Control valve and control valve system for controlling solids flow, methods of manufacture thereof and articles comprising the same

What is claimed is: 1. A solids flow control valve comprising: a standpipe; a shoe; a transport pipe, wherein the standpipe is in operative communication with the shoe and lies upstream of the shoe, the standpipe includes a first end and a second end, the first end is in contact with a source that contains disposable solids, the second end is in fluid contact with the shoe, and the shoe being operative to restrict the flow of the disposable solids; the transport pipe being disposed downstream of the shoe to receive and transport the solids from the shoe; and a housing that is in a protective relationship with the shoe and surrounds the shoe, and the shoe includes a heel, a base and a toe, wherein the heel, the base and the toe each contact one another, with the toe being inclined to the base at an internal angle that is within a range of 105 to 135 degrees, and the toe has substantially the same vertical footprint as the heel, wherein the shoe includes at least two ports for admitting a pressurized fluid, at least one of the ports is located at the heel, while at least one of the ports is located at the base of the shoe, the port at the base of the shoe contains a porous sintered frit that is configured to allow low pressurized air to enter into the shoe, and the port at the heel of the shoe contains a sintered frit that is configured to allow pressurized air to enter into the shoe, and wherein the port at the base of the shoe is positioned substantially directly beneath the standpipe and is configured to direct the low pressurized air into the shoe in a direction substantially opposite an inlet flow direction of the disposable solids from the standpipe into the shoe. 2. The solids flow control valve of claim 1 , wherein the solids flow control valve communicates with a heat exchanger and lies downstream of the heat exchanger. 3. The solids flow control valve of claim 1 , wherein the solids flow control valve communicates with a combustion chamber and lies upstream of the combustion chamber. 4. The solids flow control valve of claim 1 , wherein the standpipe is inclined to a vertical direction. 5. The solids flow control valve of claim 1 , wherein the housing contacts the shoe and the transport pipe and provides a fluid communication pathway between the shoe and the transport pipe. 6. The solids flow control valve of claim 1 , wherein pressurized air having a pressure of about 0.08 to about 0.23 kilograms per square centimeter is intermittently introduced into the port located at the heel of the shoe. 7. The solids flow control valve of claim 6 , wherein the pressurized air is admitted into the shoe intermittently for solids flow rate control, and the pressurized air is admitted for a period of about 3 to about 10 seconds and then shut off for a period of about 5 to about 30 seconds. 8. The solids flow control valve of claim 1 , wherein the transport pipe is in communication with a combustion chamber or a receiving hopper. 9. The solids flow control valve of claim 1 , wherein the solids include ash derived from the combustion of a carbonaceous fuel. 10. The solids flow control valve of claim 1 , wherein the transport pipe is horizontal or is inclined with respect to a vertical, and the solids flow control valve contains no parts that move relative to other parts of the valve. 11. A solids flow control system comprising a plurality of solids control valves of claim 1 . 12. The solids flow control system of claim 11 , wherein the system includes 1 to 50 valves. 13. The solids flow control system of claim 11 , wherein the system includes 16 solids control valves. 14. The solids flow control system of claim 11 , wherein a plurality of solids control valves are in communication with a single transport pipe. 15. The solids flow control system of claim 14 , wherein the system includes a plurality of transport pipes, and each transport pipe is in communication with the plurality of solids control valves. 16. An active grid solids distributor comprising: a controller including a programmable logic device that is in electrical communication with a plurality of solids flow control valves; each solids flow control valve includes: a standpipe; a shoe that includes a heel, a base and a toe, wherein the heel, the base and the toe each contact one another, with the toe being inclined to the base at an internal angle within a range of 105 to 135 degrees, and the toe has substantially the same vertical footprint as the heel; wherein the shoe includes at least two ports for admitting a pressurized fluid, at least one of the ports is located at the heel, while at least one of the ports is located at the base of the shoe, the port at the base of the shoe contains a porous sintered frit that is configured to allow low pressurized air to enter into the shoe, and the port at the heel of the shoe contains a sintered frit that is configured to allow pressurized air to enter into the shoe, wherein the port at the base of the shoe is positioned substantially directly beneath the standpipe and is configured to direct the low pressurized air into the shoe in a direction substantially opposite an inlet flow direction of disposable solids from the standpipe into the shoe; a transport pipe, wherein the standpipe is in operative communication with the shoe and lies upstream of the shoe, the standpipe includes a first end and a second end, the first end is in contact with a source that contains the disposable solids, the second end is in fluid contact with the shoe, and the shoe being operative to restrict the flow of the disposable solids; a housing that is in a protective relationship with the shoe and surrounds the shoe, the housing extending substantially vertically from the shoe between the shoe and the transport pipe, and in a direction substantially parallel to the standpipe, the housing being configured to receive the disposable solids from the toe of the shoe and to direct the disposable solids from the shoe to the transport pipe; and the transport pipe being disposed downstream of the shoe to receive and transport the solids from the shoe. 17. The active grid solids distributor of claim 16 , wherein at least one valve of the plurality of valves is first actuated prior to actuating another valve, and the actuation includes turning on pressurized air in at least one valve for a period of time before turning it off. 18. The active grid solids distributor of claim 16 , wherein the active grid is actuated by turning on the air for at least one valve intermittently for solids flow rate control that includes air admission for a time period of about 3 to about 15 seconds and turning it off for a time period of about 15 to about 50 seconds. 19. The active grid solids distributor of claim 16 , wherein the transport pipe is horizontal or is inclined with respect to a vertical, and the solids flow control valve contains no parts that move relative to other parts of the valve. 20. A method comprising: discharging solids from a heat exchanger through a plurality of solids flow control valves; each solids flow control valve includes: a standpipe; a shoe that includes a heel, a base and a toe, wherein the heel, the base and the toe each contact one another, with the toe being inclined to the base at an internal angle within a range of 105 to 135 degrees, and the toe has substantially the same vertical footprint as the heel; wherein the shoe includes at least two ports for admitting a pressurized fluid, at least one of the ports is located at the h