horn JEEP DJ 1953 Service Manual

LUBRICATION

vital
to the life of the
engine.
When the vehicle
is operated under abnormal conditions, (for ex­
ample when driven on secondary roads or through
fields) then service of the air cleaner must be more frequent

Note:
Under extreme continually dusty and dirty
conditions where the vehicle operates in clouds of dust and
dirt,
service the air cleaner daily.

a.
To service the air cleaner on vehicles equipped
with the
Hurricane
F4
engine
(Fig. B-5) unscrew
the eye
bolt
on the oil cup clamp and remove the

oil
cup from the cleaner body. Remove the oil from the cup and scrape all
dirt
from the inside, wash cup clean using a cleaning solution if neces­

sary.
In summer
refill
the oil cup with IV2 pints [0,6 ltrs.] of
SAE-40
or 50 grade
engine
oil. In
winter
refill
using grade
SAE-20
engine
oil. For
servicing the air cleaner
body
(less
oil cup),
loosen

hose
clamp and remove
hose
from the cleaner. Detach breather
hose
from the fitting on the cleaner. Remove the two wing screws and lift the
cleaner from the vehicle. Agitate the cleaner
body

thoroughly in cleaning solution to clean the filtering

element.
Dry
element
with low pressure com­ pressed air. Reinstall the cleaner
body
and replace
the oil cup. Service the air cleaner every
2000
miles
[3.200
km.].
b. To service the oil bath air cleaner on vehicle
equipped with the Dauntless V-6
engine
(Fig. B-6),

first
remove the air cleaner from the carburetor
by unscrewing the wing nut. Remove the oil cup
FIG.
B-5—OIL
BATH AIR
CLEANER
-
HURRICANE F4 ENGINE 1—
Horn
7—Clamp
2—
Flexible
Connector
8—Oil
Cup
3—
Hon
Clamp
9—Clamp

A—Carburetor
Vent Tube 10—Hose 5— Body 11—Clamp
6—
Screw
and
Lock
Washer 13—Gasket
FIG.

B-6—OIL BATH AIR
CLEANER
-
DAUNTLESS V-6 ENGINE

1—WinB
Nut
2—
Cover

3—
Rubber
Gasket
4—
Cork
Gasket
5—
Oil
Cup 6—
Breather

7—
Clamp

8—
Vent
Tube 9—
Air
Pump Hose from cleaner
body
and remove the oil from the cup,
scrape all
dirt
from the inside.
Clean
oil cup thor­
oughly, wash filter
element
in a solvent that
will
leave it clean and dry.
Fill
oil cup to indicated
level with clean
S.A.E.
40 or 50 grade
engine
oil
(S.A.E.
20 grade in winter.) Assemble cleaner filter

element
to oil cup making sure that gasket is in
place
between
the two pieces. Assemble air cleaner assembly to carburetor making sure the gasket
be­

tween
air cleaner and carburetor is in place. Secure

air
cleaner to carburetor with wing nut. Service the

air
cleaner every
6000
miles
[9.600
km.],
c.
Carefully
check the
hose
clamps and
fittings
on
the breather
hoses
at frequent intervals. Loose con­nections
will
affect proper operation of the
crank­

case ventilating system.

B-26. Dry-Type
Air Cleaner Service the air cleaner on Dauntless V-6
engines

at each oil change under normal driving conditions.

If
the vehicle is operated under dusty conditions,
check the condition of the air cleaner
element
more
frequently and service if dirty.

Servicing
the air cleaner consists of cleaning or replacing the air cleaner
element
and replacing the

crankcase
ventilation filter (breather assembly). See Fig. B-7.

The
air cleaner
element
assembly consists of a
paper
element
and a polyurethane
element
The
paper
element
cannot be cleaned.

To
clean the polyurethane
element,
first carefullly remove it from the paper
element
Then
wash it in 14

'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

'Jeep*
UNIVERSAL SERIES SERVICE
MANUAL

E

FUEL
SYSTEM
Contents

SUBJECT
PAR.

GENERAL
E-1 Dash

FUEL
EVAPORATIVE EMISSION
?*^r
CONTROL SYSTEM
..E-2
Canister
.E-3 . Demand Valve E-4

Fuel
Tank.
.E-5
Inspection Test. E-8
Sealed Gas Cap. E-7

Servicing
System E-9
Vapor
Separator or Expansion
Tank
E-6

CARBURETOR
—
HURRICANE F4 ENGINE.
. .
......
..... ,. . .E-10 Accelerating Pump System.............. .E-19 Accelerating Pump Maintenance E-20

Carburetor
Reassembly
E-2
2

Carburetor
Disassembly E-21
Choke
System E-17
Dash
Pot Adjustment E-44

Fast
Idle Adjustment E-18
Float
Adjustment E-12
Float
System. E-ll
High-Speed System . .E-15
Idle
Adjustment .E-14

Low-Speed
System . E-13
Metering Rod Adjustment E-16

CARBURETOR
~r
DAUNTLESS V-6 ENGINE
.E-25
Accelerator Pump Adjustment E-41 Accelerator Pump System. . E-30

Air
Horn Body Assembly E-39
Air
Horn Body Removal and Disassembly.
E-33

Carburetor
Cleaning and Inspection E-36
Carburetor
Removal E-32
Choke
System E-31

Curb-Idle
Speed and Mixture Adjustment. .E-42

E-1. GENERAL
The
fuel system of the Jeep Universal vehicle,
whether equipped with a Hurricane F4 or Daunt­

less
V-6 Engine,
consists
of the fuel tank, fuel lines, fuel pump, carburetor and
air
cleaner.
Fig. E-1, E-2.
Vehicles equipped with a
Fuel
Evaporative
Emis­

sion Control System
also
include a
non-vent

pressure and vacuum
sensitive
gas cap, a liquid
expansion and vapor separator tank, a carbon filled vapor
storage
canister, and a vapor purge line. Service information pertaining to the
Fuel
Evap­

orative Emission Control System is outlined in

Par.
E-2 through
E-9.
Refer to Figs. E-3 and E-4.
The
most
important
attention
necessary to the fuel
system is to
keep
it clean and free from water. It should be periodically inspected for leaks.

CAUTION—Whenever
a vehicle is to be stored for

an
extended
period, the fuel system should be com­

pletely
drained, the
engine
started and allowed to
run
until the carburetor is emptied.
This
will
avoid
oxidization of the fuel, resulting in the formation of
SUBJECT
PAR.
Pot Adjustment .E-44

nal
Carburetor Adjustments.........E-40

Idle
Adjustment
.
E-43 System . . .E-26

Bowl
Body Assembly E-38

Fuel
Bowl Body Disassembly E-34

Idle
System E-27

Main
Metering System E-28
Power System . E-29
Throttle
Body Assembly .E-37

Throttle
Body Removal, and Disassembly. .E-35

FUEL
PUMP
—
HURRICANE F4 ENGINE.
E-45, 54, 60

Cleaning
and Inspection.............
.E-57,
63 Disassembly E-46, 56, 62
Installation E-59, 65
Reassembly
.E-47,
58, 64
Removal
E-55, 61

Testing.
E-49, 50, 51, 52, 53, 66

Vacuum
Pump E-48

FUEL
PUMP
—
DAUNTLESS V-6 ENGINE
E-67
Removal
E-68

AIR CLEANER
—
CARBURETOR
E-69
ACCELERATOR
LINKAGE
.E-70

FUEL
TANK
AND
LINES
E-71
Float
Unit . .E-76
Fuel
Lines E-77
Fuel
Tank
. . .E-72

Fuel
Tank
Cap E-75

Fuel
Tank
Installation. E-74
Fuel
Tank
Removal E-73

SERVICE
DIAGNOSIS
E-78

SPECIFICATIONS.
E-79
gum in the units of the fuel system. Gum formation
is similar to hard varnish and may cause the fuel
pump valves or the carburetor
float
valve to be­
come
stuck or the filter screen blocked. Acetone or commercial fuel system cleaners
will
dissolve

gum formation. In
extreme
cases
it
will
be necessary
to dissassemble and clean the fuel system. In
most

cases, however, a
good
commercial fuel system sol­
vent
used in accordance with the manufacturer's
instructions or one pint [0,6 ltr.] of
acetone
placed
in
the fuel tank with
about
one gallon [4,5 ltr.]
of
gasoline
will
dissolve
any
deposits
as it
passes

through the system with the
gasoline.

E-2.
FUEL
EVAPORATIVE EMISSION CONTROL SYSTEM

Description and Operation

•
Refer to Figs. E-3 and E-4.

The
Fuel
Evaporative Emission Control System
is
designed
to reduce fuel vapor emission that 109

'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

FUEL
SYSTEM

14261

FIG.
E-6—CARBURETOR—
F4 ENGINE,
LATE
MODEL 1—
Choke
Clamp Bracket
2—
Throttle
Lever
and Shaft
3—
Choke
Shaft and
Lever

4—
Bowl
Vent Tube
5—
Fuel
Inlet Elbow
6—
Dash
Pot Bracket 7—
Throttle
Lever
8—
Dash
Pot Plunger
9—
Dash
Pot Assembly
10—
Lock
Nut
11— Stop Pin

1
2—Idle Mixture
Limiter
Cap
13—
Idle
Speed Adjusting Screw 14—
Fast
Idle Connecting Rod
E-11.
Float System

The
float system, Fig. E-7, consists of a float,
float
pin,
air horn gasket and the
needle
and seat assembly. These parts control the fuel level in the

carburetor
bowl, a supply being maintained for all
systems under all operating conditions. To prevent
float
vibration
from affecting the fuel level, the
inlet or float valve is spring loaded. Should the

needle
and seat
become
worn, they must be re­
placed
with a matched set, including the spring,

which
is the only way they are supplied. When
reinstalling
the float, be sure to install the float pin

with
the
stop
shoulder on the side away from the bore of the carburetor.

E-12.
Float Adjustment

Correct
float level setting is required for accurate
metering of fuel in both low- and high-speed jets.

To
set the float, remove and invert the bowl cover. Remove the bowl cover gasket. Allow the weight
of the float to rest on the
needle
and spring. Be

sure
there is no compression of the spring other

than
the weight of the float. Adjust the level by
bending the float arm lip that contacts the
needle
(not the arm) to provide specified clearance be­
tween the float and cover. The specified clearance of the float is
L74\F
[6,74 mm.] on current models
(including
Exhaust
Emission Control) and [7,93 mm.] on early models shown as A in
Fig.
E-8.
FIG.
E-7—FLOAT SYSTEM
1—
Float
and
Lever
Assembly
2—
Needle
Valve and Seat Assembly

3—
Vent

4—
Float
Bowl Cover 5—
Float
7 '.. j
io8Si
i

FIG.
E-8—FLOAT
LEVEL
GAUGING
E-13.
Low-Speed System

Fuel
for idle and early part-throttle operation is
metered through the low-speed system. The low-
speed system is illustrated in Fig.
E-9.
Liquid
fuel enters the idle well through the metering rod jet.

Low-speed
jet measures the amount of fuel for
idle and early part-throttle operation. Air-by-pass,
economizer, and idle air bleed are carefully
cali­

brated
orifices which serve to break up the liquid
fuel
and mix it with air as it
moves
through the passage to the idle port and idle adjustment screw

port.

E-14.
Idle Mixture Adjustment

Note:
The idle mixture adjustment procedure for
the late model
YF-4941S
and
YF-6115S
Carter
Carburetor
equipped with the
External
Idle

Mixture
Limiter
Cap is the same as outlined below 114

'Jeep*
UNIVERSAL
SERIES
SERVICE
MANUAL

E
Note:
The
Carter
YF-6115S Carburetor has a

throttle
return spring
attached
from the carburetor
main
body
to the carburetor
throttle
shaft. The

purpose
of
this
spring is to return the
throttle
to
idle
speed
position
should a linkage failure occur.

E-21.
Carburetor Disassembly

•
Refer to Fig. E-13. a. Pry pin spring and
clevis
clip
free
and
remove
fast-idle
connector
rod.
b- Remove air horn and bowl
cover
attaching
screws and lockwashers. Remove
choke
tube
clamp

assembly.

c. Remove air horn
assembly
and
gasket.

d. Remove ball check valve retainer ring. Invert the unit and tap
lightly
to
remove
ball check valve
retainer and ball check valve.
e. Loosen the screw locking the
throttle
shaft
arm to the
throttle
shaft. Remove the
throttle
shaft

arm
and
pump
connector
link.
f. Remove diaphragm
housing
screws.
Entire
as­
sembly
can now be
lifted
out of the
body.
This

assembly
can easily be
disassembled
and reas­

sembled
if necessary.
g. On early
models
carefully
remove
pump
intake strainer
housing
using tip of knife blade.
h. With the air horn in an
upside-down
position,

remove
pin and
float.
Invert the air horn and catch
needle
pin and
needle
pin spring.

i.
Remove
metering
rod jet. Remove
low-speed

jet.

FIG.
E-13—CARBURETOR

1— Choke Shaft and Lever
2— Screw
3— Choke Lever Spring
4— Screw and Washer
5— Choke Valve Screw 6— Choke Valve
7— Screw and Washer
8—
Air
Horn
9—
Needle
Seat Gasket
10—
Needle
Spring and Seat

11—Needle
Pin
12— Float Pin
13— Float
14— Gasket 15— Pump Spring
16— Metering Rod Arm
17— Pump
Link

18— Pump Spring Retainer
19— Vacuum Diaphragm Spring
20— Screw and washer
21— Diaphragm Housing
22— Diaphragm

23—Body

24— Gasket
25— Idle Port Plug
26— Throttle Body Lever and Shaft Assembly
27— Pump
Link
Connector
28— Throttle Shaft Arm 29— Screw and Washer
30— Throttle Valve
31— Throttle Valve Screw
32—
Fast
Idle Arm 33— Adjusting Screw
34— Body Flange Plug
35— Clevis
Clip

36— Idle Adjusting Screw
37— Idle Screw Spring
38—
Fast
Idle Connector Rod 39—
Pin
Spring
40—
Ball
Check Valve
41—
Ball
Check Valve Retainer Ring
42— Metering Rod Jet
43—
Low
Speed
Jet
44— Metering Rod
45— Metering Rod Spring 46—
Inner
Pump Spring
47— Pump Spring Retainer
48—
Bracket
and Clamp Assembly (Choke and Throttle) 5^—31 | 1X892
117

E

FUEL
SYSTEM
Note:
Do not remove pressed-in parts such as
nozzle, pump jet, or antipercolator air bleed.

j.
Remove body flange attaching screws, body flange assembly, and gasket.

k.
Remove idle-adjustment screw, spring, idle

port
rivet, throttle lever assembly, washer, fast
idle arm, throttle plate screws, throttle plate, and throttle shaft.
1. Remove throttle shaft seal by prying out seal

retainer.

Note:
Do not remove pressed-in vacuum passage

orifice.

m.
Remove choke valve screws and choke valve.

Unhook
choke spring and slide shaft from housing,
n.
Wash all parts in carburetor cleaning solution

and
blow out passages with compressed air. Do not immerse diaphragm or seals in cleaning solution.

Inspect
all parts for wear or damage. Always use
new gaskets when reassembling.

E-22.
Carburetor
Reassembly

•
Refer to Fig. E-13.

To
expedite
reassembly, it is advisable to group all

related
parts by the circuit to which they belong.

a.
Install
throttle shaft seal and retainer in flange casting.

b.
Install
fast-idle
arm,
washer, and lever assembly
on throttle shaft. Slide shaft into place and install throttle valve.

c.
Install
idle port rivet plug and idle adjusting

screw
and spring.

d.
Attach flange assembly to body casting. Use new gasket.
e.
Install
low-speed jet assembly.
f.
Early
production models install pump intake
strainer
in pump diaphragm housing and carefully
press into recess.

Note:
If strainer is even slightly damaged, a new
one must be installed.
g.
Install
pump diaphragm assembly in diaphragm housing.
Then,
install pump diaphragm spring
(lower)
and retainer.

h.
Install
pump lifter
link,
metering rod
arm,
upper
pump spring, and retainer.

I.
Install
metering rod jet.

Note:
No gasket is used with this jet.

j.
Install
diaphragm housing attaching screws in
the diaphragm housing, making sure that the

edges
of the diaphragm are not wrinkled.
Lower

into place and tighten screws evenly and securely,
k.
Install
throttle shaft seal, dust seal washer, and
shaft seal spring.

I.
Install
pump connector
link
in the throttle arm
assembly.
Install
throttle shaft arm assembly on
throttle shaft guiding connector
link
in pump lifter

link
hole.
CAUTION:
Linkage
must not bind in any throttle
position. If binding occurs,
loosen
clamp screw in
throttle arm, adjust slightly, then retighten screw.

m.
Install
pump check disc, disc retainer, and lock

ring.

n.
Install
metering rod and pin spring. Connect
metering rod spring.
o.
Check
and if necessary correct meter ing rod adjustment. Follow procedure of
Par.
E-16.
p.
Install
needle
seat and gasket assembly, needle,
float
and
float pin. The
stop
shoulder on the float
pin
must be on the side away from the bore of
the carburetor.

q.
Set float level to specifications. Follow pro­ cedure of
Par.
E-12.

r.
Install
air horn gasket and air horn assembly.

Install
attaching screws, lock washers, and choke
tube clamp assembly. Tighten center screws first,
s. Slide choke shaft and lever assembly into place
and
connect choke lever
spring.
Install
choke valve.
Center
the valve by tapping lightly, then hold in
place with fingers when tightening screws,
t.
Install
fast-idle connector rod with
offset
portion
of rod on top and pin spring on outside.
Install
fast-idle connecting rod spring.

E-23.
Correcting Acceleration
Flat
Spot

Early
production
Carburetor
Models 938-S, 938-
SA,
938-SC

Inasmuch
as a flat
spot
on acceleration or low speed
stumble can
come
from causes other than
car­

buretor
malfunction, it is recommended that
engine

tuning be thoroughly checked before attempting
any
actual carburetor work. Make sure that
ignition, compression, and timing are correct and
that fuel pump is supplying enough gas. Also, the F-head
engine
employs a water-heated intake

manifold.
Proper vaporization of the fuel depends
on correct intake manifold temperature. Since this
temperature is controlled by the cooling system
thermostat, include an operational check of the
thermostat when diagnosing the stumble. Operating
temperatures consistently below
155°F.
can cause stumble.

If
the stumble persists, a
YF-938-S,
YF-938-SA,

or
YF-938-SC
carburetor can be converted to a
YF-938-SD
carburetor by installing Special Kit
924161, consisting of a pump discharge check
needle, a metering rod, and a metering rod jet. If this kit is installed, the pump discharge check

needle
replaces the original
ball,
weight, and re­

tainer
and the small wire-type retainer used with
the
ball
check assembly must not be reinstalled.

When
installing the kit, check the size of the pump discharge jet, No. 2, Fig. E-14.
Early
production
YF-938S
and
YF-938SA
carburetors have a .025" [0,635 mm.] jet installed. If the carburetor being
converted has a .025" jet it must be opened up to .031" [0,787 mm.] by running a No. 68
drill
through
the jet as shown in
Fig.
E-14.
The jet must be drilled
as it is a pressed in part and cannot be replaced.
Upon
completing the installation of the conversion

kit,
mark
or tag the carburetor to indicate that it
is a
YF-938SD.
118

'Jeep'
UNIVERSAL
SERIES SERVICE
MANUAL

E

FIG.
E-14—DRILLING CARBURETOR JET 1—
Drill
(#68 size)

2—
Accelerator
Pump Discharge Jet
E-24.
Steep-Grade
Carburetor
Kit

In
the
field
where a vehicle equipped
with
Carter carburetor 938-S is required to
idle
on
steep

slopes,
flooding
of the carburetor sometimes results.

A
steep-grade
carburetor kit is available that
will

allow satisfactory
idle
operation under this condi­

tion.
This kit (Part
No.
#94481,
Carter # 75-960U)
contains a metering rod, a metering rod jet, and a
plug.

To
install
this kit, replace the standard metering

rod
and metering rod jet
with
those
contained in the
kit.
Place the small
brass
plug
in the accelerator
pump
well.
Exert
finger pressure only when in­

stalling
this
plug.
Forcing the
plug
in too far
will
damage
the accelerator
jet.
Make certain the meter­

ing
rod and
float
level
are set to specifications.

When
reworking
the carburetor to include this
steep-grade
kit, check to determine if the seal (Carter #121-172) and retainer (Carter #136-152)
are installed. If
these
parts are not present, they

should
be installed.
FIG.
E-15—CARBURETOR-
DAUNTLESS V-6 ENGINE 1—
Fuel
Inlet

2—
Choke

3—
Choke
Cable
Bracket

4—
Idle
Speed Adjusting Screw 5—
Idle
Fuel-air
Mixture Screws
E-25.
CARBURETOR
—
DAUNTLESS
V-6

ENGINE

A
double-barrel, manual choke, down-draft car­
buretor (Fig. E-15) is used on the Dauntless V-6 engine.
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.

The carburetor
fuel
bowl
is located
forward
of
the main bores. The carburetor is compact in design

in
that all of the
fuel
metering is centrally located.
See Fig. E 16.

This
carburetor
uses
a calibrated cluster design

with
main
well
tubes,
idle
tubes, mixture
passages,
air
bleeds and pump jets in one removable as­

sembly.
This cluster assembly can be easily re­

moved
for cleaning and inspection purposes. It is

mounted
on a
flat
portion
of the carburetor
bowl

in
front
of the main
venturi.
The
idle
and main

well
tubes
are precision
pressed
fit in the cluster
body.
They cannot be serviced separately. The

main
nozzles and
idle
tubes
are
suspended
in the
main
wells of the
float
bowl.

The main metering jets are of the
fixed
type. A
system of calibrated air bleeds gives correct
fuel-

air
mixture throughout all operational
ranges.
This
carburetor has a vacuum-operated power sys­

tem
which
supplies extra
fuel
when needed. Power
mixtures
are regulated by drop in engine
manifold
vacuum,
regardless of throttle opening. Thus, addi­

tional
fuel
is supplied for power mixtures accord­

ing
to engine demands.
The accelerator pump plunger has a vapor vent

ball
in its head. This
ball
and its
seat
form
a valve

to
vent any
fuel
vapors
which
form
in the pump

well
to the
fuel
bowl
during hot-engine operation.
This
ensures
that the pump
well
and
passages
will

be primed
with
solid
fuel
at all times and im­ proves accelerator pump action. The carburetor is
internally
vented through a hole

in
the air horn.
FIG.
E-16—FUEL BOWL BODY—TOP VIEW
1— Pump Return Spring 3—Power
Valve
2—
Main
Metering
Jets
4—Cluster Assembly
119

'Jeep'
UNIVERSAL SERIES SERVICE
MANUAL

FIG.
E-19—
MAIN
METERING SYSTEM
1—
Main
Nozzle
2—
Mixture
Passage

3—
Boost
Venturi

4—
Main
Venturi

5—
Throttle
Valve 6—
Main
Metering Jet
7—
Main
Well
Insert
8—
Main
Well
Tube
9—
Main
Well
Air Bleed fuel through calibrated
holes
in the main well tube.

Fuel-air
mixture then
moves
upward into a channel
where another calibrated amount of air is injected through the main air bleed. It then flows down­

ward
through the channel to the venturi, where it is discharged into the air stream, and then to the
intake manifold.

E-29.
Power System

A
vacuum-operated power piston in the air horn
and
a power valve in the
bottom
of the float bowl

enrich
fuel-air mixture when more power is desired.

This
system also operates during extreme high
speed driving. Through a vacuum passage from the
carburetor
base to the power cylinder, the power
piston is
exposed
to manifold vacuum. See Fig.

E-20.

During
idle and part throttle operation, relatively
high vacuum holds the power piston in upward
FIG.
E-20—POWER
SYSTEM
position against spring tension so that the power
valve remains closed.

Increase
in
engine
load decreases manifold vacuum.

When
vacuum decreases sufficiently, the spring
overcomes vacuum and the power piston
moves
downward.
This
opens
the power valve to allow
additional fuel to flow through calibrated restric­
tions into the main well.

As
the
engine
load decreases, resulting higher

vacuum
overcomes spring tension on the power
piston and draws the power piston upward.
This

closes
the power valve.

This
carburetor has a
two-stage
power valve. In
the first
stage,
fuel is metered by the valve itself.
This
stage
occurs under light load. During heavy

load,
the valve is fully opened to the second
stage;

in
this position, the power valve supplies fuel to
be metered by power restrictions in the fuel chan­

nel
to the fuel bowl.

The
power piston cavity is connected to the main

air
flow passage by a vacuum relief passage.
This
passage prevents transfer of vacuum to fuel in the
float bowl. Any leakage of air past the piston
will

be compensated for by this relief passage; hence it

will
not affect carburetor metering.

E-30.
Accelerator Pump System

When
the throttle valve
opens
rapidly, air flow

and
manifold vacuum change almost instantaneous­

ly.
However, heavier fuel-air mixture
does
not flow immediately.
Thus,
momentarily, the
engine
does

not have sufficient fuel. The accelerator pump pro­ vides additional fuel necessary for
engine
operation

during
acceleration.

A
double-spring loaded pump plunger supplies fuel for acceleration. Top and
bottom
springs
move
the
plunger to furnish a smooth, sustained charge of
fuel for acceleration. See Fig. E-21.

Fuel
is drawn into the pump well past the inlet
check ball during the plunger intake (upward)
stroke.
Downward
motion of the pump plunger
seats
the
inlet check ball and forces fuel through the dis­ charge
passage.
This
unseats
the pump discharge
check
ball.
Fuel
then sprays through the discharge
12837

FIG.
E-21—ACCELERATOR
PUMP
SYSTEM

1— Piston Vacuum Chamber
2—
Vacuus*
Relief Passage

3—
Main
Well

4— ^Power Restrictions 5— Power Valve
6— Power Piston Spring 7— Power Piston 1— Pump
Jets

2—
Discharge
Check
Ball

3—
Discharge
Passage
4—
Inlet
Check
Ball
5—
Inlet
Screen
6—
Vapor
Vent
Check
Ball

7—
Pump
Plunger
121

E

FUEL
SYSTEM
port into the venturi.

The
check
ball
in the pump plunger head is a vapor
vent for the pump well. Without this vent, vapor
pressure in the pump would force fuel from the
pump system into the
engine
manifold, causing

hard
starting when the
engine
is hot.
There
is another
hole
in the pump lever, into which
the accelerator pump rod can be inserted to pro­ vide quicker pump action.
This
adjustment setting
is used only in extreme cold temperature condi­ tions. The pump discharge check
ball
in the dis­
charge passage prevents discharge of fuel from the
pump nozzles when the accelerator pump is in­
operative.

E-31.
Choke System

The
choke system consists of a manually-operated
choke valve, a fast-idle connecting rod, and a fast-
idle arm. The choke valve is offset-spring loaded
to prevent over-choking during the starting
warm-
up period. When the choke valve is moved to a
closed position for starting, the fast idle connector

rod
revolves the fast idle
link.
This
action increases
the
engine
idle speed to prevent stalling during the

warm-up
period. A fast-idle connector rod return
spring
prevents
partial
closing of the choke valve.

E-32.
Carburetor
Removal

a.
Remove attaching wing nut and air cleaner from
carburetor.

b. Remove throttle cable from
ball
stud on throttle
lever adapter.

c.
Disconnect fuel line from carburetor inlet fitting.

d.
Disconnect positive crankcase ventilator
hose
from
nipple on carburetor body.
e. Disconnect distributor vacuum line from throttle body of carburetor.
f. Remove four attaching cap screws, carburetor,
and
gasket from intake manifold.

E-33.
Air
Horn
Body Removal and Disassembly

a.
Remove attaching screws, and carefully lift air
horn
body upward to remove from fuel bowl body.
b. Place air horn body in inverted position on
bench. Remove float hinge pin and lift float as­ sembly from cover. Remove inlet valve
needle
from
float arm. Remove
needle
seat, fiber gasket

and
seat screen from air horn body; discard gasket. See Fig. E-22.

c.
Depress shaft and allow spring to snap re­ peatedly to remove power piston from air horn body.
This
will
force power piston retaining washer

from
air horn body.

d.
Remove retainer from end of accelerator pump
plunger shaft. Remove pump assembly from pump

inner
arm. Loosen set screw on inner arm and re­

move
outer lever and shaft from plunger. Remove gasket from air horn body or fuel bowl body and

discard.

e. Remove two retaining screws and choke valve plate from choke shaft. Withdraw choke shaft from
air
horn body. Remove choke lever and collar from
choke shaft.
Note
position of choke lever in relation
12856
FIG.
E-22—AIR HORN BODY

1
—
Float

2— Power Piston
3—
Pump
Plunger
4—
Choke
Valve to choke trip lever at end of the choke shaft for

ease
in reassembly.

E-34.
Fuel
Bowl Body Disassembly

a.
Remove return spring of pump plunger and pump well from fuel bowl body. Remove small

aluminum
check
ball
from
bottom
of pump well
by inverting fuel bowl body and shaking into hand. Remove pump inlet screen from
bottom
of fuel bowl.
b. Remove main metering jets from fuel bowl body
using Tool C-3748.

c.
Remove power valve and fiber gasket from fuel bowl body; discard gasket.

d.
Remove three attaching screws, venturi cluster
assembly, and gasket from fuel bowl body. Center
screw has smooth shank and fiber gasket for the accelerator pump fuel bypass and seal.
e. Using a
pair
of long nosed pliers, remove T-
shaped retainer, accelerator pump discharge spring

and
steel discharge
ball
from fuel bowl body.
f. Remove two inserts from main well.

E-35.
Throttle Body Removal and Disassembly

a.
Invert
fuel bowl body; remove three attaching
screws,
throttle body and gasket; discard gasket.
b. Remove idle mixture adjustment
needles
and
springs from throttle body.

Note:
No further disassembly of the throttle body
is required. The throttle valves should never be
removed, as the idle and
spark
holes
are drilled in
direct
relation to the location of the throttle valves

and
shaft. Removal of the throttle valves
will
upset
this alignment. The throttle body assembly is serv­ iced only as a complete assembly with throttle valves intact.

E-36.
Carburetor
Cleaning and Inspection
Dirt,
gum, water, or carbon contamination on the 122