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Thermal Stresses in Spherical Bodies

In this chapter the thermal stresses in spherical bodies are presented. First, one-dimensional problems for a solid and a hollow sphere are discussed. Next, twodimensional axisymmetric problems are treated by Goodier’s thermoelastic potential and the Boussinesq harmonic functions. Problems and solutions for thermal stresses in a solid and a hollow cylinder subjected to the steady and the transient temperature field are presented. [See also Chap. 24.]

19.1 One-Dimensional Problems in Spherical Bodies The equilibrium equation without body force for a one-dimensional problem in a spherical coordinate system is obtained from Eq. (16.52) 2 dσrr + (σrr − σθθ ) = 0 dr r

(19.1)

Hooke’s law is from Eq. (16.59) σrr = 2μrr + λe − βτ σθθ = σφφ = 2μθθ + λe − βτ

(19.2)

where e = rr + 2θθ . The strain-displacement relations are rr =

du r , dr

θθ = φφ =

ur r

M. Reza Eslami et al., Theory of Elasticity and Thermal Stresses, Solid Mechanics and Its Applications 197, DOI: 10.1007/978-94-007-6356-2_19, © Springer Science+Business Media Dordrecht 2013

(19.3)

475

476

19 Thermal Stresses in Spherical Bodies

The stress components in terms of the displacement component u r are   du r ur E (1 − ν) + 2ν − (1 + ν)ατ (1 + ν)(1 − 2ν) dr r  du  u E r r ν + − (1 + ν)ατ = σφφ = (1 + ν)(1 − 2ν) dr r

σrr = σθθ

(19.4)

The equilibrium equation in terms of the displacement component u r is d  1 d  2  1 + ν dτ r ur = α dr r 2 dr 1 − ν dr

(19.5)

The general solution of Eq. (19.5) is ur =

1+ν 1 α 1 − ν r2

 τr 2 dr + C1r + C2

1 r2

(19.6)

where C1 and C2 are constants. The stresses are expressed by σrr

 (1 + ν)(1 − 2ν) 1 E −2 α 3 = (1 + ν)(1 − 2ν) 1−ν r

 τr 2 dr

+ (1 + ν)C1 − 2(1 − 2ν)C2 σθθ = σφφ

 (1 + ν)(1 − 2ν)  1 E = α 3 (1 + ν)(1 − 2ν) 1−ν r

1 r3



+ (1 + ν)C1 + (1 − 2ν)C2

τr 2 dr − τ



(19.7)

1 r3

The displacement and the thermal stresses in a solid sphere of radius a with free traction are   a  1 r 2 α  r ur = (1 + ν) 2 τr dr + 2(1 − 2ν) 3 τr 2 dr 1−ν r 0 a 0  a  r   αE 2 2 τr 2 dr − 3 τr 2 dr (19.8) σrr = 1 − ν a3 0 r 0  a   αE  2 1 r 2 2 σθθ = σφφ = τr dr + τr dr − τ 3 3 1−ν a 0 r 0 The displacement and the thermal stresses in a hollow sphere of inner radius a and outer radius b with free traction are

19.1 One-Dimensional Problems in Spherical Bodies

ur =

1+ν  1 α 1 − ν r2



r

477

τr 2 dr

a

 b  r 1 b 2  2(1 − 2ν) a3 2 τr dr + τr dr 1 + ν b3 − a 3 a b3 − a 3 r 2 a   αE  2(r 3 − a 3 ) b 2 2 r 2  = τr dr − 3 τr dr (19.9) 1 − ν r 3 (b3 − a 3 ) a r a   b  αE  2r 3 + a 3 1 r 2 2 = σφφ = τr dr + τr dr − τ 1 − ν r 3 (b3 − a 3 ) a r3 a +

σrr σθθ

The displacement and the thermal stresses in an infinite space with a spherical cavity of radius a with free traction are  1+ν 1 r 2 α τr dr ur = 1 − ν r2 a  r 2αE 1 τr 2 dr (19.10) σrr = − 1 − ν r3 a   αE  1 r 2 τr dr − τ σθθ = σφφ = 3 1−ν r a

19.2 Two-Dimensional Axisymmetric Problems We now consider two-dimensional axisynetric problems of a spherical body. The equilibrium equa

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