Since the problem involves only angles, the actual size of the equilateral triangle is immaterial; for convenience, let us take it to have side length $2$.
Let A, B, C, D have co-ordinates $(0,0)$, $(2,0)$, $(1,\sqrt3)$, $(a,b)$ respectively. Then we immediately have
$$b\ =\ a\tan54^\circ.$$
Let M be the midpoint of AB and N be the foot of the perpendicular from D to CM. Then we have $|\mathrm{DN}|=1-a$, $|\mathrm{CN}|=\sqrt3-b$, and $\angle\mathrm{DCN}=\angle\mathrm{DCB}-\angle\mathrm{NCB}=18^\circ$ and so
$$\tan18^\circ\ =\ \frac{1-a}{\sqrt3-b}\ =\ \frac{1-a}{\sqrt3-a\tan54^\circ}$$
$\displaystyle\implies\ a\ =\ \frac{1-\sqrt3\tan18^\circ}{1-\tan18^\circ\tan54^\circ}.$
Finally, the positive value of the slope of the line segment DB, which is $\tan\angle\mathrm{DBA}$, is
$$\frac b{2-a}\ =\ \frac{a\tan54^\circ}{2-a}$$
and substituting for $a$ should give this value as the tangent of 42° (calculator possibly needed). (Thinking)