Patent Publication Number: US-7588198-B2

Title: Power sprayer

Description:
CROSS-REFERENCE TO RELATED APPLICATION 
   This application is a continuation-in-part of U.S. continuation-in-part patent application Ser. No. 10/863,817, filed Jun. 8, 2004, which is a continuation-in-part of U.S. non-provisional patent application Ser. No. 10/832,682, filed Apr. 27, 2004, and it claims priority thereto and to U.S. provisional patent application Ser. No. 60/530,869, filed Dec. 18, 2003, both of which are incorporated herein by reference in their entirety. 

   BACKGROUND 
   The present invention relates to devices and methods for dispensing substances. More particularly, the present invention relates to devices and methods for dispensing fluids and to a powered dispenser for attachment to a reservoir containing a fluid to be dispensed. 
   Hand operated sprayers are often mounted on containers of household liquids such as window and bathroom cleaners or ARMOR ALL®. A household liquid is dispensed from the hand-operated sprayer by repeatedly squeezing a lever on the sprayer. This can be tiresome. Consequently, powered sprayers have been previously developed to replace the hand-operated sprayers. 
   These previous powered sprayers suffer from several drawbacks. First, they often cannot be mounted on an off-the-shelf container of household liquid, instead relying on a special reservoir that must be refilled by the user. This can be messy and/or inconvenient for a user. 
   Second, the previous powered sprayers have spray heads or housings that are substantially larger and heavier than the standard hand operated sprayers. As a result, the previous powered sprayers tend to be top heavy and unwieldy. They tend to be expensive in comparison to non-powered sprayers and, for at least these reasons, are not optimally marketable. 
   There is a need in the art for a powered sprayer that has a spray head or housing that is similar in size and configuration to a standard hand operated sprayer. 
   SUMMARY 
   The present invention, in one embodiment, is a sprayer comprising a motorized liquid spray head or spray pump assembly. It includes an operating mechanism adapted to provide the user a push button actuated, automatic power spray for any of a variety of generally liquid or fluid materials. Examples of material that can be dispensed or sprayed by the power sprayer of the present invention include cleaning substances such as glass cleaner and the like. The present invention may also be used to spray or mist items with water, and it can be used to dispense insecticides, fungicides or the like. It also may be used for a wide range of other products or substances, e.g., sunscreens, liquid cleaners, disinfectants, herbicides, virtually any substance which can be dispensed, applied or used in a spray, atomized, vapor, stream, aerosol, or mist form. 
   In one embodiment, the sprayer of the present invention comprises a housing or attachment designed to fit typical, common bottles or other containers for containing substances. An example of such a container is the type used to contain common window cleaner. The sprayer, particularly the nozzle, of the present invention may be adjustable from a fine mist to a strong, and in some embodiments, generally coherent stream. 
   In one embodiment, the present invention comprises a dispenser adapted to be coupled to a fluid container. The dispenser comprises a dispensing head, an energy source, and a fluid pathway. The dispensing head includes a fluid pump, a motor adapted to power the pump, a trigger adapted to control the motor, and a nozzle orifice in fluid communication with a discharge end of the pump. The fluid pathway has one portion in fluid communication with an intake end of the pump and another portion inside the container. 
   In one embodiment, the invention includes a pick up tube, disposed inside the container or bottle to which the sprayer is attached, that is weighted and sufficiently flexible to allow the power sprayer to work at any angle and upside down. 
   In one embodiment, the weight at the end of the pick-up tube may be a die cast or brass weight with a slot in the end. The slot keeps the intake associated with the weight from being blocked or shut off against the side of the bottle. In one embodiment, the pick up tube to which the weight is attached is a very flexible silicon or like material, although any material may be selected as long as it is sufficiently flexible. The length of the pick up tube should be selected so it doesn&#39;t get caught or tangled. 
   In one embodiment, the present invention comprises a battery operated liquid spray pump which may be used interchangeably on typical containers or bottles for a variety of substances. The spray pump of the present invention may be used for a variety of purposes. For example, in the home, cleaning solutions such as window cleaners may be sprayed or dispensed with it. In the garage, for automotive uses, various cleaning materials may be dispensed or applied using the sprayer of the present invention. In the garden, the present invention may be used for spraying or dispensing insecticides, herbicides or for misting plants. It may be used in a wide variety of applications or uses at home or on the job, anywhere hand-pumped sprayers are currently in use. 
   In one embodiment, the pump unit or sprayer of the invention has two batteries (as many batteries as suitable may be used) that are housed inside the container or bottle neck in a tube-like housing when the sprayer of the invention is attached to a bottle or container. In other embodiments, other suitable power sources (e.g., a capacitor, capacitors, etc.) may be used. 
   In one embodiment, the sprayer of the present invention comprises a trigger, for example, a push button type trigger, that turns on a motorized pumping system, bringing the liquid to the sprayer nozzle under pressure and producing an adjustable spray mist. The trigger permits on/off fingertip control. The user simply touches or depresses the button when the spray is desired; release the button and the spray stops. In one embodiment, a weighted in-bottle pick up tube allows for any angle spraying. 
   In one embodiment, the sprayer unit of the present invention is designed to fit any standard cleaner bottle, but it may also comprise an empty bottle that the user can fill and use to dispense substances. 
   In some embodiments, a small funnel may be provided. Other features of the present invention may include a nozzle which is adjustable from a fine mist to a strong, substantially coherent stream. The attachment feature of the spray head unit of the present invention should be adapted to fit a typical standard size bottle or container, and in some embodiments, it may be adapted to be adjusted to containers with openings of various sizes. In one embodiment, the attachment feature or connector is a threaded adapter piece. The electrical system associated with the present invention should be water resistant whereby components should not rust or corrode due to contact with water or chemicals, including cleaning agents or soap. In one embodiment, the present invention comprises a motorized piston pump and nozzle for attaching to a container whereby the contents of the container may be dispensed. In other embodiments, the present invention may comprise a gear pump or other suitable pumping mechanism. 
   In one embodiment, the present invention comprises a dispensing attachment for mounting on or to a container containing a substance to be dispensed wherein the dispenser comprises a power source, e.g., batteries, a motor, a operating mechanism, a pump, a nozzle, and a pick up tube. 
   In some embodiments, the present invention includes a safety lock, which can comprise any suitable method for an operator to conveniently and easily lock and unlock the trigger or operating button of the invention. In one embodiment, this may comprise a safety lockout lever or slide type button. In some embodiments, the invention may be made available with a child safety cap. 
   In one embodiment, the present invention comprises a motorized spray unit comprising a motor, a piston pump, a flex weighted liquid draw or pick up tube, a battery housing and an adjustable nozzle. Suitable liquid conduits may be used to connect the liquid conducting portions of the invention and to provide a flow path. In one embodiment, the present invention uses a simple trigger or push button actuation switch to replace the manual pump and pump trigger or operating mechanisms typically found on such sprayers, and allows the user to spray without excessive finger or hand pumping or flexion. In some embodiments, the switch may be an “on/off” switch having two states. In other embodiments, a variable speed switch arrangement may be used. Such an arrangement may incorporate microprocessor, rheostatic or other suitable control components. 
   An advantage of the spray head of the present invention is that the batteries, or other suitable power source, fit inside the neck of the bottle when the spray head is attached to a bottle, whereby convenience, comfort, handling and use of the invention are balanced and facilitated. 
   In one embodiment, the entire pump unit including its handle portion and the battery unit which extends inside the bottle, should be adapted to be pivotal around a screw-on cap as one piece. This facilitates installing the spray head on a bottle or other container. 
   In one embodiment, the nozzle is rotatable between selected dispensing configurations including spray and stream. The nozzle, and/or the sprayer, may be adapted to provide indications, graphically or otherwise, of these and/or other operable conditions. In some embodiments, the sprayer may be adapted, by incorporating suitable electronic components to provide sensing and indicating features, and/or electronic control features, e.g., adjustable, rheostatic output pressure control. For example, the sprayer could sense and display dispensing pressure, contents remaining, etc. It could also be adapted to provide a visual signal of operating states, e.g., battery capacity remaining, by providing a suitable light source, e.g., a bulb, LED, etc. It could also be adapted to provide other types of signals, e.g., visual, tactile, audible, etc. to users or potential purchasers. 
   In one embodiment, the present invention comprises a powered, motorized spray pump head including a battery housing, batteries, a straw-like liquid draw or pick-up tube, a soft flexible tube, a pump, a motor and gear assembly, safety lockout tab, a primer chamber, a multiple position nozzle, a trigger contact switch, a trigger and a weighted pick-up tube. Note that the safety lock tab may be adapted to interrupt the power supply and/or physically permit or not permit positioning or depression of the trigger. 
   The components of the present invention are appropriately housed in or extend from a housing which may be formed of a number of connected pieces, or which may be formed as a single piece. 
   In one embodiment, the present invention comprises a housing for containing or mounting the operable components and features of the present invention. At the outlet end of the housing, the invention includes a cap of a nozzle which provides for adjustment of the spray. An internal washer and rubber washer are provided for sealing purposes, and an axial cover is provided to close the end. The invention provides a fluid pathway in the housing which includes a first one-way valve, a suitable connector tube and a second one-way valve. One end of the second one-way valve is coupled to a piston housing which contains a piston ring and rod for reciprocating motion. The piston ring and rod are operably coupled to a gear box containing a gear, in turn driven by a motor. These components are suitably housed in the cover or housing. The housing is adapted to carry a threaded, cap-like structure for connection to the neck of a bottle or other container. A battery tube or housing extends generally from the underside of the cover through the cap portion. This provides a water or liquid proof housing for a required number of batteries. 
   On the intake side, the present invention comprises an absorbent tube carrying at one end a plastic ring and tube connector. A push button trigger is associated with the housing, and a safety lock is operably coupled to the housing whereby it can affect the function of the trigger. 
   A suitable valve or flow control arrangement is provided for pressure equalization, using, for example, a suitable one way valve or valves. 
   In one embodiment, the present invention comprises a hand held spray gun and supply unit comprising a housing with a hand grip portion, a pump assembly mounted in the housing including a pump and a nozzle, the pump comprising a cylinder with an intake and a piston mounted in the cylinder to pump fluid from the intake through the nozzle. An electric motor is mounted in the housing, and batteries are within a special container associated with the housing. A switch on a face of the housing adjacent to the hand grip is provided for actuating or operating the motor and, therefore, the pump, and a tube depends from the housing into the container for supplying liquid from the container to the intake for discharge through the nozzle. 
   The present invention, in another embodiment, is a dispenser adapted to couple to a fluid container having an opening surrounded by a neck. The dispenser comprises a cap, a dispensing head, an energy source, and a conduit. The cap is adapted to seal the opening fluid tight when the dispenser is coupled to the container. The dispensing head is pivotably secured to the cap and includes a fluid pump, a motor adapted to power the pump, a trigger adapted to actuate the motor, and a nozzle orifice in fluid communication with a discharge end of the pump. The energy source is electrically connected to the motor and extends inside the container. The conduit has a first end in fluid communication with an intake end of the pump and a second end inside the container. In some embodiments, the energy source (e.g., batteries, capacitors, etc.) may be located adjacent to the caps without extending or only slightly extending into the container. 
   The present invention, in another embodiment, is a dispensing attachment for coupling to a container containing a substance to be dispensed. The dispensing attachment comprises a motor, an actuating mechanism adapted to actuate the motor, a pump driven by the motor and including an intake end and a discharge end, a housing enclosing the motor and pump, a nozzle in fluid communication with the discharge end of the pump, and a generally flexible pick-up tube. The generally flexible pick-up tube has a first end and a second end. The first end is in fluid is in fluid communication with the intake end of the pump. The second end is free and carrying a weight formed of a corrosion and rust resistant material. 
   The present invention, in another embodiment, is a sprayer for dispensing a fluid. The sprayer includes a fluid container and a motor operated pump. The motor operated pump includes a pump cylinder, a fluid pathway, and a venting arrangement. The fluid pathway operably connects the container, the pump and a discharge opening. The venting arrangement includes a first vent and a second vent associated with the pump cylinder. The first vent is adapted to allow air into the cylinder and the second vent is in fluid communication with the container, generally opposite to the first vent, and adapted to allow air and excess fluid into the container. 
   One potential problem with motorized pump sprayers is that when an operator of such a sprayer releases the actuating mechanism or trigger to stop spraying, liquid or fluid being dispensed may continue to flow or dribble from the nozzle. One cause may be that the piston happens to be moving forward in the cylinder when the user decides to release the trigger. Inertia inherent in the drive mechanism, e.g., piston, piston rod, etc., gradually slows down against friction and fluid pressure, instead of stopping precisely as desired when the trigger is released. Thus, the problem is that fluid delivered to the pump cylinder continues to flow or dribble from the nozzle even after the operator&#39;s intention is to stop it by releasing the trigger. This becomes messy and/or inconvenient since the fluid stream or spray does not entirely land on the intended surface or target and may instead get on materials or surface for which the fluid or liquid is not intended, perhaps causing damage. Furthermore, this problem is wasteful and costly since more fluid will be needed to spray to complete a job. In some uses or applications of motorized pump sprayers, for example, when the user is spraying poisons or caustic fluids where precise application is important to avoid burning skin or other items, this dribble or drip problem can become dangerous. 
   In motorized sprayers, there may be an air bubble in the fluid in the pump cylinder under compression. This compressed air exacerbates the drip problem by providing a propellant pressure so that even after the piston is stopped at its top dead center position, fluid may continue to drip or flow from the nozzle. 
   In motorized sprayers, such as that of the present invention and others, it would be advantageous to keep the motor running until the piston has actually just begun its return or suction stroke, thus generating negative pressure in the cylinder, at which time the electrical supply to the motor is interrupted or stopped. 
   In one embodiment, the present invention comprises an “anti-dribble” feature for sprayers. In one embodiment, the anti-dribble feature comprises a switching circuit or arrangement that acts to prevent fluid from continuing to flow from the nozzle of the sprayer after a user has released the actuating mechanism or trigger to stop spraying. Thus, an advantage of the present invention is that addresses or avoids dribbling by using an economical positioning, timing or delay switching circuit. 
   While multiple embodiments are disclosed, still other embodiments of the present invention will become apparent to those skilled in the art from the following detailed description, which shows and describes illustrative embodiments of the invention. As will be realized, the invention is capable of modifications in various obvious aspects, all without departing from the spirit and scope of the present invention. Accordingly, the drawings and detailed description are to be regarded as illustrative in nature and not restrictive. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIG. 1  is an elevation view of the non-safety lock side of the handheld power sprayer of the subject invention mounted on a reservoir adapted to contain a fluid. 
       FIG. 2  is an elevation view of the safety lock side of the handheld power sprayer and the reservoir wherein the sprayer is not mounted on the reservoir. 
       FIG. 3  is a plan view of the safety lock in the off position as taken along section line AA in  FIG. 2   
       FIG. 4  is an elevation view of the safety lock side of the sprayer wherein the safety lock side of the housing is removed to reveal the pumping mechanism and the cap is partially cut away to reveal a coupling used to threadably attach the battery tube to the cap. 
       FIG. 4   a  depicts an embodiment of a piston of the pumping mechanism depicted in  FIG. 4 . 
       FIG. 5  is an exploded isometric view of the power sprayer. 
       FIG. 6  is a vertical section taken through the nozzle assembly. 
       FIG. 7  is an isometric view of the interior of the nozzle cap. 
       FIG. 8  is an isometric view of the discharge end of the nozzle valve. 
       FIG. 9  is a vertical section taken through the nozzle assembly. 
       FIG. 10  is an isometric view of the discharge end of the nozzle valve. 
       FIG. 11  is an elevation view of the interior of the nozzle cap. 
       FIG. 12  is a front elevation view of the spherical weight that is mounted on the end of the flexible intake tube. 
       FIG. 13  is an isometric view of the spherical weight that is mounted on the end of the flexible intake tube. 
       FIG. 14  is a schematic of one embodiment of an anti-dribble switch for use with the sprayer of the present invention. 
       FIG. 15 , including  FIGS. 15   a  and  15   b , is a schematic depicting two operational positions of the switch of  FIG. 14 . 
       FIG. 16  depicts one embodiment of the present invention, wherein a switching arrangement of the type shown in  FIG. 14  is incorporated. 
       FIG. 17  is a schematic of a braking circuit which may be incorporated in some embodiments of a sprayer in accordance with the present invention. 
       FIG. 18  is a elevational view representing of one embodiment of the sprayer of the present invention, and depicting an incorporated motor brake, control chip and indicator. 
       FIG. 19  is a elevational view representing of one embodiment of the sprayer of the present invention, and depicting an incorporated rheostatic actuating mechanism or trigger. 
       FIG. 20  depicts another embodiment of the present invention. 
       FIG. 21  depicts detailed of the embodiment depicted in  FIG. 20 . 
       FIG. 22  is a plan view depicting, in representation, another embodiment of the present invention. 
       FIG. 23  is a side view of the embodiment of  FIG. 22 . 
       FIG. 24  is another side view of the embodiment of  FIG. 22 . 
       FIG. 25  is a side view of an exemplary prototype of the present invention in accordance with the embodiment of  FIG. 22 . 
       FIG. 25   a  is a representational side view of the embodiment of  FIG. 25 . 
       FIG. 26  is a view of an exemplary prototype of the present invention in accordance with the embodiment of  FIG. 25 . 
       FIG. 27  is a front view depicting another embodiment of the present invention. 
       FIG. 28  is a side view of the embodiment of  FIG. 27 , depicting several operational or use positions. 
       FIG. 29  is an assembly view of the embodiment of  FIG. 27 . 
       FIG. 30  depicts another embodiment of the present invention. 
   

   DETAILED DESCRIPTION 
   The present invention is a novel and advantageous handheld power sprayer that has a motorized means for pumping a fluid from a reservoir containing the fluid. As will be understood from this detailed description, the power sprayer of the present invention has a configuration that allows it to more closely resemble the size, appearance and feel of standard hand operated sprayers. Thus, the power sprayer of the present invention is easier to hold and less fatiguing to use as compared to prior power sprayers. 
     FIG. 1  is an elevation view of the non-safety lock side of the handheld power sprayer  2  of the subject invention mounted on a reservoir  4  (i.e., a container of common household, garage or gardening liquid such as bathroom cleaner, window cleaner, ARMOR ALL®, fungicides, herbicides, pesticides, water, etc.). As shown in  FIG. 1 , the power sprayer  2  includes a spray head  3 , a cap  14 , a battery tube  16 , and a flexible intake tube  18  with a weight  20 . When the sprayer  2  is mounted on the reservoir  4 , the spray head  3  and cap  14  are located outside the reservoir  4 , while the battery tube  16 , flexible intake tube  18 , and weight  20  are located inside the reservoir  4 . 
     FIG. 2  is an elevation view of the safety lock side of the handheld power sprayer  2  and the reservoir  4  wherein the sprayer  2  is not mounted on the reservoir  4 . As shown in  FIG. 2 , the spray head  3  includes a housing  6 , a nozzle cap  8 , a trigger  10 , and a safety lock  12 . 
   As can be understood from  FIGS. 1 and 2 , the housing  6  is ergonomically contoured such that the portion of the hand between the thumb and forefinger abuts against contoured portion X while the forefinger is positioned to depress the trigger  10 . The housing  6  contains the spraying mechanism of the sprayer  2 . 
   As indicated in  FIG. 2 , the reservoir  4  has an opening surrounded by a neck  22  with male threads. As shown in  FIG. 1 , the cap  14  connects the sprayer  2  to the reservoir  4  via female threads adapted to mate with the male threads of the neck  22 . The cap  14  is adapted to be compatible with most containers  4  used to hold common household, garage and garden liquids. However, in one embodiment, one or more adapters are provided with the sprayer  2  to facilitate the sprayer&#39;s connection to the necks  22  of most, if not all, containers  4 . 
   In one embodiment, the spray head  3  is pivotably attached to the cap  14  such that the spray head  3  may freely pivot 360° about a vertical axis passing through the center point of the neck  22 . This eases the attachment of the sprayer  2  to the neck  22  of the reservoir. 
   The trigger  10  is used to actuate the sprayer  2 . As indicated in  FIGS. 1 and 2 , in one embodiment, the power sprayer  2  is actuated by partially displacing the trigger  10  into the housing  6 . 
   As illustrated in  FIG. 2 , in one embodiment, the safety lock  12  is horizontally displaceable along the housing  6  between a position marked “OFF” and a position marked “ON.” As shown in  FIG. 3 , which is a plan view of the safety lock  12  in the off position as taken along section line AA in  FIG. 2 , when the safety lock  12  is slid into the off position, which is closer to the trigger  10  than the on position, the safety lock  12  prevents the trigger  10  from displacing into the housing  6 . Thus, when the safety lock  12  is in the off position, the power sprayer  2  cannot be actuated via the trigger  12 . Conversely, when the safety lock  12  is in the on position, the trigger  10  may be displaced into the housing  6  to actuate the power sprayer  2 . 
   As illustrated in  FIG. 3 , the safety lock  12  includes a slide button  25  attached by a screw  27  to a block  29 . The housing  6  is sandwiched between the button  25  and block  29  and has a slot  31  through which the button  25  extends to join the block  29 . The slot  31  is sufficiently long to allow the safety lock  12  to slide into or out of engagement with the trigger  10 . The block  29  has a bump  33  that mates with a depression  35  in the housing  6 . The bump  33  and depression  35  serve to positively maintain the safety lock  12  in the off position and to provide a click sound to indicate engagement of the safety lock  12 . 
   In other embodiments, the sprayer  2  may employ other safety measures for preventing unintentional discharge from the sprayer  2 . These safety measures may include other mechanical means for locking and unlocking the trigger  10  of the sprayer  2 , means for preventing the completion of the electrical circuit powering the sprayer  2 , and/or a child-proof safety cap for placement on the nozzle cap  8 . 
   As indicated in  FIGS. 1 and 2 , the nozzle cap  8  is pivotally attached to the housing  6  and allows a user to select between a spray or stream-type application of the fluid. In one embodiment, the nozzle cap  8  has four sides and each side could have a word or other indicia on it, such as “SPRAY” or “STREAM.” In some embodiments other indicators, words or indicia, e.g., the word “OFF” could be used on one of the sides. To select a stream-type application (i.e., the liquid flow from the nozzle cap  8  is a strong, generally coherent stream), the nozzle cap  8  is pivoted until a side of the nozzle cap  8  with the word “STREAM” is facing upwards. Similarly, to select a spray-type application (i.e., the liquid flow from the nozzle cap  8  is a generally fine mist), the nozzle cap  8  is pivoted until a side of the nozzle cap  8  with the word “SPRAY” is facing upwards. In embodiments including an off setting, when the nozzle cap  8  is pivoted until a side of the nozzle cap  8  with the word “OFF” is facing upwards, the nozzle cap  8  will be shut off and no flow will be able to emit from the nozzle cap  8 . 
   As shown in  FIG. 1 , when the sprayer  2  is mounted on a reservoir  4 , the battery tube  16  extends from the cap  14  down into the reservoir  4 . In one embodiment, as indicated in  FIG. 2 , the battery tube  16  contains three AAA batteries  24  that may be replaced when depleted. In other embodiments, the battery tube  16  may include a greater or lesser number of batteries  24 . Also, the batteries  24  may be other sizes, such as AA. To allow the replacement of the batteries  24 , the battery tube  16  is threadably removable from the sprayer  2 . 
   In one embodiment, the disposable batteries  24  illustrated in  FIGS. 1 and 2  are replaced with a rechargeable battery that is permanently installed in the battery tube  16 . Once the energy is depleted from the rechargeable battery, the battery tube  16  is threadably removed from the sprayer  2  and inserted into a charger for recharging. In some embodiments, recharging may be accomplished inductively. 
   In one embodiment, where the sprayer  2  itself is meant to be disposable, the disposable batteries  24  illustrated in  FIGS. 1 and 2  are replaced with a capacitor and coil system or a set of permanently installed non-rechargeable batteries. Thus, once the energy in the capacitor or non-rechargeable batteries is depleted, the entire sprayer  2  is thrown away. In some embodiments, the energy source may be located adjacent to the cap  14 , as shown in phantom in  FIG. 2 , depicting a capacitor  24 ′ near the cap  14 . 
   Positioning the sprayer energy source (i.e., the batteries  24 ) within the reservoir  4  or adjacent to the cap  14  is advantageous for at least two reasons. First the sprayer  2  can have an energy source that is long lasting and powerful without resulting in an oversized and cumbersome housing  6 . Second, positioning the batteries  24  within the reservoir lowers the sprayer&#39;s center of gravity. This makes a reservoir  4  equipped with the sprayer  2  less likely to tip over when set on a surface. Also, placing the weight of the batteries  24  below the gripping point of the sprayer  2  reduces the fatigue caused by using the sprayer  2 , as compared to placing the weight of the batteries  24  above the gripping point (i.e., in the upper portions of the housing  6 ). Another advantage is that placing the batteries in a position in which the contents of the reservoir can contact them or their housing is that the contents help keep the batteries cool. Reduction of heat advantageously helps prolong battery life. 
   As shown in  FIG. 1 , the flexible intake tube  18  has a discharge end that is in fluid communication with the spraying mechanism contained in the housing  6  and an intake end that terminates within the weight  20  and is in fluid communication with the fluid  26  contained within the reservoir  4 . The weight equipped flexible intake tube  18  is advantageous because it allows the sprayer  2  to operate regardless of the orientation of the sprayer  2  and its attached reservoir  4 . For example, when the sprayer  2  is operated in an upright position as depicted in  FIG. 1 , the weight  20  causes the intake end of the flexible tube  18  to sink to the bottom of the fluid  26 . Likewise, when the sprayer  2  is operated in an upside down position and the fluid  26  has accumulated near the neck  22  of the reservoir  4 , the weight  20  causes the intake end of the flexible tube  18  to sink to the bottom of the fluid  26  (i.e., near the cap  14 ). Thus, regardless of the orientation of the reservoir  4 , the weight  20  causes the intake end of the flexible tube  18  to be kept in fluid communication with the fluid  26  in the reservoir  4 . 
   For a detailed description of the pumping mechanism contained in the housing  6  and a description of the overall operation of the power sprayer  2 , reference is now made to  FIGS. 4 and 5 .  FIG. 4  is an elevation view of the safety lock side of the sprayer  2  wherein the safety lock side of the housing  6  is removed to reveal the pumping mechanism and the cap  14  is partially cut away to reveal a coupling  28  used to threadably attach the battery tube  16  to the cap  14 .  FIG. 5  is an exploded isometric view of the power sprayer  2 . 
   As indicated in  FIGS. 4 and 5 , the pumping mechanism is contained within the housing  6  and includes an electric motor  30 , a transmission  32  and a pump  34 . The motor  30  includes a drive gear  36 , and the transmission  32  includes a series of three gears  38   a ,  38   b ,  38   c , a cam  40 , and a cam follower shaft  42 . The pump  34  includes a piston  44  that is linearly displaceable within a cylinder  46  of the pump  34 .  FIG. 4   a  depicts in more detail that the piston has flanges  45 , with tips  47 , which help clear, purge or “sweep” the cylinder  46 . The flanges facilitate the pumping of the contents, helping to seal the cylinder by acting as “O-rings,” and maximizing the pump suction to draw in and push out the fluid or liquid being dispensed. The flanges also assist in the replacement of air pressure in and return of excess liquid or fluid to the container, thereby helping to prevent both leaking and a vacuum in the reservoir. Although two generally annular, circumferential flanges are depicted, it should understood that other embodiments, for example, using a different number of flanges or flanges of a different shape, may be used. Also, the flanges may be generally flexible, particularly the tips, and/or integrally formed with the piston, or they may be separate structures, e.g., rings, that are operably coupled to or carried by the piston. While  FIGS. 4 ,  4   a  and  5  illustrate the employment of a piston-type pump  34 , those skilled in the art will readily understand that a gear pump or other suitable pumping mechanism may be substituted for the piston pump  34  without departing from the spirit of the invention. 
   With reference to  FIGS. 14-16 , some embodiments of the present invention can include a switch mechanism  140 . This switch mechanism  140  may be thought of as a timing, positioning or delay circuit. It provides for and/or enhances the clearing, purging or sweeping of the cylinder  46 , and/or helps to prevent the fluid to be dispensed from continuing to flow, drip or leak from the nozzle of the sprayer after a user has released the trigger. Thus, the switch mechanism  140  provides an “anti-dribble” feature for embodiments of motorized pump sprayers. With reference to  FIGS. 14 and 15 , in one embodiment the switch mechanism  140  comprises a cam  142 , a spring  144 , an electrical contact  146  and suitable wires  148 . Two wires  148  are shown but as many as necessary may be used. In some embodiments, the switch  140  may be what is commonly known as a leaf-type switch, but any suitable arrangement of similar or other suitable components for providing similar functions may be used. 
   The above-identified switch components are arranged to control the position of the piston  44  in the cylinder  46 . In effect, the switch mechanism  140  creates a secondary operating circuit (indicated generally at “B” in  FIG. 14 ) to keep an electrical supply on to the motor (even though the trigger is released and the primary or trigger circuit, indicated generally at “A” is broken) until the piston  44  is in a desired position. In one embodiment, the cam  142  is coupled to or into the gear assembly (although it could be located in a separate housing, on the piston actuating arm or in another suitable location). The cam  142  is shaped and positioned adjacent to the switch mechanism  140  is such a way that when the operator lets go of the trigger, the secondary circuit provided by the switching mechanism  140  is kept closed until the piston  44  begins its return stroke. At that time, the cam  142  is turned to present its flattened area  143  to the switch, allowing the switch to open via the urging of the spring  144 , which stops all power to the motor. Thus, any residual inertia and/or gradual slow down of the piston  44  occurs on its return stroke, thereby eliminating or substantially reducing further filling of the cylinder. 
     FIG. 15  depicts two states of one embodiment of the switch mechanism  140 , namely with the switch mechanism on ( FIG. 15   a ) and with the switch mechanism off ( FIG. 15   b ).  FIG. 16  depicts one arrangement of the switch mechanism  140  as it might be used in a sprayer such as the sprayer of the present invention. 
     FIG. 17  depicts a circuit  160  of the type which may be used to provide electrical motor braking, particularly as to small DC motors. It is described by Reed Electronics. In the present invention, as shown at  160  in  FIG. 18 , such a circuit  160  may be used to enhance the anti-dribble, clear, purge, or sweep features. As set forth above, one possible difficulty with motorized sprayers is that the piston may travel after the actuator is released. Further, the motor as well may tend to move after the trigger is released depending on its initial speed and inertia. The circuit depicted in  FIG. 17  can be useful for applications and systems that may not need absolutely precise speed of control and stopping positions, but which can benefit from enhanced deceleration. 
   Generally, the circuit depicted in  FIG. 17  comprises two portions. Q 1  plays the role of the switch. D 2  protects Q 2  against inductive surges. Resistor R 2  keeps Q 1  off as long as Switch S 1  is open. R 1  limits the base current of Q 1  when S 1  is closed. S 1  can be a manual switch, a relay contact, an optocoupler, or a transistor. If S 1  is closed, Q 1  turns on, and the motor runs. Q 2 , D 1  and R 3  comprise the braking circuit. This circuit is similar to the output circuit of TTL gates. D 3  protects Q 2  from inductive surges. When S 1  closes, Q 1  turns on, and the voltage at Point A goes high (near V cc ). The voltage at the base of Q 2  is higher than the voltage at the emitter, because of the voltage drop is D 1 . If you open S 1  while the motor is running, Q 1  turns off. The voltage at Point A is near zero. The self-induced, back-EMF voltage from the motor sees a short circuit in Q 2 , whose emitter is more positive than its base and thus conducts. Short-circuiting the motor results in braking it the higher the speed or the motor, the stronger the braking effect. 
   A braking circuit or function such as that depicted in  FIG. 17  can be used in conjunction with the anti-dribble switch mechanism  140  as described with reference to  FIGS. 14-16 . Further, it may be used in any embodiment of a power sprayer in accordance with the present invention, with or without an anti-dribble switch mechanism and/or with or without features for helping to clear, purge or sweep, to help prevent accidental dripping or discharge of the fluid to be dispensed after the actuator or trigger is released to stop spraying. 
   As indicated in  FIGS. 4 and 5 , the drive gear  36  powers gear  38   a , which in turn powers gear  38   b , which in turn powers gear  38   c . Gear  38   c  causes the cam  40  to rotate, which causes the cam follower shaft  42  to reciprocally, linearly displace. The linear displacement of the cam follower shaft  42  causes the piston  44  to reciprocally, linearly displace within the cylinder  46  of the pump  34 . 
   As shown in  FIGS. 4 and 5 , the base of the housing  6  has a grooved neck  48  that receives a disc  50  therein. The disc  50  is secured to the top of coupling  28 , which is pivotally mounted within the cap  14 . As shown in  FIG. 5 , the cap  14  has a waterproof ring  54  for sealing the opening in the neck  22  of reservoir  4  when the cap  14  is threaded on tight. 
   As illustrated in  FIG. 5 , the top of the battery tube  16  has a plurality of male threads  56  for threadably engaging the female threads within the coupling  28 . When battery tube  16  is threaded tightly into the coupling  28 , a sealing ring  58  prevents any fluid  26  from entering the battery tube  16  from the reservoir  4 . 
   As shown in  FIG. 4 , a negative conductor  60  makes electrical contact with the negative pole of the bottom battery  24 . The negative conductor  60  is electrically connected to a first negative conductive pathway  62  that runs the length of the battery tube  16  to make electrical contact with a negative conductor ring  64  mounted in the bottom inside surface of the coupling  28 . The negative conductor ring  64  makes electrical contact with a second negative conductive pathway  66  that runs to a first electrical lead on the motor  30 . 
   As shown in  FIG. 4 , the coupling  28  has a positive conductor  68  for making electrical contact with the positive pole of the top battery  24  in the battery tube  16 . The positive conductor  68  is electrically connected to a first positive conductive pathway  69  that is electrically connected to a conductive sleeve  70  near the trigger  10 . A conductive saddle  72  is mounted on the trigger  10  and oriented and configured to mate with the conductive sleeve  70  when the trigger  10  is depressed by the user. 
   As indicated in  FIG. 4 , a second positive conductive pathway  74  is electrically connected to the conductive saddle  72  and runs to a second electrical lead on the motor  30 . When the trigger  10  is depressed, the conductive saddle  72  and the conductive sleeve  70  are placed in electrical contact. This completes the electrical circuit between the energy supply (i.e., the batteries  24 ) and the motor  30  and causes the sprayer  2  to function. In one embodiment, a portion of the second positive conductive pathway  74  is formed around the pivot point  76  of the trigger  10  to serve as a spring to forwardly bias the trigger  10 . 
   As shown in  FIG. 4 , when the piston  44  is displaced towards the nozzle cap  8 , air is drawn in through a first air check valve  78  (which in one embodiment is a spring loaded ball type check valve) into the rearward section  46   a  of the cylinder  46 . In one embodiment, the first air check valve  78  is located near the top of the cylinder  46 . On its backstroke, as the piston  44  displaces away from the nozzle cap  8 , the air is forced out of the rearward section  46   a  of the cylinder  46 , into an air tube  80 , through a second air check valve  82  (which in one embodiment is a spring loaded ball type check valve), through an air channel  84  running through the coupling  28 , and into the reservoir  4  to prevent vacuum lock when the sprayer  2  is operating. In one embodiment, the second air check valve  82  is located near the bottom of the cylinder  46  approximately opposite the first air check valve  78 . This linear or in-line arrangement allows any moisture accumulating in the rearward section  46   a  of the cylinder  46  to be purged, flushed, swept from and/or drained from the rearward section  46   a  into the reservoir  4 . This purging is enhanced by the flanges  45 . 
   As indicated in  FIG. 4 , when the piston  44  is displaced away from the nozzle cap  8 , the fluid  26  is drawn in into the intake opening  86  of the flexible intake tube  18 , through the flexible intake tube  18  (which passes through the coupling  28 ), through a fluid check valve  88  (which in one embodiment is a spring loaded ball type check valve), and into the front section  46   b  of the cylinder  46 . In one embodiment, the fluid check valve  88  is located near the bottom of the cylinder  46 . As the piston  44  displaces towards the nozzle cap  8 , the fluid  26  is forced out of the front section  46   b  of the cylinder  46  and through the nozzle assembly  90  to the atmosphere. 
   As shown in  FIG. 5 , the nozzle assembly  90  includes a nozzle tube  100 , a nozzle valve  102  and the nozzle cap  8 . As illustrated in  FIG. 6 , which is a vertical section taken through the nozzle assembly  90 , the nozzle tube  100  has a nozzle channel  110 , a pivot surface wall  111 , and a pin  112  on which the nozzle valve  102  is mounted. The nozzle cap  8  is pivotally mounted about the pivot surface wall  111 , and the pivot surface wall  111  has at least one retaining ridge  113  that mates with a corresponding groove in the nozzle cap  8  to retain the nozzle cap  8  in place. 
   As indicated in  FIG. 6  and more clearly depicted in  FIG. 7 , which is an isometric view of the interior of the nozzle cap  8 , the nozzle cap  8  has at least one cap channel  114  that is in fluid communication with the nozzle channel  110 . The nozzle cap  8  also has a recessed area  115  surrounding a discharge orifice  116 . 
   As illustrated in  FIG. 6  and more clearly depicted in  FIG. 8 , which is an isometric view of the discharge end of the nozzle valve  102 , the nozzle valve  102  has a radial channel  120  and a tangential channel  122  that lead to a circular recessed center  124  at the center of the nozzle&#39;s end. The circular recessed center  124  and the recessed area  115  in the nozzle cap  8  combine to form a swirl chamber. The tangential channel  122  and the radial channel  120  each have a leader channel  126  that is recessed into the cylindrical side  128  of the nozzle valve  102 . 
   As shown in  FIG. 6 , when the nozzle cap  8  is pivoted about the pivot surface wall  111  such that the word “STREAM” on the nozzle cap  8  is oriented upwards, the cap channel  114  is placed in fluid communication with the leader channel  126  that is associated with the radial channel  120 . Thus, when the sprayer  2  is actuated, liquid travels through the nozzle channel  110 , the cap channel  114 , the leader channel  126 , the radial channel  120 , the swirl chamber  115 ,  124 , and out the orifice  116  as a stream-type flow. 
   Similarly, when the nozzle cap  8  is pivoted about the pivot surface wall  111  such that the word “SPRAY” on the nozzle cap  8  is oriented upwards, the cap channel  114  is placed in fluid communication with the leader channel  126  that is associated with the tangential channel  122 . Thus, when the sprayer  2  is actuated, liquid travels through the nozzle channel  110 , the cap channel  114 , the leader channel  126 , the tangential channel  122 , the swirl chamber  115 ,  124 , and out the orifice  116  as a spray-type flow. 
   In some embodiments, when the nozzle cap  8  is pivoted about the pivot surface wall  111  to a selected position, the leader channels  126  are not placed in fluid communication with the cap channel  114 . Consequently, liquid cannot flow through the nozzle assembly  90 . 
   An alternative configuration for the nozzle assembly  90  is shown in  FIG. 9 , which is a vertical section taken through the nozzle assembly  90 . As indicated in  FIG. 9  and more clearly depicted in  FIG. 10 , which is an isometric view of the discharge end of the nozzle valve  102 , the nozzle valve  102  has a leader channel  126  that is recessed into the cylindrical side  128  of the nozzle valve  102 . The leader channel  126  runs from near the base of the nozzle valve  126  to the end  150  of the nozzle valve  102 , which is generally uniformly planar. 
   As indicated in  FIG. 9  and more clearly depicted in  FIG. 11 , which is an elevation view of the interior of the nozzle cap  8 , the nozzle cap  8  has at least one radial channel  220  recessed into the interior surface of the nozzle cap  8 . The nozzle cap  8  also has at least one tangential channel  222  recessed into the interior surface of the nozzle cap  8 . Each radial and tangential channel  220 ,  222  extends to a central circular recessed area  215  in the interior surface of the nozzle cap  8 . The circular recessed area  215  surrounds the discharge orifice  116 . The circular recessed area  215  serves as a swirl chamber. 
   In one embodiment, as illustrated in  FIG. 9 , the circular recessed area  215  tapers towards the discharge orifice  116  and, as a result, has a Y-shaped cross-section. In another embodiment, the circular recessed area  215  does not taper towards the discharge orifice  116 , but has a surface that is generally perpendicular to the axis of the discharge orifice  116 . In other words, the circular recessed area  215  has a T-shaped cross-section as depicted in  FIG. 6 . 
   As shown in  FIG. 9 , when the nozzle cap  8  is pivoted about the pivot surface wall  111  such that the word “STREAM” on the nozzle cap  8  is oriented upwards, the radial channel  220  is placed in fluid communication with the leader channel  126 . Thus, when the sprayer  2  is actuated, liquid travels through the nozzle channel  110 , the leader channel  126 , the radial channel  220 , the swirl chamber  215 , and out the orifice  116  as a stream-type flow. 
   Similarly, when the nozzle cap  8  is pivoted about the pivot surface wall  111  such that the word “SPRAY” on the nozzle cap  8  is oriented upwards, the tangential channel  222  is placed in fluid communication with the leader channel  126 . Thus, when the sprayer  2  is actuated, liquid travels through the nozzle channel  110 , the leader channel  126 , the tangential channel  222 , the swirl chamber  215 , and out the orifice  116  as a spray-type flow. 
   As indicated in  FIGS. 12 and 13 , which are front elevation and isometric views, respectively, of the spherical weight  20  that is mounted on the end of the flexible intake tube  18 , the intake opening  86  is recessed in the center of a disc  92  mounted on the spherical weight  20 . The disc  92  has channels  94  that run from the outer circumference of the disc  92  to the intake opening  86 , thereby forming protrusions  96  that extend beyond the intake opening  86 . The protrusions  96  and channels  94  combine to prevent the intake opening  86  from being blocked by a surface of the reservoir  4  or the cap  14 . 
   In one embodiment, the weight  20  is a very dense polymer sphere. In other embodiments, the weight  20  may be ceramic, glass, rubber, die cast metal, brass, etc. Regardless of the material selected, the material should be resistant to the corrosive effects of the liquid contained in the reservoir  4  and dense enough to sink in the liquid. The weight  20  is sized to be sufficiently heavy to draw the intake opening  86  of the flexible tube  18  to the bottom most portion of the fluid  26  contained in the reservoir  4 , regardless of whether the reservoir  4  is oriented upright, sideways, upside down, etc. 
   In one embodiment, the flexible intake tube  18  is a very flexible silicone rubber. In other embodiments, the flexible intake tube  18  is another very flexible polymer. The length of the flexible intake tube  18  is sufficient to reach the bottom of the container, but not so excessive that it tangles with itself. 
     FIG. 18  is a elevational view representing of one embodiment of the sprayer of the present invention, and depicting an incorporated motor brake  160  of the type depicted in  FIG. 17 .  FIG. 18  further depicts the incorporation of a suitable microprocessor control chip or PCB board  162 . Such a controller  162  may be programmed and/or used to sense, remember, control and regulate functions and operations of a sprayer in accordance with the present invention.  FIG. 18  further depicts the incorporation of an indicator or display feature  164 . This indication or display feature  164  may be visual, in the form of a suitable LED (as shown), bulb, LCD, etc., or it may be audible or tactile. Such an indicator  164  may be used to, for example, indicate low battery power or as an in-store attraction device. It can be operably coupled to the controller  162  if such a controller is used. It may have its own power source, e.g., a button battery, or it may share the sprayer power source. It could be operated independently of the trigger or it could be activated by depressing the trigger. 
     FIG. 19  is a elevational view representing of one embodiment of the sprayer of the present invention, and depicting a rheostat or rheostatic switch  166  operably coupled to the actuating mechanism or trigger  10 . Rheostatic arrangements, switches or circuits are well-known, and any suitable rheostatic arrangement, switch or circuit can be used in a sprayer in accordance with the present invention to, for example, control or regulate the speed of the motor at the actuating mechanism or trigger, thereby controls the speed that the pump cycles and the amount of fluid discharged. Note that, in a sprayer in accordance with the present invention, the trigger may be urged to its off position by a suitable spring  168  or other biasing or tensioning device. 
     FIGS. 20 and 21  depict an embodiment of the sprayer of the present invention, wherein the sprayer  3  is operably coupled to, but remote from, separate, or not directly connected to the container  4  of material to be dispensed. As shown in  FIG. 21 , this embodiment comprises a nozzle  300 , stopper valve  302 , nozzle  304 , valve case  306 , gear  308 , seal  310  (and other seals and washers as needed), gear box  312 , gears  314 ,  316 ,  317 . As further shown in  FIG. 20 , this embodiment comprises a generally pistol-shaped sprayer or spray head  3 , comprising a housing  320  formed by housing halves and containing or mounting the components referenced in  FIG. 21 . The spray head further comprises, a PCB  322 , a conduit  324 , battery housing  326  with suitable battery contacts  328  and an actuator comprising a trigger  330  and trigger switch  332 . The conduit  324  operably connects the spray head to a container  334  through a cap  336 . The container may be any suitable distance from the spray head and may be carried separately from the spray head. The spray head may have a storage position in which it is detachably connected to a container, as by a hook and loop connector. 
   It should be appreciated that any embodiment of the spray head  3  in accordance with the present invention could be disposable. That is, any spray head or assembly  3  could be adapted to carry non-replaceable alkaline batteries, for example in a suitable location such as in the head or the handle. Thus, for example, a disposable spray head could be purchased, coupled to a container and disposed of when the container is empty. 
     FIGS. 22-26  depict an embodiment of a pump suitable for use with the sprayer of the present invention, more particularly, a peristaltic-type pump. Referring to  FIG. 25   a , generally, the depicted pump includes a pump housing shell  340 , including formed by appropriate housing portions or shells. One or the other part of the housings or shells carries suitable axes or pins  342 , which in turn carry a gear and roller assembly  343 , comprising rollers  344  and gears  346 . Any number of rollers, for example 3, driven by any number of gears could be used. A suitable size motor  348  is incorporated with the pump housing or suitably mounted adjacent the pump housing in the spray head. A flexible plastic tube  350  made out of a suitable material such as silicon extends from the container to the nozzle  352  thereby forming a fluid pathway operably incorporating the peristaltic pump. In use, the rollers  344 , driven by the gears  346  periodically and repeatedly compressed the flexible tube  350  to send a pulse or surge of the substance to be dispensed through the tube and out the nozzle. The pump embodiment of  FIGS. 22-26  may be actuated by a suitable trigger mechanism  354 , and it may have a safety lock  356 . A suitable motor is a FA-130RA-2270 motor, but any suitable motor might be used. The gear ratio of the depicted gear arrangement is 30:1, but that may be varied as required. As in any of the embodiments of the present invention, it should be understood that the motor can be positioned as selected relative to the gear assembly. In other words, a suitable motor can be directly or indirectly coupled to provide the desired motive or drive effect. 
     FIGS. 25 and 26  depict an exemplary prototype of the sprayer of the present invention comprising a peristaltic pump, and depict how the compressible conduit  350  passes through the pump unit from the container  4  to the nozzle  8 . 
   Any of the embodiments of the powered sprayer of the present invention may be provided with a suitable dispense characteristic adjustment nozzle. Such nozzles include standard-type spray, stream, adjustable nozzles which provide for a stream of the substance to be dispensed, e.g., a nozzle with straight channels inside the nozzle cap to produce a high velocity narrow stream. For spray or mist characteristics, the nozzle may be adapted by having, for example, suitable grooves in a spiral to impart spin and turbulence. Such a nozzle can produce a plume or cloud of the product to be dispensed in fine, medium and coarse characteristics. Fine spray would correspond to a highly atomized mist, medium to an atomized spray and coarse to a spray or rough stream. 
   The nozzle  8  for the present invention may be available in a spray only configuration, or it could be available in a foaming nozzle arrangement wherein air intakes allow air to be introduced into the stream of material passing through the nozzle either in a stream or spray pattern. This air introduction creates turbulence to mix air and the fluid to be dispensed for foaming action. Any of the nozzle could be adapted to accommodate attachments, working ends or tools for specific purposes, e.g., scrubbing, polishing, disinfecting, etc. 
   In another embodiment, the nozzle may comprise a “infinity” spray to stream adjustable nozzle. This type of adjustable nozzle is well known to those skilled in the art and includes or is exemplified by screw-type nozzles with a full range of stream and spray patterns. Any of the nozzle embodiments may include a snap fit, removable cap rinsing or cleaning the cap and/or the nozzle. 
   The components which are integrated to form the present invention, including the outer shells and components which contact substances to be dispensed may be made of any suitable material. For example, the flexible tube could be made of silicon. Polyethylene or stainless steel are other exemplary materials which have good resistance to organic solvents, acids and bases and other chemicals which could be applied using the present invention. 
   In one embodiment, the present invention can comprise a caddy (which also may be called a carrier, cart, barrow or the like) designed to be integrated with and/or used with the power sprayer of the present invention.  FIGS. 27-30  disclose and depict exemplary caddies for use in and around the home, garden, shop or garage. As shown in  FIGS. 27-29 , the caddy  400  comprises a body, a tank  404 , and a telescoping handle  406  attached to the body and provided with a comfort grip. The tank, which can be attached and detached from the body, or which can be formed integrally with the body, includes a transparent portion  405  for monitoring contents level. The handle or the body may carry a holster  410  for carrying a spray head  3 . The caddy includes a pair of wheels  412  which may be of the snap fit non-lube bearing-type wheels connected by a steel axle  414 . A hose  416  is operably coupled to the tank at one end and to the spray head  3  at the other end. The spray head  3  depicted in  FIG. 28  can incorporate any pump and/or any of the features described above with respect to the present invention and, in some embodiments, can comprise a high output gear turbine pump. In one embodiment, this type of pump comprises an high speed motor and a high output fluid gear pump which can create a continuous stream of fluid up to 14 ft., or in a 25 ft. radius. The components of the caddy may be formed of appropriate materials, for example, various suitable plastics may be used such as for the molded portions, such include plastics commonly known as “PP”, “PVC”, “PVDF”, or “PBT” resins suitable soft tubing may be made out of FCR, nitrile-PVC blend or other PVC-based materials. Suitable silicon or other type O-rings may be provided for seals. Generally, any material with properties useful for use with certain material to be dispensed, liquid or fluid, may be integrated as components or the present invention. 
   In one embodiment, the caddy incorporates a power sprayer. The sprayer may be operated or powered by a suitable pump, including gear, piston or peristaltic pumps. Any suitable motor and/or gear or power transfer arrangement may be used to drive the selected type of pump. In some embodiments, the pump, pump drive, conduit and nozzle features may be tuned together for optimum performance. As described above, the nozzle itself may be a single dispense mode nozzle, an adjustable spray nozzle, a foaming nozzle, or an infinitely adjustable nozzle. 
     FIG. 30  depicts an embodiment of the caddy, incorporating the power sprayer of the present invention. This embodiment comprises a body  402  with a tray-like container accommodating feature, one or more spray heads  3 , and suitable hoses or conduits (which may be part of the sprayer head(s)  3 ). The body may be molded or otherwise suitably formed. Two pistol-type power sprayers  3  may be provided, as well as two separate containers or two separate areas within the body for accommodating containers, as well as other items such as wash mitts, chamois, etc. In this way, one of the sprayers  3  may be used for spraying a window cleaner or vinyl protectant, and the other sprayer may be used to spray waxes, tire dressing, bug cleaners, soap, etc. Each power sprayer may be provided with an independent power source as described above (e.g., a battery or batteries as shown in  FIG. 20 ) and are coupled to the container of material to be dispensed by a suitable conduit or tube. 
   Again, components of the present invention may be formed from any suitable material, including plastics, vinyls, resins, metals, alloys, adhesives and other suitable materials, and suitable forming or manufacturing and assembly processes may be used. 
   Although the present invention has been described with reference to preferred embodiments, persons skilled in the art will recognize that changes may be made in form and detail without departing from the spirit and scope of the invention.