The present invention relates to systems and methods for cleaning and maintaining apparatus for cooling air by evaporation of water.
Air conditioning and industrial cooling systems typically make use of cooling towers to cool process water and reject unwanted heat into the atmosphere. While cooling towers of various types may be utilized, wet (or evaporative) cooling towers are generally more efficient at heat removal, and accordingly are quite common in commercial and industrial applications. Such wet cooling towers generally cascade heated water over a “fill” material that provides a large wetted surface as an enhanced water-to-air interface, allowing for increased evaporation and heat transfer. Cooled process water is collected beneath the fill while heated, saturated air is expelled from the tower, usually via mechanical means such as a fan.
Even when the process water is filtered or treated, however, the fill material often becomes fouled with scale deposits and/or biological growth, both of which greatly diminish the ability of the cooling tower to efficiently transfer and expel heat.
In the prior art, proper cooling tower maintenance accordingly often includes a pre-rinse of the fill followed by application of chemical cleaners or inhibitors sprayed onto the fill material, and then a final rinse or wash of the fill to remove chemical residue along with dislodged and/or dissolved scale or biological materials. Such maintenance typically includes use of a specialized chemical sprayer to appropriately apply the chemical agents, followed by utilization of a high-pressure power-washing device to rinse and remove debris from the fill material.
The present invention is directed to improved systems and methods for cleaning fill in a cooling tower. In addition to the procedure described hereinabove, steps are added wherein a) the fill is treated with an acidic or alkaline solution to promote descaling of the fill; b) the pH of the acidic or alkaline solution is monitored and adjusted to provide an optimum pH level; c) the pH of the fill surface is neutralized by treatment with a neutralizer after the acidic or alkaline treatment; the fill is treated with a biofilm disruptor, also referred to in the art as a disinfectant or sanitizer. Optionally, a cooling tower may be sprayed with a mold suppressor, which may be a biofilm disruptor, disinfectant, or sanitizer, before initiating the recited methods for cleaning the fill; further, cleaning tower process water may be drained and sludge vacuumed from the water reservoir; and still further, after all the cleaning steps, the water reservoir is refilled or topped up and preferably a biocide is added to control growth of Legionella and other bacteria.
The present invention will now be described, by way of example, with reference to the accompanying drawings, in which:
Throughout the following description, specific elements are set forth in order to provide a more thorough understanding of the invention. However, in some embodiments the invention may be practiced without some of these elements. In other instances, well known elements have not been shown or described in detail to avoid unnecessarily obscuring the disclosure. Accordingly, the specification and drawings are to be regarded as illustrative rather than restrictive. It is to be further noted that the drawings may not be to scale.
Embodiments described herein generally relate to chemical gel cleaning formulations for cooling tower fill (e.g., vertical surface) cleaning operations, and systems and methods for utilizing such chemical gel formulations to effectuate cooling tower fill (e.g., vertical surface) cleaning activities. While the term “gel” is utilized herein for ease of description, it should be understood that in one or more states and/or environments, the chemical cleaning/treatment formulations described herein may comprise liquids and/or gels as is or becomes desirable or practicable. The term “gel” is generally utilized herein to refer to a chemical cleaning/treatment formulation that is amenable to being sprayed onto a surface to be cleaned and exhibits certain changes in viscosity and/or effervescence upon application, as described in detail herein. Further, while the “gel” may be sprayed upon a surface to be cleaned as described herein and the surface may comprise or contain other substances such as water and/or calcium carbonate, in some embodiments the application of the gel to the surface and the resulting combination or mixture of substances (e.g., the “gel”, the water, and/or the calcium carbonate) and/or reactive components or byproducts thereof may be continually referred to as the “gel”, for ease of description.
In some embodiments, chemical gel formulations may comprise a mixture of ingredients that combine to provide a viscosity that, when applied to, for example, a vertical surface (and/or a surface angled at greater than two degrees (2°) from the horizontal) and/or cooling tower fill in need of cleaning, tends to promote an optimal retention time of the formulation on the surface so that its active ingredients, in turn, can provide optimal cleaning performance. In one or more embodiments, the viscosity promoting optimal cleaning performance may be achieved when the chemical gel formulation comes into contact with, and is diluted by, residual water on the vertical surface (e.g., residual water from a pre-rinse of the fill surface). For example, in some embodiments, the chemical gel formulation may have a thinner viscosity (e.g., ten to fifty centistokes (10-50 cSt)) before it is applied to a wet surface, and upon exposure to the wet environment and/or the undesirable deposits on the fill surface, the chemical gel formulation may thicken and become more viscous, for example between one hundred and three hundred centistokes (100-300 cSt)). In embodiments where the chemical gel transforms from a gel or fluid state (e.g., upon application such as spraying) to a foam or froth state (e.g., upon reaction with surface components such as water and/or scale as described herein), the utilization of the term “viscosity” may refer to the differences in the ability of the different states to resist shear stress such as the ability to sustain on a vertical surface. In some embodiments, for example, the foam/froth state may have a greater ability to sustain on the vertical surface than the originally sprayed “gel”. According to some embodiments, this increase in “viscosity” or ability to dwell on the vertical surface for longer periods may be imparted due to surface tension forces provided by the foam/froth resultant from the reaction of the gel (or components thereof) with materials of the sprayed surface (e.g., water and/or scale).
Throughout this disclosure, water will be used as an exemplary solvent as it is a common residual solvent present on the surface of cooling tower fill (because of either or both of normal operations and a pre-rinse thereof). A person of ordinary skill will understand that water, as used herein, is an exemplary residual solvent. Chemical gel formulations can be made to perform similarly or identically with other organic or inorganic residual solvents present on (and/or applied to) a cooling tower fill and/or vertical surface to be cleaned.
Lower viscosity (e.g., approximately the same viscosity of water, or one centistoke (1 cSt)) chemical formulations, when applied to a surface in need of cleaning, have certain advantages over higher viscosity liquids and/or gels. For example, a lower viscosity liquid is easier to spray, and produces less backpressure that would otherwise result from spraying a higher viscosity liquid/gel. Moreover, a lower viscosity liquid may be sprayed in a more efficient manner and may result in less waste and better cleaning performance. For example, a lower viscosity liquid may be sprayed further, and thus may permit easier access of cleaning to remote sections of cooling tower fill. This is especially advantageous when cleaning fill that includes various increased surface area features, for example, multiple bends, curves and other complex structures (e.g., honeycomb features) used to increase the surface area of the fill so that it is able to exchange heat effectively and efficiently.
A lower viscosity liquid may also be advantageous in that it may penetrate deeper into the undesired deposits residing on a surface in need of cleaning. For example, a less viscous formulation may be less likely to reside on the surface of deposits, and more likely to sink into and penetrate microscopic accretion and pitting created by the accumulation of undesired deposits, such as calcium carbonate. This allows deposits to be removed from the surface in need of cleaning with greater efficacy and efficiency, as the descaling process is allowed to proceed at the top layer of the surface and thus the base of the deposits.
On the other hand, a lower viscosity chemical formulation when applied to a given surface has certain disadvantages. For example, low viscosity liquids may not have optimal retention time, for example, on vertical surfaces (e.g., vertical fill surfaces and/or portions of cooling tower fill surfaces that are oriented at an angle to the horizontal—e.g., to promote cooling water flow and/or cascading). For example, a low viscosity liquid (and/or gel) may easily become separated from and fall off a vertical/angled surface due to the pull of gravity. Due to such decreased dwell or “hang” time on a vertical/angle surface, lower viscosity formulations must typically include higher concentrations of acid to allow for desired effectiveness of scale and/or biofilm removal. Higher concentration acids, however, increase occupational hazards in application, particularly in the case that they are sprayed in a pressurized, low viscosity liquid formulation. Low viscosity liquid formulations are subject to misting, for example, which can result in a high concentration acid mist that may have high mobility from and around an application site. As many cooling towers are on top of buildings and/or in highly populated areas (e.g., city rooftops), acid misting is not a desirable occurrence.
Higher viscosity liquids or gels may not suffer the same issues because increased viscosity may have the effect of increasing retention times of the chemical gel formulation on the vertical/angled surface and may eliminate the potential for misting. Thus, higher viscosity liquids/gels will allow the reactive ingredients present within a cleaning formulation to remain on the vertical/angled surface for longer periods of time, thereby optimizing the chemical gel's cleaning performance even at lower acid concentrations. Moreover, the increased retention time of higher viscosity formulations minimizes the need to apply repeated coats of a cleaning formulation, as a single coat may be all that is necessary to perform the task of removing undesirable deposits. In practice, however, thicker formulations also experience deficiencies. Higher viscosity liquids/gels generally impede transport of dissolved scale and/or other deposits, for example, and tend to leave a residue on vertical/angled surfaces such as cooling tower fill—the residue being undesirable, as it gives the appearance of an incomplete cleaning application (and may even impede cooling tower performance). Further, higher viscosity formulations tend to encapsulate and/or inhibit reaction of the active ingredients with deposits on the vertical/angled surface to be cleaned. A portion of the high viscosity formulation will react with the surface and, in the case of an acid reacting with a calcium carbonate scale deposit for example, will off-gas carbon dioxide. The carbon dioxide will create bubbles adjacent to the surface and in the case of a high viscosity liquid/gel, the viscosity of the formulation may prevent the carbon dioxide from transporting through the formulation, impeding additional active ingredients from reacting with the surface—as the gaseous bubbles form a barrier preventing physical contact of the active ingredients with the deposits on the surface.
While foam formulations have been attempted in an effort to move away from the problems experienced by each of the low viscosity liquids and the high viscosity liquid/gel formulations, such formulations have also experienced limited success due to operational difficulties. Foam formulations necessarily have lower acid concentrations, for example, and accordingly are less effective at removing scale deposits. While their increased dwell time offsets this inefficiency somewhat, as foam is light and presents high surface area by nature, it is highly susceptible to being transported by breezes and/or during rinse-off or power washing processes.
Accordingly, several novel embodiments of the chemical gel formulations described herein combine various advantageous properties of both lower viscosity and higher viscosity formulations. For example, as disclosed herein, a lower viscosity gel formulation may thicken to a higher viscosity formulation (and/or change to a foam or froth state) upon contact with a surface in need of cleaning and accordingly may exhibit multiple cleaning advantages over formulations that have either lower or higher viscosity, such as in the case that a surface is exposed to outdoor conditions (e.g., exterior walls of a surface in need of cleaning that may be exposed to outdoor elements). In one or more embodiments of the chemical gel formulations described herein, one or more desirable characteristics of the lower viscosity liquids (e.g., for increased spraying and penetration) may be combined with one or more desirable characteristics of a higher viscosity liquid/gel (e.g., increased retention time and cleaning potential). Further, in some embodiments, the novel chemical gel formulations described herein may reduce or eliminate the reactive encapsulation effect of higher viscosity formulations, providing for a more efficient and effective cleaning solution.
Creating a chemical gel formulation that thickens and/or foams/froths upon contact with a surface for cleaning can be achieved in many ways, and the following examples are not provided to limit the scope of the embodiments herein, but rather to provide examples of how such formulations may be created. The method or process of creating a formulation that thickens upon contact with a given surface can be achieved in a variety of ways. For example, in some embodiments, the viscosity of a chemical gel formulation may be increased upon its application to a surface in part by the evolution of gas created by the active ingredients reacting with the undesirable deposits; for example, certain acidic active ingredients may react with calcium carbonate deposits on a surface for cleaning, and the off-gas may be combined with the gel carrier of the formulation to create a foaming effect. Thus, in accordance with one or more embodiments, a chemical gel formulation may be formulated in a manner that it becomes more viscous as it is permeated by effervescence from the reaction of the active ingredients with undesirable deposits on the surface in need of cleaning, thereby creating a higher viscosity foam with optimal retention times, for example, on vertical and/or angled surfaces.
Examples of acidic active ingredients that may be used in chemical gel formulation disclosed herein include citric acid, hydrochloric acid, sulfuric acid, sulfurous acid, phosphoric acid, phosphorous acid, nitric acid, nitrous acid, hydrobromic acid, bromous acid, hydroiodic acid, perchloric acid, chloric acid, boric acid, acetic acid, formic acid, oxalic acid, pyruvic acid, malonic acid, malic acid, tartaric acid, propanoic acid, lactic acid, succinic acid, and carbonic acid. According to some embodiments, the chemical gel formulation may comprise a combination of phosphoric acid, hydrochloric acid, and citric acid present in a percent weight of the final formulation.
It has been found that chemical gel formulations comprising certain combinations and amounts of acids have provided surprising, unexpected, and advantageous results over other formulations. For example, it has been found that the combination of citric, phosphoric, and hydrochloric acids may provide optimal cleaning performance when compared to other acid combinations. Specifically, it has been found that a formulation may comprise a combination of citric, phosphoric, and hydrochloric acids at a ratio of 11:9:3.5 to provide superior cleaning properties (e.g., desirable dwell time and scale penetration levels), however the phosphoric acid and citric acids may be added in a range of about 5-40% by weight of the final formulation, and hydrochloric acid may be added in a range of about 1-36% by weight of the final formulation. The combination of these acids also provides a surprising advantage over other cleaning formulations by creating a protective sheen or glaze on the cleaned surface, thus helping to protect the cleaned surface from the accrual of future deposits, thereby significantly increasing the cleaning performance of the chemical gel formulation.
In other embodiments, chemical gel formulations that thicken and/or foam/froth upon application to a surface for cleaning may comprise ingredients that react with water, and thus effervesce or otherwise react in the presence of residual water residing on the surface. Examples of ingredients that may react with water to effervesce including alkali metals, alkaline earth metals, carbides, hydrides and anhydrides. For example, in some embodiments, sodium hydride or butyllithium may be utilized as ingredients that react with water and effervesce to increase the viscosity of the chemical gel formulation upon application to a wet surface.
Chemical gel formulations that increase in viscosity and/or foam/froth upon application to a surface may also or alternatively be made through other means, for example, through the addition of water insoluble ingredients that precipitate and thicken upon contact with water. For example, hydrophobic compounds such as oils, parabens, waxes, or other water insoluble organic or inorganic compounds may be used to precipitate and thicken upon application to a wet surface, thus increasing the viscosity of a chemical gel formulation. In other embodiments, one or more ingredients that react with each other in an aqueous environment may be added to a chemical gel formulation to increase its viscosity when applied to a surface for cleaning. In still other embodiments, the viscosity of the chemical gel formulation may be increased by adding a water-absorbent ingredient, for example polymers, that swell creating a more viscous formulation upon contact with residual water on a surface in need of cleaning.
A chemical gel formulation, in accordance with multiple embodiments disclosed herein, may be formed of ingredients that may be altered to achieve a desired viscosity both pre- and post-application to a surface in need of cleaning. According to some embodiments, the individual ingredients comprising the chemical gel formulation may be solid, semi-solid or liquid at ambient temperature, so long as the combination of these ingredients achieves a desired viscosity when applied to a surface for cleaning. For example, in one or more embodiments, glycerin, which may be used as a carrier for the chemical gel formulation, may be thickened to a desired viscosity using one or more polysaccharides. Polysaccharides that may be used for thickening the glycerin carrier may include, without limitation, starch, glycogen, cellulose, chitin, or any combination of these or other polysaccharides. In some embodiments, while the carrier glycerin (or thickened glycerin) may reduce viscosity upon introduction to residual water on the surface to be cleaned, this initial reduction in viscosity upon application of a chemical gel to a wetted surface may be counteracted by enhanced transport of the acids to the scaled surface.
Enhanced transport of the acids may, for example, increase foaming and/or froth action due to reaction with scale, and the resulting foam/froth mixture may comprise surface tension forces that provide a greater ability of resultant mixture/froth to dwell on the vertical surface. In some embodiments, this increased dwell time may be provided by the increased viscosity/froth action while allowing transport of off-gassing to prevent reactive encapsulation experienced with higher viscosity cleaning substances.
One or more embodiments of chemical gel formulations disclosed herein may comprise one or more corrosion inhibitors. A corrosion inhibitor is a chemical ingredient that may be applied to a surface to decrease the corrosion rate of that material. The materials typically treated with corrosion inhibitors are metals and alloys, but other types of materials may also or alternatively be treated. Corrosive inhibitors that may be used in chemical gel formulations include, for example, free radical scavengers, antioxidants, anodic inhibitors, cathodic inhibitors, tolytriazole, sodium molybdate, or any combination thereof.
Several embodiments of chemical gel formulations discussed herein may comprise one or more surfactants. Surfactants used as ingredients in chemical gel formulations disclosed herein include, without limitation, organic surfactants, inorganic surfactants, ionic surfactants, non-ionic surfactants, cationic surfactants, anionic surfactants, amphoteric surfactants, polymeric surfactants, or any combination of these or other known surfactants.
Some embodiments of chemical gel formulations described herein may comprise one or more biofilm disruptors. A biofilm is residue consisting of organic and inorganic elements and compounds that naturally occur on surfaces that are exposed to moisture-laden environments. For example, biofilm may comprise a layer of slime resulting from bacterial growth and waste products. Sometimes biofilms may further comprise a layer of inorganic salts and minerals deposited, for example, by hard water. Biofilm disruptors may be used to dissolve these organic and inorganic residues. Many different types of biofilm disruptors are known in the art and may be used in chemical gel formulations in accordance with embodiments described herein. For example, biofilm disruptors that may be utilized include (but are not limited to) acids, bases, surfactants, polymers, film-forming ingredients, oxidizing agents, phosphate-containing ingredients, chlorine-containing ingredients, carbonates, and alkylalkoxylates. In some embodiments, one or more dyes, perfumes, and/or other non-reactive components may be added to the chemical gel as desired.
Referring now to
According to some embodiments, the valve 116 may also or alternatively be coupled to a second pump 130. In some embodiments, the second pump 130 may comprise a low-flow and/or low-pressure pump coupled to draw and/or direct a cleaning agent and/or formulation (not explicitly shown) from a chemical gel canister 138. According to some embodiments, the chemical formulation may be drawn through a chemical flow valve assembly 140 and directed through the cleaning wand 110 and the spray nozzle 112, to the surface 102. In some embodiments, the valve 116 may be selectively operable to switch between chemical formulation flow and wash fluid flow, and/or may be selectively operable to vary a ratio of chemical formulation and wash fluid in a combined flow stream. According to some embodiments, the cleaning wand 110 may be selectively coupled to accept either or both chemical flow and cleaning of cooling tower components such as cooling tower fill disposed as a vertical/angled surface. The system 100 may, for example, be utilized to direct a novel chemical gel formulation (as described herein) from the chemical gel canister 138 and onto the surface 102, and/or to perform such directing in coordination with various rinse and/or wash activities. According to some embodiments, various components of the cleaning system 100 may be coupled to a wheeled cart (not shown) or may otherwise be provided as a “mobile” cleaning apparatus as disclosed in the incorporated '330 patent. The cleaning wand 110, the spray nozzle 112, the valve 116, the reservoir 120, the first pump 126, the second pump 130, the chemical gel canister 138, and/or the chemical flow valve assembly 140 may, for example, be coupled to and/or housed by a mobile frame (not shown) with attendant houses, couplings, and/or fittings (also not shown).
Referring to
The method 200 may, in some embodiments, comprise rinsing the fill surface with an aqueous solution, or other acceptable rinse/wash solution, at 202. Cooling tower fill material may be wetted, for example, as a pre-rinse procedure such as to remove any easily dislodged deposits on the surface and to treat for mold. According to some embodiments, the pre-rinse may be effectuated with either a low-flow, low-pressure pump or a high-flow, high-pressure pump of a portable cooling tower cleaning apparatus. The pre-rinse may, for example, comprise pressurized water being directed from the reservoir 120, via the valve 116, and through the cleaning wand 110 and the spray nozzle 112 and onto the surface 102, by the first pump 126, all of
In some embodiments, the method 200 may comprise applying a chemical gel formulation to the fill surface, at 204. The chemical gel formulation may, for example, comprise an initially low viscosity gel (e.g., approximately ten centistokes (10 cSt)) that is sprayed onto the surface. In some embodiments, as described herein the chemical gel formulation may comprise a mixture of three acids entrained in a water-soluble transport mechanism (e.g., glycerol). The acid mixture may be released to interface with deposits on the fill surface as the glycol is dissolved by residual water/rinse agent on the surface. In some embodiments, the chemical gel formulation may generate a thickened froth or localized foam that increases the overall viscosity of the applied formulation as the acid mixture interfaces with and produces off-gassing from the deposits on the surface. In some embodiments, the application of the chemical gel formulation may comprise the chemical gel formulation being drawn from a chemical canister 138 and directed, via the valve 116, through the cleaning wand 110 and the spray nozzle 112 and onto the surface 102, by the second pump 130, all of
According to some embodiments, the method 200 may comprise allowing the chemical gel formulation to dwell on the fill surface, at 206. The chemical gel may be allowed to reside on the surface of the fill being cleaned for a predetermined amount of time. The predetermined amount of time may vary on the specific application for which the chemical gel formulation is being used. For example, in some applications, it may be advantageous to allow the gel to reside on the surface for cleaning for several minutes, while in other applications, it may be desirable to let the gel reside on the surface for several hours. In cooling tower cleaning operations with typical operational fouling, the chemical gel formulation may be left to act upon the surface for a minimum dwell time of one (1) hour.
In some embodiments, the method 200 may comprise agitating the fill surface, at 208. According to some embodiments, the agitating may comprise a rinsing of the fill surface, such as to remove any residual cleaning formulation and/or dissolved deposits. In some embodiments, the agitating may comprise a mechanical, hydraulic, sonic, and/or other agitation of the treated surface. The agitation may, for example, comprise pressurized water being directed from the reservoir 120, via the valve 116, and through the cleaning wand 110 and the spray nozzle 112 and onto the surface 102, by the first pump 126, all of
In some embodiments, an agitated pressure rinse/wash of the treated surface removes residual chemical gel formulation components and dislodged and/or dissolved deposits from the fill surface. In some embodiments, after rinsing, the fill may be imparted with a sheen or shine as a result of the action of the acid mixture (or a portion thereof, such as citric acid in the case that it is utilized) on the fill surface. Fill surfaces are often constructed from Poly-Vinyl Chloride (PVC) synthetic plastic polymer and formed in honeycomb sheets, which are often black in color. In some embodiments, the novel chemical gel formulation(s) disclosed herein may act upon and darken the fill surface leaving the surface shiny and black, which provides an expedient indicator of a properly cleaned surface (e.g., as opposed to a black surface with residual residue white residue from utilization of higher viscosity gel cleaners).
According to some embodiments, the method 200 may optionally comprise neutralizing 210 the chemical gel formulation. In some applications, for example, such as in the case that the reaction of the formulation with the surface and/or deposits thereof is desired to be ended, a neutralizing agent may be applied (e.g., a base). In some embodiments, the neutralizing 210 may be conducted in place of the rinsing. In such a manner, for example, water usage may be decreased for the overall cleaning operation. According to some embodiments, the neutralizing may be accomplished in addition to or as part of the rinsing at 212. The rinse/wash fluid may comprise an aqueous mixture or solution comprising a neutralizing agent and water, for example, sprayed on the fill surface to both dislodge or remove and neutralize any residual chemical gel formulation on the fill surface. This process is described more fully in the incorporated '765 patent, titled “DESCALING SYSTEM FOR HEAT EXCHANGE EQUIPMENT”, wherein the apparatus may be adapted for applying a neutralizing agent in accordance with the present invention.
Referring now to
Machine housing 318 is a shell defined by upright front 318a, side 318b and rear walls with closed bottom wall (not visible in
The housing interior positions a main pump (not visible) for circulating a neutralizing solution through the system, and a chemical pump for adding neutralizer chemical to the neutralizing solution. Electrical components for pump operation and control and monitoring of neutralizing progress are also located within the housing.
Housing front wall 318a has a built-in control panel 328 defined by supporting walls and a control dashboard panel 330 inclined from front wall 318a for convenient positioning of machine control switches and indicators for operator use. The control panel also mounts a pH controller 332 for embodiments of the invention described in detail below.
A side wall 318b of the housing has opening 318b′ for access to a system circulating line for positioning a pH sensor to monitor progress of a neutralizing operation applied to a given cooling tower. A pH sensor is fitted to feed line 314 for sensing pH value of neutralizing solution flowing to a cooling tower 315. The sensor provides a reading and corresponding signal to the pH controller 332. The pH controller operates the chemical pump for adding neutralizer chemical to the solution as necessary to ensure that neutralizing continues as long as desired.
The neutralizing system in accordance with the present invention uses a chemical consisting of varying concentration of either an acidic or alkaline chemical in water. In operation, the chemical is diluted with water and circulates through the cooling tower. In accordance with the present invention, progress of a neutralizing operation is determined by monitoring 214 the pH value of circulating solution and comparing monitored value with a normal or optimum pH value selected and set in a pH controller. As monitored pH rises above normal pH value while neutralizing solution is circulating through a cooling tower, residual chemical gel cleaning composition if being removed from fill surfaces. The pH controller compares monitored and normal pH values and uses the difference between values for operating the chemical pump to add chemical solution to circulating neutralizing solution. As neutralizing occurs, monitored pH value rises with respect to normal value, and neutralizer chemical is added to circulating solution restore potency and to lower monitored pH to normal level. When monitored and normal pH values coincide, surface neutralization is completed. At this point, the cooling tower fill may be rinsed 212 with water to complete the cleaning process.
In some embodiments, a chemical gel cleaning formulation for cleaning vertical/angled fill surfaces of cooling towers may comprise: (i) glycerine; (ii) at least one polysaccharide; (iii) at least one corrosion inhibitor; (iv) at least one surfactant; and/or (v) at least one acid. According to some embodiments, the chemical gel has a first viscosity, and when applied to a surface in need of cleaning, the chemical gel achieves a second viscosity greater than the first viscosity. In some embodiments, the at least one corrosion inhibitor may comprise tolytriazole. In some embodiments, the at least one corrosion inhibitor may comprise sodium molybdate. In some embodiments, the at least one corrosion inhibitor may comprise tolytriazole and sodium molybdate. In some embodiments, the at least one surfactant may comprise an ionic surfactant. In some embodiments, the at least one surfactant may comprise a non-ionic surfactant. In some embodiments, the at least one surfactant may comprise an anionic surfactant. In some embodiments, the at least one surfactant may comprise a cationic surfactant. In some embodiments, the at least one surfactant may comprise an amphoteric surfactant. In some embodiments, the at least one surfactant may comprise a polymeric surfactant. In some embodiments, the first viscosity of the chemical gel at ambient temperature may be about 10 to 50 centistokes. In some embodiments, the first viscosity of the chemical gel at ambient temperature may be about 25 to 45 centistokes. In some embodiments, the first viscosity of the chemical gel at ambient temperature may be about 30 to 40 centistokes. In some embodiments, the first viscosity of the chemical gel at ambient temperature may be about 35 centistokes. In some embodiments, the chemical gel cleaning formulation may further comprise at least one biofilm disrupter. In some embodiments, the at least one biofilm disrupter may comprise an acid. In some embodiments, the at least one biofilm disrupter may comprise a base. In some embodiments, the at least one biofilm disrupter may comprise a surfactant. In some embodiments, the at least one biofilm disrupter may comprise an organic surfactant. In some embodiments, the at least one biofilm disrupter may comprise an inorganic surfactant. In some embodiments, the at least one biofilm disrupter may comprise a polymer. In some embodiments, the at least one biofilm disrupter may comprise a film-forming ingredient. In some embodiments, the at least one biofilm disrupter may comprise an oxidizing agent. In some embodiments, the at least one biofilm disrupter may comprise a phosphate-containing ingredient. In some embodiments, the at least one biofilm disrupter may comprise a chlorine-containing ingredient.
According to some embodiments, a process of using a chemical gel cleaning formulation to clean a vertical/angled surface of a cooling tower fill may comprise: (i) applying a pre-rinse fluid to the vertical surface; (ii) applying the chemical gel cleaning formulation onto the vertical surface, the chemical gel cleaning formulation comprising glycerin, at least one polysaccharide, at least one corrosion inhibitor, at least one surfactant, and at least one acid; (iii) allowing the chemical gel cleaning formulation to dwell on the vertical surface for at least one hour; and (iv) rinsing the vertical/angled surface to remove residual chemical gel cleaning formulation and dissolved deposits from the vertical surface. In some embodiments, the rinsing may comprise applying a rinse fluid to the vertical/angled surface via an oscillating spray nozzle. In some embodiments, the process may further comprise agitating the vertical/angled surface. In some embodiments, the agitating may comprise at least one of pneumatic, hydraulic, mechanical, and sonic agitation. In some embodiments, the process may further comprise neutralizing, after the allowing, the residual chemical gel cleaning formulation. In some embodiments, the pre-rinse fluid and the rinse fluid may comprise an aqueous solution comprising one or more of: (i) water; (ii) water and inorganic solutes; and (iii) water and organic solutes. In some embodiments, the applying of the pre-rinse fluid may be accomplished by utilizing a first pump of a portable cooling tower cleaning apparatus and wherein the applying of the chemical gel cleaning formulation is accomplished by utilizing a second pump of the portable cooling tower cleaning apparatus. In some embodiments, the first pump operates at a higher pressure and a higher flow rate than the second pump.
The present disclosure provides, to one of ordinary skill in the art, an enabling description of several embodiments and/or inventions. Some of these embodiments and/or inventions may not be claimed in the present application. Applicants may file additional applications to pursue patents for subject matter that has been disclosed and enabled but not claimed in the present application.
While the invention has been described by reference to various specific embodiments, it should be understood that numerous changes may be made within the spirit and scope of the inventive concepts described. Accordingly, it is intended that the invention is not limited to the described embodiments, but will have full scope defined by the language of the following claims.
Incorporated by reference herein in their entirety are U.S. Pat. No. 9,404,069, which issued on Aug. 2, 2016, and U.S. Pat. No. 10,030,216, which issued on Jul. 24, 2018, both of which are titled “SYSTEMS AND METHODS FOR COOLING TOWER FILL CLEANING WITH A CHEMICAL GEL”; and U.S. Pat. No. 8,926,765, titled “DESCALING SYSTEM FOR HEAT EXCHANGE EQUIPMENT, which issued on Jan. 6, 2015.