1953 JEEP DJ ABS

D

HURRICANE
F4
ENGINE

FIG.
D-2
2—REFACING
VALVES
1—
Valve
Refacer

2—
Valve
a
dial
indicator as shown in
Fig.
D-21 after refacing.

The
valve seat should not be out of round more

than
.002"
[0,051
mm.]. A simple check can be
made in the absence of a
dial
indicator by spreading
a
thin coat of pencil lead or bearing-fitting blue on
the valve face and then inserting the valve into the valve seat.
With
hand pressure, rotate the valve

a
quarter
turn
and then remove the valve and ob­
serve the transfer of blue (or pencil lead) to the valve seat. An uneven transfer
will
indicate an

inaccurate
valve and valve seat refacing operation.

After
the seat is ground, check its width with a
seat width scale or a steel scale placed across the
face of the seat. The valve seat width after refacing
should measure [2,3 mm.] and not wider than
y%"
[3,2 mm.]. Valve seat width is
vital.
Too wide

a
seat can cause seat burning as it
tends
to trap

and
hold carbon particles. Seats that are too
narrow

will
not transfer heat to the coolant rapidly enough to keep the valves in proper operating condition.

When
a valve seat has been refaced several times

or
where it must be cut deeply for adequate recon­
ditioning, the seat may
become
too wide for efficient
operation. Narrow the seat without changing its
position in relation to the valve face by using a
valve seat relief counterbore above the seat and a valve seat narrowing cutter below the seat. These
operations are performed only after the valve
seats
have been refaced and then only when necessary.

The
finished valve seat should contact the approxi­mate center of the valve face.
Check
by applying

an
extremely thin coat of pencil lead or bearing-
fitting blue to the seat.
Then
install and rotate the
valve with light pressure. Blue (or pencil
marks)

will
transfer to the face of the valve. If the blue
is near the top
edge
of the valve face, lower the valve seat by using the valve seat relief counter-
bore. If the blue is transferred to the
bottom
edge

of the valve face, raise the seat by using the valve
seat narrowing cutter.

When
the valve seat can no longer be corrected, it
is advisable to investigate installing seat inserts.

D-60.
Exhaust
Valve Seat Insert Replacement

Hardened
valve seat inserts for exhaust valves
will

seldom require replacement. To avoid damaging the blcck, remove an insert with a tool designed for
this purpose.

When
installing a new insert, make certain the
counterbore is clean and smooth. Use a driver that

will
keep the insert in true alignment with the bore.

Cool
the insert and the installing tool with dry ice
for 30 minutes.

Note:
The insert should be sufficiently cooled
to permit installation with light taps; excessive

driving
of the insert may cock it in the counterbore

or
crack the insert.

Make
certain the valve seat is facing out.
Drive

in
the insert with the tool until it
bottoms
in the counterbore. After installation, grind the valve
seat at an angle of 45° and then check with a
dial

indicator
as shown in Fig. D-21.
D-61.
Valve Guide Replacement

Damaged,
loose,
or worn valve
guides
must be re­

placed.
Use valve guide driver W-238 or equivalent
to drive out the old guides. When replacing valve
guides, maximum
engine
performance can be se­

cured
only when the guide is positioned correctly
FIG.
D-23—VALVE
GUIDE
DRIVER

FIG.
D-24—VALVE
GUIDE
POSITIONS

1—Flush
at
this
point
2—One
Inch
[25
mm.
I

56

'Jeep'
UNIVERSAL SERIES SERVICE
MANUAL

Dl

©©©©©©©©©

12697

FIG.
Dl-1—DAUNTLESS
V-6
ENGINE, SIDE SECTIONAL VIEW

1—
Fan
Blade
2—
Fan
Spacer

3—Fan
Pulley
4—
Water
Pump 5—
Timing
Chain
Cover
6—
Camshaft
Sprocket
7—
Thermostat
Bypass Hose
8—
Thermostat
Housing
9—
Thermostat

10—
Carburetor

11—
Intake
Manifold
12—
Rocker
Arm Cover 13—
Cylinder
Block 14—
Push
Rod
15—
Camshaft

16—
Flywheel
17—
Clutch
Pressure Plate
18—
Clutch
Driven Plate
19—
Clutch
Pilot Bearing
20—
Oil
Seal Packing
21—
Rear
Main
Bearing Shell
22— Connecting Rods
23—
Rear
Center
Main
Bearing Shell
24—
Oil
Screen
25—
Oil
Screen Pipe and Housing
26—
Oil
Pan 27—
Front
Center
Main
Bearing Shell
28—
Crankshaft

29—
Front
Main
Bearing Shell
30—
Timing
Chain

31—
Crankshaft
Sprocket
32—
Oil
Slinger
33—
Oil
Shedder 34 Oil Shedder Packing
35—
-Woodruff
Key
36—
"Vibration
Damper
37—
Crankshaft
Pulley
38—
Fan
Belt matic adjuster, to prevent lash in the valve operat­
ing linkage. Hydraulic valve lifters also provide

a
cushion of oil to absorb operating shocks. As shown in Fig. Dl-3, all parts of a hydraulic lifter

are
housed in the body, which is the cam follower.

At
the beginning of valve operation, the valve lifter body rests on the camshaft base circle.

Plunger
spring tension prevents lash clearances in the valve linkage.

As
the camshaft forces the valve lifter body up­

ward,
both oil in the lower chamber and check

ball
spring
tension firmly seat the check ball against the plunger to prevent appreciable
loss
of oil from
the lower chamber. Oil pressure forces the plunger
upward,
with the body, to operate the valve linkage.

As
the camshaft rotates to closed-valve position, the valve spring forces the linkage and lifter down­

ward.
When the
engine
valve seats, the linkage

parts
and plunger stop, but the plunger spring forces
the body downward .002" to .003"
[0,050
a
0,076
mm.] until it again rests on the camshaft base

circle.
Oil pressure then forces the check ball away

from
its seat and allows passage of oil past the check ball into the lower chamber.
This
replaces
the slight amount of oil lost by leakage. During
the valve opening and closing operation, a very
slight amount of oil escapes
between
plunger and body, and returns to the crankcase.
This
slight
loss
of oil (leak-down) is beneficial. It provides a
gradual
change of oil in the valve lifter; fresh oil
enters the lower chamber at the end of each cycle
of operation. 77

'Jeep*
UNIVERSAL SERIES SERVICE
MANUAL

Dl

12710

FIG.
D1
-3—HYDRAULIC VALVE
LIFTER
ASSEMBLY, CROSS-SECTIONAL VIEW
1—
Snap
Ring
6—Ball Retainer

2— Rod
Seat
7—Plunger Spring

3—
Oil
Inlets
8—Lifter
Body

4—
Plunger
9—Bronzed
Cap
5— Feed
Hole
sages
in the block and cylinder head.

The
water cooled system is pressurized to provide efficient
engine
cooling. It consists of a centrifugal-
type water pump, mounted on the timing chain cover, and is driven by the
engine
fan pulley. The
pump provides coolant flow equally to both
cylin­
der banks under control of a thermostat. Coolant
flow is around the cylinders and through the
cylinder
head to dispel the heat of combustion in
the engine.

Dl-3.
Engine Mounts

The
engine-transmission unit is mounted to the chassis at three points by rubber pads. The two
front mounts are bolted to the
engine
cylinder
block and the frame members. These mounts sup­ port most of the
engine
weight, and absorb
vibra­

tion which would otherwise be caused by changes
in
engine
output torque. The single
rear
mount is
placed
between
the transmission and the trans­ mission support. It supports part of the engine'

and
transmission weight, and locates the
rear
of
the
engine
with respect to the centerline of the
vehicle.

Dl-4. ENGINE REMOVAL
To
remove the
engine
from the vehicle follow the
procedurers listed below:

a.
Remove hood. b. Disconnect battery cables from battery and
engine. c. Remove air cleaner.

d.
Drain
coolant from radiator and engine.
e.
Drain
engine
oil.
f. Disconnect alternator wiring harness from con­ nector at regulator.

cj.
Disconnect the fuel evaporative purge line con­ nected to the
P.C.V.
valve.

h.
Disconnect upper and lower radiator
hoses
from
the engine.

i.
Remove right and left radiator support
bars,

j.
Remove radiator from the vehicle.

k.
Disconnect
engine
wiring harnesses from con­
nectors located on
engine
firewall.
I.
On
engines
equipped with exhaust emission con­

trol,
remove the air pump, air distribution manifold,

and
anti-backfire (gulp) valve. See Section F2 for
procedure.

m.
Disconnect battery cable and wiring from en­

gine
starter assembly.

n.
Remove
engine
starter assembly from engine,

o.
Disconnect
engine
fuel
hoses
from fuel lines at

right
frame
rail,
p. Plug fuel lines.

q.
Disconnect choke cable from carburetor and cable support bracket mounted on engine,
r.
Disconnect exhaust pipes from right and left

engine
manifolds.
s. Place
jack
under transmission and support trans­
mission weight.
f. Remove
bolts
securing
engine
to front motor mounts.

u.
Attach suitable sling to
engine
lifting
eyes
and,
using hoist, support
engine
weight.
v. Remove
bolts
securing
engine
to flywheel housing.
w. Raise
engine
slightly and slide
engine
forward
to remove transmission main shaft from clutch plate spline.

Note:
Engine and transmission must be raised
slightly to release the main shaft from the clutch
plate while sliding the
engine
forward.
x. When
engine
is free of transmission shaft raise

engine
and remove from vehicle,
y. Place
engine
on suitable blocking or
engine
stand and remove sling from engine.

Dl-5.
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 appli­cable 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.

'Jeep'
UNIVERSAL
SERIES SERVICE
MANUAL

Dl
size have
been
selected. If necessary, check or
select

connecting rod bearings as described in Par. Dl-49.

Note:
When a piston and connecting rod assembly
is properly installed, the oil spurt
hole
in the con­ necting rod
will
face the camshaft. The rib on the

edge
of the bearing cap
will
be on the same side
as the conical
boss
on the connecting rod web;
these
marks (rib and boss)
will
be toward the other
connecting rod on the same crankpin. The notch
on the piston
will
face the front of the
engine.

a.
Be certain that cylinder bores, pistons, connect­
ing rod bearings and crankshaft journals are absolutely clean. Coat all bearing surfaces with

engine
oil.
b. Before installing a piston and connecting rod as­
sembly into its bore, rotate the crankshaft so that
the corresponding crankpin is moved downward, away from the cylinder bore.
c. Remove bearing cap from connecting rod. With
upper bearing half seated in connecting rod, install connecting rod guides. These
guides
hold the upper
bearing half in place and prevent damage to the

crankshaft
crankpin during installation of the con­
necting rod and piston assembly.

d.
Be certain that the gap in the oil ring rails faces

upward,
toward center of
engine.
Gaps of the com­
pression rings shall not be aligned with each other

or
with the oil ring
rails.

e. Lubricate the piston and rings. Compress the
rings with a suitable piston ring compressor; install
the piston and connecting rod assembly from top of cylinder bore. Refer to Fig. Dl-33.

f.
Install
bearing cap, with lower bearing half, on connecting rod. Torque bolt nuts to 30 to 40 lb-ft. [4,1 a 5,5 kg-m.].
g.
Install
all other piston and connecting rod as­
semblies in same manner.

h.
Check
end clearance
between
connecting rods
on each crankpin with a feeler
gauge.
Clearance should be .005,/ to .012" [0,127 a
0,305
mm.].

Dl-76.
Install
Oil
Pump
Intake
Pipe
and
Screen Assembly

Check
mating surfaces of oil pump intake pipe

and
engine
cylinder block to be certain that they

are
clean. Secure the pipe and screen assembly,
with a new gasket, to
engine
cylinder block with two attaching screws. See Fig. Dl-34. Torque screws 6 to 9 lb-ft. [0,83 a 1,24 kg-m.].

Dl-77.
Install
Oil Pan

Refer
to Fig. Dl-35.

Be
certain the flange surface of oil pan and cor­
responding surface of
engine
cylinder block are
clean.
Install
a new oil pan gasket on the cylinder
block.
Secure
oil pan to cylinder block with mount­ ing bolts. Torque
bolts
10 to 15 lb-ft [1,4 a 2,1

kg-m.].

Dl-78.
Install
Flywheel

Refer
to Fig. Dl-7.

a.
Check
flywheel flange of
engine
crankshaft and corresponding surface of flywheel to
be
certain that
FIG.
Dl-33—INSTALLING
PISTON
AND

CONNECTING
ROD
ASSEMBLY
1—Ring
Compressor

FIG.
Dl-34-^-OIL
PUMP
INTAKE PIPE
AND

SCREEN
INSTALLATION
1—Pipe and Screen
97

E

FUEL
SYSTEM

FIG.
E-1—FUEL SYSTEM—EARLY MODEL—F-4 ENGINE 1—
Fuel
Line
To Carburetor 4—Accelerator Treadle
2— Carburetor 5—Fuel Tank and Gauge
3— Choke Cable 6—Fuel Pump

FIG.
E-2—FUEL SYSTEM—EARLY
MODEL—V-6
ENGINE 1—
Fuel
Line
To Carburetor 5—Fuel Tank and Gauge

2—
Carburetor 6—Fuel Pump
3— Choke Cable 7—Fuel
Line
To Fuel Pump

4—
Accelerator
Treadle 8—Fuel Return
Line
normally
vents
to the atmosphere from the vehicle
fuel system.

The
fuel vapor system consists of internal fuel tank
venting, a vacuum /pressure fuel tank cap, a vapor
separator or expansion tank, vapor canister, and closed external carburetor venting. The same basic
system is used on all 'Jeep' vehicles, as shown in
Fig. E-3.

This
system involves means of trapping the fuel
vapors through the use of a charcoal canister which
absorbs the vapor and stores it until it can be re­ moved to be burned in the
engine.
This
removal is
performed by drawing
these
vapors through the purge line
into
the crankcase ventilation system

which
in
turn
enters the intake manifold. In ad­ dition to the canister, the fuel tank requires a sealed
gas cap and extra
vents
to a liquid separator or
expansion tank.
This
prevents liquid
gasoline
from entering the vapor system.
Thus,
as vapors are generated in the fuel tank,
they
flow through the

liquid
separator or expansion tank to the canister

and
are routed to the intake manifold through the 110

'Jeep*
UNIVERSAL
SERIES
SERVICE
MANUAL

E
there is a relief valve that
opens
to reduce high
(dangerous) pressures in the fuel tank. In con­

junction
with the pressure relief valve there is a
vacuum
relief valve to
stop
collapse of the fuel

tank
in case of a plugged system or failure of the demand valve. When replacing the gas cap, the
same type must be used as originally installed.

E-8.
System Inspection Test

The
fuel emission vent system should be checked

carefully
to ensure the absence of any leaks to the
atmosphere of either liquid or vapor which might
affect the accuracy, safety, or performance of the control system.

To
assure that the sealed system has been properly

installed,
the following
test
procedure has been
developed.
Disconnect the vent line from the fuel tank system
to the activated charcoal canister, induce l/i p.s.i.
air
pressure. If this pressure can be maintained for

a
few seconds the vent system is assured to be sealed. DO NOT add air pressure to the canister
because damage can occur to the demand valve if
care
is not taken.

E-9.
Servicing the System

Periodic
Maintenance — Replace carbon canister filter at
12,000
miles
[19,200
km.] or 12 month in­tervals (more
often
for operation in dusty areas).

This
is the only regular maintenance service

required.

Canister
Filter
Replacement — Disconnect
hoses

from
top of canister, remove canister from mount
-

t
FIG.
E-5—CARBURETOR—
F4 ENGINE,
EARLY
MODEL
1—
Choke
Clamp
Bracket

2—
Choke
Shaft and
Lever
Assembly

3—
Fuel
Inlet
Elbow

4—
Bowl
Vent Tube 5—
Idle
Air Adjusting
Needle
6—
Throttle
Lever
and Shaft Assembly
7—
Idle
Speed Adjusting Screw
8—
Fast
Idle Connector Rod ing bracket. Remove cover from
bottom
of canister
by pulling it down to
disengage
clips. Remove and
discard
polyurethane filter element
(squeeze
ele­

ment out from under retainer bar).
Install
new
filter by squeezing element under retainer bar and positioning it evenly around entire
bottom
of
canister with
edges
tucked under canister lip, snap

bottom
cover in place, reinstall canister on bracket

and
reconnect
hoses.

Vapor
line
hoses
used in this system are made of

special
rubber material.
Bulk
hoses
are available for
parts
service.
Ordinary
rubber
hose
should not be
used to service vapor lines as they are subject to deterioration and may clog the system.
Liquid

vapor separators or expansion tanks and canisters

are
serviced as complete units only.
Canister
air filters, however, are serviced separately.

E-10.
CARBURETOR
—
HURRICANE
F4
ENGINE

A
single-barrel manual choke, down-draft carbure­
tor (Fig. E-6) is used on the
Hurricane
F4 engine.
The
carburetor is internally vented by a tube
opening located in the air horn body of the
car­

buretor.
This
opening is connected by a rubber
tube to the air
outlet
horn of the air cleaner thus
allowing only filtered atmospheric pressure air
to enter the float chamber for balance pressure
of the carburetor fuel.

Note:
A carburetor with a specific flow character­

istic
is used for exhaust emission control. The
carburetor
is identified by a number, and the correct

carburetor
must be used, when replacement is
necessary.

Early
production models
CJ-3B,
CJ-5,
CJ-5A,
CJ-6,
and
CJ-6A
have a
Carter
YF-938SD
carbure­
tor superseding the earlier
YF-938SC,
YF-938SA,

or
YF-938S
models.

Note."
Conversion kits for changing earlier models
to SD models are available. See Par E-23. It is recommended that when a carburetor is converted
that a tag be fashioned stamped with the new model number and installed under one of the air

horn
screws.
Look
for such a tag to determine if
the carburetor has previously been converted.

Carburetors
listed above are all in the same YF
series and have only minor differences. Descriptions
and
repair procedures given in the following
para­
graphs apply equally to all
YF-series
carburetors.
YF-series
carburetors employ manual and vacuum
control of the metering rod and accelerator pump.
The
carburetor controls and vaporizes the fuel
through five separate systems: float system, low-
speed system, high-speed system, choke system,

and
accelerating-pump system. A description of the function and operation of each system provides an over all description of the carburetor.

For
identification, the series designation is stamped
on the body under the name
Carter
and the model
designation is stamped on a flange protruding
from
the body.

Note:
When checking for carburetor icing causes,
also check the vacuum-pump-to-manifold vacuum
line connector. 113

H

ELECTRICAL
SYSTEM

ffKHs)

3—<§)

FIG.
H-7—WIRING
DIAGRAM—V6
ENGINE
CURRENT
MODEL
1—
Left
Headlamp
2—Left Parking and Signal Lamp
3— Right Parking and Signal Lamp
4—Right Headlamp 5—
Marker
Lamp — Amber
6— Alternator 7— Voltage Regulator
8— Starting Motor
9— Battery Ground Cable
10— 12 Volt Battery
11—
Flasher
(Directional Signal)
12— Instrument Cluster
A—Hi-Beam
Indicator
B—Auxiliary

C—Instrument
Lights

D—Oil
Pressure Indicator
E—Charging
Indicator

F—Temperature
Indicator

G—Fuel
Gauge Indicator
H—Instrument Voltage Regulator
13— Ignition and Starter Switch
14—
Horn
Button
15— Directional Signal Switch
16— 4-Way Flasher Switch 17—
Flasher
(4-Way)
18— Windshield Wiper Motor Switch
19—
Main
Light Switch
20—
Fuel
Gauge
Tank
Unit
21—
Back-Up
Light Switch
22—
Marker
Lamp — Red
23— Right
Tail
and
Stop
Light 24— Right Back-Up Lamp
25—
Left
Back-Up Lamp 26—
Left
Tail
and
Stop
Light
27—
Marker
Lamp — Red
28—
Stop
Light Switch
29— Foot Dimmer Switch
30— Windshield Wiper Motor Assembly
31—
Ballast
Resistor 32— Ignition
Coil

33—
Spark
Plugs and Cables 34— Temperature Sending Unit
35—
Oil
Pressure Sending Unit 36—
Horn
37— Junction Block
38—
Marker
Lamp — Amber

lions
on the terminal
posts.
Be sure
condenser
is
mounted
firmly on the distributor for a
good
ground
connection.

Should a
condenser
tester
be available the capacity for
both
F4 and Prestolite V6
condenser
should
check from .25 to .28 microfarads. In the
absence

of
tester,
check by substituting a new
condenser.

H-13. Distributor Points
a. Examine the distributor
points.
If
they
show

wear,
poor
mating, transferred metal, or pitting,

then
new
ones
should be installed. Clean the
points

with a suitable
solvent
and a stiff bristled brush.
b. Check the
alignment
of the
point
for a full,
square
contact.
If not correctly aligned, bend the
stationary
contact
bracket slightly to provide align­
ment.

c. The
contact
gap should be set at .020"
[0,508
mm.],
on the F4 and .016"
[0,406
mm.] on the
Prestolite V6. Adjustment of the gap is accom­ plished by
loosening
the lock screw and turning adjusting eccentric screw until correct gap is
secured. Be sure that the fiber block on the breaker

arm
is resting on the
highest
point
on the cam while the adjustment is
being
made. Recheck the gap
after locking the adjustment.
d. Apply a thin film of cam lubricant to the cam to
lessen
fiber block wear.
e. Using Tool C-4094, check
point
contact
spring
pressure, which should be
between
17 and 20

ounces
[0,487
a
0,567
kg.] on the F4 and 17 to 22 oz.
[0,487
a
0,624
kg.] on the Prestolite V6.

Check
with a spring scale
hooked
on the breaker

arm
at the
contact
and pull at right
angle
to the
breaker arm. Make the reading just as the
points

separate. Adjust the
point
pressure by
loosening
the stud holding the end of the
contact
arm spring
and slide the end of the spring in or out as
neces­

sary.
Retighten the stud and recheck the pressure. Too low a- pressure will
cause
engine
missing at
high
speeds.
Too high a pressure will
cause
rapid
wear of the cam, block, and
points.
180

'Jeep*
UNIVERSAL
SERIES SERVICE
MANUAL

H
|
13399

FIG.
H-10—DELCO
DISTRIBUTOR—
DAUNTLESS
V-6
ENGINE

1—
Rotor
8—Vacuum
Unit

2—
Window
9—Breaker Cam
3—
All
Weather Cap
10—Drive
Gear

4—
Cap
Latch
11—Primary Lead 5—
Rotor
Mounting
Screw 12—Contact Set
6—
Lock
Washer 13—Condenser

7—
Advance
Mechanism
by
built-in
centrifugal weights, and by a vacuum

advance
system. Contact point opening is adjusted
through
a window in the distributor cap
while
the engine is
idling.
Some
parts
of the distributor may be checked or replaced
with
the distributor mount­
ed on the engine, but it is
best
to remove it periodi­
cally
for a thorough check. Information on
parts

which
can be serviced without removal is given
below.

Note:
Prestolite and Delco distributors are inter­

changeable
on V-6 engine equipped vehicles.

H-21.
Distributor Cap
The distributor cap should be inspected for cracks,
carbon runners and evidence of arcing. If any of

these
conditions exist, the cap should be replaced. Clean any corroded high tension terminals.

H-22.
Rotor
Inspect the rotor for cracks or evidence of
exces­

sive burning at the end of the metal strip.
After
a distributor rotor has had normal use, the
end of the rotor
will
become
burned. If burning is
found
on top of the rotor it indicates the rotor is too short and
needs
replacing. Usually when this
condition
is found the distributor cap
segment
will

be burned on the horizontal face and the cap
will

also
need
replacing.
H-23.
Condenser
The
condenser
prolongs the
life
of the distributor
points by preventing arcing at the contacts. It
also

provides a hotter spark by creating a
reverse
surge

of
current
which
rapidly
breaks
down the magnetic
field
of the
coil
by demagnetizing the core. Should
the
ccnaenser
be leaky a weak spark
will
result. Check the
condenser
lead for broken wires or

frayed
insulation.
Clean and tighten the connections
on
the terminal
posts.
Be
sure
the
condenser
is mounted
firmly
on the distributor for a good ground
connection.

Should
a
condenser
tester
be available the capacity
should check
from
.18 to .23 microfarads. In the

absence
of a
tester
check by substituting new con­
denser.

H-24. Distributor Points

a-
Examine distributor points. Using
Tool
C-4094, check point contact spring
pressure,
should be 19 to 23 oz. [0,538 a 0,652 kg.]. Install new points

if
they are
worn,
pitted,
mate
poorly, or show
signs

of
metal transfer. Should premature
ignition
point

failure
occur
because
of dust entering the
distri­

butor cap and causing
excessive
wear to the
ignition

point
fiber block, perform the
following
correc­
tions after installing new distributor points.
FIG. H-l
1—SEALING
DISTRIBUTOR
CAP

1—Caulking
Compound
183