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A light energy conversion (LEC) system includes a fluid circuit having a working fluid flowing therethrough and a plurality of light concentrating (LC) modules for converting light energy into electrical energy and for transforming the light energy into thermal energy. The LC modules including a fir

A light energy conversion (LEC) system includes a fluid circuit having a working fluid flowing therethrough and a plurality of light concentrating (LC) modules for converting light energy into electrical energy and for transforming the light energy into thermal energy. The LC modules including a first LC module coupled in series with a second LC module along the fluid circuit. The working fluid absorbs thermal energy while flowing through the first and second LC modules. At least the first LC module includes a light concentrating optical element that is configured to direct light energy toward a focal region and a receiver held at the focal region. The receiver includes a housing having a chamber that holds an energy conversion member. The energy conversion member transforms light energy received from the optical element into electrical and thermal energy.

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1. A light energy conversion (LEC) system for generating electrical and thermal energy, the system comprising: a fluid circuit including upstream and downstream fluidic ports, the fluid circuit configured to allow a working fluid to flow therethrough;a plurality of point-focus primary optical elemen

1. A light energy conversion (LEC) system for generating electrical and thermal energy, the system comprising: a fluid circuit including upstream and downstream fluidic ports, the fluid circuit configured to allow a working fluid to flow therethrough;a plurality of point-focus primary optical elements configured to concentrate light energy toward corresponding point-focal regions; anda plurality of receiver units for converting the concentrated light energy into electrical and thermal energy, wherein the plurality of receiver units include first and second receiver units fluidicly coupled in series along the fluid circuit such that the working fluid progressively absorbs thermal energy while flowing through the first and second receiver units, an amount of thermal energy in the working fluid exiting the second receiver unit being greater than an amount of thermal energy in the working fluid exiting the first receiver unit;wherein the first receiver unit includes an energy conversion member and a secondary optical element having a fixed position with respect to the energy conversion member, the first receiver unit also including inlet and outlet fluidic ports, the inlet and upstream fluidic ports forming a sealed engagement through an interference fit and the outlet and downstream fluidic ports forming a sealed engagement through an interference fit, wherein the first receiver unit is removably coupled to the fluid circuit, the first receiver unit receiving light energy from one of the primary optical elements and being movable with respect to said primary optical element when the first receiver unit is removed from the fluid circuit; wherein the fluid circuit includes a unit holder having a body with an open end, the inlet and outlet fluidic ports of the first receiver unit forming respective interference fits with the upstream and downstream fluidic ports when the first receiver unit is advanced in an axial direction into the open end of the body and plugged into the unit holder. 2. The LEC system in accordance with claim 1 wherein the sealed engagements are readily separable to remove the first receiver unit from the fluid circuit. 3. The LEC system in accordance with claim 1 wherein the first receiver unit is located proximate to or at the point-focal region of one of the primary optical elements, the first receiver unit being separate from said one of the primary optical elements. 4. The LEC system in accordance with claim 1 further comprising an array of light concentrator (LC) modules that includes the plurality of receiver units and the plurality of primary optical elements, the array of LC modules being supported by a rotatable support, the first and second receiver units being separately removably coupled to the fluid circuit such that the first and second receiver units are capable of being removed one at a time. 5. The LEC system in accordance with claim 1 wherein the secondary optical element receives the concentrated light energy and directs the concentrated light energy toward the energy conversion member. 6. The LEC system in accordance with claim 1 wherein the secondary optical element receives some or all of the concentrated light energy and directs the concentrated light energy toward the energy conversion member. 7. The LEC system in accordance with claim 1, wherein the energy conversion members of the first and second receiver units include respective photovoltaic cells, the cells of the first and second receiver units having different nominal current outputs at standard test conditions. 8. The LEC system in accordance with claim 1, wherein the first receiver unit has a higher nominal current output than the second receiver unit, the first receiver unit being located upstream from the second receiver unit. 9. The LEC system in accordance with claim 1 wherein the energy conversion member of the first receiver unit includes a photovoltaic (PV) cell for generating electrical energy. 10. The LEC system in accordance with claim 9 wherein the working fluid absorbs thermal energy generated around the PV cell. 11. The LEC system in accordance with claim 1 wherein the first receiver unit is a first type of receiver unit and the second receiver unit is a different second type of receiver unit, the second receiver unit converting the light energy into only thermal energy. 12. The LEC system in accordance with claim 1 wherein the first receiver unit is a first type of receiver unit and the second receiver unit is a second type of receiver unit, the first and second types of receiver units being different such that the first and second types of receiver units have different energy outputs at standard test conditions. 13. The LEC system in accordance with claim 12 wherein the first receiver unit increases the thermal energy in the working fluid by a first amount of thermal energy and the second receiver unit increases the thermal energy in the working fluid by a second amount of thermal energy, wherein the second amount of thermal energy is greater than the first amount. 14. The LEC system in accordance with claim 1 wherein the primary optical elements and the first and second receiver units are coupled to a mounting structure for aligning with a light source. 15. The LEC system in accordance with claim 1 wherein the second receiver unit is removably coupled to the LEC system, the first and second receiver units being separate receiver units such that the first and second receiver units are capable of being removed one at a time. 16. The LEC system in accordance with claim 1 wherein an entirety of the working fluid exiting the first receiver unit flows through the second receiver unit. 17. The LEC system in accordance with claim 1 wherein the first and second receiver units are of a common type such that the first and second receiver units are structurally similar and have a substantially common energy output. 18. A method of manufacturing a light energy conversion (LEC) system for generating electrical and thermal energy, the method comprising: providing a plurality of point-focus primary optical elements that are configured to concentrate light energy toward corresponding point-focal regions;coupling a first receiver unit to a fluid circuit having upstream and downstream fluidic ports, the first receiver unit including an energy conversion member and a secondary optical element having a fixed position with respect to the energy conversion member, the first receiver unit also including inlet and outlet fluidic ports, the inlet and upstream fluidic ports forming a sealed engagement through an interference fit and the outlet and downstream fluidic ports forming a sealed engagement through an interference fit, the energy conversion member configured to transform the light energy into electrical and thermal energy, wherein the first receiver unit is removably coupled to the fluid circuit, the first receiver unit receiving light energy from one of the primary optical elements and being movable with respect to said primary optical element when the first receiver unit is removed from the fluid circuit; wherein the fluid circuit includes a unit holder having a body with an open end, the inlet and outlet fluidic ports of the first receiver unit forming respective interference fits with the upstream and downstream fluidic ports when the first receiver unit is advanced in an axial direction into the open end of the body and plugged into the unit holder;coupling a second receiver unit to the fluid circuit in series with the first receiver unit, wherein the working fluid is configured to progressively absorb thermal energy while flowing through the first and second receiver units, an amount of thermal energy in the working fluid exiting the second receiver unit being greater than an amount of thermal energy in the working fluid exiting the first receiver unit. 19. The method in accordance with claim 18 further comprising replacing one of the first or second receiver units with a different type of receiver unit, the different type of receiver unit manufactured having a different energy output than the replaced receiver unit. 20. The method in accordance with claim 18 wherein the first receiver unit increases the thermal energy in the working fluid by a first amount of thermal energy and the second receiver unit increases the thermal energy in the working fluid by a second amount of thermal energy, wherein the second amount of thermal energy is greater than the first amount. 21. The method in accordance with claim 18 wherein the second receiver unit is removably coupled to the fluid circuit, the first and second receiver units being separate receiver units such that the first and second receiver units are capable of being removed one at a time. 22. The method in accordance with claim 18 wherein the first receiver unit is a first type of receiver unit and the second receiver unit is a second type of receiver unit, the first and second types of receiver units being different such that the first and second types of receiver units have different energy outputs at standard test conditions. 23. The method in accordance with claim 22 wherein the second receiver unit contains an energy conversion member that converts the light energy into only thermal energy. 24. The method in accordance with claim 18 wherein the energy conversion member of the first receiver unit includes a photovoltaic (PV) cell for generating electrical energy. 25. The method in accordance with claim 18 wherein coupling the first and second receiver units includes coupling the first and second receiver units to a mounting structure configured to align the first and second receiver units with a light source. 26. The method in accordance with claim 18 wherein an entirety of the working fluid exiting the first receiver unit flows through the second receiver unit. 27. The method in accordance with claim 18 wherein the first and second receiver units are of a common type such that the first and second receiver units are structurally similar and have a substantially common energy output.