Field of the Invention
This invention relates to an upright bare floor cleaner. In one aspect, the invention relates to a bare floor cleaner that performs steam mopping. In another aspect, the invention relates to an upright steam mop having an auxiliary hose for steam cleaning above-floor surfaces. In yet another aspect of the invention, an upright steam mop has a removable steam module for portable, above-floor steam cleaning. The steam mop of the invention provides both floor and above-floor steam cleaning.
Description of the Related Art
Conventional mops are well known for cleaning a bare floor surface, such as tile, linoleum, and hardwood floors. The most common cleaning tool for this procedure is the traditional sponge or rag mop. Mops are capable of loosening dirt from the floor and have excellent absorbency; however, when the mop requires more cleaning solution, it is placed in a bucket to soak up warm cleaning solution and returned to the floor. Each time more cleaning solution is required, the mop is usually placed in the same bucket, and after several repetitions the cleaning solution becomes dirty and cold. As a result, dirty cleaning solution is used to remove dirt from the bare surface. Mops generally require use of chemicals which can be problematic for users that have allergies or other sensitivities to cleaning chemicals, fragrances, etc.
There has been an increased interest in environmentally friendly methods for household cleaning and the interest in steam cleaning in the home has also increased. This method of cleaning has the advantage of using water rather than chemicals, which are expensive and can have negative environmental impacts. Further, steaming devices used to apply steam to household objects are well known. The uses of the devices vary widely, and may include the application of steam to drapes or other fabrics to ease wrinkles, and the application of steam to objects to assist in cleaning the objects.
Recent trends in cleaning bare floors involve the use of steam as the cleaning agent. Typical steam devices have a reservoir for storing water that is connected to an electrical water pump with an on/off switch. The exit from the electric water pump is connected to a steam boiler with a steam generator to heat the water. The heated water generates steam, which may be directed towards the intended destination through a nozzle which controls the application of the steam. Variation of the shape and size of the nozzle allows for preferred distribution of generated steam to an object to be cleaned. Different nozzles may be interchanged, based on the object to be steamed. The nozzle may be either closely coupled to the steam generator, or located at a distance from the steam generator, requiring tubing or other steam transfer structures to be interconnected between the steam generator and the discharge nozzle. Steam systems have the advantage of creating a temperature which effectively kills a wide range of microbes, bacteria, microorganisms, and dust mites. Conversely, conventional detergent cleaning systems are somewhat effective at cleaning surfaces, but could be made more effective by raising the temperature of the cleaning solution to some point below the boiling point.
A bare floor cleaner has heretofore been sold in the United States by BISSELL Homecare, Inc. under the mark Steam Mop. The Steam Mop comprises a base assembly and an upright handle pivotally mounted to the base assembly. The base assembly includes a base housing with a fluid distributor for distributing fluid to the surface to be cleaned; and a mop cloth which is affixed beneath the base housing and positioned for contacting the surface to be cleaned. The upright handle includes a handle housing; a water tank mounted to the handle housing and adapted to hold a quantity of water; a fluid distribution system between the water tank and the base housing fluid distributor for distributing fluid from the water tank to the mop cloth for applying the steam to the surface to be cleaned; and a steam generator within the fluid distribution system for heating the water from the water tank to steam.
According to one aspect of the invention, a steam mop includes a housing having a foot and an upright handle assembly pivotally mounted to the foot, a steam generator having an inlet and an outlet, a fluid distributor in the foot operable to distribute steam to a floor surface, and an auxiliary hose operable to distribute steam to an above floor surface.
The steam mop can further include an articulating joint mounting a proximal end of the auxiliary hose to the housing for rotation about a rotational axis, wherein a longitudinal axis of the auxiliary hose at the proximal end intersects the rotational axis about which the auxiliary hose rotates at a single point.
The steam mop can further include a handheld nozzle fluidly connected to a distal end of the auxiliary hose, a receiver mounted on the housing for removably receiving the handheld nozzle, whereby steam can be distributed from the fluid distributor in the foot to the floor surface when the handheld nozzle is positioned in the receiver and whereby steam can be distributed from the handheld nozzle to the above floor surface when the handheld nozzle is removed from the receiver, and a fluid control valve configured to be opened by the receipt of the handheld nozzle in the receiver.
In the drawings:
Referring now to the drawings and to
The handle assembly 12 comprises an upper handle assembly 16 and a lower handle assembly 18. The upper handle assembly 16 comprises a hollow handle tube 20 having a grip assembly 22 fixedly attached to a first end of the handle tube 20 and the lower handle assembly 18 fixedly attached to a second end of the handle tube 20 via screws or other suitable commonly known fasteners. The grip assembly 22 has an arcuate grip portion; however, it is within the scope of the invention to utilize other grips commonly found on other machines, such as closed-loop grips having circular or triangular shapes. Referring to
As shown in
The lower handle assembly 18 further comprises a recess 62 in the rear enclosure 40 in which a water tank assembly 64 is removably mounted. The water tank assembly 64 comprises a tank with an inlet and outlet (not shown) to hold a predetermined amount of liquid, preferably water or electrolyzed water. See for example, U.S. Patent Application Publication No. 2001/0034922 for electrolytic steam vacuum, U.S. Pat. No. 4,327,459 for vacuum with electrolytic steam generator, and JP2005006816A2 for floor mop with electrolytic cell. Optionally, various additives can be mixed with the water including a variety of cleaning chemicals, fragrances, botanical oils, and the like. The water tank assembly 64 is in fluid communication with a filter assembly 70, which includes a housing having an inlet 72 and an outlet 74 and which contains de-ionizing crystals. A first water tube 76 fluidly communicates between an inlet port 78 for the pump 80 and the filter assembly 70. An outlet port 82 of the pump 80 fluidly communicates with a T-connector 84. The T-connector 84 is fluidly connected to both the pressure relief valve 52, via a second water tube 86, and the steam generator 48.
The steam generator 48 is electrically coupled to the power source (not shown) and has an elongated boiler that includes an inlet 90 at one end that is fluidly connected to the pump 80 via the T-connector 84. Filtered water is heated while passing through the steam generator 48 and exits at its opposite end, via an outlet port 92, which is fluidly connected to a first steam tube 94. The steam generator 48 can be a flash steam heater or a boiler for generating steam.
Referring additionally to
Alternatively, the fluid distribution system 46, including the water tank assembly 64, can be mounted to the foot 14.
Referring back to
Referring now to
As shown in
Referring also to
The diverter valve 120 can be manually controlled to select the mode of steam application by selectively turning a selector, such as a knob 128, which in turn moves a valve element within the valve to connect the inlet 122 with the outlet 124 or the outlet 126. In the illustrations, the knob 128 is shown on the front enclosure 42 of the lower handle assembly 18: however other locations are possible. The knob 128 controls which outlet 124 or 126 is in fluid communication with the fluid distribution system 46, as is commonly known in the art.
The handheld nozzle 116 comprises a trigger 130 and a conventional normally closed valve (not shown) for selectively releasing steam. When the trigger 130 is squeezed, the valve opens and steam supplied by the fluid distribution system 46 passes through the steam hose 110 and is released out the handheld nozzle 116. It is contemplated that various cleaning attachments can be removably mounted to the handheld nozzle 116 for above-floor steam cleaning.
Referring to
The lower end of the receiver 204 is fluidly connected to a second steam tube 208 and spray nozzle 88, located in the foot 14 through conduit 220, conduit 56, connector 132 and swivel ball joint 134. For floor steam cleaning, the handheld nozzle 116 is received in the receiver 204 and trigger 130 is compressed, opening the valve (not shown) and passing steam therethrough. Thus, for the floor cleaning mode, steam is directed from the water tank assembly 64, through the steam hose 110, and to the spray nozzle 88, thereby forming the “live hose” fluid distribution system 246. Thus, in this embodiment, the receiver 204 and the trigger 130 form a fluid control system for the fluid distribution system 246 for selectively distributing steam onto the surface to be cleaned when the handheld nozzle 116 is received in the receiver 204 and the auxiliary hose 110 selectively distributes steam from the fluid distribution system 246 onto the surface to be cleaned when the handheld nozzle 116 is removed from the receiver 204.
For above-floor steam cleaning, the handheld nozzle 116 is removed from the receiver 204, releasing the trigger 130 and closing the valve (not shown). As described above, the user can selectively squeeze the trigger 130, opening the valve and passing steam from the fluid distribution system 246 through the steam hose 110 and out the handheld nozzle 116.
Referring to
The handle assembly 312 comprises a commonly known grip assembly 322 having a trigger 30 mounted thereto, and a recess 316 in which the steam module 302 is mounted.
The steam module 302 is removably mounted to the handle assembly 312 and is comprised of a rear enclosure 340 and a front enclosure 342, which mate together to form a central cavity 344 therebetween to house a fluid distribution system 346. Additionally, the steam module 302 includes a receiver 304. The steam module 302 further comprises a carry handle 54 to facilitate removing the steam module 302 from the steam mop 300. The steam module 302 can optionally comprise a latch assembly (not shown) mounted thereto for selectively interlocking the steam module 302 to the handle assembly 312. One suitable latch assembly is disclosed in U.S. Pat. No. 5,524,321, which is incorporated herein by reference. The water tank assembly 64 is also removably mounted to the steam module 302.
Referring to
The lower end of the receiver 304 is fluidly connected to a second steam tube 308 and spray nozzle 88, located in the foot 314, through receptacle port 352, connector 132 and swivel ball joint 134. For floor steam cleaning, the handheld nozzle 116 is received in the receiver 304 and the trigger 130 is compressed, opening the valve (not shown) and passing steam therethrough. Thus, for the floor cleaning mode, steam is directed from the water tank assembly 64, through the steam hose 110, and to the spray nozzle 88 for distribution to the cleaning cloth 104.
The fluid distribution system 346 further comprises an outlet port 350 and a receptacle port 352. The outlet port 350 is located in the lower, closed-end of the receiver 304 and the receptacle port 352 is located in the handle assembly 312 at the bottom of the recess 316. The outlet port 350 has an outlet valve (not shown) that is closed when the outlet port is separated from the receptacle port 352 and opens when the outlet port 350 is connected to the receptacle port 352 to selectively enable and prevent fluid communication between the steam module 302 and the foot 314. With the steam module 302 installed, the outlet port 350 is adapted to open in fluid communication with the receptacle port 352, thus fluidly connecting the water tank assembly 64 with the foot 314 nozzle 88. When the steam module 302 is removed from the handle assembly 312, the outlet port 350 is closed, thereby preventing steam from passing through the receiver 304. With the steam module 302 removed, steam generated by the enclosed fluid distribution system 346 can be selectively applied to the surface to be cleaned by the handheld nozzle 116. The described outlet and receptacle ports 350, 352 can comprise any type of suitable valves that are commonly known in the art. A suitable outlet valve is disclosed in U.S. Pat. No. 6,167,586, which is incorporated herein by reference.
Now referring to
The steam mop 10, 200, 300 can be operated as a bare floor cleaner that utilizes a disposable or re-usable, washable cleaning cloth 104 and steam for improved cleaning. When the steam mop fluid distribution system 46, 246, 346 is activated by depressing the trigger 30, steam is distributed onto cleaning cloth 104 and transferred to the surface to be cleaned. When used for above-floor cleaning, the steam mop fluid distribution system 46, 246, 346 is activated by depressing the trigger 130 and steam is released through the auxiliary handheld nozzle 116.
A fourth embodiment of the invention shown in
Referring to
The pivoting steam hose conduit 403 comprises a pivoting tube coupling 414 that is adapted to rotate about an axis defined by a male inlet barb 416 and a coaxial opposed pin 418. The male inlet barb 416 rotates within the distal end of the boss 412 in the rear enclosure 40 and the opposed pin 418 is rotatably received within a corresponding socket 420 formed within the inner surface of a steam hose rack 422. The circumference of the male inlet barb 416 includes a circular groove adapted to receive an O-ring (not shown) that is sized to rotatably seal the male inlet barb 416 within the boss 412. The horizontally oriented male inlet barb 416 is fluidly connected to an orthogonally oriented outlet barb 424 that protrudes outwardly from a cylindrical collar 426 of the pivoting tube coupling 414. The cylindrical collar 426 is adapted to receive a hose collar 428 that is fixed to the proximate end of the steam hose 110. The steam hose 110 surrounds and insulates the internal first steam tube 306 that fluidly connects the outlet barb 424 to the handheld nozzle 116. As shown in
The handheld nozzle 116 is selectively and slidingly retained within a receiver 430 that is mounted to the rear enclosure 40 and protrudes through an opening in the hose rack 422. A locking collar 432 is configured to selectively retain the handheld nozzle 116 within the receiver 430 and comprises an arcuate partial flange 434 connected to a frame 436 that rotates about a pivot bar 438 spanning the bottom of the frame. A release button 440 protrudes from an upper portion of the frame and is exposed through an access hole in the hose rack 422. The locking collar 432 is pivotally retained between the rear enclosure 40 and the hose rack 422 and is normally biased outwardly by a coil spring (not shown) mounted between the locking collar 432 and the rear enclosure 42. The arcuate partial flange 434 of the locking collar 432 is adapted to retain the handheld nozzle 116 when the handheld nozzle is seated within the receiver 430. To release the handheld nozzle 116, a user depresses the release button 440, which rotates the locking collar 432 rearwardly about the pivot bar 438, thus disengaging the arcuate partial flange 434 from the handheld nozzle 116 and permitting removal from the receiver 430.
The receiver 430 comprises a pocket 442 formed in the back side adapted to house a second microswitch 444 therein. The second microswitch 444 is operably connected to a spring biased plunger 446 that is configured to slide vertically within a channel 448 formed within the receiver 430. The upper portion of the plunger 446 is exposed within the receiver 430 and is adapted to selectively engage the handheld nozzle 116. The lower portion of the plunger 446 is adapted to selectively engage the second microswitch 444. The handheld nozzle 116 engages the upper portion of the plunger 446 when the nozzle 116 is seated within the receiver 430, which forces the lower portion of the plunger to engage the second microswitch 444.
The second microswitch 444 is electrically connected to a third microswitch 450 that is mounted within an upper portion of the rear enclosure 42. The third microswitch 450 is positioned for selective actuation by a release latch 452. The release latch 452 is slidingly mounted within the carry handle 54 of the steam module 402. A release button/actuator 454 integral to the release latch 452 protrudes through an opening at the top of the carry handle 54 for convenient user access. Two catches (not shown), which are also formed integrally with the release latch 452, protrude through openings at the lower portion of the carry handle 54 and are configured to selectively mate with corresponding recesses (not shown) formed in the upright handle assembly 312 to selectively retain the steam module 402 to the handle assembly 312 as previously described. A spring biased upper plunger 458 is slidably mounted to a bracket (not shown) in the carry handle 54 and is in register with the release latch 452 and the third microswitch 450. When the release button/actuator 454 is depressed, the release latch 452 slides downwardly and engages the upper plunger 458, which, in turn, actuates the third microswitch 450. Additionally, downward movement of the release latch 452 simultaneously disengages the catches from the recesses in the upright handle assembly 312 when the steam module 402 is mounted to the upright handle 312.
Referring to
The second branch of the pump actuation circuit comprises the second and third microswitches 444, 450. When the steam module 402 is detached from the handle assembly 312, the first microswitch 50 is open and the pump 80 can be energized only when the second and third microswitches 444, 450 are closed. The second microswitch 444 mounted within the receiver 430 and is normally closed. Accordingly, when the handheld nozzle 116 is seated within the receiver, the plunger 446 engages the second microswitch 444 and opens the switch and circuit. Thus, the pump 80 cannot be energized when the steam module 402 is detached from the handle assembly 12 and the handheld nozzle 116 is seated within the receiver. However; when the handheld nozzle 116 is removed from the receiver 430, the spring biased plunger 446 moves upwardly and disengages the switch 444, which closes the switch 444 and partially closes the second branch of the pump actuation circuit 468. The third microswitch 450 is connected in series with the second microswitch 444 and is selectively engageable by the slidably mounted release latch 452. Accordingly, the pump 80 can be selectively energized by removing the handheld nozzle 116 from the receiver, which closes the second microswitch 444, and then selectively depressing the release button/actuator 454 on the release latch 452, which engages and closes the third microswitch 450.
Referring to
In operation, the steam mop 400 can be operated either with the steam module 402 secured to the upright handle assembly 312 for floor cleaning mode or detached from the upright handle assembly 312 for above-floor steam cleaning. A user detaches the steam module 402 from the upright handle assembly 312 by depressing the release button/actuator 454 on the release latch 452, which disengages the catches 456 from the corresponding recesses in the upright handle assembly 312.
A user can rotate the steam moisture control knob 460 to the desired “wet”, “dry”, or intermediate steam wetness setting, thereby changing the variable resistor 464 input to the PCBA 466, which, in turn, adjusts the frequency of the solenoid pump 80, thus increasing or decreasing the pump 80 flowrate. Next, a user depresses the release button 440 on the locking collar 432 to disengage the arcuate partial flange 434 from the handheld nozzle 116. As the user removes the handheld nozzle 116 from the receiver 430, the spring biased plunger 446 moves upwardly and disengages the second microswitch 444, thus closing the switch and partially closing the second branch of the pump actuation circuit 468. Next, the user selectively energizes the solenoid pump 80 by depressing the release button/actuator 454 on the release latch 452, which engages and closes the third microswitch 450, thus energizing the solenoid pump 80. When energized, the pump 80 draws water from the tank assembly 64, and pumps it through the steam generator 48, which flash heats the water to generate steam or a mixture of steam and suspended water droplets, depending on the steam moisture controller 404 setting. The steam is pushed out of the outlet port 92 through a fluid flow path including the jumper tube 406, inlet fitting 408, into the male inlet barb 416 of the pivoting conduit 403, through the outlet barb 424, into the steam tube 306, whereupon it is distributed onto the cleaning surface through the handheld nozzle 116. Commonly known accessory tools can be attached to the handheld nozzle to accomplish various steam cleaning functions.
Alternatively, when the steam module 402 is secured to the upright handle and the handheld nozzle 116 is seated within the receiver 430, the pump 80 can be energized, by depressing the trigger 30, which engages the first microswitch 50 via the push rod 32 and distributes steam through the foot 14 as previously described herein.
The steam mop of the described invention offers a high degree of flexibility because it can be used in multiple configurations for steam cleaning in the home. Because the steam mop uses water and not chemicals, it is environmentally friendly and has the advantage of creating a temperature which effectively kills a wide range of microbes, bacteria, microorganisms, and mites. The steam mop can be used for steam mopping the floor as well as above-floor surfaces through the use of the auxiliary hose. Further, the steam mop has a removable, portable steam module for even greater usage flexibility.
While the invention has been described in connection with certain specific embodiments thereof, it is to be understood that this is by way of illustration and not of limitation. Reasonable variation and modification are possible within the scope of the forgoing disclosure and drawings without departing from the spirit of the invention which is defined in the appended claims.
This application is a continuation of U.S. patent application Ser. No. 14/505,917, filed Oct. 3, 2014, now U.S. Pat. No. 9,433,335, which is a continuation of U.S. patent application Ser. No. 13/389,899, filed Feb. 10, 2012, now U.S. Pat. No. 8,850,654, issued Oct. 7, 2014, which is a National Phase Application of International Application No. PCT/US2010/045167, filed Aug. 11, 2010, and claims the benefit of U.S. Provisional Patent Application No. 61/232,971, filed Aug. 11, 2009, all of which are incorporated herein by reference in their entirety.
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Number | Date | Country | |
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20160360943 A1 | Dec 2016 | US |
Number | Date | Country | |
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61232971 | Aug 2009 | US |
Number | Date | Country | |
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Parent | 14505917 | Oct 2014 | US |
Child | 15246837 | US | |
Parent | 13389899 | US | |
Child | 14505917 | US |