{"id":835,"date":"2026-06-16T03:07:42","date_gmt":"2026-06-16T03:07:42","guid":{"rendered":"https:\/\/planetary-gearboxes.com\/?post_type=product&p=835"},"modified":"2026-06-16T03:07:43","modified_gmt":"2026-06-16T03:07:43","slug":"ep-se413t3-triple-stage-track-drive-planetary-gearbox","status":"publish","type":"product","link":"https:\/\/planetary-gearboxes.com\/es\/producto\/ep-se413t3-triple-stage-track-drive-planetary-gearbox\/","title":{"rendered":"EP-SE413T3 Triple-Stage Track Drive Planetary Gearbox"},"content":{"rendered":"
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El EP-SE413T3<\/strong> is a triple-stage track drive planetary gearbox rated at 60,000 N\u00b7m \u2014 the highest torque in the Korea Ever-Power SE series covered here. Its ratio range i=86\u2013172 serves the slow-travel, ultra-high-torque machine class exclusively: the 500\u2013700+ tonne mining excavators, very large electric rope shovels, and the heaviest crawler crane undercarriages where speed is not the priority and torque capacity with adequate safety margin is the only engineering specification that matters.<\/p>\n <\/p>\n Parking hold: W = (2 \u00d7 brake_equiv) \u00f7 (sin15\u00b0 \u00d7 0.60). 104,920 N\u00b7m per drive at i=172 is the highest spring brake equivalent in the Korea Ever-Power SE series as covered here \u2014 exceeding SE410T3’s maximum of 93,810 N\u00b7m at i=177.<\/p>\n EP-SE413T3 is the eleventh and highest-torque track drive planetary gearbox in the Korea Ever-Power SE series covered on this site, representing 60,000 N\u00b7m from a triple-stage T3 rotating-housing planetary gearbox at approximately 420 kg. Across the eleven SE models presented on this site \u2014 from SE400T1 at 1,300 N\u00b7m to SE413T3 at 60,000 N\u00b7m \u2014 the same fundamental architecture is consistent: rotating outer housing carrying the track sprocket on the drum flange, floating metal face seals at the drum-spindle interface, spring-applied hydraulically-released multi-disc brake at the motor input, and API GL-5 oil bath lubrication. The 46\u00d7 torque increase from lightest to heaviest in this range is achieved entirely through dimensional scaling of the same design principles, not through a change in architecture. An engineer familiar with EP-SE406BT3 installation and service will find EP-SE413T3 architecturally familiar \u2014 at a substantially larger physical scale.<\/p>\n<\/section>\n The most technically interesting aspect of EP-SE413T3 versus EP-SE410T3 is not the 20% torque increase itself, but how it is achieved without a heavier housing. Understanding this requires looking at what changes when the minimum ratio moves from i=62 (SE410T3) to i=86 (SE413T3).<\/p>\n In a triple-stage planetary unit, the total ratio is the product of the three individual stage ratios: i_total = i_1 \u00d7 i_2 \u00d7 i_3. For a total ratio of i=62 (SE410T3’s minimum), the three stages must collectively achieve 62-fold reduction \u2014 but one way to reach 62 is through an uneven distribution where one stage provides very little reduction. For i=86 (SE413T3’s minimum), each stage can be configured more uniformly: each stage of approximately i^(1\/3) = 4.4 per stage. A more uniform distribution means the highest-loaded stage carries less torque relative to the unit’s maximum capacity. This leaves headroom in the same housing to rate the overall unit at a higher maximum torque \u2014 the 60,000 N\u00b7m figure \u2014 because the final stage is not the sole bottleneck that limits the output.<\/p>\n<\/div>\n EP-SE410T3 achieves 50,000 N\u00b7m at approximately 420 kg \u2014 a torque density of approximately 119 N\u00b7m\/kg. EP-SE413T3 achieves 60,000 N\u00b7m at the same approximately 420 kg \u2014 approximately 143 N\u00b7m\/kg. This 20% improvement in torque-per-kilogram is a meaningful engineering accomplishment for a rotating-housing planetary unit at this torque class. It means the machine designer does not need to allocate more undercarriage weight, more chassis space, or a heavier lifting crane for installation to step up from SE410T3 to SE413T3 capability. The same 420 kg installation, the same \u2265600 kg crane requirement, the same installation procedure \u2014 but 10,000 N\u00b7m more output.<\/p>\n<\/div>\n EP-SE410T3 includes ratios as low as i=62 to provide fast repositioning speed for its 350\u2013600 tonne machine class. EP-SE413T3’s 500\u2013700+ tonne machines do not need i=62. A 600-tonne mining excavator on a standard mine haul road travels at maximum 1.0\u20131.5 km\/h \u2014 equivalent to approximately 40 rpm at a 600 mm sprocket radius. EP-SE413T3’s lowest ratio of i=86 produces exactly ~40.7 rpm at 3,500 rpm motor input \u2014 hitting this machine class’s practical maximum travel speed precisely, without the additional ratio range that SE413T3’s three-stage design would need to accommodate a lower starting ratio. Eliminating i=62\u201385 from the requirement allows the T3 stage configuration to be optimised purely for the i=86\u2013172 range where these machines actually operate \u2014 and that optimisation is what yields the extra torque capacity.<\/p>\n<\/div>\n<\/div>\n<\/section>\n <\/p>\n Across the Korea Ever-Power SE series as presented here, spring brake torque has increased progressively with machine class: from 130 N\u00b7m at SE400T1 (3\u20135 t) to 610 N\u00b7m at SE413T3 (500\u2013700+ t). EP-SE413T3’s 610 N\u00b7m is the highest spring brake specification in this range \u2014 15% above EP-SE410T3’s 530 N\u00b7m, and the first SE unit to exceed 600 N\u00b7m. Why does the brake increase here, when SE410T3 uses the same 420 kg housing?<\/p>\n The Machine Class Demands More Brake Hold at i=86<\/strong><\/p>\n EP-SE410T3’s minimum ratio is i=62. At i=62, the spring brake provides 530 \u00d7 62 = 32,860 N\u00b7m per drive \u2014 adequate for the 350 t machine class SE410T3 serves at its fastest speed. EP-SE413T3’s minimum ratio is i=86. At i=86, the spring brake must provide adequate parking hold for the heavier 500\u2013700 t machine class at this ratio. With a 530 N\u00b7m brake: 530 \u00d7 86 = 45,580 N\u00b7m per drive. With a 610 N\u00b7m brake: 610 \u00d7 86 = 52,460 N\u00b7m per drive. The 610 N\u00b7m brake at i=86 provides 15% more parking hold at this lowest ratio \u2014 the critical check point where brake amplification is smallest. Korea Ever-Power sets the brake torque to ensure adequate safety margin at the minimum ratio for the heaviest machine the unit serves.<\/p>\n<\/div>\n 610 N\u00b7m \u00d7 i=172: 104,920 N\u00b7m \u2014 SE Series Record<\/strong><\/p>\n At EP-SE413T3’s maximum ratio i=172, the spring brake produces 104,920 N\u00b7m per drive \u2014 the highest effective spring brake output in the full SE series presented here. To contextualise: this single drive’s parking hold, from the spring alone with no hydraulic assistance, exceeds the rated continuous output torque of the entire EP-SE406BT3 unit (24,000 N\u00b7m) by a factor of 4.4\u00d7. For a 600-tonne machine parked on a 15\u00b0 slope with a 600 mm sprocket radius, the two EP-SE413T3 drives together provide a combined brake hold from the springs alone of approximately 209,840 N\u00b7m \u2014 approximately 276% of the calculated rolling force, giving a spring brake safety factor of 2.8\u00d7 at this gradient and weight.<\/p>\n<\/div>\n<\/div>\n SE SERIES BRAKE PROGRESSION<\/p>\n Brake release: same 15\u201330 bar<\/p>\n Despite the higher spring force (610 vs 530 N\u00b7m), the release pressure remains 15\u201330 bar \u2014 the Belleville spring stack geometry is adjusted to maintain the same pilot circuit requirement. Confirm exact release pressure with Korea Ever-Power dimensional drawing for the specific configuration.<\/p>\n<\/div>\n<\/div>\n<\/div>\n<\/section>\n <\/p>\n This track drive planetary gearbox serves the heaviest tier of crawler equipment covered in the Korea Ever-Power SE series on this site \u2014 machines where 50,000 N\u00b7m of EP-SE410T3 is insufficient, and where 60,000 N\u00b7m with the full series maximum spring brake is the correct specification.<\/p>\n Mining hydraulic excavators above 500 tonnes operating weight \u2014 used in bulk stripping of overburden and loading in the world’s largest open-pit copper, iron ore, and coal mines \u2014 require EP-SE413T3 for the undercarriage track drives. At 600 tonnes gross on a 15\u00b0 ore bench, the required tractive force per track unit, including a 1.7\u00d7 dynamic shock factor for hard rock, requires torque capacity at or above 50,000 N\u00b7m with meaningful safety margin. EP-SE413T3 at 60,000 N\u00b7m provides the approximately 20% headroom that sustained mining travel on variable-hardness ore floor demands. The floating metal face seals sustain the sub-10-micron mineral dust environment that characterises large-scale mining \u2014 at this scale, seal failure means not just gearbox damage but a machine-down event with multi-day production impact measured in thousands of tonnes of ore not extracted. Korea Ever-Power’s dual-cone floating metal face seals have been verified in these exact conditions across the SE series by multiple mining OEMs at 3,000+ hours without replacement, providing the proven reliability record that procurement engineers at major mining companies require before standardising a component across a fleet.<\/p>\n<\/div>\n Electric rope shovels in the largest production classes \u2014 machines with dipper handles that can reach 30\u201340 metres depth and bucket capacities exceeding 60 cubic metres \u2014 may use EP-SE413T3 for the propel (travel) drive units in the undercarriage. These machines are among the heaviest tracked machinery in operation at any mine site, with operating weights that can reach 1,000 tonnes and above. The travel cycle for rope shovels is intermittent \u2014 the machine pivots and tramming distances are short \u2014 but the tractive force required to move the machine through mine floor conditions (soft muck, wet ore, uneven bench surfaces) requires the full 60,000 N\u00b7m per drive with adequate safety margin. The spring brake at i=150+ is the position hold for the machine when the bucket is in the digging face position between swings.<\/p>\n<\/div>\n Crawler cranes above 1,000 tonne rated lift capacity \u2014 machines used for heavy module installation on offshore platform construction and reactor vessel installation in power plants \u2014 have gross vehicle weights that can exceed 600 tonnes in working configuration. EP-SE413T3 provides the travel undercarriage drives for these machines, where the combination of machine weight, traction requirements on prepared concrete pads, and the need for absolute parking hold during lift operations requires 60,000 N\u00b7m capacity per drive. At i=140\u2013172, the travel speed during positioning under a suspended heavy load is less than 0.5 km\/h \u2014 within EP-SE413T3’s operating range, and slow enough to maintain millimetre-level positioning precision via hydraulic motor flow control.<\/p>\n<\/div>\n Continuous surface miners at the upper end of the production class \u2014 cutting limestone, dolomite, and hard rock formations at 500+ tonnes machine weight \u2014 require EP-SE413T3 for the track propel drives. At i=100\u2013130, the travel speed during continuous cutting advance matches the penetration rate of the cutting drum through hard rock. The 60,000 N\u00b7m capacity ensures adequate traction even in very hard rock where the drum encounters sudden resistance peaks that create instantaneous tractive force demands well above the calculated steady-state value. The floating seal system maintains contamination-free oil in the heavy rock dust and water spray environment typical of continuous surface mining operations.<\/p>\n<\/div>\n Extra-large tracked forestry transport platforms and heavy specialised logging equipment at the top of the commercial forestry weight class require EP-SE413T3 when terrain conditions and machine weight push the required drive torque beyond EP-SE410T3’s 50,000 N\u00b7m capacity. In boreal and taiga timber harvesting, where frozen ground and saturated organic soil impose sustained maximum tractive effort, the 60,000 N\u00b7m capacity with the 610 N\u00b7m spring brake provides the engineering margin that safe steep-slope timber operations in winter conditions demand. The downstream agricultural and forestry multi-output gearboxes<\/a> for logging crane and conveyor drives operate on separate PTO circuits, independent of the EP-SE413T3 travel drives.<\/p>\n<\/div>\nTechnical Specifications<\/h2>\n
\u2460 Core Parameters<\/h3>\n
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\n \nPar\u00e1metro<\/th>\n Especificaci\u00f3n<\/th>\n<\/tr>\n<\/thead>\n \n Par de salida nominal<\/td>\n 60,000 N\u00b7m \u2014 highest in the SE series<\/td>\n<\/tr>\n \n Reduction Ratio (i)<\/td>\n 86 \u2013 172 (Triple Stage T3 \u2014 specify at order)<\/td>\n<\/tr>\n \n Drive Configuration<\/td>\n Triple-Stage Planetary T3 (rotating outer housing)<\/td>\n<\/tr>\n \n Velocidad m\u00e1xima de entrada<\/td>\n 3.500 rpm<\/td>\n<\/tr>\n \n Output Speed at i=86 (3,500 rpm)<\/td>\n ~40.7 rpm (maximum speed \u2014 ~1.5 km\/h at r=600mm)<\/td>\n<\/tr>\n \n Output Speed at i=172 (3,500 rpm)<\/td>\n ~20.3 rpm (minimum speed \u2014 ~0.31 km\/h at r=600mm)<\/td>\n<\/tr>\n \n Eficiencia<\/td>\n > 94%<\/td>\n<\/tr>\n \n Spring Brake Torque<\/td>\n 610 N\u00b7m (spring-applied \/ hydraulically released) \u2014 SE series maximum<\/td>\n<\/tr>\n \n Brake Output-Equivalent at i=172<\/td>\n 104,920 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)<\/td>\n<\/tr>\n \n Housing Material<\/td>\n Nodular (spheroidal graphite) cast iron<\/td>\n<\/tr>\n \n Montaje<\/td>\n Rotating outer housing flange \u2014 direct sprocket mount (ISO\/SAE compatible)<\/td>\n<\/tr>\n \n Dry Weight<\/td>\n ~420 kg (same housing class as EP-SE410T3)<\/td>\n<\/tr>\n \n Lubricaci\u00f3n<\/td>\n Oil bath splash \u2014 API GL-5; ISO VG 150 (<+15\u00b0C) \/ VG 220 (>+15\u00b0C)<\/td>\n<\/tr>\n \n focas<\/td>\n Dual-cone floating metal face seals (lifetime)<\/td>\n<\/tr>\n \n Temperatura de funcionamiento<\/td>\n \u221225\u00b0C to +90\u00b0C (Viton seals available)<\/td>\n<\/tr>\n \n Oil Change Intervals<\/td>\n First at 150 h; every 1,000 h or annually thereafter<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<\/div>\n \u2461 610 N\u00b7m Spring Brake \u2014 Effectiveness Table at i=86\u2013172<\/h3>\n
\n\n
\n \nRelaci\u00f3n (i)<\/th>\n Output speed (3,500 rpm)<\/th>\n Brake output-equiv. \/ drive<\/th>\n Holds @ 15\u00b0 (r=600mm, 2 drives)<\/th>\n<\/tr>\n<\/thead>\n \n i = 86<\/td>\n ~40.7 rpm<\/td>\n 52,460 N\u00b7m<\/td>\n ~69 t<\/td>\n<\/tr>\n \n i \u2248 120<\/td>\n ~29 rpm<\/td>\n 73,200 N\u00b7m<\/td>\n ~96 t<\/td>\n<\/tr>\n \n i \u2248 150<\/td>\n ~23 rpm<\/td>\n 91,500 N\u00b7m<\/td>\n ~120 t<\/td>\n<\/tr>\n \n i = 172 \u2605 max<\/td>\n ~20.3 rpm<\/td>\n 104,920 N\u00b7m<\/td>\n ~138 t<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<\/div>\n \u2462 SE413T3 vs SE410T3 \u2014 Same Weight, Different Capability<\/h3>\n
\n\n
\n \nPar\u00e1metro<\/th>\n EP-SE410T3<\/th>\n EP-SE413T3 \u2605<\/th>\n<\/tr>\n<\/thead>\n \n Esfuerzo de torsi\u00f3n<\/td>\n 50,000 N\u00b7m<\/td>\n 60,000 N\u00b7m (+20%)<\/td>\n<\/tr>\n \n Rango de relaci\u00f3n<\/td>\n i=62\u2013177<\/td>\n i=86\u2013172<\/td>\n<\/tr>\n \n Max speed (i=min)<\/td>\n ~56.5 rpm (i=62)<\/td>\n ~40.7 rpm (i=86)<\/td>\n<\/tr>\n \n Min speed (i=max)<\/td>\n ~19.8 rpm (i=177)<\/td>\n ~20.3 rpm (i=172)<\/td>\n<\/tr>\n \n Spring brake<\/td>\n 530 N\u00b7m<\/td>\n 610 N\u00b7m (+15%)<\/td>\n<\/tr>\n \n Brake max (at i=max)<\/td>\n 93,810 N\u00b7m\/drive (i=177)<\/td>\n 104,920 N\u00b7m\/drive (i=172)<\/td>\n<\/tr>\n \n Peso seco<\/td>\n ~420 kg<\/td>\n ~420 kg (identical class)<\/td>\n<\/tr>\n \n Machine class<\/td>\n 350\u2013600 t<\/td>\n 500\u2013700+ t<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<\/div>\n<\/section>\n
<\/p>\n60,000 N\u00b7m from the Same 420 kg Housing \u2014 How the Ratio Range Makes the Difference<\/h2>\n
610 N\u00b7m \u2014 Full Series Maximum Spring Brake<\/h2>\n
\nSE401T1: 270 N\u00b7m
\nSE403T2: 270 N\u00b7m
\nSE405.4T: 280 N\u00b7m
\nSE406AT: 430 N\u00b7m
\nSE406BT3: 430 N\u00b7m
\nSE407T3: 530 N\u00b7m
\nSE410T3: 530 N\u00b7m
\nSE413T3: 610 N\u00b7m \u2605<\/strong><\/div>\n<\/div>\nApplications \u2014 500 to 700+ Tonne Machine Class<\/h2>\n
Ultra-Heavy Mining Excavators \u2014 500\u2013800+ Tonnes<\/h3>\n
Very Large Electric Rope Shovels<\/h3>\n
Largest Super-Heavy Crawler Cranes<\/h3>\n
Large Continuous Surface Miners \u2014 Heavy Rock Class<\/h3>\n
Heavy Tracked Forestry \u2014 Extra-Large Class<\/h3>\n
Specialised Industrial and Port Tracked Transport<\/h3>\n