Heat dissipation for a photovoltaic junction box

The invention claimed is: 1. A junction box comprising: a base; a cover configured to be mounted over the base; two bus bars disposed within the junction box, and at least one bypass mechanism coupled between the two bus bars; a power device disposed within the junction box; a heat dissipation mechanism mounted on the cover or on the base, and wherein the heat dissipation mechanism is in thermal contact with the power device when the cover is mounted over the base, and wherein at least one of the bus bars includes a first heat spreading part designed to conduct heat in a first direction and a second heat spreading part designed to conduct heat in a second direction. 2. The junction box of claim 1 , wherein at least one of the bus bars is a multi-directional heat spreader. 3. The junction box of claim 1 , wherein at least one of the bus bars is designed to conduct heat in a direction of the base and in a direction of the cover. 4. The junction box of claim 1 , further comprising a plurality of connectors, each connector designed to be connected to a conductor carrying current from a photovoltaic generator, and each connector electrically coupled to at least one of the bus bars. 5. The junction box of claim 1 , wherein the at least one bypass mechanism includes at least one diode. 6. The junction box of claim 1 , further comprising a plurality of bus bars, wherein the at least one bypass mechanism comprises a plurality of bypass mechanisms, wherein the plurality of bypass mechanisms are serially coupled. 7. The junction box of claim 6 , further comprising an additional bypass mechanism disposed in parallel to two or more bypass mechanisms of the plurality of bypass mechanisms. 8. The junction box of claim 7 , wherein the additional bypass mechanism is electrically coupled between a first bus bar of the plurality of bus bars and a last bus bar of the plurality of bus bars. 9. The junction box of claim 7 , wherein the additional bypass mechanism includes a diode. 10. The junction box of claim 7 , wherein the additional bypass mechanism is a controlled switch. 11. The junction box of claim 7 , further comprising an additional bus bar, wherein the additional bypass mechanism is coupled between a bus bar of the plurality of bus bars and the additional bus bar. 12. The junction box of claim 7 , wherein the additional bypass mechanism is coupled between two bus bars of the plurality of bus bars via a conductive rod extending from the additional bypass mechanism to at least one of two bus bars of the plurality of bus bars. 13. The junction box of claim 1 , wherein the at least one bypass mechanism comprises a plurality of bypass mechanisms, the junction box further comprising an additional bypass mechanism mounted on the cover, wherein, when the cover is mounted over the base, the additional bypass mechanism is disposed in parallel to two or more bypass mechanisms of the plurality of bypass mechanisms. 14. The junction box of claim 1 , wherein the power device is configured to convert DC power having a first voltage generated by a power generator to AC power or DC power having a second voltage. 15. The junction box of claim 1 , wherein the cover comprises a communication device communicatively coupled to one or more controllers configured to control at least one component in the junction box. 16. The cover of claim 1 further comprising a section comprising a material which withstands heat dissipated from the at least one bypass mechanism. 17. A method comprising: coupling a bypass mechanism between two bus bars, the two bus bars and the bypass mechanism being comprised in a base of a junction box, the junction box further comprising walls which function as heat sinks; and coupling a cover and a base, wherein at least one of the cover and the base comprises a heat dissipation mechanism; wherein the heat dissipation mechanism is in contact with a power device when the cover is mounted over the base, and wherein at least one of the two bus bars includes a first heat spreading part designed to conduct heat in a first direction and a second heat spreading part designed to conduct heat in a second direction. 18. The method of claim 17 , wherein at least one of the bus bars is designed to conduct heat in a direction of the base and in a direction of the cover. 19. The method of claim 17 , further comprising converting, using the power device, DC power having a first voltage generated by a power generator to AC power or DC power having a second voltage.