Maximum possible number of similar three-colored triangles

Question

I want to maximize the number of similar triangles with vertices from three fixed sets, one vertex from each set. For example, if you fix two points $X$, $Y$ (i.e. two sets with only one member), then there are at most 12 points $Z_1,Z_2,\ldots,Z_{12}$ such that all the triangles $XYZ_i$ are similar.

This is the main question:

Let $A$, $B$, $C$ be three sets of points in the plane with the property that all of the triangles $XYZ$ with $X \in A$, $Y \in B$, $z \in C$ are similar. Is it true that $|A| \cdot |B| \cdot |C| \leq 12$?

For the $2\times2\times2$ case, can you find six points $X_1, X_2, Y_1, Y_2, Z_1, Z_2$ such that all eight triangles $X_iY_jZ_k$ are similar?

Answer 1

Here is a construction for the $2\times2\times2$ case. Perhaps, it is not unique.

Choose $t<1$ such that in a triangle $XYZ$ with $XY=1$, $XZ=t^3$, $YZ=t^2$ we have $2\angle X+3\angle Y=\pi$. Such $t$ exists, since for the minimal value of $t$ (i.e. $t^2+t^3=1$) we have $2\angle X+3\angle Y=0<\pi$, while for $t=1$ we have $2\angle X+3\angle Y=5\pi/3>\pi$.

Then the configuration below is what you need.

On this picture, the angles equal to $\angle X$ are marked with an arc, those equal to $\angle Y$ are marked with a double arc. If a segment is marked with a roman numeral $n$, its length is $t^n$; an unmarked segment has a unit length.

Answer 2

Not an answer, just an illustration of Morteza's $12$ points $Z_1,\ldots,Z_{12}$ and $12$ similar triangles:

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