Barometric Instruments PDF

Summary

This document provides an overview of barometric instruments used in aviation. It covers the principles of operation, components, and calibrations, including the International Standard Atmosphere (ISA).

Full Transcript

WELCOME TO
BAROMETRIC INSTRUMENTS

1
I& Bar
I o
Objectives:
At the end of this lesson, you should be able to:

1. State the purpose and the main values of the
ICAO standard atmosphere.

2. List the main components and explain the
principle of operation of:
 Airspeed indicator
- Define the term `IAS’,`CAS’,`EAS’,`TAS’ and
`Mach Number’.

 Barometric Altimeter
- Define International `Q’ Code by
ICAO

 Encoding Altimeter

 Vertical Speed Indicator:
- Diaphragm- base
- Air chamber-base
I& Bar
I o
ICAO STANDARD ATMOSPHERE
ICAO – International Civil Aviation Organisation

ISA – International Standard Atmosphere

The purpose of ISA is to provide
standard values of the atmosphere as
a basis for the calibration of all
Barometric
ISA states Instruments.
the `Standard conditions at
MSL are:

1.A temperature of 15° C,
2.Air pressure of 14.7psi / 1013.25
hectopascal (hPa)/ 29.92 inch
mercury (in Hg).
I& DEFINITION OF ISA Bar
I
STANDARD o

(Pressure,Temperature,Altitu
The
de)
STRATOSPHERE
temperature (Height: 36,089 Feet)
remains
unchanged
(Temperature : -
at -56.5⁰ C from 56.5˚C)
36,089 feet,
where the As height increases
stratosphere temperature
begins. decreases at a rate of
2˚C per 1,000 feet
from MSL.
ISA Standard
temperature is
15⁰C at MSL
MSL (Mean sea level )
= 0 Feet
I& Bar
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AIRSPEED INDICATOR

Airspeed indicator displays the speed at which
the aircraft is moving through the air relative
to the surrounding air.
The aircraft speed is determined by measuring
the dynamic pressure caused by the forward
movement of the aircraft
Dynamic Pressure = Pitot pressure –
Static pressure
I& Bar
I
Airspeed o

Indicators

CALIBRATION OF AIRSPEED
Knots
INDICATOR standard
Kilometres per hour Glider
(Km/h)
Miles per hour (mph) Obsolete
Figure 1
I& Bar
I
DEFINITION OF AIRSPEED o

Indicated Airspeed

I
IAS is the uncorrected airspeed which is directly read
from the indicator.
Calibrated Airspeed
CAS is the IAS compensated for installation, instrument
and pitot static system errors.

C
Equivalent Airspeed
EAS is the CAS compensated for air compressibility. EAS
is found as the ratio between the actual air density and
the air density at sea level in the standard atmosphere
T
E
True Airspeed
TAS is the EAS compensated for the actual density
altitude, i.e. it is the true speed of the aircraft relative
to the surrounding air.
Mach
The Mach number indicates the aircraft’s IAS relative to
the speed of sound.
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Main Components of Airspeed Indicator

Airspeed indicator consists of the
following
 components:
Air tight case
Diaphragm.
Pointer drive
mechanism
Temperature
compensation
(Bimetallic strip)
Pressure connection
marked
- P for Pitot
pressure pipe
- S for Static
pressure pipe
I& Bar
I
Pressure sensing element of ASI o

Metalic capsule

The purpose of the diaphragm (Capsule) is to
measure the dynamic pressure (the difference
between the ram or impact pressure and Static
(atmospheric) pressure sensed by the Pitot Static
Tube
The difference between total pressure and static pressure
is called Dynamic pressure
The greater the difference between the 2 pressure readings,
the greater will be the airspeed indication
I& Bar
I
Functional Principle of an ASI o

A diaphragm is used as the measuring
element. The indication is based on the
measurement of a differential pressure,
resulting from the pressure inside the
diaphragm (= total pressure pt) and inside
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Summary on Principle of ASI

AIRCRAFT DIAPRAGM AIRSPEED
FORWARD SPEED INDICATOR
POINTER
Increase Expand Move up-scale
Decrease Contract Move down-scale
Steady airspeed & Remain unchanged Remain unchanged
height
Airspeed indicator pointer movement depends
upon the EXPANSION and CONTRACTION of the
diaphragm and it is proportional to the CHANGE OF
DYNAMIC PRESSURE
1. Explain the following situ:
a. Forward speed increase
with constant altitude.
P?
Pt ?
Diaphragm?
Indication?
b. Aircraft altitude ascending,
forward speed constant.
c. The diaphragm puncture.
InterMISSIO
N
I& Bar
I MACH AIRSPEED o

INDICATOR

To indicate the speed of the aircraft relative
to the speed of sound in Mach number
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I
Mach Airspeed o

Indicators
The Mach Airspeed
Indicator displays (in
a single instrument),
indications of the 3
primary speed
functions
Indicated airspeed
(IAS)
Maximum allowable
airspeed (Vmo)
Mach number (the
ratio between
aircraft speed and
the speed of sound)
I& Bar
I Main Components of Mach o

Airspeed Indicator

 air-tight case
 diaphragm (pitot
pressure)
 aneroid capsule
(static
pressure)
 temperature
compensation
(bi-metallic strips)
 Mach number dial
 maximum-airspeed
pointer Diaphragm
 Mach number Aneroid Capsule (Pitot Px)
adjustment (Static Pressure)
AIRCRAFT PITOTSTA
INSTRUME TIC
NTS SYSTEM

MACHMETER

The machmeter indicates continually
the fraction of the local true speed of
sound the aircraft is flying and
indicates as mach number (M).
AIRCRAFT PITOTSTA
INSTRUME MACHMETER TIC
SYSTEM
NTS

A basic P
machmeter has Aneroid
the diaphragm Capsule
with pitot
pressure inside
and static
When aircraft altitude
pressure
changes
outside. but airspeed
is constant, altitude
aneroid capsule
will change
Mach Indication

When airspeed
changes but altitude
is constant, airspeed Pt
diaphragm will
change Mach Airspeed Diaphragm
Indication.
AIRCRAFT PITOTSTA
INSTRUME MACHMETER TIC
SYSTEM
NTS

VARIATION OF THE SPEED OF
SOUND

The speed of sound varies as the square root of the
absolute temperature i.e. the speed of sound decreases
as the temperature falls with altitude.
In standard atmosphere conditions, the speed of sound
at MSL temperature of 15 deg is 661 knots.
Above 36,000 feet (stratosphere) at temperature -56.5C,
the speed of sound is 573 knots.

An indicated 0.7M at MSL at standard temperature
means that the aircraft is flying at 462.7 knots (i.e.
0.7 x 661 ).
The same mach number indication at 36,000 feet gives
aircraft’s T.A.S. of
401.1 knots. (i.e. 0.7 x 573).
I& Bar
I Indication of Maximum Safe Airspeed o

At high altitudes,
the maximum safe
airspeed
decreases due to
the decrease in
density of the air.
For high-speed
aircraft, maximum
safe airspeed is
provided in order
never to exceed An indicated 0.7M at MSL standard
temperature of 15°C the aircraft will be
this speed.
flying at 462.7 knots.
With the same 0.7mach number at 40,000
feet the aircraft will be flying at 401.1
knots.
Maximum safe airspeed is a function
of both the static pressure and the
Mach number.
I& Bar
I Indication of Maximum Safe Airspeed o

The effect of the Aneroid
static pressure: Capsule

1. Altitude Increase,
Static pressure
reduces,
Aneroid capsule
expand.

2. The movement is
transmitted via
rocking shaft,
sector assembly Airspeed Diaphragm
and pinion to turn
the pointer
counter-clockwise As a precaution, mechanical stop is pre-
over a scale. set so that the pointer never indicates a
speed higher than that being decided
3. This indicates a by the aircraft’s designers to be the
lower maximum maximum speed for structural safety.
safe airspeed
 COLOUR MARKING
OF
AIRSPEED
INDICATORS

The purpose of the Colour Marking
is to highlight specific limits of
operation
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COLOUR MARKING
OF
AIRSPEED
AirspeedINDICATORS
indicator’s colour markings
indicate certain minimum, maximum
and/or safety speeds or speed ranges.

Depends on aircraft indicator installed
position.

Modern systems may have movable
pointers.
I& Bar
I COLOUR MARKING OF AIRSPEED o

INDICATORS
The marking are in the form of arcs,
radial lines and sectors.
Maximum and
RED radial line
minimum limits

Take-off and
YELLOW
precautionary
arc
ranges

GREEN arc Normal
operating range

RED arc Range in which
operation is
prohibited Speed limit for certain
flight control condition.
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Colour Markings of Airspeed
Indicator
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Colour Markings of Airspeed
Indicator
Tebuan Fly-pass
rehersal incident
 Bar
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ALTIMETER o

To indicate the altitude of the
 Bar
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ALTIMETER

Calibrated in feet

The purpose is to provide an accurate
indication of the aircraft’s height above a
certain predetermined level
(QFE/QNH/QNE).

This height is referred to as the `aircraft’s
altitude’.
 Bar
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Main components of a
basic Barometric Altimeter
Main components:
air-tight case with static
connection (S)
aneroid capsule
gear mechanism
mechanism with calibration
spring
temperature-compensating
U-bracket
pointer group (or counter,
drum)
dial Sectional View of a Typical
Altimeter
 Bar
I&I Description of the Altimeter o

system

The altimeter is a
barometer that measures
the surrounding air
pressure in relation to
the pressure set in `hPa’
and/or `in Hg’ and
indicates this pressure as
altitude information.
 Bar
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Several types of indication can be found in altimeters.
The most common ones are:
the triple-pointer type,
the single-pointer with digital counter and
the single-pointer with drum presentation.

Prevailing atmospheric pressure is usually set to either
QFE, QNE or QNH and the indicator will indicate altitude
accordingly.
 Bar
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ICAO

International Civil Aviation Organisation

The ICAO Standard Atmosphere
Due to the dynamic behaviour of the air
mass, the ICAO standard atmosphere
has been introduced to provide
standard values of the atmosphere.
ISA states the `Standard conditions at
MSL are:

1.A temperature of 15° C,
2.Air pressure of 14.7psi / 1013.25
hectopascal (hPa)/ 29.92 inch
mercury (in Hg).
ALTIMETER, TRIPLE
P0INTER

1013
1011
10 10
1 09 0
1 00 8
06 7

10
1 00

05 4 9 1
0

0
1 00 3
1 00

8 2
1 002
1 01
10
1000
ALT
CALIBRATED CALIBRATED
1000
1009
TO TO
35,000 FEET 35,000 FEET1001
10
10002
7 1
10004
10 0
3
3

06 5
11

6 4
00 8
10 0
0
10111
10
1012

5
1013

7
0

QFE
09

Local Training
KANTIN

Flight within the country QNH
Overseas / Intercontinental Flight QNE
 Bar
I&I
INTERNATIONAL
QFE : Prevailing
`Q’ CODE o

pressure at an
airfield, the
altimeter would
read `Zero’ when
aircraft is on
ground at the
QNH : Prevailing
airfield.
pressure at an
airfield, the
altimeter would
read Airfield height Local Training
above local MSL
when being on
ground.
QNE : Airfield height
relates to standard
Flight within the country
ISA setting or
setting of Altimeter
to 1013.25 hPa is Overseas / Intercontinental Flight
called `Standard
Altimeter Setting’.
 Bar
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PRINCIPLE OF OPERATION
(HEIGHT vs CAPSULE MOVEMENT)

Remember!
An Aneroid Capsule

Increasing / Decreasing
Atmospheric Pressure
An increasing in altitude, will Aneroid
cause the capsule to expand capsule

A decreasing in altitude, will
cause the capsule to contract
I&I Summary on Principle of Bar
o
Altimeter
The pressure sensing element of the
Altimeter is an evacuated, seal metal
(aneroid capsule).
ALTITUDE PRESSUR CAPSULE POINTER
E
Increase Decrease Expand Clockwise
(Climb) s
Decrease Increase Contract Counter
(Descend) clockwise
As the aircraft resumes horizontal flight, the
capsule’s resilience and the atmospheric
pressure will be in a state of balance and the
new altitude is indicated.
 Bar
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Intermissio
n
 Bar
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Servo o

Altimeter
Servo Altimeter vs Barometric
Altimeter

Servo altimeter operates Barometric altimeter
with operates
electrical power only on pressure
Fast, Easy and accurate
reading

Both serve the same purpose, to indicate the
 Servo
Altimeter
 Bar
I&I Functional Principle of a Servoed o
Altimeter
The
movement
of the
aneroid
capsule is
transmitted
through a
linkage to
the l-bar of
an 'E' and '
I' inductive
pickoff.
The movement of the l-bar is a function of the pressure change.
Determines the amplitude of the a.c voltage output.
 Bar
I&I Functional Principle of a Servoed o
Altimeter
The phase of
the output
signal of the E-
bar will depend
whether the
capsule expand
or contract.

This output is
fed to a two- Figure
10
phase drag cup
servo motor via
an amplifier.
The motor is coupled by gear train to the
pointer and counter assembly, and also to
differential gear which drives a cam.
The cam with cam follower moves to
reposition the E-bar relative to the l-bar.
 Bar
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ENCODING ALTIMETER o

Encoding Altimeter also
Barometric
known as “Altitude reporting
Altimeter
Altimeter”
Encoding altimeter is a Aneroid capsule
altimeter indicating the aircraft’s altitude to
the pilot.
Additionally, it sends the same information
to the ground
(Air Traffic Control).
 Bar
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Description of Encoding o

Altimeter

ATC transponder at Mode C,
height info pulses are
transmitted to
the ground ATC
(in increments of 100 feet).

Principle of Transponder Operation
 Bar
I&I Main Components of an Encoding o
Altimeter
Main components
 air-tight case with static
(S) and
electrical connection
 2 aneroid capsules
 encoder with amplifier
 vibrator
 altitude counter
mechanism
 barometric scale with
adjusting knob
 Maingear
planetary parts:
mechanism
 Anfailure
opticalflag.
encoder disc
(made of glass)
Light sources
Photo-transistors
Electronic power supplies
An amplifier
Pointer mechanism Functional Principle of
Control spindle an Encoding Altimeter
Amplifier
 Bar
I&I To prevent the o
stiction or friction

Figure 12 Functional Diagram of an
 Bar
I&I Functional Principle of an Encoding o
Altimeter
Encoding Disc is made of
glass and etched sectors in
10 concentric rings which
alternately pass or block
light in accordance with the
10 bit code
called as “MOA-GILHAM”.
One revolution of the disc
covers the total indicating
range of the altimeter in
increments of 100 feet.
Fix blocks of sensor modules
consist of 10 LEDs and 10
light-sensitive Darlington
transistors.

The 10-bit encoding covers the altitude range from -
1,000 feet to +63,000 feet
Encoding Altimeter’s
Warning Flag comes
‘on’ when;

 In case of power
failure

 The altitude
information
is no longer
encoded

 The Vibrator is not
working
VERTICAL SPEED VERTICAL SPEED
INDICATOR INDICATOR
(Diaphragm- (Airchamber-
based)
based)
VERTICAL SPEED INDICATOR
(Diaphragm-based)
 Bar
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VERTICAL SPEED INDICATOR
(Diaphragm-based)

The purpose of the Vertical Speed
Indicator is to indicate the rate of
altitude change of the aircraft.
Uses Static pressure of the pitot static
system.
 Bar
I&I Vertical Speed Indicator System o
Description
It is a differential-
pressure gauge
designed to detect the
change of the static
pressure.
The diaphragm
senses the changes in
the static pressure and It measures the
indicates as rate of pressure difference
climb or descent in feet between the pressure
per minute / metre per inside the diaphragm
second. (changing static
pressure) and the
pressure inside the
housing/outside the
diaphragm (“equalizing
 Bar
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Main Components of an VSI
The typical diapragm-base
Vertical Speed Indicator
consists of the
following main parts:
Air-tight case with static
connection (S)
Diaphragm unit (bellows)
Gear mechanism
Calibration spring
Temperature compensator (bi-
metal) Sectional View of a
Vertical Velocity
Diffusor assembly (capillary Indicator (capsule base)
tube) A `zero adjustment ‘screw is located in the lower
Eccentric shaft assembly and
left corner of
the front casing to reset the pointer to zero.
 Bar
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PRINCIPLE OPERATION OF
VERTICAL SPEED INDICATOR
(Diaphragm-based)
The basic principle of the VSI/ROC is
that the static pressure/barometric
pressure is
a function of altitude.
The VSI is a differential pressure
gauge.
Measures the rate-of-change of the
static pressure inside and outside of
the diaphragm.
 Bar
I&I o

Unit of measurement of
ROC is in
feet per minute.

Range of indication of a
typical ROC is
0 to 6,000 feet/min.

The upper scale section
indicates climb and
the lower section At the end of the
indicates descend. indicating ranges the
pointer deflection is
limited by means of
mechanical stops.
I&I Functional Principle of a Bar
o

Vertical Speed Indicator
(Diaphragm-based)
STRAIGHT AND LEVEL FLIGHT

Level flight:
zero
If level flight is resumed, differential
the pressure difference pressure
equalizes within 6 to 9 sec across
pointer
and the pointer returns to diaphragm.
indicates ‘0’
`zero rate of climb’.
 Bar
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AIRCRAFT DESCENDING o

Aircraft Descend:
VSI / ROC
Metering unit
maintains
case pressure lower
than
diaphragm pressure,
at constant rate of
The metering
differential unit is used
pressure
to delay
across the pressure
the capsule
entering the case
of the VSI during descent
DURING DESCEND >
- the pressure inside the diaphragm is higher
than inside the case
due to the lag of the metering unit.

- The gear linkage from the diaphragm will
 Bar
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AIRCRAFT CLIMBING
Aircraft
Climb/Ascend: VSI / ROC
Metering unit
creates a
constant differential
pressure across the
diaphragm by
maintaining case
The metering
pressure higherunit delays
the pressure
pressure
in
than diaphragm
the case
of the VSI during climbing.

DURING CLIMB >
- The pressure inside the diaphragm is lower
than inside the case
due to the lag of the metering unit.

- The pointer will be deflected up to indicate
Remembe
r !
LEVEL FLIGHT >
-pressure inside the chamber and the instrument
case is …………...
-pointer indicates ‘0’

DURING DESCEND >
-the pressure inside the chamber is ………………. than
inside the case due to the lag of the metering unit.
- Pointer moves down to indicate ‘descend’.

DURING ASCEND >
-the pressure inside the chamber is …….. than inside
the case due to the lag of the metering unit.
-the pointer will move up to indicate ‘ascend’.
 Bar
I&I o
VERTICAL SPEED INDICATOR
(Airchamber-based)
Air Chamber
 Bar
I&I
VERTICAL SPEED INDICATOR o

(Airchamber-based)
The airchamber based vertical speed
indicator consists of the following main
parts:
 air-tight case with static connection
(S)
 metering mechanism including an
airchamber
 cascade filter Air Chamber
 ‘zero adjustment’ mechanism (for
servicing only)
 dial
 pointer.
 Bar
I&I VERTICAL SPEED o
INDICATOR
(Airchamber-based)
Vertical Speed Indicator
airchamber-based type is
designed to create a
more rapid differential
pressure effect.
Hermetically sealed case
with a connection for
static pressure line. Air Chamber
Calibrated orifice
separates the
airchamber into 2
separate sections.
 Bar
I&I o

The upper chamber is
open to the case and
connected to cascade filter via
One chamber is
a calibrated aperture. Air Chamber
supplied with
Static
pressure
and the other
with the pressure
exiting inside the
housing
(Equalizing
Pressure)

The lower chamber is connected
directly to the static pressure line via
the cascade filter.
 Bar
I&I o

LEVEL FLIGHT
Air Chamber
Static
pressure
remains
constant.

The pressure
in both the
chambers are
equal.

ROC pointer
reads ’zero’.
 Bar
o
DURING
CLIMBING
Static pressure reduces.
Immediately Lower Air Chamber
Chamber
pressure reduces.
The higher pressure of
the
Upper Chamber pushes
the
Calibrated Orifice into
lower chamber (low
pressure).

A balance is achieved
between
 Bar
o

DURING CLIMB

When the aircraft ceases
to climb; Air Chamber

>The static pressure
remains constant.
>Both the chamber
pressures equalize
through the calibrated
orifice and the aperture.
>The Spiral spring returns the
indicator mechanism to zero.
 Bar
I&I o
DURING
DESCEND
 Static pressure inside the lower
chamber increases and the pointer
indicates ’down’.

 The indicated rate of descent
again increases until the pressure
difference and the spring pressure
are in balance, i.e. until the true
When thedescent
rate of aircraftof
ceases to descend;
the aircraft is
indicated.
 the static pressure remains constant
and both the chamber pressure will
equalize through the calibrated
orifice and the aperture.

 The spring returns the indicator
mechanism to zero.
SUMMARY
`Standard conditions at mean
sea level (MSL)’ , ISA states a
temperature of 15° C and an
air pressure of 1,013.25 hPa
or
I C E
(29.92 in Hg) and a
temperature lapse rate of 2
degC./1000 ft.
T
COLOUR MARKING OF
AIRSPEED INDICATORS

INTERNATIONAL `Q’ CODE
by ICAO
ENCODING
ALTIMETER
PRINCIPLE OF
OPERATION
 SUMMARY
Principle OF Operation :
LEVEL FLIGHT >
-pressure inside the chamber and the instrument
case is equal.
-pointer indicates ‘0’

DURING DESCEND >
-the pressure inside the chamber is higher than
inside the case due to the lag of the metering unit.
-the gear linkage from the chamber will deflect the
pointer down to indicate ‘descend’.

DURING ASCEND >
-the pressure inside the chamber is lower than inside
the case due to the lag of the metering unit.
-the pointer will be deflected up to indicate ‘ascend’.
 The End of
Barometric
System
The next subject is on Air Data
Computer
 Quiz
1. What is ICAO ?
2. What is the value of Standard Atmospheric
Pressure
3. What isatthe
MSL?
temperature lapse rate with
altitude?
4. State the purpose of Air Speed Indicator?
5. Air Speed Indicator are calibrated in what
unit?
6. Define types of airspeed?
7. What is the sensing device used in Air Speed
Indicator?
8. What types of pressure used in Air Speed
Indicator?
9. What happen to the diaphragm and pointer
of Air Speed
10.Indicator
What happen
when to the diaphragm
aircraft and pointer
speed is increased?
of Air Speed
Indicator when aircraft maintain steady
speed and height?