A S V A B
M e c h a n i c a l
C o m p r e h e n s i o n
force
-
ANS
mass
×
acceleration
vector
quantities
-
ANS
forces
that
has
both
size
and
direction
equilibrium
-
ANS
a
stable
situation
in
which
forces
cancel
one
another
velocity
-
ANS
the
speed
and
direction
of
a
moving
object
acceleration
-
ANS
the
rate
at
which
velocity
changes
pressure
-
ANS
force
(in
pounds)
÷
area
(in
inches)
work
-
ANS
force
×
distance
tension
is
measured
in
-
ANS
pounds-force
or
newtons
work
is
measured
in
-
ANS
foot-pounds
power
-
ANS
work
÷
time
power
is
measured
in
-
ANS
horsepower
(hp)
1
horsepower
-
ANS
33,000
foot-pounds
per
minute
or
550
foot-pounds
per
second
mechanical
advantage
-
ANS
when
a
machine
multiplies
the
force
you
use
mechanical
advantage
-
ANS
resistance
÷
effort
=
output
force
÷
input
force
fulcrum
-
ANS
point
of
support
to
reduce
resistance
and
multiply
the
effect
of
effort
resistance
arm
-
ANS
the
part
of
a
lever
that
applies
a
force
on
an
object
M e c h a n i c a l
C o m p r e h e n s i o n
force
-
ANS
mass
×
acceleration
vector
quantities
-
ANS
forces
that
has
both
size
and
direction
equilibrium
-
ANS
a
stable
situation
in
which
forces
cancel
one
another
velocity
-
ANS
the
speed
and
direction
of
a
moving
object
acceleration
-
ANS
the
rate
at
which
velocity
changes
pressure
-
ANS
force
(in
pounds)
÷
area
(in
inches)
work
-
ANS
force
×
distance
tension
is
measured
in
-
ANS
pounds-force
or
newtons
work
is
measured
in
-
ANS
foot-pounds
power
-
ANS
work
÷
time
power
is
measured
in
-
ANS
horsepower
(hp)
1
horsepower
-
ANS
33,000
foot-pounds
per
minute
or
550
foot-pounds
per
second
mechanical
advantage
-
ANS
when
a
machine
multiplies
the
force
you
use
mechanical
advantage
-
ANS
resistance
÷
effort
=
output
force
÷
input
force
fulcrum
-
ANS
point
of
support
to
reduce
resistance
and
multiply
the
effect
of
effort
resistance
arm
-
ANS
the
part
of
a
lever
that
applies
a
force
on
an
object