Fluid catalytic cracking process and apparatus for maximizing light olefin yield and other applications

What is claimed: 1. An integrated disengagement vessel comprising: a housing; a solids separation device disposed within the housing for separating a hydrocarbon stream comprising a hydrocarbon fraction, second particles, and first particles into a first stream, comprising the first particles and the hydrocarbon fraction, and a second stream, comprising the separated second particles, each of the first and second particles having a particle size distribution, an average particle size and an average density, the second particles having an average particle size and/or an average density greater than the first particles; one or more cyclones disposed within the housing for separating the first stream to recover a solids fraction, comprising the first particles, and a vapor fraction, comprising the hydrocarbon fraction; an internal vessel disposed within the housing for receiving the second stream comprising the separated second particles; an annular region between the housing and the internal vessel for receiving the solids fraction comprising the first particles; a vapor outlet for recovering the vapor fraction; and a first outlet for recovering the second stream from the internal vessel, and a second outlet for recovering the solids fraction from the annular region, wherein the outlets are configured to maintain the solids fraction and the second stream separate. 2. The system of claim 1 , further comprising a flow line for feeding the solids fraction from the annular region to a regenerator. 3. The system of claim 1 , further comprising: a fractionation system configured for receiving the vapor fraction and separating the hydrocarbon fraction therein into two or more hydrocarbon streams including a naphtha fraction; and a flow line for feeding the naphtha fraction to a riser reactor as a hydrocarbon feedstock. 4. An integrated disengagement vessel comprising: a solids separation device for separating a hydrocarbon stream comprising a hydrocarbon fraction, second particles, and first particles into a first stream, comprising the first particles and the hydrocarbon fraction, and a second stream, comprising the separated second particles, each of the first and second particles having a particle size distribution, an average particle size and an average density, the second particle having an average particle size and/or average density greater than the first particle; one or more cyclones for separating the first stream to recover a solids fraction, comprising the first particles, and a vapor fraction, comprising the hydrocarbon fraction; a vessel for receiving the second stream comprising the separated second particles; and a region around the vessel for receiving the solids fraction comprising the first particles; a flow line for feeding the solids fraction from the region to a regenerator; and a flow line for feeding the separated second particles, unregenerated, to a riser reactor. 5. The system of claim 4 , further comprising an outlet on the riser reactor for recovering the hydrocarbon stream. 6. The system of claim 5 , further comprising a flow line for feeding the hydrocarbon stream to the solids separation device. 7. The system of claim 4 , further comprising a flow line for feeding a regenerated first particles to the riser reactor.