Heat pipe augmented passive solar heating system

What is claimed is: 1. A heat pipe for transferring solar energy, comprising: a conduit for holding a working fluid, the conduit having: a first end comprising an evaporator positioned proximal to a solar absorber to receive solar energy, wherein when a working fluid is present in the first end the solar energy that is received from the solar absorber is transferred to the working fluid while the working fluid is in a liquid state and converts the working fluid to a gas state, and wherein the heat pipe is configured for the working fluid to travel in the conduit passively as a gas to a second end comprising a condenser, wherein the condenser receives the working fluid from the evaporator and is where while the working fluid is in the gas state is converted to the liquid state and wherein the heat pipe is configured for the working fluid to travel in the conduit passively as a liquid to the evaporator; an adiabatic section between the first end and the second end, the adiabatic section comprising a region of conduit formed from a non-metal thermal insulating material different from the material forming at least one of the conduit ends, the adiabatic section configured to resist heat transfer moving in the direction from the condenser to the evaporator; and further comprising a valve positioned between the first and second ends to limit heat transfer moving in the direction from the condenser to the evaporator when the valve is closed or partially closed compared to when the valve is opened. 2. The heat pipe of claim 1 , wherein the second end is configured to communicate with a storage tank that retains energy produced at the condenser. 3. The heat pipe of claim 1 , wherein the adiabatic section is formed from rubber and the condenser and evaporator are formed from a metal or metal alloy. 4. The heat pipe of claim 1 , wherein the valve is positioned in the adiabatic section. 5. The heat pipe of claim 1 , wherein the evaporator has a fin joined to the solar absorber. 6. A heat transfer system, comprising: a solar absorber that receives solar energy; a thermal storage tank; a plurality of heat pipes, wherein each heat pipe comprises: a conduit for holding a working fluid, the conduit having a first end comprising an evaporator that is proximal to the solar absorber where solar energy from the solar absorber is transferred, wherein when the working fluid is present in the first end, the solar energy that is received from the solar absorber is transferred to the working fluid while the working fluid is in a liquid state; a second end comprising a condenser that receives the working fluid from the evaporator and is where the working fluid is in a gas state, undergoes cooling to convert to a liquid state and wherein the heat pipe is configured for the working fluid to travel passively in the conduit as a liquid to the evaporator; and an adiabatic section between the first end and the second end, the adiabatic section comprising a region of conduit formed from a non-metal thermal insulating material that is different from the material forming at least one of the conduit ends, the adiabatic section configured to resist heat transfer moving in the direction from the condenser to the evaporator; wherein the movement of the working fluid in any of said heat pipes produces a temperature gradient between the first and second ends of the conduit and wherein at least one of the heat pipes further comprises a valve positioned between the first and second ends to limit heat transfer moving in the direction from the condenser to the evaporator when the valve is closed or partially closed compared to when the valve is opened. 7. The system of claim 6 , wherein at least one of the heat pipes further comprises a fin joined to the evaporator at the first end proximal to the solar absorber. 8. The system of claim 6 , wherein no mechanical pumping force is employed to transport the working fluid as it moves within the heat pipe. 9. The system of claim 6 , wherein the adiabatic section is formed from rubber and the condenser and evaporator are formed from a metal or metal alloy. 10. The system of claim 6 , further comprising insulation surrounding at least a portion of the conduit. 11. The system of claim 10 , wherein the insulation surrounds the entire adiabatic section. 12. The system of claim 6 , wherein the second end of at least one of the conduits is at an incline relative to the first end. 13. The system of claim 12 , wherein the incline is about 2-10 degrees. 14. The system of claim 6 , further comprising at least one lever operatively engaged with at least one of the conduits that adjusts an incline of one end of the conduit relative to the other end. 15. The system of claim 6 , wherein the second end of at least one of the heat pipes thermally communicates with the thermal storage tank to allow the thermal storage tank to receive and store energy from the condenser. 16. The system of claim 6 , wherein the valve is positioned in the adiabatic section. 17. The system of claim 6 , further comprising a cover proximal to the solar absorber. 18. The system of claim 6 , wherein at least one heat pipe is entirely positioned outside of, and not in thermal communication with, the thermal storage tank to allow energy from a gas to liquid phase conversion of the working fluid to be transferred directly to an ambient environment surrounding the second end. 19. A method for passive heating of a room of a building, comprising: forming a hole in an exterior wall of a building, the wall having a thickness and the hole sufficiently sized to accommodate the heat pipe of claim 1 ; arranging the heat pipe of claim 1 through the wall with the first end positioned on the exterior of the building, the second end on the interior of the building, and at least a portion of the heat pipe between the first and second ends within the thickness of the wall; providing a working fluid in a liquid state within the conduit of the heat pipe; positioning the first end of the heat pipe in thermal communication with a solar absorber that absorbs solar energy from the sun, wherein the working fluid proximal the first end evaporates and the gas phase of the working fluid transfers to the second end heat pipe where it condenses back to liquid at the condenser, such that the liquid phase of the working fluid transfers to the first end of the heat pipe; positioning a valve between the first and second ends of the heat pipe for limiting heat transfer between the respective ends when the valve is closed or partially closed. 20. The method of claim 19 , further comprising performing all steps of claim 19 for at least two heat pipes of claim 1 , wherein at least one but not all of the heat pipes is positioned in thermal communication with a thermal storage tank positioned in the room. 21. A method for passive cooling of a room of a building by transferring energy to the exterior of the building, comprising: configuring a heat pipe with a first end comprising a condenser, a second end comprising an evaporator, and a middle section between the two ends, wherein the heat pipe comprises a conduit for holding a working fluid and positioning a valve between the first and second ends of the heat pipe for limiting heat transfer between the respective ends when the valve is closed or partially closed; forming a hole in an exterior wall of a building, the wall having a thickness and the hole sufficiently sized to accommodate the heat pipe; arrangi