Method for assembling a PV system with thermoelectric generation

The invention claimed is: 1. A method for assembling a PV system with thermoelectric generation, comprising: attaching, by a thermally conductive adhesive, a plurality of thermoelectric generators to a back surface of a photovoltaic panel, wherein the back surface of the photovoltaic panel is a polymer; attaching, by the thermally conductive adhesive, one of a plurality of micro flat heat pipes (HP) over at least one thermoelectric generator to completely cover the at least one thermoelectric generator and overhang the at least one thermoelectric generator; attaching, by the thermally conductive adhesive, an aluminum spacer to a back surface of the photovoltaic panel adjacent each thermoelectric generator and beneath each micro flat heat pipe, wherein the thermally conductive adhesive is present as a continuous layer between the back surface of the photovoltaic panel and each thermoelectric generator of the plurality of thermoelectric generators; connecting, by first piping, condensate water from an air conditioning evaporator to a pump; connecting, by second piping, the pump to a first heat sink reservoir; connecting, by third piping, the first heat sink reservoir to a second heat sink reservoir; connecting, by fourth piping, the second heat sink reservoir to a drain; attaching, by thermally conductive adhesive, the second piping over each first end of a first number of micro flat heat pipes; and attaching, by thermally conductive adhesive, the fourth piping over each first end of a second number of micro flat heat pipes, the first number and the second number equaling the plurality of micro flat heat pipes; wherein the photovoltaic panel has a front surface, a frame and at least one electrical junction box, wherein the photovoltaic panel is configured to generate electrical current from solar radiation impinging on the front surface; the plurality of thermoelectric generators have a first side and a second side, the first side attached to the back surface, wherein each thermoelectric generator is configured to generate electrical current when the first side is at a different temperature than the second side; wherein each micro flat heat pipe of the plurality of micro flat heat pipes is attached to an entirety of the second side of at least one of the thermoelectric generators, each micro flat heat pipe having a hot end and a cold end; each heat sink of the plurality of heat sinks comprising a water reservoir; the air conditioner evaporator is connected to an air conditioner having a condensate drain; the PV system with thermoelectric generation further comprising: a water pumping unit comprising a fluid manifold in thermal contact with the hot ends of the plurality of micro flat heat pipes and a pump fluidly coupled to each water reservoir and the condensate drain; a battery; a plurality of spacers, each of the spacers being provided between each of the plurality of micro flat heat pipes and the back surface only in areas of the back surface not covered by one of the thermoelectric generators, the spacers being configured to provide thermal contact between the micro flat heat pipes and the back surface in areas not covered by one of the thermoelectric generators, the thermoelectric generators being configured to provide thermal contact between the micro flat heat pipes and the back surface in areas not covered by one of the spacers, and the spacers directly contacting the back surface, the micro flat heat pipes, and the thermoelectric generators; a controller operatively connected to the pump, the plurality of thermoelectric generators, the at least one electrical junction box and the battery, the controller comprising circuitry and at least one processor, the controller configured to: receive electrical current from the at least one electrical junction box and the plurality of thermoelectric generators; control a speed of the pump; and invert the electrical current to charge the battery. 2. The method of claim 1 , wherein the PV system with thermoelectric generation further comprises: a temperature sensor connected to the back surface and the controller; wherein the temperature sensor is configured to change resistance based on the temperature of the back surface; and wherein the controller is further configured to control the pump based on the resistance of the temperature sensor. 3. The method of claim 1 , wherein the photovoltaic panel is a monocrystalline photovoltaic panel. 4. The method of claim 1 , wherein the PV system with thermoelectric generation comprises 8 micro flat heat pipes and 8 thermoelectric generators. 5. The method of claim 1 , wherein the photovoltaic panel is a polycrystalline photovoltaic panel. 6. The method of claim 5 , wherein the PV system with thermoelectric generation comprises 4 micro flat heat pipes and 8 thermoelectric generators. 7. The method of claim 6 , wherein each micro flat heat pipe is attached to the second sides of two thermoelectric generators. 8. The method of claim 2 , wherein the controller is further configured to determine a state of charge of the battery; and wherein the controller further comprises switching circuitry configured to switch the battery to one of receiving charging current and providing voltage to the air conditioner. 9. The method of claim 2 , wherein the controller is further configured to determine a state of charge of the battery; and wherein the controller further comprises switching circuitry configured to switch the battery to one of receiving charging current and providing voltage to a load. 10. The photovoltaic panel system method of claim 9 , wherein the controller further comprises switching circuitry configured to connect the electrical current directly to an electrical grid. 11. The photovoltaic panel system method of claim 10 , wherein the PV system with thermoelectric generation further comprises a display operatively connected to the controller, the display configured to show the temperature of the back surface, a speed of the pump, the current output from each junction box, the battery state of charge and an operational status of the air conditioner. 12. The method of claim 1 , further comprising: attaching, by thermally conductive adhesive, electrode ends of a temperature sensor to the back surface. 13. The method of claim 12 , further comprising: electrically connecting each thermoelectric generator; each junction box of the photovoltaic panel; a battery; the temperature sensor and a grid connector to a controller. 14. The method of claim 13 , further comprising at least one of: electrically connecting a power input of the controller to the battery; electrically connecting a power input of the controller to at least one junction box; and electrically connecting a power input of the controller to the grid.