Post on 16-Mar-2018
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High-Performance Universal Joint Shafts Products | Engineering | Service
Universal Joint Shafts and Hirth Couplings
We are the experts for cardanic power transmission components and Hirth couplings at
Voith Turbo.
Voith Turbo, the specialist for hydrodynamic drive, coupling and braking systems for road,
rail and industrial applications, as well as for ship propulsion systems, is a Group Division
of Voith AG.
Voith is one of the largest family-owned companies in Europe with a workforce of around
39,000, EUR 5.1 billion in sales in the 2008/2009 fiscal year and 280 sites worldwide. The
company is active in the energy, oil and gas, paper and raw materials as well as transpor-
tation and automotive markets around the world.
3Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Contents
1 Voith high-performance universal joint
shafts – What makes them unique? 4
2 Range 6
3 Designs 8
4 Applications 9
5 Definitions and abbreviations 12
5.1 Lengths 12
5.2 Torque loads 13
6 Technical data 14
6.1 Series S 14
6.2 Series M 16
6.3 Series W 18
6.4 Series H 20
6.5 Series E 22
7 Complementing products and services 24
7.1 Engineering 24
7.2 Connecting components for universal
joint shafts
25
7.3 Quick-release coupling GT 26
7.4 Voith Hirth serrations 27
7.5 Universal joint shafts supports 28
7.6 Safeset safety couplings 29
7.7 ACIDA torque monitoring systems 30
8 Engineering basics 31
8.1 Major components of a Voith universal
joint shaft
31
8.2 Length compensation with SAE or
involute profile 32
8.3 Kinematics of the universal joint 34
8.4 Two universal joints 37
8.5 Bearing forces on input and output shafts 38
8.6 Balancing of universal joint shafts 41
9 Selection Aids 42
9.1 Definitions of operating variables 42
9.2 Size selection 44
9.3 Operating speeds 47
9.4 Masses and mass moments of inertia 50
9.5 Installation: Connecting flanges, bolted
connections 54
10 Service 58
10.1 Installation and commissioning 59
10.2 Training 60
10.3 Voith genuine spare parts 61
10.4 Overhaul, maintenance 62
10.5 Repairs, maintenance 63
10.6 Modernization, retrofits 64
11 High-performance lubricant
for universal joint shafts 65
12 Quality – Environment – Safety 67
12.1 Quality 68
12.2 Environment 69
12.3 Occupational health and safety 70
4 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
1 Voith high-performance universal joint shafts – What makes them unique?
Features Advantages Benefits
n Closed bearing eye n Heavy-duty cross-sections without joints or boltsn Minimal notch stressesn Enclosed seal surfaces
n Productivity increasen Long service life
n Drop-forged journal crosses n Best possible torque capacity
n FEM-optimized geometry n Optimal design for torque transmissionn Minimal notch stresses
n High strength tempering and case hardened steels n Capability to withstand high static and dynamic loads
n Load-optimized welded joints n Optimal design for torque transmission
n Length compensation with SAE profile (straight flank profile) for larger series
n Low normal forces and thus lower displacement forces
n Low surface pressuren High wear resistance
n Ease of movementn Long service life
n Patented balancing procedure n Dynamic balancing in two planesn Balancing mass where unbalanced forces act
n Extremely smooth operation
n Engineering and product from a single source n One contact person when designing the drive line n Time and cost savingsn Combined responsibility
n Certifications and classifications for rail vehicles and marine vessels n Officially approved product n Time and cost savings
n Made in Germany n Seal of approval for quality, efficiency and precision
n Reliability
n "Engineered reliability" n Competent and trustworthy partner n Innovative product and system solutions
Assembly building for Voith universal joint shafts Welding robot
5Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Features Advantages Benefits
n Closed bearing eye n Heavy-duty cross-sections without joints or boltsn Minimal notch stressesn Enclosed seal surfaces
n Productivity increasen Long service life
n Drop-forged journal crosses n Best possible torque capacity
n FEM-optimized geometry n Optimal design for torque transmissionn Minimal notch stresses
n High strength tempering and case hardened steels n Capability to withstand high static and dynamic loads
n Load-optimized welded joints n Optimal design for torque transmission
n Length compensation with SAE profile (straight flank profile) for larger series
n Low normal forces and thus lower displacement forces
n Low surface pressuren High wear resistance
n Ease of movementn Long service life
n Patented balancing procedure n Dynamic balancing in two planesn Balancing mass where unbalanced forces act
n Extremely smooth operation
n Engineering and product from a single source n One contact person when designing the drive line n Time and cost savingsn Combined responsibility
n Certifications and classifications for rail vehicles and marine vessels n Officially approved product n Time and cost savings
n Made in Germany n Seal of approval for quality, efficiency and precision
n Reliability
n "Engineered reliability" n Competent and trustworthy partner n Innovative product and system solutions
Welding robot Balancing machine Shipping
6 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Series Torque rangeMz [kNm]
Flange diametera [mm]
Features Applications
S
0.25 to 275 58 to 435
n Standard design of Voith universal joint shaftsn Non-split bearing eyes thanks to single-piece forged flange yoken Length compensation with involute profile
n Paper machinesn Pumpsn General industrial machineryn Marine vesselsn Rail vehiclesn Test standsn Construction machinery and cranes
M
32 to 143 225 to 350
n Optimized torsional rigidity and deflection resistance in a low-weight designn Particularly suitable for use with high-speed drivesn Low-maintenance length compensation using plastic-coated (Rilsan®)
involute profile
n Paper machinesn Pumpsn General industrial machinery n Marine vesselsn Rail vehicles
W
55 to 1,000 225 to 550
n High torque capacityn Optimized bearing lifen Flange with face key, flange with Hirth coupling upon requestn Length compensation with involute profile up to size 390; from size 440 with
SAE-profile (straight flank profile, see page 32)
n Rolling mill drivesn Heavy-duty drives in general engineering
H
260 to 10,000 350 to 1400
n Very high torque capacity n Optimized bearing lifen Flange with Hirth coupling to transmit maximum torquen Length compensation with SAE -profile (straight flank profile, see page 32)
n Rolling mill drivesn Construction of heavy machinery
E
over 16,000 up to 1300
n Maximum torque capacityn Optimized bearings for exceptionally demanding requirementsn Patented 2-piece flange yoken Flange with Hirth coupling to transmit maximum torquen Length compensation with SAE profile (straight flank profile, see page 32)
n Heavy-duty rolling mill drives
2 Range
Voith high-performance universal joint shafts offer an ideal combination
of torque capacity, torsional rigidity and deflection resistance. We supply
standard universal joint shafts, customer-specific adaptations as well as
special designs. Technical consultation, simulation of torsional vibrations
and measurement of operating parameters complete our range of services.
7Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Series Torque rangeMz [kNm]
Flange diametera [mm]
Features Applications
S
0.25 to 275 58 to 435
n Standard design of Voith universal joint shaftsn Non-split bearing eyes thanks to single-piece forged flange yoken Length compensation with involute profile
n Paper machinesn Pumpsn General industrial machineryn Marine vesselsn Rail vehiclesn Test standsn Construction machinery and cranes
M
32 to 143 225 to 350
n Optimized torsional rigidity and deflection resistance in a low-weight designn Particularly suitable for use with high-speed drivesn Low-maintenance length compensation using plastic-coated (Rilsan®)
involute profile
n Paper machinesn Pumpsn General industrial machinery n Marine vesselsn Rail vehicles
W
55 to 1,000 225 to 550
n High torque capacityn Optimized bearing lifen Flange with face key, flange with Hirth coupling upon requestn Length compensation with involute profile up to size 390; from size 440 with
SAE-profile (straight flank profile, see page 32)
n Rolling mill drivesn Heavy-duty drives in general engineering
H
260 to 10,000 350 to 1400
n Very high torque capacity n Optimized bearing lifen Flange with Hirth coupling to transmit maximum torquen Length compensation with SAE -profile (straight flank profile, see page 32)
n Rolling mill drivesn Construction of heavy machinery
E
over 16,000 up to 1300
n Maximum torque capacityn Optimized bearings for exceptionally demanding requirementsn Patented 2-piece flange yoken Flange with Hirth coupling to transmit maximum torquen Length compensation with SAE profile (straight flank profile, see page 32)
n Heavy-duty rolling mill drives
8 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Type Description
…T Universal joint shaft with standard length compensation
…TL Universal joint shaft with extra-long length compensation
…TK Universal joint shaft with short-coupled length compensation
…TR Universal joint shaft with tripod length compensation
Technical data: Please request separate catalog
…F Universal joint shaft without length compensation (fixed-length shaft)
…G Joint coupling: short, separable joint shaft without length compensation
…FZ Intermediate shaft with a joint head and bearing
…Z Intermediate shaft with double bearing
3 Designs
Example of type designation STL1 250.8:
Size 250 (flange diameter 250 mm)
Universal joint shaft with extra-long length compensation
"S" Series universal joint shaft
S TL1 250.8
9Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
4 Applications
Rolling mills (horizontal rolling stand) Rolling mills (vertical rolling stand)
Paper machines
10 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Pumps
Rail drive lines
Test stands
11Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Special drives (winding gear)
Marine propulsion
12 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Universal joint shaft with length compensation Universal joint shaft without length compensation
lB: Operating length (to be provided with order.)
lz: Shortest length of the universal joint shaft (collapsed)
lv: Available length compensation
The distance between the driving and driven machines, together with any length changes during operation, determines the operating length:
Optimum operating length: lB,opt ≈ lz + lv __ 3
Maximum permissible operating length: lB,max = lz + lv
lB: Operating length, corresponds to the universal joint shaft length l (to be provided with order.)
5 Definitions and abbreviations5.1 Lengths
Note:
MDW, MDS and MZ are load limits for the
universal joint shaft. For torque values near
the load limit, the transmission capability of the
flange connection must be checked, especially
when Hirth serrations are not being used.
lB,max
lz lv lB (=l)
13Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Designation Explanation
Components
MDW Is the reversing fatigue torque rating. The shaft will have infinite fatigue life up to this torque.
MDS Is the pulsating one-way fatigue torque rating. The shaft will have infinite fatigue life up to this torque level.Here: MDS ≈ 1.5 · MDW
MK Maximum permissible torque. Above this value, plastic deformation may occur.
Bearing
MZ Permissible torque for rarely occurring peak loads. At torque values above MZ, the bearing tracks might suffer from plastic deformation. This can lead to shorter bearing life.
Flange connections
Designed individually
Universal joint shaft with length compensation Universal joint shaft without length compensation
lB: Operating length (to be provided with order.)
lz: Shortest length of the universal joint shaft (collapsed)
lv: Available length compensation
The distance between the driving and driven machines, together with any length changes during operation, determines the operating length:
Optimum operating length: lB,opt ≈ lz + lv __ 3
Maximum permissible operating length: lB,max = lz + lv
lB: Operating length, corresponds to the universal joint shaft length l (to be provided with order.)
5.2 Torque loads
Note:
MDW, MDS and MZ are load limits for the
universal joint shaft. For torque values near
the load limit, the transmission capability of the
flange connection must be checked, especially
when Hirth serrations are not being used.
M (t)
MDS
MDW
0t
14 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
6 Technical data6.1 Series S
SF
l
SG
lfix
SFZ
ld
l
taga
Ød
General data ST STL 1 STL 2 STK 1 STK 2 STK 3 STK 4* SF SG SFZ SZ SFZ, SZ
Size Mz
[kNm]MDW
[kNm]CR
[kNm]ßmax [°]
a k b ± 0.1 c H7 h C12 lm r t z g LA lv Iz min LA lv Iz min LA lv Iz min LA lv Iz fix LA lv Iz fix LA lv Iz fix LA lv Iz fix Imin Ifix Imin Imin Id d ga ta
058.1 0.25 0.08 0.09 30 58 52 47 30 5 30 28 x 1.5 1.5 4 3.5 A, B 25 240
lz and lv vary, values upon request
B 25 215 B 25 195 B 25 175 B 20 165 160 120
065.1 0.52 0.16 0.16 30 65 60 52 35 6 32 32 x 1.5 1.7 4 4 A, B 30 260 B 30 235 B 30 220 B 30 200 B 20 180 165 128
075.1 1.2 0.37 0.23 30 75 70 62 42 6 36 40 x 2 2.2 6 5.5 A, B 35 300 B 35 270 B 35 250 B 35 225 B 25 200 200 144
090.2 2.2 0.68 0.44 20 90 86 74.5 47 8 42 50 x 2 2.5 4 6 A, B, C 40 350 B, C 40 310 B, C 40 280 B, C 40 250 B, C 25 225 216 168
100.2 3.0 0.92 0.62 20 100 98 84 57 8 46 50 x 3 2.5 6 7 A, B, C 40 375 B, C 40 340 B, C 40 310 B, C 40 280 B, C 30 255 250 184
120.2 4.4 1.3 0.88 20 120 115 101.5 75 10 60 60 x 4 2.5 8 8 A, B, C 60 475 B, C 60 430 B, C 60 400 B, C 50 360 B, C 35 325 301 240
120.5 5.4 1.6 1.4 20 120 125 101.5 75 10 60 70 x 4 2.5 8 9 A, B, C 60 495 B, C 60 450 B, C 60 420 B, C 50 375 B, C 35 345 307 240
150.2 7.1 2.2 2.0 20 150 138 130 90 12 65 80 x 4 3 8 10 C 110 550 C 80 490 C 80 460 C 80 400 C 40 360 345 260
150.3 11 3.3 2.6 35 150 150 130 90 12 90 90 x 4 3 8 12 C 110 745 C 110 680 C 110 640 C 80 585 C 40 545 455 360
150.5 13 4.3 3.3 30 150 158 130 90 12 86 100 x 5 3 8 12 C 110 660 C 110 600 C 80 555 C 45 495 C 40 400 430 344
180.5 22 6.7 4.6 30 180 178 155.5 110 14 96 110 x 6 3.6 8 14 C 110 740 C 110 650 C 60 600 C 45 560 C 60 500 465 384
225.7 35 11 6.9 30 225 204 196 140 16 110 120 x 6 5 8 15 C 140 830 A, D 380 1144 A, D 680 1444 C 110 720 C 80 650 C 55 600 C 40 550 520 440 533 586 171 80 25 4
250.8 45 23 11.4 15 250 208 218 140 18 120 152.4 x 14.2 6 8 18 B, C 140 920 A, D 370 1200 A, D 670 1500 B, C 85 840 B, C 85 780 B, C 85 710 B, C 70 640 520 480 626 732 229 90 32 5
285.8 70 35 19.1 15 285 250 245 175 20 140 165.1 x 14.2 7 8 20 B, C 140 1035 A, D 370 1280 A, D 670 1580 B, C 100 855 B, C 100 795 B, C 60 735 620 560 716 812 251 110 34 6
315.8 100 50 26.4 15 315 285 280 175 22 160 193.7 x 14.2 7 8 22 B, C 140 1190 A, D 370 1430 A, D 770 1830 B, C 120 1025 B, C 120 950 B, C 80 880 720 640 804 883 277 130 42 6
350.8 143 71 36.6 15 350 315 310 220 22 180 219.1 x 16 8 10 25 B, C 140 1315 A, D 370 1570 A, D 770 1970 B, C 130 1160 B, C 130 1070 B, C 90 980 805 720 912 1019 316.5 160 45 7
390.8 200 100 48.3 15 390 350 345 250 24 194 244.5 x 20 8 10 32 B, C 150 1410 A, D 400 1690 A, D 800 2090 B, C 105 1280 B, C 105 1170 B, C 90 1070 855 776 980 1087 344.5 200 48 7
435.8 275 138 67.1 15 435 390 385 280 27 215 267 x 25 10 10 40 B, C 170 1590 A, D 400 1845 A, D 800 2245 B, C 150 1400 B, C 150 1300 B, C 90 1200 955 860 1023 1091 346.5 200 48 9
Dimensions in mm *shorter lZ upon request
15Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
lz
t
lm
lvg
øh
øb
øc
øk ør
øb
z=4
45°
øh
øb
z=6
60°
øh
øb
z=8
22.5°45°
øh
øb
z=10
36°
36°
øa
ST/STL/STK
SZ
ta
lld
ga
ød
General data ST STL 1 STL 2 STK 1 STK 2 STK 3 STK 4* SF SG SFZ SZ SFZ, SZ
Size Mz
[kNm]MDW
[kNm]CR
[kNm]ßmax [°]
a k b ± 0.1 c H7 h C12 lm r t z g LA lv Iz min LA lv Iz min LA lv Iz min LA lv Iz fix LA lv Iz fix LA lv Iz fix LA lv Iz fix Imin Ifix Imin Imin Id d ga ta
058.1 0.25 0.08 0.09 30 58 52 47 30 5 30 28 x 1.5 1.5 4 3.5 A, B 25 240
lz and lv vary, values upon request
B 25 215 B 25 195 B 25 175 B 20 165 160 120
065.1 0.52 0.16 0.16 30 65 60 52 35 6 32 32 x 1.5 1.7 4 4 A, B 30 260 B 30 235 B 30 220 B 30 200 B 20 180 165 128
075.1 1.2 0.37 0.23 30 75 70 62 42 6 36 40 x 2 2.2 6 5.5 A, B 35 300 B 35 270 B 35 250 B 35 225 B 25 200 200 144
090.2 2.2 0.68 0.44 20 90 86 74.5 47 8 42 50 x 2 2.5 4 6 A, B, C 40 350 B, C 40 310 B, C 40 280 B, C 40 250 B, C 25 225 216 168
100.2 3.0 0.92 0.62 20 100 98 84 57 8 46 50 x 3 2.5 6 7 A, B, C 40 375 B, C 40 340 B, C 40 310 B, C 40 280 B, C 30 255 250 184
120.2 4.4 1.3 0.88 20 120 115 101.5 75 10 60 60 x 4 2.5 8 8 A, B, C 60 475 B, C 60 430 B, C 60 400 B, C 50 360 B, C 35 325 301 240
120.5 5.4 1.6 1.4 20 120 125 101.5 75 10 60 70 x 4 2.5 8 9 A, B, C 60 495 B, C 60 450 B, C 60 420 B, C 50 375 B, C 35 345 307 240
150.2 7.1 2.2 2.0 20 150 138 130 90 12 65 80 x 4 3 8 10 C 110 550 C 80 490 C 80 460 C 80 400 C 40 360 345 260
150.3 11 3.3 2.6 35 150 150 130 90 12 90 90 x 4 3 8 12 C 110 745 C 110 680 C 110 640 C 80 585 C 40 545 455 360
150.5 13 4.3 3.3 30 150 158 130 90 12 86 100 x 5 3 8 12 C 110 660 C 110 600 C 80 555 C 45 495 C 40 400 430 344
180.5 22 6.7 4.6 30 180 178 155.5 110 14 96 110 x 6 3.6 8 14 C 110 740 C 110 650 C 60 600 C 45 560 C 60 500 465 384
225.7 35 11 6.9 30 225 204 196 140 16 110 120 x 6 5 8 15 C 140 830 A, D 380 1144 A, D 680 1444 C 110 720 C 80 650 C 55 600 C 40 550 520 440 533 586 171 80 25 4
250.8 45 23 11.4 15 250 208 218 140 18 120 152.4 x 14.2 6 8 18 B, C 140 920 A, D 370 1200 A, D 670 1500 B, C 85 840 B, C 85 780 B, C 85 710 B, C 70 640 520 480 626 732 229 90 32 5
285.8 70 35 19.1 15 285 250 245 175 20 140 165.1 x 14.2 7 8 20 B, C 140 1035 A, D 370 1280 A, D 670 1580 B, C 100 855 B, C 100 795 B, C 60 735 620 560 716 812 251 110 34 6
315.8 100 50 26.4 15 315 285 280 175 22 160 193.7 x 14.2 7 8 22 B, C 140 1190 A, D 370 1430 A, D 770 1830 B, C 120 1025 B, C 120 950 B, C 80 880 720 640 804 883 277 130 42 6
350.8 143 71 36.6 15 350 315 310 220 22 180 219.1 x 16 8 10 25 B, C 140 1315 A, D 370 1570 A, D 770 1970 B, C 130 1160 B, C 130 1070 B, C 90 980 805 720 912 1019 316.5 160 45 7
390.8 200 100 48.3 15 390 350 345 250 24 194 244.5 x 20 8 10 32 B, C 150 1410 A, D 400 1690 A, D 800 2090 B, C 105 1280 B, C 105 1170 B, C 90 1070 855 776 980 1087 344.5 200 48 7
435.8 275 138 67.1 15 435 390 385 280 27 215 267 x 25 10 10 40 B, C 170 1590 A, D 400 1845 A, D 800 2245 B, C 150 1400 B, C 150 1300 B, C 90 1200 955 860 1023 1091 346.5 200 48 9
Dimensions in mm *shorter lZ upon request
LA: Length compensationA: without profile protectionB: with profile protectionC: Rilsan® coating with profile protectionD: Rilsan® coating without profile protection
16 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
General data MT MF MG MFZ
Size Mz [kNm]
MDW [kNm]
CR [kNm]
ßmax [°]
a K b ± 0.1 c H7 h C12 lm r t z g LA lv Iz min Imin Ifix Imin Id d ga ta
225.8 32 16 8.6 25 225 198 196 140 16 110 160 x 10 5 8 15 C 110 780 480 440 535 171 80 25 4
250.8 45 23 11.4 15 250 208 218 140 18 120 170 x 10 6 8 18 C 100 815 520 480 630 229 90 32 5
285.8 70 35 19.1 15 285 250 245 175 20 140 200 x 10 7 8 20 C 100 895 570 560 695 251 110 34 6
315.8 100 50 26.4 15 315 285 280 175 22 160 220 x 10 7 8 22 C 135 1060 680 640 780 277 130 42 6
350.8 143 71 36.6 15 350 315 310 220 22 180 240 x 12.5 8 10 25 C 135 1170 750 720 880 316.5 160 45 7
Dimensions in mmLA: Length compensation
C: Rilsan® coating with profile protection
6.2 Series M
MT
lz
t
lm
lvg
øa
øh
øb
øc
øk
ør
z=8
22.5°
øh
øb
z=10
45°
øb
36°
36°
MF
l
17Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
General data MT MF MG MFZ
Size Mz [kNm]
MDW [kNm]
CR [kNm]
ßmax [°]
a K b ± 0.1 c H7 h C12 lm r t z g LA lv Iz min Imin Ifix Imin Id d ga ta
225.8 32 16 8.6 25 225 198 196 140 16 110 160 x 10 5 8 15 C 110 780 480 440 535 171 80 25 4
250.8 45 23 11.4 15 250 208 218 140 18 120 170 x 10 6 8 18 C 100 815 520 480 630 229 90 32 5
285.8 70 35 19.1 15 285 250 245 175 20 140 200 x 10 7 8 20 C 100 895 570 560 695 251 110 34 6
315.8 100 50 26.4 15 315 285 280 175 22 160 220 x 10 7 8 22 C 135 1060 680 640 780 277 130 42 6
350.8 143 71 36.6 15 350 315 310 220 22 180 240 x 12.5 8 10 25 C 135 1170 750 720 880 316.5 160 45 7
Dimensions in mmLA: Length compensation
C: Rilsan® coating with profile protection
MF
l
MG
lfix
MFZ
ld
l
ga
ta
ØD
18 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
WT/WTL/WTK
lz
t
lm
lv
gøh
øb
øc
øk
ør
z=8
22.5°
øh
øb
z=10
45°
øb
30°30°
z=16
øh
øb
20°
20°
20°10°
y
x
General data WT WTL 1 WTL 2 WTK 1 WTK 2 WTK 3 WF WG
Size Mz
[kNm]MDW
[kNm]CR
[kNm]ßmax [°]
a K b ± 0.2 c H7 h lm r t z g x h9 y LA lv Iz min LA lv Iz min LA lv Iz min LA lv Iz fix LA lv Iz fix LA lv Iz fix Imin Ifix
225.8 55 26 11.4 15 225 208 196 105 17 120 152.4 x 14.2 5 8 20 32 9 B 140 920 A 370 1200 A 670 1500 B 85 840 B 85 780 B 85 710 520 480
250.8 80 35 19.1 15 250 250 218 105 19 140 165.1 x 14.2 6 8 25 40 12.5 B 140 1035 A 370 1280 A 670 1580 B 100 855 B 100 795 B 60 735 620 560
285.8 115 50 26.4 15 285 285 245 125 21 160 193.7 x 14.2 7 8 27 40 15 B 140 1190 A 370 1430 A 770 1830 B 120 1025 B 120 950 B 80 880 720 640
315.8 170 71 36.6 15 315 315 280 130 23 180 219.1 x 16 8 10 32 40 15 B 140 1315 A 370 1570 A 770 1970 B 130 1160 B 130 1070 B 90 980 805 720
350.8 225 100 48.3 15 350 350 310 155 23 194 244.5 x 20 8 10 35 50 16 B 150 1410 A 400 1690 A 800 2090 B 105 1280 B 105 1170 B 90 1070 855 776
390.8 325 160 67.1 15 390 390 345 170 25 215 267 x 25 8 10 40 70 18 B 170 1590 A 400 1845 A 800 2245 B 150 1400 B 150 1300 B 90 1200 955 860
440.8 500 250 100 15 435 440 385 190 28 260 323.9 x 30 10 16 42 80 20 B 190 1875 A 400 2110 A 800 2510 B 170 1535 B 130 1400 B 70 1300 1155 1040
490.8 730 345 130 15 480 490 425 205 31 270 355.6 x 32 12 16 47 90 22.5 B 190 2040 A 400 2300 A 800 2700 B 180 1780 B 180 1630 B 150 1520 1205 1080
550.8 1000 500 185 15 550 550 492 250 31 305 419 x 36 12 16 50 100 22.5 B 240 2300 A 400 2500 A 800 2900 B 180 1940 B 100 1770 B 80 1680 1355 1220
Dimensions in mmLA: Length compensation
A: without profile protectionB: with profile protection
6.3 Series Wø
a
19Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
General data WT WTL 1 WTL 2 WTK 1 WTK 2 WTK 3 WF WG
Size Mz
[kNm]MDW
[kNm]CR
[kNm]ßmax [°]
a K b ± 0.2 c H7 h lm r t z g x h9 y LA lv Iz min LA lv Iz min LA lv Iz min LA lv Iz fix LA lv Iz fix LA lv Iz fix Imin Ifix
225.8 55 26 11.4 15 225 208 196 105 17 120 152.4 x 14.2 5 8 20 32 9 B 140 920 A 370 1200 A 670 1500 B 85 840 B 85 780 B 85 710 520 480
250.8 80 35 19.1 15 250 250 218 105 19 140 165.1 x 14.2 6 8 25 40 12.5 B 140 1035 A 370 1280 A 670 1580 B 100 855 B 100 795 B 60 735 620 560
285.8 115 50 26.4 15 285 285 245 125 21 160 193.7 x 14.2 7 8 27 40 15 B 140 1190 A 370 1430 A 770 1830 B 120 1025 B 120 950 B 80 880 720 640
315.8 170 71 36.6 15 315 315 280 130 23 180 219.1 x 16 8 10 32 40 15 B 140 1315 A 370 1570 A 770 1970 B 130 1160 B 130 1070 B 90 980 805 720
350.8 225 100 48.3 15 350 350 310 155 23 194 244.5 x 20 8 10 35 50 16 B 150 1410 A 400 1690 A 800 2090 B 105 1280 B 105 1170 B 90 1070 855 776
390.8 325 160 67.1 15 390 390 345 170 25 215 267 x 25 8 10 40 70 18 B 170 1590 A 400 1845 A 800 2245 B 150 1400 B 150 1300 B 90 1200 955 860
440.8 500 250 100 15 435 440 385 190 28 260 323.9 x 30 10 16 42 80 20 B 190 1875 A 400 2110 A 800 2510 B 170 1535 B 130 1400 B 70 1300 1155 1040
490.8 730 345 130 15 480 490 425 205 31 270 355.6 x 32 12 16 47 90 22.5 B 190 2040 A 400 2300 A 800 2700 B 180 1780 B 180 1630 B 150 1520 1205 1080
550.8 1000 500 185 15 550 550 492 250 31 305 419 x 36 12 16 50 100 22.5 B 240 2300 A 400 2500 A 800 2900 B 180 1940 B 100 1770 B 80 1680 1355 1220
Dimensions in mmLA: Length compensation
A: without profile protectionB: with profile protection
WF
l
WG
lfix
20 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
6.4 Series H
HT
lz
lm
lvg
øa
øh
øb
øk
ør
z=12
30°
øh
øb
z=16
30°
øb
22.5° 22.5°
z=24
øh
øb
15°15°
General data HT HF HG General data HT HF HG
Size ßmax [°]
a k b ± 0.2 h lm r z g LA lv Iz min Imin Ifix Size ßmax [°]
a k b ± 0.2 h lm r z g LA lv Iz min Imin Ifix
350.10 10 350 350 320 17,5 210 292 x 20 12 45 B 170 1684 1050 840 830.10 10 820 830 765 39 500 762 x 60 24 105
Values upon request
2000
390.10 10 390 390 355 20 230 323.9 x 20 12 50 B 170 1874 1160 920 860.10 10 850 860 795 39 510 762 x 60 24 105 2040
440.10 10 440 440 405 20 260 368 x 22.2 16 55 B 190 2104 1300 1040 890.10 10 880 890 805 45 535 790 x 75 24 115 2140
490.10 10 490 490 450 22 290 406.4 x 28 16 60 B 210 2344 1460 1160 920.10 10 910 920 835 45 550 790 x 75 24 120 2200
550.10 10 550 550 510 24 330 470 x 28 16 70 B 250 2644 1620 1320 950.10 10 940 950 865 45 570 790 x 85 24 120 2280
590.10 10 580 590 535 26 350 508 x 50 24 75 B 250 2784 1740 1400 980.10 10 970 980 895 45 580 790 x 85 24 120 2320
620.10 10 610 620 565 26 370 508 x 50 24 75 B 250 2864 1820 1480 1010.10 10 1000 1010 920 45 590 865 x 90 24 130 2360
650.10 10 640 650 590 30 390 558.8 x 55 24 80 B 250 3034 1940 1560 1040.10 10 1030 1040 940 52 620 865 x 90 24 135 2480
680.10 10 670 680 620 30 405 558.8 x 55 24 80 B 250 3094 2000 1620 1070.10 10 1060 1070 975 52 640 915 x 90 24 135 2560
710.10 10 700 710 645 33 420 609.6 x 60 24 90 B 250 3284 2100 1680 1090.10 10 1080 1090 995 52 660 966 x 90 24 145 2640
740.10 10 730 740 675 33 440 609.6 x 60 24 90 B 250 3364 2180 1760 1120.10 10 1110 1120 1025 52 670 966 x 90 24 145 2680
770.10 10 760 770 700 36 460 660.4 x 65 24 95 B 250 3554 2300 1840 1170.10 10 1160 1170 1065 62 700 1000 x 90 24 150 2800
800.10 10 790 800 730 36 480 660.4 x 65 24 95 B 250 3634 2400 1920 1200.10 10 1190 1200 1095 62 720 1000 x 90 24 150 2880
1250.10 10 1240 1250 1145 62 740 1100 x 90 24 160 2960
1280.10 10 1270 1280 1175 62 760 1100 x 90 24 160 3040
1320.10 10 1310 1320 1215 62 790 1200 x 90 24 170 3160
1360.10 10 1350 1360 1255 62 815 1200 x 90 24 170 3260
1400.10 10 1390 1400 1285 70 840 1200 x 90 24 180 3360
Dimensions in mm Torque capacities upon request LA: Length compensationB: with profile protection
21Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
HF
l
HG
lfix
General data HT HF HG General data HT HF HG
Size ßmax [°]
a k b ± 0.2 h lm r z g LA lv Iz min Imin Ifix Size ßmax [°]
a k b ± 0.2 h lm r z g LA lv Iz min Imin Ifix
350.10 10 350 350 320 17,5 210 292 x 20 12 45 B 170 1684 1050 840 830.10 10 820 830 765 39 500 762 x 60 24 105
Values upon request
2000
390.10 10 390 390 355 20 230 323.9 x 20 12 50 B 170 1874 1160 920 860.10 10 850 860 795 39 510 762 x 60 24 105 2040
440.10 10 440 440 405 20 260 368 x 22.2 16 55 B 190 2104 1300 1040 890.10 10 880 890 805 45 535 790 x 75 24 115 2140
490.10 10 490 490 450 22 290 406.4 x 28 16 60 B 210 2344 1460 1160 920.10 10 910 920 835 45 550 790 x 75 24 120 2200
550.10 10 550 550 510 24 330 470 x 28 16 70 B 250 2644 1620 1320 950.10 10 940 950 865 45 570 790 x 85 24 120 2280
590.10 10 580 590 535 26 350 508 x 50 24 75 B 250 2784 1740 1400 980.10 10 970 980 895 45 580 790 x 85 24 120 2320
620.10 10 610 620 565 26 370 508 x 50 24 75 B 250 2864 1820 1480 1010.10 10 1000 1010 920 45 590 865 x 90 24 130 2360
650.10 10 640 650 590 30 390 558.8 x 55 24 80 B 250 3034 1940 1560 1040.10 10 1030 1040 940 52 620 865 x 90 24 135 2480
680.10 10 670 680 620 30 405 558.8 x 55 24 80 B 250 3094 2000 1620 1070.10 10 1060 1070 975 52 640 915 x 90 24 135 2560
710.10 10 700 710 645 33 420 609.6 x 60 24 90 B 250 3284 2100 1680 1090.10 10 1080 1090 995 52 660 966 x 90 24 145 2640
740.10 10 730 740 675 33 440 609.6 x 60 24 90 B 250 3364 2180 1760 1120.10 10 1110 1120 1025 52 670 966 x 90 24 145 2680
770.10 10 760 770 700 36 460 660.4 x 65 24 95 B 250 3554 2300 1840 1170.10 10 1160 1170 1065 62 700 1000 x 90 24 150 2800
800.10 10 790 800 730 36 480 660.4 x 65 24 95 B 250 3634 2400 1920 1200.10 10 1190 1200 1095 62 720 1000 x 90 24 150 2880
1250.10 10 1240 1250 1145 62 740 1100 x 90 24 160 2960
1280.10 10 1270 1280 1175 62 760 1100 x 90 24 160 3040
1320.10 10 1310 1320 1215 62 790 1200 x 90 24 170 3160
1360.10 10 1350 1360 1255 62 815 1200 x 90 24 170 3260
1400.10 10 1390 1400 1285 70 840 1200 x 90 24 180 3360
Dimensions in mm Torque capacities upon request LA: Length compensationB: with profile protection
22 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
6.5 Series E
Series E high-performance universal joint shaft
Features Advantages Benefits
Joints n Flange geometry with optimal design for torque transmissionn Reinforced journal crossesn Optimized cross-sections and transition radii on all torque-transmitting components
n Considerably higher torque capacity than previous universal joint shaft designs
n Optimized to withstand torque peaks
n Productivity increasen Long service lifen Lower maintenance costsn Rolling of high strength steels
n Patented 2-piece flange yoke, serrations aligned on the symmetry axisn One-piece bearing eye
n Heavy-duty cross-sections without joints or bolts
Bearing technology n Maximum utilization of space available for installation with largest possible bearings and journal crosses
n Capability to withstand high static and dynamic loads and long bearing life
n Optimized incorporation of bearingsn Best loading at journal cross
n Long bearing lifen Uniform load distribution throughout bearingn Capability to withstand high static and dynamic loads
n Roller bearings with outer and inner rings n Individually replaceable roller bearings
n Optimized rolling element dimensions n Optimized to withstand torque peaks
n Improved rolling element lubrication n Hydrodynamic lubrication improved
Connection technology n Flange with Hirth coupling n Reliable transmission of the highest torquesn Optimum centeringn Easy to assemble
n Low assembly and maintenance costsn Productivity increase
n Full flange design n No weakening of components as a result of necking or reduced cross-sections
n Rolling of high strength steelsn Able to withstand overloads
n ET, EF and EG designs
n Sizes up to 1300
n Torque capacities upon request
Series E high-performance universal joint shafts with size comparison
23Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Series E high-performance universal joint shaft
Features Advantages Benefits
Joints n Flange geometry with optimal design for torque transmissionn Reinforced journal crossesn Optimized cross-sections and transition radii on all torque-transmitting components
n Considerably higher torque capacity than previous universal joint shaft designs
n Optimized to withstand torque peaks
n Productivity increasen Long service lifen Lower maintenance costsn Rolling of high strength steels
n Patented 2-piece flange yoke, serrations aligned on the symmetry axisn One-piece bearing eye
n Heavy-duty cross-sections without joints or bolts
Bearing technology n Maximum utilization of space available for installation with largest possible bearings and journal crosses
n Capability to withstand high static and dynamic loads and long bearing life
n Optimized incorporation of bearingsn Best loading at journal cross
n Long bearing lifen Uniform load distribution throughout bearingn Capability to withstand high static and dynamic loads
n Roller bearings with outer and inner rings n Individually replaceable roller bearings
n Optimized rolling element dimensions n Optimized to withstand torque peaks
n Improved rolling element lubrication n Hydrodynamic lubrication improved
Connection technology n Flange with Hirth coupling n Reliable transmission of the highest torquesn Optimum centeringn Easy to assemble
n Low assembly and maintenance costsn Productivity increase
n Full flange design n No weakening of components as a result of necking or reduced cross-sections
n Rolling of high strength steelsn Able to withstand overloads
Three-dimensional sectioned model of a Series E joint
24 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
7 Complementing products and services 7.1 Engineering
We supply not only products, but also ideas. You too can benefit from our many
years of engineering expertise in all-around project planning of complete drive
systems: from design calculations, installation and commissioning, to questions
about cost-optimized operating as well as maintenance concepts.
Engineering services
n Preparation of specifications
n Preparation of project-specific
drawings
n Torsional and bending vibration
calculations
n Design and sizing of universal
joint shafts and connecting
components
n Clarification of special
requirements from the operator
n Preparation of installation and
maintenance instructions
n Documentation and certificates
n Special acceptance tests
conducted by classifying
and certifying agencies
n Condition monitoring
n Torque measurements
Project planning for a drive line using CAD software
FEM analysis for a working roll with a split connecting roll end hub (illustration: roll journal and half of a roll end hub)
Special universal joint shafts
Designing special universal joint
shafts to match your drive system
and your operating conditions is just
one of the everyday engineering
services we offer. These include:
n All necessary design work
n Integrity checks and optimization
of design through application of
FEM analysis
n Reliability trials based on
dynamic testing
25Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
7.2 Connecting components for universal joint shafts
Description
Input and output-end connecting
parts to the universal joint shaft
reliably transmit the torque, e.g.:
n Roll end hubs
n Connecting flanges
n Adapter flanges
n Adapters
Features
n Individual adaptation to all
adjoining components
n Precision manufacturing through
the use of state-of-the-art
machining centers
n Transmission of maximum torque
through use of high-quality
materials
n High level of wear resistance
through hardened contact
surfaces
Connecting parts used in rolling mills to connect universal joint shafts to the rolls (roll end hubs)
Applications
n Rolling mills
n Paper machines
n Pumps
n General industrial machinery
n Test stands
n Construction machinery and
cranes
26 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
7.3 Quick release coupling GT
Primary functions of quick release coupling GT
Description
The quick release coupling GT is
designed to be a very effective
connecting device. The GT coupling
allows you to quickly assemble
and disassemble a very wide
range of shaft connections on
your machinery, which in turn
significantly reduces down times
for maintenance and repair.
Applications
n Drives that require quick and
centrally aligned replacement
of coupling connections, e.g.
universal joint shafts and disc
couplings
n Roll and cylinder connections,
e.g. in paper machines
Features
n Positive transmission of torque
through claw serrations
n Quick and easy assembly/
disassembly
n Compact design
n Only two major components
n Stainless steel version available
Universal joint shaft with ring of the quick release coupling GT
27Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Positive locking
Fa
Fu
Accurate in
indexing Self-centering
7.4 Voith Hirth serrations
Description
Voith Hirth serrations transmit
maximum torque at specified
diameters.
Applications
n Universal joint shafts with high
torque requirements
n Connecting flange for universal
joint shafts (also when provided
by customer)
n Machine tools
n Turbo compressors
n Measuring equipment
n Robotic equipment
n Nuclear technology
n Medical equipment
n General industrial machinery
Universal joint shaft flanges with Hirth serration
Schematic diagram
Features
n High level of torque transmission,
as angular surfaces provide
positive locking transmission of
most of the peripheral forces.
Only a small axial force needs
to be absorbed by the bolts.
n Self-centering through use of
optimized tooth geometry
n Highly wear resistance due to the
high load-bearing percentage of
tooth profile
n Excellent repeatable accuracy
as a result of the multiple wedge
design
28 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
7.5 Universal joint shaft supports
Description
Universal joint shaft supports,
position and support the universal
joint shafts, including the roll end
hubs and connecting flanges.
Applications
n Rolling mills
n Customer-specific drives
Universal joint shaft support (red) and roll end hub support (yellow)
Features
n Increased productivity and
system availability as a result
of shorter down time for
maintenance
n Reduced energy and lubricant
costs as well as higher trans-
mission efficiency through use of
roller bearings
n Reduced wear as a result of
uniform power transmission
29Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
7.6 Safeset safety couplings
Three-dimensional section through a Safeset safety coupling (type SR-C)
Description
The Safeset coupling is a torque-
limiting safety coupling that imme-
diately interrupts the power trans-
mission of the drive line in the event
of an overload, thus protecting all of
the components such as motor,
gearbox, universal joint shafts etc.
against damage.
Placing the safety coupling between
the joints, what is known as Voith
"integral design", provides smaller
deflection angles in the joints and
thus a longer lifetime of drive line
components.
Applications
n Protects the drive line from
potentially damaging overload
torques
n Rolling mills
n Shredders
n Cement mills
n Sugar mills
n Railway drives
Features
n Adjustable release torque
n Shutdown torque remains
constant
n Backlash-free power transmission
n Compact, lightweight design
n Low mass moment of inertia
n Minimal maintenance required
Torque-limiting Safeset safety coupling (blue) integrated into a Voith high-performance universal joint shaft
30 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
7.7 ACIDA torque monitoring systems
The drive torque is displayed with high accuracy and dynamic response (blue trace). The dynamic response of other signals, for instance the motor current or the hydraulic pressure, is unsatisfactory (red trace)
Description
ACIDA torque monitoring systems
have proven their value in reliable
monitoring of universal joint shafts.
Direct measurement of the actual
mechanical load on the drive pro-
vides important information for
process monitoring and system
optimization.
Analysis modules, for instance load
spectra or lifetime observation,
have been developed especially for
extremely heavy-duty drives and
unusually severe load conditions.
Additional options include online
vibration diagnosis for gearboxes
and roller bearings.
Applications
n Torque monitoring
n Vibration monitoring
n Process optimization
n Condition-based maintenance
n Reference systems: Rolling mills,
cement mills, briquetting plants,
agitators, conveying equipment,
marine propulsion systems,
rail drive lines, paper machines,
mining etc.
Features
n Permanent or temporary torque
measurement systems
n Complete monitoring systems,
incl. hardware and software
n Report generator with automatic
analysis, alarm signaling and
reporting
n Tele-service with expert support
1 Rotor: Strain gauge and telemetry. No drive modification.
2 Non-contact operation: Air gap between rotor and stator
3 Stator: Signal reception and inductive power supply
Time [s]
Torq
ue [N
m]
62.84 63.90 64.95 66.00 67.06 68.11 69.16 70.22
-46
103
253
401
550
3
1
2
31Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
8 Engineering basics8.1 Major components of a Voith universal joint shaft
All versions and sizes of Voith universal joint shafts, regardless
of the Series, share many common attributes that contribute to
reliable operation:
n Single-piece yokes and flange yokes
n Drop-forged journal crosses
n Low-maintenance roller bearings with maximum load capacity
n Use of high-strength tempering and hardened steels
n Superior welded joints
1 Flange yoke2 Journal cross3 Welded yoke4 Bearing5 Tube6 Splined journal7 Splined hub8 Profile protection9 Dirt scraper
3+5+7 Hub yoke3+6+8+9 Shaft yoke
9 6 8 3 2 1 4
1 2 4 4 3 5 7
32 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
8.2 Length compensation with SAE or involute profile
Involute profileSAE profile (straight flank profile)
Length compensation is required in the universal joint shaft for many
applications. In contrast to other drive elements, length compensation in the
center section and offset are achieved through the joints for universal joint
shafts.
Two types of length compensation are utilized in Voith universal joint shafts:
the SAE profile (straight flank profile) and the involute profile. The universal
joint shaft series and size determine the type of length compensation.
For the loads experienced by smaller universal joint shafts, the involute profile
is a suitable solution with a good cost/benefit ratio. The SAE profile (straight
flank profile) is a better solution for large high-performance universal joint
shafts.
Features Advantages Benefits
Length compensation with SAE profile (straight flank profile)
n Straight flank diameter-centered profile n Separation of torque transmission and centering functions n Long service life
n Almost orthogonal introduction of force n Low normal forces and thus lower displacement forces n Moves easily
n Large contact surfaces n Low surface pressure n Long service life
n Favorable pairing of materials for hub and spline shaftn Spline shaft nitrated as standard
n High wear resistance n Long service life
n Patented lubricating mechanism in the grease distribution groove for uniform distribution of grease over the entire diameter of the profile
n Tooth shape incorporates lubricant reservoir for reliable supply of lubricant to sliding surfaces
n Extended maintenance intervals
33Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Features Advantages Benefits
Length compensation with SAE profile (straight flank profile)
n Straight flank diameter-centered profile n Separation of torque transmission and centering functions n Long service life
n Almost orthogonal introduction of force n Low normal forces and thus lower displacement forces n Moves easily
n Large contact surfaces n Low surface pressure n Long service life
n Favorable pairing of materials for hub and spline shaftn Spline shaft nitrated as standard
n High wear resistance n Long service life
n Patented lubricating mechanism in the grease distribution groove for uniform distribution of grease over the entire diameter of the profile
n Tooth shape incorporates lubricant reservoir for reliable supply of lubricant to sliding surfaces
n Extended maintenance intervals
SAE -profile(straight flank profile)
Involute profile
FN ≈ FU
FN > FU
FU
SAE -profile(straight flank profile)
Involute profile
Centering function
Torque transmission
Force introduced during torque transmission Torque transmission and centering
34 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
8.3 Kinematics of the universal joint
n When the input shaft W1 rotates at a constant angular
velocity (v1 = const.), the output shaft W2 rotates at a
varying angular velocity (v2 ≠ const.).
n The angular velocity of the output shaft v2 and the
differential angle w = (a1 – a2) vary in a sinusoidal
manner, their values depend on the deflection
angle b.
n This characteristic of a universal joint is called the
gimbal error and must be taken into consideration
when selecting a universal joint shaft.
G1 Simple universal jointW1 Input shaftW2 Output shaft
a1, a2 Rotation angleb Deflection angleM1, M2 Torquev1, v2 Angular velocityW1
a1
b
G1
W2
a2
M1, v1
M2, v2
35Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
n With one rotation of the shaft W1, the differential
angle w changes four times as does the angular
velocity v2.
n During one rotation, the shaft W2 passes through the
points of maximum acceleration and deceleration
twice.
n At larger deflection angles b and higher velocities,
considerable forces can be generated.
The following equations apply:
w = a1 – a2 (1)
tan a1 _____ tan a2
= cos b (2)
tan w = tan a1 · (cos b – 1)
________________ 1 + cos b · tan2 a1 (3)
This results in the ratio of the angular velocities
between the two shafts W1 and W2:
v2 ___ v1
= cos b
_______________ 1 – sin2 b · sin2 a1
(4)
with the maximum
v2 ___ v1
| max = 1 _____ cos b bei a1 = 90° and a1 = 270° (4a)
and the minimum
v2 ___ v1
| min = cos b bei a1 = 0° and a1 = 180° (4b)
For the torque ratio, the following equation applies:
M2 ___ M1
= v1 ___ v2
(5)
with the maximum
M2 ___ M1
| max = 1 _____ cos b bei a1 = 90° and a1 = 270° (5a)
and the minimum
M2 ___ M1
| min = cos b bei a1 = 0° and a1 = 180° (5b)
a1
w
v2 ___ v1
b b b b b
lwmaxlfor b = 12°
1 – cos 12°
0.8°
0.4°
0°
-0.4°
-0.8°
1,02
1.01
1.00
0.99
0.98
0° 90° 180° 270° 360°
b = 12°
b = 12°
b = 6°
b = 6°
36 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
One indicator of the variation is the variation factor U:
U = v2 ___ v1
| max –
v2 ___ v1 | min
= 1 _____ cos b – cos b = tan b · sin b (6)
Finally, for the maximum differential angle wmax the
following equation applies:
tan wmax = ± 1 – cos b
_________ 2 · √_____
cos b (7)
Conclusion
A single universal joint should be used only if the
following requirements are satisfied:
n The variation in rotational speed of the output shaft
is of secondary importance
n The deflection angle is very small (b < 1°)
n The forces transmitted are low.
A. All components of the universal joint shaft lie in one plane
Uwmax
wmax
b
4.4°
4.0°
3.6°
3.2°
2.8°
2.4°
2.0°
1.6°
1.2°
0.8°
0.4°
0.44
0.40
0.36
0.32
0.28
0.24
0.20
0.16
0.12
0.08
0.04
0° 3° 6° 9° 12° 15° 18° 21° 24° 27° 30°
U
G1
G2
A
37Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
8.4 Double universal joints
Section 8.3 shows that the output shaft W2, when
connected via a single universal joint at a given
deflection angle b, always rotates at the varying
angular velocity v2.
If, however, two universal joints G1 and G2 are con-
nected together correctly in the form of a universal
joint shaft in a Z or W arrangement, the variations
in the speeds of the input and output shaft cancel
each other completely.
Universal joint shaft in Z arrangement, input and output shafts lie parallel to one another in one plane
Universal joint shaft in W arrangement, input and output shafts intersect one another in one plane
Conditions for synchronous rotation of the input
and output shafts:
The three conditions A, B and C ensure that joint G2
operates at a phase shift of 90° and completely com-
pensates for the gimbal error of joint G1. This universal
joint shaft arrangement is called the ideal universal joint
shaft arrangement with complete motion compensation.
It is the arrangement to strive for in reality. If only one of
the three conditions is not satisfied, the universal joint
shaft no longer operates at constant input and output
speeds, i.e. no longer operates homo-kinetically. In
such cases, please contact your Voith Turbo repre-
sentative.
B. Both yokes of the center section of the shaft lie in one plane C. The deflection angles b1 and b2 of the two universal joints are identical
G1
G2
B
b1
b2
G1
G2
C
b1
b2
b1 b2
38 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Maximum values of radial bearing forces on universal joint shafts in a Z arrangement
a b
Md
A B
L
b1
b2
E F
e fG1
G2
b1 ≠ b2 b1 = b2
a1 = 0°
B1 F1
A1 E1
A1 = Md · b · cos b1 ________
L · a · (tan b1 – tan b2)
B1 = Md · (a + b) · cos b1 _____________
L · a · (tan b1 – tan b2)
E1 = Md · (e + f) · cos b1 ____________
L · f · (tan b1 – tan b2)
F1 = Md · e · cos b1 ________
L · f · (tan b1 – tan b2)
A1 = 0
B1 = 0
E1 = 0
F1 = 0
a1 = 90°
B2 E2
A2 F2
A2 = Md · tan b1 ______ a
B2 = Md · tan b1 ______ a
E2 = Md · sin b2 ________
f · cos b1
F2 = Md · sin b2 ________
f · cos b1
A2 = Md · tan b1 ______ a
B2 = Md · tan b1 ______ a
E2 = Md · tan b1 ______
f
F2 = Md · tan b1 ______
f
8.5.1 Radial bearing forces
Because of the deflection of the universal joint shaft,
the connection bearings are also subjected to radial
loads. The radial forces on the bearings vary between
0 and their maximum value twice per revolution.
8.5 Bearing forces on input and output shafts
Maximum values of radial bearing forces on universal joint shafts in a W arrangement
b1 ≠ b2 b1 = b2
a1 = 0°
A1 = Md · b · cos b1 ________
L · a · (tan b1 – tan b2)
B1 = Md · (a + b) · cos b1 _____________
L · a · (tan b1 – tan b2)
E1 = Md · (e + f) · cos b1 ____________
L · f · (tan b1 – tan b2)
F1 = Md · e · cos b1 ________
L · f · (tan b1 – tan b2)
A1 = 2 · Md · b · sin b1 ________
L · a
B1 = 2 · Md · (a + b) · sin b1 ____________
L · a
E1 = 2 · Md · (e + f) · sin b1 ____________
L · f
F1 = 2 · Md · e · sin b1 ________
L · f
a1 = 90°
A2 = Md · tan b1 ______ a
B2 = Md · tan b1 ______ a
E2 = Md · sin b2 ________
f · cos b1
F2 = Md · sin b2 ________
f · cos b1
A2 = Md · tan b1 ______ a
B2 = Md · tan b1 ______ a
E2 = Md · tan b1 ______
f
F2 = Md · tan b1 ______
f
39Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Maximum values of radial bearing forces on universal joint shafts in a Z arrangement
b1 ≠ b2 b1 = b2
a1 = 0°
A1 = Md · b · cos b1 ________
L · a · (tan b1 – tan b2)
B1 = Md · (a + b) · cos b1 _____________
L · a · (tan b1 – tan b2)
E1 = Md · (e + f) · cos b1 ____________
L · f · (tan b1 – tan b2)
F1 = Md · e · cos b1 ________
L · f · (tan b1 – tan b2)
A1 = 0
B1 = 0
E1 = 0
F1 = 0
a1 = 90°
A2 = Md · tan b1 ______ a
B2 = Md · tan b1 ______ a
E2 = Md · sin b2 ________
f · cos b1
F2 = Md · sin b2 ________
f · cos b1
A2 = Md · tan b1 ______ a
B2 = Md · tan b1 ______ a
E2 = Md · tan b1 ______
f
F2 = Md · tan b1 ______
f
Maximum values of radial bearing forces on universal joint shafts in a W arrangement
ab
Md
AB
L
b1 b2
EF
ef
G1 G2
b1 ≠ b2 b1 = b2
a1 = 0°
B1 F1
A1 E1
A1 = Md · b · cos b1 ________
L · a · (tan b1 – tan b2)
B1 = Md · (a + b) · cos b1 _____________
L · a · (tan b1 – tan b2)
E1 = Md · (e + f) · cos b1 ____________
L · f · (tan b1 – tan b2)
F1 = Md · e · cos b1 ________
L · f · (tan b1 – tan b2)
A1 = 2 · Md · b · sin b1 ________
L · a
B1 = 2 · Md · (a + b) · sin b1 ____________
L · a
E1 = 2 · Md · (e + f) · sin b1 ____________
L · f
F1 = 2 · Md · e · sin b1 ________
L · f
a1 = 90°
B2 F2
A2 E2
A2 = Md · tan b1 ______ a
B2 = Md · tan b1 ______ a
E2 = Md · sin b2 ________
f · cos b1
F2 = Md · sin b2 ________
f · cos b1
A2 = Md · tan b1 ______ a
B2 = Md · tan b1 ______ a
E2 = Md · tan b1 ______
f
F2 = Md · tan b1 ______
f
Designations and formulasG1, G2 Universal jointsA, B, E, F Connection bearingsMd Input torqueA1/2, B1/2, C1/2, D1/2 Bearing forcesa1 Angle of rotationb1, b2 Deflection angle
40 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
8.5.2 Axial bearing forces
In principle, the kinematics of a universal joint shaft
do not generate any axial forces. Nevertheless, axial
forces that must be absorbed by the connection
bearings arise in universal joint shafts with length
compensation for two reasons:
1. Force Fax,1 as a result of friction in the length
compensation assembly
As the length changes during transmission of torque,
friction is generated between the flanks of the spline
profiles in the length compensation assembly. The
frictional force Fax,1, which acts in an axial direction,
can be calculated using the following equation:
Fax,1 = m · Md · 2 ___ dm
· cos b
Where:
m Coefficient of friction
m ≈ 0.11…0.14 for steel against steel (lubricated)
m ≈ 0.07 for Rilsan® plastic coating against steel
Md Input torque
dm Pitch circle diameter of the spline profile
b Deflection angle
2. Force Fax,2 as a result of the pressure build-up
in the length compensation assembly during
lubrication
During lubrication of the length compensation
assembly, an axial force Fax,2 arises that depends
on the force applied while lubricating. Please note,
information with regard to this subject is available
in the installation and operating instructions.
Type of machine – general examples Balance quality level G
Complete piston engines for cars, trucks and locomotives G 100
Cars. wheels, rims, wheel sets, universal joint shafts; crank drives with mass balancing on elastic mounts G 40
Agricultural machinery; crank drives with mass balancing on rigid mounts; size reduction machinery; drive shafts (cardan shafts, propeller shafts)
G 16
Jet engines; centrifuges; electric motors and generators with a shaft height of at least 80 mm and a maximum rated speed of up to 950 rpm; electric motors with a shaft height below 80 mm; fans; gearboxes; general industrial machinery; machine tools; paper machines; process engineering equipment; pumps; turbochargers; hydro-power turbines
G 6.3
Compressors; computer drives; electric motors and generators with a shaft height of at least 80 mm and a maximum rated speed over 950 rpm; gas turbines, steam turbines; machine tool drives; textile machinery
G 2.5
41Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Type of machine – general examples Balance quality level G
Complete piston engines for cars, trucks and locomotives G 100
Cars. wheels, rims, wheel sets, universal joint shafts; crank drives with mass balancing on elastic mounts G 40
Agricultural machinery; crank drives with mass balancing on rigid mounts; size reduction machinery; drive shafts (cardan shafts, propeller shafts)
G 16
Jet engines; centrifuges; electric motors and generators with a shaft height of at least 80 mm and a maximum rated speed of up to 950 rpm; electric motors with a shaft height below 80 mm; fans; gearboxes; general industrial machinery; machine tools; paper machines; process engineering equipment; pumps; turbochargers; hydro-power turbines
G 6.3
Compressors; computer drives; electric motors and generators with a shaft height of at least 80 mm and a maximum rated speed over 950 rpm; gas turbines, steam turbines; machine tool drives; textile machinery
G 2.5
8.6 Balancing of universal joint shafts
As with any other rotating equipment, a universal joint
shaft has a non-uniform distribution of mass around
the axis of rotation. This leads to unbalanced forces
during operation. Depending on the operating speed
and the specific application, Voith universal joint
shafts are dynamically balanced in two planes.
Depending on the application and maximum operating
speed, balance quality levels for universal joint shafts
lie in the range between G 40 and G 6.3. The repro-
ducibility of measurements can be subject to wider
tolerances due to the influence of various physical
factors. Such factors include:
n Design characteristics of the balancing machine
n Accuracy of the measurement method
n Tolerances in the connections to the universal
joint shaft
n Radial and axial clearances in the universal
joint bearings
n Deflection clearance in the splined center section
The benefits of balancing:
n Avoidance of vibrations, resulting in smoother
operation
n Longer lifetime of the universal joint shaft
The balancing procedure employed by Voith for
universal joint shafts is based on that prescribed
in DIN ISO 1940-1 ("Mechanical vibration – Balance
quality requirements for rotors in a constant (rigid)
state – Part 1: Specification and verification of balance
tolerances"). An extract from this Standard lists the
following approximate values for balance quality levels:
42 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
9 Selection aids
The design of a universal joint shaft depends on a number of factors.
Reliable, verified calculations and tests prevent any danger to the
surrounding area. Consideration of the costs that arise during the entire
product lifecycle also comes into play.
The design procedures described in this chapter are merely rough
guidelines. When making a final decision about a universal joint shaft,
you can rely on our sales engineers with their expertise and many years
of experience. We will be happy to advise you.
Desig na-tion
Usual unit
Explanation
PN [kW] Rated power of the drive motor
nN [rpm] Rated speed of the drive motor
MN [kNm] Rated torque of the drive motor, where: MN = 60 ______
2p · nN · PN ≈ 9.55 ·
PN ___ nN with MN in kNm, nN in rpm and PN in kW
ME [kNm] Equivalent torqueThis torque is an important operating variable if bearing lifetime is the main criterion in selection of a universal joint shaft. It takes operating conditions into account and can be calculated for situations involving combined loads (see Section 9.2.1). If the operating conditions are not sufficiently known, the rated torque is used for an initial estimate.
nE [rpm] Equivalent speedThis speed is an important operating variable if bearing lifetime is the main criterion in selection of a universal joint shafts. It takes operating conditions into account and can be calculated for situations involving combined loads (see Section 9.2.1). If the operating conditions are not sufficiently known, the rated speed is used for an initial estimate.
Mmax [kNm] Peak torqueThis is the maximum torque that occurs during normal operation.
nmax [rpm] Maximum speedThis is the maximum speed that occurs during normal operation.
9.1 Definitions of operating variables
Designa-tion
Usual unit
Explanation
nz1 [rpm] Maximum permissible speed as a function of the deflection angle during operation.The center section of a universal joint shaft in a Z or W-arrangement (b ≠ 0°) rotates at a varying speed. It experiences a mass acceleration torque that depends on the speed and the deflection angle. To ensure smooth operation and prevent excessive wear, the mass acceleration torque is limited by not exceeding the maximum speed of universal joint shaft nz1. For additional information, see Section 9.3.1.
nz2 [rpm] Maximum permissible speed taking bending vibrations into account.A universal joint shaft is an elastic body when bent. At a critical bending speed, the frequency of the bending vibrations equals the natural frequency of the universal joint shaft. The result is a high load on all of the universal joint shaft components. The maximum speed of the universal joint shaft must be considerably below this critical speed. For additional information, see Section 9.3.2.
b [°] Deflection angle during operationDeflection angle of the two joints in a Z or W-arrangement, where:
b = b1 = b2
If the situation involves three-dimensional deflection, a resultant deflection angle bR is determined:
tan bR = √______________
tan2 bh + tan2 bV and where: b = bR
bmax [°] Maximum possible deflection angle
43Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Desig na-tion
Usual unit
Explanation
PN [kW] Rated power of the drive motor
nN [rpm] Rated speed of the drive motor
MN [kNm] Rated torque of the drive motor, where: MN = 60 ______
2p · nN · PN ≈ 9.55 ·
PN ___ nN with MN in kNm, nN in rpm and PN in kW
ME [kNm] Equivalent torqueThis torque is an important operating variable if bearing lifetime is the main criterion in selection of a universal joint shaft. It takes operating conditions into account and can be calculated for situations involving combined loads (see Section 9.2.1). If the operating conditions are not sufficiently known, the rated torque is used for an initial estimate.
nE [rpm] Equivalent speedThis speed is an important operating variable if bearing lifetime is the main criterion in selection of a universal joint shafts. It takes operating conditions into account and can be calculated for situations involving combined loads (see Section 9.2.1). If the operating conditions are not sufficiently known, the rated speed is used for an initial estimate.
Mmax [kNm] Peak torqueThis is the maximum torque that occurs during normal operation.
nmax [rpm] Maximum speedThis is the maximum speed that occurs during normal operation.
The following factors have a major influence on any
decision regarding universal joint shafts:
n Operating variables
n Main selection criterion:
Bearing lifetime or durability
n Installation space
n Connection bearings
Designa-tion
Usual unit
Explanation
nz1 [rpm] Maximum permissible speed as a function of the deflection angle during operation.The center section of a universal joint shaft in a Z or W-arrangement (b ≠ 0°) rotates at a varying speed. It experiences a mass acceleration torque that depends on the speed and the deflection angle. To ensure smooth operation and prevent excessive wear, the mass acceleration torque is limited by not exceeding the maximum speed of universal joint shaft nz1. For additional information, see Section 9.3.1.
nz2 [rpm] Maximum permissible speed taking bending vibrations into account.A universal joint shaft is an elastic body when bent. At a critical bending speed, the frequency of the bending vibrations equals the natural frequency of the universal joint shaft. The result is a high load on all of the universal joint shaft components. The maximum speed of the universal joint shaft must be considerably below this critical speed. For additional information, see Section 9.3.2.
b [°] Deflection angle during operationDeflection angle of the two joints in a Z or W-arrangement, where:
b = b1 = b2
If the situation involves three-dimensional deflection, a resultant deflection angle bR is determined:
tan bR = √______________
tan2 bh + tan2 bV and where: b = bR
bmax [°] Maximum possible deflection angle
bv1
bh1
bv2
bh2
Three-dimensional bending
44 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
9.2.1 Selection on the basis of bearing lifetime
The procedure used for calculating the bearing lifetime
is based on that prescribed in DIN ISO 281 ("Rolling
bearings – Dynamic load ratings and rating life"). How-
ever, when applying this standard to universal joint
shafts, several different factors are not taken into
account, for instance, support of the bearing, i.e.
deformation of the bore under load. To date, these
factors could only be assessed qualitatively.
The theoretical lifetime of a bearing in a universal
joint shaft is calculated using the following equation:
Lh = 1.5 · 107
_________ nE · b · KB · ( CR ___ ME
) 10 ___ 3
where:
Lh is the theoretical lifetime of the bearing
in hours [h]
CR Load rating of the universal joint in kNm
(see tables in Chapter 6)
b Deflection angle in degrees [°]; in the case
of three-dimensional bending, the resultant
deflection angle bR is to be used; in any case,
however, a minimum angle of 2°
KB Operational factor
nE Equivalent speed in rpm
ME Equivalent torque in kNm
9.2 Size selection
Operational factor
In drives with diesel engines, torque spikes occur that
are taken into account by the operational factor KB:
Prime mover (driving machine) Operational factor KB
Electric motor 1
Diesel engine 1.2
There are essentially two selection criteria when choosing the size of a universal joint shaft:
1. The lifetime of the roller bearings in the joints
2. The fatigue-free operating range, and thus the torque capacity and/or load limits
As a rule, the application determines the primary selection criterion. A selection on the
basis of bearing lifetime is usually made if drives must have a long service life and pro-
nounced torque spikes never occur or occur only briefly (for instance, during start-up).
Typical examples include drives in paper machines, pumps and fans. In all other appli-
cations, selection is made on the basis of the fatigue-free operating range.
45Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Incremental variation of the load on a universal joint shaft
M, n M1
n1
M2
n2
Mu
nu
q1 q2 quq0 1
ME = ( ∑ i = 1
u
qi · ni · M i 10 ___ 3
___________ nE
) 3 ___ 10
= ( q1 · n1 · M 1 10 ___ 3
+ q2 · n2 · M 2 10 ___ 3
+ … + qu · nu · M u 10 ___ 3
_____________________________________ nE
) 3 ___ 10
Conclusions
n The calculated lifetime of the bearing is a theoretical
value that in practice is usually exceeded by a con-
siderable amount.
n The following additional factors affect the lifetime of
the bearings, sometimes to a significant degree:
– Quality of the bearings
– Quality (hardness) of the journals
– Lubrication
– Overloading that results in plastic deformation
– Quality of the seals
Equivalent operating values
The equation for the theoretical lifetime of the bearing
assumes a constant load and speed. If the load changes
in increments, equivalent operating values that produce
the same fatigue as the actual loads can be determined.
The equivalent operating values are ultimately the
equivalent speed nE and the equivalent torque ME.
If a universal joint shaft transmits the torque Mi for a time
period Ti at a speed ni, a time segment qi that normalizes
the time period Ti with respect to the overall duration of
operation Tges is first defined:
qi = Ti ____ Tges
with ∑ i = 1
u
qi = q1 + q2 + … + qu = 1
In this way, the equivalent operating values can be
determined:
nE = ∑ i = 1
u
qi · ni = q1 · n1 + q2 · n2 + … + qu · nu
46 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
9.2.2 Selection on the basis of fatigue-free
operating range
Calculations regarding the fatigue-free operating range
can be performed using a load spectrum. In practice,
however, sufficiently accurate load spectra are seldom
available. In this case, one relies on the quasi-static
dimensioning procedure. Here, the expected peak
torque Mmax is compared with the torques MDW, MDS
and MZ (see Section 5.2).
The following estimate is made for the peak torque:
Mmax ≈ K3 · MN
K3 is called the shock factor. These are empirical values
based on decades of experience in designing universal
joint shafts.
The peak torque determined in this manner must
satisfy the following requirements:
1. Mmax < MDW for alternating load
2. Mmax < MDS for pulsating load
3. Individual and rarely occurring torque spikes must
not exceed the value MZ. The permissible duration
and frequency of these torque spikes depends on
the application; please contact Voith Turbo for more
information.
Load peaks Shock factor K3
Typical driven machinery
Minimal 1.1…1.3 n Generators (under a uniform load)n Centrifugal pumpsn Conveying equipment
(under a uniform load)n Machine toolsn Woodwork machinery
Moderate 1.3…1.8 n Multi-cylinder compressorsn Multi-cylinder piston pumpsn Light-section rolling millsn Continuous wire rolling millsn Primary drives in locomotives and
other rail vehicles
Severe 2…3 n Transport roller tablesn Continuous pipe millsn Continuously operating main roller
tablesn Medium-section rolling millsn Single-cylinder compressorsn Single-cylinder piston pumpsn Fansn Mixersn Excavatorsn Bending machinesn Pressesn Rotary drilling and boring
equipmentn Secondary drives in locomotives
and other rail vehicles
Very severe 3…5 n Reversing main roller tablesn Coiler drivesn Scale breakersn Cogging/roughing stands
Extremely severe
6…15 n Roll stand drivesn Plate shearsn Coiler pressure rolls
47Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Load peaks Shock factor K3
Typical driven machinery
Minimal 1.1…1.3 n Generators (under a uniform load)n Centrifugal pumpsn Conveying equipment
(under a uniform load)n Machine toolsn Woodwork machinery
Moderate 1.3…1.8 n Multi-cylinder compressorsn Multi-cylinder piston pumpsn Light-section rolling millsn Continuous wire rolling millsn Primary drives in locomotives and
other rail vehicles
Severe 2…3 n Transport roller tablesn Continuous pipe millsn Continuously operating main roller
tablesn Medium-section rolling millsn Single-cylinder compressorsn Single-cylinder piston pumpsn Fansn Mixersn Excavatorsn Bending machinesn Pressesn Rotary drilling and boring
equipmentn Secondary drives in locomotives
and other rail vehicles
Very severe 3…5 n Reversing main roller tablesn Coiler drivesn Scale breakersn Cogging/roughing stands
Extremely severe
6…15 n Roll stand drivesn Plate shearsn Coiler pressure rolls
In addition, the mass acceleration moment can affect
the entire drive line on universal joint shafts with length
compensation as well as universal joint shafts without
length compensation. Torsional vibrations should be
mentioned here by way of example.
To prevent these adverse effects, please comply with
the following conditions:
nmax < nz1
9.3 Operating speeds
Approximate values of nz1 as a function of b
9.3.1 Maximum permissible speed nz1 as a
function of deflection angle during
operation
Section 8.3 shows that a universal joint exhibits a
varying output motion. A universal joint shaft is a
connection of two universal joints in series with one
another. Under the conditions described in Section 8.4,
a universal joint shaft in a Z or W arrangement exhibits
homokinetic motion between the input and output.
Nevertheless, the center section of the universal joint
shaft still rotates at the periodically varying angular
velocity v2.
Since the center section of the universal joint shaft still
exhibits a mass moment of inertia, it creates a moment
of resistance to the angular acceleration dv2 /dt. On
universal joint shafts with length compensation, this
alternating mass acceleration moment can cause
clattering sounds in the profile. The consequences
include less smooth operation and increased wear.
b 2 4 6 8 10 12 14 16 18 20 22 24 26 28 30
ST 058.1ST 065.1ST 075.1
ST 090.2ST 100.2
ST 120.2 ST 120.5
ST 150.2 ST 150.3ST 150.5
ST 180.5 ST 225.7
ST 250.8 WT 225.8 MT 225.8
WT 490.8WT 550.8
ST 285.8 WT 250.8 MT 250.8
ST 315.8 WT 285.8 MT 285.8
ST 350.8 WT 315.8 MT 315.8
MT 350.8ST 390.8 WT 350.8
ST 435.8 WT 390.8WT 440.8HT 390.10
HT 490.10HT 550.10
6000
600
800
4000
2000
1000
500
n z1 [
rpm
]
b [°]
48 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
The maximum permissible speed nz2 is determined in
such a way that provides a safety allowance with re-
spect to the critical bending speed that is suitable for
the particular application.
For safety reasons and to prevent failure of the uni-
versal joint shaft, please comply with the fol lowing
conditions:
nmax < nz2
For normal connecting and operating conditions, it is
possible to specify approximate values for the max-
imum permissible speeds nz2 as a function of operating
length lB:
9.3.2 Maximum permissible speed nz2
as a function of operating length
Every universal joint shaft has a critical bending speed
at which the rotational bending speed (bending fre-
quency) matches the natural frequency of the shaft. The
result: high loads on all components of the univer sal
joint shaft. Damage to or destruction of the universal
joint shaft is possible in unfavorable situations.
Calculating this critical bending speed for a real uni-
versal joint shaft in a drive line is a complex task that
Voith Turbo performs using numerical computing
programs.
The critical bending speed depends essentially on three
factors:
n Operating length lBn Deflection resistance of the universal joint shaft
n Connecting conditions at the input and output ends
Approximate values of nz2 as a function of lB for the S Series
1000 2000 3000 4000 5000 6000
ST 435.8ST 390.8ST 350.8ST 315.8ST 285.8ST 250.8ST 225.7ST 180.5ST 150.5
ST 150.3ST 150.2ST 120.5ST 120.2ST 090.2ST 100.2ST 075.1ST 065.1ST 058.1
100
200
400
600
800
2000
4000
6000
1000
n z2 [
rpm
]
IB [mm]
49Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Approximate values of nz2 as a function of lB for the M and H Series
Approximate values of nz2 as a function of lB for the W Series
HT 550.10HT 490.10HT 440.10HT 390.10HT 350.10MT 350.8MT 315.8MT 285.8MT 250.8MT 225.8
2000 3000 4000 5000 6000500600
800
2000
4000
1000
n z2 [
rpm
]
IB [mm]
IB [mm]
WT 550.8WT 490.8WT 440.8WT 390.8WT 350.8WT 315.8WT 285.8WT 250.8WT 225.8
500600
800
2000
4000
1000
n z2 [
rpm
]
2000 3000 4000 5000 6000
IB [mm]
50 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
9.4 Masses and mass moments of inertia
Size Values for the tube based on length
Universal joint shafts with length compensation Universal joint shafts without length
compensation
Joint coupling
m’R J’R mL min JL min mL min JL min mL min JL min mL min JL min mL min JL min mL min JL min mL min JL min mL min JL min mL fix JL fix
[kg/m] [kg·m2/m] [kg] [kg·m2] [kg] [kg·m2] [kg] [kg·m2] [kg] [kg·m2] [kg] [kg·m2] [kg] [kg·m2] [kg] [kg·m2] [kg] [kg·m2] [kg] [kg·m2]
ST/STL/SF ST STL 1 STL 2 STK 1 STK 2 STK 3 STK4 SF SG
058.1 1.0 0.00017 1.1 0.00019
Values upon request Values upon request
1.1 0.00024 1.0 0.00022 1.0 0.00021 0.9 0.00018 0.9 0.00015 0.8 0.00014
065.1 1.1 0.00026 1.7 0.00042 1.7 0.00045 1.6 0.00043 1.5 0.00042 1.4 0.00039 1.2 0.00034 1.0 0.00030
075.1 2.0 0.00068 2.7 0.00098 2.5 0.00096 2.4 0.00093 2.3 0.00092 2.1 0.00089 2.0 0.00078 1.0 0.00062
090.2 2.4 0.00140 4.8 0.00250 4.3 0.00260 4.1 0.00240 4.0 0.00230 3.8 0.00220 3.6 0.00240 3.2 0.00150
100.2 3.5 0.00190 6.1 0.00380 5.8 0.00430 5.5 0.00420 5.3 0.00400 5.1 0.00390 4.5 0.00350 4.2 0.00300
120.2 5.5 0.00440 10.8 0.01000 10.2 0.01200 9.8 0.01200 9.2 0.01100 8.6 0.01000 7.7 0.00960 7.4 0.00710
120.5 6.5 0.00710 14.4 0.01800 13.7 0.01500 13.2 0.01500 12.3 0.01800 11.5 0.01800 10.5 0.01400 9.2 0.01000
150.2 7.5 0.011 20.7 0.032 20.7 0.032 20.1 0.031 17.1 0.027 15.8 0.025 15.2 0.024 13.8 0.021
150.3 8.5 0.018 32.0 0.045 27.0 0.045 25.9 0.044 27.4 0.043 26.0 0.043 22.1 0.043 16.6 0.041
150.5 11.7 0.027 36.4 0.048 36.5 0.049 34.9 0.047 32.4 0.044 29.4 0.043 25.3 0.041 21.6 0.380
180.5 15.4 0.042 51.7 0.100 48.5 0.084 46.7 0.082 43.1 0.081 40.9 0.078 32.4 0.073 30.6 0.740
225.7 16.9 0.055 65 0.160 74 0.170 88 0.200 66 0.180 64 0.160 60 0.150 56 0.150 36 0.120 36 0.110
250.8 49 0.23 123 0.45 150 0.56 183 0.64 113 0.42 109 0.37 96 0.28 86 0.270 79 0.37 86 0.41
285.8 53 0.30 171 0.99 197 1.11 234 1.23 154 0.91 148 0.87 136 0.83 123 0.85 129 0.94
315.8 63 0.51 261 1.99 299 2.26 357 2.54 242 1.87 228 1.84 220 1.74 183 1.76 190 1.84
350.8 80 0.80 380 3.29 432 3.66 512 4.11 353 3.03 344 2.91 332 2.77 261 2.89 270 3.00
390.8 115 1.41 525 5.88 628 6.62 744 7.38 492 5.57 463 5.39 437 5.12 359 5.01 378 5.45
435.8 150 2.21 740 10.30 820 11.40 967 12.60 688 9.69 658 9.21 604 8.75 509 8.41 540 9.78
MT/MF MT MF MG
225.8 37.0 0.21 88 0.380 56 0.25 59 0.24
250.8 39.5 0.25 109 0.580 77 0.34 81 0.34
285.8 46.9 0.42 160 1.100 116 0.80 122 0.79
315.8 51.8 0.57 246 1.900 171 1.63 180 1.50
350.8 70.1 0.91 344 3.420 243 2.53 256 2.68
WT/WTL/WF WT WTL 1 WTL 2 WTK 1 WTK 2 WTK 3 WF WG
225.8 49 0.23 122 0.42 150 0.527 182 0.62 112 0.39 108 0.34 95 0.25 78 0.31 82 0.35
250.8 53 0.30 172 0.93 197 1.057 235 1.18 154 0.86 148 0.81 136 0.78 124 0.76 127 0.83
285.8 63 0.51 263 1.92 300 2.197 358 2.47 244 1.81 229 1.78 221 1.68 185 1.58 189 1.71
315.8 80 0.80 382 3.18 434 3.555 514 4.01 355 2.94 346 2.82 334 2.67 262 2.46 270 2.81
350.8 115 1.41 527 5.54 630 6.274 746 7.04 494 5.24 465 5.06 439 4.8 359 4.38 370 4.78
390.8 150 2.21 738 9.56 817 10.6 964 11.8 684 8.9 655 8.43 600 7.99 506 7.59 524 8.22
440.8 217 4.74 1190 20.0 1312 21.9 1537 24.8 1050 18.1 1025 16.5 985 15.7 790 14.6 798 15.4
490.8 255 6.70 1452 34.1 1554 35.9 1779 40.2 1350 31.2 1300 29.2 1260 28.6 1014 24.3 1055 25.2
550.8 345 12.50 2380 64.8 2585 70.5 3045 79.7 2170 58.1 2120 53.7 2090 52.4 1526 45.4 1524 48.0
Continued on page 52/53
51Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Size Values for the tube based on length
Universal joint shafts with length compensation Universal joint shafts without length
compensation
Joint coupling
m’R J’R mL min JL min mL min JL min mL min JL min mL min JL min mL min JL min mL min JL min mL min JL min mL min JL min mL fix JL fix
[kg/m] [kg·m2/m] [kg] [kg·m2] [kg] [kg·m2] [kg] [kg·m2] [kg] [kg·m2] [kg] [kg·m2] [kg] [kg·m2] [kg] [kg·m2] [kg] [kg·m2] [kg] [kg·m2]
ST/STL/SF ST STL 1 STL 2 STK 1 STK 2 STK 3 STK4 SF SG
058.1 1.0 0.00017 1.1 0.00019
Values upon request Values upon request
1.1 0.00024 1.0 0.00022 1.0 0.00021 0.9 0.00018 0.9 0.00015 0.8 0.00014
065.1 1.1 0.00026 1.7 0.00042 1.7 0.00045 1.6 0.00043 1.5 0.00042 1.4 0.00039 1.2 0.00034 1.0 0.00030
075.1 2.0 0.00068 2.7 0.00098 2.5 0.00096 2.4 0.00093 2.3 0.00092 2.1 0.00089 2.0 0.00078 1.0 0.00062
090.2 2.4 0.00140 4.8 0.00250 4.3 0.00260 4.1 0.00240 4.0 0.00230 3.8 0.00220 3.6 0.00240 3.2 0.00150
100.2 3.5 0.00190 6.1 0.00380 5.8 0.00430 5.5 0.00420 5.3 0.00400 5.1 0.00390 4.5 0.00350 4.2 0.00300
120.2 5.5 0.00440 10.8 0.01000 10.2 0.01200 9.8 0.01200 9.2 0.01100 8.6 0.01000 7.7 0.00960 7.4 0.00710
120.5 6.5 0.00710 14.4 0.01800 13.7 0.01500 13.2 0.01500 12.3 0.01800 11.5 0.01800 10.5 0.01400 9.2 0.01000
150.2 7.5 0.011 20.7 0.032 20.7 0.032 20.1 0.031 17.1 0.027 15.8 0.025 15.2 0.024 13.8 0.021
150.3 8.5 0.018 32.0 0.045 27.0 0.045 25.9 0.044 27.4 0.043 26.0 0.043 22.1 0.043 16.6 0.041
150.5 11.7 0.027 36.4 0.048 36.5 0.049 34.9 0.047 32.4 0.044 29.4 0.043 25.3 0.041 21.6 0.380
180.5 15.4 0.042 51.7 0.100 48.5 0.084 46.7 0.082 43.1 0.081 40.9 0.078 32.4 0.073 30.6 0.740
225.7 16.9 0.055 65 0.160 74 0.170 88 0.200 66 0.180 64 0.160 60 0.150 56 0.150 36 0.120 36 0.110
250.8 49 0.23 123 0.45 150 0.56 183 0.64 113 0.42 109 0.37 96 0.28 86 0.270 79 0.37 86 0.41
285.8 53 0.30 171 0.99 197 1.11 234 1.23 154 0.91 148 0.87 136 0.83 123 0.85 129 0.94
315.8 63 0.51 261 1.99 299 2.26 357 2.54 242 1.87 228 1.84 220 1.74 183 1.76 190 1.84
350.8 80 0.80 380 3.29 432 3.66 512 4.11 353 3.03 344 2.91 332 2.77 261 2.89 270 3.00
390.8 115 1.41 525 5.88 628 6.62 744 7.38 492 5.57 463 5.39 437 5.12 359 5.01 378 5.45
435.8 150 2.21 740 10.30 820 11.40 967 12.60 688 9.69 658 9.21 604 8.75 509 8.41 540 9.78
MT/MF MT MF MG
225.8 37.0 0.21 88 0.380 56 0.25 59 0.24
250.8 39.5 0.25 109 0.580 77 0.34 81 0.34
285.8 46.9 0.42 160 1.100 116 0.80 122 0.79
315.8 51.8 0.57 246 1.900 171 1.63 180 1.50
350.8 70.1 0.91 344 3.420 243 2.53 256 2.68
WT/WTL/WF WT WTL 1 WTL 2 WTK 1 WTK 2 WTK 3 WF WG
225.8 49 0.23 122 0.42 150 0.527 182 0.62 112 0.39 108 0.34 95 0.25 78 0.31 82 0.35
250.8 53 0.30 172 0.93 197 1.057 235 1.18 154 0.86 148 0.81 136 0.78 124 0.76 127 0.83
285.8 63 0.51 263 1.92 300 2.197 358 2.47 244 1.81 229 1.78 221 1.68 185 1.58 189 1.71
315.8 80 0.80 382 3.18 434 3.555 514 4.01 355 2.94 346 2.82 334 2.67 262 2.46 270 2.81
350.8 115 1.41 527 5.54 630 6.274 746 7.04 494 5.24 465 5.06 439 4.8 359 4.38 370 4.78
390.8 150 2.21 738 9.56 817 10.6 964 11.8 684 8.9 655 8.43 600 7.99 506 7.59 524 8.22
440.8 217 4.74 1190 20.0 1312 21.9 1537 24.8 1050 18.1 1025 16.5 985 15.7 790 14.6 798 15.4
490.8 255 6.70 1452 34.1 1554 35.9 1779 40.2 1350 31.2 1300 29.2 1260 28.6 1014 24.3 1055 25.2
550.8 345 12.50 2380 64.8 2585 70.5 3045 79.7 2170 58.1 2120 53.7 2090 52.4 1526 45.4 1524 48.0
Continued on page 52/53
52 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Designation Explanation
m’R Mass of the tube per 1 m of length
J’R Mass moment of inertia of the tube per 1 m of length
Universal joint shafts with length compensation Universal joint shafts without length compensation
mL min Mass of the universal joint shaft for a length of…
lz min lminJL min Mass moment of inertia of the universal joint shaft
for a length of…
Calculations for the entire universal joint shaft:
mges Total mass mges = mL min + (lz – lz min) · m’R mges = mL min + (l – lmin) · m’R
Jges Total mass moment of inertia Jges = JL min + (lz – lz min) · J’R Jges = JL min + (l – lmin) · J’R
Size Values for the tube based on length
Universal joint shafts with length compensation Universal joint shafts without length
compensation
Joint coupling
m’R J’R mL min JL min mL min JL min mL min JL min mL min JL min mL min JL min mL min JL min mL min JL min mL min JL min mL fix JL fix
[kg/m] [kg·m2/m] [kg] [kg·m2] [kg] [kg·m2] [kg] [kg·m2] [kg] [kg·m2] [kg] [kg·m2] [kg] [kg·m2] [kg] [kg·m2] [kg] [kg·m2] [kg] [kg·m2]
HT/HF HT HF HG
350.10 134.2 2.50 685 10.41 508 7.47 453 6.32
390.10 149.9 3.48 1018 17.59 708 12.94 626 10.85
440.10 189.3 5.68 1415 32.04 1001 23.19 895 19.68
490.10 261.3 9.41 1979 54.73 1379 39.61 1228 33.48
550.10 305.2 14.97 2807 100.35 1918 70.47 1730 60.33
590.10 564.7 29.97 3887 143.96 2442 100.48 2154 83.96
620.10 564.7 29.97 4232 168.93 2787 125.45 2466 106.01
650.10 683.3 43.88 4949 220.04 3243 162.00 2856 135.18
680.10 683.3 43.88 5364 256.12 3657 198.08 3232 167.10
710.10 813.2 62.14 6523 347.32 4286 255.85 3758 212.41
740.10 813.2 62.14 7020 398.98 4783 307.51 4207 257.99
770.10 954.4 85.59 8186 514.63 5461 383.59 4759 316.30
800.10 954.4 85.59 8764 585.38 6038 454.33 5282 378.87
Values for dimensions and series not listed are available on request
53Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Designation Explanation
m’R Mass of the tube per 1 m of length
J’R Mass moment of inertia of the tube per 1 m of length
Universal joint shafts with length compensation Universal joint shafts without length compensation
mL min Mass of the universal joint shaft for a length of…
lz min lminJL min Mass moment of inertia of the universal joint shaft
for a length of…
Calculations for the entire universal joint shaft:
mges Total mass mges = mL min + (lz – lz min) · m’R mges = mL min + (l – lmin) · m’R
Jges Total mass moment of inertia Jges = JL min + (lz – lz min) · J’R Jges = JL min + (l – lmin) · J’R
Size Values for the tube based on length
Universal joint shafts with length compensation Universal joint shafts without length
compensation
Joint coupling
m’R J’R mL min JL min mL min JL min mL min JL min mL min JL min mL min JL min mL min JL min mL min JL min mL min JL min mL fix JL fix
[kg/m] [kg·m2/m] [kg] [kg·m2] [kg] [kg·m2] [kg] [kg·m2] [kg] [kg·m2] [kg] [kg·m2] [kg] [kg·m2] [kg] [kg·m2] [kg] [kg·m2] [kg] [kg·m2]
HT/HF HT HF HG
350.10 134.2 2.50 685 10.41 508 7.47 453 6.32
390.10 149.9 3.48 1018 17.59 708 12.94 626 10.85
440.10 189.3 5.68 1415 32.04 1001 23.19 895 19.68
490.10 261.3 9.41 1979 54.73 1379 39.61 1228 33.48
550.10 305.2 14.97 2807 100.35 1918 70.47 1730 60.33
590.10 564.7 29.97 3887 143.96 2442 100.48 2154 83.96
620.10 564.7 29.97 4232 168.93 2787 125.45 2466 106.01
650.10 683.3 43.88 4949 220.04 3243 162.00 2856 135.18
680.10 683.3 43.88 5364 256.12 3657 198.08 3232 167.10
710.10 813.2 62.14 6523 347.32 4286 255.85 3758 212.41
740.10 813.2 62.14 7020 398.98 4783 307.51 4207 257.99
770.10 954.4 85.59 8186 514.63 5461 383.59 4759 316.30
800.10 954.4 85.59 8764 585.38 6038 454.33 5282 378.87
Values for dimensions and series not listed are available on request
54 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
When installing the Voith universal joint shaft in a drive
line, connecting flanges and bolted connections must
satisfy several requirements:
1. Design
n When using a universal joint shaft without length
compensation, a connecting flange ("roll end hub")
that is moveable in a longitudinal direction is required
so that the universal joint shaft can slide over the
spigot. The connecting flange also absorbs additional
length changes arising, for instance, from thermal
expansion or changes in the deflection angle.
2. Material
n The material used for the connecting flanges has
been selected to permit use of bolts in property class
10.9 (to ISO 4014-10.9).
n Special case for S, M and W Series:
If the material used for the connecting flanges does
not permit use of bolts in property class 10.9, the
torque that can be transmitted by the flange con-
nection is reduced. The specified tightening torques
for the bolts must be reduced accordingly.
3. Dimensions, bolted connections
n On universal joint shafts from the S, M and W Series,
the dimensions of the connecting flanges match
those of the universal joint shaft, except for the
locating diameter c. The locating diameter provides
a clearance (fit H7/h6).
n On universal joint shafts from the H Series, the dimen-
sions of the connecting flanges are identical to those
of the universal joint shaft. The Hirth couplings are
self-centering.
n On universal joint shafts from the S, M and W Series,
the relief diameter fg on the universal joint shaft
flange is not suitable for locking hexagon head bolts
or nuts. A relief diameter fa on the connecting flange
is suitable for this purpose.
9.5 Installation: Connection flanges, bolted connections
55Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Sketch of the flange connection for S, M, W and H Series universal joint shafts
Bolt hole pattern for the flange connection on S, M, W and H Series universal joint shafts
A B A
Z1
g g v
ya
t
øb
øf gøa
øf a øc
x
Z2
mn o p
mmin Z1
g g v
øb
øf gøa
øf a
m
S, M, W Series Series H
A+B
22.5°
A A
A
A
B
8 x A 4 x B
10 x A 4 x B
A
A
A
B
22.5° 30°
8 x A
10 x A
12 x A
16 x A
36° 36°22.5°
A
A
A
A
A
A
A
AA A
A
A
A
mmin
56 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Dimensions of the connecting flanges
Standardbolted connection (A)
Bolted connection with split sleeve (B)
Comments 1 2 3 4 5 6 7 8 9 10 11 12
Size a b ±0.1 c H7 fa -0.3 fg g t v x P9 ya +0.5 Z1. Z2 z z z m MA EB z n o p MA
[mm] [mm] [mm] [mm] [mm] [mm] [mm] [mm] [mm] [mm] [mm] Bolt [Nm] Bolt Sleeve Washer [Nm]
ST/STL/STK/STR/SF/SG
058.1 58 47 30 38.5 3.5 1.2 -0.15 9 0.05 4 M5 x 16 7 No
065.1 65 52 35 41.5 4 1.5 -0.25 12 0.05 4 M6 x 20 13 No
075.1 75 62 42 51.5 5.5 2.3 -0.2 14 0.05 6 M6 x 25 13 No
090.2 90 74.5 47 61 6 2.3 -0.2 13 0.05 4 M8 x 25 32 No
100.2 100 84 57 70.5 7 2.3 -0.2 11 0.05 6 M8 x 25 32 No
120.2 120 101.5 75 84 8 2.3 -0.2 14 0.05 8 M10 x 30 64 No
120.5 120 101.5 75 84 9 2.3 -0.2 13 0.05 8 M10 x 30 64 No
150.2 150 130 90 110.3 10 2.3 -0.2 20 0.05 8 M12 x 40 111 No
150.3 150 130 90 110.3 12 2.3 -0.2 18 0.05 8 M12 x 40 111 No
150.5 150 130 90 110.3 12 2.3 -0.2 18 0.05 8 M12 x 40 111 No
180.5 180 155.5 110 132.5 14 2.3 -0.2 21 0.05 8 M14 x 45 177 No
225.7 225 196 140 171 159 15 4 -0.2 25 0.06 8 M16 x 55 270 No 4 M12 x 60 21 x 28 13 82
250.8 250 218 140 190 176 18 5 -0.2 24 0.06 8 M18 x 60 372 No 4 M14 x 70 25 x 32 15 130
285.8 285 245 175 214 199 20 6 -0.5 30 0.06 8 M20 x 70 526 No 4 M16 x 75 28 x 36 17 200
315.8 315 280 175 247 231 22 6 -0.5 31 0.06 8 M22 x 75 710 Yes 4 M16 x 80 30 x 40 17 200
350.8 350 310 220 277 261 25 7 -0.5 30 0.06 10 M22 x 80 710 Yes 4 M18 x 90 32 x 45 19 274
390.8 390 345 250 308 290 32 7 -0.5 36 0.06 10 M24 x 100 906 No 4 M18 x 110 32 x 60 19 274
435.8 435 385 280 342 320 40 8 -0.5 40 0.06 10 M27 x 120 1340 No 4 M20 x 110 35 x 60 21 386
MT/MTR/MF/MG
225.8 225 196 140 171 159 15 4 -0.2 15 0.06 8 M16 x 55 270 Yes 4 M12 x 60 21 x 28 13 82
250.8 250 218 140 190 176 18 5 -0.2 18 0.06 8 M18 x 50 372 Yes 4 M14 x 70 25 x 32 15 130
285.8 285 245 175 214 199 20 6 -0.5 20 0.06 8 M20 x 70 526 No 4 M16 x 75 28 x 36 17 200
315.8 315 280 175 247 231 22 6 -0.5 22 0.06 8 M22 x 75 710 Yes 4 M16 x 80 30 x 40 17 200
350.8 350 310 220 277 261 25 7 -0.5 25 0.06 8 M22 x 80 710 Yes 4 M18 x 90 32 x 45 19 274
WT/WTL/WTK/WF/WG
225.8 225 196 105 171 159 20 4 -0.2 25 32 9.5 0.06 8 4 M16 x 55 270 No
250.8 250 218 105 190 176 25 5 -0.2 25 40 13 0.06 8 4 M18 x 75 372 No
285.8 285 245 125 214 199 27 6 -0.5 26 40 15.5 0.06 8 4 M20 x 80 526 No
315.8 315 280 130 247 231 32 7 -0.5 31 40 15.5 0.06 10 4 M22 x 95 710 No
350.8 350 310 155 277 261 35 7 -0.5 30 50 16.5 0.06 10 6 M22 x 100 710 No
390.8 390 345 170 308 290 40 7 -0.5 40 70 18.5 0.06 10 6 M24 x 120 906 No
440.8 435 385 190 342 320 42 9 -0.5 38 80 20.5 0.1 10 6 M27 x 120 1340 No
490.8 490 425 205 377 350 47 11 -0.5 46 90 23 0.1 10 8 M30 x 140 1820 No
550.8 550 492 250 444 420 50 11 -0.5 40 100 23 0.1 10 8 M30 x 140 1820 No
HT/HF/HG
350.10 350 320 295 280 45 25 0.15 12 M16 x 115 270 No
390.10 390 355 327 305 50 30 0.15 12 M18 x 130 372 No
440.10 440 405 377 355 55 40 0.15 16 M18 x 150 372 No
490.10 490 450 419 395 60 30 0.15 16 M20 x 150 526 No
550.10 550 510 477 450 70 30 0.15 16 M22 x 170 710 No
57Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Dimensions of the connecting flanges
Standardbolted connection (A)
Bolted connection with split sleeve (B)
Comments 1 2 3 4 5 6 7 8 9 10 11 12
Size a b ±0.1 c H7 fa -0.3 fg g t v x P9 ya +0.5 Z1. Z2 z z z m MA EB z n o p MA
[mm] [mm] [mm] [mm] [mm] [mm] [mm] [mm] [mm] [mm] [mm] Bolt [Nm] Bolt Sleeve Washer [Nm]
ST/STL/STK/STR/SF/SG
058.1 58 47 30 38.5 3.5 1.2 -0.15 9 0.05 4 M5 x 16 7 No
065.1 65 52 35 41.5 4 1.5 -0.25 12 0.05 4 M6 x 20 13 No
075.1 75 62 42 51.5 5.5 2.3 -0.2 14 0.05 6 M6 x 25 13 No
090.2 90 74.5 47 61 6 2.3 -0.2 13 0.05 4 M8 x 25 32 No
100.2 100 84 57 70.5 7 2.3 -0.2 11 0.05 6 M8 x 25 32 No
120.2 120 101.5 75 84 8 2.3 -0.2 14 0.05 8 M10 x 30 64 No
120.5 120 101.5 75 84 9 2.3 -0.2 13 0.05 8 M10 x 30 64 No
150.2 150 130 90 110.3 10 2.3 -0.2 20 0.05 8 M12 x 40 111 No
150.3 150 130 90 110.3 12 2.3 -0.2 18 0.05 8 M12 x 40 111 No
150.5 150 130 90 110.3 12 2.3 -0.2 18 0.05 8 M12 x 40 111 No
180.5 180 155.5 110 132.5 14 2.3 -0.2 21 0.05 8 M14 x 45 177 No
225.7 225 196 140 171 159 15 4 -0.2 25 0.06 8 M16 x 55 270 No 4 M12 x 60 21 x 28 13 82
250.8 250 218 140 190 176 18 5 -0.2 24 0.06 8 M18 x 60 372 No 4 M14 x 70 25 x 32 15 130
285.8 285 245 175 214 199 20 6 -0.5 30 0.06 8 M20 x 70 526 No 4 M16 x 75 28 x 36 17 200
315.8 315 280 175 247 231 22 6 -0.5 31 0.06 8 M22 x 75 710 Yes 4 M16 x 80 30 x 40 17 200
350.8 350 310 220 277 261 25 7 -0.5 30 0.06 10 M22 x 80 710 Yes 4 M18 x 90 32 x 45 19 274
390.8 390 345 250 308 290 32 7 -0.5 36 0.06 10 M24 x 100 906 No 4 M18 x 110 32 x 60 19 274
435.8 435 385 280 342 320 40 8 -0.5 40 0.06 10 M27 x 120 1340 No 4 M20 x 110 35 x 60 21 386
MT/MTR/MF/MG
225.8 225 196 140 171 159 15 4 -0.2 15 0.06 8 M16 x 55 270 Yes 4 M12 x 60 21 x 28 13 82
250.8 250 218 140 190 176 18 5 -0.2 18 0.06 8 M18 x 50 372 Yes 4 M14 x 70 25 x 32 15 130
285.8 285 245 175 214 199 20 6 -0.5 20 0.06 8 M20 x 70 526 No 4 M16 x 75 28 x 36 17 200
315.8 315 280 175 247 231 22 6 -0.5 22 0.06 8 M22 x 75 710 Yes 4 M16 x 80 30 x 40 17 200
350.8 350 310 220 277 261 25 7 -0.5 25 0.06 8 M22 x 80 710 Yes 4 M18 x 90 32 x 45 19 274
WT/WTL/WTK/WF/WG
225.8 225 196 105 171 159 20 4 -0.2 25 32 9.5 0.06 8 4 M16 x 55 270 No
250.8 250 218 105 190 176 25 5 -0.2 25 40 13 0.06 8 4 M18 x 75 372 No
285.8 285 245 125 214 199 27 6 -0.5 26 40 15.5 0.06 8 4 M20 x 80 526 No
315.8 315 280 130 247 231 32 7 -0.5 31 40 15.5 0.06 10 4 M22 x 95 710 No
350.8 350 310 155 277 261 35 7 -0.5 30 50 16.5 0.06 10 6 M22 x 100 710 No
390.8 390 345 170 308 290 40 7 -0.5 40 70 18.5 0.06 10 6 M24 x 120 906 No
440.8 435 385 190 342 320 42 9 -0.5 38 80 20.5 0.1 10 6 M27 x 120 1340 No
490.8 490 425 205 377 350 47 11 -0.5 46 90 23 0.1 10 8 M30 x 140 1820 No
550.8 550 492 250 444 420 50 11 -0.5 40 100 23 0.1 10 8 M30 x 140 1820 No
HT/HF/HG
350.10 350 320 295 280 45 25 0.15 12 M16 x 115 270 No
390.10 390 355 327 305 50 30 0.15 12 M18 x 130 372 No
440.10 440 405 377 355 55 40 0.15 16 M18 x 150 372 No
490.10 490 450 419 395 60 30 0.15 16 M20 x 150 526 No
550.10 550 510 477 450 70 30 0.15 16 M22 x 170 710 No
Desig-nation
Explanation Com-ments
Additional information
a Flange diameter
b Bolt circle diameter
c Locating diameter
fa Flange diameter, bolt side
fg Flange diameter, nut side
g Flange thickness
t Locating depth in connecting flange
v Length from the contact surface of the nut to the end of the hexagon head bolt
x Width of face key in universal joint shaft connecting flanges with face key
ya Depth of face key in universal joint shaft connecting flanges with a face key
Z1 Axial run-out 1 Permissible values for deviation in axial run-out Z1 and concentricity Z2 at operating speeds below 1500 rpm. At operating speeds of 1500 rpm to 3000 rpm, the values should be halved!
Z2 Concentricity
m Hexagon head bolt to ISO 4014-10.9 with hexagon nut to ISO 7040-10
2 z each per standard connecting flange
3 z each per connecting flange with face key
4 z each per connecting flange with Hirth coupling
5 Dimension of hexagon head bolt with nut
6 Tightening torque for a coefficient of friction μ = 0.12 and 90% utilization of the bolt yield point value
mmin Minimum length for installation of bolt
Length of the hexagon head bolt m including the height of the bolt head
EB Options for insertion 7 Insertion of bolts from the joint side
n Hexagon head bolt to ISO 4014-8.8 with hexagon nut to ISO 7040-10
8 z each per connecting flange
9 Dimension of hexagon head bolt with nut
12 Tightening torque for a coefficient of friction μ = 0.12 and 90% utilization of the bolt yield point
o Split sleeve 10 Split sleeve dimensions [mm x mm]
p Washer 11 Washer dimensions [mm]
58 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Original spare parts supply
Modernizations, retrofits
Repairs
Overhaul
Torque measurements (ACIDA)
Consulting and engineeringPre-sales
After-sales
10 Service
For us, service means quality and dependability that exceeds the expectations of our
customers. We will support you anywhere in the world throughout the entire lifetime of
your plant. You can count on us from the planning and commissioning phase through to
maintenance. With the Universal Joint Shaft Service from Voith Turbo, you will increase
the availability and lifetime of your system.
Success needs reliable partners.That’s what moves us.
Training
Installation Commissioning
59Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Proper installation of a universal joint shaft provides the basis
for problem-free commissioning. A systematic commissioning
procedure with extensive operational testing is an important
factor in achieving reliable and long-lasting operation of the
universal joint shaft and the entire system.
10.1 Installation and commissioning
Your benefits
n Immediate access to the know-how of experts during
the entire start-up phase
n Assurance of problem-free and professional commis-
sioning of your universal joint shaft
Our services:
n Installation and commissioning by our service experts
n Training of the operating and maintenance personnel
60 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
10.2 Training
Efficiency, reliability and availability are essential factors in
making your system successful. One requirement in this regard
is the best-trained employees in technology and servicing.
Initial and continuing training are worthwhile investments to
ensure efficient operation of your universal joint shaft. Our
training programs provide specific technical knowledge about
our products. We bring your personnel up to speed with the
latest Voith technology – in theory and in practice.
Your benefits
n Safe handling of Voith products
n Avoidance of operating and maintenance errors
n Better understanding of Voith technology in the
drive line
Our services:
n Product training at Voith or on-site at your premises
n Theoretical and practical maintenance and repair
training
61Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Your benefits
n Safe and reliable operation of all components
n The highest quality and parts that fit exactly
n Maximum lifetime of drive elements
n Manufacturer‘s warranty
n High degree of system availability
n Fast spare parts delivery
10.3 Voith genuine spare parts
Our services:
n Most original spare and wearing parts warehoused at
our service branches
n Shipment of in-stock parts on the same day
(for orders received by 11 a.m.)
n Consultation with your spare parts management staff
n Preparation of project-specific spare and wearing
parts packages
n Spare parts also available for older generations of
Voith universal joint shafts
Avoid risks by using original spare and wearing parts. Only these
are manufactured with Voith know-how and guarantee reliable
and safe operation of your Voith products. High availability, com-
bined with efficient logistics, ensures quick delivery of parts
around the world.
62 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
10.4 Overhaul, maintenance
Constant operation subjects universal joint shafts to natural wear,
which is also influenced by the surroundings. Professional and
regular overhauls of your universal joint shaft prevent damage
and minimize the risk of expensive production down time. You
gain operational reliability and save money in the long term.
Your benefits
n Safety thanks to professional maintenance
n Manufacturer‘s warranty
n Increased system availability
Our services
n Maintenance or complete overhaul by our service
experts with all the necessary tools and special
fixtures
n Use of original spare and wearing parts
n Consultation regarding your maintenance strategy
63Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Even with the best preventive maintenance, unplanned down time
due to equipment failures cannot be excluded. The priority then
is to repair machinery and equipment as quickly as possible. As
the manufacturer, we not only have a wealth of knowledge about
universal joint shafts, but also possess the necessary technical
competence, experience and tools to ensure professional repairs.
Our service technicians can assess the damage in a minimum
amount of time and provide suggestions for rapid rectification of
the situation.
10.5 Repairs, maintenance
Your benefits
n Safety thanks to proper repair
n Manufacturer‘s warranty
n The shortest possible outage and down time
n Avoidance of a repeat outage or malfunction
Our services:
n Fast and professional repairs that comply with our
safety standards on-site at your premises or in one of
the head office-certified Voith Service Centers around
the world
n Competent damage assessment with analysis of
weaknesses
n Fast delivery of original spare parts
64 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
10.6 Modernization, retrofits
Technology is advancing all the time and sometimes the original
requirements on which the design of a system was based can
change. Voith Turbo helps you achieve significant improvements
in efficiency and reliability through a tailored modernization or
retrofit of old drive elements, e.g. slipper spindles. We analyze,
provide advice and modernize universal joint shafts – including
the connecting components – to provide you with the latest and
most economical technology.
Your benefits
n Improved reliability, availability and affordability
of your drive system
n Reduced operating costs
n A universal joint shaft that features the latest
technology
Our services
n Modification of or a new design for your universal
joint shafts and connecting components
n Competent consultation regarding modernization
opportunities, including the design of the drive line
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11 High-performance lubricant for universal joint shafts
Voith development engineers have combined their universal joint
shaft know-how with the tribological know-how of renowned bear-
ing and lubricant manufacturers. The result of this cooperation is
an innovative and exclusive lubricant with properties far above
those of conventional standard lubricants. This lubricant gives
bearings in universal joint shafts operating at low speeds and
under high loads an even longer life. In addition, lubrication inter-
vals are extended and emergency dry-running characteristics im-
proved significantly.
Voith WearCare 500 in 45 kg and 180 kg drums
66 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Characteristics of Voith‘s WearCare 500 high-performance lubricant
Benefits
n Optimum adhesion and surface wetting n Lubricating film even in the event of poor lubricationn Formulated for oscillating bearing motion
n Exceptional corrosion protection n Ideal for rolling mills
n Maximum ability to withstand pressure n Hydrodynamic lubricating film even under maximum torque conditions
n Optimum and long-lasting lubricating action n Minimal abrasive wear in the bearingn Extended lubrication intervalsn Lower maintenance costs
n Can be mixed with lithium-based greases n Simple conversion to Voith‘s high-performance lubricant
n High resistance to aging n Long shelf life
n Excellent compatibility with all bearing components n No softening of bearing sealsn Does not corrode nonferrous metals
n Free from silicone and copper-based ingredients n Suitable for aluminum rolling mills
FE8 test stand trial: Bearing wear in an axial cylindrical roller bearing
Field trial: Metal particles in the bearing lubricant of a high-performance universal joint shaft used in a rolling mill drive
1
10
Rel
ativ
e be
arin
g w
ear
Standard lubricant
Voith WearCare 500
5
15
1
0Rel
ativ
e m
etal
par
ticle
s in
the
lubr
ican
t
Voith WearCare 500
Operating time in months
0 3 6 9 15 18 21 2412
Standard lubricant
1.5
0.5 Extended operating time
Reference wear condition
67Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Certificates for the management systems to ISO 9001: 2000 (quality), ISO 14001: 2000 (environment) and OHSAS 18001: 1999 (occupational health and safety)
At Voith, our top priority is to ensure the affordability, reliability,
environmental compatibility and safety of our products and ser-
vices. In order to maintain these principles in the future just as
we do today, Voith Turbo has a firmly established integrated
management system for quality, the environment, and occupa-
tional health and safety. For our customers, this means that they
are purchasing high-quality capital goods that are manufactured
and can be used in safe surroundings and with minimal environ-
mental impact.
Characteristics of Voith‘s WearCare 500 high-performance lubricant
Benefits
n Optimum adhesion and surface wetting n Lubricating film even in the event of poor lubricationn Formulated for oscillating bearing motion
n Exceptional corrosion protection n Ideal for rolling mills
n Maximum ability to withstand pressure n Hydrodynamic lubricating film even under maximum torque conditions
n Optimum and long-lasting lubricating action n Minimal abrasive wear in the bearingn Extended lubrication intervalsn Lower maintenance costs
n Can be mixed with lithium-based greases n Simple conversion to Voith‘s high-performance lubricant
n High resistance to aging n Long shelf life
n Excellent compatibility with all bearing components n No softening of bearing sealsn Does not corrode nonferrous metals
n Free from silicone and copper-based ingredients n Suitable for aluminum rolling mills
12 Quality – Environment – Safety
68 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
12.1 Quality
Flange for a high-performance universal joint shaft on a 3-D coordinate measuring machine
n We employ state-of-the-art 3-D coordinate measuring
machines for quality assurance.
n To ensure perfectly welded joints, we conduct x-ray
inspections in-house.
n We offer our customers a variety of product and
application-specific certifications and classifications.
n Production and assembly fixtures are inspected on a
regular basis.
n Quality-relevant measuring and testing instruments
are subject to systematic monitoring.
n For the welding methods employed, process controls
to ISO SO 3834-2 are used. Welding technicians are
qualified to EN 287 and welding equipment is
monitored.
n Employees that perform nondestructive testing are
qualified to ASNT-C-1A and/or EN 473.
69Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
12.2 Environment
n Voith universal joint shafts are fitted with sealed roller
bearings. These provide two major advantages over
slipper and gear spindles when using our universal
joint shafts:
An employee coats the roller bearing for a universal joint shaft with Voith WearCare 500 high-performance lubricant
Comparison of the efficiency and power loss in a main drive for a rolling mill. Input power 8000 kW, deflection angle 2°
EfficiencyPower loss
99.10%
71.1 kW
Slipper spindle
99.49%41.1 kW
Gear spindle
0.32 kW
Voith universal joint shaft
99.996%
1. Lubricant consumption is considerably lower be-
cause of the seals.
2. Efficiency is enhanced, as rolling friction is signifi-
cantly less than sliding friction. This translates into
reduced CO2 emissions and protects the environ-
ment.
70 Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Voith universal joint shafts receive their final finish in a modern paint booth
12.3 Occupational health and safety
n Voith painting technicians use a modern painting
system that meets all requirements for occupational
health and safety as well as environmental protection
when painting the universal joint shafts.
n Electrostatic application of the paint reduces over-
spray.
n An exhaust system extracts any residual mist from
painting.
n An exhaust air treatment system with combined heat
recovery reduces the impact on employees as well as
the environment.
71Voith Turbo I High-Performance Universal Joint Shafts I G 830 en
Voith Turbo GmbH & Co. KG
Universal Joint Shafts and Hirth Couplings
Alexanderstr. 2
89522 Heidenheim, Germany
Tel. +49 7321 37-8283
Fax +49 7321 37-7106
UJShafts@voith.com
www.voithturbo.com/universal-joint-shafts
G83
0en
, S&
F-S
DL/
CM
, 04.
2010
, 150
0. D
imen
sion
s an
d ill
ustr
atio
ns w
ithou
t ob
ligat
ion.
Sub
ject
to
mod
ifica
tions
.