Hybrid solar module coupling and method of making

1 . A fluid coupler for hydronic solar panels, framed with a rigid frame, comprising: a male coupling rigidly attached to a first manifold pipe, the male coupling having a sealing face perpendicular to a longitudinal axis of the first manifold pipe; and a female coupling rigidly attached to a second manifold pipe, the female coupling having a sealing face perpendicular to a longitudinal axis of the second manifold pipe, and wherein the female coupling includes a coupling nut longitudinally constrained along and freely rotatable around the axis of the second manifold pipe. 2 . The fluid coupler of claim 1 , wherein the male coupling terminates inside a solar panel module with a spigot coupling that is engaged after a frame has been applied to the solar panel module. 3 . The fluid coupling of claim 2 , wherein the spigot is formed by welding or machining. 4 . The fluid coupling of claim 2 , wherein the engaged configuration creates a distance between the shoulder of the male coupling and the shoulder of the female coupling that is the same width as the internal frame to frame distance, so that the projection of couplings beyond the frame is constant. 5 . The fluid coupling of claim 1 , wherein the female coupling terminates inside a solar panel module with a spigot coupling that is engaged after a frame has been applied to the solar panel module. 6 . The fluid coupling of claim 5 , wherein the spigot is formed by welding or machining. 7 . The fluid coupling of claim 5 , wherein the engaged configuration creates a distance between the shoulder of the male coupling and the shoulder of the female coupling that is the same width as the internal frame to frame distance, so that the projection of couplings beyond the frame is constant. 8 . The fluid coupling of claim 1 , wherein the freely rotating nut is constrained between the frame and an internal shoulder of a flat faced body element of the female coupling. 9 . The fluid coupling of claim 1 forming, when the coupling nut is engaged with the male coupling, a continuous straight pipe through multiple solar panel modules. 10 . The fluid coupling of claim 1 , wherein, when the coupling nut is engaged with the male coupling forming a continuous pipe, the formed continuous pipe has constant inner diameter to minimize pressure loss. 11 . The fluid coupling of claim 1 , wherein the male coupling and female coupling are made of the same material to avoid corrosion. 12 . The fluid coupling of claim 1 , wherein the frame is predominantly flat walled. 13 . The fluid coupling of claim 1 , wherein the diameter of the male coupling is larger than a clearance hole in the frame. 14 . The fluid coupling of claim 1 , wherein the diameter of the female coupling is larger than a clearance hole in the frame. 15 . The fluid coupling of claim 1 further comprises an O-ring seal constrained in an annular groove in one of the sealing faces. 16 . The fluid coupling of claim 15 , wherein the annular groove is an angled groove providing positive retention force on the O-ring tending to prevent displacement of the O-ring retained therein. 17 . The fluid coupling of claim 1 , in combination with first and second hydronic solar panels, framed with rigid frames that when engaged, have a frame to frame spacing of 15-25 mm, the coupling being disposed in the spacing. 18 . The fluid coupling of claim 1 , wherein the male and female couplings extend through respective clearance holes disposed in respective frame portions of respective solar panel modules, and wherein the respective clearance holes each include an anti-rotation feature tending to prevent rotation of the manifold pipe with respect to the frame portion thereat when torque is applied to the coupling nut. 19 . The fluid coupling of claim 18 , where the anti-rotation feature comprises one or more flat edges. 20 . A method of making a hybrid solar panel module, the method comprising the steps of: assembling a photovoltaic laminate; connecting a roll bond heat exchanger to the laminate using an adhesive layer; applying a sealing gasket and frame to the module; preassembling coupling and pipe sections to form the spigot for connecting into a central manifold tee; inserting the spigot-coupling sections through an orifice in the coupling nut and clearance holes of the frame; and connecting the manifold to the internal tee connector after the inserting.