Abstract:
A dual mode carpet cleaning method is capable of being used in both a deep cleaning mode and a fast drying surface cleaning mode. The method utilizes a carpet cleaning apparatus that provides selective communication with different sets of cleaning jets. One set of cleaning jets is operated to deliver a first cleaning solution that penetrates deeply into a carpet in the deep cleaning mode. A second set of cleaning jets is operated to deliver a lower flow rate of a second cleaning solution that does not penetrate as deeply into the carpet and dries quickly. The method involves manually operating a valve on the apparatus to selectively communicate a source of cleaning fluid of the apparatus with one of the first set of cleaning jets and the second set of cleaning jets, and discharging the cleaning liquid from the selected one of the first set of cleaning jets and second set of cleaning jets onto a carpet to be cleaned.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
   This is a DIV. of Ser. No. 09/898,584 filed on Jul. 2, 2001 now U.S. Pat. No. 6,789,290. 

   STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT 
   Not Applicable. 
   REFERENCE TO A MICROFICHE APPENDIX 
   Not Applicable. 
   FIELD OF THE INVENTION 
   This invention relates to cleaning machines, carpet cleaning solutions, the system incorporating the cleaning machines and carpet cleaning solutions, and methods of cleaning carpet. Specifically, the carpet cleaning machine of the present invention is capable of operating in either a surface cleaning mode and a deep cleaning mode, or alternatively, a fast drying mode and a longer drying mode. 
   BACKGROUND OF THE INVENTION 
   Currently, machines for cleaning carpets consist of a system for delivering a cleaning solution, typically a hot aqueous detergent solution, to a carpet and a system for vacuuming the applied cleaning solution from the carpet. Many of these machines also have rotating brushes or beater bars to work the cleaning solution into the carpet and to aid in the dislodging of dirt and other debris from the carpet fibers. 
   The system for delivering the cleaning solutions in these machines usually includes a tank for holding the solution and a pump for pumping solution from the tank to a spray nozzle chamber. The spray nozzle chamber then distributes the cleaning solution to the carpet. The system for vacuuming generally comprises a vacuum chamber disposed in a cleaning head positioned over the carpet (The term “carpet” is defined to also include rugs.). The brushes then scrub the carpet. Next, a vacuum pump in fluid communication with the vacuum chamber and nozzle generates suction to remove the solution applied to the carpet. 
   These cleaning systems come in various varieties. The first variety is a deep clean system in which the tanks, the delivery system, the removal system and the brush are all contained on a moveable cart. A cleaning solution is applied to the carpet through various applying mechanisms that allow the solution to penetrate to the carpet backing material and remove unwanted dirt. The dirt/solution mix is subsequently removed by the vacuum. U.S. Pat. Nos. 5,473,792, 4,809,397 and 4,803,753 are examples of these machines. In this deep cleaning variety, the carpet is first administered a high pressure stream of cleaning solution, then scrubbed or otherwise agitated, and finally subjected to a vacuum to remove the solution and unwanted soil. This type of application provides thorough cleaning, and penetrates to the carpet backing material with the cleaning solution. As a result the carpet takes usually at least four to seven hours, or longer to dry. Long drying times make it logistically difficult to deep clean carpets in high traffic areas. As a result, many businesses are unable to deep clean carpets more than once a year. 
   Other varieties of cleaning systems include petroleum powder, dry cleaning, SORI (Spray On Rub In), and shampoo. The petroleum powder system involves spraying on a petroleum powder that binds to dirt. However, powder removal is never complete, and the remaining powder residue continues to attract dirt, making the carpet dirtier. The dry cleaning system involves applying dry cleaning chemicals to the carpet which can create environmental concerns. The SORI system is for spot cleaning where carpet cleaner is sprayed onto carpeting, and hand scrubbed. The shampoo system requires a shampoo solution containing a relatively small amount of water to be applied to the carpet. A bonnet on a machine is used to absorb the solution-dirt mixture from the surface of the carpet. 
   Currently, a machine does not exist that can be used for both a traditional deep cleaning application and a faster drying surface cleaning application. In addition, a cleaning solution does not exist that is designed for use in both a deep cleaning application and a surface cleaning application. Although numerous examples of cleaning solutions and powders are known in the art, none are specifically formulated to be used in both deep cleaning and surface cleaning varieties. 
   Additionally, neither a system using a dual mode carpet cleaning machine using a fast drying solution, nor methods of using such a system exist in the art. Therefore, what is needed is 1) a dual mode carpet cleaning machine that operates in a fast drying, surface cleaning mode and a longer drying, deep cleaning mode; 2) a fast drying carpet cleaning solution that will penetrate the carpet to the carpet backing mixed at one concentration and that will not penetrate the carpet to the carpet backing at another concentration; 3) a system using the dual mode carpet cleaning machine and fast drying carpet cleaning solution; and 4) methods of using such a system. Each of these features result in faster carpet drying times while retaining high cleaning efficiency. 
   BRIEF SUMMARY OF THE INVENTION 
   The present invention is drawn to the next generation of carpet cleaning machines and cleaning agents. The invention solves the above mentioned problems and will allow a user the ability to use the same machine and the same cleaning solution to either deep clean or surface clean a carpet, resulting in faster drying times while retaining high cleaning efficiencies. The invention empowers the user of the carpet cleaning machines and carpet cleaning solutions of the invention to choose whether they want to clean the surface of a carpet and quickly have the carpet available for use, or deeply clean the carpet for sanitary or other reasons when time has been allowed for longer drying times. Hotels and other businesses would greatly benefit from such an invention when carpets need to be cleaned quickly between guests or business hours, but provide the hotel or other business the option of deep cleaning carpets using the same machine and carpet cleaning solution when time is not of the essence. 
   One aspect of the invention is to provide an improved machine that allows the easy selection of either a deep cleaning mode or a surface cleaning mode, or alternatively a longer drying time mode or a faster drying time mode. By the simple change of the selection mechanism, the machine will adjust the physical characteristics of the delivered cleaning solution and thus the manner in which the cleaning solution interacts with the rug or carpet, prior to being removed by the vacuum. This in turn enables the user to control the carpet drying time. 
   Another aspect of the invention is to provide a new cleaning solution. The new cleaning solution has characteristics that allow it to be diluted into a mixture for use in both a longer-drying, deep-cleaning application as well as a fast-drying, surface-cleaning application by changing the solution concentration in the water. Even with a single mode, deep cleaning machine, the improved cleaning solution shows faster carpet drying times over prior art mixtures, without the use of alcohol or other volatile flammable solvents. 
   The cleaning solution of the present invention is formed by diluting a specific amount of cleaning mixture with clean water. The cleaning mixture has a combination of surfactants, detergents and wetting agents optimized for use in a surface cleaning application, but also formulated to deep clean carpets. An additional benefit of the solution of the invention is that it imparts cleaning efficiencies that are similar to the efficiencies of prior art cleaning solutions while at the same time providing for a substantial reduction in carpet drying time over the prior art. A key property of the carpet cleaning mixture is that it creates a foam when mixed with water at a lower concentration, but creates a gel-like higher viscosity foam when mixed with water in a higher concentration. Preferably, the higher concentration is about twice as concentrated as the lower concentration. The gel-like foam produced upon agitating the solution at this concentration imparts increased foam stability while other components enhance sheeting action. The combination of the lower application rate and the creation of this foam prevents deep penetration of the cleaning solution into the carpet prior to removal by the vacuum system. This results in a surface-cleaned carpet that typically dries in less than two hours as compared to four-to-seven hours or more of current carpet cleaning systems. 
   Yet another aspect of the invention is to provide a dual mode carpet cleaning system using the dual mode cleaning machine and the fast drying cleaning mixture. 
   A further aspect of the invention is to provide a method of cleaning carpet. The method comprises the steps of mixing the concentrated carpet cleaning solution at a concentration such that a foam produced by agitating the carpet cleaning solution does not penetrate the carpet to the carpet backing, placing the mixed carpet cleaning solution into the dual mode carpet cleaning machine, selecting a fast dry mode of the carpet cleaning machine, and applying the carpet cleaning solution to the carpet fibers. 
   Further features and advantages of the present invention as well as the structure, composition and operation of various embodiments of the present invention, are described in detail below with reference to the accompanying drawings. 

   
     DESCRIPTION OF THE DRAWINGS 
     In the drawings: 
       FIG. 1  illustrates an elevated perspective view of the carpet cleaning machine of the present invention; 
       FIG. 2  illustrates an elevated, perspective exploded view of a removal section of the carpet cleaning machine of the present invention; 
       FIG. 3  illustrates an elevated, perspective exploded view of a storage section and an application and extraction section of the carpet cleaning machine of the present invention; 
       FIG. 4  illustrates a detailed perspective view of jet tip nozzles of the carpet cleaning machine of the present invention; 
       FIG. 5  is a chart which illustrates the results of a cleaning efficiency test; 
       FIG. 6  is a chart which illustrates the results of a second cleaning efficiency test; and 
       FIG. 7  is a chart which illustrates the results of a drying time test. 
   

   DETAILED DESCRIPTION OF THE INVENTION 
   Referring to the accompanying drawing in which like reference numbers indicate like elements, the machine, the cleaning mixture and the system of the present invention are set forth below. 
   A. The Machine 
   Referring now to  FIGS. 1–4  it can be seen a portable self-contained carpet cleaning machine is shown generally at  10  in accordance with the present invention. Machine  10  includes a main support housing, shown generally at  12 , having an application and extraction section shown generally at  14 , a storage section  16 , and a removal section shown generally at  18 . A handle  20  is attached to the support and wheels  24  allow machine  10  to be rolled. 
   As shown in  FIG. 3 , the application and extraction section  14  includes a vacuum nozzle  30  attached to a removal conduit  32 , a brush assembly shown generally at  34 , solution pump  38 , spray nozzle chamber  40  and a ball valve  42 . The brush assembly  34  uses a motor  46  with off-center drive shaft  48  to drive link member  50  linked to a brush  52  (bristles not shown in this top view) which drives the brush  52  back and forth between the vacuum nozzle  30  and the spray nozzle chamber  40 . The solution pump  38  pumps cleaning solution (not shown) to the spray nozzle chamber  40  through solution pump outlet  55 . The machine  10  may be produced using a range of nozzle spraying patterns, varying in length, width, dispersion, and other geometrical configurations. The spray nozzle chamber  40  is equipped with both a deep cleaning jet tip  60  (preferably model H1/8 VV-KY11010 for narrower width spraying such as in a Rug Doctor Mighty Pack machine or model 1/8HVV KY11006 for wider spraying such as in a Rug Doctor Wide Track machine, available from Spraying Systems Co., Wheaton, Ohio) and a fast dry jet tip  62  (preferably model 1/8K SS1.5 for narrower width spraying or model 1/8K SS2.5 for wider spraying, available from Spraying Systems Co., Wheaton, Ohio). The deep cleaning jet tip  60  is pointed downward and forcefully propels a stream of cleaning solution. Preferably, the surface cleaning (fast dry) jet tip  62  has a deflector surface (in the preferred model specified) and covers the same area of carpet as the deep cleaning jet tips  60 . However, the presence of a deflector surface in fast dry tip  62  is also dependent upon the geometrical orientation of the jet tips  60 ,  62 . Other tips with or without deflector surfaces can be used according to geometrical constraints. 
   A ball valve  42  is continuously fed diluted cleaning solution from the solution pump  38  and can be switched between first and second outlets,  70  and  72 , respectively . When the ball valve  42  is aligned with the first outlet  70 , cleaning solution is fed to a deep cleaning jet tip  60 , and when the ball valve  42  is aligned with the second outlet  72  cleaning solution is fed to the fast dry jet tip  62 . 
   The ball valve  42  of machine  10  is actuated by an actuator (shown generally at  78 ). The actuator comprises an indicator  76  and a shaft  77 . The indicator  76  can be rotated between a first position  79  (shown) and a second position  80  (shown in shadow). Movement of the indicator  76  between the two positions  79 ,  80  selectively places the two types of jet tips  60 ,  62  in fluid communication with the cleaning solution. 
   In the first position  79 , cleaning solution is fed to the deep cleaning jet tip  60 . The machine  10  (e.g., the Rug Doctor Mighty Pack machine) may be configured to deliver a carpet-covering spray pattern at a rate of preferably between 0.52 to 0.55 GPM (gallons per minute), more preferably 0.54 GPM through the deep clean jet tip  60 . A machine  10  configured to deliver a wider spray pattern, (e.g., the Rug Doctor Wide Track machine), may be configured to deliver preferably 0.60 to 0.70 GPM, more preferably 0.65 GPM. Other configurations may be used depending on the geometrical configuration requirements of different machines. 
   The second position  80  provides cleaning solution to a fast dry jet tip  62 . A carpet cleaning machine (e.g., Rug Doctor Mighty Pack machine) may be configured to deliver preferably between 0.13 to 0.24 GPM, more preferably 0.17 to 0.21 GPM, and still more preferably 0.19 GPM. A carpet cleaning machine (e.g. Rug Doctor Wide Track machine) configured to deliver a wider spray pattern may be configured to deliver preferably between recovery tank  108 . The air inlet  109  side (under the motor and not shown) of vacuum motor  102  is attached to an inlet conduit  118  which passes through an aperture  134  in the vacuum cover  104  and connects to one side of a dome  120 . The vacuum motor creates suction to pull air and dirty water recovered from the carpet through nozzle  30  (best seen in  FIG. 3 ). Dirty water and air travel through the removal conduit  32  (best seen in  FIG. 3 ), up through the first conduit  112  (best seen in  FIG. 2 ,  FIG. 2  and  FIG. 3  hoses match up at x and y), through an aperture  114  in the vacuum cover  104  and into dome  120 . The dirty water and air hit a baffle (inside the dome  120  and not shown) and the dirty water drops into the recovery bucket  108  ( FIG. 3 ). After traveling through the inlet conduit  118  into the vacuum motor  102 , the air leaves through exhaust  110  and is directed into hose  126 . Hose  126  goes down the main support  12  and exits out of the bottom of the machine (best seen in  FIG. 2 ). The dome  120  has a gasket  124  about its base and is sealed about an aperture  130  in the top of recovery tank  108 . The seal between the dome  120  and the recovery tank  108  is maintained by a bale  132  that doubles as a carrying handle for the recovery tank  108 . 
   In a preferred embodiment, the vacuum nozzle  30  includes a pair of spaced triangular plates  140 ,  142 , joined on two sides and open on the bottom, the rear plate of which has a fitting for attachment to the first conduit  112  (alternatively called removal conduit  32 ). The vacuum nozzle  30  preferably has an ear  144  and is held in the grooves  146  with a single screw not shown. It will be appreciated by those skilled in the art, however, that the vacuum nozzle  30  may be attached by any suitable means known in the art. 
   The top of the cavity has a hollow extending into a notch  148  up the rear wall  150  of the clean water tank for receipt of the first conduit  112 . A second notch  152  is provided in the rear wall  150  for receipt of the hose  126  which is vented through a rear panel  160 . The rear panel  160  is attached to the pan  162  and the rear wall  150  of the clean water tank  82  with screws (not shown) or any other suitable means. 
   In use, as machine  10  is pulled rearwardly on wheels  24  by handle  20 , premixed cleaning solution is drawn through strainer  90  in clean water tank  82  through first tube  164  into the inlet  92  of solution pump  38 . The cleaning solution is then forced from the outlet  55  of solution pump  38  into second tube  166 , through selection mechanism  168  (comprising ball valve  42 , indicator  76 , and actuator  78 ) and delivered under pressure to spray nozzle chamber  40 . Spray nozzle chamber  40  directs a spray of the solution onto a carpet just behind vibratory brush assembly  34 . The wetted carpet is given a brief scrubbing and the cleaning solution immediately recovered with vacuum nozzle  140 . Spent cleaning solution is sucked through conduit  112 , into dome  120 , where it is stopped by a baffle (not shown) and falls under gravity to the bottom of recovery tank  108 . 
   B. The Cleaning Mixture 
   The carpet cleaning solution of the invention is a mixture comprising a detergent, foam stabilizer and an emulsifying agent. The solution is preferably a concentrate that can be diluted to different concentrations for use in different carpet cleaning modes of a dual mode carpet cleaning machine. A single compound may provide all three functions—detergency, stabilization, and emulsification—but it is preferred that at least two and more preferably three distinct compounds provide each individual function. In one embodiment, the carpet cleaning solution combines 1) an active detergent which may also function as a foaming agent, corrosion preventer, and a foam bubble-size reducer, and 2) an emulsifying agent which may also function as a profoamer, sheeting agent, and dispersing agent. These agents are referred to as the active agents of the invention. In addition, agents such as optical brighteners, deodorizers, water softeners, acid/base buffers, preservatives, and suspending agents may be added to optimize the carpet cleaning performance. 
   More preferably, the solution additionally includes: 3) a suspending agent which may also function as an incrustation inhibitor, an anti-redeposition agent, and a detergency booster; 4) a non-bleach optical brightener; and 5) a sequestering agent which may also function as an acidic/alkaline buffer and a soil dispersing agent. Finally, the solution may additionally include: 6) a preservative; 7) a water softener which may also function as an alkaline buffer; and 8) a fragrance or odor absorber. 
   The Active Detergent 
   The active detergent is preferably sodium lauryl sulfate (available from Para-Chem, Inc., Dalton, Ga.), but may also comprise an anionic detergent such as alkyl glyceryl ether sulfonates, alkyl sulfonates, alkyl monoglyceride sulfates or sulfonates, alkyl polyethoxy ether sulfonates, alkyl aryl sulfonates, aryl sarcosinates, aryl esters of isothionates, alkyl esters of sulfosuccinic acid, and alkyl phenol polyethoxy sulfonates. They are used in the form of water-soluble salts, such as, by way of example only, sodium, potassium and ammonium salts. Specific examples of the anionic organic detergents include sodium lauryl sulfate, sodium dodecyl sulfonate and sodium lauroyl sarcosinate. 
   The active detergent is more preferably a mixture of sodium lauryl sulfate and sodium lauroyl sarcosinate (available from Stephan Chemicals, Chicago, Ill.). It is believed the sodium lauroyl sarcosinate stabilizes the foam produced from agitating the carpet cleaning solution resulting in a drier foam with smaller and more uniform bubble size. The mixture of active detergents and the emulsifying agent below produces the unique properties of the invention upon increasing the concentration of the solution, e.g., from 4 oz./gallon to 8 oz./gallon, thereby imparting cleaning properties typical of current carpet cleaners at a lower concentration, but reduced drying time, cleaning activity with a drier, more stable foam, and increased sheeting action at higher concentrations. This also provides the advantage that the same carpet cleaning solution may be used in different concentrations in the same carpet cleaning machine to perform different functions. 
   The Emulsifying Agent 
   The emulsifying agent is preferably Silwet L-7608 (polyethyleneoxide modified trisiloxane copolymer, available from Osi Specialties, Inc., Greenwich, Conn.), but may comprise other compounds that increase the adhesion of the carpet cleaning solution to the carpet or increase the cross-link density of the carpet cleaning solution. It is believed that Silwet L-7608 aids foaming and foam stability and increases other properties such as viscosity, adhesion to the carpet, increased wetting of the carpet, and increased cross-linking of compounds within the foam. The emulsifying agent is also believed to function as a profoamer, sheeting agent, and dispersing agent. 
   The Sequestering Agent 
   The sequestering agent is preferably sodium tripoly-phosphate (Na 5 P 3 O 10 , available from Solutia, Inc., St. Louis, Mo.), but may also comprise other agents that provide sequestration of multivalent metal ions. The sequestering agent may also function as an acidic/alkaline buffer and a soil dispersing agent. 
   The Suspending Agent 
   The suspending agent is preferably Sokalan CP-9 (available from BASF, A.G., Germany), but may also comprise other polycarboxylate copolymers such as carboxylic acid copolymers, acrylic acid homopolymers, carboxymethyl cellulose, and nonionic copolymers such as polyvinylpyrrolidone. The suspending agents may also function as incrustation inhibitors, anti-redeposition agents, and as detergency boosters. 
   The Non-Bleach Optical Brightener 
   The non-bleach optical brightener is preferably Tinopal® (available from Ciba Specialty Chemicals, Greensboro, N.C.), but may also comprise other agents that absorb incipient, invisible UV light and convert it into visible light, e.g., UVITEX® (available from Ciba Specialty Chemicals, Greensboro, N.C.) or other agents that make the carpet appear brighter than the light which strikes it. 
   The Preservative 
   The preservative is preferably Dowicil-75 (1-(3-chloroallyl)-3,5,7-triaza-1-azoniaadamantane chloride, available from Dow Chemical Company, Midland, Mich.), but may comprise other compounds which provide antimicrobial activity. 
   The Water Softener 
   The water softener is preferably sodium sesqui-carbonate (Na 2 CO 3 .NaHCO 3  2H 2 O available from Solutia, Inc., St. Louis, Mo.) which may also function as an alkaline buffer. Other water softening agents may be used which provide a reduction in calcium or magnesium hardness. 
   The Fragrance 
   The fragrance is preferably a lemon scent (available from Chemia Corp., St. Louis, Mo.), but may also provide other agents which provide a pleasant scent or odor absorbance. 
   As one skilled in the art will observe from the above descriptions of the preferred agents of the carpet cleaning solution, the foam generated by agitation of the solution applied to a carpet will acquire different properties when applied in different concentrations. For example, when applied in a 4 oz./gallon concentration, the cleaning solution easily penetrates to the carpet backing material. It is believed that the foam stabilizer and emulsifier are dilute enough at this concentration to reduce foam persistence and viscosity so that the cleaning solution may easily penetrate the lower layers of the carpet fiber thereby providing excellent cleaning power. 
   When applied in an 8 oz./gallon concentration, however, the foam does not easily penetrate the carpet backing, but remains substantially in the upper layer of carpet fibers. It is believed that the foam stabilizer and emulsifier become increasingly cross-linked as concentrations increase so that the foam takes on the consistency of a gel rather than loosely organized and compacted bubbles. Thus, the agents mixed in the carpet cleaning solution form a more viscous and concentrated mass of foam staying on the upper layer of carpet fiber thereby concentrating the active agents on the upper layer. Thus, the benefit of the carpet cleaning solution of the invention is not only the ability to use the same carpet cleaning solution applied in different concentration to perform two different cleaning tasks, but concentrating the carpet cleaning solution and foam on the upper layer of carpet fibers allows the user to clean more quickly, using less carpet cleaning solution, with greater ease, and allowing faster drying times. 
   The carpet will be substantially dry within two hours of applying the carpet cleaning solution of the invention to the carpet, preferably in less than two hours, and more preferably less than one hour. As used herein, the term “substantially dry” is preferably defined to mean dry to the human touch. As used in the EXAMPLES below, however, substantially dry can be objectively determined by measuring the moisture content of a carpet using an RF monitor (model “Protimeter Aquant”, available from Protimeter PLC, Marlow, United Kingdom). On a scale from 0 where no moisture is detected and 15 where 100% moisture saturation is detected, “substantially dry” is more preferably defined to mean obtaining less than a “level 3” reading on a scale of 15 of the RF Protimeter Aquant under normal temperature and humidity conditions, but in no case less dry than ambient humidity. 
   The preferred active agents of the carpet cleaning solution may be combined in different ranges depending on the desired characteristics the manufacturer may wish the solution and foam to embody. Generally, the formulation may comprise the eight agents mixed in amounts defined in TABLE 1 below. It will be appreciated, however, that the active agents may be applied alone in one embodiment of the invention. 
   
     
       
             
             
             
           
             
             
             
           
         
             
               TABLE 1 
             
             
                 
             
             
               Ingredient 
               Percent Weight 
               Percent Weight 
             
             
                 
             
           
           
             
                 
             
           
        
         
             
               Carboxylate Copolymer 
               0.100 
               1.000 
             
             
               Non-Bleach Optical Brightener 
               0.001 
               0.0025 
             
             
               1-(3-chloroallyl)-3,5,7-Triaza- 
               0.012 
               0.012 
             
             
               1-Azoniaadamantane Chloride 
             
             
               Sodium Tripoly-Phosphate 
               3.000 
               6.000 
             
             
               Sodium Sesqui-Carbonate 
               3.000 
               6.000 
             
             
               Sodium Lauryl Sulfate(30%) 
               0.400 
               1.500 
             
             
               Sodium Lauroyl Sarcosinate 
               0.400 
               1.500 
             
             
               Fragrance (Lemon) 
               0.0375 
               0.075 
             
             
               Polyethyleneoxide Modified 
               0.250 
               2.000 
             
             
               Trisiloxane Copolymer 
             
             
               Water 
               Remainder 
               Remainder 
             
             
               Total 
               100.00 
               100.00 
             
             
                 
             
           
        
       
     
   
   While the formulation of the carpet cleaning solution may comprise individual components within the ranges specified in TABLE 1, the preferred concentrations of the components are listed in TABLE 2 as follows: 
                                             TABLE 2                       Ingredient   Percent Weight                                        Carboxylate Copolymer   0.2500           Non-Bleach Optical Brightener   0.0015           1-(3-chloroallyl)-3,5,7-Triaza-1-   0.0120           Azoniaadamantane Chloride           Sodium Tripoly-Phosphate   4.8000           Sodium Sesqui-Carbonate   4.8000           Sodium Lauryl Sulfate (30%)   0.5000           Sodium Lauroyl Sarcosinate   0.5000           Fragrance   0.0375           Polyethyleneoxide Modified   0.5000           Trisiloxane Copolymer           Water   Remainder           Total   100.00                        
The solution of TABLE 2 is hereinafter referred to as the “Preferred Solution.”
 
C. The System
 
   The invention contemplates a system which combines the machine of Part A with the Mixture of Part B. When the machine is set up for a deep clean operation, the cleaning solution is formed by mixing about 4 ounces of cleaning mixture per gallon of clean water. When the machine is set up for a Fast Dry surface clean operation the cleaning solution is formed by mixing about 8 ounces of cleaning mixture per gallon of clean water. 
   After cleaning in the Deep Clean mode, a typical carpet is, on average, approximately 91% clean and takes longer than 2 hours to dry. After a cleaning in the Fast Dry Surface Clean mode the typical carpet is, on average, approximately 86% clean and takes less than 2 hours to dry. The testing parameters and standards used to determine the above characteristics are discussed in the Part E Testing section below. 
   D. The Method 
   A method of cleaning is disclosed by the invention. After a survey of the area to be cleaned a user chooses to proceed with a Deep Clean application or a Surface Clean application. The machine is then set up for the application. First the user moves selection mechanism  168  to the proper position. Second the user prepares the cleaning solution tank by mixing 4 ounces of cleaning mixture per gallon of clean water when the Deep Clean application is selected or 8 ounces of cleaning mixture per gallon of clean water when the Fast Dry surface application is selected. Finally the area to be cleaned is cleaned. 
   E. Testing 
   To define terms, the term “Standard Machine” is a standard “Mighty Pack” machine, available from Rug Doctor, L.P., Fenton, Mo. and a “Fast Dry Machine” is a modified 0.19 gallon per minute delivery rate (“GPM”) Mighty Pack machine. The track width of these machines is approximately 10.5 inches. Similar tests results were obtained using a modified 0.28 GPM “Wide Track” machine (available from Rug Doctor, L.P., Fenton, Mo.). The track width of this machine is approximately 12.5 inches. A 4 oz. per gallon solution of Steam Cleaner carpet cleaning solution (hereinafter “Steam Cleaner”, available from Rug Doctor, L.P., Fenton, Mo.) and a 4 oz. per gallon concentration of the Preferred Solution (defined below) of the invention were compared to hot water. 
   Extensive testing was performed on carpets made from different materials of construction. The solutions were tested on a ⅜ inch pile height Nylon Saxony Plush carpet ( FIG. 7 ), the most common type of carpet currently on the market. Similar results were derived from tests on Olefin loop and Nylon loop carpets. The carpet gauge was about 1/10 inch with 10 stitches per inch. The diluted solutions tested were approximately 110° F., ambient relative humidity between 21 to 32% and ambient temperature between 70 to 73° F. 
   The tests show in  FIG. 7  that the carpet cleaning system, when used with the Preferred Solution of the invention, at a concentration of 8 oz. per gallon dried in periods ranging from one to two hours, depending on the type of carpet tested. When the same carpets were cleaned with the standard Steam Cleaner solution in the Standard Machine at 4 oz. per gallon, the drying time was 3 to 7 hours depending on the type of carpet cleaned. When the carpets were cleaned with exactly the same concentration of the two cleaning solutions using the same machine, i.e., the Preferred Solution and the Steam Cleaner, the carpet cleaned with the Preferred Solution dried about 15% faster than that cleaned with the Steam Cleaner. This is believed to be due to the sheeting agent that allows the Preferred Solution to be spread into a thin film on the surface of the carpet fiber. The spreading of this film increases the surface area of the Preferred Solution and helps it dry quicker. The Active Detergent is also believed to be involved as the increased foam stability, increased viscosity, more uniform bubble size, and increased cross-linking between the polymers of the Emulsifying Agent and the Active Detergent act to keep the foam close to the top of the carpet fibers without penetrating to the carpet backing. Thus, the tests show that the combination of reduced flow and improved sheeting and foam characteristics of the Preferred Solution reduces drying time considerably. 
   Clean carpet strips were color measured using a Minolta Spectrophotometer (available from Minolta Corporation, Ramsey, N.J.) to determine an original color value. A standardized method of applying uniform soil to the carpet strips was developed to obtain precise and accurate measurements across data sets. The standardized method uses ajar mill with a Standard Soil mixture. The strips were then removed, vacuumed and color measured using the Minolta Spectrophotometer to determine a “Soil color” value. The soiled strips were then affixed to the floor. The carpet strips were then cleaned with the carpet cleaning solutions using a Deep Clean machine and a Surface Clean machine. 
   The carpet strips were cleaned with the Steam Cleaner and Preferred Solution using a Standard Machine for comparison. A linear cleaning rate of 30 feet per minute was used whenever possible. A pre-measured lateral overlap of two inches was allowed between strokes. The % Cleaning Efficiency was calculated after using the Minolta Spectrophotometer to determine the “clean color” value using the formula: 
   
     
       
         
           
             % 
             ⁢ 
             
                 
             
             ⁢ 
             Cleaning 
             ⁢ 
             
                 
             
             ⁢ 
             Efficiency 
           
           = 
           
             
               
                 ( 
                 
                   
                     Clean 
                     ⁢ 
                     
                         
                     
                     ⁢ 
                     Color 
                     ⁢ 
                     
                         
                     
                     ⁢ 
                     value 
                   
                   - 
                   
                     Dirty 
                     ⁢ 
                     
                         
                     
                     ⁢ 
                     Color 
                     ⁢ 
                     
                         
                     
                     ⁢ 
                     value 
                   
                 
                 ) 
               
               
                 ( 
                 
                   
                     Original 
                     ⁢ 
                     
                         
                     
                     ⁢ 
                     Color 
                     ⁢ 
                     
                         
                     
                     ⁢ 
                     value 
                   
                   - 
                   
                     Dirty 
                     ⁢ 
                     
                         
                     
                     ⁢ 
                     Color 
                     ⁢ 
                     
                         
                     
                     ⁢ 
                     value 
                   
                 
                 ) 
               
             
             × 
             100 
           
         
       
     
   
   Although the fast dry jet tips (delivering 0.19 GPM in the Mighty Pack machine and 0.28 GPM in the Wide Track machine) and deep clean jet tips (delivering 0.54 GPM in the Mighty Pack machine and 0.64 GPM in the Wide Track machine) of the invention are affected by the viscosity of the cleaning solutions and the pressure generated by the solution pump, the most important variable that was kept constant in the EXAMPLES below was the spray pattern. Different track widths, spray pattern widths, and liquid delivery rates are encompassed within the scope of the invention so long as the solution delivered by a dual mode machine is capable of producing the fast drying times presented in the invention. Other track widths, spraying patterns, spraying pattern widths, and jet tips may be used as one skilled in the art will observe. 
   EXAMPLE 1 
   Methods 
   A Standard Machine and a Fast Dry Machine were compared. A 4 oz. per gallon solution of Steam Cleaner and a 4 oz. per gallon Preferred Solution were used in the Standard Machine (applying the cleaning solutions at 0.54 GPM, or in the “deep cleaning mode”) and Fast Dry Machine (applying the cleaning solutions at 0.19 GPM, or in the “surface cleaning mode”) and were compared to hot water. The track width of these machines is approximately 10.5 inches. Similar tests results were obtained using a modified 0.28 GPM “Wide Track” machine (available from Rug Doctor, L.P., Fenton, Mo.). The track width of this machine is approximately 12.5 inches. 
   An acceptable cleaning standard for the Preferred Solution was arbitrarily targeted to be within 5% of the % cleaning efficiency result obtained from the Np machine using 4 oz./gallon of Steam Cleaner (87.33%−5%=82.33%). Test results show that the Preferred Solution in the preferred concentration actually improves the carpet cleaning results when comparing both the Preferred Solution of the invention and Steam Cleaner in the Standard Machine. 
     FIG. 5  shows the results of this test: 
   (a) Cleaning with a 4 oz./gallon concentration of the Preferred Solution in the deep cleaning mode, the average % cleaning efficiency is 91.03%. Cleaning with Steam Cleaner showed an average % cleaning efficiency of 87.33% compared to a baseline level of 54.1% using hot water in the deep cleaning mode. 
   (b) Cleaning with a 4 oz./gallon concentration of the Preferred Solution in the surface cleaning mode, the average % cleaning efficiency is 75.84%. However, using 4 oz/gallon concentration of the Steam Cleaner in the surface cleaning mode, the average cleaning efficiency drops to 52.36%, while plain hot water can only show baseline cleaning efficiency of 31.92% in the surface cleaning mode. 
   Results 
   From EXAMPLE 1(a), it is clear that the Preferred Solution outperforms the standard Steam Cleaner in the deep cleaning mode at 4 oz./gallon. This dilution is the preferred use level for the Preferred Solution in the deep cleaning mode. 
   From EXAMPLE 1(b), the results demonstrate that the cleaning performance of the Preferred Solution declines when used at 4 oz./gallon in the surface cleaning mode. However, the performance of the standard Steam Cleaner, at the same dilution decreases far more than that of the Preferred Solution. This demonstrates that a higher concentration of detergent is required for efficacious cleaning in the reduced flow mode. 
   EXAMPLE 2 
   Methods 
   A Standard Machine and a Fast Dry Machine were compared. An 8 oz. per gallon solution of Steam Cleaner and an 8 oz. per gallon Preferred Solution were used in the Standard Machine and the Fast Dry Machine, and were compared to hot water.  FIG. 6  shows the results of this test: 
   (a) Cleaning with a 8 oz./gallon concentration of the Preferred Solution in the deep cleaning mode, the average % cleaning efficiency is 94.0%. In comparison, cleaning with 8 oz./gallon concentration Steam Cleaner gave an average % cleaning efficiency of 90.0% and a baseline level of 54.1% using hot water, both in the deep cleaning mode. 
   (b) Cleaning with an 8 oz./gallon concentration of the Preferred Solution in the surface cleaning mode, the average % cleaning efficiency is 86.12%. However, using 8 oz./gallon concentration of Steam Cleaner in the surface cleaning mode, the average cleaning efficiency is merely 61.26%, while hot water can only show a baseline level of 31.92% in the surface cleaning mode. 
   Results 
   From EXAMPLE 2(a), the results show that the cleaning performance of the Preferred Solution and the standard Steam Cleaner is high (accepted performance levels when compared to the 82.33% benchmark of EXAMPLE 1) when used at 8 oz./gallon in the deep cleaning mode. However, from EXAMPLE 2(b), at 8 oz./gallon, the performance of the standard Steam Cleaner decreases to a “below acceptable” (below the 82.33% benchmark of EXAMPLE 1) level in the surface cleaning mode. At the same 8 oz./gallon concentration, the Preferred Solution shows an average cleaning efficiency that is acceptable in the surface cleaning mode. This dilution is the preferred use level for the Preferred Solution in the reduced flow mode. 
   Further experiments were run using carpets soiled in real-life conditions to obtain similar results. For example, cleaning a soiled carpet from a typical residence with an 8 oz./gallon concentration of the Preferred Solution in the surface cleaning mode, the average % cleaning efficiency improved to 88.42% from 86.12% in the controlled experiments. Thus, the slight variation in this result suggests that the results obtained in the laboratory will be comparable, if not better, in a real world environment. 
   A Nylon Saxony Plush carpet was used in this test, but similar results were obtained for various carpet fibers including Nylon Loop and Olefin Loop carpets. 
   Overall, it can be deduced from the above EXAMPLES that the Preferred Solution 1) provides acceptable cleaning in both the deep cleaning and surface cleaning modes of the carpet cleaning machine; 2) the preferred dilution ratios for the Preferred Solution are unique to the carpet cleaning machine of the invention; and 3) the combined performance of reduced drying time and cleaning efficiency cannot be achieved by using the standard Steam Cleaner solution. 
   The embodiments were chosen and described in order to best explain the principles of the invention and its practical application to thereby enable others skilled in the art to best utilize the invention in various embodiments and with various modifications as are suited to the particular use contemplated. 
   As various modifications could be made in the constructions and methods herein described and illustrated without departing from the scope of the invention, it is intended that all matter contained in the foregoing description or shown in the accompanying drawings shall be interpreted as illustrative rather than limiting. For example, ball valve  42  of selection mechanism  168  could be any multi-positional valve. In addition the two deep clean jet tips  60  could be replaced with a single jet tip  60 . Thus, the breadth and scope of the present invention should not be limited by any of the above-described exemplary embodiments, but should be defined only in accordance with the following claims appended hereto and their equivalents.