In a triangle $ABC, AB=AC$, $BC=22\sqrt3$, $\cos A=-\frac{17}{225}$. $D$ is a point on $AC$ such that $AD<DC$ and $P$ is the point on the segment $BD$ such that $\angle APC = 90^{\circ}$. Given $\angle ABD=\angle BCP$, find $BD$.
Here's a diagram of what it's like I guess:
With reference to the diagram, $\cos (x+y)=\frac{11}{15}$, after taking $\cos (180^{\circ}-A)$ and so on. I kind of did cosine rule for both triangles $ABD$ and $BCD$ to get expressions for $BD^2$ and tried to sub in $\cos(x+y)$ but that is quite messy and doesn't really get anything. I also tried Stewart's theorem for $BD^2$. Are there any similar triangles or auxiliary lines that I'm not seeing? Can someone give a hint on this? Thanks.
Hint:
\begin{align} \triangle BCD&\cong \triangle CPD ,\\ \frac{|BD|}{|CD|} &= \frac{|CD|}{|PD|} =\frac{|BC|}{|PC|} \end{align}
\begin{align} \cos\tfrac\alpha2&=\frac{2\sqrt{26}}{15} =\sin\beta ,\\ \cos\beta&=\frac{11}{15} ,\\ |AB|=|AC|&=\frac{|BC|}{2\cos\beta} =15\sqrt3 ,\\ |AM|=|MC|=|MP|&=\tfrac12|AC|=\tfrac{15\sqrt3}2 ,\\ \triangle CDP:\quad \frac{|CD|}{|PD|} &=\frac{\sin\beta}{\sin(\beta-\phi)} ,\\ \triangle PMD:\quad |PD| &= \frac{|PC|\sin(\beta-\phi)}{\sin(2\beta-\phi)} ,\\ \frac{|BD|}{|CD|} &=\frac{|BC|}{|PC|} \\ &=\frac{|BC|}{|AC|\cos(\beta-\phi)} =\frac{22}{15\cos(\beta-\phi)} . \end{align}
From \begin{align} \frac{\sin\beta}{\sin(\beta-\phi)} &=\frac{22}{15\cos(\beta-\phi)} ,\\ \phi& =\beta-\arctan(\tfrac{15\sin\beta}{22}) =\beta-\arctan(\tfrac{\sqrt{26}}{11}) \end{align}
\begin{align} \frac{|BD|}{|CD|} &=\frac{22}{15\cos(\arctan(\tfrac{\sqrt{26}}{11}))} =\frac{14\sqrt3}{15} ,\\ \triangle CDP:\quad |PD| &= \frac{|AC|\cos(\beta-\phi)\sin(\beta-\phi)}{\sin(2\beta-\phi)} . \end{align}
After simplification, $|PD|=\tfrac{75}7$ and then
\begin{align} \frac{|BD|}{|CD|} \cdot \frac{|CD|}{|PD|} &=\left(\frac{|BD|}{|CD|}\right)^2 =\frac{196}{75} =\frac{|BD|}{|PD|} ,\\ |BD|&=\frac{196}{75} \cdot\frac{75}7 =28 . \end{align}