MQ-125 Right Angle Gearbox MQ-125 Right Angle Gearboxes can output up to 2450 Nm (depends on ratio) Calculate your machine and find the required gearbox output torque using this tool Engineering Calculator Horizontal TabsOverview Performance data: Number of stages: 1 Transmission ratios: 4.83:1 to 83:1 Backlash: <2' and <8' Input motor flanges: For all servomotors Output shaft Single output shaft Double output shaft Hollow shaft with keyway Hollow shaft with shrink disk Typical Applications: Packaging Food Industry Pharma Industry Textile Industry Robotics Conveyors Metal Forming Machines Automated Warehouses General Automation Advantages: Very Low Backlash, thanks to tight tolerances and a constant worm bearing preload, making it ideally suited for machine tool and robotics operations. High Torque, thanks to painstakingly cut, hardened and ground worms and a bronze alloy wheels, born of a unique design process. Quiet operation: The precision high quality worm gearing provides extremelly low noise levels (under 55 dB). Superior Shock Absorption, thanks to a heavyweight cast iron housing. Zero Backlash Motor Coupling. Can be be provided with torsionally rigid coupling for optimal motor shaft alignment. Suitable for intermittent and continuous operation. Compact design. The right angle design can be a space saver. The full transmission ratio in only one stage. Maintenance free thanks to lifetime synthetic lubrication. Input flange for all servomotors brands. Specifications Main Specs Ratio n1 = 1000 rpm n1 = 1500 rpm n1 = 2000 rpm n1 = 3000 rpm Backlash (arcmin) Weight (kg) i T2TH [Nm] T2Max [Nm] η T2TH [Nm] T2Max [Nm] η T2TH [Nm] T2Max [Nm] η T2TH [Nm] T2Max [Nm] η 4.83 1042 2282 0.96 936 2282 0.96 720 2282 0.96 635 2282 0.96 <2' <8' 80 7.25 1296 2450 0.95 1232 2450 0.95 1034 2450 0.95 938 2450 0.95 10 1406 2369 0.94 1337 2369 0.94 1196 2369 0.95 1062 2369 0.95 13 801 1354 0.92 763 1354 0.92 737 1354 0.93 700 1354 0.93 14.5 1426 2450 0.91 1355 2450 0.91 1212 2450 0.92 1054 2450 0.91 20 1555 2450 0.89 1479 2450 0.90 1323 2450 0.91 1175 2450 0.90 26 1063 1822 0.87 1013 1822 0.87 978 1822 0.88 929 1822 0.88 29 1491 2450 0.83 1391 2450 0.83 1268 2450 0.85 1043 2450 0.84 40 1633 2450 0.81 1553 2450 0.82 1389 2450 0.82 1234 2450 0.83 52 1190 2076 0.76 1132 2076 0.77 1092 2076 0.80 1037 2076 0.79 62 1635 2211 0.72 1555 2211 0.73 1391 2211 0.75 1236 2211 0.74 72 1397 1896 0.66 1397 1896 0.68 1318 1896 0.70 1109 1896 0.68 83 1167 1953 0.66 1167 1953 0.68 1167 1953 0.71 167 1953 0.71 Moment of Inertia Ratio J (Kg·cm2) 4.83 46.88 7.25 36.06 10 26.44 13 22.53 14.5 29.57 20 22.86 26 20.39 29 27.95 40 21.97 52 19.86 62 22.10 72 22.08 83 22.05 Dimensions ME 125 A 284 A4 337 B 210 B1 155 B3 145 B6 25 C 25 C1 220 D 38k6 D1 55m6 D1V 60m6 D2 55H7 D3 80 D4 225H7 D6 230 D9 203 D11 25 D12 138 D13 60.5-0.3 D14 60H7 D15 62H7 E 125 E1 250 E4 67.5 F2 300 F3 254 F4 265 G1 187 G2 272 G3 146.4 G7 70 H 359 H1 92 H3 33 I 4.5 K 12 K1 30 L 58 L1 82 L2 50 L3 70 L7 32 L8 31 M 10.2 N 211 O 45 R 240 S M16×25 S1 19 S2 14 S3 M16×25 T 105 T2 41 T3 59 T3V 64 T4 59.3 U1 41 U2 10h9 U3 16h9 U3V 18h9 U4 16JS9 V 3 V1 5 DM, D7, D8, FM, F8, G4, I2, I3, and LM depend on motor dimensions