Concentrated solar power solids-based system

The invention claimed is: 1. A concentrated solar power solids-based system, comprising: a solar receiver; a heated solids storage tank downstream of and connected to the solar receiver; a fluidized bed heat exchanger downstream of the heated solids storage tank; means for feeding heated solid particles from the heated solids storage tank to the fluidized bed heat exchanger; means for transporting solid particles from the fluidized bed heat exchanger to a cold solids storage tank that is located downstream of the fluidized bed heat exchanger; and means for transporting and metering cold solid particles from the cold solids storage tank to the solar receiver; wherein the fluidized bed heat exchanger includes at least a first fluidized bed, a first heating surface located in the first fluidized bed, a second fluidized bed, and a second heating surface located in the second fluidized bed; and wherein the system is further defined by at least one of the following in order to reduce the margin between average and maximum upset temperatures in each fluidized bed: (i) fluidizing medium flows to the first fluidized bed and the second fluidized bed can be independently controlled; and (ii) the first fluidized bed and the second fluidized bed are located in parallel particle flow streams within the fluidized bed heat exchanger. 2. The solar power system of claim 1 , wherein the solar receiver includes a plurality of heating areas that can receive cold solid particles separately from the cold solids storage tank to the solar receiver. 3. The solar power system of claim 1 , wherein a freeboard height of each fluidized bed is not less than a transport disengaging height of each fluidized bed. 4. The solar power system of claim 1 , wherein the first heating surface and the second heating surface are part of one or more fluid transport conduits, and the fluid flowing through the one or more fluid transport conduits is independently selected from water, steam, a steam-water mixture, air, carbon dioxide, helium, and nitrogen. 5. The solar power system of claim 1 , wherein solid particles can travel through the solar receiver and through the heated solids storage tank to the fluidized bed heat exchanger by gravity. 6. The solar power system of claim 1 , wherein the means for feeding heated solid particles from the heated solids storage tank to the fluidized bed heat exchanger is non-mechanical. 7. A concentrated solar power solids-based system, comprising: a solar receiver; a heated solids storage tank downstream of and connected to the solar receiver; a fluidized bed heat exchanger downstream of the heated solids storage tank; means for feeding heated solid particles from the heated solids storage tank to the fluidized bed heat exchanger; means for transporting solid particles from the fluidized bed heat exchanger to a cold solids storage tank that is located downstream of the fluidized bed heat exchanger; and means for transporting and metering cold solid particles from the cold solids storage tank to the solar receiver; wherein the fluidized bed heat exchanger includes at least a first fluidized bed, a first heating surface located in the first fluidized bed, a second fluidized bed, and a second heating surface located in the second fluidized bed; and wherein the means for feeding heated solid particles from the heated solids storage tank to the fluidized bed heat exchanger includes a safety chamber, wherein solid particles can only pass through the safety chamber when in a fluidized state. 8. The solar power system of claim 1 , wherein the means for transporting solid particles from the fluidized bed heat exchanger to the cold solids storage tank is a mechanical carrier. 9. The solar power system of claim 1 , wherein the means for transporting solid particles from the fluidized bed heat exchanger to the cold solids storage tank comprises a pneumatic transport means that uses a gaseous carrier for lifting solid particles to the cold solids storage tank. 10. The solar power system of claim 9 , wherein the pneumatic transport means includes a separator located above the cold solids storage tank to separate the gaseous carrier from the solid particles, the solid particles traveling by gravity from the separator to the cold solids storage tank. 11. The solar power system of claim 1 , further comprising an intermediate storage tank downstream of the fluidized bed heat exchanger and upstream of the means for transporting solid particles from the fluidized bed heat exchanger to the cold solids storage tank. 12. The solar power system of claim 11 , wherein the solid particles are transported from the fluidized bed heat exchanger to the intermediate storage tank by gravity. 13. The solar power system of claim 1 , wherein the first heating surface and the second heating surface are part of one common fluid transport conduit, or wherein the first heating surface and the second heating surface are part of two different fluid transport conduits. 14. A method of heating a working fluid using solar energy, comprising: passing cold particles through a solar receiver by gravity to capture solar energy and obtain heated particles, the heated particles traveling by gravity into and through a heated solids storage tank; sending the heated particles from the heated solids storage tank to a fluidized bed heat exchanger; fluidizing the heated particles and sending the fluidized particles to at least a first fluidized bed and a second fluidized bed; transferring heat from the fluidized particles in the first fluidized bed to a working fluid on the opposite side of a first heating surface located in the first fluidized bed and obtaining cooled particles; transferring heat from the fluidized particles in the second fluidized bed to a working fluid on the opposite side of a second heating surface located in the second fluidized bed and obtaining cooled particles; and transporting the cooled particles to a cold solids storage tank downstream of the fluidized bed heat exchanger and connected to the solar receiver; wherein the method is further defined by at least one of the following in order to reduce the margin between average and maximum upset temperatures in each fluidized bed: (i) fluidizing medium flows to the first fluidized bed and the second fluidized bed are independently controlled; and (ii) the first fluidized bed and the second fluidized bed are located in parallel particle flow streams within the fluidized bed heat exchanger. 15. A method of heating a working fluid using solar energy, comprising: passing cold particles through a solar receiver by gravity to capture solar energy and obtain heated particles, the heated particles traveling by gravity into and through a heated solids storage tank; sending the heated particles from the heated solids storage tank to a fluidized bed heat exchanger; fluidizing the heated particles and sending the fluidized particles to at least a first fluidized bed and a second fluidized bed; transferring heat from the fluidized particles in the first fluidized bed to a working fluid on the opposite side of a first heating surface located in the first fluidized bed and obtaining cooled particles; transferring heat from the fluidized particles in the second fluidized bed to a working fluid on the opposite side of a second heating surface located in the second fluidized bed and obtaining cooled particles; and transporting the cooled particles to a cold solids storage tank downstream of the fluidized bed heat exchanger and connected to the solar receiver; and wherein the heated partic