Okay, I can't guarantee if I have understood the question perfectly, but here's what I came up with:
Plane 1
normal vector = CA x BA = (0,1,5) x (1,1,8) = (3,5,-1)
So the equation can be written as 3x+5y-z+k=0.
Since it passes point B, 3(1)+5(1)-(8)+k=0, so k=0. (3+5-8+k=0)
The equation I got is therefore 3x+5y-z=0.
Plane 2
This plane is perpendicular to the line passing points B and C as you mentioned. Therefore, the line joining B and C is a normal to this plane.
BC = C - B = (0,1,5) - (1,1,8) = (-1,0,-3) = normal vector of B
The equation can be written as -x-3z+k=0, or x+3z+k=0 if you'd like.
Since it also passes point A, (0)+3(0)+k=0, so k=0.
The equation I got is therefore x+3z=0.
Plane 3
This plane is perpendicular to the line passing A and C as you mentioned. Therefore, the vector AC is a normal to this plane.
AC = C - A = (0,1,5) - (0,0,0) = (0,1,5) = normal vector of C
The equation can be written as y+5z+k=0.
Since it also passes point B, (1)+5(8)+k=0, so k= -41 (1+40+k=0)
The equation I got is therefore y+5z-41=0
So let's solve for the variables now, given point r = (x,y,z).
(A) 3x+5y-z=0
(B) x+3z=0
(C) y+5z-41=0
I will eliminate 'z' as it appears nonzero in all three equations.
3(A)+(B)
(9x+15y-3z) + (x+3z) = 10x+15y=0 (1)
and
5(A)+(C)
(15x+25y-5z) + (y+5z-41) = 15x+26y-41=0 (2)
Solve for 'x' and 'y' given these two equations.
(1) 10x+15y=0
(2) 15x+26y-41=0
Eliminate x.
3(1) - 2(2)
(30x+45y) - (30x+52y-82) = 0
-7y+82=0
7y=82
y = 82/7
Substitute to either equation.
(1) 10x+15(82/7)=0
10x+1230/7=0
10x=-1230/7
x = -123/7
Substitute x and y into plane (A).
3(-123/7) + 5(82/7)- z = 0
-369/7 + 410/7 - z = 0
41/7 - z = 0
z = 41/7
Point 'r' is therefore r(-123/7,82/7,41/7).
, but yes, it must be in the plane of ABC