An embodiment provides a ballast water treatment system, including: a ballast pump; a backwash pump, wherein an outflow of the backwash pump is mechanically coupled to an outlet of the ballast pump; a treatment unit, wherein the treatment unit is located fluidly between the ballast pump and the backwash pump; wherein the ballast water treatment system has at least two modes, comprising: a ballast mode, wherein, during the ballast mode, the ballast pump pumps water through the ballast treatment system to a ballast tank, and a de-ballast mode, wherein, during the de-ballast mode, the backwash pump conveys backwash water to an outlet of the ballast pump. Other aspects are described and claimed.

A method of sterilizing ballast water contains providing a device in a pressurized cabin of a ship, the device includes: a first sterilization unit, multiple second sterilization units, and a third sterilization unit. The first sterilizer includes a first valve connected with a first pump via at least one first pipe, and the multiple second sterilization units are soaked in ballast water of the pressurized cabin. A method of sterilizing the ballast water contains steps of: S1. feeding seawater into the first valve from an exterior of the ship and pumping the seawater into the first sterilizer via the at least one first pipe; S2. magnetizing, wherein the first sterilizer has multiple magnetization elements so as to destroy cell walls of microorganism and bacteria in the seawater by using a magnetic field of the multiple magnetization elements; and S3. inhibiting a growth of the microorganism and the bacteria.

A method for treating a liquid loaded with ingredients includes injecting the liquid into a reactor vessel such that a circular movement is imparted to the liquid and such that a concentration of the ingredients in a region of a peripheral wall of the reactor vessel increases in a direction from a reactor inlet to a reactor outlet, impinging ultrasound waves having a first intensity and/or ultraviolet radiation having a first intensity on the liquid in a first portion of the reactor vessel, and impinging ultrasound waves having a second intensity and/or ultraviolet radiation having a second intensity on the liquid in a second portion of the reactor vessel. The concentration of the ingredients in the first portion is less than the concentration of the ingredients in the second portion and the first intensity is less than the second intensity. Also a reactor vessel.

An online antifouling ship ballast water treatment system includes a ballast water main pipeline, a ballast water branch pipeline, a dispensing pipeline, a filter on the ballast water main pipeline, an electrolysis unit on the ballast water branch pipeline, and a dispensing pump on the dispensing pipeline. Some of seawater introduced into the system is filtered by the filter and flows to the ballast water branch pipeline and the electrolysis unit, some of seawater electrolyzed by the electrolysis unit is reinjected to the filter through the dispensing pump and the dispensing pipeline after a ballast process is completed, and kept in the filter until a next ballast operation, so that growth and propagation of marine organisms in the filter can be inhibited by sodium hypochlorite contained in a TRO solution when a ballast pump stops working. The present invention also provides a ship ballast water treatment method.

An electrochlorination system comprises a source of feed fluid, a product fluid outlet, and a plurality of electrochemical cells connected fluidically between the source of feed fluid and the product fluid outlet. The system is configured to operate at least one of the plurality of electrochemical cells at one of a first current density or a first flow rate, and to operate another of the plurality of electrochemical cells at a second current density or second flow rate different from the respective first current density or first flow rate.

A ballast water treatment system for producing treated seawater is described herein that includes: a reaction chamber, wherein the reaction chamber is located within a vessel; an inlet for introducing chlorine dioxide into the reaction chamber, wherein the reaction chamber is equipped with one or more turbulence inducing devices configured for inducing turbulence, wherein the turbulence inducing device is a stationary device; a second inlet for the introduction of seawater, into the reaction chamber; and an outlet from the reaction chamber, wherein the treated seawater is returned to a storage facility within the vessel or is returned to the sea. A method of treating ballast seawater for producing treated seawater is also described that includes: providing a reaction chamber, wherein the reaction chamber is located within a vessel; providing an inlet for introducing chlorine dioxide into the reaction chamber, wherein the reaction chamber is equipped with one or more turbulence inducing devices configured for inducing turbulence, wherein the turbulence inducing device is a stationary device; providing a second inlet for the introduction of seawater, into the reaction chamber; providing an outlet from the reaction chamber; and treating the seawater with chlorine dioxide, wherein the treated seawater is returned to a storage facility within the vessel or is returned to the sea.

An electrochlorination system includes an electrolyzer fluidically connectable between a source of feed fluid and a product fluid outlet, and a sub-system configured to one of increase a pH of the feed fluid, or increase a ratio of monovalent to divalent ions in the feed fluid, upstream of the electrolyzer.

A water treatment apparatus using a lamella structure according to an embodiment of the present invention includes a first treatment tank which includes a plurality of inclined plates and is configured to pass water subject to treatment between the inclined plates adjacent to each other and a second treatment tank which is installed at a rear end of the first treatment tank to accommodate the water subject to treatment and into which bubbles are supplied, wherein the plurality of inclined plates include positive electrode plates and negative electrode plates that are alternately arranged, and the water subject to treatment passes between the positive electrode plate and the negative electrode plate.

A ballast water treatment apparatus and a ballast water treatment system having a ballast water treatment apparatus are provided. The ballast water treatment apparatus includes a ballast water transport line configured to transport ballast water between a first location and a second location, the transported ballast water being passed through at least one injector, and a plasma generation device configured to be fed with a feed gas optionally comprising oxygen, and configured to generate a feed gas plasma by a streamer type discharge in a discharge area to provide a treated gas at a treated-gas outlet. The injector includes a liquid passage having an area constructed such as to increase a velocity of the passed-through water in a region of increased velocity, and an injector gas inlet provided in the region of increased velocity. The treated-gas outlet is in gaseous connection with the injector gas inlet.

Aqueous activated ferrate solutions, methods of their preparation, and methods of disinfecting organisms and oxidizing pollutants in water are provided.