How does WolframAlpha get an exact answer here? ${}{}$
Here are three relevant formulas:
$\sin 2x = 2 \sin x \cos x$.
$\cos \cos^{-1} x = x.$
$\sin \cos^{-1} x = \sqrt{1 - x^2}$ after drawing an appropriate right triangle.
Combining these three to get the desired conclusion is left to the interested reader.
Call
$$ u = \cos^{-1}\frac{15}{17} $$
Therefore
$$ \cos u = \frac{15}{17} $$
and
$$ \sin u = \sqrt{1 - \cos^2 u} = \sqrt{1 - \frac{15^2}{17^2}} = \frac{8}{17} $$
With these two you just need to calculate
$$ \sin 2u = 2\sin u \cos u = 2\frac{15}{17}\frac{8}{17} = \color{blue}{\frac{240}{289}} $$
\begin{align} \sin \theta &= \dfrac{8}{17} \\ \cos \theta &= \dfrac{15}{17} \\ \hline \sin\left(2 \arccos \dfrac{15}{17} \right) &= \sin(2 \theta) \\ &= 2 \sin(\theta) \cos(\theta) \\ &= \cdots \end{align}
$ (8,15,17)$ are lengths of a Pythagorean triple right triangle. A narrow right triangle of these side lengths can be drawn if needed.
$$\sin(2\cos^{-1}\frac{15}{17}) = \sin(2\sin^{-1}\frac{8}{17}) = 2 \cdot \frac{8}{17}\cdot \frac{15}{17} =\frac{240}{289}.$$
Let $\cos^{-1}x=y\implies\cos y=x$
Using Principal values, $0\le x\le\pi\implies\sin y\ge0$
and $\sin y=+\sqrt{1-\cos^2y}=?$
Finally, $\sin2(\cos^{-1}x)=\sin2y=2\sin y\cos y=?$