Luiz:
Both equations yield approx. the same answers if you keep the units straight. I calculated the friction factor (f)(using the Colebrook equation) to be 0.00497. This compared nicely with the friction factor value of 0.005 from the Moody diagram. Next, I determined the friction term (F) from the following equation:
F(mech/chem) = [(2*f*L*V^2)/(D)]
This is the correct equation to use with friction factor as found with the Colebrook equation. The friction factors between civil and mechanical/chemical engineering varies by a factor of 4:
f(civ) = 4*f(mech/chem)
thus
F(civ) = 4*F(mech/chem) = [(f*L*V^2)/(2*D)]
this calculation yields F(mech)=43775.53 m^2/s
To find the pressure drop, you must use Bernoulli's equation. Ignoring kinetic and potential energy changes and assuming no work is being done, the equation simplifies to the following:
Delta [Pressure/density] = F
For time, assume density changes are negligible, thus:
Pressure drop = F*density - in units of kgf/cm^2
(you may have to divide by gc to get the units to work out)
I did this in english units (gc = 32.2 lbm*ft/lbf*s^2)
As far as the Sarco equation goes... you must first calculate the steam flowrate (Q). This is accomplished by:
Q= (V*PI*(D/2)^2)/density - make sure it's in (kg/hr)
then just plug it in.
I calculated the following values:
By Colebrook and Darcy formulas, we have:
Pressure drop = 25.87 psi (1.819 kgf/cm^2) or 59.68 ft (18.19 m)
By Spirax Sarco formula:
Pressure drop = 33.41 psi (2.35 kgf/cm^2) or 77.06 ft (23.49 m)
Considering the Sarco formula is an estimate, I would expect it to give a bigger pressure drop (conservative). These numbers are not that far off, though. If I were you, I would make sure your units are correct. I would also check the physical properties you are using for the 8 Kgf/cm2 (113.7 psi) sat. steam. There is a lot of room for error when using the Colebrook and Darcy formulas.
Be diligent and keep those units straight!
Good luck
Jproj
