Viscosity dependent valve system

What is claimed is: 1. A system for controlling flow of well fluids within a wellbore, comprising: a sand screen assembly deployable in the wellbore, the sand screen assembly comprising a base pipe, a sand screen disposed about the base pipe and deployable within the wellbore concurrently with the base pipe, and a flow control device comprising: a production circuit positioned in fluid communication with the sand screen and an interior of the base pipe via viscosity switches positioned within the production circuit and operable to control flow from the production circuit to the interior of the base pipe, the production circuit having arrays of fluid nozzles; and a metering circuit positioned in fluid communication with the sand screen and the interior of the base pipe via a check valve, the metering circuit positioned in parallel to the production circuit such that a first portion of the well fluids flow through the production circuit into the interior of the base pipe and a second portion of the well fluids flow through the metering circuit into the interior of the base pipe, the metering circuit having a filter, a viscosity pressure loss device, a metering orifice, and the check valve positioned sequentially and the metering circuit in pressure communication with the viscosity switches such that changes in viscosity of the well fluids flowing through the metering circuit opens or closes the viscosity switches, wherein the filter is located in an annular space between the sand screen and the base pipe. 2. The system as recited in claim 1 , wherein the arrays of fluid nozzles comprise a pair of arrays. 3. The system as recited in claim 1 , wherein the viscosity pressure loss device comprises a bead filled tube. 4. The system as recited in claim 1 , wherein the viscosity pressure loss device comprises a series of fluid passage restrictions. 5. The system as recited in claim 1 , wherein the viscosity switches are located within an outer housing and externally of the base pipe. 6. The system as recited in claim 1 , wherein the arrays of fluid nozzles and the viscosity switches utilize pressure differentials which close the viscosity switches in a presence of a gas flow. 7. The system as recited in claim 1 , wherein the arrays of fluid nozzles and the viscosity switches utilize pressure differentials which close the viscosity switches in a presence of a water flow. 8. The system as recited in claim 1 , wherein the viscosity switches each comprise a plug mounted on a diaphragm. 9. A system deployable in a wellbore, the system comprising: a well completion having a sand screen assembly that, when deployed in the wellbore, allows well fluids to flow from an exterior to an interior production flow passage during production of the well fluids, the sand screen assembly comprising: a base pipe through which the well fluids flow to the interior production flow passage; a sand screen deployable within the wellbore concurrently with the base pipe; and a flow control device having: a production circuit positioned in fluid communication with the sand screen and the interior production flow passage via viscosity switches positioned within the production circuit and operable to control flow from the production circuit to the interior production flow passage; and a metering circuit positioned in fluid communication with the sand screen and the interior production flow passage, the metering circuit positioned in parallel to the production circuit such that a first portion of the well fluids flow through the production circuit into the interior production flow passage and a second portion of the well fluids flow through the metering circuit into the interior production flow passage, the metering circuit in pressure communication with the viscosity switches such that changes in viscosity of the well fluids flowing through the metering circuit opens or closes the viscosity switches, wherein the metering circuit comprises a filter, a viscosity pressure loss device, and a metering orifice positioned sequentially, and wherein the filter is located in an annular space between the sand screen and the base pipe. 10. The system as recited in claim 9 , wherein the production circuit comprises arrays of fluid nozzles. 11. The system as recited in claim 10 , wherein the viscosity switches open or close depending on the viscosity of the well fluid flowing through the viscosity pressure loss device and the arrays of fluid nozzles. 12. The system as recited in claim 11 , wherein the arrays of fluid nozzles and the viscosity switches utilize pressure differentials which close viscosity switches in a presence of a gas flow. 13. The system as recited in claim 11 , wherein the arrays of fluid nozzles and the viscosity switches utilize pressure differentials which close viscosity switches in a presence of a water flow. 14. The system as recited in claim 10 , wherein the viscosity pressure loss device comprises a bead filled tube. 15. A method, comprising: placing a sand screen assembly comprising a base pipe, a sand screen, a flow control device, and viscosity switching valves in a well completion; then deploying the well completion in a wellbore, wherein the base pipe and sand screen are deployed concurrently in the wellbore; and then using the flow control device selectively allow well fluids into the base pipe, the method further comprising: constructing the flow control device with a production circuit positioned in fluid communication with the sand screen and an interior of the base pipe via the viscosity switching valves positioned within the production circuit and operable to control flow from the production circuit to the interior of the base pipe and a metering circuit positioned in fluid communication with the sand screen and the interior of the base pipe and further positioned in parallel to the production circuit such that a first portion of the well fluids flow through the production circuit into the interior of the base pipe and a second portion of the well fluids flow through the metering circuit into the interior of the base pipe, the metering circuit in pressure communication with the viscosity switching valves such that changes in viscosity of the well fluids flowing through the metering circuit opens or closes the viscosity switching valves; and forming the metering circuit with a filter, a viscosity pressure loss device, and a metering orifice positioned sequentially, wherein the filter is located in an annular space between the sand screen and the base pipe. 16. The method as recited in claim 15 , further comprising forming the production circuit with arrays of fluid nozzles working in cooperation with the viscosity switching valves.