Here are some thoughts so that you do not overcomplicate things next time you see something like this.
First, when you have an equilibrium situation, the sum of moments about
any point will be zero. That's because the system doesn't know (and doesn't care) what point you choose as reference for the moments. It will not acquire angular acceleration about that point simply because you chose it.
Second, you have two unknowns, namely the two support forces ##SF_1## and ##SF_2.## This means that you need two equations to find them, i.e. you need to solve a system of two equations and two unknowns. The first equation is the sum of forces equal to zero and the second the sum of moments equal to zero. The procedure for tackling this is to solve one equation, say the force equation, for one unknown in terms of the other, e.g. ##SF_2=1.2~(\text{N})-SF_1##, substitute that in the moments equation and solve for ##SF_1##.
However, you can take a shortcut and choose as reference point for the moments the point at which one of the forces is applied. This gives you an equation with only one unknown moment which you can solve for the unknown force. That's exactly what
@Chestermiller did in post #2 by choosing as reference the point where ##SF_1## is applied. Of course, the remaining force can be found by substituting in the sum of forces is zero equation.
To summarize, in static equilibrium problems the moment balance is simplified by choosing a reference point for moments where one (or more) forces act.
