Cessna_182_C182H 1965 Owners Manual Cessna 182 C182H

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THERE ARE MORE CESSNAS FLYING THAN ANY OTHER W.AKE

2L8_

I_
oW
MAN UAL
WORLDS LARGEST PRODUCER OF GENERAL AVIATION AIRCRAFT SINCE 1956

PERFORMANCE

-

SPECIFICATIONS

GROSS WEIGHT
SPEEft
Top Speed at Sea Level
Cruise
75% Power at 6500 ft.
RANGE:
Cruise
75% Power at 6500 ft.
60 Gallons, No Reserve
Cruise
75% Power at 6500 ft.
79 Gallons, No Reserve
Optimum Range at 10, 000 ft.
60 Gallons, No Reserve
Optimum Range at 10, 000 ft.
79 Gallons, No Reserve
RATE OF CLIMB AT SEA LEVEL
SERVICE CEILING
TAKE-OFF:
Ground Run
Total Distance Over
50-Foot Obstacle
LANDING:
Ground Roll
Total Distance Over
50- Foot Obstacle
EMPTY WEIGHT (Approximate)
BAGGAGE
WING LOADTNG Pounds/Sq Foot
POWER WADING: Pounds/HP.
FUEL CAPACITY: Total
Standard Tanks
Optional Long Range Tanks
OIL CAPACITY: Total
PROPELLER: Constant Speed (Diameter).
ENGINE: Continental Engine
230 rated HP at 2600 RPM

.

MODEL 182

SKYIJANE

2600 lbs

2800 lbs

167 mph
159 mph

170 mph
162 mph

685mi
4. 3 hrs
159 mph
BOSmi
5.7 hrs
159 mph
905m1
7. 6 hrs
119 mph
1190 ml
10. 0 hrs
119 mph
980 fpm
18, 900 ft

695 ml
4.3 hrs
162 mph
925 ml
5.7 hrs
162 mph
925 ml
7. 6 hrs
121 mph
1215 ml
10.0 hrs
121 mph
980 1pm
18, 900 ft

625ft

625 ft

12051t

1205 ft

590ft

590 ft

1350 ft
1550 lbs
120 lbs
16.1
12.2

1350 ft
1610 lbs
120 lbs
16. 1
12. 2

65ga1.
84gaL
l2qts
82 inches
O-470-R

65 gal.
84 gal.
l2qts
82 inches
O-470-R

CONGRATULATIONS

I
I

Welcome to the ranks of Cessna Owners! Your Cessna has been designed
and constructed to give you the most in performance, economy, and com
fort. It is our desire that you will find flying it, either for business or
pleasure, a pleasant and profitable experience.
This Owner’s Manual has been prepared as a guide to help you get the
most pleasure and utility from your Model 182/Skylane. It contains in
formation about your Cessna’s equipment, operating procedures, and
performance; and suggestions for its servicing and care. We urge you
to read it from cover to cover, and to refer to It frequently.
Our interest in your flying pleasure has not ceased with your purchase of
a Cessna. World-wide, the Cessna Dealer Organization backed by the
Cessna Service Department stands ready to serve you. The following
services are offered by most Cessna Dealers:
FACTORY TRMNED PERSONNEL to provide you with courteous
expert service.
FACTORY APPROVED SERVICE EQWPMENT to provide you
with the most efficient and accurate workmanship possible.
A STOCK OF GEMJTNE CESSNA SERVICE PARTh on hand
when you need them.
THE LATEST AUTHORITATIVE INFORMATION FOR SERV
ICING CESSNA AIRPLANES, since Cessna Dealers have all
of the Service Manuals and Parts Catalogs, kept current by
Service Letters and Service News Letters, published by Cessna
Aircraft Company.
We urge all Cessna owners to use the Cessna Dealer Organization to the
fullest.
A current Cessna Dealer Directory accompanies your new airplane. The
Directory is revised frequently, and a current copy can be obtained from
your Cessna Dealer. Make your Directory one of your cross-country
flight planning aids; a warm welcome awaits you at every Cessna Dealer.

I

TABLE OF CONTENTS
Page =

SECTION I

-

OPERATING CHECK LIST

SECTION II

-

DESCRIPTION AND

1-1

OPERATING DETAILS

2-1

OPERATING LIMITATIONS

3-1

SECTION IV- CARE OF THE AIRPLANE

4-1

SECTION III

-

OWNER FOLLOW-UP SYSTEM
SECTION V

4-8

OPERATIONAL DATA

5-1

SECTION VI- OPTIONAL SYSTEMS

6-1

-

ALPHABETICAL INDEX

Index-i

This manual describes the operation and performance of both
the Cessna Model 182 and the Cessna Skylane. Equipment
described as “Optional” denotes that the subject equipment
is optional on the Model 182. Much of this equipment is
standard on the Skylane model.

lii

‘ti-r

Section
OPERATING CHECK

‘I

is,

EXTERIOR
INSPECTION
DIAGRAM

NOTE
Chock general aircraft
condition during walk.
arneand inspection. If
night flight is planned,
chock operation of all
lights, and omits ear,
a Qashlight is available.

Se I

SI

(3)

C.

Tarn on master switch and check fuel
quantity indicatorsl then tarn master
switch “OFF.
Check iwiUtti switch “OFF.
Check fuel task selector nive handle on
“BoTh.”
Oi first flight of day and after each refu tl
ing, pull mat atridner drain knob for about
four seconds, to clear Suet strainer of pos
sible waler and sediment,
Remove control whoel lack.
Chock baggage door for security.

a.
b.

Remove rudder gust lock, If I tatailed.
nisconnect tail tie-don.

a.

b,

e.
d.

e,

()

a.
b.
c.
d.
C.

I.

a.

aii.
c.

Chock maio wheel tire for proper inflation.
Inspect airspeed static source hole on side
of fusetago for stoppage.
Disconnect wing tie-dosn.

b.

Check propeller and spinner for ricks ‘al
security, and propeller for oil leaks.
Make vimal chock in thsnsre that fuel stnir,er
tht valve Is closed after dnmtr.g operation.
Chock nose wheel strut and tin for proper
irliation.
Otaconnoct nose tic-down.
Check carbarctetr air filter for restrictions
by dust or other foreign mailer.
Check oil level. Do not operate with lean
than nine quarts. Fill for extended flight.
Remove pitot tube covor, It installed, and
check pitot tube opening for stoppage.
Check fuel taste vent opening for stoppage,
Aieo, check ftc! tank vent opening provided
in right wing when optional long range fuel
taste, are installed.

LIST

One of the first steps in obtaining the utmost performance, service,
and flying enjoyment from your Cessna is to familiarize yourself with your
airplane’s equipment, systems1 and controls. This can best be done by
reviewing this equipment while sitting in the airplane. Those items whose
function and operation are not obvious are covered in Section U.
Section I lists, in Pilot’s Check List form, the steps necessary to
operate your airplane efficiently and safely. It is not a check list in its
true form as it is considerably longer, but it does cover briefly all of the
points that you should know for a typical flight.
The flight and operational characteristics of your airplane are normal
in all respects. There are no ‘unconventional” characteristics or oper
ations that need to be mastered. All controls respond in the normal way
within the entire range of operation. All airspeeds mentioned in Sections
I and II are indicated airspeeds. Corresponding calibrated airspeeds
may be obtained from the Airspeed Correction Table in Section V.

BEFORE ENTERING THE AIRPLANE.
(1)

Make an exterior Inspection in accordance with figure 1-1.

BEFORE STARTING THE ENGINE.
(1) Seats and Seat Belts
Adjust and lock.
(2) Flight Controls
Check.
(3) Brakes
Test and set.
(4) Master Switch
“ON.’
(5) Cowl Flaps
‘OPEN.” (Move lever out of locking hole to
reposition.)
(6) Elevator and Rudder Trim
“TAKE-OFF’ setting.
(7) Fuel Selector Valve
“BOTH,”
(8) Turn all radio switches “OFF,’
-—

--

--

®

samoan®

——

--

--

Figure l—L

--

lv
1—1

1C:J.

STARTING ENGINE.
TAKE-OFF.

Cold.
(1) Carburetor Heat
Nch.
(2) Mixture
High RPM.
(3) Propeller
(4) Throttle-- Cracked (one-hall inch).
As required.
(5) Primer
“START.” Hold until engine fires, but not
(6) IgnitIon Switch
longer than 30 seconds.
Release to “BOTH” (immediately after engine
(7) Ignition Switch
fires).

133.
:‘

,

*

—-

- -

.:.
NORMAL TAKE-OFF.
(1) Wing Flaps-- Up.
Cold.
(2) carburetor Heat
Full throttle and 2600 RPM.
(3) Power
Raise nosewheel at 60 MPH.
(4) Elevator Control
90 MPH until all obstacles are cleared, then set
(5) Climb Speed
up climb speed as shown in “NORMAL CLIMB” paragraph.

--

--

--

--

—-

-—

-—

--

NOTE
If engine has been overprimed, start with throttle open
1/4 to 1/2 full open. Reduce throttle to idle when en
gine fires.
•

NOTE
After starting, check for oil pressure indication within
30 seconds in normal temperatures and 60 seconds in
cold temperatures. U no indicatIon appears, shut off
engine and Investigate.

BEFORE TAKE-OFF.

\

MAXIMUM PERFORMANCE TAKEOFF.
(1) Wing Flaps
20°.
Cold,
(2) carburetor Heat
(3) Brakes
Apply.
(4) Power
Full throttle and 2600 RPM.
Release.
(5) Brakes
Maintain slightly tail-low attitude.
(6) Elevator Control
60 MPH until all obstacles are cleared, then set
(7) Climb Speed
climb speed as shown In “MA4I PERFORMANCE CIB.”
(8) Wing Flaps
Up after obstacles are cleared.
;.

——

•.

-—

--

--

-—

--

--

—-

CUMB.
up

.•.

.

NORMAL CLIMB.
(1) Air Speed
100 to 120 MPH.
23 Inches and 2450 RPM.
(2) Power
(3) Mixture
Full rich (unless engine is rough due to excessively
rich mixture).
(4) Cowl Flaps
Open as required.
--

1700 RPM.
(1) Throttle SettIng
Check.
(2) Engine Instruments
Check operation, then set to cold unless
(3) Carburetor Heat
icing conditions prevail.
Check.
(4) Ammeter
Check (4. 5 inches of mercury desired, 3.75 to
(5) Suction Gage
5.0 acceptable).
Check (50 RPM maximum differential between
(6) Magnetos
magnetos).
Cycle from high to low RPM; return to high RPM
(7) Propeller
(full in).
Recheck.
(8) Flight Controls
Check operation and set 0° to 20°.
(9) Wing Flaps
(10) Cowl Flaps-- Full”OPEN.”
Recheck “TAKE-OFF” setting.
(11) Elevator and Rudder Trim
Cased and locked.
(12) Cabin Doors
Set.
(13) Flight Instruments and Radios
-

--

—-

—-

--

--

—-

-—

--

--

--

MAXIMUM PERFORMANCE CLIMB.
(1) Mr Speed
88 MPH (sea level) to 84 MPH (10,000 feet).
Full throttle and 2600 RPM.
(2) Power
(3) Mixture
Full rich (unless engine is rough).
(4) Cowl Flaps
Full “OPEN.”
-—

-

-

—-

--

CRUISING.

——

--

--

--

(1) Engine Power
15 to 23 inches of manifold pressure and 2200
2450 RPM.
Open as required.
(2) Cowl Flaps
(3) Elevator and Rudder Trim
Adjust.
(4) Mixture
Lean.
--

-

--

--

-—

1-2

1—3

LET-DOWN.
(1)
(2)
(3)

Rich.
Mixture
As desired.
Power
Apply (if icing conditions exist).
Carburetor Heat
-—

--

--

DESCRIPTION AND OPERATING DETAILS

BEFORE LANDING.
(1)
(2)
(3)
(4)
(5)
(6)
(7)
(8)
(9)

“BOTH”
Fuel Selector Valve
Rich.
Mixture
Propeller
High RPM.
Closed.
Cowl Flaps
Apply before closing throttle.
Carburetor Heat
80 to 90 MPH (flaps retracted).
Airspeed
00 to 40° (below 110 MPH).
Wing Flaps
70 to 80 MPH (flaps extended).
Airspeed
Adjust.
Elevator and Rudder Trim
--

The following paragraphs describe the systems and equipment
whose
function and operation is not obvious when sifting in the airplan
e. This
section also covers in somewhat greater detail some of the items
listed
In Check List form in Section I that require further explanation.

--

--

--

--

--

--

--

FUEL SYSTEM.

--

Fuel is supplied to the engine from two tanks, one in each
wing. The
total usable fuel, for all flight conditions is 60 gallons for
standard tanks
and 79 gallons for optional long range tanks.

NORMAL LANDINa
(1)

Landing Technique

--

Conventional for all flap settings.

NOTE

AFTER LANDING.

Unusable fuel Is at a minimum due to the design of the
fuel system. However, with 1/4 tank or less, prolon
ged
uncoordinated flight such as slips or skids can uncove
r
the fuel tank outlets, causing fuel starvation and engine
stoppage when operating on a single tank. Therefore,
to avoid this problem with low fuel reserves, the fuel
selector should be set at ‘BOTH” position.

“OPEN,”
(1) Cowl Flaps
Retract.
(2) Wing Flaps
Cold.
(3) Carburetor Heat
--

--

SECURE AIRCRAFT.
(1)

Mixture

—-

Fuel from each wing tank flows by gravity to a selector valve.
Depending
upon the setting of the selector valve, fuel from the left,
right, or both
tanks flows through a fuel strainer and carburetor to the engine
induction
system.

Idle cut-off (pulled full out).
NOTE

Do not open throttle as engine stops since this actuates
the accelerator pump.
Off.
(2) All Switches
Set.
(3) Brakes
installed.
(4) Control Lock
——

--

--

1-4

NOTE

I

I

Take off with the fuel selector valve handle in the “BOTH
”
position to prevent inadvertent take-oft on an empty
tank.
However, when the selector is in the “BOTH” position,
unequal fuel flow from each tank may occur after extend
ed
flight if the wings are not maintained exactly level.
Re—

:
suiting wing heaviness can be alleviated gradually by
turning the selector valve handle to the tank in the “heavy”
wThg. The recommended cruise fuel management pro
cedure for extended flight is to use the left and right tank
alternately.

RIGHT WING TANK

LEFT WING TANK

ELECTRICAL SYSTEM.
Electrical energy is supplied by a 14-volt, direct-current system
powered by an engine-driven alternator. The 12-volt battery is located
aft of the rear baggage compartment wail.
CIRCUIT BREAKERS.

FUEL SYSTEM
r SCHEMATIC I
TO ENGINES
FUEL
STRAINER

ENGINE PRIMER

6’
ql

•1

All electrical circuits in the airplane, except the clock circuit, are
protected by circuit breakers. The clock has a separate fuse mounted
adjacent to the battery. The stall warning transmitter and horn circuit
and the optional turn-and-bank indicator circuit are protected by a single
automatically resetting circuit breaker mounted behind the instrument
panel. The cigar lighter is protected by a manually reset type circuit
breaker mounted directly on the back of the lighter behind the instrument
panel. The remaining circuits are protected by “push-to-reset’ circuit
breakers on the instrument panel.
I

ROTATING BEACON (OPT)
The rotating beacon should not be used when flying through clouds
or overcast; the moving beams reflected from water droplets or particles
in the atmosphere, particularly at night, can produce vertigo and loss of
orientation.

THROTTLE

fl
CARBURETOR
—

MIKTURE
CONTROL KNOB

TO
ENGINE

Figure 2-1.

CABIN HEATING, VENTILATING AND
DEFROSTING SYSTEM.
The temperature and volume of airflow into the cabin can be regulated
to any degree desired by manipulation of the push-pull “CABIN HEAT” and
“CABIN AIR” knobs. Both control knobs are the double-button type with
friction locks to permit intermediate settings.
NOTE
Always pull out the “CABIM AIR” knob slightly when the

2—2
2—3

“CABIN HEAr’ knob Is cut. This action increases the
airflow through the system, increasing efficiency, and
blends cool outside air with the exhaust manifold heated
air, thus eliminating the possibility of overheating the
system ducting.

F

The rotary type “DEFROST” knob regulates the airflow for windshield
defrosting.
Front cabin heat and ventilating air is supplied by outlet holes spaced
across a cabin manifold just forward of the pilot’s and copilot’s feet. Rear
cabin heat and air is supplied by two ducts from the manifold, one extend
ing down each side of the cabin. Windshield defrost air is also supplied by
a duct leading from the cabin manifold.
Separate adjustable ventilators supply additional air; one near each
upper corner of the windshield supplies air for the pilot and copilot, and
two in the rear cabin ceiling supply air to the rear seat passengers.

STARTING ENGINE.
Ordinarily the engine starts easily with one or two strokes of the
primer in warm temperatures to six strokes in cold weather with the
throttle open approximately 1/2 inch. In extremely cold temperatures
it may be necessary to continue priming while cranking. Weak inter
mittent explosions followed by puffs of black smoke from the exhaust
stack indicate overpriming or flooding. Excess fuel can be cleared
from the combustion chambers by the following procedure: Set the mix
hire control full lean and the throttie full open; then crank the engine through
several revolutions with the starter. Repeat the starting procedure
without any additional priming.
U the engine is underprimed (most flicely in cold weather with a cold
engine) it will not fire at all. Additional priming will be necessary for the
next starting attempt.
As soon as the cylinders begin to fire, open the throttle slightly to
keep it running.
U prolonged cranking is necessary, allow the starter motor to cool
at frequent intervals, since excessive heat may damage the armature.
2—4

Figure 2-2.
2—5

TAXIING.
The carburetor air heat knob should be pushed full in during all ground
operations unless heat is absolutely necessary for smooth engine operation.
When the knob is pulled out to the heat position, air entering the engine is
not filtered.

plane to start rolling before high RPM is developed, and the gravel will be
blown back of the propeller rather than pulled into It.

Taxiing over loose gravel or cinders should be done at low engine
speed to avoid abrasion and stone damage to the propeller tips.

Most engine wear occurs from improper operation before the engine
is up to normal operating temperatures, and operating at high powers and
RPM’s. For this reason the use of maximum power for take-off should be
limited to that absolutely necessary for safety. Whenever possible, reduce
take-off power to normal climb power.

BEFORE TAKE-OFF.

Normal take-offs are accomplished with wing flaps up, cowl flaps
open, full throttle, and 2600 RPM. Reduce power to 23 inches of mani
fold pressure and 2450 RPM as soon as practical to minimize engine wear.

Since the engine is closely cowled for efficient in-flight cooling, pre
cautions should be taken to avoid overheating on the ground. Full throttle
checks on the ground are not recommended unless the pilot has good reason
to suspect that the engine is not turning up properly.
The magneto check should be made at 1700 RPM with the propeller
in flat pitch as follows: Move the ignition switch first to “R” position and
note RPM. Then move switch back to “BOTH” position to clear the other
set of plugs. Then move switch to “U’ position and note RPM. The dif
ference between the two magnetos operated singly should not be more than
50 RPM. if there is a doubt concerning the operation of the ignition sys
tem, RPM checks at a higher engine speed will usually confirm whether
a deficiency exists.
An absence of RPM drop may be an indication of faulty grounding of
one side of the ignition system or should be cause for suspicion that the
magneto timing has been “bumped-up” and is set in advance of the setting
specified.

Using 20° wing flaps reduces the ground run and total distance over
the obstacle by approximately 20 per cent. Soft field take-offs are per
formed with 20° flaps by lifting the airplane off the ground as soon as
practical in a slightly tail-low attitude. However, the airplane should
be leveled off immediately to accelerate to a safe climb speed.
if 20° wing flaps are used for take-off, they should be left down until
all obstacles are cleared. To clear an obstacle with wing flaps 20 degrees,
the best angle-of-climb speed (60 MPH, LAS) should be used. if no ob
structions are ahead, a best “flaps up” rate-of-climb speed (90 MPH, LAS)
would be most efficient. These speeds vary slightly with altitude, butthey
are close enough for average field elevations.
Flap deflections of 30° to 40° are not recommended at any time for
take—off.

TAKE-OFF.

Take-offs into strong crosswinds normally are performed with the
minimum flap setting necessary for the field length, to minimize the drift
angle immediately after take-off. The airplane is accelerated to a speed
slightly higher than normal, then pulled off abruptly to prevent possible
settling back to the nmway while drifting. When clear of the ground, make
a coordinated turn into the wind to correct for drift.

It is important to check full-throttle engine operation early in the take
off run. Any signs of rough engine operation or sluggish engine accelera
Uon is good cause for discontinuing the take-off.

CLIMB.

Full throttle runups over loose gravel are especially harmful to
propeller tips. when take-offs must be made over a gravel surface, it is
very important that the throttle be advanced slowly. This allows the air2—6

A cruising climb at 23 inches of manifold pressure, 2450 RPM (ap
proximately 75% power) and 100 to 120 MPH is recommended to save time
and fuel for the overall trip. In addition, this type of climb provides bet
ter engine cooling, less engine wear, and more passenger comfort due to

-

lower noise level.
if it is necessary to climb rapidly to clear mountains or reach favor
able winds at high altitudes, the best rate-of-climb speed should be used
with maximum power. This speed is 88 MPH at sea level, decreasing
2 MPH for each 5000 feet above sea level.
If an obstruction ahead requires a steep climb angle, the airplane
should be flown at the best angle of climb with flaps up and maximum
power. This speed is 70 MPH.
In a balked landing (go-around) climb, the wing flap setting should be
reduced to 200 immediately after fun power is applied. Alter all
obstacles are cleared and a safe altitude and airspeed are obtained, the
wing flaps should be retracted.

CRUISE.
Normal cruising is done between 65% and 75% power. The power
settings required to obtain these powers at various altitudes and outside
air temperatures can be determined by using your Cessna Power Com
puter or the OPERATIONAL DATA, Section V.

The Optimum Cruise Performance table (figure 2-3), shows that
cruising can be done most efficiently at higher altitudes because very
nearly the same cruising speed can be maintained at much less power.
For a given throttle setting, select the lowest engine RPM in the
green arc range that will give smooth engine operation.
The cowl flaps should be adjusted to maintain the cylinder head tem
perature near the middle of the normal operating (green arc) range to
assure prolonged engine life.
To achieve the range figures shown in Section V, the mixture should
be leaned as follows: pull mixture control out until engine becomes rough;
then enrich mixture slightly beyond this point. Any change in altitude,
power, or carburetor heat will require a change in the lean mixture
setting.
Application of full carburetor heat may enrich the mixture to the
point of engine roughness. To avoid this, lean the mixture as instructed
In the preceding paragraph.

STALLS.

I OPTIMUMCRUSE PERFORMANCEI

The stall characteristics are conventional and aural warning is pro
vided by a stall warning horn which sounds between 5 and 10 MPH above
the stall in all configurations.

wsaansamfl

tBHP

ALTITUDE

75

TRUE
AIRSPEED

(Std.Tanks)

6500

162

695

70

8000

160

735

65

1O000

158

785

Figure 2—3.
2—8

RANGE

Power-off stall speeds at maximum gross weight and aft c. g. position
are presented in figure 5-2 as calibrated airspeeds since indicated air
speeds are unreliable near the stall.

SPIN S.
Intentional spins are prohibited In this airplane. Should an Inadvert
ent spin occur, standard liit plane recovery techniques should be used.

LANDING.
landings are usually made on the main wheels first to reduce the
2—9

landing speed and the subsequent need for braking In the landing mu.
The nosewheel is lowered gently to the runway alter the speed has di
müilshed to avoid unnecessary ixise gear load. This procedure Is es
pecially important in rough field landings.
For short fleW landings, make a power off approach at 69 MPH,
lAS with 40° flaps and land on the main wheels first. Immediately alter
touchdown, lower the nose gear to the ground and apply heavy braking as
required. For maximum brake effectiveness alter all three wheels are
on the ground, retract the flaps, hold full nose up elevator and apply max
imum possible brake pressure without sliding the tires.

turn to locked position to avoid possibility of engine
drawing fuel through the primer.
(2) Clear propeller.
(3) Turn master switch “ON.”
(4) Turn magneto switch to “BOTH.’
(5) Open throttle 1/2” and engage starter.
(6) Pun carburetor heat on alter engine has started, and leave on
until engine is running smoothly.
Without Preheat:

COLD WEATHER OPERATION,
STARTTNG.
Prior to starting on a cold morning, it is advisable to puU the
propeller through several times by hand to “break loose” or “Umber”
the oil, thus conserving battery energy. In extremely cold (0° F and
lower) weather, the use of an external preheater (for both the engine and
battery) and an external power source is recommended whenever possible
to obtain positive starting and to reduce wear and abuse to the engine and
the electrical system.
pre-heat will thaw the oil trapped in the oil cooler, which probably
will be congealed prior to starting in extremely cold temperatures. When
using an external power source, the position of the master switch is im
portant. Refer to Section VI, paragraph GROUND SERVICE PLUG RE
CEPTACLE, for operating details.
Cold weather starting procedures are as follows:
With Preheat:
(1) WIth magneto switch “OFF” and throttle open 1/2”, prime the
engine four to eight strokes as the propeller is being turned over by
hand.
NOTE
Use heavy strokes of primer for best atomization of
fuel. After priming, push primer all the way in and
2—10

(1) Prime the engine six to eight strokes while the propeller is
being turned by hand with throttle open 1/2”. Leave primer charged
and ready for stroke.
(2) Clear propeller.
(3) Tarn master switch “ON,”
(4) Turn magneto switch t0 “BOTH.”
(5) Pump throttle rapidly to full open twice. Return to 1/2” open
position,
(6) Engage starter and continue to prime engine until it is running
smoothly, or alternately, pump throttle rapidly over first 1/4 of
total travel.
(7) Pull carburetor heat on alter engine has started. Leave on
until engine is running smoothly
(8) Lock primer.
NOTE
H the engine does not start during the first few
attempts, or if engine tiring diminishes in strength,
it is probable that the spark plugs have been frosted
over. Preheat must be used before another start is
attempted.
IMPORTANT
Excessive priming and pumping throttle may cause
raw fuel to accumulate in the intake air duct, creat
ing a fire hazard in the event of a backfire. U this
occurs, maintain a cranking action to suck flames
into the engine. An outside attendant with a fire
extinguisher Is advised for cold starts without preheat.
2-11

OPERATION.
During cold weather operations, no indication will be apparent on.
the oil temperature gage prior to take-off if outside air temperatures are
very cold. After a suitable warm-up period (2 to 5 minutes at 1000 RPM),
accelerate the engine several times to higher engine RPM. If the engine
accelerates smoothly and the oil pressure remains normal and steady,
the airplane is ready for take—off.
Rough engine operation in cold weather can be caused by a combina
tion of an inherently leaner mixture due to the dense air and poor vapori
zation and distribution of the fuel-air mixture to the cylinders. The
effects of these conditions are especially noticeable during operation on
one magneto In ground checks where only one spark plug fires in each
cylinder.
To operate the engine without a winterizadon kit in occasional out
side air temperatures from 10° to 20° F, the following procedure is
recommended:
(1) Use full carburetor heat during engine warm-up and ground
check.
(2) Use minimum carburetor heat required for smooth operation in
take-off, climb, and cruise.
(3) select relatively high manifold pressure and RPM settings for
optimum mixture distribution, and avoid excessive manual leaning
In cruislr.g flight.
(4) Avoid sudden throttle movements during ground and flight opera
tion.
When operating In sub-zero temperatures, avoid using partial car
buretor heat. Partial heat may raise the carburetor air temperature to
the 32° to 700 range where Icing is critical under certain atmospheric
conditions.
Refer to section VI for cold weather equipment and operating details
for the OIL DILUTION SYSTEM.

OPERATING LIMITATIONS

OPERATIONS AUTHORIZED.
Your Cessna, with standard equipment as certificated under FAA
Type Certificate No. 3A13, Is approved for day and night operation under
VFR.
Additional optional equipment is available to Increase its utility and to
make it authorized for use under IFR day and night. An owner of a proper
ly equipped Cessna is eligible to obtain approval for its operation on single
engine scheduled airline service under VFR. Your Cessna Dealer will be
happy to assist you in selecting equipment best suited to your needs.

MANEUVERS—NORMAL CATEGORY.
The airplane exceeds the requirements for airworthiness of the
Federal Aviation Regulations, Part 3, set forth by the United States
Government. Spins and aerobatic maneuvers are not permitted in normal
category airplanes in compliance with these regulations. In connection
with the foregoing, the following gross weight and flight load factors apply:

Maximum Gross Weight
Flight Load Factort Flaps Up
Flight Load Factort Flaps Down

+3.8
+3.5

2800 lbs.
—1. 52

tThe design load factors are 150% of the above, and in
all cases, the structure meets or exceeds design loads.

HOT WEATHER OPERATION.
The general warm temperature starting Information on page 2-4 is
appropriate. Avoid prolonged engine operation on the ground.

Your airplane must be operated in accordance with all FAA approved
markings, placards and check lists in the airplane. If there is any infor
mation in this section which contradicts the FAA approved markings, pla
cards and check lists, it is to be disregarded.

2—12
3—1

AIRSPEED LIMITATIONS.
The following are the certificated calibrated airspeed limits for
your Cessna:
Never Exceed (Glide or dive, smooth air)
Caution Range
Maximum Structural Cruising Speed
(Level flight or climb)
Normal Operation Range
Maximum Speed, Flaps Extended
Flap Operation Range
Maneuvering Speedt

.

193 MPH (red line)
160- 193 MPH (yeflow arc)
160 MPH
.

TACHOMETER.
Normal Operating Range
Cautionary Range
Do Not Exceed (Engine rated speed)

2200-2450 RPM (green arc)
2450- 2600 RPM
2600 RPM (red line)

.

67-160 MPH (green arc)
110MPH
60-110 MPH (white arc)
128 MPH

tThe maximum speed at which abrupt control travel
can be used without exceeding the design load factor.

CARBURETOR AIR TEMPERATURE GAGE (OPT).
Under possible icing conditions:
Normal Operating Range
5° to 20°C (green arc)
Cautionary Range
0° to 5°C (yellow arc)
Icing Range
-20° to 0°C (red arc)
FUEL OUANTITY INDICATORS.
Empty

E (red liz)

ENGINE OPERATION LIMITATIONS.
Power and Speed

230 BLIP at 2600 RPM

ENGINE INSTRUMENT MARKINGS.
OIL TEMPERATURE GAGE.
Normal Operating Range
DoNotExceed

Green Arc
225°F(redllne)

OIL PRESSURE GAGE.
Idling Pressure
Normal Operating Range
Maximum Pressure

10 psi (red line)
30-60 psi (green arc)
100 psi (red line)

MANIFOLD PRESSURE GAGE.
Normal Operating Range
CYLINDER HEAD TEMPERATURE GAGE.
Normal Operating Range
Do Not Exceed

15-23 In. Hg (green arc)
275—450°F (green arc)
450°F (red line)

3—2
3—3

WEIGHT AND BALANCE.

I’

—I—

The following information will enable you to operate your Cessna
within the prescribed weight and center of gravity limitations. To figure
the weight and balance for your particular airplane, use the Sample
Problem, Loading Graph, and Center of Gravity Moment Envelope as
follows:

b

Take the licensed Empty Weight aixi Moment/bOO from the Weight
and Balance Data sheet, plus any changes noted on forms FAA-337
carried in your airplane, and write them down In the proper columns.
Using the Loading Graph, determine the moment/bOO of each item to
be carried. Total the weights and moments/i 000 and use the Center
of Gravity Moment Envelope to determine whether the point falls with
in the envelope, and if the loading is acceptable.
I

:11.±

:

Your Airplane

Sample Airplane

SAMPLE LOADING PROBLEM

weight
(lbs(

Moment
lb-in;.

1660

57.9

22

-0.3

3. PIlot & Front Passenger

340

1 2.2

4. Fuel. (60.0 Gal at 6ff/Goll

360

17.3

S. Rear Passenger,

340

24.1

78

7.6

I. Licensed Empty Weight Sample Airplane)
2. oil

.

12

Qls

6. Baggage Ic’ Passenger on Au1lJory Seall
7. Total AircraFt Weight ILoodedl

2800

11 8.8

Weight

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3—4
3—5

C
a,
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trmti

C
C.

CARE OF THE AIRPLANE

-4

02

ru

Ti your airplane is to retain that new-plane performance and dependa
bility, certain inspection and maintenance requirements must be followed.
It is wise to follow a planned schedule of lubrication and preventative main
tenance based on climatic and flying conditions encountered in your locality.
o
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—

o
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ha.

50

C

o
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U-Ld

Keep in touch with your Cessna Dealer, and take advantage of his
knowledge awl experience. He knows your airplane and how to maintain
it. He will remind you when lubrications and oil changes are necessary,
and about other seasonal and periodic services.

GROUND HANDLING.
The airplane is most easily and safely maneuvered during ground
handling by a tow-bar attached to the nosewheel.
NOTE
When using the tow-bar, do not exceed the nosewheel
turning angle of 29 either side of center.

I
MOORING YOUR AIRPLANE

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Proper tie-down procedure is your best precaution against damage to
your parked airplane by gusty or strong winds, To tie-down your airplane
securely, proceed as follows:

0

(1) Set the parking brake arid install the control wheel lock.
(2) Install a surface control lock over the fin and rudder.
(3) Tie sufficiently strong ropes or chaIns (700 pounds tensile
strength) to the wing, tail, and nose he-down fittings and secure
each rope to a ramp tie-down.
(4) Install a pitot tube cover.

WINDSHIELD-WINDOWS.
The plastic windshield and windows should be kept clean and waxed at
To prevent scratches and crazing, wash them carefully with
times.
all
plenty of soap and water, using the palm of the hand to feel and dislodge
dirt and mud. A soft cloth, chamois or sponge may be used, bot only to
carry water to the surface. ltnse thoroughly, then dry with a clean,
moist chamois. Rubbing the surface of the plastic with a dry cloth builds
up an electrostatic charge so that it attracts dust particles in the air.
WipIng with a moist chamois MU remove both the dust and this charge.

I

Once the finish has cured completely, It may be waxed with a good
automotive wax. A heavier coating of wax on the leading edges of the
wings and tail and on the nose cap and propeller spinner will help reduce
the abrasion encountered in these areas.

Remove oil and grease with a cloth moistened with kerosene. Never
use gasoline, benzine, alcohol, acetone, carbon tetrachloride, fire ex
tinguisher or anti-ice fluid, lacquer thinner or glass cleaner. These
materials wiil soften the plastic and may cause it to craze.

PROPELLER CARE.

After removing dirt and grease, If the surface is not badly scratched
it should be waxed with a good grade of commercial wax. The wax will
fill in mInor scratches and help prevent further scratching. Apply a thin,
even coat of wax, and bring it to a high polish by rubbing lightly with a
clean, dry, soft flannel cloth. Do not use a power buffer; the heat gen
erated by the buffing pad may soften the plastic.

Preflight inspection of propeller blades for nicks, and wiping them
occasionally with an oily cloth to clean off grass and bug stains will as
sure long, trouble-free service. It is vital that small nicks on the pro
peller, particularly near the Ups and on the leading edges, are dressed
out as soon as possible since these tucks produce stress concentrations,
and if ignored, may result in cracks. Never use an alkaline cleaner on
the blades; remove grease and dirt with carbon tetncMoride or Stoddard
solvent.

Do not use a canvas cover on the windshield unless freezing rain or
sleet is anticipated. Canvas covers may scratch the plastic surface.

ALUMINUM SURFACES.

INTERIOR CARE.

The clad aluminum surfaces of your Cessna may be washed with clear
water to remove dirt; oil and grease may be removed with gasoline, naptha,
carbon tetrachioride or other non-alkaline solvents. Dulled aluminum
surfaces may be cleaned effectively with an aircraft aluminum polish.

To remove dust and loose dirt from the upholstery and carpet, clean
the Interior regularly with a vacuum cleaner.
Blot up any spilled liquid promptly with cleansing tissue or rags.
Don’t pat the spot; press the blotting material firmly and hold it for
several seconds. Continue blotting until no more liquid is taken up.
Scrape off sticky materials with a dull knife, then spot-clean the area.

After cleaning, and periodically thereafter, waxing with a good auto
motive wax will preserve the bright appearance and retard corrosion.
Regular waxing Is especially recommended for airplanes operated in
salt water areas as a protection against corrosIon.

I’

PAINTED SURFACES.
The painted exterior surfaces of your new Cessna require an initial
4-2

curing period which may be as long as 90 days after the finish is applied.
During this curing period some precautions should be taken to avoid dam
aging the finish or interfering with the curing process. The finish should
be cleaned only by washing with clean water and mild soap, followed by a
rinse with water and drying with cloths or a chamois. Do not use polish
or wax, which would exclude air from the surface during this 90-day cur
ing period. Do not rub or buff the finish, and avoid flying through rain,
hail or sleet.

Oily spots may be cleaned with household spot removers, used spar
ingly. Before using any solvent, read the instructions on the container
and test It on an obscure place on the fabric to be cleaned. Never satu
rate the fabric with a volatile solvent; it may damage the padding and
backing materials.
4-3

AIRPLANE FILE
ype deter
Soiled upholstery and carpet may be cleaned with a foam-t
the foam
Keep
tions.
instruc
’s
gent, used according to the manufacturer
ize
minim
to
r,
cleane
vacuum
a
with
e
it
remov
and
le
as dry as possib
wetting the fabric.
need
The plastic trim, headliner, instrument panel and control knobs
l
wheel
contro
the
on
grcasç
and
Oil
cloth.
only be wiped off with a damp
kerosene.
and control knobs can be removed with a cloth moistened with
the wind
of
care
on
aphs
paragr
in
ned
mentio
Volatile solvents, such as
.
shield, must never be used since they soften and craze the plastic

INSPECTION SERVICE AND INSPECTION PERIODS.
With your airplane you will receive an Owner’s Service Policy. Cou
and the first
pons attached to the policy entitle you to an Initial inspection
Dealer,
your
from
y
deliver
take
.
you
U
charge
at
no
tion
100-hour inspec
e to
airplan
the
of
y
deliver
he will perform the initial inspection before
your
to
It
take
to
plan
,
factory
the
at
e
airplan
up
the
pick
you, if you
permit
Dealer reasonably soon atter you take delivery on it. This will
may
appear
ents
that
adjustm
minor
any
make
to
and
over
him to check it
100 hours or 180
necessary. Also, plan an inspection by your Dealer at
ed by your
days, whichever comes first. This inspection also is perform
will be
tions
inspec
ant
Dealer for you at no charge. While these import
prefer
will
you
cases
most
in
,
Dealer
ssna
performed for you by anyCe
plish
to have the Dealer from whom you purchased the airplane accom
this work.
a
Federal Aviation Regulations require that all airplanes have
per
and
r,
istrato
admin
the
by
bed
prescri
as
tion
inspec
l)
periodic (annua
100n,
additio
r.
In
istrato
admin
formed by a person designated by the
mechanic”
hour periodic inspections made by an “appropriately-rated
ft
Aircra
Cessna
The
hire.
are required if the airplane Is flown for
e.
airplan
your
for
tion
inspec
ic
period
ur
100-ho
the
ends
Company recomm
worked
ly
careful
has
been
tion
The procedure for this 100-hour inspec
zation.
out by the factory and is followed by the Cessna Dealer Organi
Cessna
The complete familiarity of the Cessna Dealer Organization with
highest
the
es
provid
ures
proced
ved
-appro
factory
with
and
ent
equipm
type of service possible at lower cost.

There are miscellaneous data, Information and licenses that are a
part of the airplane file. The following is a check list for that file. In
addition, a periodic check should be made of the latest Federal Aviation
Regulations to insure that all data requirements are met.
A.

To be displayed in the airplane at all times:
(1) Aircraft Airworthiness Certificate (Form FAA-1362).
(2) Aircraft Registration Certificate (Form FAA-500A).
(3) Airplane Radio Station License (Form FCC-404, if
transmitter installed).

B.

To be carried in the airplane at all times:
(1) Weight and Balance, and associated papers (latest copy of
the Repair and Alteration Form, Form—337, if applicable).
(2) Airplane Equipment List.

C.

To be made available upon request
(1) Airplane Log Book.
(2) Engine Log Book.
NOTh
Cessna recommends that these items, plus the Owner’s
Manual and the “Cessna Flight Guide” (Flight Computer),
be carried in the airplane at all times,

Most of the items listed are required by the United States Federal
Aviation Regulations. Since the regulations of other nations may require
other documents and data, owners of exported airplanes should check with
their own aviation officials to determine their individual requirements.

4-5
4—4

LUBRICATION AND SERVICING
PROCEDURES
requiring daily
Specific servicing information is provided here for items
inform the pilot
to
ed
Includ
is
List
Check
ls
Interva
ing
Servic
attention. A
d.
and
service
when to have other items checked

DAiLY
FUEL TANK FILLERS:
The
Service after each flight with 80/87 minimum grade fuel.
capacity of each tank is 32. 5 gallons. When optional long range
.
fuel tanks are installed, the capacity of each tank is 42. 0 gallons
FUEL STRAINER:
Drain approximately two ounces of fuel before initial flight and
drain
after refueling to remove water and sediment. Make sure
valve is closed after draining.

SERVICING INTERVALS CHECK LIST
EACH 50 HOURS
BATTERY
Check and service. Check oftener (at least every 30 days)
If operating in hot weather.
ENGINE OIL AND OIL FILTER
Change engine oil and replace filter
element, if optional oil filter is not installed, change oil and clean screen
25 hours. Change engine oil at least every four months even though
less titan 50 hours have been accumulated. Reduce periods for prolonged
operation in dusty areas, cold dllmates, or when short flights and long
idle periods result In sludging conditions.
Clean or replace. Under extremely dusty
CARBURETOR AIR FILTER
conditions, daily maintenance of the filter is recommended.
NOSE GEAR TORQUE LINKS
Lubricate.
--

--

--

--

EACH 100 HOURS
FUEL STRAINER
Disassemble and clean.
FUEL TANK SUMP DRAIN PLUGS
Remove and drain.
Remove and drain,
FUEL LINE DRAIN PLUG
Check and fill.
BRAKE MASTER CYLINDERS
Check and fill.
SHIMMY DAMPENER
Clean.
VACUUM SYSTEM OIL SEPARATOR (OPT)
Clean.
SUCTION RELIEF VALVE INLET SCREEN (OPT)
--

OIL DIPSTICK:
than 9
Check oil level before each flight. Do not operate on less
10
to
quart
fill
r,
breathe
h
throug
oil
of
loss
ize
quarts. To minim
ed flight,
level for normal flights of less than 3 hours. For extend
nal
fill to 12 quarts. If optional oil filter is Installed, one additio
quart is required whed the filter element is changed.
OIL flLLER
n
When preflight check shows low oil level, service with aviatio
40°F.
above
50
and
SAE
40°F.
grade engine oil; SAE 0 below
t mineral
Your Cessna was delivered from the factory with straigh
l
minera
t
straigh
with
d
oil (non-detergent) and should be operate
25the
during
oil
l
minera
of
use
The
hours.
first
25
oil for the
hour break-in period will help seat the piston rings and will re
sult in less oil consumption. Alter the first 25 hours, either
mineral oil or detergeht oil may be used, if a detergent oil is
used, It must conform1 to Continental Motors Corporation Spec
brand.
ification IvuIS-24. Yot& Cessna Dealer can supply an approved
OXYGEN CYLINDER AND FILLER VALVE (OPT);
Check oxygen pressure gage for anticipated requirements before
each flight, Whenevez pressure drops below 300 psi, use filler
valve on left side of rear baggage compartment wall and refill
).
cylinder with aviator’s breathing oxygen (Spec. No. rvilL-O-272l0
Madmum pressure, 1800 psi.

4-6

--

--

--

- -

--

--

EACH 500 HOURS
WHEEL BEARINGS
Lubricate. Lubricate at first 100 hours and at
500 hours thereafter.
Replace filter element. Re
VACUUM SYSTEM MR FILTER (OPT)
place sooner if suction gage reading drops below 3.75 in. Hg.
--

--

AS REQUIRED
Keep inflated and filled.
NOSE GEAR SHOCK STRUT
Replace at instrument
GYRO INSTRUMENT A FILTERS (OPT)
overhaul.
--

--

4—7

OPERATIONAL DATA

OWNER FOLLOW-UP SYSTEM
Your Cessna Dealer has an owner follow-up system
to notify you when he receives information that applies to
your Cessna. In addition, if you wish, you may choose to
receive similar notification directly from the Cessna Serv
ice Department. A subscription card is supplied in your
airplane file for your use, should you choose to request
this service. Your Cessna Dealer will be glad to supply
you with details oncerning these follow-up programs,
and stands ready hrough his Service Department to
supply you with fast, efficient, low cost service.

The operational data charts on the following pages are presented for
two purposes; first, so that you may know what to expect from your air
plane under various conditions, and second, to enable you to plan your
flights in detail and with reasonable accuracy.
The data in the charts has been compiled from actual flight tests with
the airplane and engine in good condition and using average piloting tech
niques. Note also that the range charts make no allowances for wind, nav
igational errors, warm—up, take-off, climb, etc. You must estimate these
variables for yourself and make allowances accordingly.
Remember that the charts contained herein are based on standard
day conditions. For more precise power, fuel consumption, and endur
ance Information, consult the Cessna Flight Guide (Power Computer)
supplied with your aircraft. With the Flight Guide, you can easily take
into account temperature variations from standard at any flight altitude.

I
FLAPS
up
*FLAPS
DOWN
20°-40°

I

AIRSPIED CORRECTION TABLE
—

I

lAS

60

80

100

120

140

160

180

—

CAS

68

83

100

118

137

156

175

—

lAS

40

50

60

70

80

90

100

110

CAS

58

63

68

75

84

92

101

110

‘Maximum Flap Speed 110 MPH, CAS

I

Figure 5—1.
5—1
4-8

STALL SPEED. POWER OF
ANGEOflAN

W?&’
CONFIGURATION

0°

300

600

FLAPS UP

64

69

91

FLAPS 20°

57

61

81

RAPS 4Q4

55

59

78
r

SPEEDS ARE MPH, CAS

:11

C,
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Figure 5—2.

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1
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0

U,

C—

U,

IT

tin
a

•1

-3

11

0

0
0

C,,

L

01

0

0;

69

2800

POUNDS

APPROACH
LAS
MTh
WEQIT

GROSS

NOTE;

590

GROUND
ROLL

640

GROUND
ROLL

1430

TOTAL
TO CLEAR
50 FT. 082.

680

GROUND
ROLL

GROUND
ROLL

740

1505

Figure 5—5.

Reduce Ianthng distances 10% for each 0 MPH headwind.

1595

TOTAL
TO CLEAR
50 FT. CBS.

@7500FEET& 3r1
TOTAL
TO CLEAR
50 FT. 082.

@S000FEET&411

FLAPS ON HARD SURFACED RUNWAY
250OFEET& 50 F

400

Distanc€ are based on zero wind, power off and heavy braking.

j35

It CLEAR
50 FT. CBS.

TOTAL

@SEALEVEL&59F

LANDING DISTANCE WITH

LANDING DISTANCE TABLE

‘

OPTIONAL SYSTEMS

This section contains a description, operating procedures, and per
fonnance data (when applicable) for some of the optional equipment which
may be installed in your Cessna. Owner’s Manual Supplements are pro
vided to cover operation of other optional equipment systems when installed
in your airplane. Contact your Cessna Dealer for a complete list of avail
able optional equipment.

I

LONG RANGE FUEL TANKS

Special wings with long range fuel tanks are available to replace the
standard wings and fuel tanks for greater endurance and range. When
these tanks are installed, the total usable fuel, for all flight conditions,
is 79 gallons.
4

COLD WEATHER EQUIPMENT

“a’

r

I

WINTERIZATION KIT AND
NON-CONGEALING OIL COOLER.

•

For continuous operation in temperatures consistently below 20° F,
the Cessna winterization kit and non-congealing oil cooler, available from
your Cessna Dealer, should be Installed in improve engine operation.

C”-.

GROUND SERVICE PLUG RECEPTACLE
A ground service plug receptacle may be installed to permit the use
of an external power source for cold weather starting and during lengthy

I

6—1

____OI

I
maintenance work on the electrical system.
source, it is im
Before connecting a generator type external power
the battery
enable
will
This
on.
turned
be
switch
master
portant that the
semicon
the
e
damag
might
ise
to absorb transient voltages which otherw
external
type
battery
a
using
When
ent.
equipm
nic
ductors in the electro
an un
t
to
preven
off
turned
power source, thE master switch should be
e’s
airplan
the
es
to
batteri
source
power
the
from
necessary power drain
battery.
IMPORTANT
Be certain that the polarity of any external power source
e
or batteries is correct (positive tb positive and negativ
i
to negative). A polarity reversal will result in immed
n
electro
e’s
airplan
the
rs
in
nducto
semico
ate damage to
ic equipment.

NOTE
On the first operation of the oil dilution system each
season, use the full dilution period, drain the oil,
clean the screen, refill with new oil and redilute as
required.
H the full dilution time was used, beginning with a full oil sump (12
quarts), subsequent starts and engine warm-up should be prolonged to
evaporate enough of the fuel to lower the oil sump level to 13 quarts prior
to take-off. Otherwise, the sump may overflow when the airplane is
nosed up for climb.
To avoid progressive dilution of the oil, flights of at least two hour’s
duration should be made between oil dilution operations.

STATIC-PRESSURE ALTERNATESOVRCE VALVE.

OIL DILUTION SYSTEM.
and very low
If your airplane is equipped with an oil dilution system,
shut
down by
engine
to
prior
oil
the
dilute
ataI,
anticip
temperatures are
1000
RPM.
ng
at
operati
energizing the oil dilution switch with the engine
ature.
temper
ated
the
anticip
for
time
n
dilutio
6-1
for
(Refer to figure
d for any unusual
While diluting the oil, the oil pressure should be watche

DILUTION TABLEE
TEMPERATURE

:
0°F

mm.

Dilution Time

1’/2

Fuel Added

I qt.

—10° F
33/4

mm.

22 qt.

FIgure 6—1.

—

—20°F
6 mm.
4 qt.

NOTE: Maximuth fuel and oil in sump
for take.off is 13 quarts.

6-2

fluctuations that might indicate a screen being clogged with sludge washed
down by the fuel.

A static-pressure alternatesource valve may be installed in the
static system for use when the external statIc sources are malfunctioning.
This valve also permits draining condensate from the static lines.
U eironeous instrument readings are suspected due to water or ice
in the static-pressure lines, the statlc_pressure.alternate_sowce valve
should be opened, thereby supplying static pressure from the cabin. Cabin
pressures will vary, however, with open cabin ventilators or windows. The
most adverse combinations will result in airspeed and altimeter variations
of no more than 2 MPH and 20 feet, respectively.

I

RADIO SELECTOR SWITCHES

RADIO SELECTOR SWITCH OPERATION.

radio unit the pilot desires to use for transmission. This is accomplished
by placing the transmitter selector switch in the position corresponding to
the radio unit which Is to be used.

SPEAKER-PHONE SWITCHES.

the respec
Operation of the radio equipment is normal as covered in
audio
an
d,
installe
is
radio
one
than
more
When
ls.
live radio manua
system
ing
this
switch
on
of
operati
switching system is necessary. The
is described below.

The speaker-phone switches determine whether the output of the re
ceiver in use is fed to the headphones or through the audio amplifier to
the speaker. Place the switch for the desired receiving system either
In the up position for speaker operation or in the down position for head
phones.

TRANSMITTER SELECTOR SWITCH.

AUTOPILOT-OMNI SWITCH.

When two trans
The transmitter selector: switch has two positions.
hone to the
microp
the
switch
to
ary
necess
it
is
mitters are installed,

)

RADIO SELECTOR SWITCH ESJ

When a Nav-O-Matic autopilot is installed with two compatible omit
receivers, an autopilot-omni switch is utilized. This switch selects the
omni receiver to be used for the omni course sensing function of the auto
pilot. The up position selects the upper omni receiver in the radio panel
stack and the down position selects the lower omni receiver.

s— TRANSMITTER

SELECTOR SWITCH

1

1

SPEAKER

000000
/0MM

TRANS)77’_P1ONES

Z

Z—AUTOPILOT.OMNI
SWITCH

SPEAKER-PHONE SWITCH:
NUMBERED SWITChES CONTROL SPEAKER-PHONE
FUNCTION OF EQUIPMENT IN CORRESPONDING
RADIO POSITIONS I (TOP RADIO POSITION)
THRU 4 (BOTTOM RADIO POSITION)
IN RADIO STACK pN INSTRUMENT PANEL.

Figure 6—2.
6-4

‘yt

* ‘Wi’,

‘3L’
I

M•iSm

wc.. ty
I.

3

Uw

.$

p...(

“V’

L’. VaL4u.,.:;:.a.

nt

Las
.‘40’
6—5

I

OXYGEN SYSTEM

OXYGEN DURATION (HOURS)

I

six-place
Your airplane may be equipped with either a four-place or
baggage
oxygen system. An oxygen cylinder, located behind the rear
pressure
compartment wall, supplies oxygen for the system. Cylinder
regulator
is reduced to an operating pressure of 70 psi by a pressure
part of the reg
attached to the cylinder. A shut-off valve is included as
on the left
ulator assembly An oxygen cylinder filler valve is located
is indi
pressure
Cylinder
wall.
compartment
side of the rear baggage
valve.
filler
the
above
wall
the
on
located
gage
pressure
a
by
cated

PRESSURE

1800
1600
1400
1200
1000
BOO
600
400
200

Depending upon the type of system installed, either four or six
oxygen outlets are provided in the cabin ceiling just above the side
type
windows; one at each of the seating positions. Partial-rebreathing
indicators,
flow
and
hoses
plastic
oxygen masks, complete with vinyl
are provided.
A remote shut-off valve control, located adjacent to the pilot’s
system
oxygen outlet, is used to shut off the supply of oxygen tr the
the
shut-off
to
connected
mechanically
is
control
The
use.
not
in
when
valve at the cylinder. With the exception of the shut-off function, the
system is completely automatic and requires no manual regulation for
change of altitude.

OXYGEN SYSTEM’OPERATION.
Prior to flight, check to be sure that there is an adequate oxygen
Refer
supply for the trip, by noting the oxygen pressure gage reading.
the
Oxygen
to
and
CALCULATION,
DURATION
OXYGEN
to paragraph
and hoses
Duration Table (figure 6-3). Also, check that the face masks
condition.
good
in
and
are accessible
To use the oxygen system, proceed as follows:
NOTE

PILOT ONLY

PILOT PLUS ONE (1) PASSENGER

PRESSURE ALTITUDE

PRESSURE ALTItUDE

8000

10,000

15.000

20,000

6000

10,000

15,000

14.6
12.9
11.2
9.4
7.7
6.0
4.3
2.6
.9

13.0
11.4
9.9
8.4
6.9
5.3
3.9
2.3
.7

10.2
9.0
7.6
6.6
5.4
4.2
3.0
1.8
.6

8.4
7.4
6.4
5.4

8.0
7.1
6.2
5.2
4.3
3.3
2.4
5.4
.4

7.2
6.3
5.5
4.6
3.8
2.9
2.1
1.2
.4

5.7
5.0
4.3
3.7
3.0
2.3
1.7
1.0
.3

4.4

3.4
2.4
1.4
.4

1600
1600
1400
1200

1000
600
600
400

I

5.6
4.9
4.2
3.6
2.9
2.3
1.6
1.0

10,000
5. 0
4.4
3.6
3.2
2. 6
2. 1
1.5
.9

15,000
3.9
3.5
3,0
2. 8
2.1
1.6
1.2
.7

20,000

8000

60.000

15.000

20,000

3.2
2. 8
2. 5
2. 1
1.7

4.2
3.7
3. 2
2.7
2. 2
1.7
1.2
.7

3.8
3. 3
2,9
2. 5
2.0
1. 6
1.1
.7

3.0
2.6
2.3
1.9
1.6
1.2
.9
.5

2.5
2.2
1.9
1.6
1.3
1.0
.7

1. 3

.9

PILOT PLUS FIVE (5) PASSENGERS

PILOT PLUS FOUR (4) PASSENGERS
GAGE
PRESSURE
1600
1600
1400
1200

1000
600
600

NOTES:

PRESSURE ALTITUDE

PRESSURE ALTITUDE
8000

10,000

3.4
3,0
2.6

3.1
2,7
3.4

2.2

2.0

1.8
1.4
1.0

1.6
1.3
.9

4.7
4.1
3.6
3.0
2,5
1.9
1.3
.8
.2

PRESSURE ALTITuDE

PRESSURE ALTITUDE
8000

20,000

PILOT PLUS ThREE (3) PASSENGERS

PILOT PLUS TWO (2) PASSENGERS
GAGE
PRESSURE

J

15,000

20,000

2.4
2.2
1.9
1.6
1.3
1.0
.7

2.0
1.7
1.5
1.3
1.0
.6
.6

8000

10,000

15,000

20,000

2.9
2.5
2.2

2.8
2.3
2.0

2.0
1.8
1.5

1.7
1.5
1.3

1.6

1.7

1,3

1.1

1.5
1,2
.8

1.4
1.1
.7

1.1
.8
.6

.9
.7
.5

1. MI figures based on ptlot with orange color - coded oxygen line
fitting and passengers with green color coded line fittings.
actual duration will depend
2. Duration figures are averages
upnn accuracy of setting altituth and ambient temperature.
alutode.
on
pressure
3. Dur4jon times are based
—

———

Permit no smoking when using oxygen.
Figure 6—3.
(1) Pull oxygen supply control knob “ON.”
(2) Select mask and hose.
6-6

6—7

altitude. The same pressure will sustain the pilot and three (3)
passengers for 2. 9 hours at 10, 000 feet.
NOTE

-

NOTE
In a standard four-place or six-place oxygen system
installation, the hose assembly provided I or the pilot
is of a higher flow rate than those for the passengers.
The pilot’s hose assembly is color-coded with an
orange band adjacent to the plug-in fitting. The hoses
provided for the passengers are color-coded with a
green band. U the aircraft owner prefers to do so,
he may provide the higher flow rate hoses for all
passengers; these hoses would also be color-coded
with an orange band. In any case, it Is recommended
that the pilot use the larger capacity hose. All masks
are identical.
snug
(3) Attach mask to face and adjust metallic nose strap for
mask fit.
occupy
(4) Select oxygen outlet located nearest to the seat you are
uously
contin
flow
will
n
it.
Oxyge
into
hose
y
ing, and plug deliver
l ad
at the proper rate of flow for any altitude without any manua
justments.
n Is flow
(5) Check the flow indicator in the face mask hose. Oxyge
mask.
the
toward
forced
being
is
or
ing if the indicat
when discontin
(6) Unplug the deUvery hose from the outlet coupling
flow of oxygen.
the
stops
atically
autom
.
This
system
uhig use of oxygen

Oxygen Duration Table figures are based on a standard
configuration oxygen system having one orange colorcoded hose assembly for the pilot and green color-coded
hoses for the passengers. U orange color-coded hoses
are provided for the passengers in your airplane, it will
be necessary to compute new duration figures due to the
greater consumption of oxygen with these hoses.

OXYGEN SYSTEM SERVICING.
The oxygen cylinder, when fully charged, contains 48 cubic feet of
oxygen, under a pressure of 1800 psi at 70°F. Refer to servicing pro
cedures, page 4-6, for oxygen system servicing requirements.
IMPORTANT
Oil, grease, or other lubricants in contact with oxygen
create a serious fire hazard, and such contact must be
avoided.

OXYGEN DURATION CALCULATION.
determin
The Oxygen Duration Table (fIgure 6-3) should be used in
in your airplane.
supply
oxygen
of
the
(in
iours)
n
duratio
usable
the
ing
the duration from
The following procedure outlines the method of finding
table.
the
re gage.
(1) Note the available bxygen pressure shown on the pressu
nt to
adjace
n
colum
URE”
PRESS
E
the
“GAG
(2) Find this figure In
nts in the air
r
occupa
of
numbe
the
to
ble
applica
figures
of
block
the
plane.
then, read
(3) Locate the pressurp altitude at which you intend to fly;
the gage
with
r
line
in
numbe
ct
the
interse
you
until
n
down this colum
pressure reading. The resulting number is the usable duration (in
hours) of the existing oxygen supply.
will
(4) As an example of tAe above procedure, 1400 psi of pressure
pressure
foot
10,000
a
at
hours
9.9
for
bnly
pilot
the
sustain
safely
6-8

6-9

ALPHABETICAL INDEX
CESSNA ECONOMY MIXTURE INDICATOR)
The Cessna Economy Mixture Indicator is an exhaust gas temperature
sensing device which is used to aid the pilot in selecting the most desirable
fuel-air mixture for cruising flight at less than 75%power. Exhaust gas
temperature (EQT) varies with the ratio of fuel-to-air mixture entering
the engine cylinders. The EGT will peak at a value that is approximately
maximum range mixture.
Operation at peak ECT is not authorized, except to establish peak
EGT for reference. A richer mixture which provides a drop of approx
imately iOO°F from peak ECT is recommended for normal cruise at
less than 75%power. Leaning in this manner will provide fuel consump
tion very close to the Cessna Flight Computer and Owner’s Manual values
and will result in a decrease of only 1 MPH In airspeed from that obtain
able with the same power setting and best power mixture.

OPERATING INSTRUCTIONS.
(1) In take-off and full;power climb, use full rich mixture.
(2) In level flight (or cruising climbat less than 75%power), lean
the mixture to peak EGT, then enrichen one large division
(-100°F) below peak EGT. While leaning the mixture under
some operating conditions, engine roughness may occur
before peak EGT is reached. In this case, enrichen the
mixture approxImately 100° F from the EGT corresponding
to the onset of roughness.
NOTE
Changes in altitude or power setting require the EGT
to be re-checked and the mixture re-set.
(3)

Use rich mixture (or mixture appropriate for field elevation) in
idle descents or landing approaches. Leaning technique for
cruise descents may be with EGT reference method (at least
every 5000 feet) or. by simply enriching to avoid engine rough
ness, if numerous power reductions are made.

A
Alter Landing, 1-4
Airplane,
before entering, 1 -1
file, 4—5
mooring, 4-1
secure, 1-4
Airspeed Correction Table, 5-1
Airspeed LimitatIons, 3-2
Aluminum Surfaces, 4-2
Authorized Operations, 3-1

B
Baggage, Weight, inside front
cover
Beacon, Rotating, 2-3
Before Entering Airplane, 1-I
Before Landing, 1-4
Before Starting Engine, 1-1
Before Take-Off, 1-2, 2-6

C
Cabin Heating, Ventilating and
Defrosting System, 2-3
Capacity,
fuel, inside front cover
oil, inside front cover
Carburetor, 2-2
Care,
interior, 4-3
propeller, 4-3
Center of Gravity Moment
Envelope, 3-6
Check List, Servicing Intervals, 4-7

Circuit Breakers, 2—3
Climb, 1-3, 2—7
maximum performance, 1-3
normal, 1-3
Cold Weather Equipment, 6-1
Cold Weather Operation, 2-10
operation, 2-12
starting, 2-10
Correction Table, Airspeed, 5-i
Cruise Performance, Optimum, 2-8
Cruise Performance, 5-4, 5-5, 5-6
Cruising, 1—3, 2—8

D
Diagram,
exterior inspection, iv
fuel system schematic, 2—2
principal dimensions, ii
taxiing, 2-5
Dilution System, Oil, 6-2
dilution table, 6-2
Dimensions, Principal, ii

E
Economy Mixture Indicator, 6-10
operating instructions, 6-10
Electrical System, 2-3
circuit breakers, 2-3
ground service plug recept
acle, 6—1
rotating beacon, 2—3
Empty Weight, inside front cover
Engine, inside front cover
before starting, 1—1
instrument markings, 3-2
Index—i

6-10

0
operation limitations, 3-2
primer, 2-2
starting, 1-2, 2-4
Equipment, Cold Weather, 6-1
Exterior Inspection Diagram, iv

F
File, Airplane, 4-5
Fuel System, 2-1
capacity, inside front cover
carburetor, 2-2
engine primer, 2-2
fuel strainer, 2-2
long range tanks, 6—1
mixture control, 2-2
schematic, 2—2
selector valve, 2-2
throttle, 2-2
wing tanks, 2-2

G
Graph,
center of gravity moment
envelope, 3-6
loading, 3-5
Gross Weight, inside front cover
Ground HandlIng, 4-1
Ground Service Plug Receptacle, 6-1

H
Handling Airplane On Ground, 4-1
Heating, Ventilating and Defrosting
System, CabIn, 2-3
Hot Weather Operation, 2-12

I
Inspection Diagram, Exterior, iv

Inspection

Inspection Service
Period, 4-4
Instrument Markings, Engine, 3-2
Interior Care, 4-3
—

Oil System,
capacity, inside front cover
dilution system, 6-2
dilution system table, 6-2
Operation, Cold Weather, 2—10
Operation, Hot Weather, 2-12
Operation Limitations, Engine, 3-2
Operations Authorized, 3-1
Optimum Cruise Performance, 2-S
Owner Follow-Up System, 4-8
Oxygen System, 6-6
duration calculation, 6—8
duration table, 6-7
operation, 6-6
servicing, 6—9

I.
Landing, inside front cover, 1-4,
2-9
after, 1-4
before, 1-4
distance table, 5-’I
normal, 1-4
Let-DOwn, 1-4
Limitations, Airspeed, 3-2
Limitations, Engine Operation, 3-2
Loading, Power, inside front cover
Loading, Wing, inside front cover
Loading Graph, 3-5
Loading Problem, Sample, 3-4
Long Range Fuel Tanks, 6-1
Lubrication and Servicing
Procedures, 4-6

p
Painted Surfaces, 4-2
Performance Specifications,
Inside front cover
Power, Inside front cover
Power Loading, inside front cover
Primer, Engine, 2-2
Principal Dimensions Diagram, Ii
Propeller, inside front cover
care, 4-3
-

M
Normal Category, 3-1
Maneuvers
Maximum Performance Climb, 1-3
Maximum Performance Take -Off,
1—3
Mixture Control, 2-2
Moment Envelope, Center of
Gravity, 3-6
Mooring Your Airplane, 4-1
—

Radio Selector Switches, 6-4
autopilot—omni switch, 6-4, 6-5
operation, 6-4
speaker-phone, 6-4, 6-5
transmitter selector, 6-4
Range, inside front cover
Rate of Climb at Sea Level,
inside front cover
Rotating Beacon, 2-3

N
Normal
Normal
Normal
Normal

Maneuvers, 3-1
Category
Climb, 1-3
Landing, 1-4
Take-Off, 1—3
—

S
Sample Loading Problem, 3-4
Securing Aircraft, 1-4
Selector Valve, Fuel, 2-2
Service Ceiling, inside front cover
Servicing and Lubrication
Procedures, 4-6
Servicing Intervals Check List, 4-7
Servicing Requirements, inside
back cover
Specifications Performance,
Inside front cover
Speed, inside front cover
Spins, 2-9
Stalls, 2-9
speed chart, 5—2
Starting Engine, 1-2, -4
Static-Pressure Alternate-Source
Valve, 6—3
Strainer, Fuel, 2-2
Surfaces,
aluminum, 4-2
painted, 4-2
System,
cabin heating, ventilating and
defrosting, 2-3
electrical, 2—3
fuel, 2—I
oil dilution, 6-2
owner follow-up, 4-S
oxygen, 6-6
-

T
Take—Off, inside front cover, 1—3, 2—6
before, 1—2, 2—6
maximum performance, 1-3
normal, 1-3
Take-Off and Climb Data Table, 5-3
Taxiing, 2-6
diagram, 2-5
Throttle, 2-2
Index-3

Index-2

I

I
V
Valve, Fuel Selector, 2-2

w
Weight,
baggage, Inside front cover

empty, inside front cover
gross, inside front cover
Weight and Balance, 3-4
Windshield and Windows, 4-2
Wing Loading, Inside front cover
Wing Tanks, Fuel, 2-2
Winterization Mt and Non-Congeal
ing 011 Cooler, 6-1

I

SERVICING REQUIREMENTS

FUEL:
80/87 MINIMUM GRADE
AVIATION GRADE
32.5 GALLONS
CAPACITY EACH STANDARD TANK
42.0 GALLONS
CAPACITY EACH LONG RANGE TANK
--

--

--

ENGINE OIL:
SAE 30 BELOW 40° F.
SAE 50 ABOVE 400 F.
(AIRCRAFT DELIVERED MTh STRAIGHT MINERAL OIL.
EITHER MINERAL OIL OR DETERGENT OIL MAY BE
USED. IF DETERGENT OIL IS USED, IT MUST CONFORM
TO CONTINENTAL MOTORS SPECIFICATION MHS-24.)
12 QUARTS
CAPACITY OF ENGINE SUMP
(DO NOT OPERATE ON LESS ThAN 9 QUARTS. TO
MINIMIZE LOSS OF OIL THROUGH BREATHER, FILL
TO 10 QUART LEVEL FOR NORMAL FLIGHTS OF LESS
THAN 3 HOURS. FOR EXTENDED FLIGHT, FILL TO
12 QUARTS. IF OPTIONAL OIL FILTER IS INSTALLED,
ONE ADDITIONAL QUART IS REQUIRED WHEN THE
FILTER ELEMENT IS CHANGED.)
AVIATION GRADE

WARRANTY
The Cessna Aircraft Company (Cessna) warrants each new
•
aircraft, including factory installed equipment and accessories,
and warrants aU new aircraft equipment and accessories bearing
the name “Cessna,1’ to be free from defects in material and work
mansifip under normal use and service. Cessna’s obligation under
this warranty is limited to supplying a part or parts to replace any
part or parts which, within six (6) months after delivery of such
aircraft or such aircraft equipment or accessories to the original
retail purchaser or first user, shall be returned transportation
charges prepaid to Cessna at Wichita, Kansas, or such other place
as Cessna may designate and which upon examination shall dis
close to Cessna’s satisfaction to have been thus defective.

--

--

HYDRAULIC FLUID:
MIL-H-5506 HYDRAULIC FLUID

The provisions of this warranty shafl not apply to any aircraft,
•
equipment or accessories which have been subject to misuse, neg
ligence or accident, or which shall have been repaired or altered
outside of Cessna’s factory in any way so as In the judgment of
Cessna to affect advedely its performance, stability or reliability.
This warranty is expressly in lieu of any other warranties, ex
pressed or implied, including any implied warranty of merchant
ability or fitness for a particular purpose, and of any other ob
ligation or liability on Lhe part of Cessna of any nature whatsoever
and Cessna neither asumes nor authorizes any one to assume for
it any other obligation br liability in connection with such aircraft,
equipment and accessobes.

Index-4

L

OXYGEN:
AVIATOR’S BREATHING OXYGEN
1800 PSI
MAXIMUM PRESSURE

--

SPEC. NO. MIL-O-27210

--

TIRE PRESSURE:
32 PSI ON 6.00x 6 TIRES
25TO35 PSIONB.OOX6TIRES(OPT)
NOSE WHEEL --32 PSI ON 5.OOxS TIRE
20 TO 29 PSI ON 6.00 X 6 TIRE (OPT)
MAIN WHEElS

---

--

I

“TAKE YOUR CESSNA HOME
FOR SERVICE AT THE SIGN
OF THE CESSNA SHIELD”,

CESSNA AIRCRAFT COMPANY
WICHITA, KANSAS

P0: 790366

LOT: 30—17679

P/N:

14—00783

LOG: ZNS
866690015
CESSNR 182H & SKYLPNE 1965 OWNERS MPNUAL



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