An insulated steel pipe with inner and outer diameters di = 100 mm and do = 110 mm, respectively, and length of 32 m carries steam at a temperature of 150°C while the air temperature is 30°C. The insulation thickness is 50 mm. The thermal conductivities of the pipe and insulation materials are

Question

An insulated steel pipe with inner and outer diameters $d_{i}$ = 100 mm and $d_{o}$ = 110 mm, respectively, and length of 32 m carries steam at a temperature of 150°C while the air temperature is 30°C. The insulation thickness is 50 mm. The thermal conductivities of the pipe and insulation materials are k = 40 W/m K and $k_{i}$ = 0.04 W/m K, respectively. The heat-transfer coefficients are: $h_{i}$ = 50 W/m²K and $h_{o}$ = 13 W/m²K.

Determine the rate of heat loss from steam to air for uninsulated and insulated pipe.
The insulation effect on the pipe heat loss is analyzed in Example 14.2.

Accepted Answer

Uninsulated pipe ([latex] d_i [/latex] = 0.1 m and [latex] d_o [/latex] = 0.11 m)
Overall heat-transfer coefficient for the uninsulated pipe

[latex]U_{\mathrm{{L}}}=1/\left[1/(\mathbf{p}d_{\mathrm{{i}}}h_{\mathrm{{i}}})+\ln\,(d_{\mathrm{{o}}}/d_{\mathrm{{i}}})/(2\mathbf{p}k)+1/(\mathbf{p}d_{\mathrm{{o}}}\,h_{o})\right][/latex]

[latex]U_{L}=1/[1/({\bf p}\,∗\,0.1\,∗\,50)+\ln\,(0.11/0.1)/(2{\bf p}\,∗\,40)+1/({\bf p}\,∗\,0.11\,∗\,13)][/latex]

[latex]=3.49\mathrm{~W/mK}[/latex]

Rate of heat loss of the uninsulated pipe

[latex]Q=U_{\mathrm{L}}L~(t_{\mathrm{i}}-t_{\mathrm{o}})=3.49∗32∗(150-30)=13402\,\mathrm{W}[/latex]

Insulated pipe with [latex]d_{i}[/latex]/[latex]d_{o}[/latex] = 0.1 m/0.11 m and [latex]d_{oi}[/latex] = 0.11 + 2∗0.05 = 0.21 m Overall heat-transfer coefficient of the insulated pipe

[latex]U_{\mathrm{{L,ins}}}=1/[1/(\mathbf{{p}}d_{\mathrm{{i}}}h_{\mathrm{{i}}})+\ln{(d_{\mathrm{{o}}}/d_{\mathrm{{i}}})/(2\mathbf{{p}}k_{})}+\ln{(d_{\mathrm{{oi}}}/d_{\mathrm{{o}}})/(2\mathbf{{p}}k_{\mathrm{{i}}})+1/(\mathbf{{p}}d_{\mathrm{{oi}}}h_{\mathrm{{o}}})}][/latex]

[latex]U_{\mathrm{L,~ins}}=1/\Big[1/({\bf p}\,∗\,0.1\,∗{50})+\ln\,(0.11/0.1)/(2{\bf p}{}\,∗\,40)+\ln\,(0.21/0.11)\Big][/latex]

[latex](2{\bf p}\ ∗\,0.04)+1/({\bf p}\ ∗\,0.21∗\,{ 13})\Big]\ =0.363\;\mathrm{W/mK}[/latex]

Rate of heat loss of the insulated pipe

[latex]Q_{{ins}}=U_{\mathrm{{L,ins}}}L\left(t_{\mathrm{i}}-t_{\mathrm{o}}\right)=0.363\,∗\ 32\,∗\,\left(150-30\right)=1395\,\mathrm{W}[/latex]

Thus, in this case the pipe insulation reduces the heat loss by (1–[latex]Q_{ins}[/latex]/Q) ∗ 100 = 90%.

Question 14.2: An insulated steel pipe with inner and outer diameters di = ......

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