Answer to Question #320687 in Electric Circuits for John

Explanation

"\\qquad\\qquad\n\\begin{aligned}\n\\small \\frac{F}{\\Delta L}&=\\small \\mu.\\frac{i_1i_2}{2\\pi d} = F_{given}\\\\\n\\small i_2&=\\small F_g.\\frac{(2\\pi d)}{\\mu.i_1}\\\\\n\\\\\n\\small B_{total}&=\\small \\mu.\\frac{i_1}{2\\pi x}+\\mu.\\frac{i_2}{2\\pi(d-x)}= 0\\\\\n\\small \\frac{i_1}{x}&=\\small \\frac{i_2}{x-d}\\\\\n\\small x&=\\small \\frac{i_1 d}{(i_1-i_2)}\n\\end{aligned}"

• Here "\\small i_1" is the 13 A current on the top line and the current on the other line can be calculated.
• "\\small d" is the separation between the wires.
• Then the distance to the layer where the magnetic field is zero can be calculated.
• "\\small i_2>i_1" should be as the wires are held by an attracting force meaning that both currents are along the same direction.
• Then probably the x should receive a negative value meaning that it is not in between the wires but outside of them.