Let $M$ be the midpoint of $CH$. Furthermore, let $P$ be a point on (the extension of) $CH$ such that $SP$ is perpendicular to $CH$. Because $\angle CHS - \angle CSB = 90^{\circ}$, it is straightforward to show that the triangles $\triangle SBC$ and $\triangle SPH$ are similar. Consider spiral homotheties $$B(90^\circ \text{counter clockwise},\rho:=\frac{BS}{BC}=\frac{PS}{PH})$$ and $$P(90^\circ \text{counter clockwise},\frac{1}{\rho}).$$
The combination of these two transformations is a $180^{\circ}$ rotation that maps $C$ to $H$. Therefore, $M$ (i.e., the midpoint of $CH$) is the center of this rotation and is invariant under the transformation. Using this fact, it is straightforward to show that $MB=MP$. It is also easy to show that $M$ lies on the perpendicular bisector of $BD$, meaning that $MB=MD$. Therefore, we can conclude that $S$, $P$, and $T$ are collinear. In other words, $CH$ is perpendicular to $ST$.
To show that $BD$ is tangent to the circumcircle of $\triangle HST$ it suffices to show that
$$\angle DHT = \angle HST.\tag{*}$$
Note that, $CPSB$ is cyclic and therefore $\angle HPB = \angle CPB = \angle CSB = \angle HSP$. Hence, $BP$ is perpendicular to $HS$. Similarly, we have $\angle HPD = \angle HTP$ and $DP$ is perpendicular to $HT$. Let $X$ denote the intersection of $HS$ and $BP$. Similarly, let $Y$ be the intersection of $HT$ and $DP$. We have $\triangle XBS \sim \triangle PCS$, $\triangle YDT \sim \triangle PCT$, $\triangle XPH \sim \triangle PSH$, and $\triangle YPH \sim \triangle PTH$. Therefore, we can deduce
\begin{align}
\frac{SP/SH}{SB/CS} & = \frac{TP/TH}{TD/CT} = 1 \\
\implies \frac{XP}{XB} = \frac{HP}{CP}\cdot\frac{SP/SH}{SB/CS} & = \frac{HP}{CP}\cdot\frac{TP/TH}{TD/CT} = \frac{YP}{YD} \\
\implies XY & \parallel BD \\
\implies \angle DHT = \angle DHY & = \angle XYH \\
& = \angle XPH,
\end{align}
where the last equation holds because $XPYH$ is cyclic. Now, (*) follows immediately using the fact that $\angle XPH = \angle HST$.
reflex $\angle ADC=360^{\circ}-146^{\circ}=214^{\circ}=2\times 107^{\circ}=2\times \angle ABC$
Since the angle subtended at the center of a circle is double the angle subtended at the circumference, above proves that our constructed circle also passes through the point $B$. So, $|DA|=|DB|=|DC|$ which in turn means that $\angle ABD=\angle BAD=\angle DAC+\angle BAC=47^{\circ}$.
Best Answer
Take two right angles as follows, rotate one to some small angle then make them intersect.