flaps were introduced in 2016 specifically for oval tracks to mitigate blowover risks during spins.^[35] These flaps, mounted on the rear wing between the main plane and endplates, automatically deploy when airflow reverses, creating drag to keep the car planted and reducing the likelihood of airborne incidents, as demonstrated in crashes like Spencer Pigot's during the 2016 Indianapolis 500.^[36] Unlike the roof-mounted design in stock cars, IndyCar's implementation focuses on the rear wing for integration with open-wheel aerodynamics, though it shares the core principle of disrupting lift without electronic control.^[37] Adoption remains limited in series like Formula 1 and IMSA due to divergent aerodynamic philosophies that prioritize ground-effect downforce and active systems over passive roof flaps. In Formula 1, cars rely on low ride heights, diffusers, and floor designs to generate downforce, rendering roof flaps unnecessary for stability, while overtaking aids like the Drag Reduction System (DRS) address performance rather than emergency lift prevention.^[38] Similarly, IMSA prototypes and GT cars use fixed elements like shark fins on rear wings to provide constant anti-lift stability, akin to a perpetually deployed flap, but without the dynamic deployment of traditional roof flaps.^[39] The concept has influenced passive aero safety devices in other stock car-inspired series globally.

Safety Impact

Improvements

The introduction of roof flaps in 1994 has significantly reduced airborne incidents in NASCAR, with upwards of 15 rollovers in a single season in the early 1990s becoming rare occurrences thereafter.^[15] No driver has been killed in a lift-off crash since their implementation, marking a pivotal advancement in preventing catastrophic airborne events.^[15] Roof flaps have proven particularly effective in multi-car wrecks at restrictor-plate tracks like Daytona and Talladega, where high-speed drafting often leads to chain-reaction collisions; by disrupting airflow and generating downforce, the flaps keep vehicles grounded, allowing them to slide into barriers rather than becoming projectiles.^[1] These aerodynamic devices complement other safety innovations, such as the stiffer chassis introduced in the 2007 Car of Tomorrow, which enhances structural integrity during potential rollovers, and the Head and Neck Support (HANS) device, mandatory since 2001, which mitigates injury risks from head and neck forces in grounded but high-impact crashes, forming a layered approach to rollover prevention.^[40]^[41]

Regulations

In NASCAR, roof flaps are mandatory safety devices on all Cup Series and Xfinity Series vehicles, positioned near the rear of the roof with one flap aligned along the vehicle's centerline and the second oriented at a 45-degree angle to address common spin directions.^[10] These flaps, constructed from carbon fiber composite, measure approximately 10 inches by 18 inches following a 2013 redesign to enhance their aerodynamic effectiveness in preventing lift-off. In the 2022 Next Gen cars, the system was refined with a cable linking the roof flaps to a rear diffuser flap, ensuring synchronized activation for better control during backward slides.^[10]^[5] They deploy automatically to a roughly 90-degree angle when airflow under the flaps exceeds that over the roof, generating downward force to keep the car grounded during spins or backward motion.^[9] NASCAR conducts rigorous testing of roof flaps in wind tunnels capable of simulating full 360-degree yaw angles to verify deployment under high-speed, multi-directional conditions.^[1] Rule specifications, including flap dimensions, materials, and deployment mechanisms, are detailed in the official NASCAR Rule Book and updated annually through technical bulletins issued by NASCAR's Research and Development Center to incorporate safety advancements and address emerging issues.^[1] Non-compliance with roof flap regulations can result in severe penalties, including disqualification, points deductions, and monetary fines. For instance, in 2013 at Daytona International Speedway, 31 teams were found to have illegal spacers on their roof flap hinges during pre-race inspection, though NASCAR opted not to impose penalties after a review determined no competitive advantage was gained.^[42]

References

[1]
New roof flaps help NASCAR keep cars grounded
Jan 18, 2013 · The larger, redesigned roof flaps on the new Sprint Cup Series cars, the latest weapon in the battle to prevent vehicles from going airborne at restrictor- ...
[2]
NASCAR LEARNS TO KEEP TIRES ON THE GROUND
Jack Roush had installed the prototype on one of his cars, and the flaps withstood the forces from the jet engines." Although it was the holiday season, NASCAR ...
[3]
Memorable wrecks at Talladega Superspeedway - NASCAR.com
Sep 28, 2023 · After Wallace's crash, NASCAR added roof flaps on the tops of cars. 3 of 22. RacingOne/2011 RacingOne. 1996 Winston Select 500. Thirteen cars ...
[4]
Top 10 List: The Wrenches | NASCAR Hall of Fame | Curators' Corner
Jan 23, 2021 · Roush is responsible for pioneering the roof flaps used to keep ... Jack Roush (2019) to form Roush Yates Engines. In winning three ...
[5]
Next Gen design carries legacy of safety into future - NASCAR.com
May 5, 2021 · Roof-mounted air flaps that deploy during a spin carry over from the current car, but the Next Gen model includes a cable that connects the roof ...
[6]
NASCAR to mandate right-side air deflector at Daytona
Aug 21, 2024 · NASCAR will mandate a new right side rear-window air deflector beginning with Saturday's Coke Zero Sugar 400 at Daytona International Speedway.
[7]
NASCAR to debut new A-post flap for Cup Series race at Daytona
Nov 5, 2025 · NASCAR® and its marks are trademarks of the National Association for Stock Car Auto Racing, LLC The RaceView® trademark is owned by Turner ...
[8]
What Are the Roof Flaps on a NASCAR Stock Car?
Apr 28, 2024 · Roof flags change the airflow over the car, which pushes the car back down onto the racing surface. Chris Rice in the video above compares it to ...
[9]
The Flap over Roof Flaps - Building Speed
Jul 5, 2013 · As shown at left, the roof flaps are flaps of metal that are normally flush with the roof.
[10]
NASCAR's new A-post flaps aim to keep cars from becoming airborne
Aug 21, 2025 · The roof flaps are like a parachute that forces the air moving over the car to slow down. NASCAR made the roof flaps larger in 2013. A ...
[11]
Developing NASCAR's Gen 7 Aerodynamics - Racecar Engineering
Jan 28, 2022 · The Next Gen features the passively deployed bonnet (hood), and roof flaps NASCAR uses in all its vehicles, but the diffuser presented a new ...
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[13]
https://doi.org/10.4271/942522
[14]
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Mar 7, 2021 · Prior to the advent of roof flaps, rollover accidents in the 1990s threatened NASCAR's very existence as we know it.
[15]
No penalties for unapproved roof spacers - Official Site Of NASCAR
Jul 10, 2013 · The spacers support the hinge bar of the roof flap, which is a safety mechanism designed to keep the car on the ground in the event of a spin. ...
[16]
The Development and Manufacture of a Roof Mounted Aero Flap System for Race Car Applications
### Summary of Roof Flap System Development for NASCAR
[17]
NASCAR HOPES NEW ROOF FLAPS KEEP CARS GROUNDED
One source said wind-tunnel tests showed the flaps may help keep a car on the ground at speeds as high as 180 mph. Without them, cars can begin to lift at ...Missing: development collaboration
[18]
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[19]
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Generation 4 (NASCAR) - Wikipedia
... ARCA Racing Series until 2017. The generation has been described as the ... To keep cars firmly planted, roof flaps were required in 1994. 1994 was ...
[21]
WALLACE TAKES RAP FOR UNAPPROVED FLAPS, WILL START ...
But NASCAR's penalty for use of ``unapproved'' roof flaps put driver Rusty Wallace in an unenviable position in today's $1.5 million NASCAR Winston Cup race.
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30-day returnsNov 30, 1994 · The Development and Manufacture of a Roof Mounted Aero Flap System ... SAE Technical Paper 942522, 1994, https://doi.org/10.4271/942522 ...
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Closed Wheel Race Vehicle Aerodynamic Lift-Off | Request PDF
Oct 14, 2025 · Drag coefficient, lift coefficient, and velocity contours were ... Ultimately, a roof flap system was produced that has significantly ...
[27]
[PDF] ADVANCES IN VEHICLULAR AERODYNAMICS
Roof Flaps: NASCAR roof flaps typically work similar to the air brakes used on jets. When engaged, the roof flaps obstruct the aerodynamic flow due to ...
[28]
Why Two and Not Three Cars in a Draft? - Building Speed
Feb 13, 2011 · ... speed, it can become airborne, even when its roof flaps deploy. There's not a magic “take-off” speed ... 150 miles per hour! Enjoy your ...
[29]
NASCAR, manufacturers unveil Next Gen models for 2022 Cup Series
May 5, 2021 · Roof flaps will carry over to the new-generation car, but it will also include a lower-mounted diffuser flap that deploys to help keep cars on ...
[30]
This is a roof flap off of a Truck Series truck. Anybody got any ideas ...
Apr 6, 2020 · Could be off the red #8 truck Chad McCumbee drove for MPD motorsports in 2009.TIL While testing roof flaps, Nascar tethered cars to flatbed trailers ...[MovementYT] Kyle Sieg's Blowover today was the first ... - RedditMore results from www.reddit.com
[31]
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Feb 25, 2025 · In this blog post, we'll dissect the intricate world of NASCAR's technical inspection process, exploring the rules, regulations, and potential pitfalls.
[32]
Staying Grounded: How Roof Flaps Work - YouTube
Apr 27, 2016 · NASCAR.com's Jonathan Merryman and Chris Rice break down how roof flaps keep NASCAR Sprint Cup Series race cars on the ground.
[33]
Roof flaps confiscated from 31 teams - ESPN
Jul 4, 2013 · The roof-flap spacers had been illegally machined down to reduce weight. NASCAR inspectors made those Cup teams install new, unaltered roof ...
[34]
NASCAR tackles upswing in inspection failures
Apr 23, 2015 · Based on the 2015 NASCAR Deterrence System, multiple warnings issued to a member or team will result in one or more P1 penalties. Should a team ...Missing: roof flap spring tension
[35]
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Jun 4, 2015 · (AP) NASCAR has declined to penalize the 31 cars that failed inspection in the Sprint Cup and Nationwide Series at Daytona. NASCAR confiscated ...
[36]
IndyCars 'unsettled' by Indy 500 safety rule tweaks - Rahal team
Apr 11, 2016 · IndyCar has also introduced wing flaps that raise during spins, similar to NASCAR's roof flaps.
[37]
IndyCar: Safety changes work in Pigot's crash
May 18, 2016 · Credit the flaps that deployed at the car's rear, IndyCar said. Those flaps, which are similar in principle to the roof flaps NASCAR has ...
[38]
IndyCar 101 – Rear Wing Beam Flaps - LSWT |
May 17, 2016 · The rear wing beam flaps added this year to help slow Verizon IndyCar Series cars when they spin backward on superspeedways like the Indianapolis Motor ...
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How does a Formula 1 car work? Wings, diffusers and more explained
May 31, 2020 · The endplates stop the high-pressured air on top of the wing from spilling underneath, increasing the level of downforce produced. They are ...
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Help me understand the Shark Fin, please. : r/IMSARacing - Reddit
Mar 21, 2024 · Think of the fin like a NASCAR roof flap that is always deployed. It adds inertia and provides an aero moment that pushes the car back down ...Does anyone know why many of the cars have had their roof flaps ...Roof Flaps propped up while at full speed : r/NASCAR - RedditMore results from www.reddit.com
[41]
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Apr 17, 2020 · NASCAR wanted the Car of Tomorrow to satisfy all three issues: cost, safety and competition. Like most experiments, some results were better than expected.
[42]
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Feb 15, 2019 · Roof Flaps. In 1994, NASCAR introduced roof flaps -- a safety device designed to keep cars from going airborne and tumbling over the track.Missing: post- | Show results with:post-
[43]
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Jul 9, 2013 · NASCAR announced that following a thorough review it will not assess any penalties to the 31 teams that had to change out the spacers that support the hinge ...