Difference between revisions of "105-2019201 Practice 2"

Wind turbines 101

Question 1

One of the simplest models for understanding wind turbines is the 1-D momentum model. In 1-D momentum model, the wind turbine acts as a braking disk, that reduces the speed of incoming air from ${\displaystyle V_{0}}$ to ${\displaystyle V_{1}}$.

The kinetic energy carried by the incoming wind is

${\displaystyle E_{i}={\frac {1}{2}}mv_{0}^{2}}$

where the mass of incoming air is

${\displaystyle m=\rho V_{i}}$

If the wind turbine has area A, the mass of air it receives per unit time is

${\displaystyle \Delta V=Av_{0}\Delta t}$

(a)

Calculate the incoming wind power (incoming energy per time) at the blades of the turbine. How does it change with the area the blades cover? How does it change with the incoming wind speed?

(b)

The kinetic energy ${\displaystyle K_{f}}$ of the air mass after the blade can not be zero (otherwise air would not flow). Prove that the effective power (the power that can be used by the turbine) is given by

${\displaystyle P_{e}ff=P_{i}-P_{f}={\frac {\rho A}{4}}(v_{0}+v_{1})(v_{0}^{2}-v_{1}^{2})}$

Note: because the mass flow must be continuous, the area ${\displaystyle A_{1}}$ after the wind turbine is bigger than the area ${\displaystyle A_{0}}$ before. Assume

${\displaystyle A_{0}v_{0}=A_{1}v_{1}=A{\frac {(v_{0}+v_{1})}{2}}}$

(c)

The power coefficient ${\displaystyle CP}$ characterizes the relative drawing power:

${\displaystyle C_{p}={\frac {P_{e}ff}{P_{w}}}}$

prove that its optimum value is %59

Question 2

solutions