Reactor and heater configuration synergies in paraffin dehydrogenation process

What is claimed is: 1. An integrated apparatus for a reforming system, comprising: a plurality of radiant fired heaters having at least one process coil disposed within the heater, burners, and a flue gas outlet, wherein at least one process coil has one outlet, at least one inlet, and wherein the flue gas outlet is disposed on the lower surface of the fired heater; and one outlet manifold per heater having an inlet in fluid communication with the outlet of the at least one process coil, and at least one manifold outlet; wherein each process coil has a configuration of three tubes in a parallel orientation, with two semi-circular tubular sections connecting the ends of the tubes, such that the tubes and tubular sections form a W-shaped coil, with the central tube having a diameter greater than a diameter of the two outer tubes, and the central tube having one end connected to the inlet of the outlet manifold. 2. The integrated apparatus of claim 1 further comprising a convection bank having an inlet in fluid communication with the flue gas outlet, and heating tubes, wherein the heating tubes have an inlet and an outlet. 3. The integrated apparatus of claim 2 , wherein the heating tubes are for steam generation. 4. The integrated apparatus of claim 1 further comprising a plurality of moving bed reactors, wherein there is one radiant fired heater for each reactor. 5. The integrated apparatus of claim 4 wherein the reactors are stacked vertically, and the radiant fired heaters are arranged side-by-side near the stack of reactors. 6. The integrated apparatus of claim 1 wherein the process coil inlet and the outlet are disposed on an upper surface of the fired heater. 7. The integrated apparatus of claim 1 wherein the radiant fired heaters are arranged in a side-by-side disposition. 8. An integrated apparatus for a reforming system, comprising: a plurality of moving bed reactors, each reactor having a process fluid inlet and a process fluid outlet; a plurality of radiant fired heaters having at least one process coil disposed within the heater, burners, and a flue gas outlet, wherein the at least one process coil has a configuration of three tubes in a parallel orientation, with two semi-circular tubular sections connecting the ends of the tubes, such that the tubes and tubular sections form a W-shaped coil, with the central tube having a diameter greater than a diameter of the two outer tubes, and each of the outer tubes having an inlet and the central tube having an outlet, and wherein the flue gas outlet is disposed on the lower surface of the fired heater; at least two inlet manifolds, each inlet manifold having an inlet, and multiple outlets, with each inlet manifold outlet in fluid communication with the inlet of one of the outer tubes; and one outlet manifold per heater having an inlet in fluid communication with the outlet of the central tube and at least one manifold outlet in fluid communication with the reactor process fluid inlet. 9. The integrated apparatus of claim 8 wherein the reactors are stacked vertically, and the radiant fired heaters are arranged side-by-side near the stack of reactors. 10. The integrated apparatus of claim 9 wherein the plurality of reactors comprises four reactors stacked vertically. 11. The integrated apparatus of claim 8 wherein the process coil inlet and the outlet are disposed on the upper surface of the fired heater. 12. The integrated apparatus of claim 8 wherein the process coil inlet and the outlet are disposed on the upper surface of the fired heater. 13. An integrated apparatus for a reforming system, comprising: a plurality of reactors, each reactor having a process fluid inlet and a process fluid outlet, a plurality of radiant fired heaters having at least one process coil disposed within the heater, burners, and a flue gas outlet, wherein the at least one process coil has a compressed design including at least two tubular sections, wherein each tubular section has an inlet, and the tubular sections merge to form a third tubular section with one outlet, and wherein the flue gas outlet is disposed on the lower surface of the fired heater; and one outlet manifold per heater having an inlet in fluid communication with the outlet of the third tubular section and at least one manifold outlet in fluid communication with the reactor process fluid inlet. 14. The integrated apparatus of claim 13 wherein each process coil has a configuration of three tubes in a parallel orientation, with two semi-circular tubular sections connecting the ends of the tubes, such that the tubes and tubular sections form a W-shaped coil, with the central tube having an increased diameter, and the two smaller tubes having one end connected to an inlet and the larger central tube having one end connected to the outlet. 15. The integrated apparatus of claim 13 wherein the reactors are moving bed reactors. 16. The integrated apparatus of claim 13 wherein the reactors are fixed bed reactors. 17. The integrated apparatus of claim 13 wherein the reactors are stacked vertically, and the radiant fired heaters are arranged side-by-side near the stack of reactors.