NZ619916B2

NZ619916B2 - Methods for the on-site production of chloramine and use thereof

Info

Publication number: NZ619916B2
Application number: NZ619916A
Authority: NZ
Inventors: Randall Elliott; Amit Gupta; Yumei Lu; Laura E Rice; Wen Li Tu; yu mei Lu
Original assignee: Nalco Company
Priority date: 2011-09-30
Filing date: 2012-09-21
Publication date: 2016-07-01

Abstract

The disclosure relates to a method of producing stable disinfectant for use as a biocidal composition, the method comprising providing reagents comprising an amine source of disinfectant in concentrated form, an oxidizing halogen compound in concentrated form, and a diluent and asynchronously feeding at least two of the reagents into a wide space, and allowing all three of the reagents to come into contact and mix with each other. The amine source may be chloramine and the oxidizing halogen may be sodium hypochlorite. g at least two of the reagents into a wide space, and allowing all three of the reagents to come into contact and mix with each other. The amine source may be chloramine and the oxidizing halogen may be sodium hypochlorite.

Description

PCT/U52012/056567 S FOR THE ON—SITE PRODUCTION OF CHLORAMINE AND USE THEREOF Cross-Reference to d Applications This ation is a Continuation-In Part of currently pending US Patent Application 12/546,086 which was ﬁled on August 24, 2009 and which itselfis a Continuation-In Part of now abandoned US Patent Application 11/618,227 ﬁled on December 29, 2006.

Statement Regarding Federally Sponsored Research or Development Not Applicable.

Background of the Invention This invention relates to methods and compositions for producing stable chloramine for use as a biocidal composition. rial water s are subject to various sorts of fouling. Fouling can occur in the form of mineral fouling, ical fouling, and often combinations of the two. In fact mineral fouling often provides an anchor and substrate for biological infestations, and some organisms leach or secrete minerals onto industrial water system es.

Fouling may occurs as a result of a variety of isms including deposition of air-borne and water-borne and water-formed contaminants, water stagnation, process leaks, and other factors. If d to progress, fouling can cause a system to suffer from decreased operational efﬁciency, premature equipment failure, loss in productivity, loss in product quality, and (in particular in the case of microbial fouling) increased health-related risks.

Biological fouling results from rapidly spreading microbial communities that develop on any wetted or semi-wetted e of the water system. Once these microorganisms SUBSTITUTE SHEET (RULE 26) PCT/U52012/056567 are present in the bulk water they will form of biofilms on the system’s solid surfaces.

Exopolymeric substance secreted from the microorganisms aid in the formation of biofilms as the microbial communities p. These biofilms are complex ecosystems that ish a means for concentrating nutrients and offer protection for growth. Bioﬁlms can accelerate scale, corrosion, and other fouling processes. Not only do bioﬁlms contribute to reduction of system efficiencies, but they also provide an excellent environment for microbial proliferation that can include pathogenic bacteria. It is therefore important that biofilms and other fouling processes be reduced to the greatest extent possible to maximize process efﬁ ciency and minimize the health-related risks from water-borne pathogens.

Several factors contribute to the m of biological fouling and govern its extent. Water temperature; water pH; organic and inorganic nutrients, growth conditions such as aerobic or anaerobic conditions, and in some cases the presence or absence of sunlight, etc. can play an important role. These s also help in deciding what types of microorganisms might be present in the water system.

Many different Prior Art approaches have been attempted to control ical fouling of industrial processes. The most commonly used method is the application of biocidal compounds to the s . The es applied may be oxidizing or non-oxidizing in nature. Due to several different factors such as economics and environmental concerns, the oxidizing biocides are preferred. Oxidizing biocides such as chlorine gas, lorous acid, bromine derived biocides, and other oxidizing biocides are widely used in the treatment of industrial water systems.

One factor in ishing the efficacy of oxidizing biocides is the presence of components within the water matrix that would constitute a ne demand or oxidizing biocide demand. Chlorine-consuming substances include, but are not limited to, microorganisms, WO 48899 PCT/U52012/056567 organic molecules, ammonia and amino derivatives; sulfides, es, oxidizable cations, pulp lignins, starch, sugars, oil, water treatment additives like scale and corrosion tors, etc.

Microbial growth in the water and in bioﬁlms butes to the chlorine demand of the water and to the chlorine demand of the system to be treated. Conventional oxidizing biocides were found to be ctive in waters containing a high chlorine , including heavy slimes.

Non-oxidizing biocides are usually recommended for such waters.

As described in US Patent ations 12/5 46,086 and 11/618,227, mines are effective and are typically used in conditions where a high demand for oxidizing es such as chlorine exists or under conditions that benefit from the persistence of an oxidizing biocide. Domestic water systems are increasingly being treated with chloramines. Chloramines are generally formed when free chlorine reacts with ammonia present or added to the waters.

Many ent methods for production of chloramines have been documented. Certain key parameters of the on between the chlorine and the nitrogen source determine the stability and efficacy of the produced biocidal compound.

Prior Art methods of producing chloramines have been described for example in US Patents 7,285,224, 6,132,628, 5,976,386, 7,067,063, and 3,254,952 and US Published Patent Application and 2007/0123423. The Prior Art methods generally rely on the combination of an ammonium stabilizer component and a sodium hypochlorite component in a dilute or concentrated form to produce a solution of chloramines followed by immediate introduction into the water system being treated. Also typically the combination of the chemical ents is conducted in a continuous and synchronous fashion in a conduit. To achieve this the components are either added to separate diluent (such as water) streams ed by the combination of the different streams containing the diluted components or the components are added simultaneously to the same stream at different locations, or the concentrated from of the components are 2012/056567 combined. The components comprise a nitrogen source typically in the form of a ammonium salt (such as a sulfate, bromide, or chloride) and a chlorine or Bromine donor in the form of gas or combined With alkali earth metal (such as sodium, potassium, or calcium). Also the prior art methods have relied upon controlling the pH of the mixed solution by addition of a component at a high pH or by the separate addition of a caustic solution.

The limitations of these Prior Art methods have d a number of drawbacks on their use. NIost limiting is the fact that the produced chloramine must be ately used and cannot be stored for future use because it is subject to rapid degradation. The chloramine also must be generated outside of the system being treated and must be rapidly piped in to the system. As a result various economic, efficiency, and process, constraints limit the use and practicality of these Prior Art methods. Thus there is clear need and utility for a s and compositions useful in improving the production and use of stable chloramine for use as a al composition.

The art described in this n is not ed to constitute an ion that any patent, publication or other information referred to herein is "Prior Art" With respect to this invention, unless speciﬁcally designated as such. In addition, this section should not be construed to mean that a search has been made or that no other pertinent information as deﬁned in 37 CFR § 1.56(a) exists.

Brief Summary of the Invention At least one embodiment of the invention is directed to a method of ing stable disinfectant for use as a biocidal composition. The method comprises: A) providing reagents, B) asynchronously feeding the at least two of the reagents into a Wide space, and C) allowing all the reagents to come into contact and mi); with each other. The PCT/U52012/056567 reagents comprise: a) an amine source of disinfectant in concentrated form, b) an oxidizing halogen compound in trated form, and c) a diluent.

The amine source may be chloramine. The diluent may comprise enough caustic to reduce the pH of the combination of reagents to no more than 12. 5. The concentration of the ectant in concentrated form may be in the range from 5% — 80% and after it is mixed with the diluent it drops to 0.01% - 5%. The concentration of the oxidizing halogen compound in concentrated form may be within the range of 3% - 18% and after it is mixed with the t it drops to 0.01% - 3%. The molar ratio of chloramine to oxidizing halogen may be within the range of 0.1:1 to 10:1. The oxidizing halogen may be a chlorine source and may be sodium hypochlorite. The ectant may be produced according to a batch process, a continuous dose s, a slug dose process and any combination thereof.

Additional features and advantages are described herein, and will be apparent from, the following ed Description.

Brief Description of the Drawings A detailed description of the invention is hereafter described with speciﬁc reference being made to the drawings in which: is a drawing of a separate addition method of producing mine using a wide space in the blending lines or a batch method. is a drawing of a uous dilution method of producing chloramine using a wide space in the blending lines or a batch method. is a drawing of a prior mixing method of producing dilute chloramine using a wide space in the blending lines or a batch method. is a drawing of a prior mixing and subsequent dilution method of 2012/056567 producing chloramine using a wide space in the ng lines or a batch . is a g of a sequential addition method of producing dilute mine.

Delete ﬁgure 6 from graphics. is a drawing of a sequential feed method of introducing chloramine into a system to be treated. is a drawing of a periodic addition method of introducing chloramine into a system to be treated. is a drawing of a first form of alternating on method of introducing chloramine into a system to be treated. is a drawing of a second form of alternating addition method of introducing chloramine into a system to be treated. is a drawing of a third form of alternating addition method of introducing chloramine into a system to be treated. is a drawing of a fourth form of alternating addition method of introducing chloramine into a system to be treated. is a drawing of a first form of alternating feeding addition method of introducing chloramine into a system to be treated. is a drawing of a second form of alternating feeding addition method of introducing chloramine into a system to be treated. is a drawing of a third form of alternating feeding addition method of introducing chloramine into a system to be treated. is a drawing of a third form of alternating feeding addition method of introducing chloramine into a system to be treated where the amine and halogen components are WO 48899 PCT/U52012/056567 added at the same location in the conduit. is a g of a third form of alternating feeding addition method of introducing chloramine into a system to be treated where the amine and halogen components are added at the same location in the t. is a drawing of a third form of alternating feeding addition method of introducing chloramine into a system to be treated where the amine and halogen components are added at the same location in the conduit. is a drawing of a third form of alternating feeding addition method of introducing chloramine into a system to be treated where the amine and halogen components are added at the same location in the conduit. is a dra wing of a third form of ating g addition method of introducing chloramine into a system to be treated where the amine and halogen components are added at the same location in the conduit.

Detailed Description of the Invention The following definitions are provided to ine how terms used in this application, and in particular how the claims, are to be construed. The organization of the deﬁnitions is for convenience only and is not ed to limit any of the deﬁnitions to any particular category.

“Amine Source” means any inorganic or organic compound comprising an um ion and/or moiety which can be oxidized and/or halogenated by an oxidizing halogen.

“Asynchronous Mixing” means mixing such that over a discrete period oftime the amount or concentration of a material mixed and then fed into a system ﬂuctuates.

PCT/U52012/056567 Asynchronous Mixing of biocides is more likely to result in the particular formulation ideal for killing the particular organism present happening to result and it also creates a dynamic environment which makes it difﬁcult for organisms to adapt to.

“Batch Process” means a chemical process in which only a ﬁnite number of reagents can be fed into a reaction operation over a period of time having a discrete start time and end time and which produces a ﬁnite amount of product.

"Channeling" means a s in which mixture of materials ﬂowing through a line tes into different ﬂowing layers sorted by density, viscosity, temperature or some other ty. Channeling can be prevented by use of a wide space in the mixing line.

"Chlorine demand” means the quantity of chlorine that is reduced or otherwise ormed to inert forms of chlorine by substances in the water.

“Concentrated” means the materials are used as delivered, without the addition of a diluent. Where sodium hypochlorile is used, the concentration will range from 31-18% as total available chlorine. The concentration of the amine solutions may range from 5-80%.

“Continuous Process” means an ongoing al process, which is capable of theoretically continuing over an unlimited period of time in which reagents can be continuously fed into a reaction operation to continuously produce product. Continuous Process and Batch Process are mutually exclusive.

“Fouling” means the unwanted deposition of organic or inorganic material on a surface.

“Oxidizing Halogen” means a halogen bearing composition of matter including but not limited to chlorine, bromine or iodine tives, most preferably a chlorine or bromine derivative such as lorous acid or omous acid, wherein the composition is capable of oxidizing an amine source.

PCT/U52012/056567 “Wide Space” means an area in the mixing line where the er of the line is larger than the largest individual t supply line leading into it and in which the transition from the smaller to larger diameter is not streamlined, whereby when a liquid ﬂows into this area the change in er results in eddies which mix the fed als in an erratic manner and prevents channeling. This wide space allows for adequate mixing, functioning differently than a standard conduit. The wide space could be an isolated batch tank.

In the event that the above definitions or a description stated elsewhere in this application is inconsistent with a meaning (explicit or implicit) which is commonly used, in a dictionary, or stated in a source incorporated by reference into this application, the application and the claim terms in particular are understood to be construed according to the deﬁnition or description in this application, and not according to the common deﬁnition, dictionary definition, or the definition that was incorporated by reference. In light of the above, in the event that a term can only be understood if it is construed by a dictionary, if the term is defined by the Kirk— Othmer opedia ofChemz'caZ Technology, 5th Edition, (2005'), (Published by Wiley, John & Sons, Inc.) this definition shall control how the term is to be defined in the claims.

In at least one embodiment chloramine is generated by a process in which the chemical reagents are introduced into a wide space for the tion of mine. In at least one embodiment one or more of the reagents are introduced either automatically via a controller device, such as a PLC device or a timer, or manually. Any number of measurements can be used to regulate the ﬂow of reagents, including but not limited to tank volume, ORP, residual ne, pH, temperature, and microbial activity. The wide space can take the shape of a plumbed wide zone in a conduit that is then connected to the process being treated or it can be a separate container, for e a tank. A diluent which is any riate liquid including but not limited to water is also streamed into the wide space.

PCT/U52012/056567 In FIG.s 1-19 there are shown a number of arrangements for an apparatus used in the inventive method. These apparatuses involve the feeding of at least three items into the wide space (4). Feed item A (1) is a concentrated or a diluted chlorine source, lly sodium hypochlorite. Feed item B (2) is a concentrated or a diluted stabilizer composition which is a nitrogen bearing composition. The nitrogen bearing n can be an organic material or an ammonium salt. The salt form can be a result of the nitrogen bearing item being in the form of a sulfate, e or de. The nitrogen bearing material can also include ammonium sulfamate. At some point Feed Item A (1), Feed Item B (2), come into contact with a diluent (3).

In at least one ment the diluent comprises water. In at least one embodiment the diluent comprises enough caustic to maintain the pH of the combination of Feed Items A and B (1, 2) to no more than 12.5. Other means of caustic addition e adding caustic to the halogen and/or stabilizer solution to maintain the pH of the combination of Feed Items A and B (1, 2) to no more than 12.5.

Referring now to there is shown a method in which Feed Items A and B (1, 2) are added as concentrates or as d products. Additional diluent (3) may or may not be added or the products may be batch diluted on-site. The setup may contain an optional mixer to aid mixing of the different components. The chloramine as produced in the tank is then introduced into the process water system (7) needing to be treated. The introduction may be by way of a pump (6). The chloramine is produced in the wide space (4) and is then introduced into the s water system needing to be treated.

Referring now to there is shown a method in which Feed Items A and B (1, 2) are diluted continuously as they are introduced into the wide space (4). Feed Items A and B (1, 2) and diluent (3) may be blended in any order. In at least one embodiment not all components are diluted. The setup may contain an al in-line or static mixer to aid mixing PCT/U52012/056567 of one or more chemical ents and the diluent. Also, the setup may include a mixer in the tank to aid in the blending of the different solutions. The chloramine as produced in the tank is then introduced into the process water system requiring treatment.

Referring now to there is shown a method in which Feed Items A and B (1, 2) are either concentrates or diluted and are mixed with each other prior to being introduced into the tank. The setup may contain an optional in-line mixer to aid mixing of the chloramine and the t. Also, the setup may include a mixer in the tank to aid in the blending of the different solutions. The diluent can optionally be introduced into the tank in a separate stream.

Referring now to there is shown a method in which Feed Items A and B (l, 2) can be mixed prior to entering the tank ed by the addition of the diluent to the conduit before entering the wide space (4). Feed Items A and B (l, 2) may be concentrates or diluted prior to blending. The setup may n an optional in-line mixer to aid in the blending of the chloramine and the diluent. Also, the setup may include a mixer in the tank to aid in efficient ng of the different solutions.

Referring now to there is shown a method in which Feed Items A and B (l, 2) are added sequentially to a stream of the diluent. The combination of Feed Items A and B (1, 2) result in the formation of the chloramine, which is then introduced into the wide space (4) along with the diluent. The setup may n an optional in-line mixer to aid mixing of the chemical components and the diluent. Also, the setup may include a mixer in the tank to aid in efficient mixing of the different solutions.

Referring now to FIGs. 6-13 there are shown s in which Feed Items A and B (1, 2) are synchronously or asynchronously combined in a d form (concentrate added to a diluent) Via a controller device, such as a PLC device or a timer, PCT/U52012/056567 or manually and the resulting chloramine is introduced, synchronously or asynchronously, into the s to be treated. In this method, any number of chemical components can be introduced into the diluent stream. The diluent can be water or any other liquid stream appropriate for the dilution of the al components. The method may comprise a valve (5) to l the ﬂow. A solid arrow line after the valve (5), depicts a continuous ﬂow while a dashed line represents an interrupted or discontinuous ﬂow.

Referring now to there is shown a method in which Feed Items A and R (1, 2) are added sequentially into the conduit in a continuous manner and the feed of the resulting chloramine to the s being treated is continuous.

Referring now to there is shown a method in which Feed Items A and B (1, 2) are added sequentially into the conduit in a continuous manner but the feed of the resulting chloramine to the process being d is discontinuous.

Referring now to FIGS. 8, 9, 10, and 11 there are shown a method in which Feed Items A and B (1, 2) are added sequentially into the conduit but the addition of one of Feed Items A or B is periodic. The feed of the resulting mine to the process being treated can be either continuous or periodic.

Referring now to FIGs. 12 and 13 there are shown s in which Feed Items A and B (1, 2) are added sequentially into the conduit but the addition of all the chemical components is periodic. The feed of the resulting chloramine t0 the process being treated can be either continuous or periodic.

Referring now to FIGs. 14, 15, 16, 17, 18, and 19 there are shown methods in which Feed Items A and B (1, 2) are added simultaneously at the same location in the conduit and the addition of all the reactants can be continuous or periodic. The feed of the resulting mine to the process being treated can be either continuous or periodic. 2012/056567 The inventive methods facilitate the production of chloramine in ways that display numerous advantages. The method facilitates batch production and can be performed under dilute conditions. The ability to ﬁne tune the amounts of chloramine, stabilizer, and halogen components allows for enhanced process compatibility and program performance through optimized chemical use. In at least one ment the production is coupled to a monitor device which measures quantity produced, and/or product quality.

As described earlier, the tion of a halogenated amine disinfectant (for example chloramine) utilizes an amine source, an oxidizing halogenated compound and a diluent rably water) as chemical components. The concentration of the amine source in the concentrate form of the solution can range from 5% i 80% and in the dilute form it can range from 0.01% - 5%. Similarly, the concentration of the oxidizing halogenated composition in the concentrated form can range from 3% - 18% and in the dilute form it can range from 0.01% - 3%. From the perspective of blending ratio between the reactants, the molar ratio can range from 0.1:1 (N: C1) to 10:1 (N:Cl). The ratio at which blending optimizes the ion of chloramine will determine the ﬂow rates of the reactant in on to time (invented method #1 above) or in relation to the ﬂow rate of the diluent (invented method #2 . The need for pH control at the time of blending may be achieved through the addition of other chemical components, for example caustic or an acid, or other means.

Among other reasons, this invention is superior to the prior art because it s in a form of stabilized-chlorine that has enhanced persistence of chlorine in fouled water systems thus providing for improved biofouling control.

The invention also moots the need for uous operation of the PCT/U52012/056567 chloramine feed system. Also, since the chloramine is produced in a dilute batch mode, the equipment required for production is simpliﬁed and the need for expensive, compatible materials is reduced. This also results in a safer system as there is no danger of a “runaway” reaction in controlled batch production that exits in continuous reactions.

The lled nature of the reaction also allows for precise dose changes in response instant changes in the reaction conditions.

The chloramine can be produced in a batch mode and then be dosed continuously or intermittently into the system being treated. This method also provides the ability to ically deliver shock doses at much higher concentrations than would normally be applied and then allowing the chlorine residual to decay prior to uent lrealmenl. Application of chloramine in such a shock dose regime provides for more persistent and widely distributed chlorine residual. ed persistence of chlorine allows for better control over microbiological populations that may not be tely controlled at lower ne doses or that may tend to develop as ‘resistant‘ populations.

In at least one embodiment the chloramine is added according to an ronous mixing process. Unlike for example in US Patents 6,132,628 and ,976,386 the ronous mixing of the reagents is more likely to result in the particular formulation ideal for g the particular organism present happening to result and it also creates a dynamic environment which makes it difficult for organisms to adapt to. Such a moving target allows for a more thorough biocidal effect.

In at least one embodiment the asynchronous mixing process is a batch process. The reagents are made in discrete batches and are blended and added for a discrete period of time.

In at least one embodiment the asynchronous mixing process is a PCT/U52012/056567 continuous process. The ﬂow of ts is not linked to a single blending. At any time there is an alternation of which reagents are fed. At some times all of the reagents are being fed and at other times some or none of the reagents are fed.

In at least one embodiment the ﬂow of reagents is inhibited and does not pass directly from the conduit in which it is mixed into the system to be treated. d the reagent ﬂow is stopped for a period of time in a tank or wide space for a period of time where at least some mixing occurs and only then do the reagents continue on to the system being treated.

In at least one ment, the chloramine is produced by the blending of an amine and chlorine (or bromine) source in a certain ratio. Chloramines provide for a more persi stenl chlorine residual in fouled water systems. Therefore, there are times when it would be beneﬁcial to not dose mine but to dose only one of the two reactants (amine source or the chlorine nd). The need for such a strategy will vary from one application to another. For example, in conditions where there is the likelihood of low halogen consumption, a periodic addition of the amine source alone (no halogen) will aid quenching the free hypochlorous acid, formed or introduced, and thereby reduce corrosion. NIinimizing free halogen also provides for ed compatibility with other chemicals that might be added to water systems, ing but not limited to th aids, retention or drainage aids, sizing chemicals, optical brightening agents, and dyes. Similarly, under conditions of high halogen , it would be prudent to periodically administer the oxidizing halogen alone (without amine) so that the halogen reduces some of the chlorine demand and improves the long-term persistence of the chloramine and chlorine residual in the water system.

In at least one embodiment the process water system being treated for 2012/056567 ial control e but are not limited to: cooling water systems, domestic water systems, boiler water systems, biofouling control or cleaning of RO membrane systems, in Food and Beverage applications such as flume water treatment, washing of fruits, salads and vegetables, treatment of waste water systems, ballast water systems, and paper, tissue, towel and board manufacturing processes, including machine chests, head box waters, broke , shower water etc.

In at least one embodiment the flow of at least one of the reagents is ed by a feeding mechanism. The feeding mechanism may be in informational communication with one or more forms of diagnostic equipment. The diagnostic equipment may e and transmit the measurement of such les as pH, temperature, amount of biological infestation, type of biological infestation, and concentrations of one or more compositions of matter. The measurement may be of any portion of the system to be d and/or in any portion of the feed line(s). In at least one embodiment at least one of the forms of diagnostic equipment is at least one form of equipment described in US Patent 7,981,679. In at least one embodiment the feeding mechanism is constructed and arranged to increase, decrease, or cease the ﬂow of at least one reagent in response to receiving at least one transmitted measurement.

In at least one embodiment the asynchronous flow of reagents is accomplished according to a “slug dose” strategy. In a slug dose the feeding alternates between low or non doses of one or more reagents and then concentrated gs. For example over a 24 hour period extending between hour 0 and hour 24, at some point between hour zero and hour 6 nothing is fed into the system, then for up to 6 hours bleach or ammonium sulfate is added, then for up to 6 hours both bleach and ammonium sulfate are added. In this regiment the concentration of free bleach free ammonium sulfate PCT/U52012/056567 chlorine and formed mine varies. The slug dose can be targeted to be in synch with the expected growth and tence of ular forms of biological infestation. In at leats one embodiment multiple slug doses can be fed per 24 hour period interspersed with periods of time in which nothing is fed to the system.

In at least one embodiment the asynchronous flow of reagents is accomplished according to a “continuous dose” strategy. In a continuous dose there is ntly some reagent being fed into the system but what and how much of each reagent changes. For example over a 24 hour period extending between hour 0 and hour 24, at some point between hour zero and hour 6 all of the reagents are fed into the system, then for up to 6 hours only bleach or only ammonium sulfate is added, then for up to 6 hours both bleach and ammonium sulfate are added. In this regiment the concentration of free bleach free ammonium sulfate chlorine and formed chloramine also varies. In addition the continuous dose can also be targeted to be in synch with the ed growth and persistence of particular forms of biological infestation. In at least one embodiment multiple doses of only bleach and/or only ammonium e can be fed per 24 hour period interspersed with periods of time in which both are fed to the system.

While this invention may be embodied in many different forms, there bed in detail herein specific red embodiments of the invention. The present disclosure is an exempliﬁcation of the principles of the invention and is not intended to limit the invention to the particular ments illustrated. All patents, patent applications, scientiﬁc papers, and any other referenced materials mentioned herein are incorporated by reference in their entirety. Additionally, the invention also encompasses any possible combination of some or all of the various embodiments described and incorporated herein. rmore the invention also encompasses combinations in which PCT/U52012/056567 one, some, or all but one of the various embodiments described and/or incorporated herein are excluded.

The above disclosure is intended to be illustrative and not exhaustive. This description will suggest many variations and alternatives to one of ordinary skill in this art. All these alternatives and variations are intended to be included within the scope of the claims where the term "comprising" means "including, but not d to". Those familiar with the art may recognize other equivalents to the ic ments described herein which equivalents are also intended to be encompassed by the claims.

All ranges and parameters disclosed herein are understood to encompass any and all subranges subsumed therein, and every number n the endpoints. For example, a stated range of “"1 to 10” should be considered to include any and all subranges between (and inclusive of) the minimum value of l and the m value of 10', that is, all subranges beginning with a minimum value of l or more, (e.g. l to 6.1), and ending with a maximum value of 10 or less, (e.g. 2.3 to 9.4, 3 to 8, 4 to 7), and ﬁnally to each number 1, 2, 3, 4, 5, 6, 7, 8, 9, and 10 contained within the range.

This completes the description of the preferred and alternate embodiments of the invention. Those skilled in the art may recognize other equivalents to the specific embodiment bed herein which equivalents are intended to be assed by the claims attached hereto.

Claims

1. A method of producing stable disinfectant for use as a biocidal composition in a process water system, the method comprising the steps of: providing items, the items consisting of: 5 a) an amine source in concentrated form, b) an oxidizing halogen compound in concentrated form, and c) water creating an amine-free flow of water through a first feed; asynchronously feeding the halogen compound in a trated form into the first 10 feed line; when it is determined that the halogen demand of the process water system is such that the oxidizing halogen compound alone will not operate as an effective biocidal composition, asynchronously feeding the amine source in a concentrated form via a halogen-free second feed line into a wide space such that the concentrated amine, 15 concentrated n, and water come into contact and mix with each other in the wide space wherein the wide space is a tank constructed and arranged such that it has a diameter larger than both the first and second feed lines and the transition from the first and second feed lines to the tank is not streamlined and thereby the flow from the first and second feed lines results in eddies which mixes the items so 20 that for a time when the halogen is not fed into the tank there is still ing n in the tank mixing with remaining amine whose reaction products are formed and fed into the s water system thereby creating a dynamic and widely distributed chlorine residual; and when it is determined that the halogen demand is low adding amine source and not 25 adding n compound to the wide space thereby quenching free hypochlorous acid in the process water .

2. The method of claim 1 n the amine source is chloramine.

3. The method of claim 1 wherein the tration of the amine in concentrated form is in the range from 5% - 80% and after it is mixed with the water the 30 concentration of the amine drops to 0.01% - 5%.

4. The method of claim 1 wherein the concentration of the oxidizing halogen compound in concentrated form is within the range of 3% - 18% and after the oxidizing halogen is mixed with the water the concentration of the oxidizing halogen drops to 0.01% - 3%. 35

5. A method of claim 1, wherein the molar ratio of amine to oxidizing halogen is within the range of 0. 1 : 1 to 10: 1.

6. The method of claim 1 wherein the oxidizing halogen is a chlorine source.

7. The method of claim 1 wherein the oxidizing halogen is sodium hypochlorite.

8. The method of claim 1 n the flow is passed according to a batch process. 5

9. The method of claim 1 wherein the flow is passed ing to a continuous dose process.

10. The method of claim 1 wherein the flow is passed according to a slug dose process.

11. A method of claim 1, wherein the molar ratio of amine to oxidizing halogen is 10 within the range of 7:1 to 10:1.