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John Deakin |
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| About the Author ... |
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John Deakin is a 35,000-hour pilot who worked his way up the aviation food chain
via charter, corporate, and cargo flying; spent five years in Southeast Asia
with Air America; 33 years with Japan Airlines, mostly as a 747 captain; and
now flies the Gulfstream IV for a West Coast operator.
He also flies his own
V35 Bonanza (N1BE) and is very active in the warbird and vintage aircraft
scene, flying the C-46, M-404, DC-3, F8F Bearcat, Constellation, B-29, and
others. He is also a National Designated Pilot Examiner (NDPER), able to give
type ratings and check rides on 43 different aircraft types.
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First,
some old business ...
I'm pleased to report that my
previous column has had a good response, almost entirely by private email.
There are now about 25 people signed up for the C-131 ground school. Many are
"crew chiefs" and non-pilot volunteers, some are obviously
well-qualified to be SICs, and several are qualified to be PICs, at least on
paper. It remains to be seen how many show up, and how well they do in the
actual airplane.
I've
advised all that the following steps are mandatory for participation, in
order:
- Join the CAF
- Join the SoCal Wing
- Get on my Email lists
- Send in completed CAF Forms 600 and 601 (I can email these)
- Attend Ground school on February 1, 2 & 3, in Camarillo, Calif.
As the completed Form 601s arrive, I'll summarize them, and make a list for
the local leaders to review. At that point, a loose "pecking order"
will be established, according to some magic combination of:
- Past and current participation as a volunteer, or anticipation of future
volunteer efforts
- Contributions to the CAF and to SoCal (NOT just money, but time,
resources, talent, workdays)
- A good attitude, able to work with other volunteers and represent the
CAF to the public
- Willingness and ability to help out with fuel costs (not required, but
we're so short of funds, it's a major plus)
- Current experience with big recips and warbirds
- Past experience with big recips and warbirds (distant past doesn't count
for a whole lot)
- CFIs will have an advantage (we need instructors)
- A&Ps will have a major advantage
- Non-local pilots who have airline privileges
- Above all else, demonstrated talent in the airplane
- Hours, years, and number of type ratings don't count much, as long as
the very low CAF minimum requirements are met.
A very common complaint I hear is some variation of, "Gee, I'd love to
participate, but I can't justify getting there for the ground school, unless
I'm sure I'll fly."
Sorry, but that's not the way this all-volunteer organization works! If you
can't justify coming here just on the chance you MIGHT get to fly a warbird,
you probably don't have the eagerness and the "drive" it takes to
show up and help out once you've flown.
We've also been burned by folks who show up all eager and full of promises,
but turn out to just want a "vanity" type rating, and once they get
it, , they're gone.
Now, on to the checklists, one of my very favorite
subjects. I'll cover the new "Normal" checklist in this column, and
if there is any interest, I'll do the "Emergency" checklist in the
next one.
Operators seem reluctant to alter checklists, even when they have no idea
where the one in use came from. Many seem to fear the FAA might violate them
if they try and change the checklist, or even worse, if they don't use the one
from the manufacturer. The fact is, the FAA doesn't even require a checklist
at all under Part 91, unless the airplane is over 12,500 pounds, or is
turbine-powered!
Now, don't get me wrong, as so many did in my first column here ("Throw
Away That Stupid Checklist") four years ago! One point at a time:
- A checklist is REQUIRED by the rules of common sense and good airmanship
for ALL airplanes. NO exceptions!
- In many one-pilot aircraft, a MENTAL checklist MAY be sufficient, IF the
pilot is proficient and disciplined enough to do a thorough cockpit setup
first, and THEN do that mental checklist, every time.
- In ALL OTHER CASES, a WRITTEN checklist is MANDATORY in my book, whether
required by the FAA, or not.
During our training stint in Florida, we worked with the
checklist provided, which was not from the manufacturer or the Air Force,
and was of dubious parentage, to say the least.
A much better example is the
one from North Central Airlines, provided by friend Randy Sohn (and
probably written by him, centuries ago). But it's designed for one of the old
scrolling boxes, and for an airline operation, not entirely suitable for us,
and there have been some improvements in checklists since then, too.
(You
will need Adobe
Acrobat Reader to view these two PDF files.)
I've also been tasked with coming up with a standard format for all
Commemorative Air Force (CAF) checklists, and since this has been an area of
intense interest for many years for me, I was eager to take on the job. What
follows is my initial attempt at this job, and this is the checklist we used
to bring the airplane home. Kerry and I will then see how it works for real,
collaborate on the almost-inevitable changes, and it should be pretty
"final" when training begins for the new folks.
Here is the new checklist. I have inserted occasional comments for AVweb
readers in italics that will not be in the master document.
Commemorative Air Force
Convair C-131 N131CW
(Rev 2.1 12/23/2001)
By John R. Deakin
Author's Note: We begin with a little preface, which allows me
to mount my favorite soapbox. Please forgive the sermon.
—The Reverend Deacon Deakin
This checklist is generally in compliance with the recommendations of
Degani & Weiner, who have done a great deal of research on the use and
formatting of checklists for NASA, NTSB, NBAA and aviation in general, and
whose work has been adopted by most of the world's airlines. The author hopes
to make this the standard format and style throughout the CAF.
Author's Note: The format has now been approved, and I have the
checklists for the B-24, B-25, B-29 and C-46 in hand. Few items will be
changed except to standaridize terms, at first.
Two internet references with much more detail are:
Very, very few pilots are willing to study this issue, and fewer still can
be persuaded to change the habits of a lifetime. If they've always done things
a certain way, they always will do them that way, as "good enough."
This is nowhere better illustrated than in the use of the old-fashioned
"do" lists, where the pilot sits down, and calls for the check list.
It will usually be a long one, and even with the best of intentions, the items
will not get the attention that only a few of them deserve. The person reading
the checklist will usually not be checking anything (despite SOPs to the
contrary), and the person responding will be rather mindlessly going through
the motions, with no backup and no redundancy. It's so easy. No
thought required. Very little knowledge is required, and the training value is
nil.
In most cases, the pilots become familiar with the airplane, and the long
"do" list is simply skipped, except on a check ride.
Very, very few airlines use "do" lists for normal checklists
today, and the change has nothing to do with "jets vs. recips," it
is simply a better way to operate all airplanes.
True "check" lists for normal operations are done in two stages.
First, each pilot does a "flow" pattern, checking everything in the
cockpit, setting, testing whatever needs testing, then positioning the item
for the next operation. For the most part, BOTH pilots check everything with
this flow pattern, though many operators specify which pilot is to actually
move things, or run the tests needed by some items.
In general, using this "flow," the cockpit is completely set up
for each operation from memory, after which a crewmember reads the challenges
(and sometimes responds). Responses are by the appropriate crewmember,
considering the importance and location of the items. In some cases, both
should respond. UNDER NO CIRCUMSTANCES should the challenging pilot continue
until there has been a clear, correct, thinking response (as opposed to an
absent-minded or careless one). Both crewmembers should actively participate
in the execution of all checklists except the "After Takeoff" and
"After Landing," which are not particularly critical, and may be
done silently by the pilot not flying (PNF), while the pilot flying (PF) pays
full attention to the job at hand.
On the other hand, most operators do use a combination of techniques for
emergency checklists. The "flow" becomes the "memory
items," done without a checkist (then reviewed) by checklist. The
"cleanup" or non-memory items are never done, except when there is
an actual emergency, so there is never an opportunity to do a
"flow." For this reason, they will be done carefully and slowly,
preferably by both pilots. The "cleanup" checklists done as
"do" lists will be FAR more effective than a "do" list on
routine items.
Many pilots will moan, "You mean I have to memorize that flow?"
No. All the pilot has to memorize is where to start the flow, and then simply
check each and every item in the cockpit. As each item gets a look, the pilot
MUST know what it is, what it does, and where it should be for engine start or
takeoff.
This C-131 checklist absolutely requires the latter, more modern approach,
a "flow," then a "check" list.
In summary, you should use this checklist ONLY AFTER each crewmember has
done a "flow pattern." This is NOT a "do list"! Pilots
cannot just climb into the cockpit, sit down and call for the checklist to
accomplish the desired results.
"Flows" may be done in any sequence, but each pilot should be
able to check every item in the cockpit, and not only know where it should be
positioned for each stage of flight, but should be able to explain what each
item is, how it is used, and why it should be set in a given way. The ability
to do this will be a major part of any training ride, and especially on check
rides. Once the "flow" is completed by each crewmember working
alone, the checklist should be conducted by BOTH crewmembers working together,
one challenging, the other responding. (One exception may be the "After
Takeoff" and "After Landing.") If while doing the
challenge/response checklist something is discovered that was not previously
and properly done during the "flow," it must be realized that an
error was committed, and all must THINK about the error, how it happened, and
must resolve to improve next time.
Now, let's keep this in perspective. No one is perfect, and it will be a
very rare flight indeed when this standard is met by anyone! It is a goal, a
concept. It requires a "self-critique," not a "blast" from
the instructor or check pilot (unless many such items are missed, and there is
obvious sloppiness involved).
For the most part, this C-131 checklist contains only the
"killer" items, and, in a few cases, those items most commonly
forgotten that can cause great embarrassment (CAF movement reports, for
example).
Convair Serial Number 205
USAF Serial Number 54-2809
CV-340 (with all 440 mods)
"Type 2" in Dash-1 (Flight Manual)
Author's note: Awright, you guys, anyone who sends me
that hilarious British Airways SOP is gonna get the rubber turkey
award. This is serious bidness, here!
Pilot in command (PIC)
This is the pilot legally responsible for the conduct of the flight.
Author's note: You know, the one the FAA goes after.
Second in command (SIC)
The pilot designated as under the authority of the PIC.
Crew Chief
The person designated as the third crewmember, under the authority of
both pilots.
Author's note: Our Standard Operating
Procedure (SOP) is to run with a third crew member on all flights.
To my personal knowledge, this has twice saved engines.
PF = Pilot Flying
Generally, the person handling the flight controls, usually acting as
PIC.
Pilot Not Flying
The person other than the PF, who is not handling the flight controls.
Left Seat Pilot (LS)
Right Seat Pilot (RS)
These terms identify only the physical position of the
person. May be a PIC, SIC, PF or PNF. For example, the nose gear
steering wheel is accessible only by the left seat (LS) pilot, so LS
must handle all power, brakes, and directional control on the ground
below 80 knots. He may be the PF, PNF, the PIC or SIC.
"____"
This "empty response" calls for a specific
response, but one that may be variable, depending on the
configuration, or the weight, or load, etc.
"CHECKED"
Means the item has been tested, or checked for presence, or
absence, etc. It also implies "Set," below.
"SET"
Calls for an item to be set a certain way. |
Each flight must begin with the usual preflight planning, weather and NOTAM
checks, airport data, fueling, oiling, adding hydraulic and ADI fluid, etc.
Upon arriving at the airplane, scan it from a distance for any obvious
abnormalities, such as a missing engine or removed tail.
An external preflight may start anywhere, and go around the aircraft in
either direction. This description will start at the nosewheel and proceed
clockwise. The main thrust of any external preflight is to look for ANYTHING
abnormal, and for "general condition," leaks, dents, damage, etc. No
effort will be made here to call out "general condition," as that is
assumed. Only the special items, or those unique to this aircraft will be
mentioned.
- Nose gear Steering link connected
- Safety pin removed
- Accumulator AIR pressure 1,000 or more
- Hydraulic pump switch down and guarded
- Nose gear doors connected
- Forward belly door handle secure (must be within about 1/16th inch of
touching the stop)
- Cabin Compressor Inlet clear
- Fuel drain from outside wheel well
- Fuel drain from inside wheel well
- Main gear pin "Dishpan" secure
- "Boston" gauges indication (record)
- Repeat on other side
Nothing special on the inside, check all doors, loose items.
After the external and internal preflight visual inspection, each
crewmember will take his seat, "make his nest," fastening the seat
belt and shoulder harnesses, adjusting the seat, and setting up personal
equipment. Each will then survey the cockpit in an organized fashion,
following a personal "flow," or the one suggested here. One method
would be start at the circuit breaker panel (usually checked as the cockpit is
entered), then proceed outboard to the rear outboard panel, work forward,
across the instrument panel (taking each row of instruments in turn), down
along the pedestal, then from the rear of the overhead, down and forward.
This is a highly detailed examination, realizing that many of the items
will NOT be on subsequent checklists! The person performing this
"flow" must THINK about what the item does, what it controls, and
where it should be positioned for takeoff, if possible, for engine start if
not.
Author's Note: Here's where I run into a lot of
resistance. The nay-sayers whine, "But we only fly these airplanes 20
hours a year, we can't possibly be expected to remember all that! PRECISELY!
When you sit down and try the "flow" after being away from the
airplane for a couple of months, and it seems difficult, that's your clue
you NEED to go over every item in the cockpit, and either pull out the
manual, or do some review with other crewmembers! The "flow"
FORCES you to review!
This "Before Start" checklist is intended to be run without
electrical power. This will conserve the battery power for the critical engine
start, but will get many time-consuming items done so that only a few items
are left to do between turning the battery on and hitting the starter.
Author's Note: Airlines and the military almost
always used an external power cart, a luxury we do not have. A battery start
was considered to be almost an emergency procedure. For us, it is normal,
and we have adapted our procedures to that.
The written checklist should be held in one hand, with the thumb gripping
the front side AT the item being called, as a "pointer." This should
not change until the item has been covered.
Author's Note: I know, that's really getting
basic, but you see, I'm anticipating having some Navy pilots, here. You know
the type, "When the big hand is on the twelve …"
If the checklist is interrupted, it's good technique for the RS to say,
"Holding at ," and place the checklist in an
obvious location as a reminder. The PF should come back to it with something
like "Let's continue the checklist, what was that last item?" Only
when BOTH crewmembers are POSITIVE that they are looking at the last item
completed should the checklist go forward.
External/Internal Preflight · · · · · · · ·
· · COMPLETE
At least one crewmember is expected to do a thorough external and internal
preflight inspection of the entire aircraft. By the time this checklist is
executed, this must have already been completed. One pilot might say, "I
did the outside, but not the inside," and the other might say, "Ok,
I got the inside." Or, "Ohmigosh, I did the outside, too, did you do
the inside?" If not done properly, one seatbelt gets undone, and the
interior preflight gets done before proceeding with the checklist.
Steering Link · · · · · · · · · · CONNECTED
This extremely important item must be checked visually by at least
one crewmember. If no one in the cockpit can positively remember checking it,
get out of the seat and check it again.
|
WARNING
Failure to disconnect this link for towing, or to connect it for
taxiing will result in major damage, and possible loss of the
airplane. |
Paperwork, Logs, Forms · · · · · · · · · ·
COMPLETE
This is a reminder to make sure all paperwork requirements have
been met, the logs are on board, and sufficient blank forms are on board.
Weight and balance must have been considered, all fluid quantities recorded,
etc. This is one of those items that is not directly involved in safety of the
airplane, but can be very embarrassing if overlooked, AND often is.
Movement Report (1-800-545-9758) · · · · · · ·
· · · COMPLETE
Self-explanatory. Only on this checklist to cover "The
Embarrassment Factor."
Author's Note: The CAF requires notification of
all flights, officially known as a "Movement Report," unofficially
known as "Calling Mother." "Mother" is Kelly Wimberley,
at HQ in Midland, who prepares "Movement Awards" to be presented
to a few deserving pilots at the big annual "CAF AIRSHO," also in
Midland. The good guys who were timely and accurate all year with their
reports get golden-colored ones ("The Golden Movement Award"),
those who didn't do as well get them in the appropriate shade ("Brown
Movement Awards"). Yes, that's what they look like, too.
Circuit Breaker Panels · · · · · · · · · ·
"_______"
All circuit breakers must have already been checked, and the
respondent should call out any exceptions (such as the compressor disconnect
circuit breaker, normally left off).
Fuel, Oil, Hyd, ADI Quantity · · · · · · · ·
· · "_______"
Respondent should review and reply with the QUANTITY of each fluid.
For example, "1,500 gallons of fuel, 25 gallons of oil in each engine,
Hydraulic quantity is correct for this system pressure, 15 gallons of ADI,
enough for several takeoffs." Use extreme caution, as the cockpit fuel
gauges are marked in POUNDS, while the "Boston" gauges are marked in
GALLONS.
Author's Note: "Boston" gauges are
mechanical indicators in the lower surface of the wing, no power required.
Due to the dihedral, the lower/inner one shows up to about 400 gallons, the
higher/outer one shows up to about 835 gallons, with a tank capacity of
about 865 gallons (only the two wing tanks). Does anyone know the origin of
the term "Boston Gauges"?
Emergency Air Pressure · · · · · · · · · ·
"_______"
This direct reading gauge should have been checked at this point
(during the "flow"), and should contain about 2,000 PSI.
Author's Note: This is a very small bottle that
will blow the gear uplocks, and provide a few brake applications in the
event of a hydraulic failure.
Gear Pins, Pitot Covers · · · · · · · · · ·
REMOVED
RS MUST look across at the bulkhead behind the LS, and carefully
count THREE pins present, then respond. One or both should specifically
remember removing and stowing the pitot covers.
Author's Note: I may someday tell the story of
how I came to be in the left seat of a certain Martin 404 with the nose gear
pin still installed. For now, let's just say I'm sensitive on this subject.
Gear Handle · · · · · · · · · · DOWN
RS should make sure the gear handle is horizontal with the safety
latch stowed. This should have been checked during the "flow," and
checked again now.
Hydraulic Bypass Valve · · · · · · · · · ·
DOWN
Self-explanatory.
TOLD, Crew Briefing, Speeds · · · · · · · ·
· · COMPLETE
"TOLD" is standard terminology for "TakeOff and
Landing Data," usually a card or paper with "The Numbers" on
it. This data should have been ALREADY determined and discussed. This is the
time to discuss it and make sure both pilots know the numbers and the
intentions of the PF, both for the normal taxi route and departure, and any
emergency return.
At this point, the aircraft should be ready for electrical power. When
cleared to start, the PF should turn on the battery, check the bus voltage for
22VDC or more, make sure the beacon light is on, check the fire warning system
and all other warning lights, pull the gear safety latch out to check that the
three green gear lights extinguish, return it to the normal position and make
sure the green lights come on again. If not already set, the parking brakes
must be set at this time. After doing this, the PF should call for the
"remaining items," or "below the line."
· · · · Elecrical Power On · ·
· ·
Beacon Lights · · · · · · · · · · ON
Note this switch is best left on at all times, even with the
battery off. This serves as an external warning that there is something going
on in the cockpit, and it may serve to remind a careless crew that the battery
has been left on after they leave the cockpit.
Author's Note: Some complain this drains the
battery, but it really isn't that much of a load, and the very real safety
benefits far outweight this small disadvantage.
Warning Lights, Fire Test · · · · · · · · ·
· COMPLETE
The gear lights, all warning lights, and the fire detection system
should have been checked at this point.
Parking Brakes · · · · · · · · · · SET,
PRESSURE "____"
Minimum HYDRAULIC brake pressure (as shown in the cockpit) is a
judgment call, and requires specific knowledge of this system. If the cockpit
hydraulic pressure gauge shows zero, chocks should be used for the start. If
it shows anywhere between approximately zero and 1,000, the system must be
serviced. Anything over 1,000 is normal.
Author's Note: Many get confused on this subject,
as it involves "accumulators," not often found on small GA
aircraft.
At this point, the aircraft is ready for engine start. The start is done
entirely from memory.
The right engine will almost always be started first to produce hydraulic
pressure for raising the airstair. The airstair CAN be raised with the
emergency hydraulic pump, but it is a very heavy load on the battery, better
conserved for the start.
|
WARNING
Starting with a low battery may leave insufficient battery power
to continue cranking for a fire during the start. |
RS must turn on the "STARTER ARM" switch on the RS console.
Either pilot may start either or both engines, but this overview assumes
"LS" will be start both.
Author's Note: Convair must have been REALLY
worried about inadvertent prop movement, because there are no less than FIVE
separate switches that must all be in the proper position before the starter
actually turns!
Turn on the right boost pump and check that the right low pressure light
(DC) extinguishes.
Note that no other indication of fuel or oil pressure exists at this point,
as the inverters are not on in order to conserve battery power. LS moves the
starter selector to the right, and then squeezes the two starter switches
together. RS watches and counts blades aloud as "three, six, nine,
twelve," and (if requested) switches the right mags on at 12 blades
(cold) or six (hot).
(Airline pilots count "One, One, One, …")
Author's Note: The following describes the
"controlled quantity start," or "primer start," most
often used on big radials. There are other ways to do it, but this is the
favored one. The engine is started solely on the primer, with the mixture in
idle cutoff.
LS primes carefully, by "tickling" the primer. The primer system
on this engine is MUCH more powerful than many other R-2800 installations. In
general, steady prime, even when cold, will not work as well as
"tickling" the primer switch. This is something of an art form,
taught only by experience. When cold, you might use half a second of prime,
and then one second of "no prime." That will probably be enough to
get it going. Once the engine is running smoothly, full prime on a cold day
may work, but be alert for signs of flooding, and be ready to momentarily stop
priming. If the primer is left off for too long, a backfire will surely
result. If the engine is hot, use just a touch of prime, then wait a couple
seconds.
If a CAF ground crew member is watching, he will signal with a "Thumb
down" that fuel is dripping or running from the blower drain, a sign that
the engine is overprimed. Priming should cease until he gives the "Thumb
up," indicating the dripping has ceased.
Author's Note: If the ground crew waves one hand
in a large, horizontal figure eight, it means "You have a fire."
The seriousness of the fire can be judged by the size of his eyeballs, and
his direction and speed of movement.
If there is no ground crew present who knows this technique, then the pilot
on the side being started must lean out and watch for the fuel (and fire),
calling it out to the pilot starting the engine. To this end, the RS may have
to start the left engine, while the LS watches for fuel.
|
WARNING
Too much prime will result in a serious "torching"
fire inside the cowl, which may be visible either at the upper cowl
flap, or the rear end of the augmenter tube. KEEP CRANKING, and get
the engine running! |
Once the engine is running smoothly on the primer alone, turn on the #1
inverter to power the (AC) oil pressure instrument and check the oil pressure.
If that appears normal, advance the mixture to AUTO-RICH, wait for the engine
to flood and start losing RPM and then release the primer switch.
[An alternative trick on this airplane only is to move the mixture
forward just a few inches, then pull it back against the mechanical stop that
prevents inadvertently moving to ICO (Idle Cut Off). This will usually give an
excellent idle mixture for ground operation. Once both engines are warm, it
will usually be beneficial to remove the stop, and lean each individually for
maximum RPM for ground operations.]
After the primer switch has been released, LS should turn off the right
boost pump and check the right fuel pressure. RS should check hydraulic
pressure (main and brake), cabin compressor oil pressure, and AC/DC electrical
on the right engine. At 1,000 RPM, the generator should supply some output,
which will assist the battery in starting the left engine.
With a well-charged battery, all inverters may be turned on even before the
right engine is started, if necessary. With a low battery (less than 22V),
they should probably be left off, except perhaps for momentarily checking the
oil pressure.
Once the right engine is running, the airstair should be retracted by the
crew chief.
|
WARNING
It is imperative that the person closing the main door knows
exactly how to do it. Great personal injury can result from getting a
face full of the door structure, and failure to properly engage the
latches my result in loss of the aircraft. |
Note that with one engine running and one stopped, this is the only
opportunity to determine FBP (Field Barometric Pressure) unless the inverter
is turned on before the right engine is started.
Author's Note: "FBP is the Manifold Pressure
before the engine is started. When the engine is run up at high power later,
setting the manifold pressure to exactly that number will produce a
specified RPM at all elevations, under all conditions, unless there is
something wrong with the engine. This is a VERY accurate power check. The MP
gauge in this airplane is AC powered, so it will not work at all until one
main inverter is turned on.
While the door is being closed, the LS pilot may start the left engine in
the same manner as the right. However, if the main door is closed after the
left engine is started, remember that all doors are connected to the
"Door Open" light, and it MAY remain on even after the main door is
properly locked. This would necessitate lowering the main airstair again and
having one person descend right in front of a running prop. He will then need
to go check the outside handle on the forward belly, which is very close
behind the right prop, also running.
For this reason, it is general policy to wait until the forward airstair is
closed, AND the "Door Open" light has extinguished before starting
the left engine.
|
WARNING
Do not allow passengers to use the airstairs while the LEFT
engine is running. At the discretion of the PIC, a crewmember may do
so, but this is strongly discouraged as a policy. |
With both engines running, LS pilot should turn off the left boost pump and
check the left fuel pressure, return all starting switches to the neutral
positions, turn on both inverters, and call for the ground power (if used) to
be removed. RS should return the "Start-Safe" switch to
"Normal," turn on the window heat (low), and check the electrical
systems (DC and AC) on the left engine.
It is also recommended at this point to reduce RPM below 1,000, then move
each mag switch from BOTH, to RIGHT, LEFT, OFF, BOTH to make sure that both
mags are "live," and that ignition grounding is normal when the
switch is OFF. Then increase RPM to somewhere between 900 and 1,000, again.
Author's Note: This is actually an excellent
procedure to use in ALL aircraft with mags.
The "flow" is complete, and the LS will call for the "After
Start" checklist.
Important note: CAF policy FORBIDS operating CAF engines in "Auto
Lean" on the ground (possible exception: Holley carburetors). It serves
NO useful purpose, AND it creates the risk of taking off in Auto Lean, with
possible detonation and engine damage. The engines MUST be operated in Auto
Rich at all times on the ground, OR MANUALLY LEANED to the point of near fuel
starvation. This WILL prevent fouling, and it WILL prevent an inadvertent
takeoff in Auto Lean. Manual leaning is highly recommended on these engines.
Author's Note: This is also true of most recip
engines on the ground. Almost all of them idle too rich, and it's even worse
at higher elevations.
In the C-131, manual leaning on the ground is very easy. Initially just
pull the mixture all the way back to the mechanical stop that prevents
inadvertent shutdown in flight. Then release the stop, and gently lean for
maximum RPM.
DO NOT USE AUTO LEAN ON THE GROUND!
Once the "flow" is complete, the PF calls for the "After
Start" checklist.
Engine Instruments · · · · · · · · · ·
NORMAL
Cabin Compressor Oil Pressure · · · · · · · · · · "____"
These two should have been already scanned for "normal"
during the flow.
Starter Arm Switch · · · · · · · · · ·
NORMAL
This is the switch on the RS console. It should have been returned
to "Normal" by the RS when starting was complete.
Author's Note: This dual function switch enables
the starter circuitry, and closes/disables the heat source valves in each
nacelle during start.
Window Heat · · · · · · · · · · LOW
Should be in "Low" (this is for bird impact protection,
not anti-icing!)
Generators, Inverters · · · · · · · · · ·
ON, CHECKED
RS should have already checked all electrical indications by
switching through all positions on both selectors right after both engines are
running.
Ground Power · · · · · · · · · ·
DISCONNECTED
Confirm by signals from the ground that it has been removed, and
the aircraft is clear.
Door Light · · · · · · · · · · OUT
Confirm this light is out (whoever closes the door should also
watch it as the door is locked for a positive indication that all doors are
closed).
Hydraulics · · · · · · · · · · CHECKED
An excellent way to check hydraulics is to extend the flaps to the
takeoff position. This assures that the entire system is working properly, and
that there will be brakes available. It also adds a bit of redundancy for the
flaps, to "do" them now, and "check" them later.
Time Out · · · · · · · · · ·
"____"
Unlike most items on this checklist, this is not a safety item. But
it is so often forgotten that it is added here.
At this point, the aircraft is ready to move. Oil temperature is seldom a
problem, as the aircraft will move away with about 1,000 or 1,100 RPM. If more
than 1200 RPM is required to initiate movement, wait for 40ºC on the oil
temperature. Oil temps are very slow to start moving on this airplane, but
once they do start moving, they rise quickly.
Author's Note: Very old classic rule with big
radials, "Do not exceed 1,000 RPM until oil temperature is moving, and
do not exceed 1,200 RPM until oil temperature is 40ºC. This is a fairly
"religious" item.
Author's Note: An interesting sidelight. Many
pilots erroneously think these temperature considerations apply to TAXI!
Some manuals even have this! They will sit in the parking spot, waiting for
the oil temps to rise. Folks, the engine doesn't know if the airplane is
taxiing, or stopped!
LS should call "Clear right side?" He should wait for an
affirmative response, and check the left side clear before moving. 1,000 RPM
may be enough to start moving. It may take a little more with a heavy
airplane, but rarely over 1,200. As soon as the aircraft is moving, check the
brakes gently, and the RS should note that the brake pressure cycles and
remains normal. During the first turn, check that the needle and ball respond
properly, and that the directional instruments rotate and indicate the correct
headings.
Reverse is NOT normally checked, as once it is checked, there is no
assurance it will work the "next time," and it simply wears out the
machinery. It is not required for takeoff, abort, or return for landing.
Once clear of the ramp and all obstructions, and during taxi to the runway,
the "Before Takeoff" checklist may be started. Every item requires
the full participation of both pilots.
Flight Instruments · · · · · · · · · ·
CHECKED & SET
This is a reminder that the instruments should have been set and
checked (altimeter, headings, radios, etc.). It's not a bad idea to review
them again at this time.
Flaps · · · · · · · · · · "____",
SET
Flaps should be confirmed at the correct setting for takeoff, by
BOTH pilots, and called by both. (RS challenges, "Flaps." LS says,
"Takeoff Flaps "__" set." RS says, "Takeoff flaps
"__", set.")
Trim · · · · · · · · · · 1, 2, 3, SET
Both pilots should check that the pitch trim is set for about 5
units up, and that the other trim tabs are set to zero (or slightly offset
from previous flight, if desired). Both pilots respond, in turn.
Takeoff Data · · · · · · · · · · REVIEWED
PF reviews aloud, confirmed by PNF. This has all already been
reviewed and briefed before the engine start, but it's not a bad time to
re-review the speeds, and anything additional.
Warning Lights · · · · · · · · · · CHECKED
Checked and called by both pilots. None should be on.
This completes the checklist as far as it can be done without a runup. If
no runup will be performed (as for an immediate takeoff after landing),
proceed with the checklist during taxi.
· · · · Runup · · · ·
Runup is quite conventional, and performed from memory. 1500 to 1700 RPM,
check the props for smooth function, and for a minimum governed RPM of 1,200
when the "Low Lights" illuminate. If more than one cycle is needed,
it is NOT necessary to run the governors all the way to "High
Lights," just toggle them up to 1,700 RPM, then toggle them back for the
next cycle. The full run between "High Lights" and "Low
Lights" should be about 14 seconds.
Still at 1500 to 1700 RPM, push each feather button in turn, check the
amperage draw on the ammeter, check the red light comes on in the button,
check the RPM drop (very quick on this airplane) and pull the button out to
the "neutral" position. If you inadvertently pull the feather button
out (beyond neutral), the RPM will decrease to about 1200, but the button does
not remain out by itself.
Carburetor heat should NOT be checked during runup, or within about five
minutes of takeoff. If this check is requested by maintenance, it should be
checked right after engine start, or during early taxi.
Engines should be run up to Field Barometric Pressure together, and a power
check noted (2100 RPM, at FBP on the left engine, about 50 RPM less on the
right due to the load of the cabin compressor). Engine instruments should be
quickly scanned, and mags should be checked, taking at least five seconds on
each mag. Further high-power runup will unnecessarily heat up the engines, and
should be avoided. If preferred, engines may be run up one at a time. That
reduces the time at high power slightly, but prolongs the total runup time.
With the runup complete, the aircraft is ready, and the checklist may be
continued to get more items done in preparation for takeoff.
Mixtures · · · · · · · · · · AUTO RICH
This item is to catch the case where the mixtures have been MANUALLY leaned,
and forgotten. It also helps those who insist on using Auto Lean on the
ground, from long habit. If anyone does that on this airplane, they will not
be on this airplane very long.
Auto-Feather · · · · · · · · · · ON, THREE
LIGHTS
Both pilots should make sure the single auto-feather light next to
the switch is on, and (VERY important!) also make sure the red lights in the
feather buttons are ON, indicating the torque sensors are working. Both pilots
should respond.
ADI · · · · · · · · · · ON, TWO LIGHTS
Similarly, both pilots should make sure the ADI switch is on, and
that both lights are on. Both should respond.
Props · · · · · · · · · · HIGH LIGHTS
Both pilots should check the prop lights are on, and respond to
that effect. Some will push the switches forward to make sure they don't go
out, and others will take the additional step of pulling them back, checking
the lights extinguish, and then pushing them forward again, checking again for
"high lights."
Author's Note: These are the very interesting
"Step Head Motor" switches, controlling small DC motors right on
the prop governor. This system replaces the long cable runs, so difficult to
design, install and maintain through a pressure vessel. It has the
disadvantage that an electrical failure means loss of prop control, and the
RPM will stay where it was when the electrical failure occurred. These are
NOT, however, "electric props," but normal Hamilton Standard
props, operated by engine oil. Only the control method is
"different."
Cabin Air Control · · · · · · · · · ·
AUTO/ALT
This is to catch the situation where "Cool" or
"Heat" has been selected on the ground. These "ground
only" positions are forbidden for takeoff.
Flight Controls · · · · · · · · · · FREE,
CORRECT
Flight controls should have been checked, and both pilots should
respond. Consideration must be given to winds and potential prop/jet blast on
the flight controls. If there is any risk of controls being blown against the
stops, this step should be delayed until taking the runway.
At this point, the aircraft is ready to line up on the runway, and the
checklist should be stopped here until cleared into position.
When cleared onto the runway, the PF (or PNF, if requested) should turn on
the boost pumps, set the cowl flaps to "Mid," and turn on the
transponder, then call for the "final items."
· · · · Taking Runway · · · ·
Boost Pumps · · · · · · · · · · ON
Transponder · · · · · · · · · · ON
Should be in the "Normal" position.
(We are probably going to change the location of this item, and make it
happen sooner, in order to reduce the number of things that are being done as
the aircraft moves into position. Turning on a transponder early (and turning
it off late) no longer messes up ATC radar.)
Cowl Flaps · · · · · · · · · · MID
Cowl flaps should be in the "Mid" position.
Time Off · · · · · · · · · ·
"____"
PNF should note the time off, or start a timer running.
See page 2-20 in the "Dash 1."
The takeoff procedure is fairly complex, and pilots should practice the
sequence and timing until it is second nature. There are many things to do,
and they occur very quickly.
It is also very important (and required by FARs) to understand and consider
takeoff performance. Highly detailed charts are provided in an extensive set
of charts in the appendices, unlike earlier aircraft that are flown "by
the seat of the pants." Pilots will be expected to have a fair
understanding of these charts.
Technically speaking, this aircraft does not have V1 and V2 speeds, for
they are mentioned nowhere in the manual. The military manual (the official
manual for this airplane) speaks of "Refusal Speed", which may be
considered as roughly synonymous with "V1," as used in the airline
world, and "Takeoff Speed," which is very roughly synonymous with
"V2." We will use "V1" and "V2" as a useful
"shorthand" for these terms, recognizing that this is only
shorthand.
In principle, all takeoffs will be made at flaps 15, a field elevation of
3,000' density altitude or less, with 5,000 feet of runway length or more, and
with no tailwind. If those parameters are met, the tabular data on the
checklist may be used. If they are exceeded, then takeoff performance must be
thoroughly investigated in the proper appendices of the "Dash-One,"
and takeoff must be made within those limits.
"Rolling takeoffs" are permitted. Many pilots prefer bringing the
airplane to a complete stop in position. Either way, both engines will be
brought up to some significant power setting (about 30" MP), a final
engine check should be done, and the red lights in the feather buttons MUST be
extinguished (at about 25" MP, or 80 BMEP). If the stop was made, the
brakes should be GENTLY released. Do not delay with engines at 30", as
the cylinder head temperatures will already be rising quickly.
|
WARNING
If either red light fails to extinguish at about 80 BMEP, the
takeoff must be aborted, as that prop will probably automatically
feather when the MP reaches about 45", and the throttle switch
"makes." |
Always abort for ANY malfunction of the prop system.
Author's Note: The term "BMEP" will be
a strange one to many AVweb readers, and an old familiar friend to others.
It is synonymous with "torque," and is a very accurate indication
of actual torque delivered to the prop shaft.
The PF will bring the manifold pressure up to full maximum power smoothly
and aggressively, with the PNF assisting with the final setting as needed, and
blocking throttles from overboost. RS will then place BOTH HANDS on the YOKE
(whether PF or PNF), and will hold the yoke as needed for crosswinds, while
the LS steers the airplane with nose gear steering during the initial roll,
until rudder control is effective.
|
WARNING
FAA and CAF regulations, and good airmanship absolutely demand
the use of full takeoff power on all takeoffs. |
After brake release and the feather lights extinguish, and before reaching
80 knots, there will be a few seconds of acceleration with little else to do,
and this is a good time to do a last scan of the engine instruments. The PNF
should do this, and report "Engines ok."
Starting at about 80 knots, four things occur in rapid succession.
(1) PNF will call "Eighty Knots" when he sees it, and the PF will
confirm that approximate reading on his own airspeed indicator. A major
difference (or no indication on either side) is cause for an abort, and either
crewmember may take that action before 80 knots. After 80 knots, only the PIC
may actually abort the takeoff.
(2) No later than 80 knots, LS will move his left hand off the nose gear
steering wheel. The PF will call "My Yoke" (LS), or "My
Steering" (RS), and the other person will acknowledge with "Your
yoke" (RS), or "Your steering" (LS).
Author's Note: This is very confusing to those
who have never flown this configuration. You don't want pilots fighting for
any of the controls (NGS, yoke, rudder pedals), so the transition must be
made very, very clear.
(3) The PF will, at that time (now passing about 90), lift the nose enough
to extend the nose gear strut fully, and allow the airplane to fly off in that
attitude. It should lift off just after passing V2.
(4) As the airplane passes refusal speed (V1), the PIC will take his hand
off the throttles, as the clear and universal signal committing to the
takeoff, even with an engine failure. (In other words, the PIC is required to
keep his hand on the throttles until refusal speed, and then is required to
move his hand OFF them after refusal speed.)
When the PF is positive the airplane will not contact the runway again, he
will call "Gear Up," also giving the classic "Thumb Up"
motion. The PNF must confirm the aircraft is well clear of the runway and not
likely to settle back. One common technique is to observe an "up"
indication on the vertical speed indicator, call "positive rate,"
and then call for or retract the gear. With some old airplanes, this may delay
gear retraction a bit more than desired, as the initial climb rate is very
low, and the VSI may lag for several seconds.
After the liftoff, there are three possible speed/climb options. THIS IS
NOT A JET, and no major pitch up is EVER permissible! (Author's note: One of
the most difficult habits to break in those who have flown only jets is the
"Rotate" syndrome. Correct in jets, but BAD in recips! Recips are
flown off the ground, not pulled off.)
(1) The most common technique with a normal airplane and no obstructions is
to simply hold the liftoff attitude while increasing speed and altitude
together. (If an engine quits after liftoff, this same attitude will be very
close to what is needed to maintain the desired speed (not below V2)).
(2) With real obstructions that demand max performance, pitch up slightly
to maintain V2+10 until the obstructions are cleared, then lower the nose to
the liftoff attitude and accelerate.
(3) With an engine failure, maintain the speed at failure, but not below V2
until a safe altitude is reached. A stable attitude is key here, and it will
be very close to the normal liftoff attitude. "Safe altitude" is
very much a PIC decision, but many will arbitrarily select the altitude used
in certification, 400 feet, after which acceleration begins. However, if there
are no obstructions, acceleration may begin immediately, as with (1) above.
Regardless of the profile selected, at 120 knots and accelerating, the PF
will call "Flaps up," then "METO Power." The idea here is
that power should not be reduced to METO unless and until takeoff power would
not be required if an engine quit. Below pattern altitude, always maintain
power and configuration as if you KNOW an engine is going to fail.
Author's Note: On approaches, I see a lot of
pilots "dirty up" long before it's necessary to do so. If I'm
instructing when they do this, I will instantly simulate the failure of one
engine, and then the fun begins. They will go through a flurry of gear
and/or flap retraction, putz around figuring out which engine is out, move a
whole bunch of unnecessary controls, and almost invariably they will need
"desperation power" in order to make the runway. If they make the
runway (they often don't), the comment is "Boy, the performance on one
engine is really poor!" No, it isn't, they just royally screwed up. If
they'd kept the airplane "clean" until descent is required, and I
cut an engine in the same place, they usually can get away with just raising
one eyebrow, easing the power up a bit, and continuing the approach with no
other action. If there is time, they may choose to go through the
"identify, feather" drill, but the whole maneuver is far less
critical. Back to the takeoff.
Note: When very heavy, the PF may wish to delay the
call for METO, to 500 feet agl or so, but observing the two-minute
limitation unless an engine is out.
Note: The two minute limitation for TAKEOFF power does NOT mean
the engine will melt down, or fail if TAKEOFF power is held for longer.
TAKEOFF is a power setting that is good indefinitely, but if the two minute
limit is consistently exceeded on many takeoffs, engine life (TBO) may be
reduced.
When the airplane is "clean," the climb is stable at 140 knots or
better, and sufficient altitude has been gained (usually 400' to 500' agl when
light, perhaps 1,000' agl when heavy), the PF will call "Climb Power,
Autofeather off, ADI off." The PNF will perform those actions. As with
the reduction to METO, do not reduce to Climb Power until METO would not be
needed with an engine out.
Note: The next higher power setting may be selected if an engine
fails, but using the procedure above, the increased power won't be needed
quite as soon.
After passing about 1,000' agl, the boost pumps should be turned off one at
a time, and the hydraulic bypass valve should be moved to the UP position.
Once outside the traffic pattern area, the PF should call for the "After
Takeoff" checklist, and the PNF may either call it, or do it silently.
Auto-Feather & ADI · · · · · · · · · ·
OFF
Confirm these switches are off.
Gear · · · · · · · · · · UP
Handle should be secure, flat against the pedestal, latch stowed,
and all gear lights should be extinguished.
Flaps · · · · · · · · · · UP
Flaps should indicate fully up.
Hydraulic Bypass · · · · · · · · · · UP
Handle should be up, relieving all but brake hydraulic pressure.
Boost Pumps · · · · · · · · · · OFF
These should have been turned off one at a time, while observing
fuel pressure. A small drop is normal. If there is fluctuation (common with
hot fuel), they may be left on. (Boost pumps will almost always be required
above 11,000' DA, to counter bubbles and fuel flow fluctuation.)
There is no "Cruise" checklist, as engine and systems management
is a continuous, on-going matter throughout any flight. From memory, pilots
should set the desired MP and RPM. Power and performance charts are not the
easiest way to determine power settings, but they are certainly favored by the
old-time flight engineers. Here's a much simpler way. We know that:
| Horsepower = RPM X BMEP / 283 |
From this we find that at 2100 RPM (common figure from the cruise charts,
not too high, not too low), 140 BMEP produces about 1,038 HP. We don't care if
we produce 900 HP or 1100HP, both are reasonable (low and high) cruise power
settings, as is anything in between. What we DO care about is a proper
mixture. If we are going to end up at 140 BMEP after a "12 drop",
then our starting BMEP must be 152. Simply set 30" MP (momentarily), 2100
RPM, AutoLean, and then set whatever MP it takes to produce 152 BMEP. Let that
stabilize for about five minutes (for AMC cooling and stabilization), while
closing the cowl flaps as needed to maintain about 200º. Then, if necessary,
reset 152 BMEP, then lean for the 12 drop to 140. This automatically takes
care of temperature, pressure, and altitude. It may leave the MP needles
slightly split, and that's fine.
There is no "magic" about 200º CHT, and there is absolutely no
"minimum CHT," inflight. 150º CHT would be just fine, with no harm
to the engine. But 200º is about the hottest CHT that should be allowed for
long periods, for best engine life. The reason we try for 200º is to be able
to close the cowl flaps as much as possible, to reduce drag, and increase
airspeed. For example, if you have the power set properly, but are showing
180º CHT, the cowl flaps are too far open, with too much drag. Closing them a
bit will raise the CHT, decrease drag, and increase airspeed.
For all maneuvering flight (training, etc.), cowl flaps may be left in the
"MID" position, with CHT below 200º, even far below it, as drag
doesn't matter. For cruising flight, where "gallons per mile"
becomes important, try for 200º by cowl flap control, at the power setting
desired.
After about 15 minutes of stabilized operation, it is a good procedure to
turn the oil cooler control switches to the off position for the remainder of
the flight. This will prevent the automatic temperature control from
"masking" a sudden change in oil temperature, and will give earlier
warning of an engine problem.
For descent, keep the BMEP under 140, or some figure less than that to
control airspeed as needed. If mixture is a concern, simply set AutoLean. At
normal descent speeds, do not reduce below about 100 BMEP.
Somewhere within range of the ATIS broadcast, and at least ten minutes
before entering the traffic pattern, the crew should get the ATIS, discuss it,
and discuss and brief the arrival and landing, including speeds to be used,
whether reverse will be used, and the techniques involving the PNF. The PF
should make all intentions known to the PNF so that both know exactly what is
supposed to happen. If there is an instrument approach involved, all the
details must be discussed, and the radios set (or briefed) for the final
approach. The generic part of the briefing may be shortened to "Same as
previous," if the same crew has flown the airplane the same day, but this
shortcut should not be overused.
Both pilots should perform a "flow" very much like the one that
was done before starting, pre-positioning every possible switch and control in
the cockpit for landing.
At some fairly significant power setting, and in AutoLean or AutoRich, a
quick mag check should be done, listening and feeling for roughness. Even a
single plug failure can be felt, and this check will catch almost all such
failures, preventing a mission abort on the next flight. Some roughness is
normal if manually leaned.
Author's Note: This is a wonderful technique in
ALL aircraft with mags! It is a FAR more demanding test of the ignition
system than the 1700 RPM used in most GA runups.)
A thorough check of all the electrical systems should be performed, testing
both generators, both emergency alternators, and all inverters for proper
operation. Again, this may prevent a mission abort on the next flight.
|
WARNING
DO NOT turn generators off and back on when loaded, this may
cause a sheared drive shaft. It is sufficient to check the gauge
indications for each unit. |
After all that is done, the PF will call "Approach Checklist."
This should be done well before arriving anywhere near the airport area in
order that the crew can devote full attention to flying the airplane, other
traffic, and radio instructions.
Briefing, Landing Data · · · · · · · · · ·
COMPLETE
This should have been completed by this point.
Fuel · · · · · · · · · · "____",
TANK TO ENGINE
This should have already been done, but it's a good idea to recheck
that both tank switches are ON, and the crossfeed switch is OFF. The
"blank" in the checklist response should be filled with with some
indication of quantity. This serves as a "fuel state awareness
check" during multiple landings.
Cabin Signs · · · · · · · · · · ON
Should be ON, and the cabin should be checked secure at least five
or ten minutes before landing.
Mags, Gens, Invs, Alts · · · · · · · · · ·
CHECKED
Should have been checked during the flow.
Emergency Air Pressure · · · · · · · · · ·
"____"
Recheck this direct reading gauge, which should show about 2,000
PSI.
Mixtures · · · · · · · · · · AUTO-RICH
Put them in Auto-Rich well outside the traffic pattern, and leave
them alone.
Hydraulic Bypass · · · · · · · · · · DOWN
This lever should be down, pressurizing the system.
Hydraulic Quantity · · · · · · · · · ·
CHECKED
The LS person must look back and down to the left, and describe
what he sees, with "Three quarters full," or whatever it is. There
are marks for a pressurized system, and for an unpressurized system.
See page 2-23.
The airport pattern should be entered at about 140 knots clean, or 120
knots with approach flaps. There are three key points that illustrate where
the gear should be extended if all is normal:
(1) Abeam the numbers on a visual downwind at 1,500' agl, about 120 knots,
(2) Intercepting the ILS GS or passing 1500' agl on GS, about 120 knots,
(3) Any other equivalent distance and altitude, about 120 knots.
When the PF calls "Gear Down, Landing Check," the PNF should put
the gear down, place the cowl flap switches in "Mid," turn the boost
pumps on, and by that time the gear should be down, three green lights should
be showing, and the hydraulic pressure should be normal. The PNF will
immediately begin calling the checklist.
Gear · · · · · · · · · · DN, 3 GREEN,
PRESS, QUAN
BOTH pilots should respond with the full response, pointing first
to the handle, then the lights, then the pressure indicator.
Boost Pumps · · · · · · · · · · ON
Cowl Flaps · · · · · · · · · · MID
PNF should verify that these switches are already set, and then
call, "Landing check complete, standing by flaps and High Lights."
Or, "Flaps and High Lights to go."
Props · · · · · · · · · · HIGH LIGHTS
The PNF should put his fingers on the prop switches as a reminder
to both pilots. Somewhere on short final, or when the RPM has dropped below
the governing range, or when PF calls for them, the PNF should move the
switches forward, and watch for the high lights to come on, call them, and say
"High Lights, Landing Check Complete."
PF will call for flaps as needed/desired. Flaps 28 will give outstanding
go-around capability with a minimum of control force change, at the expense of
more runway used for the landing, due to the lack of aerodynamic drag on the
landing roll. Flaps 40 will have a slightly lower stalling speed (about 4
knots), which is insignificant, but the landing roll will be reduced by the
additional drag. In either case, reverse is very effective.
|
WARNING
The airspeed must be 95 knots or less when crossing the
threshold with flaps 28 or more. The airplane really floats in ground
effect, and higher speeds will cause a touchdown far down the runway. |
At touchdown, the PF should call "Reversing!" This is the clue to
the PNF to pull the T-Handle, which moves the stop out of the way. PF must be
careful to pull only a small amount of power until the reverse lights indicate
reverse is working, then to modulate reverse power very carefully and gently.
This is not a jet transport, where the pilot can yank in full reverse to
mechanical stops until the reversers are locked, then pull full reverse! Use
no more than 30" of manifold pressure in reverse, and seldom that much,
unless running off the runway is imminent.
As the speed drops to 80 knots, the LS must call "Your yoke" (if
LS is PF), or "My steering" (if RS is PF), and move his hand to the
nosegear steering wheel. RS will hold the yoke firmly with both hands to
prevent buffeting from reverse, keeping whatever correction is necessary to
help hold the wings level in crosswinds.
When unreversing, the throttles should be moved forward past the reverse
stops, and the RPM must be very carefully watched to prevent the engines from
dying at low RPM and low airspeed.
Neither PF nor PNF should take any further action in the cockpit until the
airplane is fully down to taxi speed, and preferably clear of the runway. Do
not retract the flaps until (1) the brakes are checked, (2) system pressure is
normal, (3) aircraft is taxiing straight, no turns are imminent, and everyone
knows where it is going, and (4) there is no conceivable need for brakes in
the next few seconds. If there is any wind at all, or the final landing is
done, lock the controls.
When everything is stable, LS will say, "Flaps Up, After Landing
Checklist." RS will proceed with that, working silently. He should note
the time, raise the flaps for the next takeoff (or up, if done), turn off the
boost pumps, open the cowl flaps, turn off all unnecessary radios and
equipment (including windshield heat), do a grounding check on the mags, and
note all fuel, oil, and ADI quantities. Turn off the right inverter unless
another takeoff is going to be done. After doing that by "flow," run
the checklist.
Time On · · · · · · · · · ·
"____"
PNF records the time of landing, to calculate "Airborne" time.
Gust Locks · · · · · · · · · · ON
If the LS has not already called and done this, the RS should
suggest it, unless there is no wind and there will be another takeoff.
Author's note: Locking and unlocking the flight controls on
this aircraft is definitely a two-person job! LS will have left hand on the
NGS, and his right hand will be fully occupied by the gust lock device. RS
will need to center up first the ailerons, then the elevator, then the
rudder, as the gust lock mechanism engages each in turn.
Trim · · · · · · · · · · 1, 2, 3, SET
RS should reset the trim tabs for the next takeoff, normally 5
units up on the pitch, zero and zero.
Cowl Flaps · · · · · · · · · · OPEN
PNF should place the switches in the "Open" position, and
hold them there long enough to be sure all cowl flaps are open. A visual check
by each pilot is a good idea, too.
|
WARNING
Cowl flaps must be fully open at all times on the ground to
assure cooling, even in Arctic conditions. |
Boost Pumps · · · · · · · · · · OFF
Off for the taxi.
Flaps · · · · · · · · · · UP
Flaps should be up if the airplane is to be shut down, or set for
takeoff.
Windshield Heat · · · · · · · · · · OFF
Turned off, unless another takeoff is to be performed.
Unnecessary Equipment · · · · · · · · · ·
OFF
If the airplane is being taxied back for another takeoff, there is
little or nothing to turn off. If the final landing is complete, this includes
the windshield heat, all radios except the comm radios. The #2 inverter may be
turned off to reduce load.
Grounding Check · · · · · · · · · ·
COMPLETE
At some point during the final taxi-in, the RPM should be reduced
to less than 1,000, and each mag switch sould be moved to the OFF position
momentarily, then back to BOTH.
Fuel, Oil, ADI Readings · · · · · · · · · ·
RECORDED
These should be recorded, and reconciled with actual amounts,
later.
Author's Note: Fuel tracking is much more
important in this airplane than some. There is no way to physically
determine the amount of fuel in the wings. There are mechanical fuel
quantity gauges on the bottoms of the wings (gallons), and AC electrical
gauges in the cockpit (pounds). Only keeping track of "probable fuel
used," and "fuel added," and some combination of fuel
quantity indications, we can be reasonably sure of the fuel status.
Upon stopping at the ramp, LS should set the parking brake, check the
pressure, then shut down (or ask the RS to do so) the left engine with the
mixture so that the crew chief can lower the airstair. LS should turn off the
seat belt sign, and turn off the remaining inverter(s). When the airstair is
down, the right engine can be shut down with the mixture, wait for the prop to
stop, turn off all mags, and lighting, and finally, turn off the battery.
Parking Brake · · · · · · · · · · SET
Parking brake should be set until the wheels are chocked. If the
brakes are at all hot (pilot judgement), they should be released until cool.
Once cool, the parking brakes should be left SET for parking, unless towing is
anticipated. Chocks are of very little benefit in strong winds without the
parking brakes set, as the airplane will bounce around and nudge the chocks
away, leaving the airplane free. Parking brakes are by far the best way to
protect the airplane from wind, without a hangar.
Seat Belt Sign · · · · · · · · · · OFF
Inverters · · · · · · · · · · OFF
Mags · · · · · · · · · · OFF
Battery · · · · · · · · · · OFF
Check all four of these items "OFF":
Movement Close (1-800-545-9758) · · · · · · ·
· · · COMPLETE
Not a safety of flight item, but so often forgotten…
(And don't forget, Kelly passes those "Movement Awards.")
Gear Pins, Pitot Covers, Bird Blocks · · · · ·
· · · · · INSTALLED
A reminder to secure the outside of the aircraft.
Fuel, Oil Quantity · · · · · · · · · ·
CHECKED
Oil quantity should be checked if at all possible, before it has a
chance to drain down into the engine. Record all indications for comparison
with the cockpit indications.
(Replaces After Takeoff, Approach, Landing Checks)
When remaining in the traffic pattern for repetitive takeoffs and landings,
only a limited number of items are required. If all the checklists are run,
there are too many superfluous items, and the pilots will be too busy running
checklists, and not paying enough attention to other traffic, ATC, and flying
the airplane. This one highly abbreviated checklist is intended to be called
for and worked after the gear is down for the next landing.
However, in order to instill good habits, the PF should always call for the
"After Takeoff Checklist." The PNF should call "Complete"
without actually taking any action. Similarly, the PF should call for the
"Approach" checklist, and the instructor calls "Complete,"
again without taking action.
Fuel · · · · · · · · · · "____",
TANK TO ENGINE
During repetitive landings, especially touch and go landings, it is
very easy to lose track of fuel quantity, and this is the primary purpose of
this item.
Emergency Air Pressure · · · · · · · · · ·
"____"
Since this is the only source of backup brakes, it should be
checked on every landing.
Gear · · · · · · · · · · DN, 3 GREEN,
PRESS, QUAN
Boost Pumps · · · · · · · · · · ON
As on the normal landing check, the PNF should call,
"Checklist complete, flaps and high lights to go," keeping his
fingers on the prop switches in readiness.
Props · · · · · · · · · · HIGH LIGHTS
Again, the PNF should call, "Checklist complete, High Lights
to go."
(End Normal Expanded Checklist)
Here's
a link to the
actual (non-expanded, non-annotated) C-131 checklists we now use in the
airplane in PDF format (You will need Adobe
Acrobat Reader to view it.)
Be careful up there!
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