Cardan Shafts for Industrial Applications - Dana
Cardan Shafts for Industrial Applications - Dana Cardan Shafts for Industrial Applications - Dana
Data sheet series 687/6880.02 with length compensation, tubular design0.03 without length compensation, tubular design9.01 with length compensation, short design9.03 with length compensation, short design9.04 without length compensation, double flangeshaft designDesignML zMG∅W∅S∅KF∅A∅Cb0.02Shaft sizeT CSkNmT DWkNmLc –b
Data sheet series 687/688DesignL f22,5°36°0.0345°L z∅B∅B9.019.03∅H8-hole flange∅H10-hole flangeL fNOTE: Hole patterns not optional.Each cardan shaft size has a specific hole pattern.9.04Design Shaft size 687/688.45 687/688.55 687/688.650.020.039.019.039.04L z min mm 595 703 585 662 681 622 686 686L a mm 110 180 110 110 110 110 110 110G kg 35,7 38,4 37,7 44,0 49,2 47,0 60,6 64,6G R kg 11,44 12,95 11,44 16,86 16,86 16,86 20,12 20,12Jm kgm 2 0,1002 0,1242 0,1342 0,131 – 0,151 0,2224 0,2614Jm R kgm 2 0,0385 0,0357 0,0385 0,055 – 0,055 0,0932 0,0932C Nm/rad. 3,10 x 10 5 2,18 x 10 5 3,10 x 10 5 4,05 x 10 5 – 4,05 x 10 5 5,63 x 10 5 5,63 x 10 5C R Nm/rad. 3,93 x 10 5 3,65 x 10 5 3,93 x 10 5 5,60 x 10 5 5,60 x 10 5 5,60 x 10 5 9,50 x 10 5 9,50 x 10 5L f min mm 425 425 415 475 495 435 491 491G kg 28,0 27,8 30 33,1 – 36,1 47,3 51,3Jm kgm 2 0,0954 0,0976 0,1294 0,1176 – 0,1376 0,2032 0,2422C Nm/rad. 4,82 x 10 5 3,71 x 10 5 4,82 x 10 5 5,39 x 10 5 – 5,39 x 10 5 7,17 x 10 5 7,17 x 10 5L z min mm 517 538 507 587 606 547 601 601L a min mm 70 60 70 70 70 70 70 70L z max mm 557 658 547 617 636 577 641 641L a max mm 110 180 110 100 100 100 110 110L z min mm 447 – 437 513 – 473 524 524L a min mm 50 – 50 50 – 50 50 50L z max mm 507 – 497 563 – 523 584 584L a max mm 110 – 110 110 – 110 110 110L f min mm 380 380 360 460 460 380 440 440L z min = Shortest possible compressed lengthL a = Length compensationL f min = Shortest fi xed lengthL z + L a = Maximum operating lengthGG RJmJm R= Weight of shaft= Weight per 1.000 mm tube= Moment of inertia= Moment of inertia per 1.000 mm tubeCC R= Torsional stiffness of shaft without tube= Torsional stiffness per 1.000 mm tube15
- Page 1: Cardan Shafts forIndustrial Applica
- Page 4: Today, there are basically two type
- Page 8 and 9: Survey of Spicer ® GWB TM cardan s
- Page 10 and 11: Special designs of Spicer ® GWB TM
- Page 13 and 14: Intermediate shafts*(available with
- Page 15: Data sheet series 687/688DesignL f6
- Page 19 and 20: Data sheet series 587DesignL fStand
- Page 21 and 22: Data sheet series 390 Maximum beari
- Page 23 and 24: Data sheet series 392/393 High torq
- Page 25 and 26: Data sheet series 492 Maximum torqu
- Page 27 and 28: Data sheet series 498DesignL fFlang
- Page 29 and 30: Data sheet series 587/190 Super sho
- Page 31 and 32: Data sheet series 230 Quick release
- Page 33 and 34: Data sheet Flange connection with s
- Page 35 and 36: Data sheet Standard companion flang
- Page 37 and 38: Design features series 390/392/3931
- Page 39 and 40: General theoretical instructionsThe
- Page 41 and 42: Technical instructions for applicat
- Page 43 and 44: Technical instructions for applicat
- Page 45 and 46: Technical instructions for applicat
- Page 47 and 48: Technical instructions for applicat
- Page 49 and 50: Technical instructions for applicat
- Page 51 and 52: Selection of Spicer ® GWB TM carda
- Page 53 and 54: Additional information and ordering
- Page 55 and 56: GreeceSokrates Mechanics GmbH205, P
Data sheet series 687/688DesignL f22,5°36°0.0345°L z∅B∅B9.019.03∅H8-hole flange∅H10-hole flangeL fNOTE: Hole patterns not optional.Each cardan shaft size has a specific hole pattern.9.04Design Shaft size 687/688.45 687/688.55 687/688.650.020.039.019.039.04L z min mm 595 703 585 662 681 622 686 686L a mm 110 180 110 110 110 110 110 110G kg 35,7 38,4 37,7 44,0 49,2 47,0 60,6 64,6G R kg 11,44 12,95 11,44 16,86 16,86 16,86 20,12 20,12Jm kgm 2 0,1002 0,1242 0,1342 0,131 – 0,151 0,2224 0,2614Jm R kgm 2 0,0385 0,0357 0,0385 0,055 – 0,055 0,0932 0,0932C Nm/rad. 3,10 x 10 5 2,18 x 10 5 3,10 x 10 5 4,05 x 10 5 – 4,05 x 10 5 5,63 x 10 5 5,63 x 10 5C R Nm/rad. 3,93 x 10 5 3,65 x 10 5 3,93 x 10 5 5,60 x 10 5 5,60 x 10 5 5,60 x 10 5 9,50 x 10 5 9,50 x 10 5L f min mm 425 425 415 475 495 435 491 491G kg 28,0 27,8 30 33,1 – 36,1 47,3 51,3Jm kgm 2 0,0954 0,0976 0,1294 0,1176 – 0,1376 0,2032 0,2422C Nm/rad. 4,82 x 10 5 3,71 x 10 5 4,82 x 10 5 5,39 x 10 5 – 5,39 x 10 5 7,17 x 10 5 7,17 x 10 5L z min mm 517 538 507 587 606 547 601 601L a min mm 70 60 70 70 70 70 70 70L z max mm 557 658 547 617 636 577 641 641L a max mm 110 180 110 100 100 100 110 110L z min mm 447 – 437 513 – 473 524 524L a min mm 50 – 50 50 – 50 50 50L z max mm 507 – 497 563 – 523 584 584L a max mm 110 – 110 110 – 110 110 110L f min mm 380 380 360 460 460 380 440 440L z min = Shortest possible compressed lengthL a = Length compensationL f min = Shortest fi xed lengthL z + L a = Maximum operating lengthGG RJmJm R= Weight of shaft= Weight per 1.000 mm tube= Moment of inertia= Moment of inertia per 1.000 mm tubeCC R= Torsional stiffness of shaft without tube= Torsional stiffness per 1.000 mm tube15
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