The present invention relates to a fuel cell system capable of adjusting a bypass flow rate, in which the bypass flow rate can be automatically adjusted according to the temperature of an exhaust gas discharged from a fuel cell stack. The fuel cell system capable of adjusting a bypass flow rate, according to an embodiment of the present invention, comprises: an exhaust gas inlet flow path; an exhaust gas discharge flow path; a bypass flow path for bypassing a membrane humidifier to allow at least a portion of an exhaust gas discharged from a fuel cell stack to flow to the exhaust gas discharge flow path; and a bypass flow rate control unit that is formed in the bypass flow path and adjusts the opening degree of the bypass flow path according to the temperature of the exhaust gas discharged from the fuel cell stack.

Provided is a temperature-based dialysate regeneration device for regulating a temperature of dialysate discharged from a hemodialyzer to remove uremic toxins and waste therefrom, the temperature-based dialysate regeneration device including: a Joule-Thomson refrigerator, including a compressor, condenser, expander and evaporator, an adsorbent column, and a dialysate heat exchanger in which heat transfer occurs between dialysates. The refrigerant used for the JT refrigerator may be a mixture of two or more refrigerants to enhance the heat transfer generated by the latent heat in the evaporator and the condenser.

A water treatment device includes a primary unit having a plurality of primary elements as reverse osmosis membrane devices disposed in parallel with each other to separate water to be treated into primary condensed water and fresh water; a pump which feeds the water to be treated from the upstream side of the primary unit to the primary unit; a secondary unit having secondary elements which are provided to be fewer in number than the primary elements and separate the primary condensed water into secondary condensed water and fresh water; a sub-element which separates one of the water to be treated and the primary condensed water; and a mode switching unit which switches the sub-element between a primary mode of being used as the primary element in the primary unit and a secondary mode of being used as the secondary element in the secondary unit.

A water purification system that allows for bypassing one or more stages of purification during periods of high demand. Bypass can be selectively implemented as a function of fluid particulate levels and/or reservoir level.

A perfusion bioprocessing system (10) includes a bioreactor (12) and a recirculation flow path (14) provided with at least in one first feed flow control device (46) and at least one second feed control device (48). The perfusion bioprocessing system (10) further includes a first tangential flow filter (16) coupled to the bioreactor (12) via the recirculation flow path (14) and a second tangential flow filter (18) coupled to the bioreactor (12) via the recirculation flow path (14). The first tangential flow filter and the second tangential flow filter are coupled to a permeate flow path and a retentate flow path. Additionally, the perfusion bioprocessing system (10) includes a control unit (90) coupled to the at least one first feed flow control device (38) and the at least one second feed control device (40).

A process for extracting a phosgene compound, comprising providing a membrane extracting unit comprising at least one extracting cell that comprises at least one membrane contactor module having at least two sides, a gas side and a liquid side; letting an initial gas stream comprising a phosgene compound flow on the gas side of the membrane contactor module; and letting an extractant liquid stream, suitable for dissolving a phosgene compound, flow on the liquid side of the membrane contactor module so that the extractant liquid stream absorbs the phosgene compound from the initial gas stream and provides a second extractant liquid stream enriched with the phosgene compound.

Provided is a temperature-based dialysate regeneration device for regulating a temperature of dialysate discharged from a hemodialyzer to remove uremic toxins and waste therefrom, the temperature-based dialysate regeneration device including: a Joule-Thomson refrigerator, including a compressor, condenser, expander and evaporator, an adsorbent column, and a dialysate heat exchanger in which heat transfer occurs between dialysates. The refrigerant used for the JT refrigerator may be a mixture of two or more refrigerants to enhance the heat transfer generated by the latent heat in the evaporator and the condenser.

The present invention relates to a method for operating a separation membrane module including a separation membrane having a first face and a second face, a liquid-to-be-filtrated flow channel along which liquid to be filtrated which is to be fed to the first face flows, and a permeated-liquid flow channel along which permeated liquid obtained from the second face flows, the method including: a filtration step of obtaining permeated liquid containing components that become insoluble when coming into contact with acids by feeding liquid to be filtrated to the liquid-to-be-filtrated flow channel; a first water substitution step of substituting liquid in the permeated-liquid flow channel with water, after the filtration step; a first chemical cleaning step of performing backwashing by causing an acidic chemical solution to flow from the second face toward the first face of the separation membrane, after the first water substitution step; and a second water substitution step of substituting liquid in the permeated-liquid flow channel with water, after the first chemical cleaning step.

A water filtering system including an inlet, an outlet and a filter positioned between the inlet and the outlet, where feed water enters the inlet and passes through the filter, and filtered water exits the through the outlet. A measurement device is connected to at least one of the inlet and the outlet measures a concentration of Total Dissolved Solids in at least one of the inlet and the outlet. A bypass valve is connected between the inlet and the outlet, and moves between a closed position and an open position, where the filtered water moves from the outlet to the inlet. A controller communicates with the measurement device and the bypass valve and automatically moves the bypass valve to a position between the closed position and the open position based on the concentration of the Total Dissolved Solids in the filtered water measured by the measurement device.

A perfusion bioprocessing system (10) includes a bioreactor (12) and a recirculation flow path (14) provided with at least one first feed flow control device (46) and at least one second feed control device (48). The perfusion bioprocessing system (10) further includes a first tangential flow filter (16) coupled to the bioreactor (12) via the recirculation flow path (14) and a second tangential flow filter (18) coupled to the bioreactor (12) via the recirculation flow path (14). The first tangential flow filter and the second tangential flow filter are coupled to a permeate flow path and a retentate flow path.