Abstract: Disclosed herein are systems and method for managing material balance between incoming and outgoing streams of material in an industrial system. A method may include providing a graphical user interface (GUI) that enables a system administrator to generate a visual model of the industrial system that includes (1) elements that are interconnected in the industrial system, and (2) streams including at least one incoming stream of material to each element and at least one outgoing stream of material from each element. The method may include receiving, via the GUI, a plurality of parameters of the elements and the streams such as material chemistry, user demand of each user element of the user elements, and flowrate for each stream of the streams. The method may include determining a category of each stream and automatically balancing, by a processor, incoming and outgoing streams for each element.

Abstract: Disclosed herein are systems and method for managing material balance between incoming and outgoing streams of material in an industrial system. A method may include providing a graphical user interface (GUI) that enables a system administrator to generate a visual model of the industrial system that includes (1) elements that are interconnected in the industrial system, and (2) streams including at least one incoming stream of material to each element and at least one outgoing stream of material from each element. The method may include receiving, via the GUI, a plurality of parameters of the elements and the streams such as material chemistry, user demand of each user element of the user elements, and flowrate for each stream of the streams. The method may include determining a category of each stream and automatically balancing, by a processor, incoming and outgoing streams for each element.

Abstract: A system and method of managing water in an evaporative cooling system includes one or a combination of three components. A first component is to purify incoming water to the target quality. A second component is to purify condenser loop water to the target quality. The choice of the technology may depend on the site specific environmental conditions determining the quality of the recirculated condenser water and may include (but not limited to) filtration allowing for meeting target quality parameters, such as ultrafiltration, microfiltration, etc. A third component is to provide protection for the condenser loop hardware, preventing or reducing rate of corrosion, fouling, and scaling by adding chemicals to water in the system.

Abstract: Integrated membrane treatment systems for treatment of an aqueous solution. In embodiments, components, such as an MBR, are integrated with means to recover energy from the system, for example from an RO concentrate, to operate the other components. In embodiments including biological treatment, RO is integrated with other components, such as an MBR with the ROs ability to remove inorganic nitrogen enabling biological treatment to be performed with only partial nitrification and the MBR operated without active pH control. In embodiments, RO is integrated with a chlorine generator to convert chlorides present in the RO concentrate for an in-situ source of oxidizing biocides for disinfection purposes. Chloramines may be generated in-situ from residual ammonia and chlorides in the RO reject. In embodiments, carrier media is employed in a membrane tank to enhance removal of residual organics by the MBR and to also improve effectiveness of membrane scouring.

Abstract: Integrated membrane treatment systems for treatment of an aqueous solution. In embodiments, components, such as an MBR, are integrated with means to recover energy from the system, for example from an RO concentrate, to operate the other components. In embodiments including biological treatment, RO is integrated with other components, such as an MBR with the ROs ability to remove inorganic nitrogen enabling biological treatment to be performed with only partial nitrification and the MBR operated without active pH control. In embodiments, RO is integrated with a chlorine generator to convert chlorides present in the RO concentrate for an in-situ source of oxidizing biocides for disinfection purposes. Chloramines may be generated in-situ from residual ammonia and chlorides in the RO reject. In embodiments, carrier media is employed in a membrane tank to enhance removal of residual organics by the MBR and to also improve effectiveness of membrane scouring.

Abstract: Integrated membrane treatment systems for treatment of an aqueous solution. In embodiments, components, such as an MBR, are integrated with means to recover energy from the system, for example from an RO concentrate, to operate the other components. In embodiments including biological treatment, RO is integrated with other components, such as an MBR with the ROs ability to remove inorganic nitrogen enabling biological treatment to be performed with only partial nitrification and the MBR operated without active pH control. In embodiments, RO is integrated with a chlorine generator to convert chlorides present in the RO concentrate for an in-situ source of oxidizing biocides for disinfection purposes. Chloramines may be generated in-situ from residual ammonia and chlorides in the RO reject. In embodiments, carrier media is employed in a membrane tank to enhance removal of residual organics by the MBR and to also improve effectiveness of membrane scouring.