System and method and apparatus for maintaining a pressure balance in a solids flow loop and for controlling the flow of solids therethrough

What is claimed is: 1. A system, comprising: a standpipe for receiving a flow of solids therethrough, the standpipe having at least one inlet configured to receive a gas for decreasing a solids-to-gas ratio of the flow; a sealpot having an inlet fluidly coupled to the standpipe and an outlet fluidly coupled to a riser, the sealpot being configured to fluidize the solids received from the standpipe and to transport the solids to the riser; and a drain device fluidly coupled to an outlet in the standpipe, the outlet being located upstream from the inlet of the sealpot; wherein the drain device includes a solids and gas separation device for receiving the gas from the standpipe, and a bypass conduit fluidly coupled at one end to the solids and gas separation device and at another end to the riser to facilitate the free flow of the excess gas between the riser and the standpipe, wherein the drain device is configured to remove excess gas from the flow of solids within the standpipe to increase the solids-to-gas ratio of the flow prior to the solids entering the sealpot. 2. The system of claim 1 , wherein: the outlet in the standpipe is located below the at least one inlet of the standpipe and above the inlet of the sealpot. 3. The system of claim 1 , wherein: the solids and gas separation device is generally conical in shape. 4. The system of claim 3 , wherein: a flow pathway defined by the solids and gas separation device is oriented at an angle of approximately 30 degrees relative to a flow direction of the solids within the standpipe. 5. The system of claim 1 , wherein: the system is part of a chemical reaction system. 6. The system of claim 1 , wherein: the sealpot includes a fluidizing bed configured to fluidize the solids within the sealpot and a transport bed configured to transport the solids out of the sealpot and into the riser; wherein the bypass conduit is configured to transport excess gas in the standpipe and balance a pressure difference between the riser and the standpipe. 7. The system of claim 6 , wherein: the sealpot includes an orifice plate adjacent to the transport bed; wherein the orifice plate includes a plurality of apertures disposed at a height above the transport bed, the plurality of apertures allowing transport of fluidized solids and gas through the plurality of apertures of the orifice plate from the transport bed to riser. 8. The system of claim 1 , wherein: the drain device includes a control valve positioned within the outlet in the standpipe, the control valve being configured to regulate a flow of the gas out of the standpipe. 9. A system for pressure balancing and controlling the flow of solids within a solids flow loop of a chemical reaction system, comprising: a downcomer standpipe having an upper end, which receives solids of the power plant, a lower end, an inlet intermediate the upper end and the lower end and configured to receive a gas for passage into the flow of solids within the standpipe, and an outlet intermediate the inlet and the lower end of the standpipe; a sealpot having an inlet fluidly coupled to the lower end of the standpipe and an outlet fluidly coupled to a discharge passageway, the sealpot being configured to receive the solids from the lower end of the standpipe and to transport the solids to the discharge passageway; and a drain device fluidly coupled to the outlet in the standpipe and being configured to facilitate removal of the gas from the flow of solids within the standpipe, wherein the drain device includes a solids and gas separation device for receiving the gas from the standpipe, and a bypass conduit fluidly coupled at one end to the solids and gas separation device and at another end to the discharge passageway, the bypass conduit facilitating the free flow of excess gas between the discharge passageway and the standpipe while bypassing the sealpot. 10. The system of claim 9 , wherein: the sealpot includes a fluidizing bed configured to receive fluidizing gas to fluidize the solids within the sealpot and a transport bed configured to transport the fluidized solids to the discharge passageway. 11. The system of claim 9 , wherein: the solids and gas separation device is generally conical in shape. 12. The system of claim 11 , wherein: a flow pathway defined by the solids and gas separation device is oriented at an angle effective to separate solids and gas in the standpipe. 13. A method of pressure balancing and controlling the flow of solids within a solids flow loop, comprising the steps of: providing a supply of gas to a standpipe at an inlet to facilitate a flow of solids through the standpipe; removing at least a portion of the gas from the standpipe at an outlet positioned downstream from the inlet; and diverting the gas removed from the standpipe around the sealpot to a location within the flow loop downstream from the sealpot. 14. The method according to claim 13 , further comprising the step of: fluidly coupling the outlet of the standpipe to a riser of the flow loop, the riser being located downstream from the sealpot; wherein the fluid coupling between the outlet of the standpipe and the riser facilitates a free flow of gas between the riser and the standpipe while bypassing the sealpot. 15. The method according to claim 13 , further comprising the step of: connecting a conical solids and gas separation device to the outlet such that a flow pathway defined by the solids and gas separation device is oriented at an upward angle of approximately 30 degrees relative to a downward flow direction of the solids within the standpipe.