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(Redirected from ZF 5HP19 transmission) Motor vehicle automatic transmission models For the heavy-duty 5 speed automatic transmission, see ZF Ecomat. Motor vehicle
5HP 18 · 5HP 30 · 5HP 24
Overview
ManufacturerZF Friedrichshafen
Production1991–2008
Model years1991–2008
Body and chassis
Class5-Speed Longitudinal Automatic Transmission
RelatedMB 5G-Tronic
Chronology
PredecessorZF 4HP Transmission Family
SuccessorZF 6HP

5HP is ZF Friedrichshafen AG's trademark name for its 5-speed automatic transmission models (5-speed transmission with Hydraulic converter and Planetary gearsets) for longitudinal engine applications, designed and built by ZF's subsidiary in Saarbrücken.

Gear Ratios
GearModel R 1 2 3 4 5 Total
Span
Span
Center
Avg.
Step
Compo-
nents
5HP 18 · 1990
5HP 19 · 1997
−4.096 3.665 1.995 1.407 1.000 0.742 4.936 1.650 1.491 3 Gearsets
3 Brakes
4 Clutches
5HP 30 · 1992 −3.684 3.553 2.244 1.545 1.000 0.787 4.517 1.672 1.458 3 Gearsets
3 Brakes
3 Clutches
5HP 24 · 1996 −4.095 3.571 2.200 1.505 1.000 0.804 4.444 1.694 1.452
  1. Differences in gear ratios have a measurable, direct impact on vehicle dynamics, performance, waste emissions as well as fuel mileage

Specifications

Final Conventionally Designed Gearbox

With planetary gearboxes, the number of gears can be increased conventionally by adding additional gearsets as well as brakes and clutches, or conceptually by switching from serial to parallel power flow. The conceptual way requires a computer-aided design.

The 5HP is the last transmission family with serial power flow: to provide more gears, components were added. This makes these transmissions larger, heavier and even more expensive to manufacture. As the presence of 10 main components (together with brakes and clutches) in the Ravigneaux gearbox types shows, this meant the end of the conventional gearbox design. The approach of the all new Lepelletier gear mechanism from the later 6HP-family, requiring only 8 main components for 6 gears, reflects the progress that this new paradigm represented.

1990: 5HP 18 · 1997: 5HP 19 · Ravigneaux Planetary Gearset Types

Gear Ratios
With Assessment Planetary Gearset: Teeth Count Total
Center
Avg.
Ravigneaux Simple
Model
Type
Version
First Delivery
S1
R1
S2
R2
S3
R3
Brakes
Clutches
Ratio
Span
Gear
Step
Gear
Ratio
R
i R {\displaystyle {i_{R}}}
1
i 1 {\displaystyle {i_{1}}}
2
i 2 {\displaystyle {i_{2}}}
3
i 3 {\displaystyle {i_{3}}}
4
i 4 {\displaystyle {i_{4}}}
5
i 5 {\displaystyle {i_{5}}}
6
i 6 {\displaystyle {i_{6}}}
Step i R i 1 {\displaystyle -{\tfrac {i_{R}}{i_{1}}}} i 1 i 1 {\displaystyle {\tfrac {i_{1}}{i_{1}}}} i 1 i 2 {\displaystyle {\tfrac {i_{1}}{i_{2}}}} i 2 i 3 {\displaystyle {\tfrac {i_{2}}{i_{3}}}} i 3 i 4 {\displaystyle {\tfrac {i_{3}}{i_{4}}}} i 4 i 5 {\displaystyle {\tfrac {i_{4}}{i_{5}}}} i 5 i 6 {\displaystyle {\tfrac {i_{5}}{i_{6}}}}
Δ Step i 1 i 2 : i 2 i 3 {\displaystyle {\tfrac {i_{1}}{i_{2}}}:{\tfrac {i_{2}}{i_{3}}}} i 2 i 3 : i 3 i 4 {\displaystyle {\tfrac {i_{2}}{i_{3}}}:{\tfrac {i_{3}}{i_{4}}}} i 3 i 4 : i 4 i 5 {\displaystyle {\tfrac {i_{3}}{i_{4}}}:{\tfrac {i_{4}}{i_{5}}}} i 4 i 5 : i 5 i 6 {\displaystyle {\tfrac {i_{4}}{i_{5}}}:{\tfrac {i_{5}}{i_{6}}}}
Shaft
Speed
i 1 i R {\displaystyle {\tfrac {i_{1}}{i_{R}}}} i 1 i 1 {\displaystyle {\tfrac {i_{1}}{i_{1}}}} i 1 i 2 {\displaystyle {\tfrac {i_{1}}{i_{2}}}} i 1 i 3 {\displaystyle {\tfrac {i_{1}}{i_{3}}}} i 1 i 4 {\displaystyle {\tfrac {i_{1}}{i_{4}}}} i 1 i 5 {\displaystyle {\tfrac {i_{1}}{i_{5}}}} i 1 i 6 {\displaystyle {\tfrac {i_{1}}{i_{6}}}}
Δ Shaft
Speed
0 i 1 i R {\displaystyle 0-{\tfrac {i_{1}}{i_{R}}}} i 1 i 1 0 {\displaystyle {\tfrac {i_{1}}{i_{1}}}-0} i 1 i 2 i 1 i 1 {\displaystyle {\tfrac {i_{1}}{i_{2}}}-{\tfrac {i_{1}}{i_{1}}}} i 1 i 3 i 1 i 2 {\displaystyle {\tfrac {i_{1}}{i_{3}}}-{\tfrac {i_{1}}{i_{2}}}} i 1 i 4 i 1 i 3 {\displaystyle {\tfrac {i_{1}}{i_{4}}}-{\tfrac {i_{1}}{i_{3}}}} i 1 i 5 i 1 i 4 {\displaystyle {\tfrac {i_{1}}{i_{5}}}-{\tfrac {i_{1}}{i_{4}}}} i 1 i 6 i 1 i 5 {\displaystyle {\tfrac {i_{1}}{i_{6}}}-{\tfrac {i_{1}}{i_{5}}}}
5HP 18 310 N⋅m (229 lb⋅ft)
1990
38
34
34
98
32
76
3
4
4.9363
1.6495
1.4906
Gear
Ratio
−4.0960
1 , 323 323 {\displaystyle -{\tfrac {1,323}{323}}}
3.6648
1 , 323 361 {\displaystyle {\tfrac {1,323}{361}}}
1.9990
7 , 938 3 , 971 {\displaystyle {\tfrac {7,938}{3,971}}}
1.4067
294 209 {\displaystyle {\tfrac {294}{209}}}
1.0000
1 1 {\displaystyle {\tfrac {1}{1}}}
0.7424
49 66 {\displaystyle {\tfrac {49}{66}}}
Step 1.1176 1.0000 1.8333 1.4211 1.4067 1.3469
Δ Step 1.2901 1.0102 1.0444
Speed -0.8947 1.0000 1.8333 2.6053 3.6648 4.9363
Δ Speed 0.8947 1.0000 0.8333 0.7719 1.0596 1.2715
5HP 19 325 N⋅m (240 lb⋅ft)
1997
38
34
34
98
32
76
3
4
4.9363
1.6495
1.4906
Ratio −4.0960 3.6648 1.9990 1.4067 1.0000 0.7424
Ratio
R & Even
R 2 ( S 3 + R 3 ) S 2 R 3 {\displaystyle -{\tfrac {R_{2}(S_{3}+R_{3})}{S_{2}R_{3}}}} R 2 ( S 1 + R 1 ) ( S 3 + R 3 ) S 1 R 3 ( S 2 + R 2 ) {\displaystyle {\tfrac {R_{2}(S_{1}+R_{1})(S_{3}+R_{3})}{S_{1}R_{3}(S_{2}+R_{2})}}} 1 1 {\displaystyle {\tfrac {1}{1}}}
Ratio
Odd
R 1 R 2 ( S 3 + R 3 ) S 1 S 2 R 3 {\displaystyle {\tfrac {R_{1}R_{2}(S_{3}+R_{3})}{S_{1}S_{2}R_{3}}}} R 2 ( S 1 + R 1 ) S 1 ( S 2 + R 2 ) {\displaystyle {\tfrac {R_{2}(S_{1}+R_{1})}{S_{1}(S_{2}+R_{2})}}} R 2 S 2 + R 2 {\displaystyle {\tfrac {R_{2}}{S_{2}+R_{2}}}}
Algebra And Actuated Shift Elements
Brake A
Brake B
Brake C
Clutch D
Clutch E
Clutch F
Clutch G
Lepelletier Gear Mechanism
Simple Ravigneaux
6HP 600 N⋅m (443 lb⋅ft)
2000
37
71
31
38
38
85
2
3
6.0354
1.6977
1.4327
Gear
Ratio
−3.4025
4 , 590 1 , 349 {\displaystyle -{\tfrac {4,590}{1,349}}}
4.1708
9 , 180 2 , 201 {\displaystyle {\tfrac {9,180}{2,201}}}
2.3397
211 , 140 90 , 241 {\displaystyle {\tfrac {211,140}{90,241}}}
1.5211
108 71 {\displaystyle {\tfrac {108}{71}}}
1.1428
9 , 180 8 , 033 {\displaystyle {\tfrac {9,180}{8,033}}}
0.8672
4 , 590 5 , 293 {\displaystyle {\tfrac {4,590}{5,293}}}
0.6911
85 123 {\displaystyle {\tfrac {85}{123}}}
Step 0.8158 1.0000 1.7826 1.5382 1.3311 1.3178 1.2549
Δ Step 1.1589 1.1559 1.0101 1.0502
Speed –1.2258 1.0000 1.7826 2.7419 3.6497 4.8096 6.0354
Δ Speed 1.2258 1.0000 0.7826 0.9593 0.9078 1.1599 1.2258
  1. Layout
    • Input and output are on opposite sides
    • Planetary gearset 2 (the outer Ravigneaux gearset) is on the input (turbine) side
    • Input shafts are, if actuated, S1, C1/C2 (the combined carrier of the compound Ravigneaux gearset 1 + 2), and R1/S2
    • Output shaft is C3 (the carrier of gearset 3)
  2. Total Ratio Span (Total Ratio Spread · Total Gear Ratio)
    • i n i 1 {\displaystyle {\tfrac {i_{n}}{i_{1}}}}
    • A wider span enables the
      • downspeeding when driving outside the city limits
      • increase the climbing ability
        • when driving over mountain passes or off-road
        • or when towing a trailer
  3. Ratio Span's Center
    • ( i n i 1 ) 1 2 {\displaystyle (i_{n}i_{1})^{\tfrac {1}{2}}}
    • The center indicates the speed level of the transmission
    • Together with the final drive ratio
    • it gives the shaft speed level of the vehicle
  4. Average Gear Step
    • ( i n i 1 ) 1 n 1 {\displaystyle ({\tfrac {i_{n}}{i_{1}}})^{\tfrac {1}{n-1}}}
    • With decreasing step width
      • the gears connect better to each other
      • shifting comfort increases
  5. Sun 1: sun gear of gearset 1: inner Ravigneaux gearset
  6. Ring 1: ring gear of gearset 1: inner Ravigneaux gearset
  7. Sun 2: sun gear of gearset 2: outer Ravigneaux gearset
  8. Ring 2: ring gear of gearset 2: outer Ravigneaux gearset
  9. Sun 3: sun gear of gearset 3
  10. Ring 3: ring gear of gearset 3
  11. ^ Standard 50:50
    — 50 % Is Above And 50 % Is Below The Average Gear Step —
    • With steadily decreasing gear steps (yellow highlighted line Step)
    • and a particularly large step from 1st to 2nd gear
      • the lower half of the gear steps (between the small gears; rounded down, here the first 2) is always larger
      • and the upper half of the gear steps (between the large gears; rounded up, here the last 2) is always smaller
    • than the average gear step (cell highlighted yellow two rows above on the far right)
    • lower half: smaller gear steps are a waste of possible ratios (red bold)
    • upper half: larger gear steps are unsatisfactory (red bold)
  12. ^ Standard R:1
    — Reverse And 1st Gear Have The Same Ratio —
    • The ideal reverse gear has the same transmission ratio as 1st gear
      • no impairment when maneuvering
      • especially when towing a trailer
      • a torque converter can only partially compensate for this deficiency
    • Plus 11.11 % minus 10 % compared to 1st gear is good
    • Plus 25 % minus 20 % is acceptable (red)
    • Above this is unsatisfactory (bold)
  13. ^ Standard 1:2
    — Gear Step 1st To 2nd Gear As Small As Possible —
    • With continuously decreasing gear steps (yellow marked line Step)
    • the largest gear step is the one from 1st to 2nd gear, which
      • for a good speed connection and
      • a smooth gear shift
    • must be as small as possible
      • A gear ratio of up to 1.6667:1 (5:3) is good
      • Up to 1.7500:1 (7:4) is acceptable (red)
      • Above is unsatisfactory (bold)
  14. ^ From large to small gears (from right to left)
  15. ^ Standard STEP
    — From Large To Small Gears: Steady And Progressive Increase In Gear Steps —
    • Gear steps should
      • increase: Δ Step (first green highlighted line Δ Step) is always greater than 1
      • As progressive as possible: Δ Step is always greater than the previous step
    • Not progressively increasing is acceptable (red)
    • Not increasing is unsatisfactory (bold)
  16. ^ Standard SPEED
    — From Small To Large Gears: Steady Increase In Shaft Speed Difference —
    • Shaft speed differences should
      • increase: Δ Shaft Speed (second line marked in green Δ (Shaft) Speed) is always greater than the previous one
    • 1 difference smaller than the previous one is acceptable (red)
    • 2 consecutive ones are a waste of possible ratios (bold)
  17. ^ inner and outer sun gears of the Ravigneaux planetary gearset are inverted
  18. Blocks R1 (ring gear of the inner Ravigneaux gearset) and S2 (sun gear of the outer Ravigneaux gearset)
  19. Blocks C1 and C2 (the common Ravigneaux carrier 1 + 2)
  20. Blocks S3
  21. Connects S1 (the sun of the inner Ravigneaux gearset) with the turbine
  22. Couples R1 (the ring gear of the inner Ravigneaux gearset) and S2 (the sun gear of the outer Ravigneaux gearset) with the turbine
  23. Connects C1 and C2 (the common Ravigneaux carrier 1 + 2) with the turbine
  24. Couples S3 with R3
  25. To reflect the progress, the Lepelletier gear mechanism means both technically and in terms of manufacturing effort. The 6HP-transmission is the first one to use this intriguing gear mechanism

1992: 5HP 30 · 1996: 5HP 24 · Simpson Planetary Gearset Types

Gear Ratios
With Assessment Planetary Gearset: Teeth Count Total
Center
Avg.
Simpson Simple
Model
Type
Version
First Delivery
S1
R1
S2
R2
S3
R3
Brakes
Clutches
Ratio
Span
Gear
Step
Gear
Ratio
R
i R {\displaystyle {i_{R}}}
1
i 1 {\displaystyle {i_{1}}}
2
i 2 {\displaystyle {i_{2}}}
3
i 3 {\displaystyle {i_{3}}}
4
i 4 {\displaystyle {i_{4}}}
5
i 5 {\displaystyle {i_{5}}}
6
i 6 {\displaystyle {i_{6}}}
Step i R i 1 {\displaystyle -{\tfrac {i_{R}}{i_{1}}}} i 1 i 1 {\displaystyle {\tfrac {i_{1}}{i_{1}}}} i 1 i 2 {\displaystyle {\tfrac {i_{1}}{i_{2}}}} i 2 i 3 {\displaystyle {\tfrac {i_{2}}{i_{3}}}} i 3 i 4 {\displaystyle {\tfrac {i_{3}}{i_{4}}}} i 4 i 5 {\displaystyle {\tfrac {i_{4}}{i_{5}}}} i 5 i 6 {\displaystyle {\tfrac {i_{5}}{i_{6}}}}
Δ Step i 1 i 2 : i 2 i 3 {\displaystyle {\tfrac {i_{1}}{i_{2}}}:{\tfrac {i_{2}}{i_{3}}}} i 2 i 3 : i 3 i 4 {\displaystyle {\tfrac {i_{2}}{i_{3}}}:{\tfrac {i_{3}}{i_{4}}}} i 3 i 4 : i 4 i 5 {\displaystyle {\tfrac {i_{3}}{i_{4}}}:{\tfrac {i_{4}}{i_{5}}}} i 4 i 5 : i 5 i 6 {\displaystyle {\tfrac {i_{4}}{i_{5}}}:{\tfrac {i_{5}}{i_{6}}}}
Shaft
Speed
i 1 i R {\displaystyle {\tfrac {i_{1}}{i_{R}}}} i 1 i 1 {\displaystyle {\tfrac {i_{1}}{i_{1}}}} i 1 i 2 {\displaystyle {\tfrac {i_{1}}{i_{2}}}} i 1 i 3 {\displaystyle {\tfrac {i_{1}}{i_{3}}}} i 1 i 4 {\displaystyle {\tfrac {i_{1}}{i_{4}}}} i 1 i 5 {\displaystyle {\tfrac {i_{1}}{i_{5}}}} i 1 i 6 {\displaystyle {\tfrac {i_{1}}{i_{6}}}}
Δ Shaft
Speed
0 i 1 i R {\displaystyle 0-{\tfrac {i_{1}}{i_{R}}}} i 1 i 1 0 {\displaystyle {\tfrac {i_{1}}{i_{1}}}-0} i 1 i 2 i 1 i 1 {\displaystyle {\tfrac {i_{1}}{i_{2}}}-{\tfrac {i_{1}}{i_{1}}}} i 1 i 3 i 1 i 2 {\displaystyle {\tfrac {i_{1}}{i_{3}}}-{\tfrac {i_{1}}{i_{2}}}} i 1 i 4 i 1 i 3 {\displaystyle {\tfrac {i_{1}}{i_{4}}}-{\tfrac {i_{1}}{i_{3}}}} i 1 i 5 i 1 i 4 {\displaystyle {\tfrac {i_{1}}{i_{5}}}-{\tfrac {i_{1}}{i_{4}}}} i 1 i 6 i 1 i 5 {\displaystyle {\tfrac {i_{1}}{i_{6}}}-{\tfrac {i_{1}}{i_{5}}}}
5HP 30 560 N⋅m (413 lb⋅ft)
1992
40
100
32
108
38
97
3
3
4.5169
1.6716
1.4578
Gear
Ratio
−3.6842
70 19 {\displaystyle -{\tfrac {70}{19}}}
3.5526
135 38 {\displaystyle {\tfrac {135}{38}}}
2.2436
175 78 {\displaystyle {\tfrac {175}{78}}}
1.5449
275 178 {\displaystyle {\tfrac {275}{178}}}
1.0000
1 1 {\displaystyle {\tfrac {1}{1}}}
0.7865
70 89 {\displaystyle {\tfrac {70}{89}}}
Step 1.0370 1.0000 1.5835 1.4522 1.5449 1.2714
Δ Step 1.0904 0.9400 1.2151
Speed -0.9643 1.0000 1.5835 2.2995 3.5526 4.5169
Δ Speed 0.9643 1.0000 0.5835 0.7161 1.2531 0.9643
5HP 24 440 N⋅m (325 lb⋅ft)
1996
36
93
32
100
35
90
3
3
4.4435
1.6943
1.4519
Gear
Ratio
−4.0952
86 21 {\displaystyle -{\tfrac {86}{21}}}
3.5714
25 7 {\displaystyle {\tfrac {25}{7}}}
2.2000
11 5 {\displaystyle {\tfrac {11}{5}}}
1.5047
161 107 {\displaystyle {\tfrac {161}{107}}}
1.0000
1 1 {\displaystyle {\tfrac {1}{1}}}
0.8037
86 107 {\displaystyle {\tfrac {86}{107}}}
Step 1.1467 1.0000 1.6234 1.4621 1.5047 1.2419
Δ Step 1.1103 0.9717 1.2094
Speed -0.8721 1.0000 1.6234 2.3736 3.5714 4.4435
Δ Speed 0.8721 1.0000 0.6234 0.7502 1.1979 0.8721
Ratio
R & Even
S 2 ( S 1 + R 1 ) ( S 3 + R 3 ) S 1 R 2 S 3 {\displaystyle -{\tfrac {S_{2}(S_{1}+R_{1})(S_{3}+R_{3})}{S_{1}R_{2}S_{3}}}} ( S 2 + R 2 ) ( S 3 + R 3 ) S 2 R 3 + S 3 ( S 2 + R 2 ) {\displaystyle {\tfrac {(S_{2}+R_{2})(S_{3}+R_{3})}{S_{2}R_{3}+S_{3}(S_{2}+R_{2})}}} 1 1 {\displaystyle {\tfrac {1}{1}}}
Ratio
Odd
S 3 + R 3 S 3 {\displaystyle {\tfrac {S_{3}+R_{3}}{S_{3}}}} ( S 1 ( S 2 + R 2 ) + R 1 S 2 ) ( S 3 + R 3 ) S 2 ( S 1 + R 1 ) ( S 3 + R 3 ) + S 1 R 2 S 3 {\displaystyle {\tfrac {(S_{1}(S_{2}+R_{2})+R_{1}S_{2})(S_{3}+R_{3})}{S_{2}(S_{1}+R_{1})(S_{3}+R_{3})+S_{1}R_{2}S_{3}}}} S 2 ( S 1 + R 1 ) ( S 3 + R 3 ) S 2 ( S 1 + R 1 ) ( S 3 + R 3 ) + S 1 R 2 S 3 {\displaystyle {\tfrac {S_{2}(S_{1}+R_{1})(S_{3}+R_{3})}{S_{2}(S_{1}+R_{1})(S_{3}+R_{3})+S_{1}R_{2}S_{3}}}}
Algebra And Actuated Shift Elements
Brake A
Brake B
Brake C
Clutch D
Clutch E
Clutch F
Lepelletier Gear Mechanism
Simple Ravigneaux
6HP 600 N⋅m (443 lb⋅ft)
2000
37
71
31
38
38
85
2
3
6.0354
1.6977
1.4327
Gear
Ratio
−3.4025
4 , 590 1 , 349 {\displaystyle -{\tfrac {4,590}{1,349}}}
4.1708
9 , 180 2 , 201 {\displaystyle {\tfrac {9,180}{2,201}}}
2.3397
211 , 140 90 , 241 {\displaystyle {\tfrac {211,140}{90,241}}}
1.5211
108 71 {\displaystyle {\tfrac {108}{71}}}
1.1428
9 , 180 8 , 033 {\displaystyle {\tfrac {9,180}{8,033}}}
0.8672
4 , 590 5 , 293 {\displaystyle {\tfrac {4,590}{5,293}}}
0.6911
85 123 {\displaystyle {\tfrac {85}{123}}}
Step 0.8158 1.0000 1.7826 1.5382 1.3311 1.3178 1.2549
Δ Step 1.1589 1.1559 1.0101 1.0502
Speed –1.2258 1.0000 1.7826 2.7419 3.6497 4.8096 6.0354
Δ Speed 1.2258 1.0000 0.7826 0.9593 0.9078 1.1599 1.2258
  1. Layout
    • Input and output are on opposite sides
    • Planetary gearset 1 is on the input (turbine) side
    • Input shafts are, if actuated, S1, C2, S3, and R1
    • Output shaft is C3 (the carrier of gearset 3)
  2. Total Ratio Span (Total Ratio Spread · Total Gear Ratio)
    • i n i 1 {\displaystyle {\tfrac {i_{n}}{i_{1}}}}
    • A wider span enables the
      • downspeeding when driving outside the city limits
      • increase the climbing ability
        • when driving over mountain passes or off-road
        • or when towing a trailer
  3. Ratio Span's Center
    • ( i n i 1 ) 1 2 {\displaystyle (i_{n}i_{1})^{\tfrac {1}{2}}}
    • The center indicates the speed level of the transmission
    • Together with the final drive ratio
    • it gives the shaft speed level of the vehicle
  4. Average Gear Step
    • ( i n i 1 ) 1 n 1 {\displaystyle ({\tfrac {i_{n}}{i_{1}}})^{\tfrac {1}{n-1}}}
    • With decreasing step width
      • the gears connect better to each other
      • shifting comfort increases
  5. Sun 1: sun gear of gearset 1
  6. Ring 1: ring gear of gearset 1
  7. Sun 2: sun gear of gearset 2
  8. Ring 2: ring gear of gearset 2
  9. Sun 3: sun gear of gearset 3
  10. Ring 3: ring gear of gearset 3
  11. ^ Standard 50:50
    — 50 % Is Above And 50 % Is Below The Average Gear Step —
    • With steadily decreasing gear steps (yellow highlighted line Step)
    • and a particularly large step from 1st to 2nd gear
      • the lower half of the gear steps (between the small gears; rounded down, here the first 2) is always larger
      • and the upper half of the gear steps (between the large gears; rounded up, here the last 2) is always smaller
    • than the average gear step (cell highlighted yellow two rows above on the far right)
    • lower half: smaller gear steps are a waste of possible ratios (red bold)
    • upper half: larger gear steps are unsatisfactory (red bold)
  12. ^ Standard R:1
    — Reverse And 1st Gear Have The Same Ratio —
    • The ideal reverse gear has the same transmission ratio as 1st gear
      • no impairment when maneuvering
      • especially when towing a trailer
      • a torque converter can only partially compensate for this deficiency
    • Plus 11.11 % minus 10 % compared to 1st gear is good
    • Plus 25 % minus 20 % is acceptable (red)
    • Above this is unsatisfactory (bold)
  13. ^ Standard 1:2
    — Gear Step 1st To 2nd Gear As Small As Possible —
    • With continuously decreasing gear steps (yellow marked line Step)
    • the largest gear step is the one from 1st to 2nd gear, which
      • for a good speed connection and
      • a smooth gear shift
    • must be as small as possible
      • A gear ratio of up to 1.6667:1 (5:3) is good
      • Up to 1.7500:1 (7:4) is acceptable (red)
      • Above is unsatisfactory (bold)
  14. ^ From large to small gears (from right to left)
  15. ^ Standard STEP
    — From Large To Small Gears: Steady And Progressive Increase In Gear Steps —
    • Gear steps should
      • increase: Δ Step (first green highlighted line Δ Step) is always greater than 1
      • As progressive as possible: Δ Step is always greater than the previous step
    • Not progressively increasing is acceptable (red)
    • Not increasing is unsatisfactory (bold)
  16. ^ Standard SPEED
    — From Small To Large Gears: Steady Increase In Shaft Speed Difference —
    • Shaft speed differences should
      • increase: Δ Shaft Speed (second line marked in green Δ (Shaft) Speed) is always greater than the previous one
    • 1 difference smaller than the previous one is acceptable (red)
    • 2 consecutive ones are a waste of possible ratios (bold)
  17. Blocks S1
  18. Blocks C1 (the carrier of gearset 1)
  19. Blocks R3
  20. Connects S2 and S3 with the turbine
  21. Connects R1 with the turbine
  22. Connects C1 with the turbine
  23. To reflect the progress, the Lepelletier gear mechanism means both technically and in terms of manufacturing effort. The 6HP-transmission is the first one to use this intriguing gear mechanism

Applications

1990: 5HP 18 · 1997: 5HP 19 · Ravigneaux Planetary Gearset Types

5HP 18

  • Introduced in MY 1991 on the BMW E36 320i/325i and E34 5 Series.
  • Input torque maximum is 310 N⋅m (229 lb⋅ft)
  • Weight: ~75 kg (165 lb)
  • Oil capacity: ~10.5 L (11.1 US qt)

Applications

  • 1992–1993 BMW E32 — 730i M60B30
  • 1992–1995 BMW E34 — 525i M50B25TÜ
  • 1992–1995 BMW E34 — 530i M60B30
  • 1992–1995 BMW E34 — 525tds M51D25
  • 1995–2000 BMW E38 — 725tds M51D25
  • 1994–1996 BMW E38 — 730I M60B30
  • 1993–1996 BMW E36 — M3 S50B30US
  • 1995–1999 BMW E36 — 328i M52B28 - BMW Part No A5S 310Z
  • 1996–1998 BMW E38 — 728i/iL M52B28
  • 1997–1999 BMW E36 — M3 3.2 S52B32
  • 1995–1999 BMW E39 — 523i M52B25
  • 1995–1999 BMW E39 — 528i M52B28
  • 1995–1999 BMW E39 — 525tds M51D25
  • 1991–1999 BMW E36 — 320i

5HP 19

Applications

BMWlongitudinal engine, rear wheel drive

  • 2001–2003 BMW E46 — 330Ci M54B30
  • 2001–2003 BMW E46 — 330i M54B30
  • 2000–2003 BMW E46 — 320i M52TUB20/ M54B22
  • 2000– BMW E46 — 323Ci M52TUB25
  • 2000– BMW E46 — 323i M52TUB25
  • 2000– BMW E46 — 328i M52TUB28
  • 2000– BMW E38 — 728i M52TUB28
  • 2001–2003 BMW E46 — 325Ci M54B25
  • 2001–2003 BMW E46 — 325i M54B25
  • 1999–2002 BMW E39 — 520i M52TUB20
  • 1999–2002 BMW E39 — 523i M52TUB25
  • 1999–2002 BMW E39 — 528i M52TUB28
  • 2001–2003 BMW E39 — 525i M54B25
  • 2001–2003 BMW E39 — 530i M54B30
  • 2002–2005 BMW E85 — Z4 (M54 engine)

5HP 19FL

Applications

Volkswagen Grouplongitudinal engine transaxle, front-wheel drive

5HP 19FLA

Applications

Volkswagen Grouplongitudinal engine, transaxle permanent four-wheel drive

1999 (DRN/EKX) transmissions used Induction speed sensors and 2000+ (FAS) transmissions used Hall Effect sensors. These transmissions are mechanically the same, but are not interchangeable.

5HP 19HL

Applications

Porschelongitudinal engine rear engine transaxle

5HP 19HLA

Applications

Porschelongitudinal engine rear engine transaxle

Porschemid-engine design flat-six engine, 5-speed tiptronic #1060, rear-wheel drive A87.01-xxx, A87.02-xxx, A87.21-xxx,

  • 1997-2004 Porsche Boxster 986 2.5 6-cyl
  • 1997-2004 Porsche Boxster 986 2.7 6-cyl
  • 1997-2004 Porsche Boxster 986 3.2 6-cyl
  • 2005–2008 Porsche Boxster 987 2.7 6-cyl
  • 2005–2008 Porsche Boxster S 987 3.4 6-cyl
  • 2005–2008 Porsche Cayman 987 2.7 6-cyl
  • 2005–2008 Porsche Cayman S 987 3.4 6-cyl

1992: 5HP 30 · 1996: 5HP 24 · Simpson Planetary Gearset Types

5HP 30

Applications

5HP 24

Applications

5HP 24A

Applications

See also

References

  1. ^ "ZF North America Application Chart (automatic)" (PDF). ZF-Group.com. Archived from the original (PDF) on 12 September 2003.
  2. "ZF Parts Catalog" (PDF). zf.com. Archived from the original on 2012-09-06.{{cite web}}: CS1 maint: bot: original URL status unknown (link)
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