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260 

14 CFR Ch. I (1–1–24 Edition) 

§ 25.563 

would cause the greatest likelihood of 
the upper torso restraint system 
(where installed) moving off the occu-
pant’s shoulder, and with the wings 
level. Peak floor deceleration must 
occur in not more than 0.09 seconds 
after impact and must reach a min-
imum of 16g. Where floor rails or floor 
fittings are used to attach the seating 
devices to the test fixture, the rails or 
fittings must be misaligned with re-
spect to the adjacent set of rails or fit-
tings by at least 10 degrees vertically 
(

i.e., out of Parallel) with one rolled 10 

degrees. 

(c) The following performance meas-

ures must not be exceeded during the 
dynamic tests conducted in accordance 
with paragraph (b) of this section: 

(1) Where upper torso straps are used 

for crewmembers, tension loads in indi-
vidual straps must not exceed 1,750 
pounds. If dual straps are used for re-

straining the upper torso, the total 
strap tension loads must not exceed 
2,000 pounds. 

(2) The maximum compressive load 

measured between the pelvis and the 
lumbar column of the anthropomorphic 
dummy must not exceed 1,500 pounds. 

(3) The upper torso restraint straps 

(where installed) must remain on the 
occupant’s shoulder during the impact. 

(4) The lap safety belt must remain 

on the occupant’s pelvis during the im-
pact. 

(5) Each occupant must be protected 

from serious head injury under the con-
ditions prescribed in paragraph (b) of 
this section. Where head contact with 
seats or other structure can occur, pro-
tection must be provided so that the 
head impact does not exceed a Head In-
jury Criterion (HIC) of 1,000 units. The 
level of HIC is defined by the equation: 

HIC

t

t

t

t

a t dt

t

t

=

(

)

(

)

⎩⎪

⎭⎪

2

1

2

1

2 5

1

1

2

( )

.

max

Where: 

t

1

is the initial integration time, 

t

2

is the final integration time, and 

a(t) is the total acceleration vs. time curve 

for the head strike, and where 

(t) is in seconds, and (a) is in units of gravity 

(g). 

(6) Where leg injuries may result 

from contact with seats or other struc-
ture, protection must be provided to 
prevent axially compressive loads ex-
ceeding 2,250 pounds in each femur. 

(7) The seat must remain attached at 

all points of attachment, although the 
structure may have yielded. 

(8) Seats must not yield under the 

tests specified in paragraphs (b)(1) and 
(b)(2) of this section to the extent they 
would impede rapid evacuation of the 
airplane occupants. 

[Amdt. 25–64, 53 FR 17646, May 17, 1988] 

§ 25.563

Structural ditching provi-

sions. 

Structural strength considerations of 

ditching provisions must be in accord-
ance with § 25.801(e). 

F

ATIGUE

E

VALUATION

 

§ 25.571

Damage-tolerance and fatigue 

evaluation of structure. 

(a) 

General.  An evaluation of the 

strength, detail design, and fabrication 
must show that catastrophic failure 
due to fatigue, corrosion, manufac-
turing defects, or accidental damage, 
will be avoided throughout the oper-
ational life of the airplane. This eval-
uation must be conducted in accord-
ance with the provisions of paragraphs 
(b) and (e) of this section, except as 
specified in paragraph (c) of this sec-
tion, for each part of the structure that 
could contribute to a catastrophic fail-
ure (such as wing, empennage, control 
surfaces and their systems, the fuse-
lage, engine mounting, landing gear, 
and their related primary attach-
ments). For turbojet powered air-
planes, those parts that could con-
tribute to a catastrophic failure must 
also be evaluated under paragraph (d) 
of this section. In addition, the fol-
lowing apply: 

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