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Composite tension leaf springs: Available for trucks at last | CompositesWorld

Together, the two Spanish companies will outline plans for eVTOL aircraft and operations integration in Europe and Latin America to ensure compatible interaction and maximize aircraft performance.

Following DOA approval, Lilium shifts from the design phase to industrialization, including fuselage matching and joining and a ramp-up of parts production from Tier 1 aerospace suppliers. Flat Springs

Composite tension leaf springs: Available for trucks at last | CompositesWorld

The composites-intensive electric aircraft was purchased to meet the airline’s goal of flying a commercial demonstrator by 2026.

The $37 million contract will enable Piasecki to demonstrate its ARES tilt-duct VTOL aircraft and hydrogen fuel cell propulsion technologies.

Design Organization Approval makes Lilium qualified to design and hold a type certificate for aircraft developed according to the EASA’s SC-VTOL safety objective rules.

The two-seat EL-2 Goldfinch is a blown-lift aircraft filling the gap for air travel routes between 50-500 miles. Certification and entry into service is targeted for 2028.

Combined LSAM and five-axis CNC milling capabilities will optimize D-Composites’ production services, flexibility and cut time and cost for composite tooling manufacture.

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Simutence and Engenuity demonstrate a virtual process chain enabling evaluation of process-induced fiber orientations for improved structural simulation and failure load prediction of a composite wing rib.

3D imaging and analysis capability illustrates detailed, quality characterization and performance simulation of composites and other advanced materials that properly captures the as-manufactured component.

Latest version of comprehensive simulation software speeds up computations and introduces surrogate model functionality.

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Components critical to a bobsled’s functionality — push handles, hand grips and seats — were tailored from Windform materials, heightening both performance and safety for athletes’ racing in the 2026 Winter Olympics.

The inaugural CW From the Archives revisits Sara Black’s 2007 story on out-of-autoclave infusion used to fabricate the massive composite upper cargo door for the Airbus A400M military airlifter.

Holding the new Guinness World Record at 11.98 meters, the 3D-printed composite water taxi used a CEAD Flexbot to print two hulls in less than 12 days.

The novel large-format Flexbot Research XL platform enables TGS to offer 3D printing services, making use of a versatile composite material range.

Startup Fited and Brightlands Materials Center have developed a lighter weight, thinner CFRP corrective brace, including pressure sensors made from continuous carbon fibers.

Components critical to a bobsled’s functionality — push handles, hand grips and seats — were tailored from Windform materials, heightening both performance and safety for athletes’ racing in the 2026 Winter Olympics.

The inaugural CW From the Archives revisits Sara Black’s 2007 story on out-of-autoclave infusion used to fabricate the massive composite upper cargo door for the Airbus A400M military airlifter.

Combined LSAM and five-axis CNC milling capabilities will optimize D-Composites’ production services, flexibility and cut time and cost for composite tooling manufacture.

CW explores key composite developments that have shaped how we see and think about the industry today.

Knowing the fundamentals for reading drawings — including master ply tables, ply definition diagrams and more — lays a foundation for proper composite design evaluation.

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Performing regular maintenance of the layup tool for successful sealing and release is required to reduce the risk of part adherence.

Increasingly, prototype and production-ready smart devices featuring thermoplastic composite cases and other components provide lightweight, optimized sustainable alternatives to metal.

Interest in higher performance and more sustainability drive new composite materials innovations in sporting goods and other consumer products.

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OEMs around the world are looking for smarter materials to forward-think their products by combining high mechanical performance with lightweight design and long-lasting durability. In this webinar, composite experts from Exel Composites explain the benefits of a unique continuous manufacturing process for composites profiles and tubes called pull-winding. Pull-winding makes it possible to manufacture strong, lightweight and extremely thin-walled composite tubes and profiles that meet both demanding mechanical specifications and aesthetic needs. The possibilities for customizing the profile’s features are almost limitless — and because pull-winding is a continuous process, it is well suited for high volume production with consistent quality. Join the webinar to learn why you should consider pull-wound composites for your product. Agenda: Introducing pull-winding, and how it compares to other composite manufacturing technologies like filament winding or pultrusion What are the benefits of pull-winding and how can it achieve thin-walled profiles? Practical examples of product challenges solved by pull-winding

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Tension leaf springs with progressive spring rates meet the demanding needs of truck suspensions.  

BrightDrop electric delivery vans (above) as well as Chevrolet Silverado/GMC Sierra pickups from General Motors Co. feature North America’s first composite tension leaf springs (TLS) with progressive spring rates on rear axles for better ride and lighter vehicles. Photo Credit: General Motors Co. (above) and SPE Automotive Div. (image at top, in line with title)

Last year, some versions of 2022 model year Chevrolet Silverado and GMC Sierra full-size, half-ton pickups and all BrightDrop electric delivery vans from General Motors Co. (GM, Detroit, Mich., U.S.) debuted with North America’s first tension leaf springs (TLS) featured on the rear axles. Compared to a steel leaf spring (SLS), the composite TLS reduces mass significantly for these light- and medium-duty truck programs while improving durability, ride, noise/vibration/harshness (NVH) and more. The road to developing this technology was neither straightforward nor easy.

Leaf springs are an important element of vehicle suspension systems, which themselves are a series of linkages, springs and shock absorbers that connect vehicle wheels and body, enabling both to move relative to each other while permitting control of steering and braking.

They are designed to spring/flex vertically in response to irregular road surfaces and as weight is added to or removed from the vehicle. As such, leaf springs serve multiple functions, such as improving ride smoothness, locating the axle to facilitate turning, controlling vehicle height, protecting cargo from damage and keeping tires aligned on the road.

Leaf springs have been used to improve vehicle ride for hundreds of years, starting with horse-drawn carts and carriages, and were widely used on nearly all motorized vehicles until the 1930s when GM introduced helical coil springs as part of its independent front suspension offerings.

With some exceptions, today SLS are mostly used on commercial vehicles designed to carry heavier loads, including larger trucks, buses, delivery vans and pickups, because their high spring rates and high load capacity make them cost effective versus other suspension options.

There are numerous mono- and multi-leaf spring designs and mounting options, but all essentially feature a relatively thin, curved/bowed plate called a leaf (initially wood and currently metal or composite) or a stack of (usually) progressively shorter leaves joined to each other in a pack via a central bolt and additional external clips.

Lateral/longitudinal leaf springs are oriented parallel to the vehicle’s main axis (front to back) and perpendicular to the axles; transverse leaf springs run parallel to the axles (left to right) and perpendicular to the main axis of the vehicle. With longitudinal leaf springs, which are typically used on the rear suspension, the pack’s center is connected to the axle, its front is connected directly to the frame and its rear is connected to the frame via a shackle (short swing arm) that pivots to compensate as the leaf spring lengthens/shortens in response to the addition/removal of weight, or as the suspension moves up/down in response to a bumpy road.

Most leaf springs are still steel, although that wasn’t always the case. The first composite leaf spring — a filament-wound, compression-molded transverse rear mono-leaf — debuted in 1981 on GM’s C3 (third-generation) Chevrolet Corvette sports car. The new design was lighter, quieter, corrosion-resistant and improved ride. Three years later, the C4 Corvette sported front and rear transverse composite mono-leaf springs (CMLS), a change that enabled the hood line to be lowered. By 1985, GM minivans were equipped with CMLS, and in 1986, luxury cars followed. For the next decade or so, millions of midsize cars used CMLS technology.

In Europe, the Mercedes-Benz Sprinter commercial van from Mercedes-Benz Group AG (Stuttgart, Germany) has sported transverse CMLS in the front for 16 years, and in the rear starting in 2016. However, CMLS technology never took off on North American light-duty or commercial trucks, despite numerous attempts. This is likely due to the linear spring rate characteristic of composite and steel mono-leaf designs and the stepped but still linear rates of steel multi-leaf designs (see sidebar below).

Consequently, most truck suspensions have continued to use multi-leaf SLS or metallic coil springs. Notable exceptions are GM’s 2019 Silverado/Sierra 1500 pickups and 2021 Ford F-150 pickups from Ford Motor Co. (Detroit, Mich., U.S.), which feature the first hybrid multi-leaf spring on rear axles. That system combined a high-strength steel main pack/leaf with a high-pressure resin transfer molded (HP-RTM) fiberglass-reinforced epoxy helper pack (second leaf). The resulting dual spring rate reportedly provided the same stiffness and durability as a multi-leaf SLS at 30% lower mass, while increasing payload capability, reducing part count, decreasing interleaf friction and noise and providing smoother engagement.

Traditional steel or composite mono-leaf springs have linear spring rates regardless of how much weight the vehicle is carrying. Multi-leaf SLS systems offer multiple spring rates. As load is applied to the first bowed leaf spring, it bends/is displaced via suspension travel. Partway through that deflection, the first spring contacts the next leaf spring, which begins to bend, contributing a second spring rate. Hence, a vehicle with a multi-leaf spring will have multiple spring rates, but they are stepped so the transition between rates is not smooth, as shown for the multi-leaf SLS at 30 millimeters’ displacement in the graph below.

This makes a multi-leaf spring more effective at providing a smoother ride than a mono-leaf spring for a vehicle whose load changes regularly as cargo (or occupants/gear) is added/removed and/or as the vehicle travels rougher roads or offroad. However, it won’t create the smoothest ride because of those transitions between one spring rate to the next.

Compared to a steel multi-leaf spring, with linear/stepped spring rates, a tension leaf spring, which offers a progressive spring rate, provides a smoother ride both unloaded (curb weight load) and fully loaded. Photo Credit: Muhr und Bender KG

A better option to ensure a more homogeneous ride regardless of load status or road condition would be to design a leaf spring with a progressive spring rate offering smoother transitions at increasing load and displacement (tension leaf spring curve above). Some metal coil springs do provide progressive spring rates via coil-to-coil or coil-to-seat contact. However, coil springs are less desirable on rear axles (under the cargo-carrying rear box) as they are less efficient at carrying heavy loads. They also are prone to rust, NVH issues and sagging as they age.

Creating an SLS with a progressive spring rate has proven very challenging. To permit a practical amount of suspension travel (the spring’s response to higher loading), the induced strains would be so high that they would lead to severe plastic deformation or outright failure of steel leaves or to severely curtailed suspension travel (with concurrent restrictions in load-carrying capacity) — poor options for commercial vehicles. However, because composites generally offer better fatigue properties than steel and can repeatedly handle high induced strains without permanent deformation or failure, efforts have been focused on composite materials for nearly 15 years.

The ability to incorporate a progressive spring rate into a composite mono-leaf spring was finally solved by Tier 1 Muhr und Bender KG (Mubea, Attendorn, Germany) in 2018. Previously, no leaf spring (regardless of material) offered an infinitely progressive spring rate (see sidebar for more on spring rates). Even then, it took a full decade of R&D effort for Mubea — which has deep experience designing and building suspension systems for passenger and commercial vehicles — to find the right combination of design and materials to prove out the concept and to build a production facility to service the first commercial TLS program in Europe.

Geometry of conventional steel multi-leaf spring (top) versus composite tension leaf spring (bottom, with front of spring on the left and rear of spring on right) — both shown from the side. Photo Credit: Muhr und Bender KG

In terms of geometry, the TLS looks different than typical C-shape mono- or multi-leaf springs. While the front half does curve upward, there is an extra S-curve (elbow) at the rear instead of a shackle that is key to providing a progressive spring rate while still maintaining a reasonable amount of suspension travel. Without a shackle, length compensation occurs via tensile loading in the spring rather than shackle rotation. This induced tensile load adds to the spring rate progressively as spring displacement increases. 

“The ratio between tensile strength and [tensile] modulus is key to making this concept work,” explains Jared Heitsch, Mubea engineering manager – chassis composites. “While our tensile strength is similar to that of steel, our modulus is about one-fifth that of steel. Composite’s lower modulus allows us to induce a high amount of tensile loading in the spring, enabling our progressive [spring] rate while maintaining wheel travel. This concept does not work in steel while still permitting good suspension travel owing to the lower elastic elongation that steel can withstand before yielding.”

Finding the right type of continuous fiber reinforcement for the application proved important. Initial work ruled out carbon fiber because slightly better weight savings came at higher cost. Also, carbon fiber’s higher strength and modulus and penchant for brittleness would have led to the same kinds of restrictions seen in SLS (restricted travel or restricted load-carrying capacity) or would have required modifications to the geometry that would have caused other vehicle-level performance issues, adds Heitsch. As the longitudinally mounted TLS deforms due to displacement, fibers orient to carry high tensile loads in combination with the bending mode of the spring, which progressively resists further deflection. Interaction between both forces provides the progressive spring rate.

In its final form, Mubea’s composite TLS is produced by robotically laying up as many as 60 plies of continuous fiberglass-reinforced epoxy prepreg/tapes (all at zero-degree orientation) and compression molding the stack. The fully automated process offers high repeatability and reproducibility (R&R) and is fast enough to supply high-volume automotive programs like GM’s pickups.

As Mubea’s concept for the TLS evolved, the company talked with automakers in Europe and North America to assess interest. The first customer was Mercedes Benz’s Sprinter van, which switched to a composite TLS on the rear axle in 2018. Meanwhile, Mubea had also been working with GM to prove out the technology on the automaker’s light-duty pickups since 2015. Significant virtual prototyping was done, followed by physical prototyping and small- then large-scale physical testing, including significant on-vehicle testing at GM’s Canadian Technical Centre in Oshawa, Ontario, Canada. Design and testing work was iterative, and each round led to further modifications of the concept and design. Once the technology was proven in GM engineering, the TLS was launched on 2022 Sierra/Silverado pickups.

In a parallel program, work was underway to adapt the technology to GM’s new BrightDrop electric delivery van, which is a larger vehicle designed to carry heavier payloads than either the pickups or the Sprinter van. Being an electric vehicle (EV), weight savings would be more impactful in terms of distance traveled/charge. Although the basic TLS design is the same for both platforms, BrightDrop’s spring is longer and thicker to accommodate that vehicle’s heavier loads. Interestingly, the technology passed all the automaker’s requirements while eliminating the need for shackles, shackle bushings and helper leaves.

Weight savings is a major benefit of the technology change. On Silverados/Sierras, the TLS saved 32 kilograms per vehicle (75% mass reduction) versus SLS and was 58% lighter than the hybrid system on 2019 models. On the BrightDrop Zevo 600, 52 kilograms were saved versus comparable SLS. Lighter leaf springs increased payload capacity while reducing CO2 emissions. This helps the pickups avoid greenhouse gas penalties, which makes the technology lower on a net cost basis.

The TLS also eliminates corrosion and is projected to double the durability/lifespan of SLS while improving ride, thanks to the progressive rate curve, reduction in unsprung mass and elimination of interleaf friction and self-generated noises, which have historically been a major warranty issue with SLS systems. The progressive spring rate also reduces impact loads on the jounce bumpers.

Not only does the tension leaf spring look different than a conventional SLS, but it also performs differently and offers a greater range of benefits. Photo Credit: Muhr und Bender KG

Additional benefits include more flexible design parameters, thanks to the more forgiving production process. For example, lateral stiffness can be improved without degrading ride quality; wind-up/wind-down stiffness is improved and slip-yoke travel is reduced versus SLS, further improving NVH. Wheel recession can be tuned for desired steering characteristics, and the tuning range for suspension damping also is improved thanks to reduced interleaf friction.

“The TLS represents the next evolution in leaf springs and suspension components for light- and medium-duty trucks,” explains Leandro Castro, GM design release engineer. “As such, our peers in industry have recognized its significance with important industry honors, including the 2020 Altair Enlighten Award and the 2022 SPE Automotive Innovation Grand Award.”

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Composite tension leaf springs: Available for trucks at last | CompositesWorld

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