Method and system for operating a high recovery separation process
First Claim
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1. A reverse osmosis system comprising:
- a pump operable to pressurize a feed stream;
a first membrane array configured to receive the feed stream and to generate a first permeate stream and a first brine stream from the feed stream;
a second membrane array configured to receive the first brine stream and to generate a second permeate stream and a second brine stream from the first brine stream;
a first turbocharger comprising a first turbine configured to receive the second brine stream and to use first energy from the second brine stream to selectively increase a first pressure of the first brine stream, said first turbine comprising a first turbocharger housing comprising a first bypass passage associated with a first bypass valve, a first main nozzle communicating a first part of a first portion of the second brine stream to a first volute and a first auxiliary nozzle comprising a first auxiliary valve selectively communicating a second part of the first portion of the second brine stream to the first volute;
a second portion of the second brine stream is communicated through the first bypass valve and wherein the first portion and second portion combine to reform the second brine stream;
a second turbocharger comprising a second turbine configured to receive the second brine stream after the first turbocharger and to use second energy from the second brine stream to increase a second pressure of the feed stream, said second turbine comprising a second turbocharger housing comprising a second bypass passage associated with a second bypass valve, a second main nozzle communicating a first part of a third portion of the second brine stream to a second volute and a second auxiliary nozzle comprising a second auxiliary valve selectively communicating a second part of the third portion of the second brine stream to the second volute;
a fourth portion of the second brine stream is communicated through the second bypass valve;
a first flowmeter generating a first flow signal corresponding to a first flow of the first permeate stream;
a second flowmeter generating a second flow signal corresponding to a second flow of the second permeate stream;
a third flowmeter generating a third flow signal corresponding to a third flow of the second brine stream;
a motor coupled to the first turbocharger, operable to use energy from a power supply to drive the first turbocharger; and
a controller in communication with the first flowmeter, the second flowmeter, and the third flowmeter, said controller controlling the first auxiliary valve, the first bypass valve, the second auxiliary valve and the second bypass in response to the first flow signal, the second flow signal and the third flow signal.
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Abstract
A reverse osmosis system and method includes a pump pressurizing a feed stream, a first and second membrane array that generates permeate and brine streams. A first energy recovery device uses first energy from the second brine stream to pressurize the first brine stream. A first and second auxiliary and bypass valves are associated with the first and second energy recovery device. A second energy recovery device uses second energy from the second brine stream to increase a second pressure of the feed stream. A first flowmeter generates a first flow signal for the first permeate stream. A second flowmeter generates a second flow signal for of the second permeate stream. A third flowmeter generates a third flow signal for the second brine stream. A motor drives the first energy recovery device. A controller controls the in response to the flow signals.
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Citations
22 Claims
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1. A reverse osmosis system comprising:
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a pump operable to pressurize a feed stream; a first membrane array configured to receive the feed stream and to generate a first permeate stream and a first brine stream from the feed stream; a second membrane array configured to receive the first brine stream and to generate a second permeate stream and a second brine stream from the first brine stream; a first turbocharger comprising a first turbine configured to receive the second brine stream and to use first energy from the second brine stream to selectively increase a first pressure of the first brine stream, said first turbine comprising a first turbocharger housing comprising a first bypass passage associated with a first bypass valve, a first main nozzle communicating a first part of a first portion of the second brine stream to a first volute and a first auxiliary nozzle comprising a first auxiliary valve selectively communicating a second part of the first portion of the second brine stream to the first volute; a second portion of the second brine stream is communicated through the first bypass valve and wherein the first portion and second portion combine to reform the second brine stream; a second turbocharger comprising a second turbine configured to receive the second brine stream after the first turbocharger and to use second energy from the second brine stream to increase a second pressure of the feed stream, said second turbine comprising a second turbocharger housing comprising a second bypass passage associated with a second bypass valve, a second main nozzle communicating a first part of a third portion of the second brine stream to a second volute and a second auxiliary nozzle comprising a second auxiliary valve selectively communicating a second part of the third portion of the second brine stream to the second volute; a fourth portion of the second brine stream is communicated through the second bypass valve; a first flowmeter generating a first flow signal corresponding to a first flow of the first permeate stream; a second flowmeter generating a second flow signal corresponding to a second flow of the second permeate stream; a third flowmeter generating a third flow signal corresponding to a third flow of the second brine stream; a motor coupled to the first turbocharger, operable to use energy from a power supply to drive the first turbocharger; and a controller in communication with the first flowmeter, the second flowmeter, and the third flowmeter, said controller controlling the first auxiliary valve, the first bypass valve, the second auxiliary valve and the second bypass in response to the first flow signal, the second flow signal and the third flow signal. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10)
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11. A method for operating a reverse osmosis system, the method comprising:
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directing a feed stream to a first membrane array to separate the feed stream into a first permeate stream and a first brine stream; directing the first brine stream to a second membrane array to separate the first brine stream into a second permeate stream and a second brine stream; determining a first flow signal corresponding to a first flow in the first permeate stream; determining a second flow signal corresponding to a second flow in the second permeate stream; determining a third flow signal corresponding to a third flow in the second brine stream; receiving the second brine stream at a first turbine of a first turbocharger, said first turbine comprising a first turbocharger housing comprising a first bypass passage associated with a first bypass valve, a first main nozzle and a first auxiliary nozzle; communicating a first part of a first portion of the second brine stream to a first volute through the first main nozzle; selectively communicating a second part of the first portion of the second brine stream to the first volute through a first auxiliary valve of the first auxiliary nozzle; communicating a second portion of the second brine stream through the first bypass valve; and combining the first portion and second portion combine to reform the second brine stream; determining a first auxiliary nozzle valve setting and a first bypass valve setting in response to the first flow signal and the third flow signal; receiving the second brine stream at a second turbine of a second turbocharger, said second turbine comprising a second turbocharger housing comprising a second bypass passage associated with a second bypass valve, a second main nozzle and a second auxiliary nozzle; communicating a first part of a third portion of the second brine stream to a second volute through the second main nozzle; selectively communicating a second part of the third portion of the second brine stream to the second volute through a second auxiliary valve of the second nozzle; communicating a fourth portion of the second brine stream through the second bypass valve; determining a second auxiliary nozzle valve setting and a second bypass valve setting in response to the second flow signal and the third flow signal; and controlling a torque output of a motor-generator coupled to a first hydraulic pressure booster to adjust an amount by which a first hydraulic booster increases a pressure of at least one of the feed stream and the first brine stream in response to the first flow signal. - View Dependent Claims (12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22)
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Specification
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Current AssigneeFluid Equipment Development Company, LLC (Vector Technologies, LLC)
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Original AssigneeFluid Equipment Development Company, LLC (Vector Technologies, LLC)
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InventorsOklejas, Jr., Eli
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Primary Examiner(s)Menon, Krishnan S
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Application NumberUS16/138,291Publication NumberTime in Patent Office284 DaysField of SearchNoneUS Class CurrentCPC Class CodesB01D 2311/14 Pressure controlB01D 2311/16 Flow or flux controlB01D 2313/083 Bypass routesB01D 2313/18 Specific valvesB01D 2313/243 PumpsB01D 2313/246 Energy recovery meansB01D 2313/60 Specific sensors or sensor ...B01D 2313/70 Control means using a progr...B01D 2317/022 Reject seriesB01D 2317/04 Elements in parallelB01D 2317/06 Use of membrane modules of ...B01D 61/025 Reverse osmosis; Hyperfiltr...B01D 61/026 comprising multiple reverse...B01D 61/06 Energy recoveryB01D 61/10 Accessories; Auxiliary oper...B01D 61/12 Controlling or regulatingC02F 1/441 by reverse osmosisC02F 2103/08 Seawater, e.g. for desalina...C02F 2201/005 ValvesC02F 2209/40 Liquid flow rateView All
