Home
Class 11
PHYSICS
Three elastic wires PQ, PR and PS suppor...

Three elastic wires `PQ, PR` and `PS` support a body `P` of mass `M`, as shown in figure. The wires are of the some material and cross sectional area, the middle one being vertical. Find the loads by each wire.

Text Solution

Verified by Experts

Figure shows the situation wn the load (body `P`) desceneds due to the stretch in the wires. The new positions of wires `PQ` and `PS` are shown by the dotted lines. Let `T_(1)` and `T_(2), T_(3)` be teloads (tensions) carried by the three wires `PQ, PR` and `PS`, respectively, with the wires `PQ` and `PS` making angle `theta` with the vertical.

Considering the horizontal equilibrium of point `P`
`T_(1)sintheta=T_(3)sinthetaimpliesT_(1)=T_(3)=T` (say)
Considering vertical equilibrium of point `P`
`T_(2)+2Tcostheta=Mg`..........i
If `delta_(1)` and `delta_(2)` be the elongations in the wires `PR` and `PQ` (or `PS`), respectively then
`deltal_(2)=deltal_(1)costheta` (from geometry)
If `A` and `Y` be the cross sectional area and Young's modulus of each of the wires, then
`T/(AY)(Asectheta)=(T_(2))/(AY)Acosthetaimplies T=T_(2)cos^(2)theta`........ii
Solving eqn i and ii `T_(2)=(Mg)/(1+2cos^(3)theta)`
and `T_(1)=T_(3)=T=(Mgcos^(2)theta)/(1+2cos^(3)theta)`
Promotional Banner

Topper's Solved these Questions

  • PROPERTIES OF SOLIDS AND FLUIDS

    CENGAGE PHYSICS ENGLISH|Exercise Solved Examples|11 Videos

  • PROPERTIES OF SOLIDS AND FLUIDS

    CENGAGE PHYSICS ENGLISH|Exercise Exercise 5.1|12 Videos

  • NEWTON'S LAWS OF MOTION 2

    CENGAGE PHYSICS ENGLISH|Exercise Integer type|1 Videos

  • RIGID BODY DYNAMICS 1

    CENGAGE PHYSICS ENGLISH|Exercise Integer|11 Videos

Similar Questions

Explore conceptually related problems

The V – I graph for a wire of copper of length L and cross -section area A is shown in the figure below . The slope of the graph will be

The V – I graph for a wire of copper of length L and cross -section area A is shown in the figure below . The slope of the graph will be

A triangular system of mass 100 gm consisting of 3 wires of length, as shown in Fig and length of AO as 4 units, are placed in the magnetic field of 1T. The current of 1 A flows through wire AO. The wires are of same material and cross-sectional area. In which direction will the system move?

A block of mass M is suspended from a wire of length L, area of cross-section A and Young's modulus Y. The elastic potential energy stored in the wire is

A bar of mass m and length l is hanging from point A as shown in the figure . If the Young's modulus of elasticity of the bar is Y and area of cross - section of the wire is A, then the increase in its length due to its own weight will be

A metal wire of length L_1 and area of cross section A is attached to a rigid support. Another metal wire of length L_2 and of the same cross sectional area is attached to the free end of the first wire. A body of mass M is then suspended from the free end of the second wire, if Y_1 and Y_2 are the Young's moduli of the wires respectively the effective force constant of the system of two wires is

A metal wire of length L_1 and area of cross section A is ttached to a rigid support. Another metal wire of length L_2 and of the same cross sectional area is attached to the free end of the first wire. A body of mass M is then suspended from the free end of the second wire, if Y_1 and Y_2 are the Young's moduli of the wires respectively the effective force constant of the system of two wires is

A heavy plank of mass 100 kg hangs on three vertical wires of equal length arranged symmetrically (see figure). All the wires have the same cross - section. The middle wire is of steel and the other two are of copper . The modulus of elasticity of steel is assumed to be double that copper. Determine the tensions in the wire. (use g=9.8ms^-2 )

A rigid bar of mass 15 kg is supported symmetrically by three wires, each of length 2 m. The wires at the endpoints are made of copper and the middle one is made of steel. If the tension in each wire is the same, then the diameter of copper wire to the diameter of steel wire is ["Given, "Y_("copper")=1.1xx10^(11)"N m"^(-1) and Y_("steel")=1.9xx10^(11)"N m"^(-2)]

A long straight wire carrying current of 25A rests on a table as shown in figure. Another wire PQ of length 1m, mass 2*5g carries the same current but in the opposite direction. The wire PQ is free to slide up and down. To what height will PQ rise?