$$2\sin (x+30^\circ)\sin 11^\circ\sin 71^\circ=\sin 33^\circ\sin 30^\circ=\frac12(3\sin 11^\circ-4\sin^311^\circ)$$ applying $\sin3y=3\sin y -4\sin^3y$
$$\implies 4\sin (x+30^\circ)\sin 71^\circ=3-4\sin^211^\circ=3-2(1-\cos22^\circ)$$ as $\sin11^\circ\ne0$
$$\implies 2\{\cos(x-41^\circ)-\cos(x+101^\circ)\}=2\left(\cos22^\circ+\frac12\right)$$
One way to solve is to put
$(1)\cos(x-41^\circ)=\cos22^\circ,\cos(x+101^\circ)=-\frac12$
or $(2)\cos(x+101^\circ)=-\cos22^\circ=\cos(180-22)^\circ$ as $\cos(\pi-y)=-\cos y$
$=\cos158^\circ,\cos(x-41^\circ)=\frac12$
$(1)\implies x-41^\circ=360^\circ n\pm22^\circ$ where $n$ is any integer.
Taking $'+'$ sign, $x=360^\circ n+41^\circ+22^\circ=360^\circ n+63^\circ$
$\implies \cos(x+101^\circ)=\cos(360^\circ n+63^\circ+101^\circ)=\cos164^\circ \ne-\frac12$
$\implies x\ne360^\circ n+63^\circ$
Taking $'-'$ sign, $x=360^\circ n+41^\circ-22^\circ=360^\circ n+19^\circ$
$\implies \cos(x+101^\circ)=\cos(360^\circ n+19^\circ+101^\circ)=\cos120^\circ=-\frac12$
$\implies x=360^\circ n+19^\circ$ is a solution
$(2)\implies x+101^\circ=360^\circ m\pm158^\circ$ where $m$ is any integer
Taking $'+'$ sign, $x=360^\circ m+158^\circ-101^\circ=360^\circ m+57^\circ$
$\implies \cos(x-41^\circ)=\cos(360^\circ n+57^\circ-41^\circ)=\cos16^\circ \ne\frac12$
$\implies x\ne360^\circ m+57^\circ$
Taking $'-'$ sign, $x=360^\circ m-158^\circ-101^\circ=360^\circ m-259^\circ$
$\implies \cos(x-41^\circ)=\cos(360^\circ m-259^\circ-41^\circ)=\cos(-300^\circ)=\cos(360^\circ-60^\circ)=\cos60^\circ=\frac12$
$\implies x=360^\circ m-259^\circ$ is another solution