From Wikipedia, the free encyclopedia
Motor vehicle automatic transmission models
Motor vehicle
The 3HP is a 3-speed Automatic transmission family with a hydrodynamic Torque converter with hydraulic control for passenger cars from ZF Friedrichshafen AG . In selector level position "P", the output is locked mechanically. The Ravigneaux planetary gearset types were first introduced in 1963 and produced through the mid seventies. The Simpson planetary gearset types were launched in 1973 and produced through 1990. Both were used in different versions in a large number of cars.
Gear Ratios[ a]
Gear
Model
R
1
2
3
Total Span
Span Center
Avg. Step
Compo- nents
3HP 12 Small Engines
−2.000
2.560
1.520
1.000
2.560
1.600
1.600
2 Gearsets 3 Brakes 2 Clutches
3HP 12 Big Engines
−2.000
2.286
1.429
1.000
2.286
1.512
1.512
3HP 22 Big Engines
−2.086
2.479
1.479
1.000
2.479
1.575
1.575
2 Gearsets 3 Brakes 2 Clutches
3HP 22 Small Engines
−2.086
2.733
1.562
1.000
2.733
1.653
1.653
3HP 22 Porsche 944
−2.429
2.714
1.500
1.000
2.714
1.648
1.648
^ Differences in gear ratios have a measurable, direct impact on vehicle dynamics, performance, waste emissions as well as fuel mileage
1963: 3HP 12 · Ravigneaux Planetary Gearset Types[ edit ]
The 3HP 12 was produced through the mid-seventies and has been used in a variety of cars. There are versions for longitudinal and transverse engines.
Gear Ratios
With Assessment
Planetary Gearset: Teeth[ a] Ravigneaux
Count
Total[ b] Center[ c]
Avg.[ d]
Model Type
Version First Delivery
S1 [ e] R1 [ f]
S2 [ g] R2 [ h]
Brakes Clutches
Ratio Span
Gear Step[ i]
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}}}
Step[ i]
−
i
R
i
1
{\displaystyle -{\tfrac {i_{R}}{i_{1}}}}
[ j]
i
1
i
1
{\displaystyle {\tfrac {i_{1}}{i_{1}}}}
i
1
i
2
{\displaystyle {\tfrac {i_{1}}{i_{2}}}}
[ k]
i
2
i
3
{\displaystyle {\tfrac {i_{2}}{i_{3}}}}
Δ Step[ l] [ m]
i
1
i
2
:
i
2
i
3
{\displaystyle {\tfrac {i_{1}}{i_{2}}}:{\tfrac {i_{2}}{i_{3}}}}
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}}}}
Δ Shaft Speed[ n]
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}}}}
3HP 12
160 N⋅m (118 lb⋅ft ) 1963
2532
32 64
3 2
2.5600 1.6000
1.6000[ i]
Gear Ratio
−2.0000 [ j]
−
2
1
{\displaystyle -{\tfrac {2}{1}}}
2.5600
64
25
{\displaystyle {\tfrac {64}{25}}}
1.5200[ k]
38
25
{\displaystyle {\tfrac {38}{25}}}
1.0000
1
1
{\displaystyle {\tfrac {1}{1}}}
Step
0.7825 [ j]
1.0000
1.6842 [ k]
1.5200
Δ Step[ l]
1.1080
Speed
-1.2800
1.0000
1.6842
2.5600
Δ Speed
1.2800
1.0000
0.6842
0.8758
3HP 12
Big Engines 1963
2832
32 64
3 2
2.2857 1.5119
1.5119[ i]
Gear Ratio
−2.0000[ j]
−
2
1
{\displaystyle -{\tfrac {2}{1}}}
2.2857
16
7
{\displaystyle {\tfrac {16}{7}}}
1.4286
10
7
{\displaystyle {\tfrac {10}{7}}}
1.0000
1
1
{\displaystyle {\tfrac {1}{1}}}
Step
0.8750 [ j]
1.0000
1.6000
1.4286
Δ Step[ l]
1.1280
Speed
-1.1429
1.0000
1.6000
2.2857
Δ Speed
1.1429
1.0000
0.6000
0.6842
Ratio
−
R
2
S
2
{\displaystyle -{\tfrac {R_{2}}{S_{2}}}}
R
1
R
2
S
1
S
2
{\displaystyle {\tfrac {R_{1}R_{2}}{S_{1}S_{2}}}}
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})}}}
1
1
{\displaystyle {\tfrac {1}{1}}}
Algebra And Actuated Shift Elements
Brake A[ o]
❶
Brake B[ p]
❶
Brake C[ q]
❶
❶
Clutch D[ r]
❶
❶
❶
Clutch E[ s]
❶
❶
^ Layout
Input and output are on opposite sides
Planetary gearset 2 (the outer Ravigneaux gearset) is on the input (turbine) side
Input shafts is, if actuated S1 or S2
Output shaft is R2 (the ring gear of the outer Ravigneaux gearset
^ 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
^ 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
^ 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
^ Sun 1: sun gear of gearset 1: inner Ravigneaux gearset
^ Ring 1: ring gear of gearset 1: inner Ravigneaux gearset
^ Sun 2: sun gear of gearset 2: outer Ravigneaux gearset
^ Ring 2: ring gear of gearset 2: outer Ravigneaux gearset
^ a b c d 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 1) is always larger
and the upper half of the gear steps (between the large gears; rounded up, here the last 1) 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)
^ a b c d e 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)
^ a b c 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)
^ a b c From large to small gears (from right to left)
^ 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)
^ 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)
^ Blocks R1 (ring gear of the inner Ravigneaux gearset) and S2 (sun gear of the outer Ravigneaux gearset)
^ Support link with freewheel · blocks R1 (ring gear of the inner Ravigneaux gearset) and S2 (sun gear of the outer Ravigneaux gearset) in one direction
^ Blocks C1 and C2 (the common Ravigneaux carrier 1 + 2)
^ Couples S1 (sun gear of the inner Ravigneaux gearset) with the turbine
^ Couples S2 (sun gear of the outer Ravigneaux gearset) with the turbine
1973: 3HP 22 · Simpson Planetary Gearset Types[ edit ]
The all new 3HP 22 was introduced in 1973 and was produced through 1990 and has been used in a variety of cars from Alfa Romeo , BMW ,[ 1] Citroën , Peugeot , and Fiat .[ 2]
Specifications
Weight
45 kg (99 lb ) with converter
Control
mechanical · hydraulic
Gear Ratios
With Assessment
Planetary Gearset: Teeth[ a] Simpson
Count
Total[ b] Center[ c]
Avg.[ d]
Model Type
Version First Delivery
S1 [ e] R1 [ f]
S2 [ g] R2 [ h]
Brakes Clutches
Ratio Span
Gear Step[ i]
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}}}
Step[ i]
−
i
R
i
1
{\displaystyle -{\tfrac {i_{R}}{i_{1}}}}
[ j]
i
1
i
1
{\displaystyle {\tfrac {i_{1}}{i_{1}}}}
i
1
i
2
{\displaystyle {\tfrac {i_{1}}{i_{2}}}}
[ k]
i
2
i
3
{\displaystyle {\tfrac {i_{2}}{i_{3}}}}
Δ Step[ l] [ m]
i
1
i
2
:
i
2
i
3
{\displaystyle {\tfrac {i_{1}}{i_{2}}}:{\tfrac {i_{2}}{i_{3}}}}
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}}}}
Δ Shaft Speed[ n]
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}}}}
3HP 22
320 N⋅m (236 lb⋅ft ) 1963
35 73
35 73
3 2
2.4795 1.5746
1.5746[ i]
Gear Ratio
−2.0857[ j]
−
2
1
{\displaystyle -{\tfrac {2}{1}}}
2.4795
181
73
{\displaystyle {\tfrac {181}{73}}}
1.4795[ k]
108
73
{\displaystyle {\tfrac {108}{73}}}
1.0000
1
1
{\displaystyle {\tfrac {1}{1}}}
Step
0.8412 [ j]
1.0000
1.6759 [ k]
1.4795
Δ Step[ l]
1.1328
Speed
-1.1888
1.0000
1.6759
2.4795
Δ Speed
1.1888
1.0000
0.6759
0.8035
3HP 22
Small Engines 1973
35 73
41 73
3 2
2.7331 1.6532
1.6532[ i]
Gear Ratio
−2.0857 [ j]
−
73
35
{\displaystyle -{\tfrac {73}{35}}}
2.7331
6983
2555
{\displaystyle {\tfrac {6983}{2555}}}
1.5616 [ k]
114
73
{\displaystyle {\tfrac {114}{73}}}
1.0000
1
1
{\displaystyle {\tfrac {1}{1}}}
Step
0.7631 [ j]
1.0000
1.7501 [ k]
1.5616
Δ Step[ l]
1.1207
Speed
-1.3103
1.0000
1.7501
2.7331
Δ Speed
1.3103
1.0000
0.7501
0.9829
3HP 22
Porsche 944 1981
28 68
32 64
3 2
2.7143 1.6475
1.6475[ i]
Gear Ratio
−2.4286[ j]
−
17
7
{\displaystyle -{\tfrac {17}{7}}}
2.7143
19
7
{\displaystyle {\tfrac {19}{7}}}
1.5000 [ k]
3
2
{\displaystyle {\tfrac {3}{2}}}
1.0000
1
1
{\displaystyle {\tfrac {1}{1}}}
Step
0.8947 [ j]
1.0000
1.8095 [ k]
1.5000
Δ Step[ l]
1.2063
Speed
-1.1176
1.0000
1.8095
2.7143
Δ Speed
1.1176
1.0000
0.8095
0.9048
Ratio
−
R
1
S
1
{\displaystyle -{\tfrac {R_{1}}{S_{1}}}}
S
1
(
S
2
+
R
2
)
+
R
1
S
2
S
1
R
2
{\displaystyle {\tfrac {S_{1}(S_{2}+R_{2})+R_{1}S_{2}}{S_{1}R_{2}}}}
S
2
+
R
2
R
2
{\displaystyle {\tfrac {S_{2}+R_{2}}{R_{2}}}}
1
1
{\displaystyle {\tfrac {1}{1}}}
Algebra And Actuated Shift Elements
Brake A[ o]
❶
Brake B[ p]
❶
❶
Brake C[ q]
❶
❶
Clutch D[ r]
❶
❶
❶
Clutch E[ s]
❶
❶
^ Layout
Input and output are on opposite sides
Planetary gearset 1 is on the input (turbine) side
Input shafts is, if actuated, S1 or R2
Output shaft is R1
^ 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
^ 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
^ 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
^ Sun 1: sun gear of gearset 1: inner Ravigneaux gearset
^ Ring 1: ring gear of gearset 1: inner Ravigneaux gearset
^ Sun 2: sun gear of gearset 2: outer Ravigneaux gearset
^ Ring 2: ring gear of gearset 2: outer Ravigneaux gearset
^ a b c d e 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 1) is always larger
and the upper half of the gear steps (between the large gears; rounded up, here the last 1) 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)
^ a b c d e f g 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)
^ a b c d e f g 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)
^ a b c d From large to small gears (from right to left)
^ 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)
^ 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)
^ Blocks S1
^ Support link with freewheel · blocks S1 in one direction
^ Blocks C1 (the planetary gear carrier 1)
^ Couples S1 with the turbine
^ Couples R2 with the turbine