Flywheel Eccentric Training: How to Effectively Generate Eccentric Overload
Reviewed by John Baur, PT, DPT, OCS, CSCS, FAAOMPT
This article explains why and how to use “flywheel eccentric training” to deliberately create eccentric overload—loads greater than what the athlete can produce concentrically—and provides practical programming, safety, and exercise‑selection guidance for sport performance and injury prevention. Eccentric contractions are the active “lengthening” of muscle and are unique in several ways: eccentric strength is ~40% greater than concentric strength; force rises with velocity until it plateaus; the metabolic cost and motor unit recruitment are lower for a given mechanical output; and a phenomenon called residual force enhancement (likely involving titin) can elevate force after lengthening. Together, these neuromuscular and mechanical features make eccentrics especially potent for strength, speed, change of direction (COD), and resilience to injury.
Muscle damage, DOMS, and the repeated‑bout effect. Eccentrics can induce more muscle damage when loads are higher, velocities faster, muscle lengths longer, or individuals are inexperienced; genetics matter too. However, damage is not “inevitable”—unaccustomedness is a major driver—and the repeated‑bout effect rapidly reduces soreness and damage on subsequent exposures. Practically, coaches should progress volume, intensity, and exercise length appropriately, especially when training at long muscle lengths that, while beneficial for adaptations, also heighten DOMS.
What adaptations do eccentrics drive? Compared with concentric work, eccentric training tends to produce larger gains in maximal strength and distinct morphological changes: increased fascicle length, greater serial sarcomere number, region‑specific hypertrophy, lower pennation angle, and increased stiffness. These adaptations underpin stronger sprinting, jumping, stretch‑shortening cycle efficiency, and faster COD—partly by enabling greater braking and propulsive forces with shorter contact times. Meta‑analyses cited in the paper show improved speed, power/jump, and COD performance after eccentric‑biased or flywheel programs.
Why eccentrics are especially relevant in team and racket sports. Match analyses show team sports often involve more and/or more intense decelerations than accelerations, making the ability to absorb force a key determinant of performance and fatigue. For example, in soccer, harsher CODs are linked with neuromuscular fatigue, and the most common goal‑preceding movements include linear advances followed by decelerations and turns. A controlled trial in U23 women’s soccer reported that 10 sessions of lower‑body flywheel eccentric work increased high‑intensity accelerating/decelerating distance and peak/average acceleration–deceleration versus controls, supporting real‑match relevance.
How flywheel devices work and why they’re useful. A flywheel system stores kinetic energy during the concentric phase and returns that inertia to the user in the subsequent eccentric phase, enabling mechanical eccentric overload if programmed correctly. The device is portable, accommodates resistance through the full ROM (no “sticking point”), and lets athletes perform multi‑planar, sport‑specific patterns. Device geometry matters: “horizontal, cylinder‑style” systems generally afford higher eccentric forces, whereas “vertical cone” (“conical pulley”) systems can reach higher velocities. Low inertias behave like light loads (emphasizing velocity and SSC use), high inertias like heavy loads (emphasizing force). The intent is maximal speed in the concentric phase and decisive braking in the eccentric phase. Figure 1 (p. 6) in the article illustrates common devices (squat, leg curl/extension, leg press, pulley, conical pulley, multigym).
Training effects of flywheel eccentric training. Systematic reviews and meta‑analyses highlighted by the author indicate increases in strength, power, sprint speed, and COD, often surpassing gravity‑dependent controls; some umbrella reviews note similar outcomes to traditional resistance training, but overall the weight of evidence is favorable—particularly among younger and well‑trained athletes who “attack” both concentric and eccentric phases. Flywheel eccentric work has also been linked to fewer in‑season injuries in team sport cohorts, potentially via increases in hamstring fascicle length.
Programming guidelines. The paper synthesizes practical guidance (Table 1, p. 8–9):
Power: 2 + 3–6 reps, 1–3 sets, low–medium inertia, short rests; devices like conical pulley/flywheel pulley/squat.
Strength: 2 + 5–8 reps, 1–4 sets, medium–high inertia, longer rests; devices like squat, multigym, leg press, extensions/curls.
Injury prevention: 2 + 5–8 reps, 1–4 sets, low–to–high inertia depending on exercise selection (single‑joint often preferred).
The “2 + x” notation means 2 start‑up “spin‑up” reps to accelerate the wheel, then x maximal reps. Recommended frequency is 1–3 sessions/wk (≥48 h between), with higher inertias requiring more rest between sets.
Weekly scheduling. The author outlines in‑season and two‑match‑week templates (Tables 2–3, pp. 9–10). A common structure is a power session on MD‑4, an upper‑body + microdose lower‑body strength/IP later that day, and a main lower‑body strength/IP on MD‑3, with adjustments for starters vs non‑starters and microdoses after midweek matches when congested. The aim is to maintain strength/IP stimuli without compromising freshness for matches.
Eccentric overload is not automatic. A key caution: only 17 of 79 flywheel studies provided enough data to confirm actual eccentric overload, typically via higher eccentric “peak” power/velocity than concentric. Reasons overload may be absent include submaximal concentric intent (insufficient stored energy), movement mechanics (e.g., peak concentric force in stronger joint angles vs peak eccentric near the turning point), and inexperience. Overload likelihood rises with horizontal cylinder devices, higher inertias, technique that “reduces eccentric time” (e.g., braking in the final third), and user experience. The paper also notes possible gender and experience influences.
Methods to “create” eccentric overload (Figure 3 and photo sequences in Figure 4, pp. 12–14).
- Increase concentric ROM (e.g., add plantarflexion or a late hip rotation) so more energy is generated concentrically than will be absorbed eccentrically.
- Reduce eccentric ROM/time (alternate half/quarter squats; stop the wheel in the last third; or perform a high‑overload “catch,” i.e., attempt an isometric hold low, then yield).
- Coach/athlete/load‑assisted (assist concentric to create more stored energy; assist eccentric by pulling the rope down; or add a hand‑held load only during the eccentric phase).
- Alternate exercises or laterality between phases (e.g., concentric squat → eccentric RDL; or concentric bilateral → eccentric unilateral).
- Combine methods for advanced athletes (e.g., add rotation “and” brake in the last third). Direct device feedback (encoders/force plates via the manufacturer’s app) is encouraged to verify overload and motivate effort.
Safety, technique, and progression. Start with 1–2 exercises for novices; advanced athletes may tolerate 2–4 exercises × 2–4 sets. Ensure the harness is correctly fitted; on squat devices, teach athletes to “immediately” flex hips/knees after lockout to avoid “hanging” at end‑range; cue stable foot placement mid‑platform; and use the device’s stop to finish safely. A touch of plantarflexion at the top can smooth the transition from concentric to eccentric. Tables 4–6 (pp. 14–16) give full lower‑body session examples for athletes at low, medium, and high flywheel competence, including power primers, microdosing, and strength lifts.
Bottom line. Flywheel devices can reliably deliver eccentric overload “when you design for it”, not merely by using the device. Choose the right inertia and device, emphasize maximal concentric intent, shorten eccentric absorption time or increase concentric energy, progress volume thoughtfully, and place sessions intelligently in the weekly plan. Done well, flywheel eccentrics enhance strength, speed, jump, COD, and may lower injury incidence—especially in sports dominated by decelerations.
- C. Eccentric. Eccentric = active lengthening where the muscle “absorbs” energy from an external load (p. 3).
- C. 40%. Eccentric strength is ~40% greater than concentric in men and women (p. 3).
- A. Increases. Eccentric force increases with higher speeds until it plateaus/slightly decreases (p. 3).
- B. Greater pennation angle. Eccentrics tend to “lower” pennation angle while increasing fascicle length and sarcomere number (p. 4).
- A. Increase speed performance. Meta‑analysis shows improved sprint speed after eccentric‑biased training (p.4).
- C. Inertia. The device returns inertia accumulated in the concentric phase to the eccentric phase (p. 5).
- A. Light/heavy. Low/high inertia in flywheel work maps to light/heavy load in traditional training (p. 5).
- A. An increase in muscle fascicle length. Longer fascicles are a plausible mechanism for reduced in‑season injuries observed with flywheel eccentrics (p. 7).
- C. High inertias. High inertias are recommended for strength adaptations (>0.050 kg·m²) (p. 7).
- C. High inertias. Researchers (Raya‑González etal.) recommend high inertias for injury prevention (p.7).
References:
Martínez‑Hernández D. Flywheel Eccentric Training: How to Effectively Generate Eccentric Overload. Strength & Conditioning Journal. 2024;46(2):234‑250.