Policy for Type Certification of Very Light Airplanes as a Special Class of Aircraft, 53815-53823 [2023-17084]
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53815
Proposed Rules
Federal Register
Vol. 88, No. 152
Wednesday, August 9, 2023
Federal Aviation Administration
New Jersey Avenue SE, Washington,
DC, between 9 a.m. and 5 p.m., Monday
through Friday, except Federal holidays.
FOR FURTHER INFORMATION CONTACT:
Hieu Nguyen, Product Policy
Management, AIR–62B, Policy and
Standards Division, Aircraft
Certification Service, Federal Aviation
Administration; telephone 816–329–
4123; email hieu.nguyen@faa.gov.
SUPPLEMENTARY INFORMATION:
14 CFR Part 21
Comments Invited
[Docket No. FAA–2023–0623]
The FAA invites interested people to
take part in the development of this
proposed policy by sending written
comments, data, or views. The most
helpful comments reference a specific
portion of the proposed policy, explain
the reason for any recommended
change, and include supporting data.
Before acting on this proposal, the
FAA will consider all comments
received on or before the closing date
for comments. The FAA may consider
comments filed late if it is possible to
do so without incurring delay. The FAA
may change the proposed policy based
on the comments received.
This section of the FEDERAL REGISTER
contains notices to the public of the proposed
issuance of rules and regulations. The
purpose of these notices is to give interested
persons an opportunity to participate in the
rule making prior to the adoption of the final
rules.
DEPARTMENT OF TRANSPORTATION
Policy for Type Certification of Very
Light Airplanes as a Special Class of
Aircraft
Federal Aviation
Administration (FAA), Department of
Transportation (DOT).
ACTION: Notice of proposed policy,
request for comments.
AGENCY:
The FAA is requesting
comments on its proposed policy for the
type certification of Very Light
Airplanes (VLA) as a special class of
aircraft under the Federal Aviation
Regulations.
SUMMARY:
Send comments on or before
September 8, 2023.
ADDRESSES: Send comments identified
by Docket No. FAA–2023–0623 using
any of the following methods:
Federal eRegulations Portal: Go to
https://www.regulations.gov/ and follow
the online instructions for sending your
comments electronically.
Mail: Send comments to Docket
Operations, M–30, U.S. Department of
Transportation (DOT), 1200 New Jersey
Avenue SE, Room W12–140, West
Building Ground Floor, Washington, DC
20590–0001.
Hand Delivery of Courier: Take
comments to Docket Operations in
Room W12–140 of the West Building
Ground Floor at 1200 New Jersey
Avenue SE, Washington, DC, between 9
a.m. and 5 p.m., Monday through
Friday, except Federal holidays.
Fax: Fax comments to Docket
Operations at 202–493–2251.
Docket: Background documents or
comments received may be read at
https://www.regulations.gov/ at any
time. Follow the online instructions for
accessing the docket or go to Docket
Operations in Room W12–140 of the
West Building Ground Floor at 1200
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DATES:
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Privacy
Except for Confidential Business
Information (CBI) as described in the
following paragraph, the FAA will post
all comments it receives, without
change, to https://www.regulations.gov/,
including any personal information you
provide. Using the search function of
the docket website, anyone can find and
read the electronic form of all comments
received into any FAA docket,
including the name of the individual
sending the comment (or signing the
comment for an association, business,
labor union, etc.). DOT’s complete
Privacy Act Statement can be found in
the Federal Register published on April
11, 2000 (65 FR 19477–19478), as well
as at https://www.dot.gov/privacy.
Confidential Business Information
CBI is commercial or financial
information that is both customarily and
actually treated as private by its owner.
Under the Freedom of Information Act
(FOIA) (5 U.S.C. 552), CBI is exempt
from public disclosure. If your
comments responsive to this proposed
policy contain commercial or financial
information that is customarily treated
as private, that you actually treat as
private, and that is relevant or
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responsive to these proposed
airworthiness criteria, it is important
that you clearly designate the submitted
comments as CBI. Please mark each
page of your submission containing CBI
as ‘‘PROPIN.’’ The FAA will treat such
marked submissions as confidential
under the FOIA, and the indicated
comments will not be placed in the
public docket for this notice. Send
submissions containing CBI to the
individual listed under For Further
Information Contact. Comments that the
FAA receives, which are not specifically
designated as CBI, will be placed in the
public docket for this notice.
Background
In 1992, the FAA issued Advisory
Circular (AC) 21.17–3,1 ‘‘Type
Certification of Very Light Airplanes
Under [14 CFR] 21.17(b)’’ (AC 21.17–3),
to provide guidance on acceptable
means of compliance for type,
production, and airworthiness
certification for very light airplanes
(VLA). AC 21.17–3 designates the Joint
Aviation Authorities (JAA) of Europe
publication, ‘‘Joint Aviation
Requirements for Very Light
Aeroplanes’’ (April 26, 1990) (JAR–
VLA), as acceptable airworthiness
criteria that provides an equivalent level
of safety under 14 CFR 21.17(b) for FAA
type certification of VLA as a special
class of aircraft. After the European
Aviation Safety Agency (now the
European Union Aviation Safety
Agency) (EASA) was formed, EASA
developed its VLA certification
standards (CS–VLA) from JAR–VLA,
with CS–VLA becoming effective on
November 14, 2003.
In 2016, the FAA promulgated
amendment 23–64 of 14 CFR part 23,
Revision of Airworthiness Standards for
Normal, Utility, Acrobatic, and
Commuter Category Airplanes. 81 FR
96572.2 In the preamble to that final
rule, the FAA stated that it intended to
continue to allow CS–VLA airplanes to
be approved as a special, stand-alone
class of airplane while also allowing
eligibility for certification in accordance
with part 23 using accepted means of
compliance. In 2017, EASA issued CS–
23 Amendment 5 and EASA recognized
1 Available
at https://drs.faa.gov.
Docket No. FAA–
2 https://www.regulations.gov;
2015–1621.
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CS–VLA as an acceptable means of
compliance to CS–23 Amendment 5.
AC 21.17–3 considers a VLA as a
special class of aircraft, and defines a
VLA as an airplane with a single engine
(spark- or compression-ignition), not
more than two seats, a maximum
certificated takeoff weight of not more
than 750 kg (approximately 1,654
pounds), and a stalling speed of not
more than 45 knots (CAS) in the landing
configuration, and limited to normal
category maneuvers and day visual
flight rule (VFR) operations only. AC
21.17–3 states that, ‘‘VLA operations at
night and under [instrument flight rule]
(IFR) conditions would be acceptable,
provided the VLA is certificated to the
JAR–VLA requirements plus certain
additional [14 CFR] part 23
requirements, including those related to
night and IFR operations, and that both
the engine and propeller installed [are]
type certificated under [14 CFR] part 33
(or JAR–E) and part 35 (or JAR–P).’’
This notice of proposed policy
contains additional airworthiness
criteria that are an acceptable means of
compliance for design features that
differ from the VLA limits defined in
AC 21.17–3 or that are not adequately
addressed by CS–VLA or JAR–VLA. The
FAA previously applied some of these
additional airworthiness criteria to
specific VLA type designs,3 and these
additional airworthiness criteria are
among those included in this notice of
proposed policy.
Discussion
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The FAA establishes airworthiness
criteria and issues type certificates to
ensure the safe design and operation of
aircraft in accordance with 49 U.S.C.
44701(a) and 44704. VLA can be type
certificated by the FAA as a special
class of aircraft because VLA
airworthiness standards have not yet
been established by regulation. Under
the provisions of 14 CFR 21.17(b), the
airworthiness standards for special class
aircraft are the portions of the
requirements in 14 CFR parts 23, 25, 27,
29, 31, 33, and 35 found by the FAA to
be appropriate and applicable to the
specific type design and any other
airworthiness criteria found by the FAA
to provide an equivalent level of safety
to the existing standards.
3 Aquila GmbH Engine Mount Connection Design
Criteria and Winglets for the Aquila GmbH AT01
JAR–VLA Airplane (68 FR 63841, October 20,
2003); Night VFR Under the Special Class (JAR–
VLA) Regulations, Aquila Aviation by Excellence
GmbH, Model AT01 (78 FR 50313, August 19,
2013); Advanced Avionics Under the Special Class
(JAR–VLA) Regulations; Aquila Aviation by
Excellence GmbH, Model AT01–100 (78 FR 68687,
November 15, 2013).
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With the adoption of performancebased regulations in part 23,
amendment 23–64, VLA airplanes are
eligible for certification as normal
category airplanes in accordance with
part 23 using accepted means of
compliance. Or, applicants may seek
type certification of VLA airplanes as a
‘‘special class’’ under § 21.17(b) using
CS–VLA or JAR–VLA requirements. The
FAA accepts CS–VLA and JAR–VLA
airworthiness criteria as providing an
equivalent level of safety under
§ 21.17(b) for special class type
certification of VLA airplanes. Special
class certification may include airplane
designs that differ from the limits
defined in AC 21.17–3 (e.g., engine
mount, winglets, night-VFR, increased
maximum certificated takeoff weight of
not more than 850 kg (1,874 pounds),
increased stall speed of not more than
50 KCAS, or lithium battery installation)
provided the airplane was certificated to
CS–VLA or JAR–VLA and the
certification basis includes additional
design requirements applicable and
appropriate for the specific type design.
The FAA plans to revise AC 21.17–3 to
incorporate the additional acceptable
airworthiness criteria proposed in this
policy.
VLA airplanes meeting the limits
defined in AC 21.17–3 are certificated to
CS–VLA or JAR–VLA requirements.
VLA airplane designs that differ from
the limits defined in AC 21.17–3 or
designs that incorporate features not
adequately addressed by CS–VLA or
JAR–VLA requirements may be
certificated to CS–VLA or JAR–VLA
with additional airworthiness criteria
applicable and appropriate for the
specific type design. Specifically, this
proposed policy contains additional
airworthiness criteria for such features
as advanced avionic displays, engine
mount to composite airframe, winglets,
night VFR operations, increased
maximum certificated takeoff weight
and increased stall speed from those
defined in AC 21.17–3, and rechargeable
lithium ion battery installations.
The following are the proposed
acceptable airworthiness criteria that
provide an equivalent level of safety for
VLA special class type certification
under 21.17(b), in addition to the
requirements in CS–VLA or JAR–VLA,
that the FAA finds to be appropriate and
applicable for specific type designs.
Each of the new criteria use a
‘‘VLA.XXX’’ section-numbering scheme.
Advanced Avionic Displays
In addition to being certificated to
CS–VLA or JAR–VLA requirements,
designs incorporating advanced avionic
displays would also need to meet the
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requirements of 14 CFR 23.1307,
Miscellaneous Equipment, amendment
23–49; § 23.1311, Electronic Display
Instrument Systems, amendment 23–62;
§ 23.1321, Arrangement and Visibility,
amendment 23–49; and § 23.1359,
Electrical System Fire Protection,
amendment 23–49.
Winglets
In addition to being certificated to
CS–VLA or JAR–VLA requirements,
airplanes with winglets on the wings
would also need to meet the
requirements of JAR 23.445,4
amendment 1, Outboard Fins or
Winglets.
Engine Mount to Composite Airframe
In addition to being certificated to
CS–VLA or JAR–VLA requirements,
designs with engine mounting to
composite airframe would also need to
meet design requirements to address fire
protection of the connection between
the metal structure of an engine mount
and composite airframe by
demonstrating that the composite
airframe can withstand a fire while
carrying loads.
Night-VFR Operations
In addition to being certificated to
CS–VLA or JAR–VLA, for certification
for night VFR operations, the airplane
would also need to meet design
requirements to address the flight
performance, design and construction,
powerplant installation, equipment, and
operating limitations and information,
that are necessary for night VFR
operations.
Increased Maximum Certificated
Takeoff Weight and Increased Stall
Speed
In addition to being certificated to
CS–VLA or JAR–VLA, for approval of
airplane designs with an increased
maximum certificated takeoff weight of
not more than 850 kg (1,874 pounds)
and increased stall speed of not more
than 50 KCAS, the airplane would also
need to meet design requirements to
address the flight performance,
structure, crashworthiness, and
performance information, that are
necessary for the increased weight and
stall speed.
(a) If an Equivalent Level of Safety
(ELOS) to CS–VLA 1143(g) and CS–VLA
1147(b) is requested, the airplane would
need to meet additional design
requirements to incorporate design
features to increase reliability, and
4 JAR–23 amendment 1: Normal, Utility,
Aerobatic, and Commuter Category Aeroplanes, can
be found in Docket No. FAA–2023–0623 at https://
www.regulations.gov.
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maintenance items that make the engine
controls attachment not likely to
separate in flight, which are necessary
to ensure that if the mixture control
separates at the engine fuel metering
device, the airplane is capable of
continued safe flight and landing.
(b) Instead of the stall-characteristics
requirements in CS–VLA 201(c), CS–
VLA 201(f), and CS–VLA 203(c)(4), the
requirements from CS 23.201(c), CS
23.201(e), and CS 23.203(c)(4)(ii),
respectively, would need to be used.
(c) In place of the handling quality
attributes in CS–VLA 177(a)(2) and CS–
VLA 177(a)(3), neutral lateral stability
would need to be achieved by showing
compliance with the requirements in
VLA.170.
(d) If an ELOS to CS–VLA 161(b)(2)(ii)
is requested, additional airworthiness
criteria from CS 23.161(c)(4), CS 23.73
(a), CS 23.75 (a)(1), (b), (c), and (d), CS
23.77(a), CS 23.145 (b)(5) and (d), CS
23.153(a), (b), (c), and (d), CS 23.157(c)
and (d), and CS 23.175(c), would need
to be met to address airplane trim
requirements.
Rechargeable Lithium Ion Battery
In addition to being certificated to
CS–VLA or JAR–VLA, airplanes with
rechargeable lithium ion battery would
need to meet airworthiness criteria
containing safety objectives necessary to
address design and installation of
rechargeable lithium ion batteries.
The contents of this document do not
have the force and effect of law and are
not meant to bind the public in any
way. This document is intended only to
provide clarity to the public regarding
existing requirements under the law or
agency policies.
Authority Citation
The authority citations for these
airworthiness criteria are as follows:
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Authority: 49 U.S.C. 106(g), 40113, 44701,
44702, 44704.
Policy
The FAA proposes to continue to
allow type certification of VLA as a
special class of aircraft under 14 CFR
21.17(b) using CS–VLA or JAR–VLA
requirements, while also allowing
eligibility for certification as a normal
category airplane in accordance with
part 23 using accepted means of
compliance. The FAA accepts CS–VLA
and JAR–VLA airworthiness criteria as
providing an equivalent level of safety
under § 21.17(b) special class type
certification of VLA airplanes. The FAA
would consider proposals for airplane
designs that differ from the VLA limits
defined in AC 21.17–3 for type
certification as a special class of aircraft
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under § 21.17(b), provided the VLA
were certificated to the JAR–VLA or CS–
VLA requirements plus additional
airworthiness criteria the FAA finds
appropriate and applicable for the
proposed design. Additional design
requirements may include but are not
limited to the airworthiness criteria
identified in the following paragraphs.
Other additional airworthiness criteria
may be required to address specific
design proposals.
Advanced Avionic Displays
If the airplane has advanced avionic
displays installed, the following
requirements from 14 CFR part 23
apply:
• 14 CFR 23.1307 at amendment 23–
49, Miscellaneous Equipment.
• 14 CFR 23.1311 at amendment 23–
62, Electronic Display Instrument
Systems.
• 14 CFR 23.1321 at amendment 23–
49, Arrangement and Visibility.
• 14 CFR 23.1359 at amendment 23–
49, Electrical System Fire Protection.
Winglets
If the airplane has any outboard fins
or winglets installed, the design must
comply with JAR 23.445.
Engine Mount to Composite Airframe
VLA.001
The requirements in this section are
applicable to airplanes with an engine
mounting to composite airframe. Tests
must be performed that demonstrate
that the interface between the metallic
engine mount and the glass fiber
reinforced plastic fuselage withstand a
fire for 15 minutes while carrying loads
under the following conditions:
(a) With one lost engine mount fitting
the loads are distributed over the
remaining three engine mount fittings.
The most critical of these fittings must
be chosen for the test.
The loads are:
(1) In Z-direction the mass of the
propulsion unit multiplied by a
maneuvering load factor resulting from
a 30° turn for 15 minutes, superimposed
by a maneuvering load of 3 seconds
representing the maximum positive
limit maneuvering load factor of n = 3.8
from JAR–VLA 337(a).
(2) In X-direction the engine
propulsion force at maximum
continuous power for 5 minutes.
(b) The flame to which the component
test arrangement is subjected must
provide a temperature of 500 °C within
the target area.
(c) The flame must be large enough to
maintain the required temperature over
the entire test zone, i.e., the fitting on
the engine compartment side.
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(d) It must be shown that the test
equipment, e.g., burner and
instrumentation are of sufficient power,
size, and precision to yield the test
requirements arising from paragraphs (a)
through (c) of this section.
Night-VFR Operations
VLA.005
The requirements in sections VLA.005
through VLA.105 are applicable to
airplanes with a single engine (spark- or
compression-ignition) having not more
than two seats, with a maximum
certificated takeoff weight of not more
than 750 kg and a stalling speed in the
landing configuration of not more than
83 km/h (45 knots) (CAS), to be
approved for day-VFR [visual flight
rules] or for day-and night-VFR.
VLA.010
(a) Any short period oscillation not
including combined lateral-directional
oscillations occurring between the
stalling speed and the maximum
allowable speed appropriate to the
configuration of the airplane must be
heavily damped with the primary
controls—
(1) Free; and
(2) In a fixed position.
(b) Any combined lateral-directional
oscillations (‘‘Dutch roll’’) occurring
between the stalling speed and the
maximum allowable speed appropriate
to the configuration of the airplane must
be damped to 1/10 amplitude in 7
cycles with the primary controls—
(1) Free; and
(2) In a fixed position.
(c) Any long period oscillation of the
flight path (phugoid) must not be so
unstable as to cause an unacceptable
increase in pilot workload or otherwise
endanger the airplane. When under the
conditions specified in CS–VLA 175,
the longitudinal control force required
to maintain speeds differing from the
trimmed speed by at least plus or minus
15% is suddenly released, the response
of the airplane must not exhibit any
dangerous characteristics nor be
excessive in relation to the magnitude of
the control force released.
VLA.015
The pilot compartment must be free
from glare and reflections that could
interfere with the pilot’s vision under
all operations for which the certification
is requested. The pilot compartment
must be designed so that—
(a) The pilot’s view is sufficiently
extensive, clear, and undistorted, for
safe operation;
(b) The pilot is protected from the
elements so that moderate rain
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conditions do not unduly impair the
pilot’s view of the flight path in normal
flight and while landing; and
(c) Internal fogging of the windows
covered under paragraph (a) of this
section can be easily cleared by the pilot
unless means are provided to prevent
fogging.
VLA.020
(a) The airplane must be so designed
that unimpeded and rapid escape is
possible in any normal and crash
attitude.
(b) The opening system must be
designed for simple and easy operation.
It must function rapidly and be
designed so that it can be operated by
each occupant strapped in their seat,
and also from outside the cockpit.
Reasonable provisions must be provided
to prevent jamming by fuselage
deformation.
(c) The exit must be marked for easy
location and operation even in darkness.
VLA.025
(a) The engine must meet the
specifications of CS–E, amendment 6,5
or 14 CFR part 33, amendment 33–36,
for night-VFR operation.
(b) Restart capability. An altitude and
airspeed envelope must be established
for the airplane for in-flight engine
restarting and the installed engine must
have a restart capability within that
envelope.
VLA.030
(a) For day-VFR operation, the
propeller must meet the specifications
of CS–22 Subpart J, amendment 3. For
night-VFR operations the propeller and
its control system must meet the
specifications of CS–P, amendment 2,6
or 14 CFR part 35, amendment 35–10,
except for fixed pitch propellers, for
which CS–22 7 subpart J is sufficient.
(b) Engine power and propeller shaft
rotational speed may not exceed the
limits for which the propeller is
certificated or approved.
VLA.035
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If an air filter is used to protect the
engine against foreign material particles
in the induction air supply—
5 CS–E amendment 6: Certification Specifications
and Acceptable Means of Compliance for Engines
can be found in Docket No. FAA–2023–0623 at
https://www.regulations.gov.
6 CS–P amendment 2: Certification Specifications
and Acceptable Means of Compliance for Propellers
can be found in Docket FAA–2023–0623 at https://
www.regulations.gov.
7 CS–22 amendment 3: Certification
Specifications, Acceptable Means of Compliance
and Guidance Material for Sailplanes and Powered
Sailplanes can be found in Docket No. FAA–2023–
0623 at https://www.regulations.gov.
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(a) Each air filter must be capable of
withstanding the effects of temperature
extremes, rain, fuel, oil, and solvents to
which it is expected to be exposed in
service and maintenance; and
(b) Each air filter must have a design
feature to prevent material separated
from the filter media from re-entering
the induction system and interfering
with proper fuel metering operation.
VLA.050
VLA.040
VLA.055
(a) Each exhaust system must ensure
safe disposal of exhaust gases without
fire hazard or carbon monoxide
contamination in the personnel
compartment.
(b) Each exhaust system part with a
surface hot enough to ignite flammable
fluids or vapours must be located or
shielded so that leakage from any
system carrying flammable fluids or
vapours will not result in a fire caused
by impingement of the fluids or vapours
on any part of the exhaust system
including shields for the exhaust
system.
(c) Each exhaust system component
must be separated by fireproof shields
from adjacent flammable parts of the
airplane that are outside the engine
compartment.
(d) No exhaust gases may discharge
dangerously near any fuel or oil system
drain.
(e) Each exhaust system component
must be ventilated to prevent points of
excessively high temperature.
(f) Each exhaust heat exchanger must
incorporate means to prevent blockage
of the exhaust port after any internal
heat exchanger failure.
(g) No exhaust gases may be
discharged where they will cause a glare
seriously affecting the pilot’s vision at
night.
If warning, caution, or advisory lights
are installed in the cockpit, they must
be—
(a) Red, for warning lights (lights
indicating a hazard which may require
immediate corrective action);
(b) Amber, for caution lights (lights
indicating the possible need for future
corrective action);
(c) Green, for safe operation lights;
and
(d) Any other color, including white,
for lights not described in paragraphs (a)
through (c) of this section, provided the
color differs sufficiently from the colors
prescribed in paragraphs (a) through (c)
of this section to avoid possible
confusion.
(e) If warning, caution, or advisory
lights are installed in the cockpit, they
must be effective under all probable
cockpit lighting conditions.
VLA.045
(a) The power or supercharger control
must give a positive and immediate
responsive means of controlling its
engine or supercharger.
(b) If a power control incorporates a
fuel shut-off feature, the control must
have a means to prevent the inadvertent
movement of the control into the shutoff position. The means must—
(1) Have a positive lock or stop at the
idle position; and
(2) Require a separate and distinct
operation to place the control in the
shut-off position.
(c) Each power or thrust control must
be designed so that if the control
separates at the engine fuel metering
device, the airplane is capable of
continuing safe flight and landing.
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(a) The control must require a
separate and distinct operation to move
the control toward lean or shut-off
position.
(b) Each manual engine mixture
control must be designed so that, if the
control separates at the engine fuel
metering device, the airplane is capable
of continuing safe flight and landing.
VLA.060
(a) Each instrument provided with
static pressure case connections must be
so vented that the influence of airplane
speed, the opening and closing of
windows, moisture, or other foreign
matter, will not significantly affect the
accuracy of the instruments.
(b) The design and installation of a
static pressure system must be such
that—
(1) Positive drainage of moisture is
provided;
(2) Chafing of the tubing, and
excessive distortion or restriction at
bends in the tubing, is avoided; and
(3) The materials used are durable,
suitable for the purpose intended, and
protected against corrosion.
(c) Each static pressure system must
be calibrated in flight to determine the
system error. The system error, in
indicated pressure altitude, at sea-level,
with a standard atmosphere, excluding
instrument calibration error, may not
exceed ±9 m (±30 ft) per 185 km/h (100
knots) speed for the appropriate
configuration in the speed range
between 1.3 VSO with flaps extended
and 1.8 VS1 with flaps retracted.
However, the error need not be less than
±9 m (±30 ft).
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VLA.065
For each airplane—
(a) Each gyroscopic instrument must
derive its energy from power sources
adequate to maintain its required
accuracy at any speed above the best
rate-of-climb speed;
(b) Each gyroscopic instrument must
be installed so as to prevent malfunction
due to rain, oil, and other detrimental
elements; and
(c) There must be a means to indicate
the adequacy of the power being
supplied to the instruments.
(d) For Night VFR operation there
must be at least two independent
sources of power and a manual or an
automatic means to select each power
source for each instrument that uses a
power source.
VLA.070
(a) Electrical system capacity. Each
electrical system must be adequate for
the intended use. In addition—
(1) Electric power sources, their
transmission cables, and their
associated control and protective
devices, must be able to furnish the
required power at the proper voltage to
each load circuit essential for safe
operation; and
(2) Compliance with paragraph (a)(l)
of this section must be shown by an
electrical load analysis, or by electrical
measurements, that account for the
electrical loads applied to the electrical
system in probable combinations and
for probable durations.
(b) Functions. For each electrical
system, the following apply:
(1) Each system, when installed, must
be—
(i) Free from hazards in itself, in its
method of operation, and in its effects
on other parts of the airplane;
(ii) Protected from fuel, oil, water,
other detrimental substances, and
mechanical damage; and
(iii) So designed that the risk of
electrical shock to occupants and
ground personnel is reduced to a
minimum.
(2) Electric power sources must
function properly when connected in
combination or independently.
(3) No failure or malfunction of any
electric power source may impair the
ability of any remaining source to
supply load circuits essential for safe
operation.
(4) Each electric power source control
must allow the independent operation
of each source, except that controls
associated with alternators that depend
on a battery for initial excitation or for
stabilization need not break the
connection between the alternator and
its battery.
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(5) Each generator must have an
overvoltage control designed and
installed to prevent damage to the
electrical system, or to equipment
supplied by the electrical system, that
could result if that generator were to
develop an overvoltage condition.
(d) Instruments. There must be a
means to indicate to the pilot that the
electrical power supplies are adequate
for safe operation. For direct current
systems, an ammeter in the battery
feeder may be used.
(e) Fire resistance. Electrical
equipment must be so designed and
installed that in the event of a fire in the
engine compartment, during which the
surface of the firewall adjacent to the
fire is heated to 1,100 °C for 5 minutes
or to a lesser temperature substantiated
by the applicant, the equipment
essential to continued safe operation
and located behind the firewall will
function satisfactorily and will not
create an additional fire hazard. This
may be shown by test or analysis.
(f) External power. If provisions are
made for connecting external power to
the airplane, and that external power
can be electrically connected to
equipment other than that used for
engine starting, means must be provided
to ensure that no external power supply
having a reverse polarity, or a reverse
phase sequence, can supply power to
the airplane’s electrical system. The
location must allow such provisions to
be capable of being operated without
hazard to the airplane or persons.
VLA.075
(a) Each storage battery must be
designed and installed as prescribed in
this section.
(b) Safe cell temperatures and
pressures must be maintained during
any probable charging and discharging
condition. No uncontrolled increase in
cell temperature may result when the
battery is recharged (after previous
complete discharge)—
(1) At maximum regulated voltage or
power;
(2) During a flight of maximum
duration; and
(3) Under the most adverse cooling
condition likely to occur in service.
(c) Compliance with paragraph (b) of
this section must be shown by tests
unless experience with similar batteries
and installations has shown that
maintaining safe cell temperatures and
pressures presents no problem.
(d) No explosive or toxic gases
emitted by any battery in normal
operation, or as the result of any
probable malfunction in the charging
system or battery installation, may
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53819
accumulate in hazardous quantities
within the airplane.
(e) No corrosive fluids or gases that
may escape from the battery may
damage surrounding structures or
adjacent essential equipment.
(f) Each nickel cadmium battery
installation capable of being used to
start an engine or auxiliary power unit
must have provisions to prevent any
hazardous effect on structure or
essential systems that may be caused by
the maximum amount of heat the
battery can generate during a short
circuit of the battery or of its individual
cells.
(g) Nickel cadmium battery
installations capable of being used to
start an engine or auxiliary power unit
must have—
(1) A system to control the charging
rate of the battery automatically so as to
prevent battery overheating;
(2) A battery temperature sensing and
over-temperature warning system with a
means for disconnecting the battery
from its charging source in the event of
an overtemperature condition; or
(3) A battery failure sensing and
warning system with a means for
disconnecting the battery from its
charging source in the event of battery
failure.
(h) In the event of a complete loss of
the primary electrical power generating
system, the battery must be capable of
providing 30 minutes of electrical
power to those loads that are essential
to continued safe flight and landing.
The 30-minute time period includes the
time needed for the pilot(s) to recognize
the loss of generated power and to take
appropriate load shedding action.
VLA.080
The instrument lights must—
(a) Make each instrument and control
easily readable and discernible;
(b) Be installed so that their direct
rays, and rays reflected from the
windshield or other surface, are
shielded from the pilot’s eyes; and
(c) Have enough distance or insulating
material between current carrying parts
and the housing so that vibration in
flight will not cause shorting. (A cabin
dome light is not an instrument light.)
VLA.085
Each taxi and landing light must be
designed and installed so that—
(a) No dangerous glare is visible to the
pilots;
(b) The pilot is not seriously affected
by halation;
(c) It provides enough light for night
operations; and
(d) It does not cause a fire hazard in
any configuration.
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VLA.090
(a) Electronic equipment and
installations must be free from hazards
in themselves, in their method of
operation, and in their effects on other
components.
(b) For operations for which
electronic equipment is required,
compliance must be shown with CS–
VLA 1309.
VLA.095
(a) A placard meeting the
requirements of this section must be
installed on or near the magnetic
direction indicator.
(b) The placard must show the
calibration of the instrument in level
flight with the engine operating.
(c) The placard must state whether the
calibration was made with radio
receivers on or off.
(d) Each calibration reading must be
in terms of magnetic headings in not
more than 30° increments.
(e) If a magnetic non-stabilized
direction indicator can have a deviation
of more than 10° caused by the
operation of electrical equipment, the
placard must state which electrical
loads, or combination of loads, would
cause a deviation of more than 10° when
turned on.
VLA.100
lotter on DSK11XQN23PROD with PROPOSALS1
The following placards must be
plainly visible to the pilot:
(a) A placard stating the following
airspeeds (IAS):
(1) Design maneuvering speed, VA;
(2) The maximum landing gear
operating speed, VLO.
(b) A placard stating the following
approved operation:
(1) For day-VFR only operation, a
placard stating, ‘‘This airplane is
classified as a very light airplane
approved for day-VFR only, in non-icing
conditions. All aerobatic maneuvers,
including intentional spinning, are
prohibited. See Flight Manual for other
limitations.’’
(2) If night-VFR operation is
approved, a placard stating, ‘‘This
airplane is classified as a very light
airplane approved for day- and nightVFR operation, in non-icing conditions.
All aerobatic maneuvers, including
intentional spinning, are prohibited. See
Flight Manual for other limitations.’’
VLA.105
(a) Airspeed limitations. The
following information must be
furnished—
(1) Information necessary for the
marking of the airspeed limits on the
indicator, as required in CS–VLA 1545,
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and the significance of the color coding
used on the indicator.
(2) The speeds VA, VLO, VLE
(maximum landing gear extended
speed) where appropriate.
(b) Weights. The following
information must be furnished:
(1) The maximum weight.
(2) Any other weight limits, if
necessary.
(c) Center of gravity. The established
c.g. limits required by CS–VLA 23 must
be furnished.
(d) Maneuvers. Authorized maneuvers
established in accordance with CS–VLA
3 must be furnished.
(e) Flight load factors. Maneuvering
load factors: the following must be
furnished—
(1) The factors corresponding to point
A and point C in the figure for CS–VLA
333(b), stated to be applicable at VA.
(2) The factors corresponding to point
D and point E of figure 1 of CS–VLA
333(b) to be applicable at never exceed
speed, VNE.
(3) The factor with wing flaps
extended as specified in CS–VLA 345.
(f) The kinds of operation (day-VFR or
day- and night-VFR, whichever is
applicable) in which the airplane may
be used, must be stated. The minimum
equipment required for the operation
must be listed.
(g) Powerplant limitations. The
following information must be
furnished:
(1) Limitation required by CS–VLA
1521.
(2) Information necessary for marking
the instruments required by CS–VLA
1549 through 1551.
(3) Fuel and oil designation.
(4) For two-stroke engines, fuel/oil
ratio.
(h) Placards. Placards required by CS–
VLA 1555 through 1561 must be
presented.
Increased Maximum Certificated
Takeoff Weight and Increased Stall
Speed
VLA.110
If the maximum certificated takeoff
weight is higher than 750 kg, but not
more than 850 kg, the requirements in
sections VLA.120 through VLA.210
apply.
VLA.115
If the stall speed in landing
configuration is higher than 45 knots,
but not more than 50 knots (CAS), the
requirements in section VLA.120
through VLA.210 apply.
VLA.120
The maximum horizontal distance
traveled in still air, in km per 1,000 m
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(nautical miles per 1,000 ft) of altitude
lost in a glide, and the speed necessary
to achieve this, must be determined
with the engine inoperative and its
propeller in the minimum drag position,
and landing gear and wing flaps in the
most favorable available position.
VLA.125
(a) Each seat is to be equipped with
at least a 4-point harness system;
(b) The applicant shall evaluate the
head strike path with validated
methods, and minimize the risk of
injury in case of a head contact with the
aircraft structure or interior.
(c) The design shall provide
reasonable precautions to minimize the
lumbar compression loads experienced
by occupants in survivable crash
landings;
(d) Each seat/harness system shall be
statically tested to an ultimate inertia
load factor of 18g forward, considering
an occupant’s mass of 77 kg. The lapbelt
should react 60% of this load, and the
upper torso restraint should react 40%
of this load.
VLA.130
(a) The airplane, although it may be
damaged in emergency landing
conditions, must be designed as
prescribed in this section to protect each
occupant under those conditions.
(b) The structure must be designed to
give each occupant reasonable chances
of escaping injury in a minor crash
landing when—
(1) Proper use is made of seat belts
and shoulder harnesses; and
(2) The occupant experiences the
ultimate inertia forces listed below:
(i) Upward 3.0g
(ii) Forward 9.0g
(iii) Sideward 1.5g.
(c) Each item of mass within the cabin
that could injure an occupant if it came
loose must be designed for the ultimate
inertia load factors:
(1) Upward, 3.0g;
(2) Forward, 18.0g; and
(3) Sideward, 4.5g.
Engine mount and supporting
structure are included in the above
analysis if they are installed behind and
above the seating compartment.
(d) The structure must be designed to
protect the occupants in a complete
turnover, assuming, in the absence of a
more rational analysis—
(1) An upward ultimate inertia force
of 3g; and
(2) A coefficient of friction of 0.5 at
the ground.
(e) Each airplane with retractable
landing gear must be designed to protect
each occupant in a landing—
(1) With the wheels retracted;
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(2) With moderate descent velocity;
and
(3) Assuming, in the absence of a
more rational analysis;
(i) A downward ultimate inertia force
of 3g; and
(ii) A coefficient of friction of 0.5 at
the ground.
VLA.135
(a) Each baggage compartment must
be designed for its placarded maximum
weight of contents and for the critical
load distributions at the appropriate
maximum load factors corresponding to
the flight and ground load conditions
for the airplane.
(b) There must be means to prevent
the contents of any baggage
compartment from becoming a hazard
by shifting, and to protect any controls,
wiring, lines, equipment, or accessories
whose damage of failure would affect
safe operations.
(c) Baggage compartments must be
constructed of materials which are at
least flame resistant.
(d) Designs which provide for baggage
to be carried must have means to protect
the occupants from injury under the
ultimate inertia forces specified in CS–
VLA 561(b)(2).
(e) If there is no structure between
baggage and occupant compartments,
the baggage items located behind the
occupants and those which might
become a hazard in a crash must be
secured for 1.33 × 18g.
lotter on DSK11XQN23PROD with PROPOSALS1
VLA.140
(a) General. For each airplane, the
following information must be
furnished:
(1) The takeoff distance determined
under CS–VLA 51, the airspeed at the
15 m height, the airplane configuration
(if pertinent), the kind of surface in the
tests, and the pertinent information with
respect to cowl flap position, use of
flight path control devices, and use of
the landing gear retraction system.
(2) The landing distance determined
under CS–VLA 75, the airplane
configuration (if pertinent), the kind of
surface used in the tests, and the
pertinent information with respect to
flap position and the use of flight path
control devices.
(3) The steady rate or gradient of
climb determined under CS–VLA 65
and 77, the airspeed, power, and the
airplane configuration.
(4) The calculated approximate effect
on takeoff distance (paragraph (a)(1) of
this section), landing distance
(paragraph (a)(2) of this section), and
steady rates of climb (paragraph (a)(3) of
this section), of variations in altitude
and temperature.
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(5) The maximum atmospheric
temperature at which compliance with
the cooling provisions of CS–VLA 1041
through 1047 is shown.
(6) The glide performance determined
under VLA.120.
(b) Skiplanes. For skiplanes, a
statement of the approximate reduction
in climb performance may be used
instead of new data for skiplane
configuration, if—
(1) The landing gear is fixed in both
landplane and skiplane configurations;
(2) The climb requirements are not
critical; and
(3) The climb reduction in the
skiplane configurations is small (0.15 to
0.25 m/s (30 to 50 feet per minute)).
(c) The following information
concerning normal procedures must be
furnished:
(1) The demonstrated crosswind
velocity and procedures and
information pertinent to operation of the
airplane in crosswinds, and
(2) The airspeeds, procedures, and
information pertinent to the use of the
following airspeeds:
(i) The recommended climb speed
and any variation with altitude.
(ii) VX (speed for best angle of climb)
and any variation with altitude.
(iii) The approach speeds, including
speeds for transition to the balked
landing condition.
(d) An indication of the effect on
takeoff distance of a grass surface as
determined from at least one takeoff
measurement on short mown dry grass
must be furnished.
VLA.145
(a) The rotation speed VR, is the speed
at which the pilot makes a control input
with the intention of lifting the airplane
out of contact with the runway.
(b) VR must not be less than stalling
speed, VS1.
(c) The Airplane Flight Manual must
provide the rotation speed established
above for normal takeoff procedures.
If an Equivalent Level of Safety
(ELOS) to CS–VLA 1143(g) and CS–VLA
1147(b) is requested, VLA.150 and
VLA.155 are applicable.
VLA.150
Power or supercharger control
attachment design must include:
(a) Features which are not likely to
separate in flight (i.e., a large loadbearing washer adjacent to the outside
face of the power control cable rod end
fitting which attaches to the fuelmetering device);
(b) Mandatory inspection intervals;
(c) Inspection procedures;
(d) Component replacement criteria.
PO 00000
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53821
VLA.155
Mixture control attachment design
must include:
(a) Features which are not likely to
separate in flight (i.e., a large loadbearing washer adjacent to the outside
face of the power control cable rod end
fitting which attaches to the fuelmetering device);
(b) Mandatory inspection intervals;
(c) Inspection procedures;
(d) Component replacement criteria.
VLA.160
(a) For an airplane with
independently controlled roll and
directional controls, it must be possible
to produce and to correct roll by
unreversed use of the rolling control
and to produce and to correct yaw by
unreversed use of the directional
control, up to the time the airplane
stalls.
(b) For an airplane with
interconnected lateral and directional
controls (2 controls) and for an airplane
with only one of these controls, it must
be possible to produce and correct roll
by unreversed use of the rolling control
without producing excessive yaw, up to
the time the airplane stalls.
(c) The wing level stall characteristics
of the airplane must be demonstrated in
flight as follows: The airplane speed
must be reduced with the elevator
control until the speed is slightly above
the stalling speed, then the elevator
control must be pulled back so that the
rate of speed reduction will not exceed
1.9 km/h (one knot) per second until a
stall is produced, as shown by an
uncontrollable downward pitching
motion of the airplane, or until the
control reaches the stop. Normal use of
the elevator control for recovery is
allowed after the control has been held
against the stop for not less than two
seconds.
(d) Except where made inapplicable
by the special features of a particular
type of airplane, the following apply to
the measurement of loss of altitude
during a stall:
(1) The loss of altitude encountered in
the stall (power on or power off) is the
change in altitude (as observed on the
sensitive altimeter testing installation)
between the altitude at which the
airplane pitches and the altitude at
which horizontal flight is regained.
(2) If power or thrust is required
during stall recovery, the power or
thrust used must be that which would
be used under the normal operating
procedures selected by the applicant for
this maneuver. However, the power
used to regain level flight may not be
applied until flying control is regained.
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lotter on DSK11XQN23PROD with PROPOSALS1
(e) During the recovery part of the
maneuver, it must be possible to prevent
more than 15° of roll or yaw by the
normal use of controls.
(f) Compliance with the requirements
of this section must be shown under the
following conditions:
(1) Wing flaps. Retracted, fully
extended and each intermediate normal
operating position;
(2) Landing gear. Retracted and
extended;
(3) Cowl flaps. Appropriate to
configuration;
(4) Power
(i) Power off; and
(ii) 75% maximum continuous power.
If the power-to-weight ratio at 75% of
maximum continuous power results in
extreme nose-up attitudes, the test may
be carried out with the power required
for level flight in the landing
configuration at maximum landing
weight and a speed of 1.4 stalling speed,
VS0, but the power may not be less than
50% maximum continuous power.
(5) Trim. The airplane trimmed at a
speed as near 1.5 VS1 as practicable.
(6) Propeller. Full increase rpm
position for the power off condition.
VLA.165
Turning flight and accelerated stalls
must be demonstrated in tests as
follows:
(a) Establish and maintain a
coordinated turn in a 30° bank. Reduce
speed by steadily and progressively
tightening the turn with the elevator
until the airplane is stalled or until the
elevator has reached its stop. The rate of
speed reduction must be constant,
and—
(1) For a turning flight stall, may not
exceed 1.9 km/h (one knot) per second;
and
(2) For an accelerated stall, be 5.6 to
9.3 km/h (3 to 5 knots) per second with
steadily increasing normal acceleration.
(b) When the stall has fully developed
or the elevator has reached its stop, it
must be possible to regain level flight by
normal use of controls and without—
(1) Excessive loss of altitude;
(2) Undue pitchup;
(3) Uncontrollable tendency to spin;
(4) Exceeding 60° of roll in either
direction from the established 30° bank;
and
(5) For accelerated entry stalls,
without exceeding the maximum
permissible speed or the allowable limit
load factor.
(c) Compliance with the requirements
of this section must be shown with—
(1) Wing Flaps. Retracted and fully
extended for turning flight and
accelerated entry stalls, and
intermediate, if appropriate, for
accelerated entry stalls;
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(2) Landing Gear. Retracted and
extended;
(3) Cowl Flaps. Appropriate to
configuration;
(4) Power. 75% maximum continuous
power. If the power-to-weight ratio at
75% of maximum continuous power
results in extreme nose-up attitudes, the
test may be carried out with the power
required for level flight in the landing
configuration at maximum landing
weight and a speed of 1.4 VS0, but the
power may not be less than 50%
maximum continuous power.
(5) Trim. 1.5 VS1 or minimum trim
speed, whichever is higher.
VLA.170
(a) Three-control airplanes. The
stability requirements for three-control
airplanes are as follows:
(1) The static directional stability, as
shown by the tendency to recover from
a skid with the rudder free, must be
positive for any landing gear and flap
position appropriate to the takeoff,
climb, cruise, and approach
configurations. This must be shown
with power up to maximum continuous
power, and at speeds from 1.2 VS1 up to
maximum allowable speed for the
condition being investigated. The angle
of skid for these tests must be
appropriate to the type of airplane. At
larger angles of skid up to that at which
full rudder is used or a control force
limit in CS–VLA 143 is reached,
whichever occurs first, and at speeds
from 1.2 VS1 to VA, the rudder pedal
force must not reverse.
(2) The static lateral stability, as
shown by the tendency to raise the low
wing in a slip, must not be negative for
any landing gear and flap positions.
This must be shown with power up to
75% of maximum continuous power at
speeds above 1.2 VS1, up to the
maximum allowable speed for the
configuration being investigated. The
static lateral stability may not be
negative at 1.2 VS1. The angle of slip for
these tests must be appropriate to the
type of airplane, but in no case may the
slip angle be less than that obtainable
with 10° of bank.
(3) In straight, steady slips at 1.2 VS1
for any landing gear and flap positions,
and for power conditions up to 50% of
maximum continuous power, the rudder
control movements and forces must
increase steadily (but not necessarily
linearly) as the angle of slip is increased
up to the maximum appropriate to the
type of airplane. At larger slip angles up
to the angle at which full rudder or
aileron control is used or a control force
limit contained in CS–VLA 143 is
obtained, aileron control movements
and forces must not reverse. Enough
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bank must accompany slipping to hold
a constant heading. Rapid entry into, or
recovery from, a maximum slip may not
result in uncontrollable flight
characteristics. The applicant must
demonstrate that lateral static stability
characteristics do not result in any
unsafe handling qualities.
(b) Two-control (or simplified control)
airplanes. The stability requirements for
two-control airplanes are as follows:
(1) The directional stability of the
airplane must be shown by showing
that, in each configuration, it can be
rapidly rolled from a 45° bank in one
direction to a 45° bank in the opposite
direction without showing dangerous
skid characteristics.
(2) The lateral stability of the airplane
must be shown by showing that it will
not assume a dangerous attitude or
speed when the controls are abandoned
for 2 minutes. This must be done in
moderately smooth air with the airplane
trimmed for straight level flight at 0.9
VH (maximum speed in level flight with
maximum continuous power) or VC
(design cruising speed), whichever is
lower, with flaps and landing gear
retracted, and with a rearward center of
gravity.
If an ELOS to CS–VLA 161(b)(2)(ii) is
requested, VLA.175 through VLA.210
are applicable.
VLA.175
Longitudinal trim. The airplane must
maintain longitudinal trim under each
of the following conditions:
(a) Approach with landing gear
extended and with—
(i) A 3° angle of descent, with flaps
retracted and at a speed of 1.4 VS1;
(ii) A 3° angle of descent, flaps in the
landing position(s) at reference landing
approach speed, VREF; and
(iii) An approach gradient equal to the
steepest used in the landing distance
demonstrations of CS 23.75, flaps in the
landing position(s) at VREF.
VLA.180
For normal, utility and aerobatic
category reciprocating engine-powered
airplanes of 2,722 kg (6,000 lb) or less
maximum weight, the reference landing
approach speed, VREF, must not be less
than the greater of minimum control
speed, VMC, determined under CS
23.149(b) with the wing flaps in the
most extended takeoff setting, and 1.3
VSO.
VLA.185
(a) A steady approach at not less than
VREF, determined in accordance with CS
23.73(a), (b) or (c) as appropriate, must
be maintained down to 15 m (50 ft)
height and—
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(1) The steady approach must be at a
gradient of descent not greater than
5.2% (3°) down to the 15 m (50 ft)
height.
(b) A constant configuration must be
maintained throughout the maneuver.
(c) The landing must be made without
excessive vertical acceleration or
tendency to bounce, nose-over, ground
loop, porpoise, or water loop.
(d) It must be shown that a safe
transition to the balked landing
conditions of CS 23.77 can be made
from the conditions that exist at the 15
m (50 ft) height, at maximum landing
weight, or the maximum landing weight
for altitude and temperature of CS
23.63(c)(2) or (d)(2), as appropriate.
VLA.190
(a) Each normal, utility, and aerobatic
category reciprocating engine-powered
airplane of 2,722 kg (6,000 lb) or less
maximum weight must be able to
maintain a steady gradient of climb at
sea-level of at least 3.3% with—
(1) Takeoff power on each engine;
(2) The landing gear extended;
(3) The wing flaps in the landing
position, except that if the flaps may
safely be retracted in 2 seconds or less
without loss of altitude and without
sudden changes of angle of attack, they
may be retracted; and
(4) A climb speed equal to VREF, as
defined in CS 23.73(a).
VLA.195
(a) It must be possible to carry out the
following maneuvers without requiring
the application of single-handed control
forces exceeding those specified in CS
23.143(c), unless otherwise stated. The
trimming controls must not be adjusted
during the maneuvers:
(1) With power off, landing gear and
flaps extended and the airplane as
nearly as possible in trim at VREF, obtain
and maintain airspeeds between 1.1 VS0
and either 1.7 VS0 or VFE (maximum flap
extended speed), whichever is lower,
without requiring the application of
two-handed control forces exceeding
those specified in CS 23.143(c).
(b) It must be possible, with a pilot
control force of not more than 44.5 N
(10 lbf), to maintain a speed of not more
than VREF during a power-off glide with
landing gear and wing flaps extended.
lotter on DSK11XQN23PROD with PROPOSALS1
VLA.200
It must be possible, while in the
landing configuration, to safely
complete a landing without exceeding
the one-hand control force limits
specified in CS 23.143(c) following an
approach to land—
(a) At a speed of VREF 9.3 km/h (5
knots);
VerDate Sep<11>2014
17:06 Aug 08, 2023
Jkt 259001
(b) With the airplane in trim, or as
nearly as possible in trim and without
the trimming control being moved
throughout the maneuver;
(c) At an approach gradient equal to
the steepest used in the landing distance
demonstration of CS 23.75;
(d) With only those power changes, if
any, which would be made when
landing normally from an approach at
VREF.
VLA.205
(a) Approach—It must be possible
using a favorable combination of
controls, to roll the airplane from a
steady 30° banked turn through an angle
of 60°, so as to reverse the direction of
the turn within—
(1) For an airplane of 2,722 kg (6,000
lb) or less maximum weight, 4 seconds
from initiation of roll; and
(2) For an airplane of over 2,722 kg
(6,000 lb) maximum weight, 1,000/W +
1,300 but not more than 7 seconds,
where W is weight in kg. (W + 2800/
2200 but not more than 7 seconds where
W is weight in lb.).
(b) The requirement of paragraph (a)
of this section must be met when rolling
the airplane in each direction in the
following conditions—
(1) Flaps in the landing position(s);
(2) Landing gear extended;
(3) All engines operating at the power
for a 3° approach; and
(4) The airplane trimmed at VREF.
VLA.210
(a) Landing. The stick force curve
must have a stable slope at speeds
between 1.1 VS1 and 1.8 VS1 with—
(1) Flaps in the landing position;
(2) Landing gear extended; and
(3) The airplane trimmed at—
(i) VREF, or the minimum trim speed
if higher, with power off; and
(ii) VREF with enough power to
maintain a 3° angle of descent.
Rechargeable Lithium Ion Battery
VLA.215
The applicant must consider the
following safety objectives when
showing compliance with regulations
applicable to the rechargeable lithium
ion battery.
Each rechargeable lithium ion battery
installation must:
(a) Be designed to maintain safe cell
temperatures and pressures under all
foreseeable operating conditions to
prevent fire and explosion;
(b) Be designed to prevent the
occurrence of self-sustaining,
uncontrollable increases in temperature
or pressure, and automatically control
the charge rate of each cell to protect
PO 00000
Frm 00009
Fmt 4702
Sfmt 4702
53823
against adverse operating conditions,
such as cell imbalance, back charging,
overcharging, and overheating;
(c) Not emit explosive or toxic gases,
either in normal operation or as a result
of its failure, that may accumulate in
hazardous quantities within the
airplane;
(d) Meet the requirements of 14 CFR
23.2325(g);
(e) Not damage surrounding structure
or adjacent systems, equipment,
components, or electrical wiring from
corrosive or any other fluids or gases
that may escape in such a way as to
cause a major or more-severe failure
condition;
(f) Have provisions to prevent any
hazardous effect on airplane structure or
systems caused by the maximum
amount of heat it can generate due to
any failure of it or its individual cells;
(g) Have a failure sensing and warning
system to alert the flightcrew if its
failure affects safe operation of the
airplane;
(h) Have a monitoring and warning
feature that alerts the flightcrew when
its charge state falls below acceptable
levels if its function is required for safe
operation of the airplane;
(i) Have a means to disconnect from
its charging source in the event of an
over-temperature condition, cell failure,
or battery failure.
Issued in Washington, DC, on August 4,
2023.
Daniel J. Elgas,
Director, Policy and Standards Division,
Aircraft Certification Service.
[FR Doc. 2023–17084 Filed 8–8–23; 8:45 am]
BILLING CODE 4910–13–P
DEPARTMENT OF TRANSPORTATION
Federal Aviation Administration
14 CFR Part 39
[Docket No. FAA–2023–1706; Project
Identifier MCAI–2023–00039–T]
RIN 2120–AA64
Airworthiness Directives; Bombardier,
Inc., Airplanes
Federal Aviation
Administration (FAA), DOT.
ACTION: Notice of proposed rulemaking
(NPRM).
AGENCY:
The FAA proposes to adopt a
new airworthiness directive (AD) for
certain Bombardier, Inc., Model BD–
700–1A10 and BD–700–1A11 airplanes.
This proposed AD was prompted by
reports that the nose wheel steering
selector valve (SSV) can be slow to
SUMMARY:
E:\FR\FM\09AUP1.SGM
09AUP1
Agencies
[Federal Register Volume 88, Number 152 (Wednesday, August 9, 2023)]
[Proposed Rules]
[Pages 53815-53823]
From the Federal Register Online via the Government Publishing Office [www.gpo.gov]
[FR Doc No: 2023-17084]
========================================================================
Proposed Rules
Federal Register
________________________________________________________________________
This section of the FEDERAL REGISTER contains notices to the public of
the proposed issuance of rules and regulations. The purpose of these
notices is to give interested persons an opportunity to participate in
the rule making prior to the adoption of the final rules.
========================================================================
Federal Register / Vol. 88, No. 152 / Wednesday, August 9, 2023 /
Proposed Rules
[[Page 53815]]
DEPARTMENT OF TRANSPORTATION
Federal Aviation Administration
14 CFR Part 21
[Docket No. FAA-2023-0623]
Policy for Type Certification of Very Light Airplanes as a
Special Class of Aircraft
AGENCY: Federal Aviation Administration (FAA), Department of
Transportation (DOT).
ACTION: Notice of proposed policy, request for comments.
-----------------------------------------------------------------------
SUMMARY: The FAA is requesting comments on its proposed policy for the
type certification of Very Light Airplanes (VLA) as a special class of
aircraft under the Federal Aviation Regulations.
DATES: Send comments on or before September 8, 2023.
ADDRESSES: Send comments identified by Docket No. FAA-2023-0623 using
any of the following methods:
Federal eRegulations Portal: Go to https://www.regulations.gov/ and
follow the online instructions for sending your comments
electronically.
Mail: Send comments to Docket Operations, M-30, U.S. Department of
Transportation (DOT), 1200 New Jersey Avenue SE, Room W12-140, West
Building Ground Floor, Washington, DC 20590-0001.
Hand Delivery of Courier: Take comments to Docket Operations in
Room W12-140 of the West Building Ground Floor at 1200 New Jersey
Avenue SE, Washington, DC, between 9 a.m. and 5 p.m., Monday through
Friday, except Federal holidays.
Fax: Fax comments to Docket Operations at 202-493-2251.
Docket: Background documents or comments received may be read at
https://www.regulations.gov/ at any time. Follow the online
instructions for accessing the docket or go to Docket Operations in
Room W12-140 of the West Building Ground Floor at 1200 New Jersey
Avenue SE, Washington, DC, between 9 a.m. and 5 p.m., Monday through
Friday, except Federal holidays.
FOR FURTHER INFORMATION CONTACT: Hieu Nguyen, Product Policy
Management, AIR-62B, Policy and Standards Division, Aircraft
Certification Service, Federal Aviation Administration; telephone 816-
329-4123; email [email protected].
SUPPLEMENTARY INFORMATION:
Comments Invited
The FAA invites interested people to take part in the development
of this proposed policy by sending written comments, data, or views.
The most helpful comments reference a specific portion of the proposed
policy, explain the reason for any recommended change, and include
supporting data.
Before acting on this proposal, the FAA will consider all comments
received on or before the closing date for comments. The FAA may
consider comments filed late if it is possible to do so without
incurring delay. The FAA may change the proposed policy based on the
comments received.
Privacy
Except for Confidential Business Information (CBI) as described in
the following paragraph, the FAA will post all comments it receives,
without change, to https://www.regulations.gov/, including any personal
information you provide. Using the search function of the docket
website, anyone can find and read the electronic form of all comments
received into any FAA docket, including the name of the individual
sending the comment (or signing the comment for an association,
business, labor union, etc.). DOT's complete Privacy Act Statement can
be found in the Federal Register published on April 11, 2000 (65 FR
19477-19478), as well as at https://www.dot.gov/privacy.
Confidential Business Information
CBI is commercial or financial information that is both customarily
and actually treated as private by its owner. Under the Freedom of
Information Act (FOIA) (5 U.S.C. 552), CBI is exempt from public
disclosure. If your comments responsive to this proposed policy contain
commercial or financial information that is customarily treated as
private, that you actually treat as private, and that is relevant or
responsive to these proposed airworthiness criteria, it is important
that you clearly designate the submitted comments as CBI. Please mark
each page of your submission containing CBI as ``PROPIN.'' The FAA will
treat such marked submissions as confidential under the FOIA, and the
indicated comments will not be placed in the public docket for this
notice. Send submissions containing CBI to the individual listed under
For Further Information Contact. Comments that the FAA receives, which
are not specifically designated as CBI, will be placed in the public
docket for this notice.
Background
In 1992, the FAA issued Advisory Circular (AC) 21.17-3,\1\ ``Type
Certification of Very Light Airplanes Under [14 CFR] 21.17(b)'' (AC
21.17-3), to provide guidance on acceptable means of compliance for
type, production, and airworthiness certification for very light
airplanes (VLA). AC 21.17-3 designates the Joint Aviation Authorities
(JAA) of Europe publication, ``Joint Aviation Requirements for Very
Light Aeroplanes'' (April 26, 1990) (JAR-VLA), as acceptable
airworthiness criteria that provides an equivalent level of safety
under 14 CFR 21.17(b) for FAA type certification of VLA as a special
class of aircraft. After the European Aviation Safety Agency (now the
European Union Aviation Safety Agency) (EASA) was formed, EASA
developed its VLA certification standards (CS-VLA) from JAR-VLA, with
CS-VLA becoming effective on November 14, 2003.
---------------------------------------------------------------------------
\1\ Available at https://drs.faa.gov.
---------------------------------------------------------------------------
In 2016, the FAA promulgated amendment 23-64 of 14 CFR part 23,
Revision of Airworthiness Standards for Normal, Utility, Acrobatic, and
Commuter Category Airplanes. 81 FR 96572.\2\ In the preamble to that
final rule, the FAA stated that it intended to continue to allow CS-VLA
airplanes to be approved as a special, stand-alone class of airplane
while also allowing eligibility for certification in accordance with
part 23 using accepted means of compliance. In 2017, EASA issued CS-23
Amendment 5 and EASA recognized
[[Page 53816]]
CS-VLA as an acceptable means of compliance to CS-23 Amendment 5.
---------------------------------------------------------------------------
\2\ https://www.regulations.gov; Docket No. FAA-2015-1621.
---------------------------------------------------------------------------
AC 21.17-3 considers a VLA as a special class of aircraft, and
defines a VLA as an airplane with a single engine (spark- or
compression-ignition), not more than two seats, a maximum certificated
takeoff weight of not more than 750 kg (approximately 1,654 pounds),
and a stalling speed of not more than 45 knots (CAS) in the landing
configuration, and limited to normal category maneuvers and day visual
flight rule (VFR) operations only. AC 21.17-3 states that, ``VLA
operations at night and under [instrument flight rule] (IFR) conditions
would be acceptable, provided the VLA is certificated to the JAR-VLA
requirements plus certain additional [14 CFR] part 23 requirements,
including those related to night and IFR operations, and that both the
engine and propeller installed [are] type certificated under [14 CFR]
part 33 (or JAR-E) and part 35 (or JAR-P).''
This notice of proposed policy contains additional airworthiness
criteria that are an acceptable means of compliance for design features
that differ from the VLA limits defined in AC 21.17-3 or that are not
adequately addressed by CS-VLA or JAR-VLA. The FAA previously applied
some of these additional airworthiness criteria to specific VLA type
designs,\3\ and these additional airworthiness criteria are among those
included in this notice of proposed policy.
---------------------------------------------------------------------------
\3\ Aquila GmbH Engine Mount Connection Design Criteria and
Winglets for the Aquila GmbH AT01 JAR-VLA Airplane (68 FR 63841,
October 20, 2003); Night VFR Under the Special Class (JAR-VLA)
Regulations, Aquila Aviation by Excellence GmbH, Model AT01 (78 FR
50313, August 19, 2013); Advanced Avionics Under the Special Class
(JAR-VLA) Regulations; Aquila Aviation by Excellence GmbH, Model
AT01-100 (78 FR 68687, November 15, 2013).
---------------------------------------------------------------------------
Discussion
The FAA establishes airworthiness criteria and issues type
certificates to ensure the safe design and operation of aircraft in
accordance with 49 U.S.C. 44701(a) and 44704. VLA can be type
certificated by the FAA as a special class of aircraft because VLA
airworthiness standards have not yet been established by regulation.
Under the provisions of 14 CFR 21.17(b), the airworthiness standards
for special class aircraft are the portions of the requirements in 14
CFR parts 23, 25, 27, 29, 31, 33, and 35 found by the FAA to be
appropriate and applicable to the specific type design and any other
airworthiness criteria found by the FAA to provide an equivalent level
of safety to the existing standards.
With the adoption of performance-based regulations in part 23,
amendment 23-64, VLA airplanes are eligible for certification as normal
category airplanes in accordance with part 23 using accepted means of
compliance. Or, applicants may seek type certification of VLA airplanes
as a ``special class'' under Sec. 21.17(b) using CS-VLA or JAR-VLA
requirements. The FAA accepts CS-VLA and JAR-VLA airworthiness criteria
as providing an equivalent level of safety under Sec. 21.17(b) for
special class type certification of VLA airplanes. Special class
certification may include airplane designs that differ from the limits
defined in AC 21.17-3 (e.g., engine mount, winglets, night-VFR,
increased maximum certificated takeoff weight of not more than 850 kg
(1,874 pounds), increased stall speed of not more than 50 KCAS, or
lithium battery installation) provided the airplane was certificated to
CS-VLA or JAR-VLA and the certification basis includes additional
design requirements applicable and appropriate for the specific type
design. The FAA plans to revise AC 21.17-3 to incorporate the
additional acceptable airworthiness criteria proposed in this policy.
VLA airplanes meeting the limits defined in AC 21.17-3 are
certificated to CS-VLA or JAR-VLA requirements. VLA airplane designs
that differ from the limits defined in AC 21.17-3 or designs that
incorporate features not adequately addressed by CS-VLA or JAR-VLA
requirements may be certificated to CS-VLA or JAR-VLA with additional
airworthiness criteria applicable and appropriate for the specific type
design. Specifically, this proposed policy contains additional
airworthiness criteria for such features as advanced avionic displays,
engine mount to composite airframe, winglets, night VFR operations,
increased maximum certificated takeoff weight and increased stall speed
from those defined in AC 21.17-3, and rechargeable lithium ion battery
installations.
The following are the proposed acceptable airworthiness criteria
that provide an equivalent level of safety for VLA special class type
certification under 21.17(b), in addition to the requirements in CS-VLA
or JAR-VLA, that the FAA finds to be appropriate and applicable for
specific type designs. Each of the new criteria use a ``VLA.XXX''
section-numbering scheme.
Advanced Avionic Displays
In addition to being certificated to CS-VLA or JAR-VLA
requirements, designs incorporating advanced avionic displays would
also need to meet the requirements of 14 CFR 23.1307, Miscellaneous
Equipment, amendment 23-49; Sec. 23.1311, Electronic Display
Instrument Systems, amendment 23-62; Sec. 23.1321, Arrangement and
Visibility, amendment 23-49; and Sec. 23.1359, Electrical System Fire
Protection, amendment 23-49.
Winglets
In addition to being certificated to CS-VLA or JAR-VLA
requirements, airplanes with winglets on the wings would also need to
meet the requirements of JAR 23.445,\4\ amendment 1, Outboard Fins or
Winglets.
---------------------------------------------------------------------------
\4\ JAR-23 amendment 1: Normal, Utility, Aerobatic, and Commuter
Category Aeroplanes, can be found in Docket No. FAA-2023-0623 at
https://www.regulations.gov.
---------------------------------------------------------------------------
Engine Mount to Composite Airframe
In addition to being certificated to CS-VLA or JAR-VLA
requirements, designs with engine mounting to composite airframe would
also need to meet design requirements to address fire protection of the
connection between the metal structure of an engine mount and composite
airframe by demonstrating that the composite airframe can withstand a
fire while carrying loads.
Night-VFR Operations
In addition to being certificated to CS-VLA or JAR-VLA, for
certification for night VFR operations, the airplane would also need to
meet design requirements to address the flight performance, design and
construction, powerplant installation, equipment, and operating
limitations and information, that are necessary for night VFR
operations.
Increased Maximum Certificated Takeoff Weight and Increased Stall Speed
In addition to being certificated to CS-VLA or JAR-VLA, for
approval of airplane designs with an increased maximum certificated
takeoff weight of not more than 850 kg (1,874 pounds) and increased
stall speed of not more than 50 KCAS, the airplane would also need to
meet design requirements to address the flight performance, structure,
crashworthiness, and performance information, that are necessary for
the increased weight and stall speed.
(a) If an Equivalent Level of Safety (ELOS) to CS-VLA 1143(g) and
CS-VLA 1147(b) is requested, the airplane would need to meet additional
design requirements to incorporate design features to increase
reliability, and
[[Page 53817]]
maintenance items that make the engine controls attachment not likely
to separate in flight, which are necessary to ensure that if the
mixture control separates at the engine fuel metering device, the
airplane is capable of continued safe flight and landing.
(b) Instead of the stall-characteristics requirements in CS-VLA
201(c), CS-VLA 201(f), and CS-VLA 203(c)(4), the requirements from CS
23.201(c), CS 23.201(e), and CS 23.203(c)(4)(ii), respectively, would
need to be used.
(c) In place of the handling quality attributes in CS-VLA 177(a)(2)
and CS-VLA 177(a)(3), neutral lateral stability would need to be
achieved by showing compliance with the requirements in VLA.170.
(d) If an ELOS to CS-VLA 161(b)(2)(ii) is requested, additional
airworthiness criteria from CS 23.161(c)(4), CS 23.73 (a), CS 23.75
(a)(1), (b), (c), and (d), CS 23.77(a), CS 23.145 (b)(5) and (d), CS
23.153(a), (b), (c), and (d), CS 23.157(c) and (d), and CS 23.175(c),
would need to be met to address airplane trim requirements.
Rechargeable Lithium Ion Battery
In addition to being certificated to CS-VLA or JAR-VLA, airplanes
with rechargeable lithium ion battery would need to meet airworthiness
criteria containing safety objectives necessary to address design and
installation of rechargeable lithium ion batteries.
The contents of this document do not have the force and effect of
law and are not meant to bind the public in any way. This document is
intended only to provide clarity to the public regarding existing
requirements under the law or agency policies.
Authority Citation
The authority citations for these airworthiness criteria are as
follows:
Authority: 49 U.S.C. 106(g), 40113, 44701, 44702, 44704.
Policy
The FAA proposes to continue to allow type certification of VLA as
a special class of aircraft under 14 CFR 21.17(b) using CS-VLA or JAR-
VLA requirements, while also allowing eligibility for certification as
a normal category airplane in accordance with part 23 using accepted
means of compliance. The FAA accepts CS-VLA and JAR-VLA airworthiness
criteria as providing an equivalent level of safety under Sec.
21.17(b) special class type certification of VLA airplanes. The FAA
would consider proposals for airplane designs that differ from the VLA
limits defined in AC 21.17-3 for type certification as a special class
of aircraft under Sec. 21.17(b), provided the VLA were certificated to
the JAR-VLA or CS-VLA requirements plus additional airworthiness
criteria the FAA finds appropriate and applicable for the proposed
design. Additional design requirements may include but are not limited
to the airworthiness criteria identified in the following paragraphs.
Other additional airworthiness criteria may be required to address
specific design proposals.
Advanced Avionic Displays
If the airplane has advanced avionic displays installed, the
following requirements from 14 CFR part 23 apply:
14 CFR 23.1307 at amendment 23-49, Miscellaneous
Equipment.
14 CFR 23.1311 at amendment 23-62, Electronic Display
Instrument Systems.
14 CFR 23.1321 at amendment 23-49, Arrangement and
Visibility.
14 CFR 23.1359 at amendment 23-49, Electrical System Fire
Protection.
Winglets
If the airplane has any outboard fins or winglets installed, the
design must comply with JAR 23.445.
Engine Mount to Composite Airframe
VLA.001
The requirements in this section are applicable to airplanes with
an engine mounting to composite airframe. Tests must be performed that
demonstrate that the interface between the metallic engine mount and
the glass fiber reinforced plastic fuselage withstand a fire for 15
minutes while carrying loads under the following conditions:
(a) With one lost engine mount fitting the loads are distributed
over the remaining three engine mount fittings. The most critical of
these fittings must be chosen for the test.
The loads are:
(1) In Z-direction the mass of the propulsion unit multiplied by a
maneuvering load factor resulting from a 30[deg] turn for 15 minutes,
superimposed by a maneuvering load of 3 seconds representing the
maximum positive limit maneuvering load factor of n = 3.8 from JAR-VLA
337(a).
(2) In X-direction the engine propulsion force at maximum
continuous power for 5 minutes.
(b) The flame to which the component test arrangement is subjected
must provide a temperature of 500 [deg]C within the target area.
(c) The flame must be large enough to maintain the required
temperature over the entire test zone, i.e., the fitting on the engine
compartment side.
(d) It must be shown that the test equipment, e.g., burner and
instrumentation are of sufficient power, size, and precision to yield
the test requirements arising from paragraphs (a) through (c) of this
section.
Night-VFR Operations
VLA.005
The requirements in sections VLA.005 through VLA.105 are applicable
to airplanes with a single engine (spark- or compression-ignition)
having not more than two seats, with a maximum certificated takeoff
weight of not more than 750 kg and a stalling speed in the landing
configuration of not more than 83 km/h (45 knots) (CAS), to be approved
for day-VFR [visual flight rules] or for day-and night-VFR.
VLA.010
(a) Any short period oscillation not including combined lateral-
directional oscillations occurring between the stalling speed and the
maximum allowable speed appropriate to the configuration of the
airplane must be heavily damped with the primary controls--
(1) Free; and
(2) In a fixed position.
(b) Any combined lateral-directional oscillations (``Dutch roll'')
occurring between the stalling speed and the maximum allowable speed
appropriate to the configuration of the airplane must be damped to 1/10
amplitude in 7 cycles with the primary controls--
(1) Free; and
(2) In a fixed position.
(c) Any long period oscillation of the flight path (phugoid) must
not be so unstable as to cause an unacceptable increase in pilot
workload or otherwise endanger the airplane. When under the conditions
specified in CS-VLA 175, the longitudinal control force required to
maintain speeds differing from the trimmed speed by at least plus or
minus 15% is suddenly released, the response of the airplane must not
exhibit any dangerous characteristics nor be excessive in relation to
the magnitude of the control force released.
VLA.015
The pilot compartment must be free from glare and reflections that
could interfere with the pilot's vision under all operations for which
the certification is requested. The pilot compartment must be designed
so that--
(a) The pilot's view is sufficiently extensive, clear, and
undistorted, for safe operation;
(b) The pilot is protected from the elements so that moderate rain
[[Page 53818]]
conditions do not unduly impair the pilot's view of the flight path in
normal flight and while landing; and
(c) Internal fogging of the windows covered under paragraph (a) of
this section can be easily cleared by the pilot unless means are
provided to prevent fogging.
VLA.020
(a) The airplane must be so designed that unimpeded and rapid
escape is possible in any normal and crash attitude.
(b) The opening system must be designed for simple and easy
operation. It must function rapidly and be designed so that it can be
operated by each occupant strapped in their seat, and also from outside
the cockpit. Reasonable provisions must be provided to prevent jamming
by fuselage deformation.
(c) The exit must be marked for easy location and operation even in
darkness.
VLA.025
(a) The engine must meet the specifications of CS-E, amendment
6,\5\ or 14 CFR part 33, amendment 33-36, for night-VFR operation.
---------------------------------------------------------------------------
\5\ CS-E amendment 6: Certification Specifications and
Acceptable Means of Compliance for Engines can be found in Docket
No. FAA-2023-0623 at https://www.regulations.gov.
---------------------------------------------------------------------------
(b) Restart capability. An altitude and airspeed envelope must be
established for the airplane for in-flight engine restarting and the
installed engine must have a restart capability within that envelope.
VLA.030
(a) For day-VFR operation, the propeller must meet the
specifications of CS-22 Subpart J, amendment 3. For night-VFR
operations the propeller and its control system must meet the
specifications of CS-P, amendment 2,\6\ or 14 CFR part 35, amendment
35-10, except for fixed pitch propellers, for which CS-22 \7\ subpart J
is sufficient.
---------------------------------------------------------------------------
\6\ CS-P amendment 2: Certification Specifications and
Acceptable Means of Compliance for Propellers can be found in Docket
FAA-2023-0623 at https://www.regulations.gov.
\7\ CS-22 amendment 3: Certification Specifications, Acceptable
Means of Compliance and Guidance Material for Sailplanes and Powered
Sailplanes can be found in Docket No. FAA-2023-0623 at https://www.regulations.gov.
---------------------------------------------------------------------------
(b) Engine power and propeller shaft rotational speed may not
exceed the limits for which the propeller is certificated or approved.
VLA.035
If an air filter is used to protect the engine against foreign
material particles in the induction air supply--
(a) Each air filter must be capable of withstanding the effects of
temperature extremes, rain, fuel, oil, and solvents to which it is
expected to be exposed in service and maintenance; and
(b) Each air filter must have a design feature to prevent material
separated from the filter media from re-entering the induction system
and interfering with proper fuel metering operation.
VLA.040
(a) Each exhaust system must ensure safe disposal of exhaust gases
without fire hazard or carbon monoxide contamination in the personnel
compartment.
(b) Each exhaust system part with a surface hot enough to ignite
flammable fluids or vapours must be located or shielded so that leakage
from any system carrying flammable fluids or vapours will not result in
a fire caused by impingement of the fluids or vapours on any part of
the exhaust system including shields for the exhaust system.
(c) Each exhaust system component must be separated by fireproof
shields from adjacent flammable parts of the airplane that are outside
the engine compartment.
(d) No exhaust gases may discharge dangerously near any fuel or oil
system drain.
(e) Each exhaust system component must be ventilated to prevent
points of excessively high temperature.
(f) Each exhaust heat exchanger must incorporate means to prevent
blockage of the exhaust port after any internal heat exchanger failure.
(g) No exhaust gases may be discharged where they will cause a
glare seriously affecting the pilot's vision at night.
VLA.045
(a) The power or supercharger control must give a positive and
immediate responsive means of controlling its engine or supercharger.
(b) If a power control incorporates a fuel shut-off feature, the
control must have a means to prevent the inadvertent movement of the
control into the shut-off position. The means must--
(1) Have a positive lock or stop at the idle position; and
(2) Require a separate and distinct operation to place the control
in the shut-off position.
(c) Each power or thrust control must be designed so that if the
control separates at the engine fuel metering device, the airplane is
capable of continuing safe flight and landing.
VLA.050
(a) The control must require a separate and distinct operation to
move the control toward lean or shut-off position.
(b) Each manual engine mixture control must be designed so that, if
the control separates at the engine fuel metering device, the airplane
is capable of continuing safe flight and landing.
VLA.055
If warning, caution, or advisory lights are installed in the
cockpit, they must be--
(a) Red, for warning lights (lights indicating a hazard which may
require immediate corrective action);
(b) Amber, for caution lights (lights indicating the possible need
for future corrective action);
(c) Green, for safe operation lights; and
(d) Any other color, including white, for lights not described in
paragraphs (a) through (c) of this section, provided the color differs
sufficiently from the colors prescribed in paragraphs (a) through (c)
of this section to avoid possible confusion.
(e) If warning, caution, or advisory lights are installed in the
cockpit, they must be effective under all probable cockpit lighting
conditions.
VLA.060
(a) Each instrument provided with static pressure case connections
must be so vented that the influence of airplane speed, the opening and
closing of windows, moisture, or other foreign matter, will not
significantly affect the accuracy of the instruments.
(b) The design and installation of a static pressure system must be
such that--
(1) Positive drainage of moisture is provided;
(2) Chafing of the tubing, and excessive distortion or restriction
at bends in the tubing, is avoided; and
(3) The materials used are durable, suitable for the purpose
intended, and protected against corrosion.
(c) Each static pressure system must be calibrated in flight to
determine the system error. The system error, in indicated pressure
altitude, at sea-level, with a standard atmosphere, excluding
instrument calibration error, may not exceed 9 m (30 ft) per 185 km/h (100 knots) speed for the appropriate
configuration in the speed range between 1.3 VSO with flaps
extended and 1.8 VS1 with flaps retracted. However, the
error need not be less than 9 m (30 ft).
[[Page 53819]]
VLA.065
For each airplane--
(a) Each gyroscopic instrument must derive its energy from power
sources adequate to maintain its required accuracy at any speed above
the best rate-of-climb speed;
(b) Each gyroscopic instrument must be installed so as to prevent
malfunction due to rain, oil, and other detrimental elements; and
(c) There must be a means to indicate the adequacy of the power
being supplied to the instruments.
(d) For Night VFR operation there must be at least two independent
sources of power and a manual or an automatic means to select each
power source for each instrument that uses a power source.
VLA.070
(a) Electrical system capacity. Each electrical system must be
adequate for the intended use. In addition--
(1) Electric power sources, their transmission cables, and their
associated control and protective devices, must be able to furnish the
required power at the proper voltage to each load circuit essential for
safe operation; and
(2) Compliance with paragraph (a)(l) of this section must be shown
by an electrical load analysis, or by electrical measurements, that
account for the electrical loads applied to the electrical system in
probable combinations and for probable durations.
(b) Functions. For each electrical system, the following apply:
(1) Each system, when installed, must be--
(i) Free from hazards in itself, in its method of operation, and in
its effects on other parts of the airplane;
(ii) Protected from fuel, oil, water, other detrimental substances,
and mechanical damage; and
(iii) So designed that the risk of electrical shock to occupants
and ground personnel is reduced to a minimum.
(2) Electric power sources must function properly when connected in
combination or independently.
(3) No failure or malfunction of any electric power source may
impair the ability of any remaining source to supply load circuits
essential for safe operation.
(4) Each electric power source control must allow the independent
operation of each source, except that controls associated with
alternators that depend on a battery for initial excitation or for
stabilization need not break the connection between the alternator and
its battery.
(5) Each generator must have an overvoltage control designed and
installed to prevent damage to the electrical system, or to equipment
supplied by the electrical system, that could result if that generator
were to develop an overvoltage condition.
(d) Instruments. There must be a means to indicate to the pilot
that the electrical power supplies are adequate for safe operation. For
direct current systems, an ammeter in the battery feeder may be used.
(e) Fire resistance. Electrical equipment must be so designed and
installed that in the event of a fire in the engine compartment, during
which the surface of the firewall adjacent to the fire is heated to
1,100 [deg]C for 5 minutes or to a lesser temperature substantiated by
the applicant, the equipment essential to continued safe operation and
located behind the firewall will function satisfactorily and will not
create an additional fire hazard. This may be shown by test or
analysis.
(f) External power. If provisions are made for connecting external
power to the airplane, and that external power can be electrically
connected to equipment other than that used for engine starting, means
must be provided to ensure that no external power supply having a
reverse polarity, or a reverse phase sequence, can supply power to the
airplane's electrical system. The location must allow such provisions
to be capable of being operated without hazard to the airplane or
persons.
VLA.075
(a) Each storage battery must be designed and installed as
prescribed in this section.
(b) Safe cell temperatures and pressures must be maintained during
any probable charging and discharging condition. No uncontrolled
increase in cell temperature may result when the battery is recharged
(after previous complete discharge)--
(1) At maximum regulated voltage or power;
(2) During a flight of maximum duration; and
(3) Under the most adverse cooling condition likely to occur in
service.
(c) Compliance with paragraph (b) of this section must be shown by
tests unless experience with similar batteries and installations has
shown that maintaining safe cell temperatures and pressures presents no
problem.
(d) No explosive or toxic gases emitted by any battery in normal
operation, or as the result of any probable malfunction in the charging
system or battery installation, may accumulate in hazardous quantities
within the airplane.
(e) No corrosive fluids or gases that may escape from the battery
may damage surrounding structures or adjacent essential equipment.
(f) Each nickel cadmium battery installation capable of being used
to start an engine or auxiliary power unit must have provisions to
prevent any hazardous effect on structure or essential systems that may
be caused by the maximum amount of heat the battery can generate during
a short circuit of the battery or of its individual cells.
(g) Nickel cadmium battery installations capable of being used to
start an engine or auxiliary power unit must have--
(1) A system to control the charging rate of the battery
automatically so as to prevent battery overheating;
(2) A battery temperature sensing and over-temperature warning
system with a means for disconnecting the battery from its charging
source in the event of an overtemperature condition; or
(3) A battery failure sensing and warning system with a means for
disconnecting the battery from its charging source in the event of
battery failure.
(h) In the event of a complete loss of the primary electrical power
generating system, the battery must be capable of providing 30 minutes
of electrical power to those loads that are essential to continued safe
flight and landing. The 30-minute time period includes the time needed
for the pilot(s) to recognize the loss of generated power and to take
appropriate load shedding action.
VLA.080
The instrument lights must--
(a) Make each instrument and control easily readable and
discernible;
(b) Be installed so that their direct rays, and rays reflected from
the windshield or other surface, are shielded from the pilot's eyes;
and
(c) Have enough distance or insulating material between current
carrying parts and the housing so that vibration in flight will not
cause shorting. (A cabin dome light is not an instrument light.)
VLA.085
Each taxi and landing light must be designed and installed so
that--
(a) No dangerous glare is visible to the pilots;
(b) The pilot is not seriously affected by halation;
(c) It provides enough light for night operations; and
(d) It does not cause a fire hazard in any configuration.
[[Page 53820]]
VLA.090
(a) Electronic equipment and installations must be free from
hazards in themselves, in their method of operation, and in their
effects on other components.
(b) For operations for which electronic equipment is required,
compliance must be shown with CS-VLA 1309.
VLA.095
(a) A placard meeting the requirements of this section must be
installed on or near the magnetic direction indicator.
(b) The placard must show the calibration of the instrument in
level flight with the engine operating.
(c) The placard must state whether the calibration was made with
radio receivers on or off.
(d) Each calibration reading must be in terms of magnetic headings
in not more than 30[deg] increments.
(e) If a magnetic non-stabilized direction indicator can have a
deviation of more than 10[deg] caused by the operation of electrical
equipment, the placard must state which electrical loads, or
combination of loads, would cause a deviation of more than 10[deg] when
turned on.
VLA.100
The following placards must be plainly visible to the pilot:
(a) A placard stating the following airspeeds (IAS):
(1) Design maneuvering speed, VA;
(2) The maximum landing gear operating speed, VLO.
(b) A placard stating the following approved operation:
(1) For day-VFR only operation, a placard stating, ``This airplane
is classified as a very light airplane approved for day-VFR only, in
non-icing conditions. All aerobatic maneuvers, including intentional
spinning, are prohibited. See Flight Manual for other limitations.''
(2) If night-VFR operation is approved, a placard stating, ``This
airplane is classified as a very light airplane approved for day- and
night-VFR operation, in non-icing conditions. All aerobatic maneuvers,
including intentional spinning, are prohibited. See Flight Manual for
other limitations.''
VLA.105
(a) Airspeed limitations. The following information must be
furnished--
(1) Information necessary for the marking of the airspeed limits on
the indicator, as required in CS-VLA 1545, and the significance of the
color coding used on the indicator.
(2) The speeds VA, VLO, VLE
(maximum landing gear extended speed) where appropriate.
(b) Weights. The following information must be furnished:
(1) The maximum weight.
(2) Any other weight limits, if necessary.
(c) Center of gravity. The established c.g. limits required by CS-
VLA 23 must be furnished.
(d) Maneuvers. Authorized maneuvers established in accordance with
CS-VLA 3 must be furnished.
(e) Flight load factors. Maneuvering load factors: the following
must be furnished--
(1) The factors corresponding to point A and point C in the figure
for CS-VLA 333(b), stated to be applicable at VA.
(2) The factors corresponding to point D and point E of figure 1 of
CS-VLA 333(b) to be applicable at never exceed speed, VNE.
(3) The factor with wing flaps extended as specified in CS-VLA 345.
(f) The kinds of operation (day-VFR or day- and night-VFR,
whichever is applicable) in which the airplane may be used, must be
stated. The minimum equipment required for the operation must be
listed.
(g) Powerplant limitations. The following information must be
furnished:
(1) Limitation required by CS-VLA 1521.
(2) Information necessary for marking the instruments required by
CS-VLA 1549 through 1551.
(3) Fuel and oil designation.
(4) For two-stroke engines, fuel/oil ratio.
(h) Placards. Placards required by CS-VLA 1555 through 1561 must be
presented.
Increased Maximum Certificated Takeoff Weight and Increased Stall Speed
VLA.110
If the maximum certificated takeoff weight is higher than 750 kg,
but not more than 850 kg, the requirements in sections VLA.120 through
VLA.210 apply.
VLA.115
If the stall speed in landing configuration is higher than 45
knots, but not more than 50 knots (CAS), the requirements in section
VLA.120 through VLA.210 apply.
VLA.120
The maximum horizontal distance traveled in still air, in km per
1,000 m (nautical miles per 1,000 ft) of altitude lost in a glide, and
the speed necessary to achieve this, must be determined with the engine
inoperative and its propeller in the minimum drag position, and landing
gear and wing flaps in the most favorable available position.
VLA.125
(a) Each seat is to be equipped with at least a 4-point harness
system;
(b) The applicant shall evaluate the head strike path with
validated methods, and minimize the risk of injury in case of a head
contact with the aircraft structure or interior.
(c) The design shall provide reasonable precautions to minimize the
lumbar compression loads experienced by occupants in survivable crash
landings;
(d) Each seat/harness system shall be statically tested to an
ultimate inertia load factor of 18g forward, considering an occupant's
mass of 77 kg. The lapbelt should react 60% of this load, and the upper
torso restraint should react 40% of this load.
VLA.130
(a) The airplane, although it may be damaged in emergency landing
conditions, must be designed as prescribed in this section to protect
each occupant under those conditions.
(b) The structure must be designed to give each occupant reasonable
chances of escaping injury in a minor crash landing when--
(1) Proper use is made of seat belts and shoulder harnesses; and
(2) The occupant experiences the ultimate inertia forces listed
below:
(i) Upward 3.0g
(ii) Forward 9.0g
(iii) Sideward 1.5g.
(c) Each item of mass within the cabin that could injure an
occupant if it came loose must be designed for the ultimate inertia
load factors:
(1) Upward, 3.0g;
(2) Forward, 18.0g; and
(3) Sideward, 4.5g.
Engine mount and supporting structure are included in the above
analysis if they are installed behind and above the seating
compartment.
(d) The structure must be designed to protect the occupants in a
complete turnover, assuming, in the absence of a more rational
analysis--
(1) An upward ultimate inertia force of 3g; and
(2) A coefficient of friction of 0.5 at the ground.
(e) Each airplane with retractable landing gear must be designed to
protect each occupant in a landing--
(1) With the wheels retracted;
[[Page 53821]]
(2) With moderate descent velocity; and
(3) Assuming, in the absence of a more rational analysis;
(i) A downward ultimate inertia force of 3g; and
(ii) A coefficient of friction of 0.5 at the ground.
VLA.135
(a) Each baggage compartment must be designed for its placarded
maximum weight of contents and for the critical load distributions at
the appropriate maximum load factors corresponding to the flight and
ground load conditions for the airplane.
(b) There must be means to prevent the contents of any baggage
compartment from becoming a hazard by shifting, and to protect any
controls, wiring, lines, equipment, or accessories whose damage of
failure would affect safe operations.
(c) Baggage compartments must be constructed of materials which are
at least flame resistant.
(d) Designs which provide for baggage to be carried must have means
to protect the occupants from injury under the ultimate inertia forces
specified in CS-VLA 561(b)(2).
(e) If there is no structure between baggage and occupant
compartments, the baggage items located behind the occupants and those
which might become a hazard in a crash must be secured for 1.33 x 18g.
VLA.140
(a) General. For each airplane, the following information must be
furnished:
(1) The takeoff distance determined under CS-VLA 51, the airspeed
at the 15 m height, the airplane configuration (if pertinent), the kind
of surface in the tests, and the pertinent information with respect to
cowl flap position, use of flight path control devices, and use of the
landing gear retraction system.
(2) The landing distance determined under CS-VLA 75, the airplane
configuration (if pertinent), the kind of surface used in the tests,
and the pertinent information with respect to flap position and the use
of flight path control devices.
(3) The steady rate or gradient of climb determined under CS-VLA 65
and 77, the airspeed, power, and the airplane configuration.
(4) The calculated approximate effect on takeoff distance
(paragraph (a)(1) of this section), landing distance (paragraph (a)(2)
of this section), and steady rates of climb (paragraph (a)(3) of this
section), of variations in altitude and temperature.
(5) The maximum atmospheric temperature at which compliance with
the cooling provisions of CS-VLA 1041 through 1047 is shown.
(6) The glide performance determined under VLA.120.
(b) Skiplanes. For skiplanes, a statement of the approximate
reduction in climb performance may be used instead of new data for
skiplane configuration, if--
(1) The landing gear is fixed in both landplane and skiplane
configurations;
(2) The climb requirements are not critical; and
(3) The climb reduction in the skiplane configurations is small
(0.15 to 0.25 m/s (30 to 50 feet per minute)).
(c) The following information concerning normal procedures must be
furnished:
(1) The demonstrated crosswind velocity and procedures and
information pertinent to operation of the airplane in crosswinds, and
(2) The airspeeds, procedures, and information pertinent to the use
of the following airspeeds:
(i) The recommended climb speed and any variation with altitude.
(ii) VX (speed for best angle of climb) and any
variation with altitude.
(iii) The approach speeds, including speeds for transition to the
balked landing condition.
(d) An indication of the effect on takeoff distance of a grass
surface as determined from at least one takeoff measurement on short
mown dry grass must be furnished.
VLA.145
(a) The rotation speed VR, is the speed at which the
pilot makes a control input with the intention of lifting the airplane
out of contact with the runway.
(b) VR must not be less than stalling speed,
VS1.
(c) The Airplane Flight Manual must provide the rotation speed
established above for normal takeoff procedures.
If an Equivalent Level of Safety (ELOS) to CS-VLA 1143(g) and CS-
VLA 1147(b) is requested, VLA.150 and VLA.155 are applicable.
VLA.150
Power or supercharger control attachment design must include:
(a) Features which are not likely to separate in flight (i.e., a
large load-bearing washer adjacent to the outside face of the power
control cable rod end fitting which attaches to the fuel-metering
device);
(b) Mandatory inspection intervals;
(c) Inspection procedures;
(d) Component replacement criteria.
VLA.155
Mixture control attachment design must include:
(a) Features which are not likely to separate in flight (i.e., a
large load-bearing washer adjacent to the outside face of the power
control cable rod end fitting which attaches to the fuel-metering
device);
(b) Mandatory inspection intervals;
(c) Inspection procedures;
(d) Component replacement criteria.
VLA.160
(a) For an airplane with independently controlled roll and
directional controls, it must be possible to produce and to correct
roll by unreversed use of the rolling control and to produce and to
correct yaw by unreversed use of the directional control, up to the
time the airplane stalls.
(b) For an airplane with interconnected lateral and directional
controls (2 controls) and for an airplane with only one of these
controls, it must be possible to produce and correct roll by unreversed
use of the rolling control without producing excessive yaw, up to the
time the airplane stalls.
(c) The wing level stall characteristics of the airplane must be
demonstrated in flight as follows: The airplane speed must be reduced
with the elevator control until the speed is slightly above the
stalling speed, then the elevator control must be pulled back so that
the rate of speed reduction will not exceed 1.9 km/h (one knot) per
second until a stall is produced, as shown by an uncontrollable
downward pitching motion of the airplane, or until the control reaches
the stop. Normal use of the elevator control for recovery is allowed
after the control has been held against the stop for not less than two
seconds.
(d) Except where made inapplicable by the special features of a
particular type of airplane, the following apply to the measurement of
loss of altitude during a stall:
(1) The loss of altitude encountered in the stall (power on or
power off) is the change in altitude (as observed on the sensitive
altimeter testing installation) between the altitude at which the
airplane pitches and the altitude at which horizontal flight is
regained.
(2) If power or thrust is required during stall recovery, the power
or thrust used must be that which would be used under the normal
operating procedures selected by the applicant for this maneuver.
However, the power used to regain level flight may not be applied until
flying control is regained.
[[Page 53822]]
(e) During the recovery part of the maneuver, it must be possible
to prevent more than 15[deg] of roll or yaw by the normal use of
controls.
(f) Compliance with the requirements of this section must be shown
under the following conditions:
(1) Wing flaps. Retracted, fully extended and each intermediate
normal operating position;
(2) Landing gear. Retracted and extended;
(3) Cowl flaps. Appropriate to configuration;
(4) Power
(i) Power off; and
(ii) 75% maximum continuous power. If the power-to-weight ratio at
75% of maximum continuous power results in extreme nose-up attitudes,
the test may be carried out with the power required for level flight in
the landing configuration at maximum landing weight and a speed of 1.4
stalling speed, VS0, but the power may not be less than 50%
maximum continuous power.
(5) Trim. The airplane trimmed at a speed as near 1.5
VS1 as practicable.
(6) Propeller. Full increase rpm position for the power off
condition.
VLA.165
Turning flight and accelerated stalls must be demonstrated in tests
as follows:
(a) Establish and maintain a coordinated turn in a 30[deg] bank.
Reduce speed by steadily and progressively tightening the turn with the
elevator until the airplane is stalled or until the elevator has
reached its stop. The rate of speed reduction must be constant, and--
(1) For a turning flight stall, may not exceed 1.9 km/h (one knot)
per second; and
(2) For an accelerated stall, be 5.6 to 9.3 km/h (3 to 5 knots) per
second with steadily increasing normal acceleration.
(b) When the stall has fully developed or the elevator has reached
its stop, it must be possible to regain level flight by normal use of
controls and without--
(1) Excessive loss of altitude;
(2) Undue pitchup;
(3) Uncontrollable tendency to spin;
(4) Exceeding 60[deg] of roll in either direction from the
established 30[deg] bank; and
(5) For accelerated entry stalls, without exceeding the maximum
permissible speed or the allowable limit load factor.
(c) Compliance with the requirements of this section must be shown
with--
(1) Wing Flaps. Retracted and fully extended for turning flight and
accelerated entry stalls, and intermediate, if appropriate, for
accelerated entry stalls;
(2) Landing Gear. Retracted and extended;
(3) Cowl Flaps. Appropriate to configuration;
(4) Power. 75% maximum continuous power. If the power-to-weight
ratio at 75% of maximum continuous power results in extreme nose-up
attitudes, the test may be carried out with the power required for
level flight in the landing configuration at maximum landing weight and
a speed of 1.4 VS0, but the power may not be less than 50%
maximum continuous power.
(5) Trim. 1.5 VS1 or minimum trim speed, whichever is
higher.
VLA.170
(a) Three-control airplanes. The stability requirements for three-
control airplanes are as follows:
(1) The static directional stability, as shown by the tendency to
recover from a skid with the rudder free, must be positive for any
landing gear and flap position appropriate to the takeoff, climb,
cruise, and approach configurations. This must be shown with power up
to maximum continuous power, and at speeds from 1.2 VS1 up
to maximum allowable speed for the condition being investigated. The
angle of skid for these tests must be appropriate to the type of
airplane. At larger angles of skid up to that at which full rudder is
used or a control force limit in CS-VLA 143 is reached, whichever
occurs first, and at speeds from 1.2 VS1 to VA,
the rudder pedal force must not reverse.
(2) The static lateral stability, as shown by the tendency to raise
the low wing in a slip, must not be negative for any landing gear and
flap positions. This must be shown with power up to 75% of maximum
continuous power at speeds above 1.2 VS1, up to the maximum
allowable speed for the configuration being investigated. The static
lateral stability may not be negative at 1.2 VS1. The angle
of slip for these tests must be appropriate to the type of airplane,
but in no case may the slip angle be less than that obtainable with
10[deg] of bank.
(3) In straight, steady slips at 1.2 VS1 for any landing
gear and flap positions, and for power conditions up to 50% of maximum
continuous power, the rudder control movements and forces must increase
steadily (but not necessarily linearly) as the angle of slip is
increased up to the maximum appropriate to the type of airplane. At
larger slip angles up to the angle at which full rudder or aileron
control is used or a control force limit contained in CS-VLA 143 is
obtained, aileron control movements and forces must not reverse. Enough
bank must accompany slipping to hold a constant heading. Rapid entry
into, or recovery from, a maximum slip may not result in uncontrollable
flight characteristics. The applicant must demonstrate that lateral
static stability characteristics do not result in any unsafe handling
qualities.
(b) Two-control (or simplified control) airplanes. The stability
requirements for two-control airplanes are as follows:
(1) The directional stability of the airplane must be shown by
showing that, in each configuration, it can be rapidly rolled from a
45[deg] bank in one direction to a 45[deg] bank in the opposite
direction without showing dangerous skid characteristics.
(2) The lateral stability of the airplane must be shown by showing
that it will not assume a dangerous attitude or speed when the controls
are abandoned for 2 minutes. This must be done in moderately smooth air
with the airplane trimmed for straight level flight at 0.9
VH (maximum speed in level flight with maximum continuous
power) or VC (design cruising speed), whichever is lower,
with flaps and landing gear retracted, and with a rearward center of
gravity.
If an ELOS to CS-VLA 161(b)(2)(ii) is requested, VLA.175 through
VLA.210 are applicable.
VLA.175
Longitudinal trim. The airplane must maintain longitudinal trim
under each of the following conditions:
(a) Approach with landing gear extended and with--
(i) A 3[deg] angle of descent, with flaps retracted and at a speed
of 1.4 VS1;
(ii) A 3[deg] angle of descent, flaps in the landing position(s) at
reference landing approach speed, VREF; and
(iii) An approach gradient equal to the steepest used in the
landing distance demonstrations of CS 23.75, flaps in the landing
position(s) at VREF.
VLA.180
For normal, utility and aerobatic category reciprocating engine-
powered airplanes of 2,722 kg (6,000 lb) or less maximum weight, the
reference landing approach speed, VREF, must not be less
than the greater of minimum control speed, VMC, determined
under CS 23.149(b) with the wing flaps in the most extended takeoff
setting, and 1.3 VSO.
VLA.185
(a) A steady approach at not less than VREF, determined
in accordance with CS 23.73(a), (b) or (c) as appropriate, must be
maintained down to 15 m (50 ft) height and--
[[Page 53823]]
(1) The steady approach must be at a gradient of descent not
greater than 5.2% (3[deg]) down to the 15 m (50 ft) height.
(b) A constant configuration must be maintained throughout the
maneuver.
(c) The landing must be made without excessive vertical
acceleration or tendency to bounce, nose-over, ground loop, porpoise,
or water loop.
(d) It must be shown that a safe transition to the balked landing
conditions of CS 23.77 can be made from the conditions that exist at
the 15 m (50 ft) height, at maximum landing weight, or the maximum
landing weight for altitude and temperature of CS 23.63(c)(2) or
(d)(2), as appropriate.
VLA.190
(a) Each normal, utility, and aerobatic category reciprocating
engine-powered airplane of 2,722 kg (6,000 lb) or less maximum weight
must be able to maintain a steady gradient of climb at sea-level of at
least 3.3% with--
(1) Takeoff power on each engine;
(2) The landing gear extended;
(3) The wing flaps in the landing position, except that if the
flaps may safely be retracted in 2 seconds or less without loss of
altitude and without sudden changes of angle of attack, they may be
retracted; and
(4) A climb speed equal to VREF, as defined in CS
23.73(a).
VLA.195
(a) It must be possible to carry out the following maneuvers
without requiring the application of single-handed control forces
exceeding those specified in CS 23.143(c), unless otherwise stated. The
trimming controls must not be adjusted during the maneuvers:
(1) With power off, landing gear and flaps extended and the
airplane as nearly as possible in trim at VREF, obtain and
maintain airspeeds between 1.1 VS0 and either 1.7
VS0 or VFE (maximum flap extended speed),
whichever is lower, without requiring the application of two-handed
control forces exceeding those specified in CS 23.143(c).
(b) It must be possible, with a pilot control force of not more
than 44.5 N (10 lbf), to maintain a speed of not more than
VREF during a power-off glide with landing gear and wing
flaps extended.
VLA.200
It must be possible, while in the landing configuration, to safely
complete a landing without exceeding the one-hand control force limits
specified in CS 23.143(c) following an approach to land--
(a) At a speed of VREF 9.3 km/h (5 knots);
(b) With the airplane in trim, or as nearly as possible in trim and
without the trimming control being moved throughout the maneuver;
(c) At an approach gradient equal to the steepest used in the
landing distance demonstration of CS 23.75;
(d) With only those power changes, if any, which would be made when
landing normally from an approach at VREF.
VLA.205
(a) Approach--It must be possible using a favorable combination of
controls, to roll the airplane from a steady 30[deg] banked turn
through an angle of 60[deg], so as to reverse the direction of the turn
within--
(1) For an airplane of 2,722 kg (6,000 lb) or less maximum weight,
4 seconds from initiation of roll; and
(2) For an airplane of over 2,722 kg (6,000 lb) maximum weight,
1,000/W + 1,300 but not more than 7 seconds, where W is weight in kg.
(W + 2800/2200 but not more than 7 seconds where W is weight in lb.).
(b) The requirement of paragraph (a) of this section must be met
when rolling the airplane in each direction in the following
conditions--
(1) Flaps in the landing position(s);
(2) Landing gear extended;
(3) All engines operating at the power for a 3[deg] approach; and
(4) The airplane trimmed at VREF.
VLA.210
(a) Landing. The stick force curve must have a stable slope at
speeds between 1.1 VS1 and 1.8 VS1 with--
(1) Flaps in the landing position;
(2) Landing gear extended; and
(3) The airplane trimmed at--
(i) VREF, or the minimum trim speed if higher, with
power off; and
(ii) VREF with enough power to maintain a 3[deg] angle
of descent.
Rechargeable Lithium Ion Battery
VLA.215
The applicant must consider the following safety objectives when
showing compliance with regulations applicable to the rechargeable
lithium ion battery.
Each rechargeable lithium ion battery installation must:
(a) Be designed to maintain safe cell temperatures and pressures
under all foreseeable operating conditions to prevent fire and
explosion;
(b) Be designed to prevent the occurrence of self-sustaining,
uncontrollable increases in temperature or pressure, and automatically
control the charge rate of each cell to protect against adverse
operating conditions, such as cell imbalance, back charging,
overcharging, and overheating;
(c) Not emit explosive or toxic gases, either in normal operation
or as a result of its failure, that may accumulate in hazardous
quantities within the airplane;
(d) Meet the requirements of 14 CFR 23.2325(g);
(e) Not damage surrounding structure or adjacent systems,
equipment, components, or electrical wiring from corrosive or any other
fluids or gases that may escape in such a way as to cause a major or
more-severe failure condition;
(f) Have provisions to prevent any hazardous effect on airplane
structure or systems caused by the maximum amount of heat it can
generate due to any failure of it or its individual cells;
(g) Have a failure sensing and warning system to alert the
flightcrew if its failure affects safe operation of the airplane;
(h) Have a monitoring and warning feature that alerts the
flightcrew when its charge state falls below acceptable levels if its
function is required for safe operation of the airplane;
(i) Have a means to disconnect from its charging source in the
event of an over-temperature condition, cell failure, or battery
failure.
Issued in Washington, DC, on August 4, 2023.
Daniel J. Elgas,
Director, Policy and Standards Division, Aircraft Certification
Service.
[FR Doc. 2023-17084 Filed 8-8-23; 8:45 am]
BILLING CODE 4910-13-P