Patent Publication Number: US-8534301-B2

Title: Steam mop

Description:
The present invention claims priority on U.S. Provisional Patent Application Ser. No. 61/057,936 filed Jun. 2, 2008, all of which is incorporated herein by reference. 
     The present invention is directed to floor cleaning products, particularly to a floor mop, and more particularly to a steam floor mop. 
    
    
     BACKGROUND OF THE INVENTION 
     Hard floor surfaces such as wood floors, tile floors, linoleum floors, marble floors, granite floors, concrete floors, and the like are popular in homes and building structures. Commonly, foods, liquids, dirt and the like are dropped and/or tracked onto the floor surface, thereby staining the floor surface. Commonly, sponges, mops and the like are used to clean the floor surface. Various types of mops have been developed and a few are disclosed in U.S. Pat. Nos. D388,705; D420,561; D477,701; 5,888,006; 5,960,508; 5,988,920; 6,003,191; 6,045,622; 6,048,123; 6,101,661; 6,142,750; 6,328,543; 6,579,023; 6,601,261; 6,685,056; 6,722,806; 6,766,552; all of which are incorporated herein by reference. These mops include various features, structures and/or components which can be used in the steam mop of the present invention. 
     It has been found that many types of stains can be cleaned with the assistance of warm or hot water. Steam has also been found useful in cleaning tile grout and many hard to clean stains. Steam can also be used to facilitate in the cleaning of other types of surfaces. 
     Various types of steam mops and steam cleaners have been developed to clean floor surfaces. One such type of steam mops and steam cleaners are disclosed in U.S. Pat. Nos. D486,279; 5,386,612; 5,502,872; 5,907,879; 5,920,952; 6,571,421; 6,584,990; 6,895,626; 6,990,708; 7,059,011; 7,266,292; and United States Patent Publication Nos. 2002/0096201; 2003/0089383; 2006/01503632007/0079470; 2007/0130719; 2007/0169304; 2007/0209139; 2008/0034514; 2008/0066789; 2008/0236635; and 2009/0000051; and European Patent Publication Nos. EP1974647; EP1690488; EP1027855; and PCT Patent Application Publication Nos. WO 2009/008703; WO 2009/026203; and WO 2008/016741; all of which are incorporated herein by reference. Another commercially available steam mop is offered under the trade name THE SHARK. These steam mops include various features, structures and/or components which can be used in the steam mop of the present invention. 
     Although these various steam mops have been useful in the cleaning of various floor surfaces, many of the steam cleaning devices include a sponge or cleaning towelette through which steam is directed through, thus the stream does not directly contact the floor surface. In addition, these steam cleaning devices do not allow a user to easily direct steam to hard to access surfaces. 
     In view of the current state of the art of steam mops, there is a need for a steam mop that can direct steam directly onto a floor surface and which steam mop can be used to apply steam to hard to access surfaces. 
     SUMMARY OF THE INVENTION 
     The present invention is directed to a steam mop with which the steam can be directed onto a surface so as to clean the surface. The temperature of the steam from the steam mop can be selected so as to disinfect and/or sterilize a hard surface; however, this is not required. The steam mop can be designed to enable the steam generating device to be removed from the body of the steam mop so that the steam generating device can function as a hand-held unit which can be used to direct steam at hard to access surfaces (e.g., sink, area, counter surfaces, etc.); however, this is not required. 
     In one non-limiting aspect of the present invention, the steam mop includes a steam generator and a mop body. The mop body generally includes 1) a base mount for connecting the steam generator to the mop body, 2) an extension member connected to the base mount, 3) a handle connected to the extension member, and 4) a mop head connected to the base mount. As can be appreciated, the mop body can include other or additional components. As can also be appreciated, one or more of the components can be integrated into the steam generator; however, this is not required. The steam generator generally includes a liquid reservoir, a heating element, and a power cord and/or power source; however, this is not required. The steam generator can be designed to be permanently or removeably connected to the base mount. Although the steam generator generally includes a liquid reservoir or tank, it can be appreciated that the liquid reservoir or tank can be located on other or additional components of the steam mop. Likewise, if the steam generator is powered by a battery or other type of portable power supply, the power supply can be located in the stream generator and/or on other or additional components of the steam mop. The steam mop generally includes a manual and/or electrical pump that causes water or some other type of liquid in the liquid reservoir or tank to be directed to a heater in the steam generator to cause steam to be generated. As can be appreciated, one or more components of the manual and/or electrical pump can be located in the stream generator and/or on other or additional components of the steam mop. The mop head can include or be designed to be connected to one or more scrubbing and/or absorbent implements such as, but not limited to, a sponge, brush, towel, towelette or the like; however, this is not required. The scrubbing and/or absorbent implement can be releaseably connected to the mop head; however, this is not required. The scrubbing and/or absorbent implement, when used, can be connected to the mop head in a variety of ways and by a variety of arrangements. The mop head can be integrally formed with the base mount; however, this is not required. The mop head can be designed to move (e.g., pivot, swivel, etc.) relative to the base mount; however, this is not required. 
     In another and/or alternative non-limiting embodiment of the invention, the steam mop is designed to direct at least a portion of the steam on a floor surface that is in front of and/or behind the mop head. In many prior art steam mops, the generated steam is discharged from the base of the steam mop. In such a configuration, the steam is directed onto the top surface of the scrubbing and/or absorbent implement, thus little, if any, of the steam actually contacts a floor surface. In such prior art arrangements, the steam essentially heats and moistens the scrubbing and/or absorbent implement on the base of the steam mop. The steam mop of the present invention is designed to at least partially direct steam directly on a floor surface so as to improve the cleaning effectiveness of the steam mop. In one non-limiting embodiment of the invention, one or more steam nozzles are designed to direct one or more streams of steam forwardly of the mop head that is connected to the base mount of the steam mop. Such an arrangement enables steam to be applied directly onto a floor surface so as to facilitate in the loosening or dissolving of dirt, grime, etc. on the floor surface so that the scrubbing and/or absorbent implement on the mop head can better clean the floor surface. In one non-limiting design, 2-6 steam nozzles are connected to the base mount and/or mop head and project steam forwardly of the mop head. In another and/or alternative non-limiting embodiment of the invention, one or more steam nozzles are designed to direct one or more streams of steam rearwardly of the mop head that is connected to the base mount of the steam mop. In still another and/or alternative non-limiting embodiment of the invention, one or more steam nozzles are designed to direct one or more streams of steam into the mop head so that a portion of the steam is directed onto the top surface of the scrubbing and/or absorbent implement that is connected to the mop head. 
     In still another and/or alternative non-limiting embodiment of the invention, the steam mop is designed to enable the steam generator to be removably connected to the base mount of the steam mop so that the steam generator can also be used as a handheld cleaner to apply steam to hard to access locations, and/or to enable the steam generator to apply steam to areas other than a floor (e.g., sink, counter, wall, etc.). When the steam generator is designed to be removably connected to the base mount of the steam mop, the steam generator typically includes a self contained liquid reservoir, a heating element, a power cord and/or power source, and a manual or electric pump; however, this is not required. In this embodiment, the base mount is designed to releasably connect the steam generator to the steam mop. Many different arrangements can be used to enable the steam generator to be releasably connectable to the base mount. Such an arrangement enables the steam mop to function as a 3 in 1 tool, namely 1) a steam mop that generates steam, 2) a regular non-steam generating mop when the steam generator is detached form the steam mop, and 3) a hand-held steam generator. In a modification to this embodiment, the steam mop can include an accessory that can be attached to the base mount instead of the steam generator. For instance, a container that includes cleaning fluid can be connected to the steam mop instead of the steam generator so that the steam mop can apply cleaning fluid instead of steam to the floor surface. In some situations, a user may want to apply a cleaning fluid to the floor instead of a steam. Due to the configuration of the steam generator, certain types of cleaning fluids may potentially damage the steam generator, especially when such cleaning fluids are heated. Furthermore, the user many not want to vaporize certain cleaning fluids when cleaning a floor surface. As such, the steam mop of the present invention can include a container that can be substituted for the steam generator to allow the user to increase the versatility of the steam mop of the present invention. The container can be filled with water or various types of cleaning solutions. In this arrangement, non-heated water or non-heated cleaning solution would be applied to the floor surface. As such, the steam mop thus becomes a 4 in 1 tool. 
     In yet another and/or alternative non-limiting embodiment of the invention, the steam mop is designed to enable the user to hand pump liquid into the steam generator. In one non-limiting arrangement, the handle and extension member and/or the extension member and the base mount include a manual pump mechanism and/or a manual mechanism that activates a pump mechanism in the steam generator. In one non-limiting design, the handle is designed to pivot relative to the extension member so as to at least partially activate a pump that is located in the extension member, the base mount, and/or the steam generator. In such a design, a user pivots the handle during use of the steam mop to cause the pump to actuate and thereby cause fluid to enter the heating element in the steam generator so that steam is generated by the steam generator. In another non-limiting design, the handle is designed to telescopically receive a portion of the extension member so as to at least partially activate a pump that is located in the extension member, the base mount, and/or the steam generator. In such a design, a user pushes the handle to cause a portion of the extension member to move into and out of a cavity in the handle during the use of the steam mop to cause a pump to actuate and thereby cause fluid to enter the heating element in the steam generator so that steam is generated by the steam generator. In still another non-limiting design, the extension member is designed to telescopically receive a portion of the handle so as to at least partially activate a pump that is located in the extension member, the base mount, and/or the steam generator. In such a design, a user pushes the handle to cause a portion of the handle move into and out of a cavity in the extension member during the use of the steam mop to cause a pump to actuate and thereby cause fluid to enter the heating element in the steam generator so that steam is generated by the steam generator. In yet another non-limiting design, the extension member is designed to telescopically receive a portion of the base mount so as to at least partially activate a pump that is located in the extension member, the base mount, and/or the steam generator. In such a design, a user pushes the handle to cause a portion of the base mount move into and out of a cavity in the extension member during the use of the steam mop to cause a pump to actuate and thereby cause fluid to enter the heating element in the steam generator so that steam is generated by the steam generator. In still yet another non-limiting design, the base mount is designed to telescopically receive a portion of the extension member so as to at least partially activate a pump that is located in the extension member, the base mount, and/or the steam generator. In such a design, a user pushes the handle to cause a portion of the extension member move into and out of a cavity in the base mount during the use of the steam mop to cause a pump to actuate and thereby cause fluid to enter the heating element in the steam generator so that steam is generated by the steam generator. In a further non-limiting design, a pump lock can be used in any of the manual pump arrangements discussed above; however, this is not required. The pump lock, when used, can be designed to deactivate the pump so that even when there is some pivot action or telescopic movement of one or more components of the steam mop, the pump does not actuate; however, this is not required. In addition or alternatively, the pump lock can be used to prevent some pivot action or telescopic movement of one or more components of the steam mop during use of the steam mop, thereby preventing actuation of the pump of the steam mop; however, this is not required. As can be appreciated, many different arrangements can be used for the pump lock, when used. 
     In still yet another and/or alternative non-limiting embodiment of the invention, the steam mop is designed to enable the user to pump liquid (e.g., water, etc.) into the steam generator by use of an electric motor. In one non-limiting arrangement, the handle includes a switch that enables a user to actuate the switch to thereby activate and deactivate a motor pump that is located in the handle, the extension member, the base mount and/or the steam generator. 
     In another and/or alternative non-limiting embodiment of the invention, the steam mop can be designed to include a pivoting and/or swivel connection between the base mount and mop head so as to facilitate maintaining the desired orientation of the scrubbing and/or absorbent implement on the mop head as the scrubbing and/or absorbent implement is moved over a floor surface. 
     In still another and/or alternative non-limiting embodiment of the invention, the steam mop includes a handle; an extension member; a base mount; a steam generator that includes a manual liquid pump, a liquid tank, a heating element; a mop head; and a scrubbing and/or absorbent implement. The scrubbing and/or absorbent implement can be designed to be removably connected to the mop head. The mop head can be designed to have a pivot and/or swivel connection to the base mount so as to facilitate in maintaining the desired orientation of the scrubbing and/or absorbent implement on a floor surface as the scrubbing and/or absorbent implement is moved over the floor surface. The steam generator includes a housing that at least partially encases the manual liquid pump, the liquid tank, the heating element. The housing of the steam generator can be designed to be releasably connected to the base mount of the steam mop. The manual pump actuation arrangement can be formed by the extension member and the base mount so as to manipulate the amount of liquid directed into the heating element of the steam generator. The housing of the steam generator can also include a separate pump actuation arrangement used to manipulate the amount of liquid directed into the heating element of the steam generator. 
     In yet another and/or alternative non-limiting embodiment of the invention, the steam mop includes a steam generator that includes a housing and an electric heating element that is used to at least partially vaporize liquid. 
     In still yet another and/or alternative non-limiting embodiment of the invention, the steam mop is designed to generate steam by pushing the handle of the steam mop during the use of the steam mop. The steam generated by the steam mop can be used to clean and/or high-temperature disinfect and/or sterilize a hard surface. 
     In another and/or alternative non-limiting embodiment of the invention, the steam generator includes a specially designed heating element that at least partially preheats liquid prior to vaporizing the liquid. In many prior art heating elements, a liquid is aimed directly onto a heated portion of the heating element to cause the liquid to vaporize on contact with the heated portion. However, when too much liquid is conveyed to the heated portion of the heating element, some of the liquid does not have time to vaporize, thus exiting the heating element still in liquid form. The heating element of the present invention is designed to preheat at least a portion of the liquid prior to the liquid contacting the heated portion of the heating element that is used to vaporize the liquid. The preheating of the liquid in the heating element results in the liquid substantially completely vaporizing when such preheated liquid contacts the heated portion of the heating element. The complete or substantially complete vaporization of the liquid in the heating element results in a drier steam being formed by the heating element as compared with prior art heating elements. The drier steam is believed to be more effective in cleaning hard surfaces. In addition, the drier stream can be used to clean carpets, upholstery, and other fabric surfaces. 
     In still another and/or alternative non-limiting embodiment of the invention, the steam generator includes a specially designed heating element that divides the liquid pumped to the heating element into a plurality of liquid streams. One or more of the liquid streams can be preheated prior to the vaporization of the liquid stream; however, this is not required. One or more of the liquid streams can be combined together prior to being directed on to the heated portion of the heating element that is used to vaporize the liquid; however, this is not required. One or more of the liquid streams can be directed to different regions on the heated portion of the heating element that is used to vaporize the liquid; however, this is not required. The dividing of the liquid streams in the heating element has been found to result in the liquid being substantially completely vaporized when such liquid contacts the heated portion of the heating element. The complete or substantially complete vaporization of the liquid in the heating element results in a drier steam being formed by the heating element as compared with prior art heating elements. 
     In one non-limiting object of the present invention, there is provided a steam mop which can distribute steam on a hard surface such as a floor. 
     In another and/or alternative one non-limiting object of the present invention, there is provided a steam mop that is compact, easy to maneuver, and simple and safe to use. 
     In still another and/or alternative one non-limiting object of the present invention, there is provided a steam mop particularly adapted for cleaning floors in the home. 
     In yet another and/or alternative one non-limiting object of the present invention, there is provided a steam mop which can distribute steam on a hard surface by pushing the handle of the steam mop. 
     In still yet another and/or alternative one non-limiting object of the present invention, there is provided a steam mop which can distribute steam on a hard surface by pushing the handle of the steam mop wherein in the handle includes a telescoping pump mechanism. 
     In another and/or alternative one non-limiting object of the present invention, there is provided a steam mop which can perform cleaning work in a convenient and time and labor efficient manner. 
     In still another and/or alternative one non-limiting object of the present invention, there is provided a steam mop which can high temperature disinfect and/or sterilize a hard surface. 
     In yet another and/or alternative one non-limiting object of the present invention, there is provided a steam mop which includes a removable steam generator for handheld use. 
     In still yet another and/or alternative one non-limiting object of the present invention, there is provided a steam mop which directs steam forwardly of the base of the mop head so that steam directly contacts a hard surface to be cleaned. 
     In another and/or alternative one non-limiting object of the present invention, there is provided a steam mop generating dry stream. 
     These and other objects and advantages will become apparent to those skilled in the art upon reading and following the description taken together with the accompanying drawings. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       Reference may now be made to the drawings which illustrate various preferred embodiments that the invention may take in physical form and in certain parts and arrangement of parts wherein: 
         FIG. 1  is a perspective view of one non-limiting embodiment of the steam mop of the present invention; 
         FIG. 2  is a cross-section view of the steam generator that is mounted in the base mount of the steam mop; 
         FIG. 3  is a partial sectional view of the mop head of the steam mop that is connected to the base mount; 
         FIG. 4  is a bottom view of the mop head and a section view of the scrubbing and/or absorbent implement that is connected to the mop head; 
         FIG. 5  illustrates the steam generator being releasably connected to the base mount of the steam mop; 
         FIG. 6  is a partial sectional view of the steam generator; 
         FIG. 7  is a side view of the steam generator having a spray attachment connected to the front end of the steam generator; 
         FIG. 8  is an enlarged cross-section of the spray attachment that is connected to the front end of the steam generator; 
         FIG. 9  is an enlarged view of the front end of the steam generator; 
         FIG. 10  is a partial sectional view of the spray attachment; 
         FIG. 11  is one non-limiting perspective view of the heating element of the steam generator; 
         FIG. 12  a bottom view of the heating element of  FIG. 11 ; 
         FIG. 13  is a cross-sectional view along line  13 - 13  of  FIG. 11 ; 
         FIG. 14  is a cross-sectional view along line  14 - 14  of  FIG. 11 ; and, 
         FIG. 15  is a cross-sectional view along line  15 - 15  of  FIG. 11 . 
     
    
    
     DETAILED DESCRIPTION OF THE NON-LIMITING EMBODIMENT 
     Referring now to the drawings wherein the showings are for the purpose of illustrating a preferred embodiment of the invention only and not for the purpose of limiting same,  FIGS. 1-10  illustrate one non-limiting embodiment of the present invention. 
       FIG. 1  illustrates a steam mop  20  comprising a handle  30 , an extension member  40 , a base mount  70 , a mop head  150  a cleaning cloth  156  that is removably connected to the mop head  150 , and a steam generator  160 . 
     The handle  30  is illustrated as having a bend top portion to facilitate in the grasping of the handle by a user. As can be appreciated, the bend portion on the handle is optional. Indeed, the handle can have many different configurations to make the handle ergonomically pleasing for use by a user and/or to facilitate in the grasping of the handle. All such configurations can be used in the present invention. The materials used to form the handle are non-limiting. The handle can include a compressible portion for facilitating in the grasping of the handle; however, this is not required. The handle can include gripping materials for facilitating in the grasping of the handle; however, this is not required. 
     Handle  30  is illustrated as being connected to a top end  46  of extension member  40 . The handle can be integrally formed on the top end  46  of the extension member or be designed to connect to the top end  46  of the extension member during the assembly of the steam mop. When handle  30  is designed to be connected to the top end  46  of the extension member, the manner in which the connection is formed is non-limiting. The handle can be designed to move (e.g., pivot, swivel, twist, move along the longitudinal length of the extension member, etc.) relative to top end  46  of the extension member, or be designed to be rigidly connected to the top end  46  of the extension member. As illustrated in  FIG. 1 , handle  30  is rigidly connected to the top end  46  of the extension member. 
     The extension member  40  can be formed of a single piece or be formed of multiple pieces. When the extension member is formed of multiple pieces, the pieces can be secured together in any number of ways. As illustrated in  FIG. 1 , the extension member  40  is formed of an upper section  42  and a lower section  44 . The length of the lower and upper sections is non-limiting. Generally, the length of the two sections is about the same; however, this is not required. The extension member can be formed of any number of materials. The length of the extension member is non-limiting. The cross-sectional shape of the extension member is illustrated as being generally circular; however, other cross-sectional shapes can be used. The extension member can be formed from a tubular material; however, this is not required. 
     Two cord brackets  60 ,  62  are illustrated as being connected to upper section  42 . The cord brackets are optional. The cord brackets, when used, can be used by a user to wind the power cord  208  that is used to supply power to the steam generator  160 . 
     Referring now to  FIG. 2 , the bottom end  48  of the extension member  40  is positioned in a tube cavity  74  of base mount  70 . Tube cavity  74  has a cross-section shape, cross-sectional size and longitudinal length to enable the lower portion of the lower section  44  of the extension member to move along a portion of the longitudinal length of the tube cavity. Generally the cross-sectional shape of the tube cavity is the same or similar to the cross-sectional shape of the lower portion of the lower section  44  of the extension member; however, this is not required. Generally, the cross-sectional size of the tube cavity is slightly larger than the cross-sectional size of the lower portion of the lower section  44  of the extension member; however, this is not required. The longitudinal length of the tube cavity is non-limiting. 
     As illustrated in  FIG. 2 , a leg extension  50  is designed to engage the bottom end  48  of the extension member  40 . The leg extension  50  can be connected the bottom end  48  of the extension member  40 ; however, this is not required. When the bottom end  48  of the extension member  40  is connected to the leg extension  50 , leg extension  50  can be integrally formed on the bottom end  48  of the extension member  40 ; however, this is not required. As illustrated in  FIG. 2 , leg extension  50  is a separate component from lower section  44  of the extension member and is not connected to the lower section  44  of the extension member. In this arrangement, the leg extension  50  is maintained within the tube cavity  74 . Any number of means can be used to maintain the leg extension  50  within the tube cavity. In addition, the lower portion of the extension member  40  is designed to be movably secured in the tube cavity so as to allow limited longitudinal movement within the tube cavity, but prevent the lower portion of the extension member  40  from being fully removed from the tube cavity. Many different means can be used to allow for such a connection arrangement. The connection arrangement can also be used to limit the rotational movement of the extension member within tube cavity  74 ; however, this is not required. The tube cavity and/or the lower portion of the extension member can include a releasable connector that would enable a user to release the lower portion of the extension member from the tube cavity; however, this is not required. 
     As illustrated in  FIG. 2 , leg extension  50  includes a side arm  52  that extends through side opening  76  of the tube cavity  74 . The height of the side opening  76  can be used to limit the amount of longitudinal movement of the leg extension  50  within tube cavity  74 ; however, this is not required. The width of the side opening  76  can also be used to limit the rotational movement of the leg extension  50  within tube cavity  74 ; however, this is not required. As will be discussed in more detail below, leg extension  50  is used to actuate a pump in steam generator  160  when the leg extension  50  is moved longitudinally within tube cavity  74  during operation by a user. 
     As also illustrated in  FIG. 2 , a biasing member  58  is positioned in the base of the tube cavity. The biasing member  58  is generally in the form of a spring; however, other or additional types of biasing members can be used. The biasing member can be connected to the base of the tube cavity and/or to the bottom of leg extension  50 ; however, this is not required. The biasing member is designed to bias the leg extension  50  away from the base of the tube cavity. As can be appreciated, other or additional means can be used to bias leg extension  50  away from the base of the tube cavity. 
     Referring now to  FIGS. 1 ,  2  and  5 , base mount  70  is designed to releasably connect steam generator  160  to the steam mop  20 . The base mount can be formed of one or more pieces. When the base mount is formed of more than one piece, the pieces can be connected together in a number of way. The materials used to form the base mount are non-limiting. Base mount  70  includes a body  72  that includes a tube cavity  74  having a side opening  76  that form a passageway to the front face  78  of body  72 . The front face  78  of body  72  is shaped and contoured to mate with the bottom face  164  of the body  162  of the steam generator  160  as illustrated in  FIG. 2 . One portion of the front face includes a notch  80  that functions as a landing for a rib portion  166  on the bottom face  164  of the body  162  of the steam generator  160 . As can be appreciated, notch  80  is an optional feature on the front face  78  of body  72 . The bottom portion of the front face includes a sloped portion  82  that begins below notch  80 . As can be appreciated, sloped portion  82  is optional. As also can be appreciated, the front face  78  of body  72  can include other or additional configurations, profiles and the like that can be used to mate with bottom face  164  of the body  162  of the steam generator  160  and/or to stabilize the steam generator  160  when mounted to base mount  70 . 
     A locking mechanism  84  is located on the top portion of the base mount  70 . The locking mechanism is designed to releasably lock the body  162  of the steam generator  160  to the front face  78  of body  72  of base mount  70 . As can be appreciated, other or additional arrangements can be used to releasably lock the body  162  of the steam generator  160  to the front face  78  of body  72  of base mount  70 . As illustrated in  FIGS. 2 and 5 , locking mechanism  84  includes a locking latch  86  having a lift arm  88  and lock leg  90 . The lift arm  88  includes a curved profiled for the bottom surface  92  that is shaped to facilitate in a user grasping the bottom surface with one or more fingers and upward lift the lift arm. As can be appreciated, the curved profiled of bottom surface  92  is optional. As also can be appreciated, bottom surface  92  can have other or additional configurations to facilitate in a user grasping the bottom surface with one or more fingers and upward lift the lift arm. The back face  94  of body  72  includes a flange  96  that can also be used by a user to facilitate in upwardly lift the lift arm  88 . As can be appreciated, flange  96  is optional. The locking latch  86  is designed to be biased in a downward position by a biasing arrangement  102 . As illustrated in  FIGS. 2 and 5 , the biasing arrangement is in the form of a spring; however, other or additional arrangements can be used to bias the locking latch  86  in a downward position. As also can be appreciated, the use of a biasing arrangement is optional. The biasing arrangement is illustrated as being positioned in a spring cavity  104  that is located in body  72  of base mount  70 . 
     As illustrated by the arrows in  FIG. 5 , the upward lifting of lift arm  88  results in the locking latch  86  being upwardly lifted. The lift arm can be designed to be inserted through a locking slot in body  72  of base mount  70 , not shown, or be configured to be inserted about a portion of the base mount. As can be appreciated, many different configurations for the locking latch  86  can be used. The upward lifting of locking latch  86  results in the upward lift of lock leg  90 . As illustrated in  FIG. 2 , when locking latch  86  is a lower locked position, lock leg  90  is positioned in the lock cavity  168  in the body  162  of the steam generator  160 . Lock leg  90  includes a downward extension  100  that is designed to engage a wall  170  of lock cavity  168  to thereby secure the body  162  of the steam generator  160  to the front face  78  to body  72  of base mount  70 . When the lift arm  88  is lifted as illustrated by the arrows in  FIG. 5 , the downward extension  100  on lock leg  90  is caused to lift upwardly and out of lock cavity  168  in the body  162  of the steam generator  160 , thereby releasing the body  162  of the steam generator  160  to the front face  78  to body  72  of base mount  70 . Thereafter, the steam generator  160  can be removed from base mount  70  as illustrated by the arrow in  FIG. 5 . 
     As best illustrated in  FIGS. 2 ,  3  and  5 , a steam nozzle receptacle  106  forms the bottom portion of base mount  70 . The steam nozzle receptacle can be integrally formed with the base mount  70  or can be connected to the base mount  70  by a variety of means. As illustrated in  FIGS. 2 ,  3  and  5 , the steam nozzle receptacle can be integrally formed with the base mount. The interior cavity  108  of the steam nozzle receptacle has a generally conical shape; however, the interior cavity  108  of the steam nozzle can have other shape. The top portion  110  of the cavity  108  can be formed at an angle to facilitate in the insertion and the removal of the end of the stream generator in and out of the cavity; however, this is not required. As can be appreciated, the top portion of the cavity can be shaped in many different ways. 
     A nozzle interface  112  that includes a nozzle cavity  114  is positioned in the base of cavity  108 . The nozzle cavity is designed to at least partially telescopically receive a portion of the end of vapor nozzle  216  of the steam generator  160 . The nozzle interface can be integrally formed in the base of the cavity or be connected to the cavity in any number of ways. Positioned adjacent to the nozzle interface  112  is a drain passage  116  to allow liquid to drain from the base of cavity  108 . The inclusion of the drain passage in cavity  108  is not required. As best illustrated in  FIG. 2 , a steam passage  118  is fluidly connected to the bottom of the nozzle cavity  114 . Connected to the end of the steam passage is a steam hose  120 . The steam hose can be connected to the end of the steam passage in a variety of ways. The steam hose is generally a flexible hose; however, this is not required. The steam hose can include a insulating covering; however, this is not required. As illustrated in  FIG. 3 , the steam hose passes through the bottom cavity  122  of the base mount and connects to an inlet opening  126  of the front sprayer  124 . 
     Referring now to  FIGS. 3 and 4 , the front sprayer  124  is connected to the bottom surface  130  of the spray cover  128 . The front sprayer  124  is illustrated in  FIG. 4  as having a slight V-shape; however, this is not required. The spray cover is illustrated in  FIG. 3  as being connected to mop head  150  and steam nozzle receptacle  106  of the base mount; however, this is not required. As illustrated in  FIG. 3 , the steam nozzle receptacle  106  is pivotally connected to the spray cover  128  and the mop head is rigidly connected to the spray cover  128 . The rigid connection between the mop head and the spray cover  128  results in a set relationship between the three sprayers  132  on the front sprayer  124  and the mop head  150 . The three sprayers  132  are positioned on the underside of the spray cover  128  so as to direct steam that is flowing into the front sprayer  124  forwardly of the mop head so that the steam contacts floor surface F during the use of the steam mop as illustrated in  FIG. 3 . As illustrated in  FIG. 4 , one or more screws  134  are used to secure front sprayer  124  to the bottom surface  130  of the spray cover  128 ; however, it will be appreciated that other or additional connection arrangements can be used. One or more of sprayers  132  can be configured to direct steam forwardly of the mop head. As can be appreciated, front sprayer  124  can include less than three sprayers  132  or more than three sprayers  132 . As can also be appreciated, one or more of the sprayers  132  can direct steam forwardly of the mop head  150  and one or more of the sprayers  132  can direct steam fully or partially on the mop head and/or cleaning cloth  156  that is connected to the mop head. As can also be appreciated, two or more of the sprayers  132  can direct steam at the same or different distance forwardly of the mop head  150 . Generally, sprayers  132  direct a majority of the steam at about 0.25-6 inches forwardly of the mop head  150  the mop head and/or cleaning cloth  156  is contacting the floor surface, and typically about 0.25-4 inches forwardly of the mop head  150 ; however, other distances can be set. The front lip  136  of the spray cover  128  is illustrated in  FIG. 3  as angling downwardly toward the floor surface F when the mop head and/or cleaning cloth  156  is contacting the floor surface. This configuration of the spray cover facilitates in directing steam S exiting the sprayers  132  to the floor surface as illustrated in  FIG. 3 . As can be appreciated, this design of the spray cover is optional and many other configurations of the spray cover can be used. As mentioned above, the rigid connection between the mop head and spray cover  128  results in sprayers  132  always directing steam to a desired location on floor surface F during the operation of the steam mop. The rigid connection between the mop head and spray cover  128  can be achieved in many different ways. The mop head and spray cover can be formed of one piece or can be formed of a plurality of pieces. The pivot connection between the steam nozzle receptacle  106  and spray cover  128  allows a user to move the handle  30  upwards and downwards during the cleaning of floor surface F while also maintaining mop head in contact with the floor surface and also steam to a desired location on floor surface F during the operation of the steam mop. The pivot connection between the steam nozzle receptacle  106  and spray cover  128  can be formed in a variety of ways. 
     As illustrated in  FIGS. 3 and 4 , the mop head  150  includes a cleaning cloth  156  connected to the mop head. The cleaning cloth  156  is generally designed to be removably connected to the mop head so that the cleaning cloth  156  can be periodically washed and/or replaced. The cleaning cloth  156  can be formed of many different materials. The cleaning cloth  156  may include a stretchable band or string type arrangement  158  that is threaded through opening  159  at an edge of the cleaning cloth. The stretchable band or string type arrangement  158  is used to secure the cleaning cloth to the mop head; however, it can be appreciated that other or additional means can be used to connect the cleaning cloth to the mop head. Non-limiting arrangements of various additional or alternative arrangements for connecting the cleaning cloth to the mop head  150  are illustrated in US 2003/0089383; US 2007/0130719; U.S. Pat. Nos. 6,584,990; 6,895,626; 6,990,708; and 7,266,292, all of which are incorporated herein by reference. The base  152  of the mop head includes a plurality of ribs  154 ; however, this is not required. As can be appreciated, base  152  can be a flat surface or have some other configuration. 
     Referring now to  FIGS. 2 ,  3  and  5 , the steam generator  160 , as mentioned above, is designed to be releasably connected to the base mount  70 . Steam mop  160  includes a body  162  having a bottom face  164  that is designed to engage and connected to the base mount  70 . A positioning rib  166  is located on bottom face  164  and is designed to be at least partially inserted into notch slot  80  in the front face  78  of body  72  of base mount  70 . As mentioned above, when the steam generator is connected to the base mount, the positioning rib  166  and the slot  80  are used to properly position the steam generator in base mount. As can be appreciated, positioning rib  166  and/or the slot  80  are optional. As can be appreciated, positioning rib  166  and back leg  167  can be used to enable the steam generator to be set on a flat surface when the steam generator is removed form the base mount  70 ; however, this is not required. Bottom face  164  also includes a lock cavity  168  that is designed to receive a portion of lock leg  90  of locking latch  86 . As illustrated in  FIG. 2 , the downward extension  100  on lock leg  90  is designed to engage wall  170  in lock cavity  168  to thereby releasably secure the steam generator to the base mount. As illustrated in  FIG. 5 , the steam generator is easily released from the base mount by merely lifting lift arm  88  as illustrated by the arrows to cause downward extension  100  on lock leg  90  to lift upwardly and release from wall  170  in lock cavity  168 , thereby enabling the body  162  of the steam generator  160  to be lifted out of the base mount as illustrated by the arrow in  FIG. 5 . As is readily apparent from the sloped configurations of downward extension  100  on lock leg  90  and the front face of wall  170  in lock cavity  168 , such sloped surfaces facilitate in the re-connection of the body of the steam generator to the base mount. As can be appreciated, such sloped surfaces are optional. As can also be appreciated, the lock leg  90  and/or wall  170  can include other or additional configurations to facilitate in the connection and/or removal of the steam generator to/from the base mount. 
     Referring now to  FIG. 2 , the bottom face  164  of body  162  of the steam generator includes a pump slot  172 . Positioned in the pump slot is the front portion of a pump leg  174 . The rear portion of the pump leg is connected to the end of a pump piston  176  of pump  178 . Pump  178  is illustrated as being a manual pump; however, it can be appreciated that pump  178  can be an electric pump. A pump spring  180  is positioned between the end of the pump piston and the housing of pump  178  to bias the pump piston in an extended position. As can be appreciated, pump spring can be designed to bias the pump piston in an unextended position. The use of pump spring  180  is optional. The top surface of the front portion of a pump leg  174  is designed to engage the bottom surface of side arm  52  of leg extension  50 . As illustrated by the arrows in  FIG. 2 , when a user pushes and pulls the steam mop over a floor surface F, such action causes the lower section  44  of the extension member to move longitudinally in tube cavity  74 . Such longitudinal movement of lower section  44  results in the upward and downward movement of side arm  52  within side opening  76  of the base mount as illustrated by the arrow in  FIG. 2 . The upward and downward movement of side arm  52  in turn causes pump leg  174  to also move upwardly and downwardly in pump slot  172  as illustrated by the arrow in  FIG. 2 . The upward and downward movement of pump leg  174  causes pump piston  176  of pump  178  to create a pump action in pump  176  as illustrated by the arrow in  FIG. 2 . The actuation of pump  176  causes fluid W in fluid tank  182  to be drawn through tank opening  184  and into a fluid tube  186  and then to pump  176 . Pump  176  then causes the fluid to flow from pump  176  through another fluid tube  186  to the heating element  196  of the steam generator. The arrows in  FIG. 2  illustrate one non-limiting tubing and pumping configuration to enable fluid such as water to be pumped from the fluid tank  182  to the heating element  196  of the steam generator when the steam generator is connected to the base mount and a user is using the steam mop to clean a floor surface F. As can be appreciated, the positioning of one or more components in the body  162  of the of the steam generator  160  is non-limiting; as such the component configuration illustrated in  FIG. 2  is just one of many component configurations that can be used. 
     As illustrated in  FIG. 2 , the fluid tank  182  is designed to supply fluid to the heating element  196  of the steam generator. The fluid tank can be filled by a user by simply removing cap  190  located on the outside surface of body  162 . The cap is generally thread onto body  162 ; however, cap  190  can be secured to body  162  in other ways. When cap  190  is removed, user can empty fluid tank  182  by pouring any liquid in the fluid tank out of top tank opening  192 , or can fill the fluid tank by pouring fluid into top tank opening  192 . 
     As mentioned above, heating element  196  is designed to vaporize fluid such as water that is directed to the heating element  196 . The heating element can have many different configurations. In one non-limiting configuration, the heating element  196  includes an optional preheating tube  260  that is connected to the outer body surface of the heating element as illustrated in  FIGS. 11-14 . The preheating tube, when used, is generally formed of a heat conducting metal material. As illustrated in  FIGS. 11-13 , when the heating element includes preheating tube  260 , a fluid tube  198  directs fluid into an entry opening  262  of the preheating tube  260 . When the heating element does not include a preheating tube, fluid tube  198  directs fluid into opening  200  of the heating element  196  as illustrated in  FIG. 2 . As illustrated in  FIG. 12 , preheating element  260  is connected to the bottom surface  197  of the heating element by brackets  264 . The brackets are illustrated as being connected to bottom surface  197  by screws  266 . As can be appreciated, the preheating tube can be connected to the heating element in other or additional ways (e.g., weld, solder, adhesive, etc.). The preheating tube is illustrated as a U-shaped component; however, many other shapes can be used. The preheating tube is illustrated as being connected to the bottom surface of the heating element; however, it can be appreciated that the preheating tube can be connected to other or additional regions of the heating element. When the heating element is activated, the heating element can be designed to allow one or more portions of the body surface to rapidly rise in temperature. On these one or more portions of the body surface, the preheating tube can be connected to cause fluid in the preheating tube to be preheated as the fluid flows through the tube as indicated by the arrows in  FIGS. 11-13 . It has been found that a drier steam can be formed by the preheating of the fluid. 
     Once the fluid is preheated, the preheated fluid can then be directed into the main heating chamber of heating element  196 . As illustrated in  FIGS. 11-13 , the preheated fluid exiting the preheating tube enters tube  268  that is designed to direct fluid into opening  200  of the heating element  196 . Tube  268  can include an insulating wrapping, not shown; however, this is not required. Tube  268  can be formed of many different types of materials (e.g., plastic, metal, polymer, etc.). The main heating chamber  270  of heating element  196  can be designed to divide the fluid stream into a plurality of fluid streams; however, this is not required. If has been found that when the fluid streams are divided into two or more fluid streams and that such divided fluid streams are directed to different portions of the main heating chamber, a significantly larger percentage of the fluid flowing through the heating element is fully vaporized, thereby forming a drier steam. In many prior art steamers, only about 50-80 percent of the fluid passing through the heating element is fully vaporized. As such a wet steam is produced and also some non-vaporized fluid is expelled from the steamer. As such, these types of steamers cannot be used to clean upholstery or other types of fabrics due to the high liquid content of the wet steam. The heating element of the present invention is designed to vaporize over 80 percent of the fluid such as water that passes through the heating element when the heating element is ready for use. In one non-limiting configuration, the heating element of the present invention vaporizes at least 85 percent of the fluid such as water that passes through the heating element when the heating element is ready for use. In another non-limiting configuration, the heating element of the present invention vaporizes at least 90 percent of the fluid such as water that passes through the heating element when the heating element is ready for use. In another non-limiting configuration, the heating element of the present invention vaporizes at least 95 percent of the fluid such as water that passes through the heating element when the heating element is ready for use. In another non-limiting configuration, the heating element of the present invention vaporizes 95-100 percent of the fluid such as water that passes through the heating element when the heating element is ready for use. 
     Referring again to  FIGS. 13-15 , a main heating chamber  270  that is divided into two chambers  272 ,  274  is illustrated. As can be appreciated, the main heating chamber  270  can be divided into more than two chambers. As also can be appreciated, the chamber configuration of the main heating chamber  270  is non-limiting. The two chambers  272 ,  274  are divided by a dividing wall  274  in the main heating chamber  270 . The dividing wall is illustrated as running straight down the middle of the main heating chamber  270 ; however, it can be appreciated that the dividing wall can have other configurations and/or be located in different regions of the main heating chamber  270 . As best illustrated in  FIG. 15 , when fluid enters the main heating chamber  270  from opening  200 , the fluid stream entering the main heating chamber  270  is divided into two smaller streams that pass on both sides of dividing wall  276  as illustrated by the arrows in  FIG. 15 . As the fluid flows in chambers  272 ,  274 , the fluid contacts the heated bottom surface  278 ,  280  of the two chambers which results in the vaporization of the fluid in the two chambers. As illustrated in  FIGS. 11 and 15 , heating plate  282  is positioned below the bottom surfaces  278  and  280  so as to heat the fluid flowing in chambers  272 ,  274 . The heating plate is illustrated as having a U-shape rod; however, other cross-sectional shapes and/or configurations of the heating plate can be used. Only a single heating plate is illustrated; however, it can be appreciated, that more than one heating plate can be used. The heating plate is illustrated as being uniformly positioned below bottom surfaces  278  and  280 ; however, this is not required. The heating plate is illustrated in  FIGS. 13 and 14  to include a heating wire  284 . One or more heating wires can be used. The heating wire is illustrated as being encircled by a protective material  286 ; however, this is not required. 
     As illustrated in  FIG. 2 , a fluid tube  198  directs fluid directly into opening  200  of the heating element  196 . In this configuration, there is no preheating tube. 
     The heating element  196  can include insulation, not shown, about the body to protect other components in the steam generator from heat damage; however, this is not required. Likewise, all or a portion of fluid tube  198  can include an insulating cover; however, this is not required. The heating element  196  is illustrated as being connected to the interior of the steam generator by a plurality of screws  202 ; however, it can be appreciated that other or additional connection arrangements can be used. The heating element  196  can also be at least partially contained within a mounting body or bracket, not shown, to further isolate the heat generated by the heating element from one or more other components within the steam generator; however, this is not required. Two electrical connections  204 ,  206  are used to supply electricity to the heating wire  284  of the heating plate  282  of the heating element  196 . These two electrical connections are connected to a power cord  208  that can be connected to a standard wall outlet. As can be appreciated, electricity from power cord  208  can be used to supply power to one or more other components of the steam generator (e.g., electric pumps, if used, indicator lights, if used; thermostats, if used; fluid level indicators, if used; status and indicator panels or displays, if used; etc); however, this is not required. As also can be appreciated, electrical connections  204 ,  206  can be connected to an internal power source in the steam generator; however, this is not required. The heating element  196  generally includes a thermostat  288  which is connected by wires  290 ,  292  to indicator light  210 . The indicator light is typically used to indicate when the heating element is heated to some predetermined temperature and is now ready for use. The indicator light can be designed to turn on or turn off when the predetermined temperature of the heating element is obtained. The use of a thermostat and/or an indicator light is optional. As can be appreciated, other or additional indicator lights or other types of indicators can be used on the steam generator to provide information to a user. 
     After the fluid passes through the heating element, the vaporized fluid exits vapor opening  212  of the heating element and into vapor tube  214 . As illustrated in  FIG. 15 , when the heating element includes more than one chamber for heating fluid, the multiple chambers are designed to converge as illustrated by the arrows so that all of the vaporized fluid exits the heating element at vapor opening  212 . As can be appreciated, the heating element can include a plurality of vapor openings; however, this is not required. If the heating element includes more than one vapor opening, a heating element that includes multiple chambers for heating fluid need not have the chambers converge; however, this is not required. The vaporized fluid that passes through vapor tube  214  enters vapor nozzle  216 . Vapor tube  214  and vapor nozzle  216  can be a single component or two or more separate components. All or a portion of the vapor tube and/or vapor nozzle can include an insulating covering; however, this is not required. Positioned about the end of vapor nozzle  216  are two seal rings  218 . The seal rings are used to form a liquid and/or vapor seal between the end of the vapor nozzle  216  and nozzle cavity  114  of nozzle interface  112  when the vapor nozzle  216  of the steam generator is inserted into the nozzle cavity  114  of nozzle interface  112 . As can be appreciated, less than two or more than two seal rings can be used. As also can be appreciated, the use of the seal rings is optional. As can further be appreciated, other or additional sealing arrangements between the vapor nozzle  216  and nozzle cavity  114  can be used. The vapor nozzle  216  is secured to the interior of the steam generator by a nozzle flange  220 ; however, it can be appreciated that other or additional arrangements can be used to secure the vapor nozzle in the body of the steam generator. 
     As discussed above, the steam generator is designed to be releasably connected to the base mount so that the steam generator can be used as a stand alone hand held steamer.  FIG. 5  illustrates how the steam generator can be detached from the base mount of the steam mop.  FIGS. 6-10  illustrate the steam generator in the stand alone mode and optional attachments that can be used with the steam generator when used in the stand alone mode. Referring now to  FIG. 6 , when the steam generator is to be used by a user in the stand alone mode, the steam generator is designed to include a handle  222  that allows the user to grasp a handle so that the steam generator can be conveniently held by a user and the vapor nozzle  216  of the steam generator can be directed to a desired location to be cleaned. The handle  222  also includes a pump lever  224  that is designed to pivot in a handle slot  226  as illustrated by the arrow in  FIG. 6 . When a user squeezes pump lever  224  at least partially into handle slot  226 , the front end  228  pivots downwardly onto pump piston  232  of pump  230 . One non-limiting configurations for mounting the handle for pivoting movement is illustrated in  FIG. 6 ; however, it can be appreciated that other configurations for mounting the handle for pivoting movement can be used. Furthermore, it can be appreciated that the handle can be mounted for non-pivoting movement. The movement of the pump piston causes pump  230  to pump fluid from fluid tank  182  to pump  230  and then from pump  230  to heating element  196  as illustrated by the arrows in  FIG. 6 . A pump spring  234  is positioned between the end of the pump piston and the housing of pump  230  to bias the pump piston in an extended position. As can be appreciated, the pump spring can be designed to bias the pump piston in an unextended position. The use of pump spring  234  is optional. The arrows in  FIG. 6  illustrate one non-limiting tubing and pumping configuration to enable fluid such as water to be pumped from the fluid tank  182  to the heating element  196  of the steam generator when the steam generator is in the hand held mode. Pump  230  is illustrated as being a manual pump; however, it can be appreciated that pump  230  can be an electric pump and that handle  224  is used to activate the electric pump; however, this is not required. As illustrated in  FIG. 6 , a user can direct vapor nozzle  216  toward a desired surface C such as, but not limited to, a counter top so as to steam clean such surface. 
     Referring now to  FIGS. 7-10 , a cleaning attachment  240  can be optionally connected to vapor nozzle  216  when the steam generator is removed from the base mount of the steam mop. As illustrated in  FIG. 7 , the cleaning attachment includes a neck  242  that is connected to a base  244 . The top of the neck  242  includes an opening  246  that is designed to receive a portion of vapor nozzle  216  when the cleaning attachment  240  is connected to the steam generator. A steam passage  254  is positioned between opening  246  and base  244  so that steam can be directed from the opening to the base. The seals  218  on the vapor nozzle  216  can be used to form a liquid or vapor seal between the vapor nozzle  216  and the the cleaning attachment  240 . The top of neck  242  also includes two lock flanges  248  that are designed to be inserted into lock slots  236  located at end  238  of body  162  of the steam generator. Once the lock flanges  248  are inserted into lock slots  236 , the cleaning attachment  240  is rotated to secure the cleaning attachment  240  to the body  162  of the steam generator. The cleaning attachment  240  can be simply removed from the body  162  of the steam generator by rotating the cleaning attachment  240  in an opposite direction and then pulling the cleaning attachment  240  off the end  238  of body  162  of the steam generator. The base  244  of the cleaning attachment  240  can include a sponge or absorbent material  250  that is located in a base cavity  252 ; however, this is not required. The base of the cleaning attachment can include a plurality of holes  256  to allow steam to exit the base; however, this is not required. As illustrated in  FIG. 7 , when the cleaning attachment  240  is connected to the steam generator, the cleaning attachment  240  can function as a small mop to steam clean small areas. As can be appreciated, the cleaning attachment  240  can have other or additional uses (e.g. press fabrics, clean curtains, clean rugs, clean upholstery, etc.). 
     It will thus be seen that the objects set forth above, among those made apparent from the preceding description, are efficiently attained, and since certain changes may be made in the constructions set forth without departing from the spirit and scope of the invention, it is intended that all matter contained in the above description and shown in the accompanying drawings shall be interpreted as illustrative and not in a limiting sense. The invention has been described with reference to preferred and alternate embodiments. Modifications and alterations will become apparent to those skilled in the art upon reading and understanding the detailed discussion of the invention provided herein. This invention is intended to include all such modifications and alterations insofar as they come within the scope of the present invention. It is also to be understood that the following claims are intended to cover all of the generic and specific features of the invention herein described and all statements of the scope of the invention, which, as a matter of language, might be said to fall therebetween.