Pressure compensated Venturi dispensing system

What is claimed is: 1. A dispensing system comprising: a flush manifold including a plurality of intake ports; an eductor including an inlet port that is fluidically coupled to a source of a diluent, a pickup port fluidically coupled to a source of a chemical product, a discharge port configured to discharge a chemical solution, and a venturi fluidically coupled to each of the inlet port, the pickup port, and the discharge port, the venturi being configured to draw the chemical product into the eductor in response to the diluent being coupled to the inlet port such that the chemical product is mixed with the diluent to form the chemical solution; and a check valve fluidically coupling an outlet of the discharge port of the eductor to an inlet of one of the intake ports of the flush manifold. 2. The dispensing system of claim 1 wherein the check valve comprises: an upstream chamber; a downstream chamber fluidically coupled to the upstream chamber by an opening; and a closing member configured to fluidically isolate the downstream chamber from the upstream chamber by covering the opening absent a flow of fluid from the upstream chamber to the downstream chamber. 3. The dispensing system of claim 2 wherein the check valve further comprises: an elastic member that urges the closing member into contact with the opening absent the flow of fluid from the upstream chamber to the downstream chamber. 4. The dispensing system of claim 2 wherein the opening is defined by a valve seat. 5. The dispensing system of claim 1 wherein the check valve provides a dynamic flood ring that has a first resistance to the flow of fluid through the eductor in a first state, and a second resistance to the flow of fluid higher than the first resistance in a second state. 6. The dispensing system of claim 5 wherein the first state is an open state and the second state is a closed state. 7. The dispensing system of claim 5 wherein the check valve maintains the eductor in a flooded state when the dynamic flood ring is in the second state. 8. The dispensing system of claim 1 , wherein the inlet port of the eductor is fluidically coupled to the source of the diluent through a remotely operated valve. 9. A method of assembling a dispensing system, the method comprising: obtaining an eductor including an inlet port, a pickup port, and a discharge port; coupling the inlet port to a source of a diluent; coupling the pickup port to a source of a chemical product; coupling the discharge port to an upstream chamber of a check valve; and coupling a downstream chamber of the check valve to one intake port among a plurality of intake ports of a flush manifold, and wherein the eductor is configured to draw the chemical product into the eductor in response to the diluent being flowed through the inlet port such that the chemical product is mixed with the diluent to form a chemical solution. 10. The method of claim 9 , wherein the source of the diluent is fluidically coupled to an inlet manifold, wherein the eductor is a first eductor, wherein coupling the inlet port of the eductor to the diluent comprises coupling the inlet port to a first outlet of the inlet manifold, and wherein the method further comprises: obtaining a second eductor comprising an inlet port, a pickup port, and a discharge port; coupling the inlet port of the second eductor to a second outlet of the inlet manifold; and coupling the discharge port of the second eductor to a different intake port of the plurality of intake ports of the flush manifold. 11. The method of claim 10 , wherein the second eductor is configured as a flush eductor. 12. The method of claim 10 , wherein the second eductor is coupled to an intake port of the flush manifold more upstream than the intake port to which the first eductor is coupled. 13. The method of claim 9 , wherein coupling the inlet port of the eductor to the diluent comprises coupling the inlet port to a remotely operated valve that is in fluid communication with the source of the diluent. 14. The method of claim 9 , wherein coupling the pickup port to a source of a chemical product comprises: coupling the source of the chemical product to an inlet of a second check valve; and coupling an outlet of the second check valve to the pickup port. 15. A dispensing system comprising: an inlet manifold comprising an inlet port and a plurality of outlet ports wherein the inlet port of the inlet manifold is fluidically coupled to a source of a diluent; a plurality of eductors, each eductor comprising an inlet port, a pickup port, a discharge port, and a venturi fluidically coupled to each of the inlet port, the pickup port, and the discharge port, wherein the inlet port of each eductor is fluidically coupled to one of the outlet ports of the inlet manifold, the pickup port of each eductor is fluidically coupled to a feed line from one of a plurality of sources of chemical products, and the venturi of each eductor being configured to draw the chemical product into the eductor in response to a flow of the diluent from the inlet manifold to the inlet port such that the chemical product is mixed with the diluent to form a chemical solution; a flush manifold comprising a plurality of intake ports; and at least one check valve fluidically coupling the discharge port of at least one eductor of the plurality of eductors to one of the intake ports of the flush manifold. 16. The dispensing system of claim 15 , wherein at least one eductor of the plurality of eductors is configured as a flush eductor wherein the discharge port of the flush eductor is fluidically coupled directly to one of the intake ports of the flush manifold. 17. The dispensing system of claim 16 , wherein the flush eductor is fluidically coupled to the most upstream intake port of the flush manifold. 18. The dispensing system of claim 15 , wherein each eductor is fluidically coupled to a different source of chemical products. 19. The dispensing system of claim 16 further comprising: a plurality of selector valves, wherein each selector valve is fluidically coupled between an outlet port of the intake manifold and an inlet port of one of the eductors of the plurality of eductors; a pressure sensor arranged to measure a pressure of the diluent; and a controller configured to control operation of the selector valves based on one or more measurement signals received from the pressure sensor. 20. The dispensing system of claim 19 , wherein the controller is further configured to: determine a duration of a flush stage based at least in part on one or more measurement signals from the pressure sensor; and open a particular one of the selector valves fluidically coupled to the inlet port of the flush eductor for the duration of the flush stage. 21. The dispensing system of claim 16 , wherein other eductors of the plurality of eductors are configured as dispensing eductors, wherein a check valve is coupled between the discharge port of each dispensing eductor and one of the intake ports of the flush manifold.