Liquid extraction cleaning device and method

Abstract

A liquid extraction cleaning device comprises a main unit, a liquid pump, a flexible hose, and a hand tool. The main unit comprises a vacuum pump. The hand tool comprises a vacuum inlet port, an agitator, a spray nozzle, and a grip portion. The vacuum inlet port of the hand tool is operatively connected to the vacuum pump via the hose passageway in a manner such that the vacuum pump is capable of drawing fluid through the vacuum inlet port and into the hose passageway. The spray nozzle is operatively connected to the liquid pump in a manner such that the liquid pump is capable of forcing liquid out of the spray nozzle.

Claims

1. A liquid extraction cleaning device comprising: a main unit comprising a vacuum pump and a base, the base having a bottom surface, the bottom surface being configured to contact a floor and at least partially support the liquid extraction device from the floor when the liquid extraction cleaning device is in an upright position; a liquid pump; a flexible hose surrounding a hose passageway, the flexible hose being operatively connected to the vacuum pump in a manner such that the vacuum pump is capable of drawing fluid through the hose passageway; a hand tool, the hand tool comprising a vacuum inlet port and a spray nozzle, the hand tool being connected to the main unit by the flexible hose such that the hand tool is movable relative to the main unit, the vacuum inlet port being operatively connected to the vacuum pump via the hose passageway in a manner such that the vacuum pump is capable of drawing fluid through the vacuum inlet port and into the hose passageway, the spray nozzle being operatively connected to the liquid pump in a manner such that the liquid pump is capable of forcing liquid out of the spray nozzle; a telescoping tow handle attached to the main unit, the telescoping tow handle being selectively adjustable between a retracted configuration and an extended configuration, the telescoping tow handle being configured and adapted to allow a person to tilt and tow the liquid extraction cleaning device when the telescoping tow handle is in the extended configuration; a pair of wheels, the pair of wheels being mounted to the base of the main unit and being configured to support the main unit above a floor when the liquid extraction cleaning device is tilted and towed, the wheels being mounted to the base of the main unit in a manner such that the bottom surface of the base will contact and at least partially support the liquid extraction device from the floor when the liquid extraction cleaning device is upright; wherein the telescoping tow handle comprises a pair of telescoping leg members and a cross member grip, the cross member grip spanning from one of the telescoping leg members to the other of the telescoping leg members, and each of the telescoping leg members comprises at least three leg segments that telescope.

2. A liquid extraction cleaning device in accordance with claim 1 wherein the liquid extraction cleaning device comprises a retractable lifting handle, the main unit comprises an upper shell mounted to and above the base, and the retractable lifting handle is retractable at least partially into the upper shell and is configured and adapted in a manner such that a person can carry the liquid extraction cleaning device via the retractable lifting handle.

3. A liquid extraction cleaning device comprising: a main unit comprising a vacuum pump and a base, the base having a bottom surface, the bottom surface being configured to contact a floor and at least partially support the liquid extraction device from the floor when the liquid extraction cleaning device is in an upright position; a liquid pump; a flexible hose surrounding a hose passageway, the flexible hose being operatively connected to the vacuum pump in a manner such that the vacuum pump is capable of drawing fluid through the hose passageway; a hand tool, the hand tool comprising a vacuum inlet port and a spray nozzle, the hand tool being connected to the main unit by the flexible hose such that the hand tool is movable relative to the main unit, the vacuum inlet port being operatively connected to the vacuum pump via the hose passageway in a manner such that the vacuum pump is capable of drawing fluid through the vacuum inlet port and into the hose passageway, the spray nozzle being operatively connected to the liquid pump in a manner such that the liquid pump is capable of forcing liquid out of the spray nozzle; a telescoping tow handle attached to the main unit, the telescoping tow handle being selectively adjustable between a retracted configuration and an extended configuration, the telescoping tow handle being configured and adapted to allow a person to tilt and tow the liquid extraction cleaning device when the telescoping tow handle is in the extended configuration; a pair of wheels, the pair of wheels being mounted to the base of the main unit and being configured to support the main unit above a floor when the liquid extraction cleaning device is tilted and towed, the wheels being mounted to the base of the main unit in a manner such that the bottom surface of the base will contact and at least partially support the liquid extraction device from the floor when the liquid extraction cleaning device is upright; wherein the liquid extraction cleaning device comprises a tow handle shroud, the tow handle shroud attaches the telescoping tow handle exteriorly to the main unit; and wherein the tow handle shroud comprises an opening therethrough, the liquid extraction cleaning device comprises a pair of hooks that are configured and adapted to wrap an electric cord therearound and are exteriorly mounted to the main unit, and the hooks extend at least partially through the opening of the tow handle shroud.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a perspective view of the preferred embodiment of an extraction cleaner in accordance with the invention, showing the extraction cleaner's handles retracted.

(2) FIG. 2 is a perspective view of the extraction cleaner with the handles extended.

(3) FIG. 3 is a perspective view of the extraction cleaner showing the rear of the extraction cleaner.

(4) FIG. 4 is a perspective view of the main unit of the extraction cleaner.

(5) FIG. 5 is an exploded perspective view showing the rear of the extraction cleaner with the tow handle assembly detached from the main unit.

(6) FIG. 6 is a perspective view of portion of the main unit of the extraction cleaner, revealing the interior of the main unit.

(7) FIG. 7 is an exploded view of the recovery tank assembly of the extraction cleaner.

(8) FIG. 8 is a perspective view of the solution tank assembly of the extraction cleaner.

(9) FIG. 9 is a perspective view of the hand tool of the extraction cleaner showing the bottom of the hand tool.

(10) FIG. 10 is a perspective view of the agitator assembly of the hand tool.

(11) FIG. 11 is a perspective view of the agitator assembly of the hand tool with the fixed brush ring removed from the assembly.

(12) Reference numerals in the written specification and in the drawing figures indicate corresponding items.

DETAILED DESCRIPTION

(13) A preferred embodiment of a liquid extraction cleaning device in accordance with the invention is shown in FIGS. 1-11. The extraction cleaner 10 comprises a main unit 12, a solution tank assembly 14, a recovery tank assembly 16, a flexible vacuum hose 18, and a hand tool 20.

(14) As shown by itself in FIG. 4, the main unit 12 comprises a base 22 and an upper shell 24 that collectively form an interior cavity that holds various operational components of the extraction cleaner 10. Such components include a vacuum pump 26, a liquid pump 28 (both shown in FIG. 6), and an electrical circuit board assembly (not shown, but attached to the inner surface of the upper shell 24). The vacuum pump 26 and liquid pump 28 are each preferably adapted to operate on standard household voltage. Preferably, the vacuum pump 26 is of the type wherein the rotor drives both a main impeller and a cooling fan. The circuit board assembly probably comprises a transformer and rectifier for supplying the hand tool 20 with low voltage DC power. Other components are also secured to the main unit 12 including a pair of wheels 30, a carrying handle 32, and a tow handle assembly 34.

(15) As shown in FIG. 6, the base 22 of the main unit 12 provides mountings for the vacuum pump 26 and the wheels 30. The wheels 30 are mounted to the base 22 on opposite sides of the main unit 12 adjacent to the rear of the main unit. The base 22 also partially forms air ducts 36, which are also formed by duct members that are attached to the base and/or each other. One such duct member covers much of the vacuum pump 26 and comprises a cooling fan air inlet 40 and primary air outlet 42, which are not operatively connected to each other. That same duct member and the base 22 collectively define cooling fan air ducts 44 which are operatively connected to cooling fan air outlets 46 formed on opposite sides of the rear of the base (see FIG. 3). A primary air intake duct 48 is also formed and extends upward to an inlet 50 that, as explained below, interfaces with the upper shell 24 of the main unit. The primary air intake duct 48 is operatively connected to the primary air outlet 42 through the impeller of the vacuum pump 26.

(16) As shown in the figures, the upper shell 24 of the main unit 12 is preferably formed by a front shell piece 52, a rear shell piece 54, and a lower facing shell piece 56 (shown in FIG. 6). The lower facing shell piece 56 and the front portion of the base 22 collectively form a hose storage receptacle 58. A pair of hose wrap protrusions 60, about which the hose 18 can be wrapped, are mounted between the base 22 and the lower facing shell piece 56 in the hose storage receptacle 58. The upper shell 24 also comprises a recessed cradle 62, a recovery tank support platform 64, and a solution tank support platform 66. The recessed cradle 62 is formed centrally on the front and part of the top of the upper shell 24 between a recovery tank support platform 64 and a solution tank support platform 66 and is adapted to readably hold the hand tool 20 during storage. The rear of the upper shell 24 comprises a pair of cooling air inlets 68 and a primary exhaust outlet 70. A pair of electrical cord wrap protrusions 72 are centrally mounted to the rear of the upper shell 24 for storage of the extraction cleaner's 10 electrical cord (which is not shown but extends through the cord hole 74 provided in the rear of the upper shell and attaches to the circuit board assembly). An opening 76 is centrally formed through the recovery tank support platform 64 and is operatively connected to the inlet 50 of the primary air intake duct 48. Another opening 78 above the recovery tank support platform 64 near the top of the upper shell 24 extends through the upper shell and is attached to a connecting duct assembly 80 (see FIG. 6), which operatively connects that opening 78 to the hose 18. Two of concentric cylindrical recesses 82, 84 are centrally formed in the solution tank support platform 66 and a small protrusion 86 extends upwardly from the center of the smaller/deeper liquid transfer recess 84. A small offset hole (not shown) is formed through the upper shell 24 in the liquid transfer recess 84 and is operatively connected to the liquid pump 28 via tubing. The carrying handle 32 has an inverted U-shape and is attach to the upper shell 24 in a manner such that it can partially retract into the interior of the main unit 12 (as shown in FIGS. 1, 3, and 4). To a limit, the carrying handle can be extended out of the interior of the main unit 12 (as shown in FIG. 2). Still further, a main power switch 88 is secured to the top of the upper shell 24 near the rear of the main unit 12.

(17) As shown in FIGS. 3 and 5, the towing handle assembly 34 includes a shroud 90 and a telescoping tow handle 92. The shroud 34 attaches to the upper shell 24 and comprises a central opening 94 through which the cord wrap protrusions 72 extend, and that prevents the shroud from blocking the primary exhaust outlet 70. The tow handle 92 comprises a cross member grip 96 and pair of telescoping leg members 98. The grip 96 extends from one of the telescoping leg members 98 to the other. Each telescoping leg member comprises a plurality of leg segments 100. The shroud 90 and the upper shell 24 fix the lower most leg segments in position relative to the upper shell. As such, the cross member grip 96 can be extended up from the shroud 90 (FIG. 2) for towing the extraction cleaner 10 via the wheels 30 and, alternatively, lowered such that the majority of the telescoping tow handle 92 is retracted into the shroud (FIG. 1). When the extraction cleaner is stowed or is not being towed, the front of the bottom surface of the base 22 of the main unit 12 rest on the ground to prevent the extraction cleaner from sliding around on its wheels 30.

(18) As shown by itself in FIG. 8, the solution tank assembly 14 of the extraction cleaner 10 comprises a solution tank 102, a fluid communication assembly 104, and a locking ring 106. The solution tank 102 is preferably translucent plastic and comprises handgrip indentations 108 and a central opening 110 at its base that is preferably treaded. The fluid communication assembly 104 comprises offset air vent tube 112 that is configured to operatively communicate with the vent recess 82 on the solution tank support platform 66 of the main unit 12 in a manner such that air can enter the solution tank 102 through the vent tube 112 above the level of liquid in the tank. The fluid communication assembly 104 also comprises a spring biased check valve 114 that enables fluid within the solution tank to exit through the valve when it's open. The check valve 114 is configured to open when the solution tank assembly 14 is placed onto the solution tank support platform 66. More specifically, the lowermost end of the check valve comprises an annular seal 116 that slides into the smaller liquid transfer recess 84, and the protrusion 86 in the recess forces the check valve open 114. Thus, when attached to the main unit 12, liquid in the solution tank 102 is in fluid communication with the liquid pump 28 of the main unit, and air is able to fill the tank a liquid is drawn out of the tank by the pump. The locking ring 106 releasably connects fluid communication assembly 104 of the solution tank assembly 14 to the central opening 110 at the base of the solution tank 102 to allow the tank to be refilled easily.

(19) The recovery tank assembly 16 includes a recovery tank 118, a deflector 120, and a float assembly 122. The recovery tank 118 is preferably is preferably translucent and comprises a pair of handgrip indentations 124, a central opening 126 at its base that is preferably threaded, and an intake opening 128 on its upper rear wall. The central opening preferably is not perfectly circular and includes flat portion 129. The deflector 120 is connected to the intake opening 128 and is configured to deflect fluid (air and extracted liquid) away from the float assembly 122 and against the outer walls of the recovery tank 118. When the recovery tank assembly 16 is placed on the recovery tank support platform 64 of the main unit, the intake opening 128 of the recovery tank 118 is operatively connected to the connecting duct assembly 80 of the main unit, which draws extracted liquid and air into the recovery tank 118. The float assembly 122 comprises an air tube 130, a locking ring 132, and a float 134. The float assembly 122 is removably attached to the central opening 126 of the recovery tank 118 via the locking ring 132. Notably, the flange at the base of the air tube 130 comprises a flat portion 136 that must be aligned with the flat portion 129 of the central opening 126 of the recovery tank 118 in order to attach the float assembly 122 to the recovery tank 118. This ensures that air tube 130 is oriented with its intake facing away from the deflector 120. When the recovery tank assembly 16 is placed on the recovery tank support platform 64 of the main unit 12, the air tube 130 is operatively connected to the impeller of the vacuum pump 26 via the primary air intake duct 48 of the main unit 12, thereby allowing air to be drawn out of the recovery tank 118 to thereby draw air and extracted liquid into the tank. The float 132 encircles the air tube 130 and, in a conventional manner, is configured to rise with the level of liquid in the recovery tank 118 until it reaches a maximum limit, at which time is seals off the upper end of the air tube to prevent further intake of fluid.

(20) The flexible vacuum hose 18 connects the hand tool 20 to the connecting duct assembly 80 of the main unit 12 and forms and surrounds a hose passageway. As such that the impeller of the vacuum pump 26 is operatively connected to the hose passageway. An electrical cable 138 and a liquid supply tube 140 (shown in FIG. 9) extend through the hose passageway. The liquid supply tube is operatively connected to the high side of the liquid pump 28 of the main unit 12. The electrical cable 138 is connected to the circuit board of the main unit 12 in a manner such that the electrical cable is feed with low voltage direct current (preferably under 25 volts). The electrical cable 138 preferably comprises three wires, namely positive, negative, and a relay signal wire. Because power transmission via low voltage requires higher amperage, running the electrical cable 138 in the hose passageway rather than spirally in the hose wall or external to the hose minimizes power loss due to wire resistance. Additionally, running both the electrical cable 138 and the liquid supply tube 140 in the hose passageway eliminates routing issues and allows the vacuum hose 18 manufactured relatively inexpensively.

(21) As shown in FIG. 9, the hand tool 20 comprises a housing 142, a spray nozzle 144, a spray trigger 146, an agitator assembly 148, a vacuum inlet port 150, a grip portion 152, and an agitator switch 154 (the latter shown in FIGS. 1 and 2). The end of the grip portion 152 is connected to the flexible vacuum hose 18, thereby connecting the hose passageway to the vacuum inlet port 150. A portion of the housing 142 adjacent to the vacuum inlet port 150 is preferably translucent such that liquid passing into the vacuum inlet port can be observed. The spray nozzle 144 is preferably directly connected to the liquid supply tube 140 that extends through the vacuum hose 18 such that when the liquid pump 28 of the main unit 12 operates, cleaning solution liquid is sprayed from the spray nozzle in a fan-like pattern. However, the spray trigger 146 is connected to the electrical cable 138 and operates an electrical switch in the hand tool 20 and sends the positive low voltage down the signal wire of the electrical cable to the circuit board of the main unit 12 when the trigger is depressed. Through a relay, the circuit board only supplies the higher AC power to the liquid pump 28 when it receives that signal. The agitator switch 154 is also connected to the electrical cable 138, but is preferably a toggle switch that selectively supplies electrical power to the agitator assembly 148. The various components of the hand tool 20 are positioned such that as a person pulls the grip portion 152 of the tool and drags the remainder of the tool along upholstery or carpet, the hand tool will spray cleaning liquid on the fabric, then agitate that portion of the fabric, and thereafter extract the soiled liquid from the fabric, all in a single motion.

(22) The agitator assembly 148 is shown in FIGS. 10 and 11 and comprises a fixed brush ring 156, a low voltage electric motor 158, a motion converter 160, and a reciprocating agitator 162. The fixed brush ring 156 preferably comprises side brushes 164 that are preferably oriented such that they extend at angle relative to the surface being cleaned, and several rows of non-angled brushes 164 in front of and behind the reciprocating agitator 162. The electric motor 158 supplies rotational power to the motion converter 160 when agitator switch 154 of the hand tool 20 supplies the agitator assembly 148 with power. The motion converter 160 converts that rotational power into linearly reciprocating power, which thereafter is converted once again into pivotally reciprocation of the agitator 162.

(23) The main power switch 88 on the main unit 12 controls the electrical power supply to the rest of extraction cleaner 10. When set to the on position, the main power supply supplies power to the circuit board which then activates the vacuum pump 26. Thus, when the main switch 88 is on, the vacuum pump operates 26, and when it's off, nothing operates. However, when the main power switch 88 on, the circuit board provides low voltage DC power to the electrical cable 138 in the hose passageway. Although the vacuum inlet port 150 of the hand tool 20 will always be sucking in air unless the main power switch 88 switched off or the recovery tank assembly 16 is full, the agitation and liquid can be controlled independently of each other from the hand tool using the spray trigger 146 and agitator switch 154.

(24) In view of the foregoing, it should be appreciated that the invention has several advantages over the prior art.

(25) 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. 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.

(26) It should also be understood that when introducing elements of the present invention in the claims or in the above description of exemplary embodiments of the invention, the terms comprising, including, and having are intended to be open-ended and mean that there may be additional elements other than the listed elements. Additionally, the term portion should be construed as meaning some or all of the item or element that it qualifies. Moreover, use of identifiers such as first, second, and third should not be construed in a manner imposing any relative position or time sequence between limitations. Still further, the order in which the steps of any method claim that follows are presented should not be construed in a manner limiting the order in which such steps must be performed, unless such an order is inherent.