Methods and systems for making well-fined glass using submerged combustion

What is claimed is: 1. A system comprising: a submerged combustion melter (SCM) configured to form a turbulent molten mass of foamed glass by melting glass-forming materials therein, the SCM comprising a roof, a floor, a sidewall structure connecting the roof and floor, and a foamed glass outlet in the floor and/or the sidewall structure; a first flow channel defining a fining chamber fluidly connected to and downstream of the SCM, the first flow channel comprising at least a floor and a sidewall structure, the first flow channel comprising glass-contact refractory at least lining the floor and at least a portion of the first flow channel sidewall structure to a height sufficient to accommodate expansion of the molten mass of foamed glass as fining occurs during transit of the molten mass of foamed glass through the fining chamber, the fining separating the molten mass of foamed glass into an upper phase consisting essentially of glass foam and a lower phase consisting essentially of molten glass as the molten mass of foamed glass flows toward an end of the first flow channel distal from the SCM; a transition section defining a passage fluidly connected to the distal end of the first flow channel, the transition section comprising a floor and a cover, the floor and cover connected by a sidewall structure, and comprising an inlet end structure and an outlet end structure, the inlet end structure comprising at least one molten glass inlet aperture and the outlet end structure comprising at least one molten glass outlet aperture, wherein all of the inlet apertures are positioned lower than a phase boundary between the upper and lower phases in the first flow channel; wherein the floor of the transition section comprises at least one controllable aperture for flowing at least some of the molten glass by gravity therethrough upon a planned or unplanned condition. 2. The system of claim 1 wherein the passage comprises a source of heat and/or a heat sink for adjusting temperature of the molten glass as it passes through the passage. 3. The system of claim 1 comprising a second flow channel having at least a floor and a sidewall structure, the second flow channel defining a temperature homogenizing chamber, the second flow channel fluidly connected to the outlet end structure of the transition section for forming a temperature homogenized, well-fined molten glass by routing the phase consisting essentially of molten glass through the at least one outlet aperture of the outlet end structure of the transition section and into the temperature homogenizing chamber. 4. The system of claim 3 comprising one or more glass forming stations fluidly connected to a distal end of the second flow channel. 5. The system of claim 4 wherein the glass forming stations are selected from the group consisting of fiber forming spinnerets, fiberization stations, and non-glass fiber product forming stations. 6. The system of claim 4 wherein the outlet end structure of the transition section is configured to allow the molten glass to well up into an inlet end of the second flow channel. 7. The system of claim 3 wherein the first flow channel comprises a roof having a height h 1 above the cover of the transition section, and the second flow channel has a roof having a height h 2 above the cover of the transition section, wherein h 1 >h 2 . 8. The system of claim 1 wherein 100 percent of the inlet aperture is lower than the floor of the first flow channel. 9. The system of claim 1 comprising at least one component for heating the molten glass in the transition section to maintain the molten glass in the molten state. 10. The system of claim 1 comprising at least one component for cooling the molten glass as it passes through the transition section to a temperature just above a desired glass product forming temperature. 11. The system of claim 1 wherein the transition section inlet end structure comprises a bottom angled at an angle “α” to horizontal, and the outlet end structure includes a bottom portion angled at an angle “β” to horizontal, wherein “α” and “β” are the same or different. 12. A system comprising: a submerged combustion melter (SCM) configured to form a turbulent molten mass of foamed glass by melting glass-forming materials therein, the SCM comprising a roof, a floor, a sidewall structure connecting the roof and floor, and a foamed glass outlet in the floor and/or the sidewall structure; a first flow channel defining a fining chamber fluidly connected to and downstream of the SCM, the first flow channel comprising at least a floor, a sidewall structure, and a roof that slants upward in the flow direction at an angle “γ” to horizontal, the first flow channel comprising glass-contact refractory at least lining the floor and at least a portion of the first flow channel sidewall structure to a height sufficient to accommodate expansion of the molten mass of foamed glass as fining occurs during transit of the molten mass of foamed glass through the fining chamber, the fining separating the molten mass of foamed glass into an upper phase consisting essentially of glass foam and a lower phase consisting essentially of molten glass as the molten mass of foamed glass flows toward an end of the first flow channel distal from the SCM; and a transition section defining a passage fluidly connected to the distal end of the first flow channel, the transition section comprising a floor and a cover, the floor and cover connected by a sidewall structure, and comprising an inlet end structure and an outlet end structure, the inlet end structure comprising at least one molten glass inlet aperture and the outlet end structure comprising at least one molten glass outlet aperture, wherein all of the inlet apertures are positioned lower than a phase boundary between the upper and lower phases in the first flow channel. 13. A system comprising: a submerged combustion melter (SCM) configured to form a turbulent molten mass of foamed glass by melting glass-forming materials therein, the SCM comprising a roof, a floor, a sidewall structure connecting the roof and floor, and a foamed glass outlet in the floor and/or the sidewall structure; a first flow channel defining a fining chamber fluidly connected to and downstream of the SCM, the first flow channel comprising at least a floor and a sidewall structure, the first flow channel comprising glass-contact refractory at least lining the floor and at least a portion of the first flow channel sidewall structure to a height sufficient to accommodate expansion of the molten mass of foamed glass as fining occurs during transit of the molten mass of foamed glass through the fining chamber, the fining separating the molten mass of foamed glass into an upper phase consisting essentially of glass foam and a lower phase consisting essentially of molten glass as the molten mass of foamed glass flows toward an end of the first flow channel distal from the SCM; and a transition section defining a passage fluidly connected to the distal end of the first flow channel, the transition section comprising a floor and a cover, the floor and cover connected by a sidewall structure, and comprising an inlet end structure and an outlet end structure, the inlet end structure comprising at least one molten glass inlet aperture and the outlet end structure comprising at least one molten glass outlet aperture, wherein all of the inlet apertures are positioned lower than a phase boundary between the upper and lower phases in the first flow channel wherein the transition section cover slants upward in the flow direction at an angle “θ” to horizontal. 14. A system