EBK MECHANICS OF MATERIALS
EBK MECHANICS OF MATERIALS
7th Edition
ISBN: 8220102804487
Author: BEER
Publisher: YUZU
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Chapter 2.3, Problem 55P

Two steel bars (Es = 200 GPa and αs = 11.7 × 10-6/°C) are used to reinforce a brass bar (Eb =105 GPa, αb = 20.9 × 10-6/°C) that is subjected to a load P = 25 kN. When the steel bars were fabricated; the distance between the centers of the holes that were to fit on the pins was made 0.5 mm smaller than the 2 m needed. The steel bars were then placed in an oven to increase their length so that they would just fit on the pins. Following fabrication, the temperature in the steel bars dropped back to room temperature. Determine (a) the increase in temperature that was required to fit the steel bars on the pins, (b) the stress in the brass bar after the load is applied to it.

Chapter 2.3, Problem 55P, Two steel bars (Es = 200 GPa and s = 11.7  10-6/C) are used to reinforce a brass bar (Eb =105 GPa, b

Fig. P2.55

(a)

Expert Solution
Check Mark
To determine

The required temperature increment to fit the steel bars on the pins.

Answer to Problem 55P

The required temperature increment to fit the steel bars on the pins is 21.4°C_.

Explanation of Solution

Given information:

The magnitude of load P is 25kN.

The coefficient (αb) of thermal expansion of brass is 20.9×106/°C.

The coefficient (αs) of thermal expansion of steel is 11.7×106/°C.

The young’s modulus (ES) of steel core is 200GPa.

The young’s modulus (Eb) of aluminium shell is 105GPa.

Determine the temperature change require to expand steel bar by this amount.

δT=αs(ΔT)L (1)

Here, L is length of bar and δT is thermal strain deformation.

Substitute 2m for L, 11.7×106/°C  for αs, and 0.5mm for δT in Equation (1).

0.5mm(1m103mm)=2×11.7×106(ΔT)0.5×103=2.34×105(ΔT)ΔT=21.368°C

Thus, the required temperature increment to fit the steel bars on the pins is 21.4°C_.

(b)

Expert Solution
Check Mark
To determine

The normal stress in the brass bar after load applied.

Answer to Problem 55P

The normal stress due to steel is 57.0MPa_.

The normal stress due to brass is 3.67MPa_.

Explanation of Solution

Calculation:

After the assembly of the bars, a compressive force is developed in the brass bars and a tensile force is developed in the steel bars.

Determine the area (As) of elongation steel using the relation:

As=b×d×t (2)

Here, b is the width of the steel bar , d is the depth of the steel bar, and t is the thickness of the bar.

Substitute 40mm for b, 2m for d, and 5mm for t in Equation (2).

As=40×2×5=400mm2(1m103mm)2=400×106m2

Determine the deformation of steel (δP)s using the relation:

(δP)s=FLAsEs (3)

Here, F is the compressive force, L is the length of the bar, and (As) is cross sectional area of steel.

Substitute 400×106m2 for As, 200GPa for Es, P for F, and 2m for L in Equation (3).

(δP)s=P×2.00400×106(200GPa(109Pa1GPa))=P×2.0080,000,000=25×109P

Determine the area (Ab) of elongation brass using the relation:

Ab=b×d (4)

Here, b is the width of the brass bar, d is the depth of the brass bar.

Substitute 40mm for b and 15mm2 for d, in Equation (4).

Ab=40×15=600mm2(1m103mm)2=600×106m2

Determine the deformation of brass (δP)b using the relation:

(δP)b=FLAbEb (5)

Here, (Ab) is cross sectional area of brass.

Substitute 600×106m2 for Ab, 105GPa for Eb, P for F, and 2m for L in Equation (5).

(δP)s=P×2.00600×106(105GPa(109Pa1GPa))=2.00P600×106(105×109)=P×2.0063,000,000=31.746×109P

The deformation of bar and steel is equal to the initial amount of misfit.

(δP)s+(δP)b=0.5mm (6)

Here, (δP)b is thermal strain of bar and (δP)s is thermal strain of steel.

Substitute 31.746×109P for (δP)s and 25×109P for (δP)b in Equation (6).

31.746×109P+25×109P=0.5mm(1m103mm)56.746×109P=0.5×103P=8.8112×103N

Find the stresses due to fabrication for steel using the relation:

σs*=PAs (7)

Substitute 8.8112×103N for P and 400×106m2 for As in Equation (7).

σs*=8.8112×103400×106=22.028×106Pa(1MPa106Pa)=22.028MPa

Find the stresses due to fabrication for brass using the relation:

σb*=PAb (8)

Substitute 8.8112×103N for P and 600×106m2 for Ab in Equation (8).

σs*=8.8112×103600×106=14.6853×106Pa(1MPa106Pa)=14.68MPa

The stresses should be added the stress due to the 25kN.

Consider δ is the additional displacement and Ps,Pb is the additional force developed in the steel and brass.

Find the force developed in steel bar Ps using the relation:

δ=PsLAsEs=PbLAbEbPs=AsEsLδ (9)

Substitute 400×106m2 for As, 200GPa for Es, P for F, and 2m for L in Equation (9).

Ps=400×106(200×109)2.00δ=40×106δ (10)

Find the force developed in brass bar Pb using the relation:

Pb=AbEbLδ (11)

Substitute 600×106m2 for As, 105GPa for Es, P for F, and 2m for L in Equation (11).

Pb=600×106(105×109)2.00δ=31.5×106δ (12)

Find the force P as follows:

P=Ps+Pb (13)

Here, Pb is force developed in brass bar and Ps is force developed in steel bar.

Substitute 31.5×106δ for Ps and 40×106δ for Pb, and 25kN for P in Equation (13).

25kN(103N1kN)=31.5×106δ+40×106δ25,000=71,500,000δδ=349.65×106m

Substitute 349.65×106m for δ in Equation (10).

Ps=40×106(349.65×106)=13,986N

Substitute 349.65×106m for δ in Equation (12).

Pb=31.5×106(349.65×106)=11,013.975N

Find the normal stress (σs) for steel using the relation:

σs=PsAs (14)

Substitute 13,986N for Ps and 400×106m2 for As in Equation (14).

σs=13,986400×106=34.965×106N/m2

Find the normal stress (σb) for steel using the relation:

σb=PbAb (15)

Substitute 11,013.975N for Pb and 600×106m2 for Ab in Equation (15).

σb=13.9860×103600×106=18.3566×106N/m2

The stress due to fabrication added.

Find the total stress using the relation:

σs=(σs)b+σs* (16)

Here, (σs)b is normal stress due to fabrication for brass and σs* is normal stress due to fabrication for steel.

Substitute 34.965×106N/m2 for (σs)b and 22.028MPa for (σs)s in Equation (16).

σs=34.965×106+22.028MPa(106Pa1MPa)=34.965×106+22.028×106=56.991×106Pa

Thus, the normal stress due to steel is 57.0MPa_.

Find the total stress using the relation:

σb=(σb)bσb* (17)

Substitute 18.3566×106N/m2 for (σs)b and 14.6853MPa for σs* in Equation (17).

σs=18.3566×106+14.6853MPa(106Pa1MPa)=18.3566×10614.6853×106=3.6713×106Pa

Thus, the normal stress due to brass is 3.67MPa_.

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Chapter 2 Solutions

EBK MECHANICS OF MATERIALS

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