ETRTO

Articles, guides, and products tagged "ETRTO" — a combined view of every catalogue resource on this topic.

User guide

E-scooter wheel engineering: BS EN ISO 4210-7:2014 wheels (39.7 J drop-ball impact + 640 N static + dynamic), BS EN ISO 4210-2:2023 § 4.10 wheel/tire assembly, ASTM F2641-23 § 8 PMD wheels-and-tires, ETRTO 2024 rim-side (BSD 305 / 349 / 406 / 451 / 507 / 559 / 622 mm), ISO 5775-2:2015 rim designation, rim materials (extruded 6061-T6 / 6082-T6 σ_y 276 MPa vs cast A356-T6/AlSi7Mg 205 MPa vs forged 7075-T6 503 MPa vs PU-foam tubeless vs CFRP T700S), wheel topology (laced 32/36-spoke cross-3 vs cast 5/6/10/12-spoke molded vs solid PU), spoke materials (304 stainless 14g/2.0 mm vs DT Swiss Aerolite ⌀ 2.34×0.9 mm bladed vs Sapim CX-Ray), spoke-tension (Park Tool TM-1 80-130 kgf drive-side, drive/non-drive ratio asymmetry 60:40), wheel-truing tolerance (radial / lateral ±0.5 mm per ISO 4210-7 § 4.10), rim profile (box-section vs single-wall vs double-wall vs aero V-shape, ERD effective-rim-diameter), lacing math (L = √(d² + r² + R² − 2rR·cos(α·k·π/n)) − ⌀h/2 Brandt 1981), failure modes (spoke elbow fatigue / rim crack at spoke-hole / hub-flange crack / cast hairline / PU-foam hardening / bead-seat damage), Hub-motor specifics (BLDC stator embedded, 36-spoke common, rim heat-sink), CPSC recall context (Xiaomi M365 2019, Hover-1/Razor cast-wheel cracks), DIY check / DIY remediation

Engineering deep-dive into the e-scooter wheel unit — rim profile + spokes/cast structure + lacing + wheel-build — paralleling other engineering-axis articles on [tires as the rubber-side interaction](@/guide/tire-engineering-rolling-resistance-grip-standards.md), [bearings as the hub-bearings axis](@/guide/bearing-engineering-iso-281-l10-life.md), and the [frame](@/guide/frame-and-fork-engineering.md). The wheel is an assembly-level engineering axis that integrates rim (profile + material) + spokes (lacing + tension) + hub (bearings, DJ-axis) + tire (DH-axis) into a single load-bearing structure. Covers: 10-row safety-standards matrix (BS EN ISO 4210-7:2014 wheels, BS EN ISO 4210-2:2023 § 4.10 wheel/tire assembly, BS EN ISO 4210-9:2014 hub bolt-axle/QR, ASTM F2641-23 § 8 PMD wheels-and-tires, ETRTO 2024 rim-side, ISO 5775-2:2015 rim designation, EN 14764:2005 § 4.6 wheels and tires, JIS D 9402 bicycle wheel test); 7-row ETRTO BSD table (305 mm 16″ children / 349 mm 16″ Brompton-style folding / 406 mm 20″ BMX-style / 451 mm 20″ road-style / 507 mm 24″ MTB / 559 mm 26″ MTB / 622 mm 700C road); 8-row materials matrix (extruded 6061-T6 / extruded 6082-T6 / cast A356-T6 / cast AlSi7Mg / forged 7075-T6 / PU-foam tubeless / CFRP T700S / 4130 chromoly steel — with σ_y, σ_t, E, ρ, σ_y/ρ, manufacturability); 5-row spoke materials (304 stainless 14g/2.0 mm / 14-15g butted / DT Swiss Aerolite bladed / Sapim CX-Ray / titanium grade 5); 6-row failure-diagnostic matrix; 8-step DIY check + 6-step DIY remediation; 17 numbered sections from anatomy (8 components) → wheel topology (3 types) → rim profile (4 types) → ERD effective-rim-diameter + lacing math (Brandt formula) → spoke-tension (Park Tool TM-1 chart) → wheel-impact test rig (BS EN ISO 4210-7 § 4.2 drop ball 22.5 kg × 180 mm = 39.7 J) → static load (640 N) → truing tolerance (±0.5 mm) → hub-motor specifics → CPSC recall corpus (Xiaomi M365 wheel-bearing 2019, Hover-1/Razor cast-wheel hairline cracks) → DIY check/remediation + 8-point recap.

15 min read

User guide

Carrying cargo and payload on an e-scooter: backpack vs panniers vs handlebar bag vs frame bag vs deck-mounted, max-payload engineering, weight distribution and effects on stopping distance / range / CoG / stability / tire pressure / motor thermal load

Carrying cargo on an e-scooter is not «just throw on a backpack» — it is a separate engineering discipline in which every extra 5 kg changes five parameters at once: stopping distance (through disc heating and pad fade), CoG height (the difference between a backpack at the shoulders +1.4 m above the deck and a load on the deck itself +0.2 m is up to ±0.1 m of composite-CoG shift, which changes the tip-over threshold and the wheelie limit), tire footprint and optimal pressure (ETRTO targets 15 % tire drop, ΔP ≈ 0.5 psi per +5 kg), range (every 9 kg of additional mass eats 5–10 % of range on flat ground and 10–20 % on uphill per Ride1Up and EBIKE Delight data), motor thermal load (power splits between traction force and gravity on grade, MOSFET overheating scales with the square of current). Manufacturer max-loads range from 100 kg (Segway Ninebot ES4) through 130 kg (Segway MAX G3) and 150 kg (Apollo Pro, Segway GT3) to 180 kg (Kaabo Wolf King GTR) — and that is total deck load, meaning `m_rider + m_apparat (not counted if you hold it) + m_cargo` must remain within a 15 % margin of spec due to frame fatigue, brake-component wear and folding-mechanism stress. The five most common carrier formats — backpack, panniers, handlebar bag, frame bag, deck-mounted — rate differently across five metrics (CoG-impact, steering-impact, fold-impact, capacity, accessibility). This guide is drill-oriented: composite-CoG physics, weight-redistribution formulas, a 7-step securing protocol and an 8-point pre-ride checklist. ENG-first sources: eridehero / Unagi / Levy / NAVEE manufacturer specs, XNITO load-weight-and-braking analysis, Rene Herse / SILCA tire-pressure (Frank Berto 15 % drop standard, ETRTO 20 % deflection), arXiv 1902.03661 tire-deformation paper, Ride1Up / EBIKE Delight / QuietKat range formulas, RegenCargoBikes / Academia.edu cargo-bike CoG physics, Letrigo / ADVMoto / Bike Forums cargo-securing best practices.

14 min read

User guide

E-scooter tire engineering: contact patch, rolling resistance Crr, Kamm circle, rubber compound, and ETRTO / ISO 5775 / DOT FMVSS 119 / EN 17128 / UTQG standards

Engineering deep-dive into the e-scooter tire subsystem — parallel to the introductory «Suspension, wheels and IP-protection» reference: contact-patch physics (p_infl · A_contact ≈ W_load — hydrostatic balance), rolling resistance (Crr = F_rr / N — 80–90 % from hysteretic loss in viscoelastic rubber, 10–20 % from aero and bearings), Kamm/friction circle (F_lat² + F_long² ≤ (μ · N)² — fundamental simultaneous-grip limit), slip ratio and slip angle plus Pacejka Magic Formula (cornering stiffness Cα with 3–6° peak), hydroplaning physics (Vp = 10,35 · √p — NASA TN D-2056 1963 for aviation tires, ~ 0,5 × NASA-formula realistic for scooter pad geometry), polymer compound composition (NR natural rubber from Hevea brasiliensis, SBR styrene-butadiene 23–40 %, BR butadiene, halogenated butyl IIR/CIIR for tubeless airtight; silica vs carbon black filler with BET surface area + Si69 coupling agent; sulfur vulcanization vs peroxide; Shore A hardness 50–80 + Tg glass transition; magic triangle wet grip ↔ rolling resistance ↔ wear), casing construction (bias-ply 45–60° crossed vs radial 90° + circumferential belt — 30 % bigger contact patch in radial at 22 psi per Schwalbe testing; TPI 60/120/240+, aramid/nylon belt, hookless TSS vs UST), tread patterns (slick / semi-slick / multi-block off-road, evacuation grooves), tubeless sealant chemistry (NR latex + 1,3-propanediol + viscous polymer in Schwalbe DocBlue / Slime / Stan's NoTubes — temperature range −20…+60 °C), and full comparison matrix of ≥8 safety standards (ETRTO Standards Manual 2024 + ISO 5775-1:2023 Part 1 dimensions + DOT FMVSS 119 49 CFR § 571.119 endurance test + UTQG 49 CFR § 575.104 treadwear/traction/temperature + EN ISO 4210-7:2014 bicycle rims/tires test methods + EN 14781:2005 racing bicycle + EN 17128:2020 PLEV § tire pressure marking + ECE R75 Rev 2 motorcycle/L-category + SAE J1100); engineering ↔ symptoms diagnostic matrix; 8-point recap.

18 min read