ALP Solutions Friction Physics Eng JEE
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Transcript of ALP Solutions Friction Physics Eng JEE
RESONANCE FRICTION - 1
TOPIC : FRICTIONPART - I
1. As m would slip in vertically downward direction, then mg = N
mg = N
N = 5.0100mg
= 200 Newton
Same normal force would accelerate M, thus aM = 50
200 = 4 m/s2
Taking (m + M) as systemF = (m + M). 4 = 240 N
2. Limiting friction between A & B = 90 NLimiting friction between B & C = 80 NLimiting friction between C & ground = 60 NSince limiting friction is least between C and ground, slipping will occur at first between C and ground. Thiswill occur when F = 60 N.
3. (i)
//////////////////////
2kgF=50N
µ = 0.32
µ = 0.51
B
A
3kg
f =0.5×10×2=10NBA
f =0.3×5×10=15NBG
3kg
fBA
< fBG
Hence, B will remain at rest. so aB = 0
(ii)
a = 3
2550 =
325
4. F.B.D. of man and plank are For plank be at rest, applying Newton's second
law to plank along the inclineMg sin = f .............(1)
and applying Newton�s second law to man along the incline.
mg sin + f = ma .............(2)
a = g sin
mM
1 down the incline
Alternate Solution :If the friction force is taken up the incline on man, then application of Newton�s second law to man and
plank along incline yields.f + Mg sin = 0 ..........(1)mg sin � f = ma ..........(2)
Solving (1) and (2)
a = g sin
m
M1 down the incline
PHYSICS SOLUTIONSADVANCE LEVEL PROBLEMS
TARGET : JEE (IITS)
RESONANCE FRICTION - 2
Alternate Solution :Application of Newton�s seconds law to system of man + plank along the incline yields
mg sin + Mg sin = ma
a = g sin
m
M1 down the incline
5. The person applying more frictional force on ground will win because friction is resisting the slipping.
6. Let the value of �a� be increased from zero. As long as a g, there shall be no relative motion betweenm1 or m2 and platform, that is, m1 and m2 shall move with acceleration a.As a > g the acceleration of m1 and m2 shall become g each.Hence at all instants the velocity of m1 and m2 shall be same The spring shall always remain in natural length.
7. Case Since, no relative motionFf is friction between A and B
a = 5
FF1 =
3
F F1 (max) =
38
F
Case
a = 3
FF
5
F 2 F2 (max) =
58
F
Clearly ; F1 (max) > F2 (max)
and 35
F
F
(max)2
(max)1
8.* Block is moving upwards due to frictionfr � mg sin 30 = ma
fr � 1 × 10 × 21
= 1 × 1
fr = 6 NContact force is the resultant of N and fr 30°
mgsin30
N fr
1kg
= 2r
2 fN = 22 )6()30cosmg( = 10.5 N
9.*_ Suppose blocks A and B move together. Applying NLM on C, A + B, and D60 � T = 6a
T � 18 � T' = 9a
T' � 10 = 1a
Solving a = 2 m/s2
To check slipping between A and B, we have to find friction force in this case. If it is less than limiting
static friction, then there will be no slipping between A and B.Applying NLM on A.T � f = 6(2)
as T = 48 Nf = 36 N
and fs = 42 N hence A and B move together.and T' = 12 N.
RESONANCE FRICTION - 3
PART - II
1. for uppermost block amax. = 1 m/s2
for lowermost block amax = 4
)1624( = 2 m/s2
Hence sliding between middle and lower block will start only after sliding between middle and upper
block has already started.for middle block F � 18 = 6 × 2 F = 30 N
2. Case - : For the lower block
amax
= 22
= 1m/s2
//////////////////////
1kg2kg
F = 6Nµ = 0.21
µ = 02
B
A
and common possible acceleration
= )21(6
= 2 m/s2 2kg0.2×1×10 = 2N
Hence, blocks move with different accelerations.
aA =
12�6
= 4 m/s2 A 6N2N
aB =
22
= 1 m/s2 B2N
Case When the force is acting on the lower blockmaximum possible acceleration of A
//////////////////////
1kgF = 6N
µ = 0.21
µ = 02
BA
2kg
= 12
= 2 m/s2
and common acceleration of the two blocks = )21(6
= 2 m/s2
Hence, both blocks move with common acceleration of aA = a
B = 2 m/s2
3. Step : When the body is moving up on the inclined plane (shown in fig. A)
Here N = mg cos
The acceleration of the body is
a1 = �
m
Nsinmg = � (g sin + g cos )
Let body is projected with speed 0 along the inclined plane (along the x-axis). After time t, body
reaches at point P ( = 0) (as shown in fig.B).
Let OP = s
s =
20
t1 =
20 t
1
a1 =
1
0
t
�0
0 = � a
1t1
s = � 2
ta 21 1
RESONANCE FRICTION - 4
t1 =
1as2
�
Fig. B
= cosgsing
s2..........(1)
Step : When the body starts to return from point P, the acceleration is
a2 =
mcosmg�sinmg
(In fig.C)
= g sin � g cos
s = 21
a2t 2
2
O
Fig. D
s
t2
t2 =
2as2
= cosg�sing
s2....(ii)
According to the problem,t2 = t
1,
Putting the value of t1 and t
2 from equations (i) and (ii), we get
=
)1(
)1�(2
2
tan = 0.16
4. For checking the direction of friction, let us assume there is no friction. Then net force acting
on the system along the string in vertically downward direction is given bym
2g � m
1g sin = (m
1 + m
2) a
m1g � m
1g/2 = (m
1 + m
1)a
a = g121
a > 0.
So the friction will act down the incline FBD of m1 gives : �
T � f � m1g sin = m
1a. T � k m
1g cos � m
1g sing = m
1a ��(i)
FBD of m2
m2g � T = m
2a ��(ii)
from (i) and (ii)
a = )1()cosk�sin�(g
a m2
T
m g2
Putting = 32 , = 30º and k = 0.1
a = 0.05 g (downward for m2)
RESONANCE FRICTION - 5
5. Acceleration of mass at distance xa = g(sin � 0 x cos)
Speed is maximum, when a = 0
g(sin � 0 x cos) = 0 x = 0
tan
6. The acceleration of block is
w = m
cosmgk�sinmg
or w = g sin � kg cos
Let AB = s cos = s
s = sec According to kinematics equation
s = 21
wt2
t = ws2
=
coskg�singsec2
or t2 =
cosk�singsec2
= )coskcos(sing
22
For being t minimumsin cos � k cos2 is maximum
dd
(sin cos � k cos2 ) = 0
cos2 � sin2 + 2k cos sin = 0cos 2 + k sin 2 = 0
tan 2 = k1
= 21
tan�1
k1
�
After putting the values , = 49º
7. For limiting frictionN + T sin = mg cos N = mg cos � T sin ��(i) and, Tcos = mg sin + f
= mg sin + k (mg cos � T sin )(from (i))
T (cos + k sin ) = mg sin + k mg cos
T = )sink(cos)cosk(sinmg
for minimum T , cos + k sin should be maximumLet y = cos + k sin
d
dy = �sin + k cos = 0
tan = k
Tmin
=
2
2
2 k1
k
k1
1
)cosk(sinmg =
2k1
)cosk(sinmg
RESONANCE FRICTION - 6
8. Step -I : Draw force diagram separately : In fig B, P is a point on the stringFrom fig. A,
mg � f = mw1
w1 =
mf�mg
...........(i)
From fig.B,T = f ...........(ii)
f
T
P
Fig.B
From fig.CMg � T = Mw
2
Mg � f = Mw2
w2 =
Mf�Mg
.............(iii)
Step II : Apply kinematic relation :
srel
= urel
t 21
wrel
t2 (Shown in fig.D)
Here srel
= , urel
= 0w
rel = w
2 � w
1
= 21
(w2 � w
1) t2
t = )w�w(2
12
Putting the value of w1 and w
2,
f = 2t)m�M(
Mm2
9. Considering the system as marked in the diagram T = (M + m)a.a is the common acceleration of the two masses in horizontal direction.Now taking the body m as system.F.B.D. for the body will be
N = ma (m has acceleration a in horizontal direction)Also mg � kN � T = ma (m has acceleration a downward w.r.t.wedge because of the constraint)
or a = Kmm2M
gm
wgbwbg aaa
bga
= 22 aa = a2 = Kmm2M
mg2
= m
MK2
g2
RESONANCE FRICTION - 7
10. If acceleration in bar is zero. Then the body (1) will slip on bar rightward and the body (2) moves downward.To prevent slipping, net force on each body should be zero in the frame of bar (non-inertial reference frame)In fig. A, T = mw + kmg ..........(i)In fig. B, T + kN = mg ..........(ii)
N = mw .........(iii)
1
mmw
kmg
W
T
Fig. A
m w
Fig. BFrom (ii) and (iii), we get
T + kmw = mgT = mg � kmw ............(iv)
From (i) and (iv), we get
w = )k1()k�1(g
............(v)
Since, relative acceleration of body with respect to bar (wrel
) is zero : So, the value of w in eqn.(v) isminimum value of w.
11. (a0 is acceleration of the wedge leftward)As a0 increases the component of ma0 up the up the incline increasesand friction attains its max value.Writing the force equation along the incline and perpendicular to the incline.
ma0 cos � mg sin � kN = 0 .......(i)mg cos + ma0 sin = N .......(ii)
From equation (i) and (ii),a0 cos � g sin = kg cos + K a0 sin a0 (cos � k sin ) = g{k cos + sin }
a0 = }sink{cos}sincosk{g
= g (1 + k cos ) / (cot � k)
12. (i) Assuming there is no slipping anywhere and the commonacceleration of the three blocks be awriting the force equation F = ma
10 = 12a or a = 65
.
Now fmax. between 2 kg & 3kg is1N = 0.2 × 20 = 4N.
For 2 kg block F.B.D. will be
F � f = ma = 2 × 65
10 � f = 6
10 10 �
610
= f
650
= f > fmax
There will be slipping between 2 kg and 3 kg block.Now considering the slipping the new equation would be
F � fmax = ma110 � 4 = 2a1 or a1 = 3 ms�2
Now lets take 3 kg & 7 kg as system and writing the force equation.fmax = 10 a0.
or 4 = 10 a0 a0 = 0.4 ms�2
RESONANCE FRICTION - 8
To check the required friction between 3 kg and 7 kg block.F on 7 kg block F = 7 × 0.4 = 2.8 N
fmax between 7 kg and 3 kg = 0.3 N2 = 0.3 × 50 = 15 N
2.8 < fmaxhence there is no slipping between the two blocks a2 = a3 = 0.4 ms�2.
(ii) Now again taking all as system the common acceleration would be 65
ms�2
for a = 65
ms�2 the required friction between 2 kg and 3 kg
block will be = m1a = 2 × 65
= 35
N.
35
N < fmax between 2 kg and 3 kg block
there is no slipping between them
Similarly for 7 kg block the required friction = m3a = 7 × 65
= 6
35 N.
635
N < fmax between 7 kg and 3 kg.
hence there is no slipping between them.
a1 = a2 = a3 = 65
ms�2
(iii) same as (b)
13. fABmax
= 0.3 × 30g cos37°
fABmax
= 72 NfBCmax
= 0.4 × 80g cos37° = 256 N
fCmax
= 0.5 × 120g cos37°= 480 N
when block �B� is pulled two cases are possible
(1) A & C remains stationary only �B� tends to move downwards.
(2) B & C both moves together and there is just slipping and A & B contact and C andwedge contactTaking case (2) Let B & C moves together and there is just slipping betweenA & B and between wedge and C
P + 40 g sin 37° + 50 g sin 37° � 72 � 480 = 0
P = 12 Nchecking friction between B & CfBC
+ 40 g sin 37° � 480 = 0
fBC
= 240which is within limit so case is correct.so max. force for which there will be no slipping P
max = 12 N the at this force both B & C tends to move
together.Ans. P = 12 N