1953 JEEP DJ oil pressure
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'Jeep'
UNIVERSAL
SERIES
SERVICE
MANUAL
C
FIG.
C-22—-CHECKING
FUEL
PUMP
PRESSURE
—
DAUNTLESS
V-6
ENGINE a
couple of strokes to be sure the pump is primed.
Using
a half-pint
bottle
or similar measure, pump
Vi
pint [0,24 It] of fuel by cranking the
engine
with
the starter motor. Count the strokes neces
sary
to
fill
the measure. If more than 20 strokes
are
required, the fuel pump is inefficient, the tank
line is leaking air, or the fuel supply is restricted.
Check
fuel filter in the fuel tank if line is restricted.
C-24.
Check Manifold Vacuum
To
check the intake manifold vacuum on the
Hurri
cane F4 engine, remove the ventilation valve and
L
fitting from the manifold and install special adapter. On the Dauntless V-6
engine
remove the
pipe plug located in the right
rear
of the intake
FIG.
C-23—CHECKING MANIFOLD VACUUM
—
HURRICANE
F4
ENGINE
manifold and install special adapter. Connect the
vacuum
gauge
tube to the special adapter as shown
in
Fig. C-23 for the
Hurricane
F4 engine.
Start
the engine. Connect a Tachometer
Tool,
C-3896,
from the distributor
primary
terminal to ground and set the
engine
speed at the specified
rpm.
given in Par. C-30. Observe the vacuum
read
ing and interpret as follows:
a.
A steady reading from 18" to 20" [457 a 508
mm.] of mercury is a normal reading, indicating
that valve and
spark
timing, valve seating, and
piston ring sealing are all satisfactory.
b. A steady but below normal reading indicates
a
condition common to all cylinders such as a
leak
at the carburetor gasket, late ignition or valve
timing, or uniform piston ring and bore wear.
c.
A slowly fluctuating or drifting reading in dicates that the carburetor idle mixture is incorrect
Look
for the cause in the fuel system.
d.
A rhythmic pulsating reading is caused by a
condition affecting one or more cylinders, but not
all,
and indicates leaky valve, gasket blowby, re
stricted intake port, or an electrical miss.
e. An intermittent pulsating reading is caused by
an
occasional malfunction, such as a sticking valve
(all
valves may be
erratic
in operation if the valve
springs are weak), electrical miss caused by insuffi
cient distributor point tension or low coil
voltage
coupled with inconsistent
spark
plug
gaps
or fouled
plugs, or
dirt
in the fuel system finding its way into
passages of
critical
size or valve
seats
in the
car
buretor.
f.
A normal reading that quickly falls off (with
engine
running at
2000
rpm.) indicates exhaust
back
pressure caused by a restriction in the exhaust
system.
g.
Make indicated corrections to bring vacuum to 18" to 20" [457 a 508 mm.] of mercury normal
reading.
C-25.
Carburetor Adjustments
•
Refer to Fig. C-24, C-25 and C-26.
Carburetor
adjustments should not be attempted
until
it is known that
engine
ignition and com
pression are in
good
order. Any attempt to adjust
or
alter the carburetor to compensate for faulty conditions elsewhere
will
result in reduced econ
omy and overall performance.
Caution:
If an
engine
is idling too slow or rough,
this may be caused by a
clogged
ventilator valve
or
hose;
therefore, never adjust the carburetor idle
without first checking the crankcase ventilator
check valve and
hose.
The
air cleaner must be left in place while making
idle speed and mixture adjustments. All lights and accessories, must be turned off. The positive
crank
case ventilator system should also be in
good
oper
ating condition when making carburetor adjust ments.
Either
of
these
items noticeably affects the
air
fuel ratio at idle.
•
Hurricane
F4 Engine.
Note:
The idle mixture adjustment procedure for
the late model
YF-4941S
and
YF-6115S
Carter
31
Page 34 of 376
TUNE-UP
C-29.
SERVICE
DIAGNOSIS
POOR
FUEL ECONOMY Ignition Timing Slow or Spark Advance Stuck
Carburetor
Float High
Accelerator Pump Not Properly Adjusted High Fuel Pump Pressure
Fuel
Leakage
Leaky
Fuel Pump Diaphragm Loose Engine Mounting Causing High Fuel Level in Carburetor
Low
Compression
Valves Sticking
Spark
Plugs Bad
Spark
Plug Cables Bad
Weak
Coil
or Condenser Improper Valve Tappet Clearance
Carburetor
Air Cleaner Dirty
High Oil Level in Air Cleaner Dragging Brakes
Front
Wheels Out of Alignment
Tires
Improperly Inflated Inaccurate Odometer
Faulty
Fuel Tank Cap
Clogged
Muffler or Bent Exhaust Pipe Sticking Exhaust Manifold Valve
LACK
OF POWER
Low
Compression Ignition System (Timing Late)
Improper Functioning Carburetor
or Fuel Pump
Fuel
Lines
Clogged
Air
Cleaner Restricted Engine Temperature High Improper Tappet Clearance
Sticking Valves
Valve Timing Late
Leaky
Gaskets
Muffler
Clogged
Bent Exhaust Pipe Sticking Exhaust Manifold Valve —
Dauntless V-6 Engine
LOW
COMPRESSION
Leaky
Valves Poor Piston Ring Seal Sticking Valves
Valve Spring Weak or Broken
Cylinder
Scored or Worn
Tappet Clearance Incorrect Piston Clearance too Large
Leaky
Cylinder Head Gasket
BURNED
VALVES AND SEATS Sticking Valves or too Loose in Guides
Improper Timing
Excessive Carbon Around Valve Head and Seat Overheating
Valve Spring Weak or Broken
Valve Tappet Sticking
Valve Tappet Clearance Incorrect
Clogged
Exhaust System
Defective
Valve
Lifter
— Hydraulic
VALVES
STICKING
Warped Valve Improper Tappet Clearance Carbonized or Scored Valve
Stems
Insufficient Clearance Valve Stem to Guide
Weak or Broken Valve Spring Valve Spring Cocked Contaminated Oil
OVERHEATING
Inoperative Cooling System
Theromstat Inoperative Improper Ignition Timing
Improper Valve Timing
Excessive Carbon Accumulation
Fan
Belt too Loose
Clogged
Muffler or Bent Exhaust Pipe
Oil
System Failure Scored or Leaky Piston Rings
Sticking Exhaust Manifold Valve — Dauntless V-6 Engine
POPPING-SPITTING-DETONATION
Improper Ignition Improper Carburetion
Excessive Carbon
Deposit
in
Combustion Chambers
Poor Valve Seating Sticking Valves
Broken Valve Spring Tappets Adjusted too Close
Spark
Plug Electrodes Burned
Water or Dirt in Fuel
Clogged
Lines Improper Valve Timing
Clogged
Fuel Filter Sticking Exhaust Manifold Valve —
Dauntless V-6 Engine
EXCESSIVE
OIL CONSUMPTION Piston Rings Stuck in Grooves, Worn or Broken Piston Rings Improperly Fitted or Weak Piston Ring Oil Return
Holes
Clogged
Excessive Clearance, Main and
Connecting Rod Bearings
Oil
Leaks at Gaskets or Oil Seals
Excessive Clearance, Valve Stem
to Valve Guide (Intake)
Cylinder
Bores Scored, Out-of-
Round or Tapered
Too Much Clearance, Piston to Cylinder Bore
Misaligned Connecting Rods
High Road
Speeds
or Temperature
Crankcase
Ventilator Not Operating
BEARING
FAILURE
Crankshaft
Bearing Journal Out-of-Round
Crankshaft
Bearing Journal Rough
Lack
of Oil
Oil
Leakage
Dirty
Oil
Low
Oil Pressure or Oil Pump Failure
Drilled
Passages
in Crankcase or Crankshaft
Clogged
Oil
Screen Dirty
Connecting Rod Bent 34
Page 38 of 376
HURRICANE
F4
ENGINE
D-1.
GENERAL
This
section describes service and repair of the
F4
engine. The
engine
code
number shown in Fig.
A-3
is provided to identify the four cylinder engine.
The
meaning of the coded letters and numbers that
are
stamped on the water pump boss, at the front of the cylinder block, is given below.
Letter
to
Designate
Market
M
—
Military
E
—
Export
D
— Domestic
I
—
Industrial
&
Marine
Letter
to
Designate
Engine
Letter
to
Designate
Year
Built
R
— 1969
S
— 1970
T
— 1971
U—
1972
V
— 1973
W
— 1974
Numbers
to Designate
Compression
Ratio
F
— F4-134
Engine
63
67
•
71
-
6.3 to 1
•
6.7 to 1
-
7.1 to 1
Market
-
D
S F
(Domestic)
(1970)
Engine-
EXAMPLE
123 A B S
(F4-134)
Day- "L
Compression
Ratio
(6.7)
-
Service Engine (S)
Short
Block
(R)
-.010*
Oversize Pistons
(123rd)
-.010*
Undersize
Main
and
Rod Bearings
All
disassembly and assembly procedures are
presented in logical order, assuming a complete
engine
overhaul with
engine
removed from the vehicle. However, many of
these
procedures can
also be performed as on-vehicle services if vehicle
or
engine
components are removed to gain access
to parts involved.
Note:
Some
engines
are equipped with an exhaust
emission control system. Service information on
the components of this system is given in Section
F-l.
D-2.
Description
The
Hurricane
F4-134
engine
is an F-head, four-
cyiinder
engine
of combination valve-in-head and valve-in-block construction.
Large
intake valves
mounted in the head allow
rapid,
unobstructed
flow of fuel and air to the combustion chambers through short, water-jacketed intake passages.The
intake valves are operated by push rods through
rocker
arms. The exhaust valves are mounted
in
the block with through water jacketing to provide
effective
cooling. The exhaust valves are
operated by conventional valve tappets.
The
engine
is pressure lubricated. An oil pump
driven
from the camshaft forces the lubricant
through oil channels and drilled passages in the
crankshaft
to efficiently lubricate the main and
connecting rod bearings.
Lubricant
is also force
fed to the camshaft bearings, rocker arms, timing
gears, etc.
Cylinder
walls and piston pins are
lubricated
from spurt
holes
in the "follow" side of
the connecting rods.
Circulation
of the coolant is controlled by a
thermostat in the water
outlet
elbow cast as part
of the cylinder head.
The
cylinder head assembly when installed on the
engine
consists of the inlet valve guides, inlet valves, inlet valve springs, rocker arm and shaft assemblies, spark plugs, temperature indicator
fitting, water
outlet
fitting, and other assembled
parts.
The carburetor and air cleaner assembly
bolt to the top of the cylinder head. The rocker
arm
cover is attached to the top of the head to
enclose
the inlet valve mechanism.
The
engine
is equipped with a fully counterbalanced
crankshaft
supported by three main bearings. To better control balance, the counterweights are in
dependently forged and permanently attached to
the crankshaft with dowels and cap screws that are tack-welded.
Crankshaft
end play is adjusted by
shims placed
between
the crankshaft thrust washer
and
the shoulder on the crankshaft.
The
exhaust manifold is a separate unit. The intake
manifold is cast as an integral part of the cylinder
head and is completely water jacketed.
This
con
struction transfers heat from the cooling system
to the intake passages and assists in vaporizing
the fuel when the
engine
is cold. Therefore, there
is no heat control valve required in the exhaust manifold. Individual exhaust ports in the cylinder
block direct
gasses
into the exhaust manifold for unobstructed flow through the exhaust system.
The
pistons have an extra
groove
directly above
the top ring which acts as a heat dam or insulator.
As
is common practice with manufacturers,
some
engines
are built with oversize cylinder bores or undersize crankshaft journals. These
engines
are
considered standard as replacement parts of the
correct
sizes are supplied. Before ordering parts or
doing any work with a particular engine, it is important to check the
engine
code
number to
determine if oversize or undersize parts are re
quired.
Definite identification is given by a letter
stamped after the
engine
code
number. See Fig.
A-5
for location. The letters used and their mean ings are given here:
A
— .010*
[0,254
mm.] undersize main and
connecting rod bearings.
B
— .010"
[0,254
mm.] oversize pistons.
AB
—
Combination
of A and B.
S
—
Service
engine.
R
—
Short
Block.
Detailed specifications for the
Hurricane
F4
engine
are
at the end of this section.
Torque
specifications
for
engine
service are at the end of this manual in Section U. When adjustments are necessary, refer to
these
specifications so that factory clearances
are
maintained.
D-3.
Engine Mountings
The
front of the
engine
is supported by two rubber
Text continued on
page
41. 38
Page 41 of 376
'Jeep*
UNIVERSAL SERIES
SERVICE
MANUAL
D
insulator
mountings attached to the frame side
rail
brackets. The
rear
of the engine-transmission
assembly is supported by a rubber insulator
mounting under the
rear
of the transmission on
the frame center cross member.
This
cross member
is bolted to the frame side
rails
so that it can be
dropped when removing the transmission or engine-
transmission
assembly. The rubber insulators allow
free side and vertical oscillation to effectively
neutralize
engine
vibration at the source.
The
rubber
insulator mountings should be inspected
for separation and deterioration by jacking the
power plant away from the frame, near the sup
ports. Vibration cannot be effectively absorbed by
separated or worn insulators. They should be re placed if faulty.
D-4.
Engine
Ground
Strap
To
be sure of an
effective
ground for the electrical
circuits,
a ground strap bridges the right front
engine
support to the chassis. The connections of this strap must be kept clean and tight for proper
operation of the electrical system.
D-5. ENGINE REMOVAL
Should
the
engine
require overhauling, it is neces
sary
to remove it from the vehicle. The following procedure covers removal of the
engine
only.
The
engine, transmission and transfer case may be
removed as a unit by removing (in addition to the following procedure) the radiator guard and the
access plates in the floor pan.
a.
Drain
the cooling system by opening the
drain
cocks at the
bottom
of the radiator and lower right
side of the cylinder block.
b.
Disconnect the battery at the positive terminal
to avoid the possibility of short
circuit.
c. Remove the air cleaner horn from the carburetor
and
disconnect the breather
hose
at the oil filler
pipe.
d.
Disconnect the carburetor choke and throttle controls by loosening the clamp
bolts
and set
screws.
e. Disconnect the fuel-tank-to-fuel-pump line at the fuel pump by unscrewing the connecting nut.
f- Plug the fuel line to prevent fuel leakage.
g. Remove the radiator and radiator grille support
rods.
h. Remove the upper and lower radiator
hoses
by
loosening the
hose
clamps and slipping the clamps
back
on the
hose.
If so equipped, remove the heater
hoses
(one to the water pump, one to the
rear
of
the cylinder head) in the same manner.
i.
Remove the four
bolts
from the fan hub and re
move
the fan hub and fan blades.
j.
Remove the four radiator attaching screws. Re
move
the radiator and shroud as one unit, k. Remove the starting motor cables. Remove the
starting
motor.
I.
Disconnect the wires from the alternator or
generator. Disconnect the ignition
primary
wire
at the ignition coil.
NOTE:
ON
ENGINES EQUIPPED WITH EX
HAUST
EMISSION CONTROL, REMOVE THE
AIR
PUMP,
AIR
DISTRIBUTION
MANI
FOLD,
AND
ANTI-BACKFIRE (DIVERTER)
VALVE.
SEE SECTION
Fl
FOR PROCEDURE.
m.
Disconnect the oil pressure and temperature
sending unit wires at the units.
n.
Disconnect the exhaust pipe at the exhaust
manifold by removing the stud nuts.
o.
Disconnect the
spark
plug cables at the plugs
and
remove the cable bracket from the rocker arm cover stud.
p.
Remove the rocker arm cover by removing the
attaching stud nuts.
q.
Attach a lifting bracket to the
engine
using
existing head bolt locations. Be sure the
bolts
selected
will
hold the
engine
with the weight
balanced.
Attach lifting bracket to a boom hoist,
or
other lifting device, and take up all slack,
r.
Remove the two nuts and
bolts
from each front
engine
support. Disconnect the
engine
ground strap.
Remove the
engine
supports.
Lower
the
engine
slightly to permit access to the two top
bolts
on
the flywheel housing.
s. Remove the
bolts
which attach the flywheel
housing to the engine.
t.
Pull
the
engine
forward, or
roll
the vehicle back
wards,
until the clutch clears the flywheel housing.
Lift
the
engine
from the vehicle.
D-6. ENGINE DISASSEMBLY
Engine
disassembly is presented in the sequence to be followed when the
engine
is to be completely
overhauled after removal from the vehicle. Some
of the operations of the procedure are also ap
plicable
separately with the
engine
in the vehicle,
provided
that wherever necessary the part of the
engine
to be worked on is first made accessible by
removal
of
engine
accessories or other parts.
When
the disassembly operations are performed
with
the
engine
out of the vehicle, it is assumed,
in
this procedure, that all of the accessories have been removed
prior
to starting the disassembly
and
the oil has been drained.
In
addition to the instructions covering operations
for disassembling the
engine
out of the vehicle,
special
instructions are given to cover different
operations required when disassembly is
done
with the
engine
installed.
During
disassembly operations, the
engine
should
be mounted in a suitable
engine
repair
stand. Where
practicable,
modify or adapt an existing repair
stand
as necessary to accommodate the engine. If
an
engine
repair stand is not used, take care to
perform
disassembly operations in a manner that
will
protect personnel against an accident and the
engine
and its parts against damage.
NOTE:
If the
engine
is being disassembled because
of possible valve failure, check the valve tappet
clearance
before disassembly. Improper valve
clearance
could be the possible cause of valve
failure,
indicating a need for more frequent valve
checks and adjustments. 41
Page 44 of 376
D
HURRICANE
F4
ENGINE
Note:
Check
the condition of the rubber O-rings.
Defective O-rings could be the major cause of oil
leakage into cylinders. Always discard and replace
all
O-rings removed as only new O-rings should be installed at reassembly.
D-18.
Ream
Cylinder
Bore Ridges
To
prevent breaking the piston lands, the ridge
at the top of each cylinder bore must be removed
first.
To remove this ridge, use a cylinder ridge
reamer,
as shown in Fig. D-3 following the instruc
tions furnished by the reamer manufacturer. Use
care
not to cut below the top of the upper ring
travel
in the bore. Keep each piston top covered
with
an oil-soaked cloth to prevent cuttings from
falling
into the cylinder.
Note:
This
operation should be performed at this
time before the
engine
is rotated for the sequence
steps
following.
D-19.
Remove Oil Pan
Rotate the
engine
to the upside down position.
Remove the screws and lockwashers that attach
the oil pan to the cylinder block. Remove the oil
pan
and gasket.
Discard
the gasket.
D-20.
Remove Piston and Connecting
Rod
Assemblies
Remove the stamped locking nuts from the lower
end of each connecting rod bearing bolt. Remove
the connecting rod nuts. Remove the bearing cap evenly. Push the connecting rod and piston as
sembly out of the cylinder block with the handle end of a hammer until the piston rings are free from
the cylinder bore. Remove the piston and connecting rod assembly
from
the top of the cylinder block. Reassemble the
connecting rod bearing cap with the bearings in
place in the rod from which it was removed. Rotate
the crankshaft and follow the same procedure until
all
the piston and connecting rod assemblies are
removed.
Pistons and connecting rod assemblies may be removed for repair with the
engine
in the vehicle after draining the cooling system, removing the
oil
pan and the cylinder head, and reaming the ridges as previously described.
D-21.
Remove
Timing
Gear
Cover
Remove the bolts, nuts, and lockwashers, that at
tach
the timing gear cover to the engine. Remove
the cover, timing pointer, and cover gasket.
Dis
card
the gasket. Remove the crankshaft oil seal
from
the timing gear cover and discard the seal. Remove the oil slinger and spacer from the
crank
shaft.
D-22.
Remove
Timing
Gears
Use puller W-172 for pulling both the crankshaft
and
the camshaft gears.
With
the threaded cap-
screws supplied, adapt the puller to the crankshaft
FIG.
D-5—PULLING TIMING GEARS
1—
Puller
W-172 2—
Camshaft
Gear
gear and
pull
the gear.
With
the special hook-type
puller
bolts
that fit behind the camshaft gear
flange,
pull
the camshaft gear. Remove the Wood
ruff
Keys.
D-23.
Remove
Front
End Plate
Remove the screws and lockwashers that attach the
front end plate to the cylinder block. Remove the
front end plate and gasket.
Discard
the gasket.
D-24. Remove
Clutch
Remove four
bolts
and lockwashers diagonally
opposite
that attach the clutch assembly to the
flywheel, leaving two
opposed
bolts
to be
loosened
alternately until the clutch spring pressure is re
lieved.
Then,
support the clutch assembly with
one hand while removing the two remaining bolts.
For
information on disassembly, inspection, repair
and
assembly of the clutch refer to Section I. In
structions for removing the clutch when the
engine
is in the vehicle are also given in Section I.
D-25.
Remove Flywheel
The
flywheel is attached to the crankshaft with two tapered dowel
bolts
and four special bolts.
Remove
these
attaching parts. Use a pry bar be tween the flywheel and the back of the
engine
and
carefully
loosen
the flywheel from the crankshaft.
If
the flywheel is to be removed with the
engine
in
the vehicle, the transmission and clutch must
first be removed as detailed in Section I.
D-26.
Remove
Crankshaft
Slide
the crankshaft thrust washer and all end-play
adjusting
shims off the front end of the crankshaft.
Pull
the two pieces of
rear
main bearing cap packing out of position
between
the side of the bearing cap
and
the cylinder block.
Note
the marks on the bearing caps and cylinder
block for bearing number and position. 44
Page 45 of 376
'Jeep'
UNIVERSAL SERIES SERVICE
MANUAL
D
Remove the screws and lockwashers that attach
the main bearing caps to the cylinder block. Use
a
lifting bar beneath the ends of each bearing cap.
Be
careful not to exert too much pressure to cause
damage to the cap or
dowels
and pry the caps free.
CAUTION:
If main bearing caps are not removed
carefully
by raising both sides of each cap evenly
until
free of the dowels, the
dowels
may be bent.
A
bent main bearing cap dowel can cause misalign ment of the cap and resultant
rapid
bearing wear
necessitating replacement. Therefore, remove each
main
bearing cap carefully. If there is reason to
believe any of the
dowels
have been bent during
the bearing cap removal, remove them and install
new
dowels
as detailed in Par. D-34c.
Remove the upper
half
of the
rear
main bearing
oil
seal from the cylinder block and the lower
half
from
the oil seal
groove
in the
rear
main bearing
cap.
Install
the main bearing caps and bearings on
the cylinder block in their original positions.
Note;
Removal of the crankshaft may be ac
complished only with the
engine
out of the vehicle.
D-27.
Remove
Exhaust
Valves and Springs
Access to the valve chamber is obtained by re moving the attaching parts and the valve spring
cover and gasket from the cylinder block. Use cloths
to block off the three
holes
in the exhaust valve
chamber to prevent the valve retaining locks falling
into the crankcase, should they be accidentally dropped.
With
a valve
/
spring compressor, compress the valve springs on
those
valves which are in the
closed position (valve seated against cylinder
block).
Remove the exhaust valve spring retainer
locks,
the exhaust valve spring retainer, and the exhaust valve spring. Close the other valves by
rotating the camshaft and repeat the above opera
tion for the other valves in the same manner.
Lift
out all the exhaust valves and tag or place them in
a
rack
to indicate the location where each was removed from the cylinder block. If a valve sticks in
the guide and cannot be easily lifted out,
pull
the valve upward as far as possible and remove the
spring.
Lower
the valve and remove any carbon
deposits
from the valve stem.
This
will
permit re moval of the valve.
For
intake valve and spring removal, see
Par.
D-l7.
D-28.
Remove Camshaft
a.
Push the intake and exhaust valve tappets into the cylinder block as far as possible so the ends of
the tappets are not in contact with the camshaft. b. Secure each tappet in the raised position by in
stalling a common clip-type clothes pin on the
shank
of each tappet or tie them up in the valve
chamber.
c. Remove the camshaft thrust plate attaching
screws.
Remove the camshaft thrust plate and
spacer.
d.
Pull
the camshaft forward out of the cylinder
block using care to prevent damage to the cam
shaft bearing surfaces.
D-29.
Remove Valve Tappets
Remove the intake and exhaust valve tappets from
the
bottom
or crankshaft side of the cylinder block
after the camshaft has been removed. Tag each
tappet or place them in a marked
rack
so they may be reassembled in their original positions.
D-30.
Remove Oil
Gallery
Plugs
Remove the plug at each end of the oil gallery in the cylinder block.
This
operation is only applicable
when the
engine
is out of the vehicle and
will
allow access to the oil gallery so it may be cleaned.
D-31. ENGINE INSPECTION
AND
REPAIR
The
inspection and repair procedures detailed here
in
are recommended to be followed when a com
plete
engine
overhaul is to be made with the
engine
out of the vehicle. These instructions can generally be applied individually with the
engine
in the
vehicle. Wherever the procedure differs due to
the
engine
being in the vehicle, the necessary
special
instructions are provided. Inspection and
repair
instructions are included to cover the
cylinder
block, cylinder head, crankshaft and bearings, connecting rods and bearings, oil pump, valves and tappets, pistons and rings, flywheel,
timing gears, and the camshaft and bearings. In addition, fitting operations for
these
engine
com
ponents
are included.
Important:
Before the inspection and repair pro
cedures listed below are begun, the
engine
serial
number must be checked for the presence of
code
letters denoting undersize bearings or oversize
pistons. Refer to Par. D-2.
D-32.
Cylinder
Block
The
cylinder block must be thoroughly cleaned, inspected and repaired as detailed in the following
paragraphs.
D-33.
Cleaning
The
cylinder block may be steam cleaned or cleaned
with
a suitable solvent. A scraper is recommended
to remove
hard
deposits, except on highly finished surfaces. Special attention must be directed to the
cleaning of the oil passages, valve chamber,
crank
case, and cylinder walls to remove all sludge,
dirt
and
carbon deposits. After cleaning, use air pressure to dry the block thoroughly.
D-34. Inspection
Examine
the cylinder block for minute cracks and
fractures.
Rusted valve springs or evidence of rust
in
the valve chamber or the cylinder walls is a
good
indication of a possible
crack
in the block,
a.
Examine all machined surfaces of the cylinder block for
burrs
and scores.
Check
for cylinder block
distortion by placing a straight
edge
along the
length of the cylinder head surface of the block.
With
a feeler
gauge,
check for clearance
between
the straight
edge
and the block, particularly be
tween adjacent cylinders. Maximum permissible
out of line for service is .010"
[0,254
mm.] over the
full
length of the block. 45
Page 51 of 376
![JEEP DJ 1953 Service Manual
-Jeep*
UNIVERSAL
SERIES SERVICE
MANUAL
E>
[5,928 a
5,926
cm.] for all main bearings. Allowable
taper or out-of-round of the journals is .001"
[0,0254
mm.].
D-42.
Checking Connecting Ro](/manual-img/16/57041/w960_57041-50.png "JEEP DJ 1953 Service Manual
-Jeep*
UNIVERSAL
SERIES SERVICE
MANUAL
E>
[5,928 a
5,926
cm.] for all main bearings. Allowable
taper or out-of-round of the journals is .001\"
[0,0254
mm.].
D-42.
Checking Connecting Ro")
-Jeep*
UNIVERSAL
SERIES SERVICE
MANUAL
E>
[5,928 a
5,926
cm.] for all main bearings. Allowable
taper or out-of-round of the journals is .001"
[0,0254
mm.].
D-42.
Checking Connecting Rod
Crankpins
Check
the crankpin diameters with a micrometer
to ensure that they are not out-of-round or tapered more than .001"
[0,0254
mm.] The standard
crank-
pin
diameter is
1.9383*
to
1.9375"
[4,9233
a
4,9213
cm.].
D-43.
Crankshaft
Main
Bearings
The
crankshaft rotates on three main bearings
with
a running clearance of .0003" to .0029"
[0,0076
a
0,0736
mm.].
These
bearings are positioned and prevented from
rotating in their supports in the cylinder block by
dowel pins. Dowel pins are used in both the center
and
the
rear
bearing caps. No dowel pins are used
in
the front bearing cap because the bearing has
a
flange. The front main bearing takes the end
thrust
of the crankshaft. The main bearings are of premium type which provides long bearing life.
They
are replaceable and when correctly installed, provide proper clearance without filing, boring,
scraping,
or shimming. Crankshaft bearings can
be removed from this
engine
only with the
engine
out of the vehicle. Crankshaft bearings must be replaced as a complete set of three bearings, each
bearing consisting of two halves.
Main
bearings
are
available in the standard size and the following
undersizes:
.001" [0,025mm.] .012" [0,305 mm.] .002" [0,051mm.] .020" [0,508 mm.] .010" [0,254mm.] .030" [0,762 mm.]
The
.001" and .002" undersize main bearings are
for use with standard size crankshafts having
slightly worn
journals.
The .010", .020", and .030" undersize bearings are for use with undersize
crankshafts
in
those
sizes. The .012" undersize
bearings are for use with .010" undersize
crank
shafts having slightly worn journals. Bearing sizes
are
rubber stamped on the reverse side of each
bearing half.
D-44. Crankshaft
Main
Bearing Inspection
The
crankshaft
journals
must be carefully inspected
as detailed previously in Par. D-41. Worn journals
will
require undersize bearings. Scored, flaked, or
worn
bearings must be replaced. Measure the main
bearing bores in the cylinder block using a
telescope
gauge
and micrometer. Measure the bores at right
angles to the split line and at 45° to the split line.
The
bores should not be over .001"
[0,0254
mm.]
out-of-round or .001" in taper from end to end.
Also,
the bores should not be more then .001"
oversize, considering the average diameter of the
bore.
D-45.
Fitting Crankshaft
Main
Bearings
Using
Plastigage
After
wiping and carefully inspecting the bearing bore, install the proper bearing. See that the oil
hole
in the bearing upper half registers properly
with
the oil
hole
in the block, and that the bearing
lock fits properly in the notch in the block.
Install
the crankshaft if replacing bearings with the
engine
out of the vehicle. The desired running fit (dif
ference
between
the diameter of the crankshaft
journal
and the inside diameter of the fitted bear ing) for a main bearing is .0003" to .0029"
[0,0076
a
0,0736
mm.]. With a dimension in
excess
of this
standard
running fit, a satisfactory bearing replacement cannot be made and it
will
be necessary to
regrind
the crankshaft.
Install
the bearing lower
half
and the bearing cap and draw the nuts down
equally and only slightly tight. Rotate the
crank
shaft by hand to be sure it turns freely without
drag.
Pull
the nuts tighter, first one then the other,
a
little at a time, intermittently rotating the
crank
shaft by hand until the recommended torque of
35 to 45 lb-ft. [4,8 a 6,2 kg-m.] is reached. If the
bearings are of the correct size, and lubricated with
light oil before installation, the crankshaft should
turn
freely in the bearings. If the crankshaft cannot
be turned, a larger bearing is
required.
If there is no binding or tightness, it is still necessary to check
clearance to guard against too
loose
a fit. Never file
either the bearing cap or the bearing to compensate
for too much clearance. Do not use shims under a
bearing cap or behind a bearing shell. Do not run a
new bearing half with a worn bearing half. The use
of "Plastigage" of the proper size to measure .001" [0,025 mm.] clearance is recommended for check
ing crankshaft main bearing clearance. The method
of checking clearance is as follows:
a.
Remove the bearing cap and carefully wipe
all
oil from the bearing and the
journal.
b.
Lay a piece of "Plastigage" y%" [3 mm.]
shorter than the width of the bearing across the
journal
(lengthwise of the crankshaft).
c.
Install
the bearing and cap and tighten first
one nut, then the other, a little at a time to the specified torque. As the bearing
tightens
down
around
the
journal,
the "Plastigage" flattens to a
width that indicates the bearing clearance.
d.
Remove the cap and measure the width of
the flattened "Plastigage," using the scale printed
on the
edge
of the envelope. The proper size "Plasti
gage"
will
accurately measure clearance down to .001".
e. If the flattened "Plastigage" tapers toward the middle, or toward the end, or both ends, there
is a difference in clearance, indicating a taper, a
low
spot,
or other irregularity of the bearing or
journal.
D-46.
Fitting Crankshaft
Main
Bearings
Using
Shim Stock
Thin
feeler or shim stock may be used instead of "Plastigage" to check bearing clearances. The
method is simple, but care must be taken to protect
the bearing metal surface from
injury
by too much pressure against the feeler stock,
a.
Cut a piece of .001" [0,025 mm.] thick, by Yl [12,7 mm.] wide, feeler stock }4" [3 mm.]
shorter than the width of the bearing. Coat this 51
Page 53 of 376
'Jeep'
UNIVERSAL
SERIES
SERVICE
MANUAL
D
satisfactory bearing replacement cannot be made
and
it
will
be necessary to regrind the crankshaft.
Install
the bearing lower
half
and the connecting
rod
cap and draw the cap bolt nuts down equally
and
only slightly tight. Move the connecting rod
endwise, one way or the other, on the crankshaft to be sure the bearing is not tight.
Pull
the nuts tighter, first one then the other, a little at a time,
and
keep trying the fit of the rod on the crankshaft by hand until the recommended torque of 35 to 45 lb-ft. [4,8 a 6,2 kg-m.] is reached. If the
bearings are of the correct size, and have been
properly
lubricated with light
engine
oil before in
stallation,
the connecting rod should be easy to
slide back and forth parallel to the
crankpin.
If
the connecting rod is tight on the crankshaft, a
larger
bearing is required. If there is no binding
or
tightness, it is
still
necessary to check clearance
to guard against too
loose
a fit. The use of "Plasti
gage"
or shim stock of the proper size to measure .001" [0,025 mm.] clearance is recommended for
checking
connecting rod bearing clearances.
This
is the same material recommended for checking
crankshaft
main bearings and the method of check
ing is
similar.
Refer to
Par.
D-45 or D-46. Connect
ing rod bearings are fitted to the same clearance as the main bearings but the torque specified for con
necting rod cap
bolts
is different.
D-50.
Connecting
Rod
Side Play
Check
the connecting rod side play with a feeler
gauge
as shown in Fig. D-l8. The side clearance is .004" to .010"
[0,101
a
0,254
mm.].
D-51.
Camshaft and Bearings
The
camshaft is supported at four points in the
cylinder
block. The front is supported in a re placeable, steel-shell, babbit-lined bearing. The
bearing
is pressed into place The other three bear-
FIG.
D-18—CONNECTING
ROD
SIDE
PLAY
ing surfaces are precision machined in the cylinder
block. The camshaft bearings are pressure
lubri
cated through drilled passages in the crankcase.
End
thrust of the camshaft is taken by a thrust plate bolted to the crankcase. The camshaft is
driven
by a silent helical-cut
tooth
timing gear at
the front of the engine. A worm gear, integral with
the camshaft, drives the oil pump and distributor.
The
fuel pump is actuated by an eccentric forged
onto
the camshaft.
Clean
the camshaft thoroughly in cleaning solvent.
Inspect
all camshaft bearing surfaces to determine
if
they are scored or rough. The cam faces must be
perfectly smooth throughout their contact face
and
must not be scored or worn.
D-52.
Camshaft
Front Bearing Replacement
Use
a suitable driver to remove the camshaft front
bearing
from the cylinder block. To install a new
bearing,
align the oil
hole
in the bearing with the
bored oil
hole
in the cylinder block and drive the
bearing
in until the front end of the bearing is
flush
with the front surface of the cylinder block.
Make
sure the oil
hole
is open and clear. It is not
necessary to line-ream the bearing after installation because bearings for replacement are precision
reamed
to the finished size. Do not stake the
bearing.
D-53-
Camshaft End Play
End
play of the camshaft is determined by running
clearance
between
the
rear
face of the camshaft gear and the thrust plate and is established by the
spacer
thickness. The standard clearance is .004"
to .007"
[0,101
a 0,178 mm.] and can be measured by a
dial
indicator. As a general rule this clearance
will
change but little through wear or when a new gear is installed. To predetermine the correct end
float with the gear, spacer, and thrust plate re
moved, measure the thickness of both the thrust
plate and spacer with a micrometer. The thickness
of the spacer should be approximately .006" [0,152 mm.] greater than that of the thrust plate.
When
this is correct and the parts are assembled
and
drawn tightly
together
by the gear retaining
screw,
the end play should
come
within standard
limits.
D-54.
Timing Gears
and
Cover
The
timing gears are mounted at the front of the
engine. Camshaft drive is through helical-cut
timing gears; a steel gear on the crankshaft and a
pressed fiber gear on the camshaft. The gears are keyed to their respective shafts. The camshaft
driven
gear is secured on the front end of the
camshaft by means of a capscrew and a plain
washer.
The crankshaft gear is secured on the
front end of the crankshaft by a nut threaded
onto
the front end of the crankshaft holding the
crank
shaft pulley, crankshaft oil slinger, and the
crank
shaft drive gear spacer. The timing gears are
lubricated
through a jet threaded into the
crank
case directly above the gear contact and oil supplied
through a drilled passage from the front main
bearing.
The timing gears are enclosed by the
sealed timing cover. The oil seal in the cover bears 53