System and method for preventing absorbent crystallization in a continuously operating solar-powered absorption cooling system with hybrid storage

The invention claimed is: 1. An absorption cooling system, comprising: a plurality of solar collectors configured to obtain energy and transfer that energy as heat to a heating fluid; a generator comprising a dilute absorbent-refrigerant solution comprising an absorbent dissolved in a first amount of a refrigerant, wherein the generator is configured to receive the heating fluid from the solar collectors and release a vapor refrigerant from the dilute absorbent-refrigerant solution; a condenser configured to receive and condense the vapor refrigerant from the generator to form a liquid refrigerant; an evaporator configured to receive the liquid refrigerant from the condenser and provide refrigerant and a cooling fluid, wherein the cooling fluid cools at least one load; an absorber configured to receive the refrigerant from the evaporator and a concentrated absorbent-refrigerant solution comprising the absorbent dissolved in a second amount of the refrigerant from the generator to reform the dilute absorbent-refrigerant solution; a heat exchanger located between the generator and the absorber, wherein heat is exchanged between the concentrated absorbent-refrigerant solution flowing from the generator to the absorber and the dilute absorbent-refrigerant solution flowing from the absorber to the generator; a first storage tank located downstream of the solar collectors and upstream of the generator, which is configured to store the heating fluid; a second storage tank located downstream of the condenser and upstream of the evaporator, which is configured to store the liquid refrigerant; a third storage tank located downstream of the evaporator, which is configured to store the cooling fluid; a first temperature control valve located between the solar collectors and the first storage tank having an open and a closed mode; a second temperature control valve located between the first storage tank and the generator having an open and a closed mode; and a plurality of additional valves; wherein the solar collectors, the first storage tank, the generator, the condenser, the second storage tank, the evaporator, the third storage tank, the absorber, and the heat exchanger are fluidly connected to one another and the generator and first storage tank are connected in parallel to the solar collectors; wherein the first amount of the refrigerant is greater than the second amount of the refrigerant; and wherein the first temperature control valve and the second temperature control valve are configured to regulate a flow of the heating fluid into the generator by automatically toggling between the open mode or the closed mode in response to a controller signal indicating a presence or an absence of a set point of a solid absorbent content in the dilute absorbent-refrigerant solution of the generator. 2. The absorption cooling system of claim 1 , wherein the absorbent is lithium bromide (LiBr) and the refrigerant is water. 3. The absorption cooling system of claim 1 , wherein the first temperature control valve, the second temperature control valve, and/or the plurality of additional valves are configured to regulate the consumption of energy obtained by the solar collectors to maintain continuous cooling of at least one load during times of low solar heat input and/or nighttime operation of the absorption cooling system. 4. The absorption cooling system of claim 1 , wherein a coefficient of performance for the absorption cooling system during times of low solar heat input and/or nighttime operation is greater than or equal to a coefficient of performance for the absorption cooling system during times of standard solar heat input and/or daytime operation. 5. The absorption cooling system of claim 1 , wherein the heating fluid flows from the solar collectors to the generator and does not flow into or out of the first storage tank when the first temperature control valve is in the closed mode and the second temperature control valve is in the closed mode; the heating fluid flows from the solar collectors to the first storage tank and does not flow into the generator or out of the first storage tank when the first temperature control valve is in the open mode and the second temperature control valve is in the closed mode; and the heating fluid flows from the first storage tank to the generator and from the solar collectors to the generator and does not flow into the first storage tank when the first temperature control valve is in the closed mode and the second temperature control valve is in the open mode. 6. The absorption cooling system of claim 5 , wherein the solid absorbent content in the dilute absorbent-refrigerant solution of the generator is present and the controller signal is an amount of precipitation of the absorbent in the dilute absorbent-refrigerant solution of the generator. 7. The absorption cooling system of claim 5 , wherein the controller signal is a mass fraction of the absorbent relative to the total weight of the dilute absorbent-refrigerant solution of the generator. 8. The absorption cooling system of claim 7 , wherein the the first temperature control valve is in the closed mode and the second temperature control valve is in the open mode when the mass fraction of the absorbent relative to the total weight of the dilute absorbent-refrigerant solution of the generator is less than or equal to 63 wt %; the first temperature control valve is in the closed mode and the second temperature control valve is in the closed mode when the mass fraction of the absorbent relative to the total weight of the dilute absorbent-refrigerant solution of the generator is greater than 63 wt % and less than 73 wt %; the first temperature control valve is in the open mode and the second temperature control valve is in the closed mode when the mass fraction of the absorbent relative to the total weight of the dilute absorbent-refrigerant solution of the generator is greater than or equal to 73 wt %. 9. The absorption cooling system of claim 5 , wherein the controller signal is a temperature of the heating fluid entering the generator. 10. The absorption cooling system of claim 9 , wherein the first temperature control valve is in the closed mode and the second temperature control valve is in the open mode when the temperature of the heating fluid entering the generator is less than or equal to 100° C.; the first temperature control valve is in the closed mode and the second temperature control valve is in the closed mode when the temperature of the heating fluid entering the generator is greater than 100° C. and less than 109° C.; and the first temperature control valve is in the open mode and the second temperature control valve is in the closed mode when the temperature of the heating fluid entering the generator is greater than or equal to 109° C. 11. The absorption cooling system of claim 1 , wherein the first temperature control valve and the second temperature control valve cannot be in the open mode at the same time. 12. The absorption cooling system of claim 1 , wherein the operating temperature in the generator is less than 115° C. 13. The absorption cooling system of claim 1 , wherein the first storage tank is further configured to provide heating fluid to an attached building water heater. 14. The absorption cooling system of claim 1 , wherein one or more of the plurality of additional valves are open during times of standard solar heat input and/or daytime operation of the absorption cooling system. 15. The absorption cooling system of claim 1 , wherein the third storage tank is further configured to