1977 DATSUN PICK-UP ESP
[x] Cancel search: ESPPage 98 of 537
Engine
Fuel
AUTOMATIC
TEMPERATURE
CONTROL
A
T
C
AIR
CLEANER
DESCRIPTION
OPERATION
A
T
C
AIR
CLEANER
HOT
AIR
OPERATION
A
T
C
AIR
CLEANER
COLD
AIR
OPERATION
A
T
C
AIR
CLEANER
COLD
AND
HOT
AIR
OPERATION
TEMPERATURE
SENSOR
DESCRIPTION
The
air
cleaner
removes
dust
and
dirt
from
the
air
before
it
enters
the
carburetor
and
engine
It
also
muffles
noise
resulting
from
the
intake
of
air
into
the
engine
The
air
cleaner
especially
designed
for
improved
exhaust
emission
control
is
referred
to
as
Automatic
Tempera
ture
Control
Air
Cleaner
In
order
to
reduce
HC
emission
when
the
under
hood
temperature
is
below
300C
860F
the
automatic
temperature
control
system
maintains
the
tempera
ture
of
air
to
be
sucked
in
the
carbure
tor
at
30
to
540C
86
to
1290F
thereby
enabling
lean
setting
for
carburetor
calibration
n
addition
to
this
the
automatic
temperature
con
twl
system
is
effective
to
improve
warm
up
characteristics
of
the
engine
CONTENTS
EF
2
EF
3
VACUUM
MOTOR
AND
AIR
CONTROL
VALVE
REMOVAL
AND
INSTALLATION
TEMPERATURE
SENSOR
VACUUM
MOTOR
FRESH
AIR
DUCT
AIR
CLEANER
INSPECTION
1
AIR
CLEANER
ELEMENT
2
HOT
AIR
CONTROL
SYSTEM
EF
3
EF
4
EF
4
EF
5
and
to
remove
carburetor
icing
The
A
T
C
air
cleaner
system
con
sists
of
the
following
devices
1
Air
cleaner
element
The
air
cleaner
element
employed
is
a
viscous
paper
type
It
requires
only
periodical
replacment
and
should
not
be
cleaned
2
Automatic
temperature
control
air
cleaner
In
the
A
T
C
air
cleaner
the
air
control
valve
is
actuated
by
intake
manifold
vacuum
to
control
the
intake
air
flow
circuit
The
temperature
sen
sor
detects
the
temperature
inside
the
air
cleaner
and
opens
or
closes
the
vacuum
passage
3
Hot
air
duct
The
hot
air
duct
is
mounted
on
the
exhaust
manifold
The
air
warmed
up
EF
2
EF
5
EF
5
EF
5
EF
5
EF
5
EF
6
EF
6
EF
6
EF
6
between
the
exhaust
manifold
and
hot
air
duct
is
led
to
the
air
cleaner
through
the
hose
4
Blow
by
gas
filter
The
blow
by
gas
nIter
removes
dirt
and
oil
from
the
blow
by
gas
sucked
in
the
air
cleaner
from
the
engine
rocker
cover
5
Fresh
air
duct
Except
for
Canada
The
fresh
air
duct
leads
the
outside
fresh
air
directly
to
the
air
cleaner
6
Idle
compensator
See
paragraph
Idle
Compensator
Page
EF
7
7
Altitude
compensator
California
models
See
paragraph
Altitude
Compensa
tor
Page
EF
20
Page 100 of 537
Underhood
air
I
@
Dr
Underhood
air
I
Engine
Fuel
f
f
l
l
ID
s
6
Cif
Ittl
ID
Air
inlet
pipe
Air
con
trol
valve
Hot
air
pipe
Diaphragm
Vacuum
hose
Diaphragm
spring
Air
bleed
valve
closed
Temperature
sensor
assembly
Holair
EF114
Fig
EF
2
Hota
r
delivery
mode
During
cold
engine
operation
7
To
manifold
Small
vacuum
1
Air
inlet
pipe
2
Air
con
trol
valw
3
Hot
air
pipe
4
Diaphnp
S
V
leuum
hoses
6
Diaphragm
prinl
7
Air
bleed
valve
closed
II
Temperature
senSOr
assembly
EF20S
Fig
EF
3
Cold
air
delivery
mode
During
cold
engine
operation
f
1
J
liP
omanifold
2
@
Air
inlet
pipe
Air
control
valve
Hot
air
pipe
Diaphragm
Vacuum
hoses
Diaphragm
spring
Air
bleed
valve
fully
open
8
Temperature
sensor
assembly
EF715
Fig
EF
4
Cold
air
delivery
mode
During
hot
engine
operation
ID
@
f
fjr
R
lfl
ow
2
underh
r
5
rv
Itti
ID
Hot
air
Air
inlet
pipe
Air
control
valve
Hot
air
pipe
Diaphragm
Vacuum
hose
Diaphragm
spring
Air
bleed
valve
partially
opened
8
Temperature
sensor
assembly
EF716
Fig
EF
5
Regulating
air
delivery
mode
EF
4
A
T
C
AIR
CLEANER
COLD
AIR
OPERATION
I
When
under
hood
air
temperature
is
low
The
sensor
air
bleed
valve
remains
in
the
closed
position
and
vacuum
passage
is
established
between
the
in
take
manifold
and
the
vacuum
motor
and
the
intake
manifold
vacuum
is
applied
to
the
vacuum
motor
dia
phragm
When
the
vacuum
is
small
or
when
the
engine
is
operating
under
eavy
1004
the
air
control
valve
opens
widely
irrespective
of
the
temperature
around
the
sensor
to
introduce
the
under
hood
air
cold
air
for
increased
power
of
the
engine
2
When
under
hood
air
temperature
is
high
The
sensor
air
bleed
valve
opens
fully
to
shut
off
the
vacuum
passage
between
the
intake
manifold
and
the
vacuum
motor
Due
to
the
force
of
the
vacuum
motor
diaphragm
spring
the
air
control
valve
closes
the
hot
air
pipe
of
the
air
cleaner
and
introduces
the
under
hood
air
cold
air
A
T
C
AIR
CLEANER
COLD
AND
HOT
AIR
OPERATION
When
the
sensor
air
bleed
valve
is
partially
opened
opening
of
the
air
control
valve
varies
with
the
vacuum
of
the
intake
manifold
With
the
air
control
valve
half
open
the
cold
air
and
hot
air
are
sucked
together
and
mixed
for
controlling
of
the
air
tem
perature
of
the
air
to
be
introduced
to
the
air
cleaner
Page 101 of 537
TEMPERATURE
SENSOR
The
temperature
sensor
is
attached
to
the
inside
of
the
air
cleaner
The
bimetal
built
in
the
sensor
detects
the
under
hood
air
temperature
and
opens
or
closes
the
vacuum
passage
in
the
sensor
The
construction
of
the
tempera
ture
sensor
is
shown
in
the
following
CD
V
00
@
I
I
@
j
I
I
1
Protector
cover
Screw
Adjusting
frame
Air
temperature
bi
metal
Rivet
Valve
seat
frame
Lower
frame
Air
bleed
valve
Gasket
Fig
EF
6
Temperature
senior
EF206
VACUUM
MOTOR
AND
AIR
CONTROL
VALVE
The
vacuum
pressure
which
varies
with
opening
of
the
carburetor
throt
tle
acts
upon
the
vacuum
motor
dia
phragm
The
valve
shaft
attached
to
the
diaphragm
is
then
moved
up
or
down
in
response
to
the
vacuum
on
the
diaphragm
This
movement
of
the
valve
shaft
actuates
the
air
control
valve
to
control
the
temperature
of
the
air
to
be
introduced
into
the
air
cleaner
pr
to
I
1
Valve
spring
00
2
Diaphragm
@
3
Retainer
E
F
207
4
Valve
shaft
Fig
EF
7
Vacuum
motor
REMOVAL
AND
INSTALLATION
TEMPERATURE
SENSOR
Removal
Using
pliers
flatten
clip
con
Engine
Fuel
neeting
vacuum
hose
to
sensor
vacuum
tube
I
Pipe
2
Calch
3
Fixed
with
adhesive
4
Hose
5
Tab
6
Clip
7
Gasket
EC019
Fig
EF
B
Removal
of
semor
2
Disconnect
hose
from
sensor
3
Take
off
clip
from
sensor
vacuum
tube
and
dismount
sensor
body
from
air
cleaner
Note
The
gasket
between
sensor
and
air
cleaner
is
bonded
to
the
air
cleaner
side
and
should
not
be
removed
Inatallatlon
Mount
sensor
on
the
specified
position
For
mounting
position
of
sensor
see
the
following
EF717
Fig
EF
9
lalling
se
or
2
Insert
clip
into
vacuum
tube
of
sensor
After
installing
each
vacuum
hose
secure
hose
with
the
clip
Note
Be
sure
to
install
vacuum
hose
correctly
Correct
position
is
R
H
side
to
Nissan
mark
at
the
top
face
of
sensor
for
intake
manifold
L
H
side
for
vacuum
motor
VACUUM
MOTOR
1
Remove
screws
securing
vacuum
motor
to
air
cleaner
2
Disconnect
valve
shaft
attached
to
vacuum
motor
diapluagm
from
air
control
valve
and
remove
cacuum
motor
assembly
from
air
cleaner
3
To
install
reverse
the
removal
procedure
FRESH
AIR
DUCT
I
Disconnect
fresh
air
duct
at
air
cleaner
2
Fresh
air
duct
is
provided
with
projections
on
its
air
inlet
side
end
Hold
fresh
air
duct
with
a
hand
and
carefully
pull
out
from
radiator
core
support
while
turning
it
in
either
direction
3
To
install
reverse
the
removal
procedure
Be
sure
to
insert
projec
lions
of
fresh
air
duct
securely
into
mounting
hole
in
radiator
core
sup
port
EF518
EF
5
Fresh
air
duct
Air
cleaner
Duct
mounting
hole
Radiator
Radiator
core
support
Fig
EF
I0
Removal
of
fresh
air
duct
Page 103 of 537
to
facilitate
smooth
operation
of
air
control
valve
If
the
above
test
reveals
any
prob
lem
in
the
operation
of
air
control
valve
carry
out
the
following
test
4
Remove
air
cleaner
cover
Set
temperature
sensing
element
of
ther
mistor
or
thermometer
to
a
position
where
temperature
around
sensor
can
be
measured
In
this
case
fIx
wiring
of
thermistor
or
thermometer
on
the
bottom
surface
of
air
cleaner
with
adhesive
tape
in
such
a
manner
that
the
set
position
of
temperature
sensing
DESCRIPTION
OPERATION
DESCRIPTION
The
idle
compensator
is
basically
a
thermostatic
valve
which
functions
to
introduce
the
air
directly
from
the
air
cleaner
to
the
intake
manifold
to
compensate
for
abnormal
enrichment
of
mixture
in
high
idle
temperature
The
bi
metal
attached
to
the
idle
compensator
detects
the
temperature
of
intake
air
and
opens
or
closes
the
valve
Two
idle
compensators
having
different
temperature
characteristics
are
installed
one
opens
at
an
intake
air
temperature
of
60
to
700C
140
to
l580F
and
the
other
at
70
to
900C
158
to
1940F
OPERATION
The
construction
of
the
idle
com
pensator
is
shown
in
the
following
Engine
Fuel
element
will
not
be
affected
by
air
flow
Then
install
air
cleaner
cover
Fig
EF
13
Checking
temperature
sensor
IDLE
COMPENSATOR
CONTENTS
5
Carry
out
test
as
described
in
steps
I
2
and
3
above
When
air
control
valve
begins
to
open
to
under
hood
air
inlet
side
several
minutes
after
engine
starting
read
the
indica
tion
of
thermistor
or
thermometer
If
reading
falls
within
the
working
tern
perature
range
of
temperature
sensor
the
sensor
is
normal
If
reading
ex
ceeds
the
range
replace
the
sensor
with
new
one
Note
Before
replacing
temperature
sensor
check
idle
compensator
as
described
in
Idle
compensator
EF
7
EF
7
REMOVAL
AND
INSTALLATION
INSPECTION
EF
B
EF
8
q
EF222
1
Orifice
2
Bi
metal
3
Rubber
valve
Fig
EF
14
Structure
of
idle
compensator
Bi
metal
Intake
air
temperature
No
1
Below
600C
1400F
60
to
70
C
140
to
l580F
Above
700C
158
OF
Below
700C
1580F
70
to
900C
158
to
1940F
Above
900C
1940F
No
2
EF
7
The
idle
compensator
operates
in
response
to
the
under
hood
air
temper
ature
as
shown
below
Idle
compensator
operation
Fully
closed
Close
to
open
Fully
open
Fully
closed
Close
to
open
Fully
open
Page 113 of 537
Step
system
The
construction
of
this
system
may
correspond
to
the
idling
and
slow
system
of
the
primary
system
Tlris
system
aims
at
the
proper
filling
up
of
the
gap
when
fuel
supply
is
transferred
from
the
primary
system
to
the
secondary
one
The
step
port
is
located
near
the
secondary
throttle
valve
edge
in
its
fully
closed
state
Secondary
switchover
mechanism
The
secondary
throttle
valve
is
linked
to
the
diaphragm
which
is
actuated
by
the
vacuum
created
in
the
venturi
A
vacuum
jet
is
provided
at
each
of
the
primary
and
secondary
venturies
and
the
composite
vacuum
of
these
jets
actuates
the
diaphragm
As
the
linkage
causes
the
secondary
throttle
valve
to
close
until
the
prima
ry
throttle
valve
opening
reaches
ap
proximately
500
fuel
consumption
during
normal
operation
is
not
exces
sive
During
high
speed
running
as
shown
in
Figure
EF
28
as
the
vacuum
at
the
venturi
is
increased
the
dia
phragm
is
pulled
against
the
diaphragm
spring
force
and
then
secondary
throt
tie
valve
is
opened
The
other
side
during
low
speed
running
as
the
primary
throttle
valve
opening
does
not
reach
500
the
secondary
throttle
valve
is
locked
to
close
completely
by
the
locking
arm
which
is
interlocked
with
primary
throttle
arm
by
linkage
When
the
primary
throttle
valve
opening
reaches
wider
position
than
500
the
secondary
throttle
valve
is
ready
to
open
because
the
locking
arm
revolves
and
leaves
from
the
se
condary
throttle
arm
Engine
Fuel
HI
h
speed
circuit
The
high
speed
circuit
improves
high
engine
output
performance
during
high
speed
driving
This
circuit
operates
only
when
driving
at
high
speed
It
consists
of
a
richer
jet
high
speed
enricher
air
bleed
and
richer
nozzle
When
the
velocity
of
suction
air
flowing
through
the
carburetor
secondary
bore
in
creases
additional
fuel
is
drawn
out
of
the
richer
nozzle
@
2
EF234
Secondary
I
Richer
jet
2
High
speed
enricher
air
bleed
3
Richer
nozzle
Primary
Fig
EF
29
High
speed
circuit
ANTI
DIESELlNG
SYSTEM
is
brought
into
operation
shutting
off
the
supply
of
fuel
to
the
slow
circuit
The
following
figure
shows
a
see
tiorial
view
of
this
control
The
carburetor
is
equipped
with
an
anti
dieseling
solenoid
valve
As
the
ignition
switch
is
turned
off
the
valve
EF230
@
l
CD
1
1
g
@eI
1
Anti
dieseling
solenoid
va1
2
Ignition
switch
3
Battery
Fig
EF
30
Schematic
drawing
of
anti
dieseling
sydtm
EF
17
Page 116 of 537
ELECTRIC
AUTOMATIC
CHOKE
An
electric
heater
wanns
a
bi
metal
interconnected
to
the
choke
valve
and
controls
the
position
of
choke
valve
and
throttle
valve
in
accordance
with
the
time
elapsed
the
warm
up
condi
tion
of
the
engine
and
the
outside
ambient
temperature
When
outside
ambient
temperature
is
above
operating
temperature
the
automatic
choke
control
serves
to
fur
ther
reduce
exhaust
gasemission
during
warm
up
by
automatically
selecting
one
of
the
two
choke
opera
tion
modes
fast
acting
or
slow
acting
Slow
acting
choke
operation
When
ambient
temperature
is
low
electric
current
flows
through
the
automatic
choke
relay
to
the
P
T
C
heater
A
and
gradually
warms
the
bi
metal
This
causes
the
choke
valve
to
open
slowly
Fast
acting
choke
operation
When
ambient
temperature
is
high
the
bi
metal
switch
is
in
on
This
causes
electric
current
to
flow
through
the
automatic
choke
relay
to
the
P
T
C
heater
A
and
heater
B
result
ing
in
quick
opening
of
the
choke
valve
r
@@
r
@
Engine
Fuel
The
construction
and
function
of
each
part
of
this
carburetor
are
as
follows
l
Bi
metal
and
heater
in
choke
cover
Electric
current
flows
through
the
ttea
r
as
t
le
engine
tl
1
SI
nd
war
the
bi
metal
The
deflection
of
the
bi
metal
is
transmitted
to
the
choke
valve
through
the
choke
yalve
lever
2
Fast
idle
cam
The
fast
idle
cam
determines
the
opening
of
the
throttle
valve
so
that
the
proper
amount
of
mixture
cor
responding
to
the
opening
of
the
choke
valve
will
be
obtained
The
opening
of
the
choke
valve
is
depend
ent
upon
the
warm
up
condition
of
the
engine
3
Fast
idle
adjusting
screw
This
screw
adjusts
the
opening
of
the
throttle
valve
of
the
fast
idle
earn
4
U
nloader
When
accelerating
the
engine
during
the
warm
up
period
that
is
before
the
choke
valve
opens
sufficiently
this
unloader
forces
the
choke
valve
open
a
liUle
so
as
to
obtain
an
adequate
air
fuel
mixture
5
Vacuum
diaphragm
After
the
enginThas
been
started
by
cranking
this
diaphragm
forces
the
choke
valve
open
to
the
predetermined
extent
so
as
to
provide
the
proper
air
fuel
ratio
6
Bi
metal
case
index
mark
The
bi
metal
case
index
mark
is
used
for
setting
the
moment
of
the
D
Il
EF232
1
Alternator
2
Automatic
choke
relay
3
Automatic
choke
cover
4
P
T
C
heater
A
5
Bi
metal
switch
6
P
T
C
heater
B
7
Bi
metal
8
Choke
valve
Fig
EF
33
Schematic
drawing
of
electric
automatic
choke
heater
EF
20
bi
metal
which
controls
the
air
fuel
mixture
ratio
required
for
starting
DASH
POT
SYSTEM
These
carburetors
are
equipped
with
a
dash
pot
interl
ked
wi
h
the
primary
throttle
valve
through
a
link
mechanism
The
dash
pot
is
intended
to
prevent
engine
stall
resulting
from
quick
application
of
the
brake
or
from
the
quick
release
of
the
accele
ra
tor
pedal
after
treading
it
slightly
In
such
a
situation
a
throttle
lever
strikes
against
the
dash
pot
stem
and
makes
the
primary
throttle
valve
close
gradually
thus
keeping
the
engine
running
ALTITUDE
COMPENSATOR
California
models
The
higher
the
altitude
the
richer
the
air
fuel
mixture
ratio
and
there
fore
the
higher
exhaust
gas
emissions
even
though
the
engine
is
properly
ad
justed
for
low
altitude
driving
The
altitude
compensator
is
design
ed
to
meet
EiiriSSion
S13ndards
for
driving
in
both
low
and
high
altitudes
At
high
altitudes
additional
air
is
sup
plied
to
the
carburetor
by
the
altitude
compensator
When
the
altitude
com
pensator
lever
is
set
at
H
air
is
conducted
through
an
air
passage
to
the
carburetor
The
air
passage
is
closed
when
the
lever
is
set
at
L
H
L
Lever
When
operating
the
H
L
lever
fol
low
these
instructions
H
position
Should
be
used
for
general
driving
in
those
areas
designated
by
law
as
High
Altitude
Counties
L
position
For
use
outside
those
areas
desig
nated
as
High
Altitude
Counties
Page 117 of 537
Notes
a
The
idle
rpm
and
CO
vary
accord
ing
to
the
altitude
Therefore
they
should
be
properly
adjusted
when
the
position
of
the
H
L
lever
is
changed
EF729
ADJUSTMENT
AND
INSPECTION
CARBURETOR
IDLE
R
P
M
AND
MIXTURE
RATIO
Cautions
3
On
automatic
transmission
equi
ped
models
check
should
be
per
formed
in
the
0
position
Be
sure
to
engage
parking
brake
and
to
lock
both
front
and
rear
wheels
with
wheel
chocks
b
Keep
your
foot
down
on
the
brake
pedal
while
depressing
the
accelera
tor
pedal
Otherwise
vehicle
surges
forward
dangerously
Notes
a
00
not
attempt
to
screw
the
idle
adjusting
screw
down
completely
Ooing
so
could
cause
damage
to
tip
which
in
turn
will
tend
to
cause
malfunctio11ll
b
If
idle
limiter
cap
obstructs
proper
adjustment
remove
it
To
install
idle
limiter
cap
refer
to
Idle
Limiter
Cap
c
After
idle
adjustment
has
been
made
shift
the
lever
to
the
N
or
P
position
for
automatic
trans
mission
d
When
measuring
CO
percentage
in
Engine
Fuel
b
Counties
1
219
m
4
000
ft
or
more
above
sea
level
have
been
designated
by
law
as
High
Altitude
Counties
For
further
details
refer
to
1977
OATSUN
PICK
UP
Service
Bulletin
Pub
No
257
0
I
Air
cleaner
rID
mOl
If
Low
altitude
Ll
n
n
L
n
Fig
EF
34
sert
probe
into
tail
pipe
more
than
40
em
15
7
in
CO
Idle
adjustment
with
CO
meter
Idle
mixture
adjustment
requires
the
use
of
a
CO
meter
especially
for
California
models
When
preparing
to
adjust
idle
mixture
it
is
essential
to
have
the
meter
thoroughly
warmed
up
and
calibrated
I
Check
carburetor
pipes
for
proper
connection
2
Warm
up
engine
until
water
tem
perature
indicator
points
to
the
middle
of
gauge
The
procedure
to
warm
up
engine
is
not
specifically
recom
mended
Either
driving
vehicle
or
oper
ating
engine
at
no
load
will
be
good
3
Make
sure
that
water
tempera
ture
indicator
points
to
the
middle
Further
keep
engine
running
at
about
2
000
rpm
for
about
5
minutes
with
out
applying
load
to
engine
in
order
to
stabilize
engine
condition
Engine
hood
should
be
open
4
Run
engine
for
about
10
minutes
at
idling
speed
Ouring
this
10
minutes
proceed
as
described
in
steps
5
to
9
below
5
Remove
air
hose
between
3
way
connector
5
way
connector
for
Cali
fornia
models
and
air
check
valve
as
EF
21
shown
in
Figure
EF
35
Plug
the
dis
connected
hose
to
prevent
dust
from
entering
0
o
EF259
Fig
EF
35
Disconnecting
air
hose
from
air
check
valve
6
Race
engine
I
500
to
2
000
rpm
two
or
three
times
under
no
load
then
run
engine
for
one
minute
at
idling
speed
7
Adjust
throttle
adjusting
screw
until
engine
is
at
specified
speed
Engine
speed
Manual
transmission
750
rpm
Automatic
transmission
in
0
position
650
rpm
8
Check
ignition
timing
If
neces
sary
adjust
it
to
specifications
This
operation
need
not
be
carried
out
at
1
600
Ian
1
000
miles
service
Ignition
timing
Manual
transmission
120
750
rpm
Non
California
100
750
rpm
California
Automatic
transmission
in
0
position
120
650
rpm
9
At
about
10
minutes
after
engine
is
run
at
idling
speed
adjust
idle
adjusting
screw
so
that
CO
percentage
is
at
specified
level
CO
percentage
Manual
transmission
2
t
l
at
750
rpm
Automatic
transmission
in
0
position
2
t
I
at
650
rpm
10
Repeat
procedures
as
described
in
steps
6
7
and
9
above
so
that
CO
percentage
is
at
specified
level
Check
ing
idle
CO
in
step
9
can
be
carried
out
right
after
step
7
II
Race
engine
1
500
to
2
000
Page 122 of 537
AUtomatic
trailamlsalon
modela
I
With
inhibitor
switch
ON
UN
or
P
position
check
for
presence
of
voltage
across
A
and
B
Refer
to
Figure
EF
51
If
voltmeter
ading
is
12
volts
d
c
B
C
D
O
circuit
is
func
tioning
properly
If
vol
tmeter
ading
is
zero
check
for
disconnected
connector
faulty
solenoid
valve
m
inhibitor
switch
2
With
inhibitor
switch
OFF
HI
2
IY
or
oR
position
Engine
Fuel
check
for
resistance
between
A
and
B
Refer
to
Figure
EF
51
If
ohmmeter
reading
is
25
ohms
or
below
circuit
is
functioning
prop
erly
If
ohmmeter
reading
is
32
ohms
or
above
check
for
poor
connection
of
connec
or
faulty
B
C
D
D
sole
noid
valve
or
inhibitor
relay
3
If
by
above
checks
faulty
part
or
unit
is
located
it
should
be
moved
and
tested
again
If
necessary
replace
yu
@
@
1
Ignition
key
2
Inhibit
T
switch
N
P
positions
ON
I
2
D
R
positions
OFF
3
D
C
D
D
solenoid
valve
4
Function
test
connector
5
Inhibitor
relay
EF712
Fig
EF
51
Checking
B
C
D
D
circuit
with
unction
t
st
connector
for
automatic
transmi
sion
Set
pressure
of
Boost
Controlled
Deceleration
Device
B
C
D
O
Generally
it
is
unnecessary
to
ad
just
the
B
CD
D
however
if
it
should
become
necessary
to
adjust
it
the
procedure
is
3S
follows
Prepare
the
foUowing
tool
I
Tachometer
to
measure
the
en
gine
speed
while
idling
and
a
screw
driver
2
A
vacuum
gauge
and
connecting
pipe
Note
A
quick
response
type
hoost
gauge
such
as
Bourdon
s
type
is
recommended
a
mercury
type
manometer
should
not
be
used
To
properly
set
the
B
C
D
D
set
pressure
proceed
as
follows
I
Remove
the
harness
of
solenoid
valve
To
B
D
D
solenoid
valve
1
B
C
D
D
olenoid
valve
harness
EF262
Fig
EF
52
Removing
harness
of
solenoid
valve
2
Connect
rubber
hose
between
vacuum
gauge
and
intake
manifold
as
shown
Fig
EF
53
Connecting
vacuum
gauge
EF
26
3
Warm
up
the
engine
until
it
is
heated
to
operating
temperature
Then
adjust
the
engine
at
nunnal
idling
setting
Refer
to
the
item
Idling
Adjustmenl
in
page
EF
21
Idling
engine
speed
Manual
transmission
750
rpm
Automatic
transmission
in
D
position
650
rpm
4
Run
the
engine
under
no
load
Increase
engine
speed
to
3
000
to
3
500
rpm
then
quickly
close
throttle
valve
5
At
the
time
the
manifold
vacuum
p
ssure
increases
abruptly
to
600
mmHg
23
62
inHg
or
above
and
then
graduaUy
decreases
to
the
level
set
at
idling
6
Check
that
the
B
C
D
D
set
pres
sure
is
within
the
specified
pressure
Specified
pressure
0
m
sea
level
and
760
mmHg
30
inHg
atmos
pheric
pressu
Manual
transmission
510
to
550
mmHg
20
1
to
21
7
inHg
Automatic
transmission
490
to
530
mmHg
19Tto
20
9
inHg
Notes
a
When
atmospheric
pressure
is
known
operating
pressure
will
be
found
by
tracing
the
arrow
line
A
See
Figure
EF
56
When
alti
tude
is
known
operating
pressure
will
be
found
by
tracing
the
arrow
line
B
See
Figu
EF
56
b
When
checking
the
set
pressu
of
B
CD
D
find
the
specified
set
pressu
in
Figure
EF
56
from
the
atmospheric
pressure
and
altitude
of
the
given
location
For
example
if
an
automatic
trans
mission
model
vehicle
is
located
at
an
altitude
of
1
000
m
3
280
ft
the
specified
set
p
ssu
for
B
C
D
D
is
445
mmHg
17
5
inHg
7
If
it
is
higher
than
the
set
level
turn
the
adjusting
screw
or
nut
until
correct
adjustment
is
made