1973 OPEL GT-R clock

MANUAL TRANSMISSION70.31COUNTER SHAFT GEAR
THRUST WASHER\Figure 76.48 Installing Spacer Ring and Needle
Bearing Onto Mainshaft
fourth speed yoke should be positioned with rounded
notch at shaft hole portion of yoke toward rear. See
Figure 78. 47.
3. Install spiral pin, allowing
i/16” to 5/64” of pin
to protrude.
Installing First and Second Gear Shifter Shaft
1. Inspect shifter shaft carefully for burrs, and
remove with emery cloth. Burrs on shifter shaft will
prevent easy installation of shifter yoke and cam.
Lightly oil with transmission oil prior to installation.
Insert first and second gear shifter shaft through hole
in rear of case with three notches down and toward
rear of transmission, pushing shaft tirst through
firstand second gear shifter yoke, which should be posi-
tioned on first and second gear sliding gear with
shoulder toward front of case. To position first and
second gear shifter yoke on first and second gear
sliding gear, push reverse idler gear forward, engag-
ing the idler gear with the first and second gear
sliding gear. This will make room for positioningfirst and second gear shifter yoke. See Figure
7B-49.2. Continue to drive first and second gear shifter
shaft through shifter shaft cam, which should be
positioned as shown in Figure
7B-50.3. Install spiral pins to secure shifter yoke and shifter
shaft cam to first and second gear shifter shaft.
Installing Selector Shaft
1. Inspect selector shaft carefully for burrs, andFigure
78.49 Countergear Thrust Washers Installed
Figure
78-50 Position of “L” Shaped Selector Dog
remove with emery cloth. Burrs on shaft will prevent
easy installation of intermediate levers. Lightly oil
with transmission oil prior to installation. Insert new
selector shaft oil seals in holes on both sides of trans-
mission case and insert selector shaft into case and
through third, fourth, and reverse intermediate lever.
Third, fourth, and reverse intermediate lever should
be positioned on selector shaft, as shown in Figure
7B-51.2. Continue to push selector shaft through first and
second intermediate lever and through other side of
case. First and second intermediate lever should be
positioned on selector shaft, as shown in Figure 7B-
52. Selector shaft is rotated counterclockwise (when
looking from lever end of selector shaft) from work-
ing position to have spiral pin holes in shaft vertical
and in line with pin holes in intermediate levers. To
rotate selector shaft in this manner, the reverse gear
shifter shaft and its reverse speed shifter yoke must
be pushed rearward so that the reverse idler gear is
against rear of case.

Figure 7C-1 Quadrant In Park Position -Opel 1900
and Manta7C- 381973 OPEL SERVICE MANUAL
R
- Reverse enables the vehicle to be operated in a
reverse direction.
N
- Neutral position enables the engine to be
started and operated without driving the vehicle.
D
- Drive range is used for all normal driving
conditions and maximum economy and has three
gear ratios. Downshifts are available for passing
by depressing the accelerator partially at lower
car speeds and through the “detent” at higher car
speeds.
S or 2
- Second range adds new performance for
hilly terrain. It has the same starting ratio as Drive
range, but prevents the transmission from shifting
above second gear to retain second gear for
acceleration or engine braking as desired. Second
range can be selected at any vehicle speed, but
should not be used above the speed shown m the
Owner’s Manual. This is to prevent over-speeding
the engine. The transmission will shift to second
gear immediately and remain in second until the
vehicle speed or the throttle position is changed
to obtajn first gear operation in the same manner
as in Drive range.
L or 1
- Lo range can be selected at any vehicle speed,
but should not be used above the speed shown in the
Owner’s Manual. The transmission will shift to low
(1st) gear immediately and remain in 1st gear regard-
less of vehicle speed or throttle position. This is par-
ticularly beneficial for maintaining maximum engine
braking.
PRINCIPLES OF OPERATION
Torque ConverterThe torque converter acts as a coupling to transmit
engine torque, through oil, to the transmission power
train. It also multiplies the torque from the engine
under certain conditions of input and output speed.
Figure
7C-2 Quadrant in Park Position - GT Models
The quadrant has six positions indicated in the fol-
lowing order: (Opel 1900 and Manta) P,R,N,D,S,
and L (Figure
7C-1); and (GT) P,R,N,D,2, and 1
(Figure 7C- 2).The torque converter used in the Opel three speed
automatic transmission consists of three basic ele-
ments: the pump (driving member), the turbine
(driven or output member) and the stator (reaction
member). See Figure
7C-3. The converter cover is
welded to the pump to seal all three members in an
oil tilled housing.
P
- Park position enables the transmission output
shaft to be locked
- thus preventing the vehicle
from roling either forward or backward. Because
the output shaft is mechanically locked by a
parking
paw1 anchored in the extension housing,
the park position should not be selected until the
vehicle has come to a stop. The engine may be
started in the Park position.Whenever the engine is running, the converter pump
turns at engine speed and acts as a centrifugal pump,
picking up oil at its center, adding energy, and dis-
charging the oil at its outer rim between the blades.
The shape of the converter pump shells and blades
cause the oil to leave the pump spinning in a clock-
wise direction toward the blades of the turbine. Asthere is no mechanical connection between converterpump and turbine, the oil is the only driving force
and strikes the blades of the turbine, transferring the

AUTOMATIC TRANSMISSION7c- 39
TURBINESTATOR
(DRIVEN MEMBER)fREACTION
MEMBER)CON;ERTER
COVERP;MP
(DRIVING MEMBER)
7c.3Figure
7C-3 Torque Converter Assembly
energy of the oil to the turbine. See Figure
7C-1. The
driven member, or turbine is splined to the transmis-
sion input shaft to transmit turbine torque to the
transmission gear train.
When the engine is idling, the converter pump is
being driven slowly. The energy of the oil leaving the
pump is very low, therefore there is very little torque
imparted to the turbine. For this reason, the engine
can idle and the car will have little or no tendancy
to “Creep.”
As the throttle is opened and pump speed increases,
the force of the oil leaving the pump increases and
the resultant torque is absorbed by the turbine.
After the oil has imparted its force to the turbine
member, oil leaving the turbine follows the contour
of the turbine blades so that it leaves the turbine
spinning counterclockwise. Since the turbine mem-
ber has absorbed the energy required to reverse the
direction of the oil, the turbine now has greater forceor torque than is being delivered by the engine, and
the process of torque multiplication has begun.TURBINE
PUMPTURBINE
PUMP7c4Figure
7C-4 Oil Flow Without Stator
If the counterclockwise spinning oil were allowed to
return directly to the converter pump, the oil would
strike the inner section of the pump blades in a direc-
tion that would hinder its rotation, cancelling out
any gains in torque that have been obtained. To pre-
vent this, a stator assembly is added, and is located
between the converter pump and turbine. See Figure7c-5.
The stator redirects the oil returning to the pump
member of the converter and changes its direction of
rotation to that of the pump. Since the direction of
the oil leaving the stator is not opposing the rotationof the pump, the energy or torque of the engine is
added to the oil as it passes through the
the entire cycle repeats. See Figure
7C-6.pump and
The force of the returning oil from the turbine tends
to rotate the stator in a counterclockwise direction,
the stator is mounted on a one-way or roller clutch
which allows it to turn clockwise but not counter-
clockwise. Therefore, at low turbine speeds, the re-
turning oil from the turbine striking the stator blades
in a counterclockwise direction causes the roller
clutch to “lockup,” and prevent the stator from turn-
ing.
As the turbine speed increases, the direction of the
oil leaving the turbine changes and flows against thestator blades in a clockwise direction. Since the sta-tar would now be hindering the smooth flow of re-
turning oil to the pump, the roller clutch releases,
and the stator rotates freely on its shaft. With this
condition, the stator becomes ineffective and no fur-
ther multiplication of engine torque is produced
within the converter. At this point the converter acts

7C- 401973 OPEL SERVICE MANUAL
ENERGIZING SPRINGS
UTER RACE (CAM)
ROLLER CLUTCHSTATOR
LOCKS UPSTATOR
COUNTER CLOCKWISE FORCES ON CAM, LOCKOVERRUNS
ROLLERS TO INNER RACE
CLOCKWISE FORCES ON CAM CAUSESTATOR ASSEMBLYx.5
ROLLERS TO OVERRUN INNER RACE
Figure 7C-5 Roller Clutch And Stator Assembly
as a fluid coupling, since both the converter pump
and turbine are turning at the same speed, or at a 1:l
ratio.
The torque converter and input shaft actually form
a simple transmission in themselves, however, since
the requirements of an automobile transmission are
greater, some means of providing additional torque,
neutral and reverse, are required. For this reason a
gear set is added behind the torque converter.
Planetary Gears
Planetary gears are used in automatic transmissions
as the basic means of multiplying the twisting force
or torque from the engine. They are so named be-
cause of their physical arrangement and are used
because they permit constant mesh operation, cannot
clash, operate in a minimum of space and distribute
the load over several gears. The simplest planetary
gear set consists of a center or sun gear, internal or
ring gear and a planetary gears called planetary pin-
ions. See Figure
7C-9. The sun gear meshes with theplanetary pinions which rotate freely on their shafts
attached to the planetary carrier. The ring gear
sur-rounds the assembly and meshes with the planetary
pinions. Power flow through the planetary gear set
is accomplished by applying power to one member,
holding another member thus making it a reaction
member and obtaining the transmitted power from
the third member, which can result in any of the
following conditions:
1. Increase torque with a proportional decrease in
output speed.
2. Increase speed with a proportional decrease of
output torque.
3. Reverse direction of rotation.
4. Act as a direct connection for direct drive.
The gear set used in the Opel Three Speed Automatic
transmission is known as a Ravigneaux planetary

AUTOMATIC TRANSMISSION7c- 41
Figure
7C-6 Oil Flow With Stator Active
gear set and utilizes two sets of planetary pinions in
one planet carrier, two sun gears and one ring gear.
See Figure
7C-8.The short planetary pinions are in constant mesh
with both the input (front) sun gear and the long
planetary pinions. The long planetary pinions are inconstr$ mesh with the reaction (rear) sun gear, the
short planetary pinions and the ring gear.
In the first gear the reaction (rear) sun gear is held
stationary. The input (front) sun gear rotates in aclockwise direction (when viewed from the front)
turning the short planet pinions counterclockwise
and the long planet pinions clockwise. The long pla-
net pinions turn the ring gear clockwise and walk
around the held reaction (rear) sun gear driving the
planet carrier and output shaft assembly in a clock-
wise direction. See Figure
7C-10.In second gear the reaction (rear) sun gear is again
held statioinry. The ring gear is the input and is
driven in a clockwise direction turning the long pla-
net pinions clockwise which walk around the station-
ary reaction (rear) sun gear, driving the planet

7C. 421973 OPEL SERVICE MANUALPLANETARY CARRIER7c.toFigure
712-10 First Gear
Figure
7C-7 Planetary Gears
LONG PINION
HORT PINION
PLANETARY CARRIER7C8Figure
7C-8 Ravigneaux Planetary Gearscariier assembly and output shaft in a clockwise di-
rection. See Figure
7C-11.In the third gear, the ring gear is driven in a clock-
wise direction and the input (front) sun gear is also
driven in the same direction. The long and short
planetary pinions cannot rotate on their shafts in this
situation, thus causing the planetary carrier, output
shaft and gears to rotate clockwise as a solid unit to
provide direct
drive See Figure 76x12,LONG PINIONPLANiTARY CARRIER
X.11Figure
7C-1 1 Second GearIn reverse, the ring gear is held and the input (front)
sun gear is driven in a clockwise direction. This
causes the short planet pinions to turn counterclock-
wise, turning the long planetary pinions clockwise.
The pinions then walk around the inside of the sta-
tionary ring gear, driving the planet carrier assembly
and output shaft in a counterclockwise direction. See
Figure
7C-13.In order to provide the necessary input and reaction
fuhftions to produce the i&iiOus iarlgesg the @al

AUTOMATIC TRANSMISSION7c- 59
b. DRIVE RANGE . FIRST GEAROrive Range . First Gear
Reverse Clutch Released
Second Clutch. Released
Sprag Locked
In Drive Range. First Gear, the low band is applied and all clutches are released.
Figure 7C-49 Drive Range First GearThird Clutch. Released
Low Band. Applied
The low band holds the reaction sun gear and drum stationary, which serves as the reaction member of the planet-
ary gear set in first gear. The input shaft drives the third clutch drum in a clockwise direction, which turns the
sprag race and retainer assembly clockwise. The sprags wedge and drive the input
sun gear.
The power is then transmitted through the gear set to the output shaft as outlined in “Principles of Operation”.
The ratio in first gear is 2.4O:l.
Low RangeIn Low Range, the third clutch is applied together with the low band. The input power flow is exactly the
Same as
drive range first gear except that the third clutch is engaged and prevents the sprag from overrunning, thus pro-
viding engine braking when coasting in Low Range.
7c49

7C- 601973 OPEL SERVICE MANUAL
c. DRIVE RANGE. SECONO GEAROrive Range . Second Gear
Reverse Clutch - Released
Second Clutch -Applied
Sprag
- Overrunning
In Drive Range. Second Gear, the low band and second clutch are applied.Third Clutch
- Released
Low Band -Applied
The input shaft drives the third clutch drum and the second clutch composition plates. When the second clutch
piston is applied, the rotating second clutch composition plates are locked
w the second clutch steel plates. Since
the second clutch drum is now rotating in a clockwise direction, the ring gear is driven clockwise. As described in
“Principles of Operation”, the carrier is driven in a clockwise direction. The long planet pinions also drive the
short planet pinions, which drive the input sun gear clockwise, causing the sprag assembly to overrun. The ratio
is 1.48:1.
second Range
In Second Range, the Power flow is exactly the seme as drive range - second gear.7c50
Figure
7C-50 Drive Range - Second Gear