{"id":848,"date":"2026-06-16T03:45:46","date_gmt":"2026-06-16T03:45:46","guid":{"rendered":"https:\/\/planetary-gearboxes.com\/?post_type=product&p=848"},"modified":"2026-06-16T03:45:46","modified_gmt":"2026-06-16T03:45:46","slug":"ep-se419t3-triple-stage-track-drive-planetary-gearbox","status":"publish","type":"product","link":"https:\/\/planetary-gearboxes.com\/ko\/product\/ep-se419t3-triple-stage-track-drive-planetary-gearbox\/","title":{"rendered":"EP-SE419T3 Triple-Stage Track Drive Planetary Gearbox"},"content":{"rendered":"
<\/p>\n \uadf8\ub9cc\ud07c EP-SE419T3<\/strong> is a triple-stage track drive planetary gearbox delivering 330,000 N\u00b7m at up to 2,500 rpm motor input. Its ratio range i=161\u2013306 combines a slightly wider accessible maximum travel speed (i=161 gives ~15.5 rpm) with a 3,000 N\u00b7m spring brake that amplifies to 918,000 N\u00b7m at maximum ratio \u2014 a brake hold capacity that exceeds the full rated torque of every preceding SE unit on this site. At 2,850 kg, it requires a \u22658,000 kg certified crane for installation.<\/p>\n EP-SE419T3 is the sixteenth model in the Korea Ever-Power SE series covered on this site and the most powerful track drive planetary gearbox presented here. Three parameters set new SE series records: 3,000 N\u00b7m spring brake (first time above 2,000 N\u00b7m in the series), 2,500 rpm maximum input speed (SE series minimum), and 2,850 kg dry weight (SE series maximum). The 918,000 N\u00b7m spring brake equivalent at i=306 exceeds the full rated output torque of every preceding SE model \u2014 the brake hold surpasses EP-SE418T3’s rated drive torque of 270,000 N\u00b7m by 3.4\u00d7. Korea Ever-Power provides motor displacement, ratio selection from i=161\u2013306, brake and counterbalance valve adequacy, and dimensional cross-reference same day, no charge, before any order commitment.<\/p>\n W = (2 \u00d7 brake_equiv) \u00f7 (sin 15\u00b0 \u00d7 0.85). 918,000 N\u00b7m at i=306 is the highest spring brake equivalent in the SE series as covered on this site \u2014 26% above EP-SE418T3’s 728,000 N\u00b7m. At minimum ratio i=161, the brake equivalent of 483,000 N\u00b7m already exceeds EP-SE417T3’s full rated output torque (220,000 N\u00b7m) by 2.2\u00d7.<\/p>\n Every SE unit from SE400T1 through SE417T3 held its spring brake at or below 2,000 N\u00b7m. EP-SE418T3 retained 2,000 N\u00b7m. EP-SE419T3 is the first SE unit in this series to exceed that threshold, with a 3,000 N\u00b7m spring brake \u2014 a 50% increase over EP-SE418T3. At i=306 maximum ratio, this produces 918,000 N\u00b7m effective output-side hold per drive. Understanding what this number means in machine and gradient terms explains why the 3,000 N\u00b7m brake is not over-engineering \u2014 it is the engineering minimum for the machine class EP-SE419T3 serves.<\/p>\n At r=850 mm sprocket radius and 15\u00b0 gradient, two EP-SE419T3 drives at i=306 provide combined spring brake hold of 1,836,000 N\u00b7m. The rolling force on a machine at 15\u00b0 is W \u00d7 9.81 \u00d7 sin15\u00b0 \u00d7 r \/ drives. To calculate what machine weight this holds: W = 1,836,000 \u00f7 (9.81 \u00d7 sin15\u00b0 \u00d7 0.85) \u00f7 1,000 = approximately 851 tonnes. A 4,000-tonne dragline on a 5\u00b0 grade produces a rolling force of approximately 4,000,000 \u00d7 9.81 \u00d7 sin5\u00b0 \u00d7 0.85 \/ 2 = 1,456,000 N\u00b7m combined \u2014 within the spring brake hold. At steeper gradients for 4,000+ tonne machines, supplementary counterbalance valves are specified alongside the spring brake, with Korea Ever-Power providing the combined adequacy calculation same day. EP-SE418T3’s maximum hold was 728,000 N\u00b7m per drive (or 1,456,000 N\u00b7m combined): EP-SE419T3 at 918,000 N\u00b7m per drive (1,836,000 N\u00b7m combined) provides 26% more spring brake margin at the same gradient, directly reducing the supplementary valve specification requirement.<\/p>\n<\/div>\n The spring brake torque must satisfy two independent requirements: first, it must provide adequate hold on the steepest operational gradient at the maximum machine weight; second, the brake disc and friction plate material must not exceed safe thermal load during emergency braking from maximum travel speed. At 330,000 N\u00b7m rated drive torque and the machine weights served by EP-SE419T3 (4,000\u201310,000+ tonnes), increasing the spring brake from 2,000 N\u00b7m (as in EP-SE418T3) to 3,000 N\u00b7m was required to satisfy both criteria simultaneously. The 3,000 N\u00b7m brake uses a larger diameter multi-disc stack than EP-SE418T3’s 2,000 N\u00b7m brake, providing greater thermal mass during emergency braking and wider contact area for sustained static hold. At 2,500 rpm maximum input (versus 3,000 rpm for SE418T3), emergency braking from maximum motor speed is also slightly less aggressive in energy terms, contributing to brake disc longevity in the 2,850 kg unit.<\/p>\n<\/div>\n Across the sixteen SE models presented on this site, the spring brake torque has followed the machine class requirements: SE400T1 at 130 N\u00b7m, SE401T1 at 270 N\u00b7m, SE403T2 at 270 N\u00b7m, SE405.4T at 280 N\u00b7m, SE406AT at 430 N\u00b7m, SE406BT3 and SE407T3 at 530 N\u00b7m, SE413T3 at 610 N\u00b7m, SE414T3 and SE415T3 at 1,200 N\u00b7m, SE417T3 and SE418T3 at 2,000 N\u00b7m, and EP-SE419T3 at 3,000 N\u00b7m. Each step in brake capacity corresponded to a step in the machine weight class requiring adequate parking hold. EP-SE419T3’s 3,000 N\u00b7m is not simply the next increment \u2014 it represents the first time the brake torque has exceeded 2,000 N\u00b7m in the SE series, a threshold that reflects the 4,000+ tonne machine class this unit is designed for, where parking on any gradient without supplementary valve assistance becomes achievable at the most commonly used operational ratios.<\/p>\n<\/div>\n<\/div>\n<\/section>\n <\/p>\n EP-SE419T3’s 2,500 rpm maximum input speed is the lowest in the full SE series on this site. SE415T3 and SE417T3\u2013SE418T3 are limited to 3,000 rpm. SE400T1 through SE414T3 allow 3,000\u20133,500 rpm. EP-SE419T3 adds another 17% reduction below the 3,000 rpm of its predecessor. Understanding why this happens \u2014 and what it means for motor selection and ratio range \u2014 is essential for engineers integrating this unit.<\/p>\n At 330,000 N\u00b7m, EP-SE419T3’s final-stage gear pitch circle diameters are larger than in EP-SE418T3 (270,000 N\u00b7m). Pitch-line velocity = \u03c0 \u00d7 d_pitch \u00d7 n \/ 60. For EP-SE419T3 to maintain the same maximum pitch-line velocity at the gear mesh contact \u2014 the limit that governs EHL film thickness and tooth surface fatigue life \u2014 the input speed n must decrease proportionally to the larger d_pitch. At 2,500 rpm, EP-SE419T3’s larger gears operate at a pitch-line velocity equivalent to EP-SE418T3’s gears at 3,000 rpm. Attempting to run EP-SE419T3 at 3,000 rpm would exceed the safe pitch-line velocity for the gear dimensions and tooth load at 330,000 N\u00b7m, leading to oil film breakdown and accelerated surface fatigue. The 2,500 rpm limit is therefore the physically correct specification \u2014 not an arbitrary reduction. Motor displacement must increase proportionally: a motor that operated at 3,000 rpm with EP-SE418T3 would need approximately 20% more displacement to deliver the same shaft torque at 2,500 rpm with EP-SE419T3 at the same hydraulic circuit pressure.<\/p>\n<\/div>\n EP-SE418T3 achieves its deepest output speed (8.24 rpm) through a very high ratio i=364 at 3,000 rpm motor input. EP-SE419T3 achieves almost the same output speed (8.17 rpm) through a lower ratio i=306 at a lower motor input of 2,500 rpm. The net output speed is nearly identical, but the engineering route differs: 2,500 \u00f7 306 = 8.17 rpm (SE419T3) versus 3,000 \u00f7 364 = 8.24 rpm (SE418T3). This matters because the three-stage internal ratio distribution is entirely different. EP-SE419T3’s stage ratios are configured to optimise torque density and load sharing at 330,000 N\u00b7m within the i=161\u2013306 operational band, at 2,500 rpm input \u2014 an entirely different internal engineering from EP-SE418T3’s i=166\u2013364 at 3,000 rpm. The i=161 minimum ratio at 2,500 rpm gives approximately 15.5 rpm output \u2014 slightly faster than EP-SE418T3’s fastest output (18.1 rpm at i=166, 3,000 rpm), providing a marginally wider top-speed ratio for machines that occasionally need to travel slightly faster.<\/p>\n<\/div>\n<\/div>\n<\/div>\n SE SERIES MAX INPUT rpm<\/p>\n <\/p>\n EP-SE419T3 at 330,000 N\u00b7m serves the machines where EP-SE418T3’s 270,000 N\u00b7m drive capacity with its 2,000 N\u00b7m brake is insufficient \u2014 either because machine weight demands more drive torque, because the required spring brake hold at operational gradients requires above 2,000 N\u00b7m, or where the combined torque and brake requirement is met by the 3,000 N\u00b7m brake at 2,500 rpm input.<\/p>\n The very largest bucket wheel excavators and walking draglines ever built \u2014 machines with operating weights above 7,000 tonnes \u2014 include models with crawler-based travel systems where EP-SE419T3 provides the propel drive. At 330,000 N\u00b7m per drive, the tractive force available from two EP-SE419T3 drives at typical sprocket radii satisfies the most demanding mine bench tramming requirements even at machine weights above 7,000 tonnes with full dynamic shock factors. The 3,000 N\u00b7m spring brake at i=250\u2013306 provides a combined hold of 1,500,000\u20131,836,000 N\u00b7m from two drives, covering emergency position hold on bench gradients of 5\u20138\u00b0 even at very high machine weights without supplementary valve assistance.<\/p>\n<\/div>\n TBMs at the extreme upper end of bore diameter \u2014 24+ metre machines planned or built for major waterway crossings, large combined tunnel systems, and major underground infrastructure \u2014 generate thrust requirements per propel unit that exceed what EP-SE418T3 (270,000 N\u00b7m) can provide in the hardest rock with the highest required safety factor per unit. EP-SE419T3 at i=180\u2013220 provides 330,000 N\u00b7m per propel unit with adequate margin at 2,500 rpm motor input, which is already within the operating range of the large-displacement axial piston motors used at this TBM scale. The 3,000 N\u00b7m brake provides substantial position hold per unit, contributing to the combined propel ring emergency hold system in case of hydraulic pressure loss during excavation.<\/p>\n<\/div>\n Electric rope shovels at the absolute top of the production class \u2014 machines with dipper payloads above 120 cubic metres and operating weights approaching 2,500 tonnes \u2014 produce propel drive torque requirements that may reach the EP-SE418T3 boundary at worst-case gradients and with required safety factors, requiring EP-SE419T3 for adequate margin. At 330,000 N\u00b7m per drive with 3,000 N\u00b7m brake, EP-SE419T3 provides significant safety margin above the calculated torque for even the largest rope shovels at 15\u00b0 worst-case gradients. Korea Ever-Power calculates the specific torque requirement for any rope shovel configuration same day.<\/p>\n<\/div>\n The very largest tracked transport and launch platforms in offshore fabrication and marine infrastructure \u2014 systems moving pre-integrated modules, gravity base structures, and subsea infrastructure bundles above 5,000 tonnes \u2014 require EP-SE419T3 when total system weight exceeds the EP-SE418T3 service envelope. Operating in salt water, high-pressure wash environments, and marine atmospheres, the 75\u2013100 litre oil volume and dual-cone floating metal face seals provide the contamination resistance and reserve volume needed for extended deployment cycles between maintenance windows. Auxiliary winch and mooring systems on these platforms use \uc6dc \uae30\uc5b4 \uac10\uc18d\uae30<\/a> for self-locking cable hold, independent of the EP-SE419T3 travel drives.<\/p>\n<\/div>\nEP-SE419T3 \u2014 Triple-Stage Track Drive Planetary Gearbox | 330,000 N\u00b7m, 3,000 N\u00b7m Brake, 2,500 rpm, 2,850 kg<\/h2>\n
<\/p>\n\uae30\uc220 \uc0ac\uc591<\/h2>\n
\u2460 \ud575\uc2ec \ub9e4\uac1c\ubcc0\uc218<\/h3>\n
\n\n
\n \n\ub9e4\uac1c\ubcc0\uc218<\/th>\n \uc0ac\uc591<\/th>\n<\/tr>\n<\/thead>\n \n \uc815\uaca9 \ucd9c\ub825 \ud1a0\ud06c<\/td>\n 330,000 N\u00b7m \u2014 highest in SE series on this site<\/td>\n<\/tr>\n \n Reduction Ratio (i)<\/td>\n 161 \u2013 306 (Triple-Stage T3)<\/td>\n<\/tr>\n \n \ub4dc\ub77c\uc774\ube0c \uad6c\uc131<\/td>\n Triple-Stage Planetary T3 (rotating outer housing)<\/td>\n<\/tr>\n \n \ucd5c\ub300 \uc785\ub825 \uc18d\ub3c4<\/td>\n 2,500 rpm \u2014 SE series minimum; 17% below SE415T3\u2013SE418T3 (3,000 rpm)<\/td>\n<\/tr>\n \n Output at i=161 (2,500 rpm)<\/td>\n ~15.5 rpm \u2014 fastest output in this unit<\/td>\n<\/tr>\n \n Output at i=306 (2,500 rpm)<\/td>\n ~8.17 rpm \u2014 minimum; same as SE418T3 at i=364 (3,000 rpm)<\/td>\n<\/tr>\n \n \ub2a5\ub960<\/td>\n > 93%<\/td>\n<\/tr>\n \n Spring Brake Torque<\/td>\n 3,000 N\u00b7m (spring-applied \/ hydraulically released) \u2014 SE series maximum, first above 2,000 N\u00b7m<\/td>\n<\/tr>\n \n Brake Equiv. at i=306<\/td>\n 918,000 N\u00b7m per drive \u2014 SE series maximum<\/td>\n<\/tr>\n \n Brake Release Pressure<\/td>\n 15\u201330 bar pilot (confirm with Korea Ever-Power dimensional drawing)<\/td>\n<\/tr>\n \n \uc8fc\ud0dd \uc790\uc7ac<\/td>\n \uad6c\uc0c1\ud751\uc5f0 \uc8fc\ucca0<\/td>\n<\/tr>\n \n \uc124\uce58<\/td>\n Rotating outer housing flange \u2014 direct sprocket mount (ISO\/SAE)<\/td>\n<\/tr>\n \n Dry Weight<\/td>\n ~2,850 kg (\u22658,000 kg rated crane required for installation)<\/td>\n<\/tr>\n \n Oil Volume (approx.)<\/td>\n 75\u2013100 litres (confirm from dimensional drawing)<\/td>\n<\/tr>\n \n \ub9e4\ub044\ub7fd\uac8c \ud558\uae30<\/td>\n Oil bath splash \u2014 API GL-5; VG 150 (<+15\u00b0C) \/ VG 220 (>+15\u00b0C)<\/td>\n<\/tr>\n \n \ubb3c\uac1c<\/td>\n Dual-cone floating metal face seals (lifetime; Viton optional)<\/td>\n<\/tr>\n \n \uc791\ub3d9 \uc628\ub3c4<\/td>\n -25\u00b0C ~ +90\u00b0C<\/td>\n<\/tr>\n \n \uc5d4\uc9c4\uc624\uc77c \uad50\ud658 \uc8fc\uae30<\/td>\n First at 150 h; every 1,000 h or annually thereafter<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<\/div>\n \u2461 3,000 N\u00b7m Brake at i=161\u2013306 \u2014 Effectiveness Table<\/h3>\n
\n\n
\n \n\ube44\uc728(i)<\/th>\n Output speed (2,500 rpm)<\/th>\n Brake equiv. \/ drive<\/th>\n Holds @ 15\u00b0 (r=850mm, 2 drives)<\/th>\n<\/tr>\n<\/thead>\n \n i = 161<\/td>\n ~15.5 rpm<\/td>\n 483,000 N\u00b7m<\/td>\n ~448 t<\/td>\n<\/tr>\n \n i \u2248 200<\/td>\n ~12.5 rpm<\/td>\n 600,000 N\u00b7m<\/td>\n ~556 t<\/td>\n<\/tr>\n \n i \u2248 250<\/td>\n ~10.0 rpm<\/td>\n 750,000 N\u00b7m<\/td>\n ~695 t<\/td>\n<\/tr>\n \n i = 306 \u2605 SE max<\/td>\n ~8.17 rpm<\/td>\n 918,000 N\u00b7m<\/td>\n ~851 t<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<\/div>\n \u2462 SE418T3 vs SE419T3 \u2014 Differences<\/h3>\n
\n\n
\n \n\ub9e4\uac1c\ubcc0\uc218<\/th>\n EP-SE418T3<\/th>\n EP-SE419T3 \u2605<\/th>\n Delta<\/th>\n<\/tr>\n<\/thead>\n \n \ud1a0\ud06c<\/td>\n 270,000 N\u00b7m<\/td>\n 330,000 N\u00b7m<\/td>\n +22.2%<\/td>\n<\/tr>\n \n \uc2a4\ud504\ub9c1 \ube0c\ub808\uc774\ud06c<\/td>\n 2,000 N\u00b7m<\/td>\n 3,000 N\u00b7m<\/td>\n +50% \u2190 SE series first >2,000<\/td>\n<\/tr>\n \n Max input rpm<\/td>\n 3,000 rpm<\/td>\n 2,500 rpm<\/td>\n \u221217% \u2190 SE series minimum<\/td>\n<\/tr>\n \n Max ratio<\/td>\n i=364<\/td>\n i=306<\/td>\n \u221216% (compensated by lower rpm)<\/td>\n<\/tr>\n \n Min output speed<\/td>\n 8.24 rpm<\/td>\n 8.17 rpm<\/td>\n \u2248 same (different path)<\/td>\n<\/tr>\n \n Brake max equiv.<\/td>\n 728,000 N\u00b7m<\/td>\n 918,000 N\u00b7m<\/td>\n +26% \u2190 SE series max<\/td>\n<\/tr>\n \n \uac74\uc870 \uc911\ub7c9<\/td>\n ~2,200 kg<\/td>\n ~2,850 kg<\/td>\n +30% \u2190 SE series max<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<\/div>\n<\/section>\n
\u00a0<\/p>\n3,000 N\u00b7m Spring Brake \u2014 The SE Series First Above 2,000 N\u00b7m, and What 918,000 N\u00b7m Hold Means<\/h2>\n
2,500 rpm Maximum Input and i=161\u2013306: Two Constraints, One Engineering Logic<\/h2>\n
\nSE407T3: 3,500 rpm
\nSE413T3: 3,500 rpm
\nSE415T3: 3,000 rpm
\nSE417T3: 3,000 rpm
\nSE418T3: 3,000 rpm
\nSE419T3: 2,500 rpm \u2605<\/strong><\/div>\n<\/div>\n<\/div>\n<\/div>\nApplications \u2014 4,000 to 10,000+ Tonne Machine Class<\/h2>\n
Extreme-Scale Walking Draglines \u2014 7,000\u201310,000 Tonne Class<\/h3>\n
Very Large TBM Propel Rings \u2014 24m+ Bore Diameter<\/h3>\n
Largest Mining Rope Shovels \u2014 Very Highest Production Class<\/h3>\n
Ultra-Scale Offshore and Marine Heavy Crawler Platforms<\/h3>\n
Super-Heavy Land Infrastructure and Civil Development<\/h3>\n