Answer:
The time of exposure required for the surface to reach the ignition temperature of 400 °C is 310 seconds.
Step-by-step explanation:
For us to solve the question, if we consider the wall to be acting like a semi - infinite wall, the equation to solve it will be given by;
(T(o) - T)/(T(∞) - T(o)) = [erf x/√(2αt)] + [exp ((hx/k) + (h²αt/k²))] x [1 - erf {(h√(αt))/k} + {(x/(2√(αt))}]
Where;
T(o) = initial uniform temperature of wall
T = required ignition temperature of the wall,
T(∞) = temperature of combustion exhaust.
h = surface coefficient between the wall and combustion gas,
α = thermal diffusivity of oak,
k = thermal conductivity of oak
x = distance from the surface of wall.
From the image i attached, looking at oak under hardwood, we have the following properties ;
ρ = 545 kg/m³
c = 2385 J/Kg.k
k = 0.17 W/m.k
Now, thermal diffusivity of oak, α is given by; α = k/ρc = 0.17/(545 x 2385) = 1.308 x 10^(-7) m²/s
Now, from the question,
T(o) = 400 °C
T = 25 °C
T(∞) = 800 °C
Thus;
(T(o) - T)/(T(∞) - T(o)) will give;
(400 - 25)/(800 - 25) = 375/775 = 0.484
At the surface, x =0,we have;
(x/(2√(αt)) = 0 and erf(0) = 0 and
1 - erf(0) = 1
also, since h= 20 W/m²K, thus, (h√(αt))/k = [20 x √((1.308 x 10^(-7) x t))]/0.17 = [20 x √(1.308 x 10^(-7) x √t)]/0.17 = 0.0425√t
Putting x = 0 in the initial equation as well as the other relevant values and rearranging, we obtain ;
0.484 = [erf 0] + [((h√αt)/k)²)] x [1 - erf {(h√(αt))/k}]
Now, from earlier, (h√(αt))/k = 0.0425√t and also erf 0 = 0 and 1 - erf (0) = 1. So;
Thus, 0.484 = e^(0.0425√t)² [(1 - erf 0.0425√t)]
By using error function calculator and trial and error method, t is approximately equal to 310 seconds.