Calculating the average of a set of times or list of wind directions could be regarded as similar to computing the average of a set of vectors (values containing both direction and magnitude). It is therefore necessary to equate the time values to their respective positions on a unity circle, derive their perpendicular component values and sum these as is the case for taking the "average" of any such form of cyclic group.
Say you have two times, 23:00 and 01:00, then a normal average calculation (sumproduct/count) will leave you with the incorrect value of 12:00 [(23+1)/2] instead of the correct 24:00 / 00:00 value. If you however regard 23:00 as equal to the vector 1<345° on a twenty-four hour circle and 01:00 equal to 1<15° you can obtain their vector average [cos(345°)+cos(15°) + i*(sin(345°)+sin(15°))] = 1<360° a value equating back to 00:00 on the 24 hour circle.
Note however that this method will cancel out times exactly 12 hours apart, e.g. if you only have 01:00 and 13:00 it is not possible to determine an average time.
I'll just leave you with the formulas then (times in A column)
TIME_TO_DEGREES COSINE SINE
=(360/24)*(HOUR(A2)+MINUTE(A2)/60) =COS(RADIANS(B2)) =SIN(RADIANS(B2))
=(360/24)*(HOUR(A3)+MINUTE(A3)/60) =COS(RADIANS(B3)) =SIN(RADIANS(B3))
=(360/24)*(HOUR(A4)+MINUTE(A4)/60) =COS(RADIANS(B4)) =SIN(RADIANS(B4))
=(360/24)*(HOUR(A5)+MINUTE(A5)/60) =COS(RADIANS(B5)) =SIN(RADIANS(B5))
COMPONENT AVERAGES =AVERAGE(C2:C7) =AVERAGE(D2:D7)
AVERAGE DEGREES DEGREES_TO_HOUR MAGNITUDE
+IF(AND(D8<0,C8>0),360,0) =E8/360 =(C8^2+D8^2)^0.5
In the case that the magnitude is zero it is an unfeasible operation to try and compute an average time.