Reverse osmosis water-on-water control valve

What is claimed is: 1. A filtration system comprising: a water-on-water storage tank comprising a squeeze side and a product side separated by a membrane; a filter module in fluid communication with the water-on-water storage tank, a feed source, a product outlet, and a drain outlet; a feed line connecting the feed source to a feed inlet of the filter module; a product line connecting a filtrate outlet of the filter module to the product side of the storage tank and the product outlet; and a drain line connecting a reject outlet of the filter module to the squeeze side of the storage tank and the drain outlet of the system; and a shuttle valve that regulates the flow from the feed source, wherein pressure in the product line determines the state of the valve; wherein the shuttle valve comprises a piston body having a first end connected to a spring, a second end having a piston face, and a plurality of sections, a first group of sections each independently being effective to block flow from or to one or more of the following: a valve feed inlet port, a valve feed outlet port, a drain port, a reject port, and a tank squeeze port depending on the state of the valve, and a second group of sections comprising linear grating or spiral grating each being effective to permit flow from or to one or more of the following: the valve feed inlet port, the valve feed outlet port, the drain port, the reject port, and the tank squeeze port depending on the state of the valve. 2. The filtration system of claim 1 , wherein the shuttle valve has at least three states depending on the product line pressure on the piston face, wherein: the first state enables flow from the feed source to the filter module and from the reject outlet of the filter module to the squeeze side of the storage tank when there is flow through the product outlet, the second state enables flow from the feed source to the filter module and from the squeeze side of the storage tank to the drain outlet of the system when there is not flow through the product outlet and the product side is not full, and the third state blocks flow from the feed source into the filtration system when the product side is full. 3. The filtration system of claim 1 , wherein the filter module comprises a reverse osmosis filter. 4. The filtration system of claim 3 , wherein the filter module comprises one or more pre-filters upstream of the reverse osmosis filter. 5. The filtration system of claim 3 , wherein the filter module comprises a post-filter downstream from the product side of the storage tank. 6. The filtration system of claim 1 , further comprising a check valve downstream from a filtrate outlet of the filter module that prevents fluid flow into the filtrate outlet of the filter module. 7. The filtration system of claim 2 , further comprising a flow control regulator that regulates flow from the reject outlet of the filter module to the drain outlet of the system when the valve is in the first state. 8. The filtration system of claim 1 wherein an end portion of the shuttle valve is in communication with a pressure downstream of the product side. 9. The filtration system of claim 2 , further comprising a check valve downstream from the product side and upstream of the valve or the combination of valves to maintain a hold pressure during the third state. 10. A reverse osmosis water-on-water valve comprising: a valve feed inlet port, a valve feed outlet port, a drain port, a reject port, and a tank squeeze port, wherein the valve has at least three states, wherein: in the first state, a first fluid path is defined by the valve feed inlet port that is in fluid communication with the valve feed outlet port, and a second fluid path is defined by the reject port that is in fluid communication with the tank squeeze port; in the second state, a third fluid path is defined by the valve feed inlet port that is in fluid communication with the valve feed outlet port, and a fourth fluid path is defined by the tank squeeze port that is in fluid communication with the drain port; and in the third state, the valve feed inlet port is not in fluid communication with the valve feed outlet port; wherein the valve is a shuttle valve comprising a piston body in a housing, the piston body having a first end portion connected to a spring; and wherein the piston body comprises a plurality of sections, a first group of sections each independently having a solid surface effective to block flow from or to one or more of the following: the tank squeeze port depending on the state of the valve, and a second group of sections each independently having a plurality of channels comprising linear grating or spiral grating to define the plurality of channels effective to permit flow from or to one or more of the following: the valve feed inlet port, the valve feed outlet port, the drain port, the reject port, and the tank squeeze port depending on the state of the valve. 11. The valve of claim 10 , wherein pressure on a second end portion of the piston body determines whether the valve is in the first, second, or third state. 12. The valve of claim 11 , wherein the piston body further comprises a piston face at the second end portion of the piston body, wherein a diameter of the piston face is greater than a maximum diameter of the piston body. 13. The valve of claim 10 , wherein the piston body further comprises a flow slot to allow fluid communication between the valve feed inlet port and the valve feed outlet port as the valve moves from the third state to the first state. 14. The valve of claim 10 , further comprising a vent through the housing to allow air to be vented as the piston body moves between states. 15. The valve of claim 10 , further comprising a plurality of sealing devices, which during the first state, are effective to separate the first fluid path from the second fluid path, and during the second state, are effective to separate the third fluid path from the fourth fluid path. 16. The valve of claim 10 , wherein the housing comprises a chamber in fluid communication with the second end portion of the piston body, wherein changes in pressure in the chamber cause the piston to move. 17. The valve of claim 16 , wherein the chamber comprises therein an inlet check valve and an outlet check valve, wherein the inlet check valve has a cracking pressure greater than a cracking pressure of the outlet check valve. 18. The valve of claim 10 , wherein the piston body has a diameter that is substantially the same along its length. 19. A filtration system comprising: a water-on-water storage tank comprising a squeeze side and a product side separated by a membrane; a filter module connected to a feed source by a feed line, to a product outlet by a product line, and to a drain outlet by a drain line; and the valve of claim 10 . 20. A filtration system comprising: a water-on-water storage tank comprising a squeeze side and a product side separated by a membrane; a filter module in fluid communication with the water-on-water storage tank, a feed source, a product outlet, and a drain outlet; a feed line connecting the feed source to a feed inlet of the filter module; a product line connecting a filtrate outlet of the filter module to the product side of the storage tank and the product outlet; and a drain line connecting a reject outlet of the filter module to the squeeze side of the storage tank and the drain outlet of the system; and a shuttle valve comprising a piston body having a fir