A process for separating an aqueous emulsion including an aqueous phase and an non-aqueous phase into separated aqueous and non-aqueous phases, to provide a recovered non-aqueous phase, and to provide a recovered aqueous phase containing an acceptable level of the non-aqueous phase. In the process,
A process for separating an aqueous emulsion including an aqueous phase and an non-aqueous phase into separated aqueous and non-aqueous phases, to provide a recovered non-aqueous phase, and to provide a recovered aqueous phase containing an acceptable level of the non-aqueous phase. In the process, at least one body, and preferably two or more bodies, of polymeric material with a high surface area, typically a foam material or polymer chips, is used in a horizontal flow treatment system to break the emulsion and thus provide both the aqueous and non-aqueous phases as two separate flows. A wide range of polymers can be used in the system as the polymeric material including polyurethane, polypropylene, polystyrene, polyester, and polyethylene. If a very low level of non-aqueous phase in the effluent is required, for example to meet potable water standards, then a Kozlowski polyurethane, as described in U.S. Pat. No. 5,239,040, is preferred as the last polymeric material body.
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The invention claimed is: 1. An apparatus for continuously separating a flow of an aqueous emulsion including an aqueous continuous phase and a non-aqueous disperse phase to provide a flow comprising a non-aqueous phase and a further flow comprising a recovered aqueous phase containing an acceptabl
The invention claimed is: 1. An apparatus for continuously separating a flow of an aqueous emulsion including an aqueous continuous phase and a non-aqueous disperse phase to provide a flow comprising a non-aqueous phase and a further flow comprising a recovered aqueous phase containing an acceptable level of non-aqueous phase, which apparatus comprises in combination at least a first compartment and a second compartment wherein: (a) the first compartment includes a first feed means for receiving the flow of aqueous emulsion into a first enclosure occupying part of the space within the first compartment, which first enclosure is packed with a first body of high surface area particulate polymeric foam material, said first feed means comprising a fixed upstream foraminous sidewall of said first enclosure; an opposed fixed downstream foraminous sidewall forming part of the first enclosure through which a flow comprising a non-aqueous phase component and an aqueous phase component can flow into a first separation space for phase separation of said components, said first separation space comprising the remainder of the space within the first compartment; a first non-aqueous phase recovery means constructed and arranged to recover from the first separation space a non-aqueous flow comprising said non-aqueous phase component; and a first aqueous phase recovery means constructed and arranged to recover from the first separation space a recovered aqueous flow comprising said aqueous phase component; and (b) the second compartment includes a respective feed means for receiving said recovered aqueous flow into a respective enclosure occupying part of the space within the second compartment, which respective enclosure is packed with a respective body of high surface area particulate polymeric foam material, said respective feed means comprising a fixed upstream foraminous sidewall of said respective enclosure; an opposed fixed downstream foraminous sidewall forming part of the respective enclosure through which a flow comprising a respective non-aqueous phase component and a respective aqueous phase component can flow into a respective separation space for phase separation of said respective components, said respective separation space comprising the remainder of the space within the second compartment; a respective non-aqueous phase recovery means constructed and arranged to recover from said respective separation space a non-aqueous flow comprising said respective non-aqueous phase component; and a respective aqueous phase recovery means constructed and arranged to recover from said respective separation space a recovered aqueous flow comprising said respective aqueous phase component. 2. An apparatus according to claim 1 further including between the first and second compartments at least one other compartment which together with the first and second compartments provide a continuous flow path, wherein the at least one other compartment includes: a further respective feed means for receiving the recovered aqueous flow from an immediately adjacent compartment upstream in the flow path into a further respective enclosure occupying part of the space within said other compartment, which further respective enclosure is packed with a further respective body of high surface area particulate polymeric foam material, said further respective feed means comprising a fixed upstream foraminous sidewall of said further respective enclosure; an opposed fixed downstream foraminous sidewall forming part of said further respective enclosure through which a flow comprising a further respective non-aqueous phase component and a further respective aqueous phase component can flow into a further respective separation space for phase separation of said further respective components, said further respective separation space comprising the remainder of the space within said other compartment; a further respective non-aqueous phase recovery means constructed and arranged to recover from the said further respective separation space a non-aqueous flow comprising said further respective non-aqueous phase component; and a further respective aqueous phase recovery means constructed and arranged to recover from said further respective separation space a recovered aqueous flow comprising said further respective aqueous phase component for delivery to an immediately adjacent compartment downstream in the flow path. 3. An apparatus according to claim 2 wherein, for each compartment other than the first compartment, the feed means for receiving said recovered aqueous flow comprises a common foraminous wall separating said compartment from the immediately upstream compartment. 4. An apparatus according to claim 1 wherein for each enclosure the high surface area particulate polymeric foam material is the same. 5. An apparatus according to claim 2 wherein for each enclosure the high surface area particulate polymeric foam material is the same. 6. An apparatus according to claim 1 wherein the high surface area particulate polymeric foam material for each enclosure is not the same. 7. An apparatus according to claim 2 wherein the high surface area particulate polymeric foam material for each enclosure is not the same. 8. An apparatus according to claim 1 wherein the high surface area particulate polymeric foam material for each enclosure comprises polyurethane. 9. An apparatus according to claim 2 wherein the high surface area particulate polymeric foam material for each enclosure comprises polyurethane. 10. An apparatus according to claim 1 which further includes a pretreatment unit having a feed means for receiving the flow of aqueous emulsion, a pretreatment box and a recovery means for transferring a flow comprising an aqueous phase to the first feed means in the first compartment.
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