Answer:
0.981
Explanation:
velocity of cars ( v1 , v2 ) = 55 mi/h
coefficient of adhesion ( u ) = 0.75
Reaction time of driver of car 1 = 2.3 -s
Reaction time of driver of car 2 = 1.9 -s
breaking efficiency of car 2 ( n2 ) = 0.80
Determine the braking efficiency of car 1
First determine the distance travelled during reaction time ( dr )
dr = v * tr ------- ( 1 )
tr ( reaction time )
v = velocity
note : 1 mile = 1609 m , I hour = 60 * 60 secs
back to equation 1
for car 1
dr1 =( 55 * 2.3 * 1609 ) / ( 60 * 60 )
= 56.53 m
for car 2
dr2 = ( 55 * 1.9 * 1609 ) / ( 60 * 60 )
= 46.70 m
next we calculate the stopping distances ( d ) using the relation below
ds = d + dr
d = distance travelled during break
dr = distance travelled during reaction time
where : d = [tex]\frac{v^2intial}{2ugn}[/tex]
for car 1
d1 = [tex]\frac{(55)^2}{2*0.75*9.81* n1} * (\frac{1609}{3600} )^2[/tex]
∴ d1 = [tex]\frac{41.10}{n1}[/tex]
for car 2
d2 = [tex]\frac{(55)^2}{2*0.75*9.8*0.8} * (\frac{1609}{3600} )^2[/tex]
∴ d2 = 51.38
since the stopping distance for both cars are the same
d1 + dr1 = d2 + dr2
( 41.10 /n1 ) + 56.53 = 51.38 + 46.70
solve for n1
hence n1 = 0.981 ( braking efficiency of car 1 )
