Systems for and methods of monitoring and analyzing deposit in an industrial water system are provided. The methods comprise heating a substrate while the substrate contacts industrial water in the industrial water system to form deposit on the substrate. A series of digital images of the substrate while the substrate contacts the industrial water in the industrial water system is created. A region of interest in the series of digital images of the substrate is defined. A deposit feature in the region of interest in the series of digital images of the substrate is identified. The deposit feature in the region of interest in the series of digital images of the substrate is analyzed to determine a deposit trend of the substrate in the industrial water system. Generally, the systems are configured so as to be capable of carrying out one or more of the methods.

The present invention relates to the use of compounds of formula (I) in the treatment of products, in particular of aqueous or nonaqueous compositions, preferably water and aqueous compositions, against bacteria of the Burkholderia cepacia complex (Bcc), and also the use thereof in a process for treating an aqueous composition or water with respect to strains of the Bcc complex.

##STR00001##

formula (I) wherein: R2 represents a hydrogen atom or a methyl or ethyl radical; R3 represents a linear C.sub.1-C.sub.12 alkyl radical (saturated), optionally substituted with a hydroxyl group; or a linear C.sub.2-C.sub.12 alkenyl radical (C═C unsaturated), optionally substituted with a hydroxyl group.

The present invention relates to the use of compounds of formula (I) in the treatment of products, in particular of aqueous or nonaqueous compositions, preferably water and aqueous compositions, against bacteria of the Burkholderia cepacia complex (Bcc), and also the use thereof in a process for treating an aqueous composition or water with respect to strains of the Bcc complex.

##STR00001##

formula (I) wherein: R2 represents a hydrogen atom or a methyl or ethyl radical; R3 represents a linear C.sub.1-C.sub.12 alkyl radical (saturated), optionally substituted with a hydroxyl group; or a linear C.sub.2-C.sub.12 alkenyl radical (C═C unsaturated), optionally substituted with a hydroxyl group.

The present invention discloses a preparation method for the plant-based nano corrosion inhibition bactericide for oilfield, comprising the following steps: Step 1. Prepare the aloin liquid; Step 2. Stir the carbon nanotube, hydroxyethyl methacrylate and acrylic acid to react for 4 h at a constant temperature of 80° C. to get the carbon nanotube after fiber treatment, namely the modified carbon nanotube; Step 3. Mix the aloin liquid with imidazoline-ammonium-salt, add acetonitrile, and then add modified carbon nanotube, increase the temperature to 95° C. stir and react for 12 hours, and filter after naturally cooling down to room temperature and get the carbon nanotube loaded with bactericide; Step 4. Stir the carbon nanotube loaded with bactericide, diphenylmethane diisocyanate and polycaprolactone to react for 6 hours at a constant temperature of 95° C. and in the reaction process, continuously inject helium to get the target bactericide.

A trivalent doped cerium oxide composition is beneficial to aid in the removal of biological contaminants, such as bacteria, viruses, fungi, protozoa (e.g., amoebae), yeast and algae. These trivalent doped cerium oxide compositions can be used to remove these biological contaminants from fluids, including air and water, and from solid surfaces. The compositions also include a support material. Also described are methods of using compositions containing these trivalent doped cerium oxide compositions to remove biological contaminants.

A treatment process for remediating H.sub.2S and other contaminants in liquids includes: partially filling a closed vessel with a contaminated liquid containing ≥5 ppm H.sub.2S with a head space above the liquid within the vessel where gasses released from the liquid from the liquid collect; separately providing a treatment composition in the head space so that the gasses from the liquid may contact the treatment composition; and permitting the contact between the vapors from the liquid and the treatment composition to continue until a collective concentration of H.sub.2S in the liquid and in the head space is <5 ppm. The treatment composition includes an aqueous solution containing at least one hydroxide compound, a collective concentration of the at least one hydroxide compound in the aqueous solution is in a range of 35-55 weight %, and the aqueous solution constitutes at least 80 weight % of the treatment composition.

A treatment process for remediating H.sub.2S and other contaminants in liquids includes: partially filling a closed vessel with a contaminated liquid containing ≥5 ppm H.sub.2S with a head space above the liquid within the vessel where gasses released from the liquid from the liquid collect; separately providing a treatment composition in the head space so that the gasses from the liquid may contact the treatment composition; and permitting the contact between the vapors from the liquid and the treatment composition to continue until a collective concentration of H.sub.2S in the liquid and in the head space is <5 ppm. The treatment composition includes an aqueous solution containing at least one hydroxide compound, a collective concentration of the at least one hydroxide compound in the aqueous solution is in a range of 35-55 weight %, and the aqueous solution constitutes at least 80 weight % of the treatment composition.

A method of forming and fluid treatment system includes a vessel that is defined by a body having an inlet constructed to be connected to a fluid source and an outlet that is constructed to be connected to a discharge passage defined by a direction of a fluid flow directed through the body. The body is preferably three-dimensionally (3D) printed as a unitary body and from a filament material to define the entirety of the body including the inlet and the outlet. The vessel is preferably formed of an antimicrobial or other materials configured to manipulate the composition of the fluid flow directed therethrough and via direct contact of the fluid flow with the interior spaces of the body of the vessel.

A method of forming and fluid treatment system includes a vessel that is defined by a body having an inlet constructed to be connected to a fluid source and an outlet that is constructed to be connected to a discharge passage defined by a direction of a fluid flow directed through the body. The body is preferably three-dimensionally (3D) printed as a unitary body and from a filament material to define the entirety of the body including the inlet and the outlet. The vessel is preferably formed of an antimicrobial or other materials configured to manipulate the composition of the fluid flow directed therethrough and via direct contact of the fluid flow with the interior spaces of the body of the vessel.

A method of controlling a volatile fatty acid in an aqueous industrial system is provided in the present disclosure. The method includes determining a level of dissolved oxygen in process water in the aqueous industrial system and adding an effective amount of a control agent to the process water if the determined level of dissolved oxygen is above a predetermined level. The compositions and methods can lower the amount of VFA present in the aqueous industrial system.