Abstract:
A system is disclosed for delivering hyper-concentrated chemicals in a ready to use non-concentrated state. The present invention affords users with the ability to dispense the hyper-concentrated chemicals in a safe electrical free environment as the system operates from fluid force. The present invention may work off a water supply being used as the primary power supply that is also used to dilute the hyper-concentrated chemical. The present invention may be configured for use in any number of environments, such as refineries, off-shore platforms, food processing facilities, agriculture facilities, and the like.

Description:
TECHNICAL FIELD 
     The present invention relates, in general to hyper-concentrated chemical delivery and dispensing systems, and more specifically to systems that can dispense hyper-concentrated chemicals in a ready-to-use non-concentrated state by diluting the hyper-concentrated chemical so that users are able to economically and efficiently use the hyper-concentrated chemical as if the hyper-concentrate was in a diluted/non-concentrated state. 
     BACKGROUND OF INVENTION 
     It is no surprise that the chemical and petrochemical industry and its various production facilities are dirty. The facilities, vessels, mixers, equipment, structures, and machinery utilized in these industries become covered with dirt, grease, grime, and various other types of waste during use. Thus, an enormous amount of time and money is spent cleaning the various types of waste and dirt generated in such an environment, such as refineries, offshore drilling platforms, dive support vessels, construction vessels, chemical production facilities and the like. 
     Due to the extent and severity of waste, dirt, grime, grease, and the like that accumulates in and around the facilities of the chemical and petrochemical industry, such as offshore platforms, oil refineries, chemical production facilities, storage tanks and holding vessels, substantial quantities of industrial cleaners and degreasers are continuously needed and purchased to clean the various components that make up these industrial facilities. Currently, the refineries and chemical production facilities acquire industrial cleaners and degreasers by purchasing the industrial cleaners and degreasers in a ready-to-use state wherein the cleaners and degreasers are in a non-hyper-concentrated state. In the non-hyper-concentrated state, these cleaners and degreasers have already been diluted with water. In such a diluted state, these types of cleaners and degreasers are ordered and transported to the various facilities in oversized bulk tanks, totes, or multiple drums. While purchasing the cleaners and degreasers in the oversized containers is a way to keep the industrial cleaners and degreasers on site, the mere size of the oversized drums, totes, or multiple drums is a problem. With the large oversized drums, totes, and tanks there is always a potential for a substantial chemical spill. In addition, the bulk tanks, oversized drums and totes also occupy a lot of space. Further, the disposal of the oversized bulk tanks, totes, and drums, once they are empty, is another disadvantage that the facilities have to deal with in obtaining industrial cleaners and degreasers in oversized drums, totes, or tanks. 
     Accordingly, a need exists in the art for a system that can dispense the needed industrial cleaners and degreasers without the cleaners and degreasers having to exist in the oversized bulk tanks, totes, or multiple drums while still delivering the same amount of cleaner and/or degreaser. Purchasing more cleaners and degreasers in smaller holding tanks is not the answer as the user is simply left with even more holding tanks, drums, or totes to dispose. 
     BRIEF SUMMARY OF THE INVENTION 
     The present invention is directed to a system and method for hyper-concentrated chemical delivery and dispensing. The system and method may comprise a primary liquid supply, such as water, a hyper-concentrated chemical, such as a solvent based cleaner that contains little to no water, a dispenser unit, a supply hose, an input hose, a mixing chamber, and an output hose. An input hose may supply the primary liquid supply water, to the dispenser unit, while a supply hose connects the hyper-concentrated chemical to the dispenser so that the dispenser unit may pull the hyper-concentrated chemicals into the dispenser to be transported to a mixing chamber so that a primary liquid, such as water, can be mixed with the hyper-concentrated chemical to achieve a user-desired ready to use chemical, such as a solvent based cleaner. 
     The dispenser unit of the present invention may be a pump capable of extracting various amounts of the hyper-concentrated chemicals from a hyper-concentrated chemical supply and then moving or displacing the hyper-concentrated chemicals into a mixing chamber/area where the hyper-concentrated chemical can be mixed with the primary liquid supply, which may be water, to create an appropriately user-defined ready-to-use chemical mixture. After the primary liquid supply and the hyper-concentrated chemicals are combined and/or mixed, the system may then discharge the ready-to-use mixture through an output hose such that a user may utilize the output hose to spray or discharge the ready-to-use mixture as needed. For example, a user may spray the ready-to-use mixture to the inside or outside of a tank that is to be cleaned with the ready-to-use mixture. 
     In a preferred embodiment, the entire hyper-concentrated chemical delivery and dispensing system is mobile and the system can be easily relocated from location to location depending on a user&#39;s needs. In such a mobile configuration, the system may be mounted on a stand that is configured to house the hyper-concentrated chemical below, next to, or near the dispensing components. Thus, when a user is ready to move the entire hyper-concentrated chemical delivery and dispensing system, the user simply disconnects the primary liquid supply and then moves the stand (possibly with the help of a forklift or dolly) to a desired location and only has to re-connect the system to a primary liquid supply, such as a new water supply, and then the system is ready for use. While the system is mobile, an embodiment of the present invention may be further configured so that the system can be easily moved by a user without the need to utilize outside assistance, such as the use of a forklift or dolly. In such an easy-to-move embodiment, the system may be mounted on some type of stand, cart, frame, or other structure with wheels whereby that stand with wheels includes room for the hyper-concentrated chemical to be located just below the dispensing unit so that all that is needed is a primary liquid supply, such as a water supply, in order for the system to operate. In such an easy-to-move embodiment, a user could then utilize the stand/cart on wheels to transport the easy-to-move system from location to location as needed for cleaning. For example, if the system were being used throughout an oil refinery for the purpose of supplying solvent based cleaners to clean tanks or other equipment, the easy-to-move system could be arranged so that the hyper-concentrated chemical is a drum of hyper-concentrated solvent-based cleaner and/or degreaser wherein a user could transport the easy-to-move system from location (tank) to location (tank). After transporting the easy-to-move unit, the user would hook up a water source to the input hose to provide the power/force needed to operate the dispenser/pump and to dilute the hyper-concentrated chemical to achieve a proper mixture. Then, the easy-to-move system with wheels could be relocated from one location to another as opposed to having to store large totes or tanks of cleaners and/or degreasers at every location the cleaner and/or degreaser would be used to clean equipment. As a result, less containers of cleaners and/or degreasers are needed thereby reducing the costs of purchasing and storing several large containers of cleaners and/or degreasers due to the use of the hyper-concentrate. 
     By utilizing the present invention, a user is able to save money through various aspects provided by the present invention. For starters, the hyper-concentrated chemicals that may be utilized with the present invention are preferably hyper-concentrated solvent based cleaners and/or degreasers that contain little to no water. Thus, a user saves money because the user would only have to purchase the hyper-concentrated chemicals as opposed to purchasing the ready-to-use chemicals which consist of large quantities of water. By purchasing hyper-concentrates and dispensing the hyper-concentrates with the present invention, the user is no longer paying for the water that is within the ready-to-use chemicals because the user will utilize his own water supply in conjunction with the present invention to convert the hyper-concentrate into a ready-to-use state. In purchasing hyper-concentrates, the containers holding the hyper-concentrates are significantly smaller and lighter than the over-sized drums and totes used to hold the ready-to-use chemicals. Thus, a user requires less storage space because the user no longer has to store several large ready-to-use containers of cleaners and/or degreasers. In addition, the transportation costs are decreased because the user is no longer utilizing the large oversized and heavy totes and containers of ready-to-use cleaners. For example, in offshore platforms, transportation costs are associated with all supplies and materials shipped to an offshore location. By utilizing the present invention, a user will be shipping less weight and require less storage space because the user can purchase and transport the hyper-concentrates in smaller and lighter containers, and the user can later convert the hyper-concentrates to a ready-to-use state with the present invention when needed. In the end, the user saves money through reduced storage space, reduced transportation costs, and reduced chemical costs because the user will ultimately use his own primary liquid supply, such as water, to achieve the desired ready-to-use chemical mixture. By utilizing the present invention, a user is no longer paying to transport, store, or purchase another&#39;s primary liquid, such as water, because the user will utilize his own primary liquid supply, water, when needed. 
     The foregoing has outlined rather broadly the features and technical advantages of the present invention in order that the detailed description of the invention that follows may be better understood. Additional features and advantages of the invention will be described hereinafter, which form the subject of the claims of the invention. It should be appreciated that the conception and specific embodiment disclosed may be readily utilized as a basis for modifying or designing other structures for carrying out the same purposes of the present invention. It should also be realized that such equivalent constructions do not depart from the invention as set forth in the appended claims. The novel features which are believed to be characteristic of the invention, both as to its organization and method of operation, together with further objects and advantages will be better understood from the following description when considered in connection with the accompanying figures. It is to be expressly understood, however, that each of the figures is provided for the purpose of illustration and description only and is not intended as a definition of the limits of the present invention. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       For a more complete understanding of the present invention, reference is now made to the following descriptions taken in conjunction with the accompanying drawings, in which: 
         FIG. 1  is an illustration of one embodiment of the present invention; 
         FIG. 2  is an illustration of various components of an embodiment of the present invention; 
         FIG. 3  is an illustration of a side view of an embodiment of the present invention; 
         FIG. 4  illustrates a close up top view of a portion of an embodiment of the present invention connecting to a hyper-concentrated chemical supply; 
         FIG. 5  is an illustration of a drum/container insert and some of the connections utilized in an embodiment of the present invention; and 
         FIG. 6  is another illustration of a drum/container insert connected to a drum containing the hyper-concentrated chemical 
     
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
       FIG. 1  is an illustration of one embodiment of chemical diluting and dispensing system  10 . In one embodiment, chemical diluting and dispensing system  10  provides an electrical free liquid flow powered dispensing system for diluting hyper-concentrated chemicals and delivering the diluted chemical mixture. Chemical diluting and dispensing system  10  includes enclosure  100  and stand  200 . Enclosure  100  houses and holds some of the various components that make up chemical diluting and dispensing system  10  as illustrated in  FIG. 2 , such as pressure regulator  110 , backflow preventer  120 , primary liquid hose  130 , pump supply hose  131 , chemical input hose  132 , chemical output hose  133 , pump output hose  134 , pump  140 , check valves  151  and  152 , mixing tee  153 , and connectors  156 ,  157 ,  158 ,  159 ,  160 ,  161 , and  162 . 
     Enclosure  100  may be fabricated from some type of weather resistant material, such as plastic, ABS (Acrylonitrile-Butadiene-Styrene) plastic, fiberglass, polycarbonate, steel, stainless steel, chrome, aluminum, and the like. As illustrated in  FIG. 1 , enclosure  100  is a weather-proof enclosure configured so that when the door of enclosure  100  is closed, the inside of enclosure  100  is sheltered from the surrounding environment such that the inside of enclosure  100  is protected from the surrounding environment and atmosphere, which may comprise any number of components, such as rain, heat, other liquids, chemicals, ice, hail, sleet, snow, fog, smog, smoke, and the like. In a preferred embodiment, enclosure  100  also includes a drain, preferably located in the bottom of enclosure  100 , that will allow any liquids, such as the hyper-concentrated chemical or primary liquid that may be leaking out of the various components within enclosure  100  to drain out of enclosure  100 . The drain also acts as a warning/indicator that can notify users of the existence of a leak by the mere fact that materials are flowing out of the drain. 
     Enclosure  100  is not limited to the configuration illustrated in  FIG. 1  as it may be arranged in any number of different configurations. For example, the door may be attached to enclosure  100  with the use of hinges located on any of the walls of enclosure  100 . Enclosure  100  may also be configured such that the door may connect to and/or attach to any of the walls of enclosure  100  with another type of securing mechanism such as a latch, screw, lock, clip, and the like. Thus, the door may secure to and completely close off enclosure  100  with the use of either said hinges or said securing mechanisms so that anything within enclosure  100  will be sheltered/protected from various components of the environment in which enclosure  100  is located. Enclosure  100  may also be configured so that it can be locked by a user to prevent unauthorized personnel from adjusting the settings of the various components within enclosure  100 , such as the settings of pump  140 . The use of such a lock to secure enclosure  100  provides an added safety and security feature to the present invention. 
     In one embodiment, enclosure  100  may be configured so that the outer surfaces of enclosure  100 , are coated with some type of insulating material that acts to insulate enclosure  100  from various conditions, such as temperature, noise, vibration, electrical shock, acid rain, biological organisms, weapons, and the like. For example, the outer surfaces of enclosure  100  may be coated with a ceramic coating to help insulate enclosure  100  and any components that may be mounted within enclosure  100  from these various conditions. 
     In a preferred embodiment, stand  200 , as illustrated in  FIG. 1 , is utilized to provide a mounting location for enclosure  100  and the components within the enclosure  100  and provides a resting location for the hyper-concentrated chemical container, such as bulk chemical supply  500 . While stand  200  is illustrated in  FIG. 1  as comprising different members made from metal Unistrut® members, the present invention is not limited to such configuration as stand  200  may be made of any number of materials configured in any number of different configurations. In some embodiments of the present invention, stand  200  may also be configured to include a holder that is capable of holding various objects, including, but not limited to a hose, such as hose  600  of  FIG. 1 , Such holder, may also be configured to hold any number of objects that may be utilized with the present invention, such as cleaning brushes, sponges, hose nozzles, spare hoses, and the like. With stand  200 , all components of system  10  may be either mounted to, resting on, or attached to stand  200  so that the entire hyper-concentrated chemical delivery and dispensing system is mobile and may be easily relocated from location to location depending on a user&#39;s needs. For example, a user can move stand  200  by simply disconnecting primary liquid supply at hose  101  and then utilizing a forklift, dolly, or the like to transport stand  200  from one location to another. While chemical diluting and dispensing system  10  is mobile, an embodiment of the present invention may be further configured so that the system can be easily moved by a user without the need to utilize outside assistance, such as the use of a forklift or dolly. In such an embodiment, the present invention may be configured so that wheels are added to stand  200  or wheels are added to a different type of stand, cart, frame, or other structure that can hold/house the components of system  10  so that system  10  is easy-to-move without the need for outside assistance. In such an embodiment, the stand/cart/frame with wheels includes room for the hyper-concentrated chemical to be located just below or near the dispensing unit so that all that is needed is a primary liquid supply, such as a water supply, in order for the system to operate. This easy-to-move embodiment is advantageous as it can allow a user to move system  10  from location to location depending on the user&#39;s needs. For example, if a user needed to clean a piece of equipment in a first location and also needed to clean a different piece of equipment in a remote location in a chemical processing plant, the user could simply transport the easy-to-move system with wheels from the first location to the remote location as opposed to having to store large totes or tanks of cleaners or degreasers at every location where the cleaner or degreaser would be used to clean equipment. The only thing needed when system  10  is moved from location to location whether in an embodiment with wheels or without wheels is a primary liquid supply/source at or near the location of use. If a primary liquid supply is not nearby, then a user can simply utilize a longer hose for hose  101  to bring the primary liquid supply, such as water, to system  10  if it were being used in a location that was not close to a primary liquid supply. 
     As illustrated in  FIGS. 2 and 3 , chemical diluting and dispensing system  10  may be configured so that some components of system  10  are positioned outside of enclosure  100 , such as valve  170 , output tee  154 , bucket tee  155 , connectors  163 ,  164 , and  165 . In addition, as illustrated in  FIGS. 1 and 2 , strainer  105 , shut-off valve  104 , nipple  103 , coupling  102 , and primary supply hose  101  may also be located outside of enclosure  100 . 
     Chemical diluting and dispensing system  10  is advantageous as it operates on liquid power/force to drive pump  140  which will in turn provide a pulling-up/suction force to pull/suction chemicals from bulk chemical supply  500  through chemical input hose  132 . As illustrated in  FIGS. 1 ,  4 , and  6  chemical diluting and dispensing system  10  sucks the hyper-concentrated chemical, such as a solvent/soap, from a bulk chemical supply  500 , such as a drum, barrel, tote, or the like. As illustrated in  FIGS. 4 and 6 , chemical input hose  132  is connected to bulk chemical supply  500  with coupler  300  and insert  400 . 
     As illustrated in  FIG. 5 , insert  400  includes adaptor member  410 , an inner threaded portion  415 , a color coded key member  420 , a color coded dot  425 , and a tube member  430 . As further illustrated in  FIGS. 4 and 5 , coupler  300  may be configured to include color coded cap  305 , vent valve  310 , threaded portion  315 , color coded key member  320 , tube member,  325 , and round handle  330 . 
     Insert  400  is advantageous as it provides a pathway for sucking/retrieving the hyper-concentrated chemicals out of bulk chemical supply  500 . Insert  400  provides another safety feature in that once an insert  400  is connected to and inserted into a hyper-concentrated chemical supply, such as bulk chemical supply  500 , it is not removed by a user. Thus, a user would not have to come into contact with the hyper-concentrated chemical as the user would not have to worry about removing insert  400  from the bulk chemical supply after it has been initially inserted by a supplier. Further, the present invention is configured so that the cost of insert  400  is minimal and insert  400  may be discarded with the empty drum/tote, such as bulk chemical supply  500 , to increase safety by eliminating the need for a user to have to remove insert  400 . As illustrated in  FIGS. 4 and 5  adaptor member  410  of insert  400  may be circular in shape and sized to fit inside a circular opening of bulk chemical supply  500 . However, the present invention is not limited so that adapter member  410  must be circular in shape, as some embodiments of the present invention may be configured with an insert  400  that includes an adapter member  410  that may take the form of any number of geometric shapes depending on the configuration, type, and/or shape of a chemical supply that insert  400  is placed inside. Inner threaded portion  415  is an area of insert  400  that is threaded to receive the corresponding threaded portion  315  of coupler  300  in order to provide a securing mechanism for securing coupler  300  to insert  400  to ultimately facilitate the transfer of the hyper-concentrated chemicals out of bulk chemical supply  500 . Color coded key member  420  is a keyed member that is preferably located below threaded portion  415  that acts to further secure and lock coupler  300  to insert  400  when a corresponding color coded coupler  300  is connected to insert  400 . Color coded dot  425  is a color coded piece of material preferably located on insert  400  to clearly identify the color coded configuration of insert  400 . It simply provides another color identifier in addition to color coded key member  420 . 
     Color coded key member  420  and color coded dot  425  assists users by identifying, signaling, and/or notifying users that only couplers  300  with matching corresponding color coded parts (such as color coded cap  305  and color coded key member  320 ) should be connected to insert  400  and bulk chemical supply  500 . This also assists in increasing safety and cutting back on mistakes and accidents by assisting users to only connect couplers  300  to inserts  400  with matching color configurations. In addition, a preferred embodiment of the present invention is configured so that only matching color coded key members of insert  400  and coupler  300  (key members  420  and  320 ) will connect to one another. For example, if a user accidentally tried to connect a coupler  300  with red color coded parts to an insert  400  with green color coded parts, the two would not connect or fasten to one another. For instance the corresponding keys of different colors ( 320  and  420 ) would not line up; thereby preventing a connection. 
     As illustrated in  FIG. 6 , tube member  430  of insert  400  is preferably a hollow cylindrical tube that extends down into bulk chemical supply  500  to provide a pathway for the hyper-concentrated chemical to be sucked up by pump  140 . Tube member  430  is not limited to any particular length as the length will be dictated by the configuration of the container holding the hyper-concentrated chemical. For example, as illustrated in  FIG. 6 , bulk chemical supply  500  is a barrel and in such an environment, tube member  430  will be long enough to reach the bottom of the barrel. In a preferred embodiment, tube member  430  is installed with a curvature so that when insert  400  is positioned in the bulk chemical supply  500 , the end of tube member  430  will be located at the bottom of the bulk chemical supply  500  that is opposite of the side where insert  400  is positioned in bulk chemical supply  500 . For example, in  FIG. 6 , insert  400  enters the right side of bulk chemical supply  500  so that tube member  430  extends into bulk chemical supply  500  and ends at or near the bottom left side of bulk chemical supply  500 . By extending to the opposite end of bulk chemical supply  500 , tube member  430  provides the benefit of enabling users to utilize a greater percentage of the hyper-concentrated chemicals in bulk chemical supply  500  before a user has to replace bulk chemical supply  500  with a new chemical supply. Such configuration of tube member  430  is further advantageous as chemical containers, such as a drum or barrel, that have less than a certain percentage of chemical remaining in the container after use may not have to be washed out prior to disposal or recycling. This helps to cut back on labor that would otherwise be spent washing out the containers. For instance, with tube member  430  in  FIG. 6  extending to the left bottom of the container, a user is able to utilize a greater percentage of the chemical thereby reducing the percentage of chemicals remaining in the container so that it is possible to dispose of and/or recycle the container without wasting time and resources spent washing out the container. 
     Coupler  300 , illustrated in  FIGS. 4 and 5 , functions to connect chemical input hose  132  to insert  400  thereby creating a path for the chemicals in bulk chemical supply  500  to reach pump  140 . In a preferred embodiment, coupler  300  contains color coded cap  305 , vent valve  310 , threaded portion  315 , color coded key member  320 , tube member,  325 , and round handle  330 . 
     Color coded cap  305  and color coded key member  320  are color indicators on coupler  300  to assist users in making sure that couplers configured with a particular color coded cap  305  and color coded key member  320  are only connected to inserts  400  that also contain matching color coded components, such as color coded key  420  and color coded dot  425 . Coupler  300  may also be configured with vent valve  310  that is utilized to provide venting for bulk chemical supply  500 . By providing a means of venting, vent valve  310  is advantageous as it operates to prevent any vacuum within bulk chemical supply  500  from collapsing whatever type of container that is holding the hyper concentrated chemical, such as the drum/barrel of bulk chemical supply  500  of  FIGS. 1 and 6 . As chemicals are drawn/sucked out of bulk chemical supply  500 , vent valve  310  may allow air to vent into the container (barrel, drum, tote, etc.) which in turn will assist in preventing a vacuum from dangerously collapsing the container housing the hyper concentrated chemical. Vent valve  310  also increases the safety of the present invention as it operates to prevent any air/fumes, such as any fumes from the hyper-concentrated chemical, from escaping out of bulk chemical supply  500 . Thus, vent valve  310  can cut down on the chances of a user being exposed to any chemical fumes associated with the hyper-concentrated chemical. Thus, vent valve  310  will allow air to vent into the container but it will prevent any fumes from escaping out of the container. 
     Outer threaded region  315  of coupler  300  is sized to screw into inner threaded portion  415  of insert  400 . This threaded region  315  provides a means to securely fasten coupler  300  to insert  400  and bulk chemical supply  500 . Color coded key member  320 , similar to color coded key member  420  of insert  400 , is a keyed member including a keyed portion  420 A that aligns with keyed portion  320 A of color coded key member  320 , that is preferably located below threaded portion  315  and outside of tube member  325  that acts to further secure and lock coupler  300  to insert  400  when coupler  300  is inserted in and connected to a corresponding color coded insert  400 . Color coded key member  320  is preferably configured so that it will only fit in/lock to a color coded key member  420  that is of same color via keyed portions  320 A and  420 A. Coupler  300  also contains tube member  325  that is preferably configured to extend down below color coded key member  320  and into insert  400 . However, the present invention is not limited to such a configuration as tube member  325  may be configured at any length. Tube member  325  may be sized smaller than tube member  430  of insert  400  so that it may extend down into tube member  430  to provide a path for chemicals sucked up tube member  430  to pass on to chemical input hose  132 . However, in an alternative embodiment, tube member  325  may be configured to simply line up and butt up against tube member  430  and still provide a path for chemicals to flow on to input hose  132 . 
     Round handle  330  of coupler  300  functions to provide users with a means to tighten and screw coupler  300  into insert  400 . While round handle  330  is illustrated in  FIGS. 4 and 5  as comprising a number of protruding tabs for a user to grip and turn, round handle  330  is not limited to any particular configuration. It may comprise any number of shapes or configurations that enable users to grip and turn so that users can tighten coupler  300  to insert  400 . Coupler  300  may also be configured to include a quick-coupler shut-off valve that operates as a safety feature to prevent drainage of chemicals from hose  132  out of tube member  325  whenever coupler  300  is disconnected from insert  400 . For example, when a user has utilized all of the hyper-concentrated chemicals in bulk chemical supply  500 , a user will have to disconnect coupler  300  from insert  400  and replace bulk chemical supply  500  with a full container. When coupler  300  is disconnected from insert  400 , any chemicals remaining in input hose  132  may tend to drain out of hose  132  through coupler  300  and out of tube member  325 . Such drainage can be a safety hazard as it may expose users to the hyper-concentrated chemicals. Thus, coupler  300  may include a quick-coupler shut-off valve located within coupler  300  that operates to prevent the flow of chemicals from input hose  132  back out of coupler  300  through tube member  325 . As such, this shut-off valve will prevent chemicals from draining out of input hose  132  into tube member  325 . In a preferred embodiment, coupler  300  will include a quick-coupler shut-off valve that is naturally in the closed/seated position so that chemicals will only flow through coupler  300  when the suction force created by pump  140  unseats the quick-coupler shut-off valve to allow chemicals to enter hose  132  and into pump  140 . Thus, when disconnecting coupler  300 , there will be no suction force from pump  140  and the quick-coupler shut-off valve in coupler  300  will be closed; thereby preventing chemicals from flowing out of coupler  300  when it is disconnected from insert  400 . In an alternative embodiment, the present invention may be configured so that a backflow preventer or other type of valve or other flow restrictor is connected to hose  132  to further prevent any chemicals from flowing back down and out of hose  132 . 
     As discussed herein, the color coded components of coupler  300  and insert  400  add an increased awareness and safety to the present invention. The color coded components function to assist users in making sure that only couplers  300  and inserts  400  containing the same color configurations will be connected to one another. For example, coupler  300  includes color coded key  320  and color coded cap  305  to assist in signaling or notifying users that only the bulk chemicals containing an insert  400  with the same color coded configuration and components (color coded key  420  and dot  425 ) should be connected to coupler  300 . For example, the color green may signify the use of a specific solvent based chemical. Thus, a coupler  300  with green color coded components will only connect to a bulk chemical supply  500  that includes an insert  400  that is also color coded green because a green color coded key  320  of coupler  300  will only connect and lock into a green color coded key  420  of insert  400 . The color coding is further advantageous as it adds an additional safety feature in that only matching components are utilized with one another. 
     Once a hyper-concentrated chemical supply, such as bulk chemical supply  500 , is connected to chemical input hose  132 , the system is ready for use. The liquid power/force is supplied by a constant flow and supply of a primary liquid, such as a user&#39;s water supply, through primary supply hose  101  as illustrated in  FIG. 1 . The present invention may be configured to accept a user&#39;s primary liquid supply, such as water, from a flexible hose, pipe, or other delivery means. In a preferred embodiment, a user&#39;s primary liquid supply, water, is connected to chemical diluting and dispensing system  10  through a secure connection mechanism, such as a coupling crow&#39;s foot connector  102 , as illustrated in  FIGS. 1 and 2 . However, the present invention is not limited to the use of a crow&#39;s foot coupling as any type of connector that can securely connect a user&#39;s primary liquid supply, such as a water supply, to system  10  will work. 
     As illustrated in  FIGS. 1 and 2 , the present invention may also be configured to include threaded nipple  103 , shut-off valve  104 , and strainer  105 . Nipple  103  simply acts as a connector to connect coupling connector  102  to shut-off valve  104 . In alternative embodiments, connector  102  may be configured to connect directly to shut-off valve  104  without utilizing nipple  103 . Shut-off valve  104  acts as a means whereby a user can shut-off the supply of the primary liquid in supply hose  101  to system  10 . For example, if a user needed to quickly shut down system  10  and/or quickly shut off force/power to pump  140 , a user could quickly close shut-off valve  104 . System  10  may also be configured so that shut-off valve  104  is connected to strainer  105  with some type of connecter such as a nipple, elbow, or other similar connector or the present invention may be configured so that strainer  105  is directly connected to shut-off valve  104 . Strainer  105  operates to screen out or filter the primary liquid supply so that any debris, sediment or other materials within the primary liquid supply are filtered out and do not pass on to the remaining components of system  10 . Thus, strainer  105  functions to make sure that only the primary liquid supply, water, in primary supply hose  101  will pass on to the remaining components of system  10 . In an alternative embodiment, system  10  may be configured to include a by-pass piping system that allows the primary liquid supply to bypass strainer  105  in the event that strainer  105  is clogged with debris and must be cleaned. In such a configuration a user is enabled to utilize the by-pass piping to by-pass strainer  105  and to continue using system  10  while strainer  105  is being cleaned or replaced. 
     As illustrated in  FIG. 2 , one embodiment of the present invention may be configured so that the output side of strainer  105  extends through an opening in enclosure  100  and connects to pressure regulator  110 . However, the present invention is not limited to such a configuration as system  10  may be configured so that strainer  105  is located within enclosure  100 . Strainer  105  may be connected directly to pressure regulator  110  or the present invention may be configured so that some type of connector, such as a union, nipple, coupling, and the like, is utilized to connect strainer  105  to pressure regulator  110 . Pressure regulator  110  operates to protect the components downline of pressure regulator  110  should the pressure of the primary liquid supply from primary supply hose  101  exceed a pre-set pressure of pressure regulator  110 . For example, a user may configure/set pressure regulator  110  to activate/regulate at 60 pounds per square inch (psi), and if the pressure in the primary liquid supply from primary supply hose  101 , such as water, exceeds the 60 psi limit, pressure regulator  110  may react and automatically cut off the flow of the primary liquid supply from primary supply hose  101  at pressure regulator  110  and prevent such high pressure liquid supply from flowing through the remainder of chemical diluting and dispensing system  10 . In cutting off the flow, pressure regulator  110  acts to insure that the pressure downline of pressure regulator  110  does not exceed 60 psi. System  10  is not limited to any particular type of pressure regulator as it may include a regulator that completely cuts off the flow of the liquid supply at a certain pressure or it may act to simply reduce and regulate the pressure of the primary liquid supply to some pre-set value as it flows to the remaining components of system  10 . 
     The output of pressure regulator  110  is connected to backflow preventer  120 . Pressure regulator  110  may be connected directly to backflow preventer  120  or the present invention may be configured so that some type of connector, such as a union, nipple, coupling, and the like is utilized to connect pressure regulator  110  to backflow preventer  120 . Backflow preventer  120 , as illustrated in  FIG. 2 , is connected to pressure regulator  110  and primary liquid hose  130 . Backflow preventer  120  is advantageous as it operates to prevent any liquids or other matter in primary liquid hose  130  from back-flowing into a user&#39;s primary liquid supply. For example, when a user&#39;s water supply is the primary liquid supply, backflow preventer  120  prevents any chemicals that may be in primary liquid hose  130  from back-flowing into and contaminating the user&#39;s water supply. Any such backflow is prevented because any chemicals that may flow back toward pressure regulator  110  will stop at backflow preventer  120  because backflow preventer  120  will prevent liquids/chemicals from flowing back past backflow preventer  120  toward pressure regulator  110 . 
     As illustrated in  FIG. 2 , the input end of primary liquid hose  130  connects to back flow preventer  120  and the output end of primary liquid hose  130  connects to one of three ports  171 ,  172 , or  173  of valve  170 . Ports  171  and  172  can be seen in  FIG. 2  and ports  171  and  173  are illustrated in  FIG. 3 . In the preferred embodiment, output end of primary liquid hose  130  connects to port  172  of valve  170 . In connecting to valve  170 , primary liquid hose  130  provides a path for the primary liquid supply from primary supply hose  101  to flow from the user&#39;s supply to valve  170 . As the primary liquid supply flows into port  172  of valve  170 , the primary liquid supply may proceed on to one of 3 flow paths depending on the user&#39;s mode of operation. 
     As illustrated in  FIG. 3 , an embodiment of the present invention may be configured so that a user may select from one of three modes of operation: (1) solvent (soap) mode; (2) off mode; and (3) rinse mode. The present invention is not limited to these three modes of operation as the present invention may be configured so that a user may select any number of operations. In such an embodiment, valve  170  may also be configured so that it is different than a three-way valve depending on the number of choices/flow paths needed for the distribution of the hyper-concentrated chemical. 
     During solvent mode, a user would turn the valve handle  174 , with position arrow  175 , to the left (counter-clockwise) so that position arrow  175  is pointing to the left or towards the “solvent” indicator or wording. When valve handle  174  is positioned for solvent operation, the valve is configured so that the flow of the primary liquid supply through primary liquid hose  130  will flow into port  172  of valve  170  and flow through valve  170  out of port  171  of valve  170  into pump supply hose  131 . Pump supply hose  131  connects the output of port  171  of valve  170  to pump  140  at connector  160 . Connector  160  operates to connect pump supply hose  131  to an input port  141  of pump  140 . Thus, pump supply hose  131  provides a passageway for the primary liquid to flow through valve  170  and into pump  140  when a user has selected the solvent mode of operation. 
     When the primary liquid enters into pump  140 , the flow of the primary liquid and the force from the flow will power and drive pump  140 . Once pump  140  begins to operate, pump  140  will create a pulling-up/suction force at pump head  145  to chemical input hose  132  to suck and/or pull chemicals up out of bulk chemical supply  500  into pump head  145 . 
     As the primary liquid (i.e. water) flows into pump  140  at input port  141  to activate pump  140 , the primary liquid will continue to be pushed out of/flow out of pump  140  at pump output port  142 . As illustrated in  FIG. 2 , the primary liquid will flow out of port  142  and into pump output hose  134 . Pump output hose  134  is preferably connected to pump output port  142  with connector  162  and connected to check valve  152  with connectors  158  and  159 . However, the present invention is not limited to such a configuration as output hose  134  may be configured so that it connects directly to output port  142  and check valve  152  without connectors. Pump output hose  134  provides a passageway for the primary liquid supply to be pushed out of/flow out of pump  140  and into check valve  152 . Primary liquid that flows into pump  140  at input port  141  will flow into pump  140  and be pushed out of/flow out of pump  140  at pump output port  142  on to check valve  152  and will then flow through connector  156  on to mixing tee  153  as illustrated in  FIG. 2 . While  FIG. 2  illustrates the use of connector  156  to connect check valve  152  to mixing tee  153 , the present invention is not limited to such a configuration. In alternative embodiments, check valve  152  may connect directly to mixing tee  153  without the need for connector  156 . 
     The suction force created by the operation of pump  140  will suck-up/pull whatever matter that chemical input hose  132  may be connected to, such as a hyper-concentrated solvent based cleaner. After the hyper concentrated chemical matter is sucked up, it proceeds through chemical input hose  132  to pump head  145 . When the present invention is in solvent mode, pump  140  may be continuously driven by a liquid power/force from a primary liquid supply, such as water, so that when an amount of hyper concentrated chemical matter is sucked up chemical input hose  132  into pump head  145 , an amount of the hyper-concentrated chemical will then be discharged out of pump head  145  through chemical output hose  133 . In one embodiment, pump  140  may be configured so that a ball-check-valve is located within pump head  145 . This ball-check-valve will allow the flow of the chemicals (sucked into pump head  145 ) into pump head  145 . When pump  140  operates to apply the suction force at pump head  145 , this suction force will unseat the ball-check-valve in pump head  145  thereby allowing the chemicals to flow into pump head  145 . During the next cycle, the injection cycle, pump  140  applies a force that will seat the ball-check-valve in pump head  145  and chemicals will be injected/forced under pressure out of pump head  145  under sufficient pressure to flow through output hose  133  and into mixing tee  153 . However, the present invention is not limited to such configuration. While pump  140  in  FIG. 2  is illustrated as containing one pump head  145 , the present invention may be configured to include a pump that comprises two heads that would assist in delivering a steady flow of chemicals during each cycle of the pump. 
     Chemical output hose  133  is connected to pump head  145  on one end and connected to check valve  151  on the opposite end. Chemical output hose  133  is preferably connected to pump head  145  with connector  161  and connected to check valve  151  with connector  157 . However, the present invention is not limited to such a configuration as output hose  133  may be configured so that it connects directly to pump head  145  and check valve  151  without connectors. Chemical output hose  133  provides a passageway for chemical discharged out of pump head  145  to flow to check valve  151 . Chemical that has been discharged out of pump head  145  will flow on to check valve  151  and will then flow on to mixing tee  153  as illustrated in  FIG. 2 . While  FIG. 2  illustrates mixing tee  153  as being within enclosure  100 , the present invention is not limited to such configuration as alternative embodiments may be configured so that mixing tee  153  is located outside of enclosure  100 . 
     Check valves  151  and  152  are advantageous as they operate to allow flow to proceed in only one direction—downstream or away from pump  140 . When water flows through check valve  152  and when chemical flows through check valve  151 , these valves operate to prevent any of the corresponding water or chemical from flowing in a reverse direction back into pump  140 . Such flow control provided by the check valves helps to increase the life of the pump by preventing and/or reducing the amount of flow of either the chemicals or water-chemical mixture flowing back into the body of pump  140 . 
     As discussed above, during a solvent or soap mode of operation, the primary liquid supplied to system  10 , such as a water supply, will flow (1) through primary liquid hose  130 , through valve  170  and then into and through pump  140 , (2) on through check valve  152 , and (3) on to mixing tee  153  where the primary liquid will preferably mix with the hyper-concentrated chemicals. The chemicals from bulk chemical supply  500  will flow (1) through chemical input hose  132 , into and out of pump head  145 , through chemical output hose  133 , (2) on through check valve  151 , and then (3) on to mixing tee  153  where the hyper-concentrated chemical will mix with the primary liquid supply. As such, the primary liquid supply and the hyper-concentrated chemical from bulk chemical supply  500  will both flow into mixing tee  153  and mix at that point inside of tee  153 . The dynamics of the mixing process inside of mixing tee  153  may be modified depending on the size of mixing tee  153 . In some embodiments, a large mixing tee may be utilized to increase the volume inside of the mixing tee  153  which can alter the dynamics of the mixing inside of mixing tee  153 . While the chemical and primary liquid, preferably water, are beginning to mix at tee  153 , the mixing process will continue as the flow of the hyper-concentrated chemical and primary liquid continues through the remainder of system  10 . The chemical/primary liquid mixture will continue to flow out of mixing tee  153  into output tee  154  through input port  154 A of output tee  154  as illustrated in  FIG. 3 . The present invention may also be modified so that any number of different types of mixing chambers may be utilized for mixing tee  153 . For example, a non-moving mixer or static mixer may be utilized as mixing tee  153  depending on the use of system  10 . Such static mixers may take any shape and may be comprised of any number of materials, such as steel, chrome, plastic, PVC, stainless steel, Teflon, Kynar, any number of polymers, polyacetal, and the like. In addition, mixing tee may be a static mixer in which the mixing housing is made of one material while the inner mixer is comprised of a different material and the inner mixer may be in any configuration, such as a spiral mixer, an alternating-spiral mixer, and the like. The present invention may also be configured so that a second static mixer may be utilized to assist with additional mixing of the chemical mixture. For example, in some embodiments, the present invention may be configured so that a static mixer or mixing chamber may be installed after output tee  154  and/or just before hose  600  to provide an additional mixing mechanism to the present invention. 
     As illustrated in  FIGS. 2 and 3 , output tee  154  is preferably configured so that input port  154 A of output tee  154  extends through enclosure  100  and connects to mixing tee  153 . The connection of output tee  154  to mixing tee  153  may be accomplished with a connector, such as a nipple, a coupling, a union, a piece of hose or a tube fastened to both tees, and the like. However, the present invention may be configured differently so that a portion of mixing tee  153  extends out of enclosure  100  and connects to output tee  154 . Any such configuration may be utilized in various embodiments of the present invention. 
     As the chemical/primary liquid mixture flows out of mixing tee  153  into output tee  154  through input port  154 A, the chemical/primary liquid mixture will initially flow in two paths. The flow will travel through output port  154 B of output tee  154  through connector  163  and into bucket tee  155 . Bucket tee  155  is advantageous as it may provide a user with another outlet for dispensing or obtaining the primary liquid/hyper-concentrated chemical mixture. In some embodiments, a hose or other outlet means, such as a spigot, faucet, valve, or the like may be connected to output port  155 A of bucket tee  155  which can enable a user to obtain some of the mixture without having to use output hose  600 . For example, if an individual is utilizing system  10  to clean an area of an industrial facility and needs a small amount of the hyper-concentrated/primary liquid mixture to place in a bucket to use with a brush in the bucket, a user may obtain the mixture from bucket tee  155  instead of utilizing hose  600 . However, as illustrated in  FIG. 3 , an embodiment of the present invention may be configured so that the top output port  155 A of bucket tee  155  is capped off with plug  180  so that there would be no way to dispense the mixture out of bucket tee  155 . 
     After the primary liquid/hyper-concentrated chemical mixture flows into bucket tee  155  it can flow out of side port  155 B of output tee  155 . During solvent mode, valve  170  will block any flow out of side port  155 B of output tee  155  so that flow will stop at valve  170  and not travel any further. 
     The second path out of output tee  154  is to the left out of port  154 C of output tee  155  through connector  165  on to output hose  600 . A user may then utilize output hose  600 , which may be of any length, typically 50 to 200 feet depending on user&#39;s needs, to transport the chemical/primary liquid mixture and apply the mixture as needed. For example, if system  10  were located on an offshore oil platform and utilized for dispensing a solvent based cleaner, a user could hook up a water supply to system  10  via primary supply hose  101  and then choose solvent operation mode. System  10  would then suck up the hyper-concentrated solvent based chemical cleaner and mix it with the proper amount of water and discharge that mixture through hose  600 . A user could then utilize hose  600  to spray/dispense the solvent based mixture as needed for cleaning. 
     In alternative embodiments, system  10  may be configured to include a foaming attachment that operates to foam the ready to use cleaner/degreaser. The foaming attachment, may, for example, be a double hose that replaces hose  600  with a first hose for the ready to use chemical and a second hose to deliver pressurized air to the ready to use chemical in order to foam the ready to use chemical. In such an embodiment, the air may be delivered to a foaming wand/nozzle located at the end of the double hose. A user would then have the option to choose a foam output. By choosing a foam output, pressurized air would be injected into the primary liquid/hyper-concentrated chemical mixture so that a user could output the mixture as foam as opposed to dispensing the mixture in a straight liquid form. The purpose of foaming is to alter the cleaner/degreaser with induced air bubbles so that the foam cleaner/degreaser will adhere to surfaces, particularly vertical surfaces, for a longer time during “soaking.” This provides a more effective cleaning and may reduce the amount of chemical used. The user may also control the air to chemical percentage with valves that may be provided on the foaming wand/nozzle. In this embodiment, a pressurized air supply is provided in addition to a primary liquid supply, such as a water supply. 
     In addition to the solvent mode of operation, a user can utilize system  10  in the rinse mode to simply apply the primary liquid without any of the hyper-concentrated chemicals in bulk chemical supply  500 . Thus, the present invention is further advantageous as only one output hose, hose  600 , is needed to both apply the primary liquid/chemical mixture and later rinse with only the primary liquid. In utilizing only one output hose, hose  600 , the user is prevented from having to carry multiple hoses while utilizing the present invention. During rinse mode, a user would turn the valve handle  174 , with position arrow  175 , to the right (clock-wise) so that position arrow  175  is pointing to the right or towards the “rinse” indicator or wording. When valve handle  174  is positioned for rinse operation, the valve  170  is configured so that the flow of the primary liquid supply from primary supply hose  101  will flow: (1) through pressure regulator  110 , (2) through backflow preventer  120 , (3) through primary liquid hose  130 , (4) into port  172  of valve  170 , and then (5) flow through valve  170  out of port  173  of valve  170 . In rinse mode, a pathway to port  171  of valve  170  is shut off so that the flow in valve  170  will only flow out of port  173  into bucket tee  155 . As discussed above, port  155 A of bucket tee may be plugged so that the flow can only flow out of bucket tee  155  and into output tee  154  on to hose  600  through connector  165 . In such an embodiment, a user can utilize hose  600  to dispense the primary liquid with out any chemicals. For example, when a user utilizes system  10  to clean a portion of a tank in an industrial facility, the user may wish to rinse the tank with water after the water/hyper-concentrated solvent based cleaner has already been applied to the tank. Thus, the user would select rinse mode and utilize hose  600  to dispense only the primary liquid, water, onto the tank in order to rinse the tank during or after cleaning. 
     As discussed above, the present invention may be configured so that bucket tee  155  may provide a user with another outlet for dispensing or obtaining only the primary liquid, such as water, in rinse mode. A hose or other outlet means, such as a spigot, faucet, valve, or the like may be connected to output port  155 A of bucket tee  155  which can enable a user to obtain some of the primary liquid without having to use output hose  600 . For example, if a user wanted a small amount of the primary liquid, the user could obtain the desired amount from bucket tee  155  instead of having to utilize hose  600 . In some embodiments, hose  600  may be several hundred feet long and may be a heavy-duty hose that would require a great deal of effort to simply obtain a small quantity of water when a user may simply turn a faucet connected to port  155 A of bucket tee  155  and quickly obtain the desired quantity. 
     During off mode, a user would turn the valve handle  174  as needed so that position arrow  175  is pointing upwards towards the “off” indicator or wording. When valve handle  174  is positioned in the off mode, the valve  170  is configured so that the flow of any primary liquid in primary liquid hose  130  will stop at port  172  as valve  170  will be blocked so that no flow can enter port  172 . With no flow through port  172 , there will be no flow out of port  171  and thus, no flow into pump  140 . With no flow into pump  140 , the pump will not operate and no hyper-concentrated chemical will be sucked up out of bulk chemical supply  500 . Thus, in off mode, the pump  140  will not operate and the flow path to output hose  600  will be blocked. 
     In a preferred embodiment, system  10  may be configured so that the amount of hyper-concentrated chemical sucked up from bulk chemical supply  500  and discharged out of pump head  145  may be controlled by a user through the user&#39;s configuration of pump  140 . As illustrated in  FIG. 2 , pump  140  includes adjustment member  143  that allows a user to alter/adjust the stroke length of the pump which can alter the amount of hyper-concentrated chemicals sucked into pump head  145 . Depending on a user&#39;s needs, a user may configure pump  140  via adjustment member  143  by adjusting the stroke length of the pump so that it may discharge either (1) a greater volume of hyper-concentrated chemical for a stronger chemical/primary liquid mixture or (2) a smaller volume of hyper-concentrated chemical for a weaker chemical/primary liquid mixture. Thus, embodiments of the present invention may allow users to customize the percentage of hyper-concentrated chemical that will be mixed with the primary liquid supply depending on the user&#39;s needs or wishes. For example, a user may increase the amount of hyper-concentrated chemicals utilized for efficiency purposes or a user may reduce the amount of chemicals used for economical reasons, such as to cut back on costs. In addition, after a user has configured the system to a particular setting, enclosure  100  can be locked so that unauthorized personnel can not change the user&#39;s desired setting. In alternative embodiments, system  10  may also be configured so that a user may configure pump  140  to modify the volume of primary liquid discharged out of pump output port  142  which will result in modifying the chemical/primary liquid supply mixture by adding more or less of the primary liquid supply. Because the primary liquid supply dilutes the hyper-concentrated chemical when the two are mixed, a user may control the volume of primary liquid discharged which ultimately controls the diluting of the hyper-concentrated chemical which will alter the strength or potency of the mixture output through hose  600 . However, the present invention is not limited to such configurations as an embodiment of the present invention may be configured so that a user may control/alter both the volume of primary liquid discharged and the volume of hyper-concentrated chemical discharged to achieve a desired potency or strength. 
     The present invention is configured to minimize the pressure drop across the various components so that there is sufficient pressure remaining at the output through hose  600  so that a user may still utilize an output hose  600  up to at least a  200  foot length to discharge the chemical mixture. In a preferred embodiment of the present invention, the arrangement of piping, hoses, and connectors is unique in that it operates to minimize the pressure drop/difference between the inlet pressure of the primary liquid supply and the outlet pressure through/at hose  600 . The pressure drop in such a preferred embodiment may range typically from 10 to 20 psi. The remaining or “unused pressure drop” is advantageous in throwing a strong spray of chemical through hose  600  and any nozzle attachment at the end of hose  600  at the “point of use.” For example, if the inlet pressure at hose  101  is 40 psi, the configuration in a preferred embodiment is such that the pressure output at hose  600  may range from 20 to 30 psi. This 10 to 20 psi drop is merely an example of the pressure drop in one embodiment of the present invention and alternative embodiments of the present invention may result in different pressure drops. In achieving this minimal 10 to 20 psi pressure drop in a preferred embodiment, the various hoses may be arranged and configured as follows: (1) hoses  130  and  131  as ¾ inch in diameter; (2) hoses  133  and  134  are preferably ½ inch in diameter; and (3) hose  132  is a ¾ inch diameter hose. In addition, in order to achieve the desired minimum pressure drop, hose  130  is preferably sized between 30 to 36 inches in length, hose  131  is preferably sized between 12 to 18 inches in length, hose  133  is preferably sized between 8 to 20 inches in length, hose  134  is preferably sized between 4 to 12 inches in length, and hose  132  is preferably sized between 3 to 10 feet in length. The measurements and configurations listed above are advantageous as such configuration illustrates an embodiment that achieves a minimal pressure drop across the system. However, these measurements and configurations are not to be construed as limitations to the entire inventive concept but merely as a specific example of one embodiment of the present invention as alternative embodiments may be configured to different specifications. 
     The present invention is not limited to dispensing any particular hyper-concentrated chemical. Any variety of chemicals may be dispensed in the various embodiments of the present invention disclosed herein, including without limitation: (1) a hyper-concentrated chemical including at least a surfactant blend of 15 to 20% and a Naphtha based solvent of 75 to 85%; (2) a hyper-concentrated chemical including at least a sodium hydroxide of 5 to 15% and a glycol based surfactant mixture of 30 to 60% that may comprise some ethylene glycol monobutyl ethers; and (3) a hyper-concentrated chemical including at least a surfactant blend of 35 to 45% and a 1-methyl-4-(1-methylethenyl)cyclohexene of 45 to 55%. However, any number of hyper-concentrated chemicals may be dispensed with the present invention as the hyper-concentrates enumerated herein are merely an example of some hyper-concentrates dispensed with the present invention. 
     Although the present invention and its advantages have been described in detail, it should be understood that various changes, substitutions and alterations can be made herein without departing from the invention as defined by the appended claims. Moreover, the scope of the present application is not intended to be limited to the particular embodiments of the process, machine, manufacture, composition of matter, means, methods and steps described in the specification. As one will readily appreciate from the disclosure, processes, machines, manufacture, compositions of matter, means, methods, or steps, presently existing or later to be developed that perform substantially the same function or achieve substantially the same result as the corresponding embodiments described herein may be utilized. Accordingly, the appended claims are intended to include within their scope such processes, machines, manufacture, compositions of matter, means, methods, or steps.