Figure shows an aluminium wire of length...

Figure shows an aluminium wire of length `60 cm` joined to a steel wire of length `80 cm` and stretched between two fixed supports. The tension produced is `40 N`. The cross-sectional area of the steel wire is `1.0 mm^(2)` and that of the aluminimum wire is `3.0 mm^(2)` The minimum frequency of a tuning fork which can produce standing waves in the system with the joint as a node is `10P` (in `Hz`) the find `P`. Given density of aluminimum is `2.6 g//cm^(3)` and that of steel is `7.8 g//cm^(3)`.

Text Solution

Verified by Experts

The correct Answer is:

Let number of loops in steel are `P` and in aluminium number of loops are `Q`.
`:. (P)/(2l_(s)) sqrt((T)/(mu_(s))) = (Q)/(2l_(Al)) = sqrt((T)/(mu_(Al))) :. (P)/(Q) = (4)/(3) …..(1)`
For minimum frequency `P = 4`
`f=(4)/(2xx(80)/(100))sqrt((40)/(10^(-6)xx7.6xx10^(3)))`
`f = 180 Hz`

Topper's Solved these Questions

WAVE ON STRING
RESONANCE ENGLISH|Exercise Exercise- 2 PART III|15 Videos
WAVE ON STRING
RESONANCE ENGLISH|Exercise Exercise- 2 PART IV|9 Videos
WAVE ON STRING
RESONANCE ENGLISH|Exercise Exercise- 2 PART I|21 Videos
TRAVELLING WAVES
RESONANCE ENGLISH|Exercise Exercise- 3 PART I|19 Videos
WAVE OPTICS
RESONANCE ENGLISH|Exercise Advanced Level Problems|8 Videos

Similar Questions

Explore conceptually related problems

A steel wire of length 50sqrt(3) cm is connected to an aluminium wire of length 60 cm and stretched between two fixed supports. The tension produced is 104 N , if the cross section area of each wire is 1mm^(2) . If a transverse wave is set up in the wire, find the lowest frequency for which standing waves with node at the joint are produced . (density of aluminimum = 2.6 gm//cm^(3) and density of steel = 7.8 gm//cm^(3) ).

A steel wire of length 60 cm and area of cross section 10^(-6)m^(2) is joined with a n aluminium wire of length 45 cm and are of cross section 3xx10^(-6)m^(2) . The composite string is stretched by a tension of 80 N. Density of steel is 7800kgm^(-3) and that of aluminium is 2600kgm^(-3) the minimum frequency of tuning fork. Which can produce standing wave in it with node at joint is

An aluminium wire and a steel wire of same cross-sectional of 10^(-2)cm^(2) were connected together. A 10 kg block loaded on the compound wire as shown in figure. Waves are set up in the compound wire. The minimum frequency of excitation for which standing waves are observed with point A as a node is [L_(1)=60cm,L_(2)=86.6cm] density of aluminium =2.6g//cm^(3) and of steel= 7.8g//cm^(3) ]

A 40 cm wire having a mass of 3.2 g is stretched between two fixed supports 40.05 cm apart. In its fundamental mode, the wire vibrates at 220 Hz. If the area of cross section of the wire is 1.0 mm^2 , find its Young modulus.

A steel wire of length 2.0 m is stretched through 2.0 mm. The cross sectional area of the wire is 4.0 mm^2. Calculate the elastic potential energy stored in the wire in the stretched condition. Young modulus of steel =2.0x10^11Nm^-2

A steel wire 4.0m in length is stretched through 2.0mm .The cross -sectional area of the wire is 2.0 mm^(2) .If young's modulus of steel is 2.0xx10^(11) N//m^(2) (a) the energy density of wire, (b) the elastic potential energy stored in the wire.

A steel wire of length 4 m and diameter 5 mm is stretched by 5kg-wt. Find the increase in its length if the Young's modulus of steel wire is 2.4 xx 10^(12) dyn e cm^(-2)

A steel wire of 4.0 m is stretched through 2.0 mm. The cross - sectional area of the wire is 2.0 mm^2. If young's modulus of steel is 2.0 xx10^(11) Nm^(-2) find (i) the energy density of the wire, (ii) the elastic potential energy stored in the wire.

A steel wire of mass 4.0 g and length 80 cm is fixed at the two ends. The tension in the wire is 50 N. Find the frequency and wavelength of the fourth harmonic of the fundamental.

RESONANCE ENGLISH-WAVE ON STRING -Exercise- 2 PART II

A certain transverse sinusoidal wave of wavelength 20 cm is moving in ...
Text Solution
|
Figure shows a string of linear mass density 1.0g cm^(-1) on which a w...
Text Solution
|
A wire of 9.8 xx 10^(-3) kg per meter mass passes over a fricationless...
Text Solution
|
A uniform rope of length 12 mm and mass 6 kg hangs vertically from a r...
Text Solution
|
A non-uniform wire of length l and mass M has a variable linear mass d...
Text Solution
|
A man generates a symmetrical pulse in a string by moving his hand up ...
Text Solution
|
A uniform horizontal rod of length 40 cm and mass 1.2 kg is supported ...
Text Solution
|
A string of length 'l' is fixed at both ends. It is vibrating in tis 3...
Text Solution
|
A string of mass 'm' and length l, fixed at both ends is vibrating in ...
Text Solution
|
A travelling wave of amplitude 5 A is partically reflected from a boun...
Text Solution
|
A 50 cm long wire of mass 20 g suports a mass of 1.6 kg as shown in f...
Text Solution
|
A 1 m long rope, having a mass of 40 g, is fixed at one end and is tie...
Text Solution
|
In an experiment of standing waves, a string 90 cm long is attached to...
Text Solution
|
Three resonant frequencies of string with both rigid ends are 90, 150 ...
Text Solution
|
A steel wire of length 1 m, mass 0.1 kg and uniform cross-sectional ar...
Text Solution
|
A wire having a lineat density of 0.05 gm/ cc is stretched between two...
Text Solution
|
Figure shows a string stretched by a block going over a pulley. The st...
Text Solution
|
Figure shows an aluminium wire of length 60 cm joined to a steel wire ...
Text Solution
|
A metallic wire with tension T and at temperature 30^(@)C vibrates wit...
Text Solution
|