Abstract:
A portable mister for cooling ambient air is disclosed comprising a housing for entirely containing a cooling agent, an irrigation system connected to the housing for receiving the cooling agent from the housing and dispersing the cooling agent in ambient air, and a pump for facilitating the transfer of the cooling agent to the irrigation system. The mister is portable in that the cooling agent is entirely enclosed in a portable housing. That is, the mister user need not connect the mister to a continuous cooling agent source for operation. Additionally, the irrigation system is configured for placement to cool the ambient air of a broad area. The housing may include a system for including a fragrance in the cooling agent. The fragrance including system facilitates added a pleasant aroma to the dispersed cooling agent.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
   This application claims priority to U.S. Provisional Application No. 60/481,536, titled “Portable Mister for Adjusting Ambient Temperature,” filed Oct. 21, 2003. 

   FIELD OF INVENTION 
   The present invention relates to a portable mister for adjusting the ambient temperature of an environment. 
   BACKGROUND OF INVENTION 
   Recent years have seen an increase in worldwide global temperatures. The result of the increasing global temperatures is that many places and people around the world experience uncomfortably hot seasonal temperatures especially during the summer months. Finding respite from the uncomfortable temperatures often means staying indoors and being blanketed by the cooling affects of air-conditioned air. For those forced to venture outdoors, “air conditioning” is not typically available. Some relief from the uncomfortable outside temperatures can be obtained by finding a shaded area not in direct sunlight. However, in some cases, even shaded areas do not provide sufficient cooling, especially if, for example, the temperature in the shade is 100° F. or higher. As such, much effort and resources are being focused on developing techniques for cooling persons who are forced to endure uncomfortably hot seasonal temperatures when outdoors. 
   One such technique provides cooling by exploring the cooling properties of evaporating mist. Cooling occurs when mist droplets impinge upon a target and are evaporated into the surrounding air. Additional cooling takes place if the liquid itself is very cold relative to the surrounding air. Further, an object or observer may be additionally cooled if an air stream transports the liquid to an observer, and the air stream blows on the user so as to accelerate the evaporation process. 
   The evaporative temperature change results from the process whereby droplets of the liquid extract heat energy from the air and use the energy to change the phase of the droplet from liquid to vapor. Thus the temperature change is achieved without the introduction of external refrigeration power, unlike cooling systems which extract heat from the refrigeration system component(s). In contrast, when a droplet evaporates, the latent heat energy expended in vaporization is drawn from the warm air, which accounts for the temperature drop. 
   It is well known that with a given mixture of the air and water, the temperature achieved by evaporative cooling varies with the initial dryness of the ambient air. For example, given dry warm air at 95° F. (35° C.) and 20 percent relative humidity, atomizing ambient temperature water therein can drop the temperature of the mixture to as low as 66° F. (19° C.). Similarly, if the same ambient air at 95° F. has a relative humidity of 50 percent, then atomizing the water reduces the temperature of the mixture to about 80° F. (27° C.). As should be easily understood, atomizing a cooled water source into ambient air reduces the temperature of the resulting air-water mixture even further. Where tap water from the domestic supply is used as a water source, the tap water will be relatively cool after flowing for a time. As such, many inventions, which use atomized water as a cooling source, make use of ordinary tap water as a cooling agent. The prior art systems, however, contain various deficiencies, in that the systems are often too inconvenient or not fully portable, as described below. 
   With the above in mind, many prior art systems incorporate a fine mist or spray as the primary cooling agent. For example, one conventional method for providing a mist or spray for cooling is disclosed in U.S. Pat. No. 6,398,132, issued Jun. 4, 2002, to Junkel. The Junkel patent generally discloses a portable spray misting device, which is fully handheld when operated. The device includes an internally hollowed body capable of holding a volume of fluid to be dispensed. The liquid is dispensed when a user manually pulls a trigger disposed alongside the hollowed body, which causes the liquid to be drawn toward a spray dispensing head for projecting the liquid as a mist into fan blades of a fan unit. The fan unit, in turn, dispenses the mist into the atmosphere, and onto a user, thereby cooling the user through mist evaporative principles. 
   The invention of the Junkel patent is suitable for users who wish to achieve personal cooling, since it ordinarily may be used by only one user at a time using one hand. However, the Junkel invention is deficient in that users must operate the invention manually, typically leaving only one hand to perform everyday tasks. That is, since the Junkel invention requires the use of at least one user hand to operate, the user of the Junkel invention will be limited in the activities the user may perform while staying cool. Thus, an invention is needed which cools a user without user assistance or user manipulation, thereby freeing the user to perform various other activities. 
   A typical invention, which cools a user without user assistance, is disclosed, for example, in U.S. Pat. No. 5,613,371, issued Mar. 25, 1997, to Nelson. The Nelson patent generally discloses a method and apparatus for misting vehicle occupants by providing a fine spray of water into the air inside and surrounding the vehicle. In accordance with Nelson, a pumping system forces water from a water reservoir on board the vehicle through mister nozzles. When attached to a vehicle, the Nelson invention cools the vehicle occupants while permitting the occupants to perform other activities. For example, where the Nelson invention is affixed to a golf cart, the occupants are cooled when being transported from golf stroke to golf stroke. 
   Similar systems are disclosed for example, in U.S. Pat. No. 5,373,703, issued Dec. 20, 1994, to Pal, and U.S. Pat. No. 6,151,907, issued Nov. 28, 2000, to Hale. The aforementioned Nelson, Pal, and Hale systems are sufficient for cooling a vehicle occupant while the occupant is seated therein. However, the systems are not suitable for cooling the occupant when the occupant exits the vehicle, such as, for example, when the user must leave the vehicle to engage in an outside activity. For example, where a user installs the aforementioned system on a golf cart while golfing, the user must typically exit the vehicle to advance the ball down the course. As such, the Nelson, Pal and Hale systems are not suitable for cooling persons situated on the outside of a vehicle. 
   One method for cooling a user outside a vehicle is disclosed in U.S. Pat. No. 5,330,104, issued Jul. 19, 1994, to Marcus. The Marcus patent generally discloses a self-contained portable mister which may mist an outdoors environment without assistance or intervention from a user. The portable misting apparatus includes a self-priming pump disposed inside a soundproof housing. The housing may include an operable lid and pivotable carrying handle. The invention further includes a rechargeable battery for powering the pump and a solar cell array disposed in the operable lid for recharging the battery. Liquid is supplied to the invention by drawing the liquid from a reservoir, such as a lake, stream, pond, swimming pool, ice chest, bucket, or the like, which is remote to the location of the invention housing. Alternatively, the invention may be adapted to provide the liquid from a pressure source of water. The pump further provides the liquid to a misting wand, which conveys the liquid to a plurality of misting nozzles. The housing of the Marcus invention further includes a cavity suitable for storage of a misting wand, when the invention is not in use. 
   One problem with the Marcus invention, however, is that a solar cell battery powers the invention. It is well known that solar cell batteries need the advent of light (e.g., sunlight or direct sunlight) for recharging and for continuous operation. Thus, the Marcus invention would necessarily have limited use when used in shaded environments or environments where light is limited. As such, a need exists for a mister system which can be used irrespective of whether the system is placed in direct light, or in a shaded area. 
   In addition, as a source for providing the cooling liquid, the Marcus invention uses a reservoir, such as a lake, stream, pond, swimming pool, ice chest, bucket, or the like, located remote to, and in communication with, the invention housing. To operate the Marcus invention, a user must provide the cooling liquid to the invention by, for example, locating the invention near a source of water (e.g., lake, stream, etc.) or to bringing the water to the invention (e.g., ice chest, bucket, etc.). As such, for example, the Marcus invention is limited in its portability, in that the user must determine the location of the liquid supply when deciding the location of invention usage, and the user may ordinarily have to supply the liquid supply in the form of a reservoir positioned externally to the invention housing. Therefore, a need exists for a more portable misting system, such as, a misting system which permits usage without requiring the user to supply an externally positioned cooling liquid source. 
   U.S. Pat. No. 6,257,502, issued Jul. 10, 2001, to Hanish, et al., is a conventional example of a system which cools a user without user assistance, and which does not require the user to transport a cooling source to the system. In accordance with Hanish, an integrated multi-head misting device is provided which is removably attached to a household faucet or garden hose for receiving a cooling liquid. A misting fan is provided which includes a fan shroud including a grille and fan blades for permitting an air stream therethrough, where the air stream results from fan blade operation. A misting device is secured to the fan hub, and a plurality of misting heads are secured to the fan housing for directing a spray of mist across a fan grille. When the mist is projected into the air stream, the blowing action of the fan blades directs the mist away from the device and into the direction of an invention user. 
   Power is supplied to the Hanish fan via a typical outlet, and the mist is provided via a pressurized source. The mist is injected across the fan grille via a misting manifold which directs the liquid through the misting heads. That is, no pump, or electricity of powering the pump, is required for providing the cooling liquid to the misting heads. More particularly, no solar powered batter is required as with, for example, the Marcus patent noted above. In that regard, the Hanish invention provides advantages over the Marcus invention in that the Hanish invention is not dependent on direct light for operation, but instead may be operated in a relatively shaded area. 
   The cooling liquid is supplied to the Hanish invention by connecting the invention to a pressurized water supply, such as, a faucet or garden hose. Consequently, the Hanish invention still includes a similar disadvantage as Marcus, in that the invention must be operated near, or connected to, a cooling liquid source. As such, the Hanish invention, like the Marcus invention, does not provide a totally portable mister device. 
   The Hanish invention includes the additional disadvantage in that the area of airflow created by the Hanish fan blades limits the area of dispersion of the cooling mist. Thus, where the fan blades blow air to a maximum area in front of the fan, the cooling liquid, which is transported by the air stream, will only travel over that area. Further, unless the Hanish invention is positioned above a user, such that the mist droplets may settle on the user, the user would necessarily need to be directly in the air stream flow in order to be properly cooled. Further still, when used with conventional household fans, the Hanish invention is typically suitable for cooling only a limited number of people at any one time. 
   Another conventional misting device of similar operation as Hanish, is disclosed in U.S. Pat. No. 5,497,633, issued Mar. 12, 1996, to Hensley. The Hensley patent generally discloses an indoor/outdoor evaporative cooling unit which is inflatable via flexible walls. The flexible walls form a partially sealed enclosure for making the invention more portable when deflated. The cooling unit includes an inner wall and an outer wall of thin flexible material. A fan forces ambient air from an inlet through a flow divider, which directs some of the flow into the enclosure and the remainder of the flow into a chamber to exhaust through a chamber outlet. Spray nozzles are attached to the enclosure and aimed to spray a coolant, such as water, into the air exhausting through the outlet. 
   In essence, the Hensley invention operates by drawing in a steady flow of ambient air through an intake, and exhausting the drawn air through a ring of nozzles spraying a coolant into the exhaust stream. The coolant (e.g., water) is supplied to the invention via a pressurized water source or by suitable flexible flow connections and a pump. In one embodiment, the combination of the chamber design and the positioning of the spray nozzles permits the Hensley mister to spray a mist at the chambers outlet, which is modestly sized for permitting service of multiple users on, for example, a walk-by basis. That is, one embodiment of the Hensley invention is similar to the Hanish invention in that it is only suitable for cooling only a limited number of people at any one time. In an alternate embodiment, however, the Hensley invention may be adapted for use in simultaneously cooling multiple persons by including multiple outlet pairs in the chamber and arranging the spray nozzles such that the nozzles are mounted in a middle of an outlet pair. This, in turn, permits the Hensley invention to create a billowing stream or cloud with a greater effective cooling range than a typical mist or stream. 
   Although the Hensley invention provides for the production of a cooling cloud for cooling multiple users, the users must typically walk through or under the point of discharge of the coolant to be cooled down. In that regard, the Hensley invention, while providing a means for cooling multiple users, does not cool the users simultaneously. 
   Accordingly, a need exists for a mister for cooling multiple users simultaneously, which is completely portable, does not require user assistance for operation, and which may be used in any light. 
   SUMMARY OF INVENTION 
   The present application discloses a portable mister for use in lowering ambient temperature of an environment indoors or outdoors. In one aspect, the present invention lowers ambient temperature by providing a mist of droplet size moisture to the atmosphere, wherein the droplets include a temperature less than or equal to ambient temperature of the atmosphere. The droplets size, rate of distribution and distribution area maybe adjusted as desired. The droplets may be provided to the atmosphere such that the droplets may travel on air currents and descend toward the earth&#39;s surface due to the effects of air currents and gravity. The evaporative properties of the droplets cool the surface on which the droplets come to rest. 
   In another aspect of the invention, the present invention operates to cool surrounding articles, people and other similar objects on which the droplets settle by providing added moisture to the surface of those objects. The moisture may then cool the article by lowering the article&#39;s temperature relative to the droplet temperature and via the droplet&#39;s evaporative properties. Moisture may be provided to the atmosphere at any location and over any desired area for cooling multiple users by proper placement of the droplet delivery means. 
   In yet another aspect of the invention, the droplet size or rate of dispersion may be controlled either manually or automatically, to provide more or less of the droplets to the atmosphere. For example, the size of the individual droplets and the rate of dispersion may be increased when it is desired to disperse a greater quantity of droplets in a shorter period of time. Where increasing droplet size but conserving the overall quantity of droplets dispersed is a concern, then the droplet size may be increased, but the rate of dispersion may be decreased. Similarly, where it is desired to, for example, increase the quantity of individual droplets, but to decrease the overall quantity of droplets dispersed, the size and dispersion rates of the droplets may be decreased. 
   In yet another aspect of the present invention, a portable mister is provided which is more convenient to use than the prior art. First, the mister of the present invention is fully portable in that the invention does not require the user to separately transport a cooling agent (e.g., water) for misting. That is, the cooling agent may be entirely contained within the invention housing, thereby eliminating the need to supply a hose, reservoir, bucket, or the like, including the agent. Second, the mister includes an irrigation system for providing a spray of thin mist to the atmosphere, which may be comprised of flexible, foldable and easily storable tubing. As such, the tubing may be arranged as desired for cooling multiple users simultaneously. Lastly, the invention is easily transportable and storable due to the unique design of the invention housing. The invention may use wheels, rollers, handles, or the like, for facilitating easy transport of the system. 
   In still another aspect of the invention, the portable mister may include means for introducing a perfume, cologne or other aromatic fragrance, or the like, into the air to enhance the misting experience. The fragrance may be included in or with the droplets as the droplets are dispersed into the atmosphere. Alternatively, the fragrance may be mixed with the cooling agent prior to dispersion. The fragrance may then be perceived by a casual observer who detects the fragrance as a pleasant addition to the environment. 
   The present invention provides advantages over the prior art in that the present invention provides a mister system for cooling ambient air, which is fully portable, provides means for including a fragrance in a cooling mist, and which is substantially totally contained in one conveniently usable unit. Thus, when taken in combination, the overall portable mister system of the present invention is improved above the prior art. 
   These features and other advantages of the system and method, as well as the structure and operation of various exemplary embodiments of the system and method, are described below. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The accompanying drawings, wherein like numerals depict like elements, illustrate exemplary embodiments of the present invention, and together with the description, serve to explain the principles of the invention. In the drawings: 
       FIG. 1  depicts an exemplary embodiment of the portable mister system in accordance with the present invention; 
       FIG. 2  is an illustration of an exemplary misting vane/irrigation tubing and nozzles in accordance with exemplary embodiments of the present invention; 
       FIG. 3  is an illustration of an exemplary housing arrangement in accordance with an exemplary embodiment of the present invention; 
       FIG. 4  is an illustration of another exemplary embodiment of a portable mister system in accordance with an exemplary embodiment of the present invention; 
       FIG. 5  is an illustration of an exemplary embodiment of a housing control panel and system processor in accordance with various embodiments of the present invention; 
       FIG. 6  is a depiction of an exemplary method of operating an exemplary embodiment of a portable mister in accordance with the present invention; 
       FIG. 7  is another exemplary embodiment of an exemplary portable mister housing in accordance with exemplary embodiments of the present invention; and 
       FIG. 8  is an illustration of a cross-sectional top view of an exemplary portable mister housing in accordance with exemplary embodiments of the present invention. 
   

   DETAILED DESCRIPTION 
   The subject matter of the invention is particularly suited for use in lowering the ambient temperature of atmosphere and cooling one or more system users when positioned outdoors. As a result, the preferred exemplary embodiment of the present invention is described in that context. It should be recognized, however, that such description is not intended as a limitation on the use or applicability of the present invention, but is instead provided merely to enable a full and complete description of a preferred embodiment. That is, the invention is suitable for use indoors or outdoors. 
   The present invention may be described herein in terms of functional block components, optional selections and various processing steps. Such functional blocks may be realized by any number of hardware and/or software components configured to perform to specified functions. For example, the present invention may employ various integrated circuit components (e.g., memory elements, processing elements, logic elements, look-up tables, and the like), which may carry out a variety of functions under the control of one or more microprocessors or other control devices. Similarly, the software elements of the present invention, where included, may be implemented with any programming or scripting language such as C, C++, Java, COBOL, assembler, PERL, or the like, with the various algorithms being implemented with any combination of data structures, objects, processes, routines or other programming elements. Further, it should be noted that the present invention may employ any number of conventional techniques for data transmission, signaling, data processing, network control, and the like. 
   Where required, the system user may interact with the system via any input device such as, a keypad, keyboard, control panel, mouse, personal digital assistant, handheld computer (e.g., Palm Pilot®, Blueberry®), cellular phone and/or the like). Similarly, the invention could be used in conjunction with any type of personal computer, network computer, work station, minicomputer, mainframe, or the like, running any operating system such as any version of Windows, Windows NT, Windows 2000, Windows 98, Windows 95, MacOS, OS/2, BeOS, Linux, UNIX, Solaris, or the like, by interfacing the control panel, described below, with, for example, a conventional user computer. One skilled in the art will understand the modifications necessary to include the aforementioned systems in the present invention. In that regard, the modifications are considered within the scope of the present invention. 
   It should be noted that the terms used in this description have their ordinary meaning unless otherwise specified. For example, the terms “safe” and “unsafe” may be used herein in accordance with their ordinary meanings relative to each other. Further, no element of the invention is considered “critical” or “essential” unless so indicated. 
     FIG. 1  illustrates an exemplary embodiment of the portable mister system  100  of the present invention. In the exemplary embodiment shown, portable mister system  100  includes a housing  102  having a removable cap  112 . A liquid dispersion system including tubing  116  (e.g., irrigation tubing  116 ) and dispersion nozzles  118  may be connected to housing  102  via connector  117  for providing a passageway for a coolant to travel from the housing  102  to the tubing  116 . Housing  102  may further include a compartment  104  including a pump  106  in communication with a second compartment  107  (called “coolant tank  107 ,” herein for brevity) via a conduit  108 . System  100  may further include a power chord  110  for powering, for example, pump  106 . 
   Housing  102  may be constructed of any material capable of being compartmentalized for holding a cooling liquid (e.g., water). In that regard, housing  102  may be preferably rigid and waterproof. In one exemplary embodiment, housing  102  may include a coolant tank  107  for holding the cooling liquid during operation. Tank  107  may be waterproof and may be constructed of any suitable material capable of holding a liquid. For example, tank  107  may be comprised of a soft, semi-rigid or rigid plastic, rubber, vinyl, synthetic polymer or the like. It should be noted that housing  102  is described both as including a second compartment  107  and a cooling liquid tank  107 . It should be understood that where the second compartment  107  comprises a cooling liquid tank  107 , the compartment and tank are discussed interchangeably. However, it is contemplated that the inventor may include a second compartment distinct from the cooling liquid tank. 
   As shown in  FIG. 8 , tank  107  may be partially surrounded by a cavity  802  in housing  102 . Cavity  802  provides a space between the housing  102  and the tank  107  for providing, for example, a thermal agent for regulating the temperature of the coolant. Exemplary thermal agents may include, for example, thermal insulation for regulating the temperature of the cooling liquid in tank  107 . Alternatively, the thermal agent may include a cooling agent for reducing the temperature of the cooling liquid, such as, for example, ice, may also be included in cavity  107  for lowering the temperature of the cooling agent. Further, in one exemplary embodiment, housing  102  includes a combination of an insulation and a cooling agent positioned in cavity  802 . 
   Tank  107  may additionally include a removable cap  112  and a filter  114  disposed adjacent thereto. Filter  114  may be any suitable filter for removing particulates from the liquid as the liquid is added. Further, instead of placing the filter  114  as shown, filter  114  may be an in-line filter included in the irrigation tubing  116 . Alternatively, filter  114  may be included in tubing coupling  117  between the tank  107  and the tubing  116 . Cap  112  may be any means for providing access to the tank  107  for adding, for example, a cooling liquid. Preferably, cap  112  forms a substantially airtight seal with tank  107 . In one exemplary embodiment, cap  112  is a screw cap including a threading around its inner perimeter which mates with a threading on tank  107  for permitting the cap  112  to be twisted on and off. When twisted off, a system user is provided access to the inside of tank  107 . When the cap  112  is twisted on, a relatively airtight seal may be created between the cap  112  and tank  107 . 
   Housing  102  may further include a first compartment  104  which includes pump  106 . Compartment  104  may be such that it is sealed from tank  107  to prevent any cross-generation of chemicals or liquids between the tank  107  and compartment  104 . The compartment  104  may include a noise insulation for dampening any noise generated by the system pump  106 . The compartment  104  may additionally include a door (not shown) or passageway for providing access to the inside of the compartment  104 . Preferably the door is of sufficient size to permit replacement or repair of, for example, pump  106 . Further, housing  102  may include a pair of wheels  120  and a handle  121  for aiding in transporting the system  100 . Compartment  104  may additionally include one or more openings or grommets, etc. (not shown), for passing an electrical cord  110  therethrough or for the insertion of a conduit (e.g., conduit  108 , connector  117 , tubing  116 ). 
   Electric cord  104  may be used to provide power to the pump  106 . For example, cord  110  may be plugged into a standard 120V socket. Alternatively, pump  106  may be powered by dc current using a battery (not shown) which may be positioned in compartment  104  in proximity to pump  106 . In which case, compartment  104  may be suitably sealed against, for example, leakage of the liquid in tank  107  into the compartment, or leakage of the electrolytic battery chemicals into tank  107 . 
   In one exemplary embodiment, pump  106  may be any pump for forcing air into tank  107  via conduit  108 . Preferably, the air pumped by pump  106  is ambient air, and most preferably, the temperature of the air is cool relative to the temperature of the cooling liquid in tank  107 . In that regard, pump  106  may be any air pump which is capable of pumping air into tank  107 , thereby increasing the volume of free space in tank  107  and forcing the liquid into irrigation tubing  116 . The air for pumping may be drawn from outside housing  102  via an opening of port  136 . A suitable pump for use with the invention includes any bladder or diaphragm pump having cylinders, as are commonly found in the art. For example, a B series pump produced by SENSODYNE®, 16333 Bay Vista Drive, Clearwater, Fla. 33760, may be suitable for use with this invention. 
   Tank  107  may be placed in communication with irrigation tubing  116  via a tubing connector  117 . Connector  117  may be any suitable connector for connecting irrigation tubing to tank  107 , thereby providing an airtight or watertight passageway through which a cooling liquid may travel. As such, connector  117  is suitably positioned in one side of tank  107 . Preferably, the connector  117  is disposed in proximity to the bottom portion of the tank  107  to ensure that the liquid will be provided to the tubing  116 , when the liquid is at its lowest fill level inside tank  107 . Additionally, it is preferred that the connector  117  and the tank  107  form a leak-proof seal. 
   Connector  117  may be further coupled to irrigation tubing  116  having nozzles  118  for dispensing a mist of cooling liquid. Tubing  116  may be constructed of any suitable material for conveying a fluid. In that regard, tubing  116  may be made of a rubber, plastic, or the like, and preferably, the tubing is UV resistant to permit the tubing to withstand the damaging effects of direct sunlight. The tubing  116  may be treated with, or include, materials or compounds for retarding floral or bacterial growth. Tubing  116  may also be flexible, and may include portions which are rigid. As such, tubing  116  may be arranged in any suitable manner for misting a desired area. Tubing  116  may be affixed to any structure capable of holding the tubing for positioning the nozzles  118  to spray or mist. The tubing  116  may be affixed using any conventional method for holding an article affixed substantially stationary to another article. For example, the tubing  116  may be affixed using tape, nails, screws, Velcro®, or the like. Preferably, during operation, tubing  116  is placed at a height sufficient for permitting the mist to drop onto a system  100  user. For example, the tubing may be placed on a patio overhang, hung from a tree, or the like. In one exemplary embodiment, tubing  116  may include a tubing support apparatus which may be segmented into multiple pieces, and which may be assembled in any desired shape. U.S. Pat. No. 5,337,960, issued Aug. 16, 1994, to Allen, discloses a suitable irrigation tubing arrangement which may be used with the present invention. As shown in  FIG. 2 , the Allen patent discloses a lightweight, portable and collapsible support apparatus for pressurized water conveyance and overhead mist spraying nozzles  88 . 
   In one exemplary embodiment, the nozzles  118  may be any conventional nozzles which may be used for atomizing a liquid. Nozzles  118  may be comprised of a rust resistant metal, such as, for example, copper, or the nozzles  118  may be treated with a rust resistant compound. The nozzles  118  may include an entrance opening for accepting a liquid at a first velocity and an exit opening for emitting or ejecting the liquid of a higher velocity. The nozzles  118  may be adjustable in spray volume, pattern, direction and/or droplet size. For example, the nozzles  118  may be pivotable, such that the spray of cooling liquid emanating therefrom may be directed as desired. Further, the nozzles  118  may be configured to provide multiple spray patterns. For example, a user may adjust the nozzles  118  opening to spray in the shape of a cloud wherein the cooling liquid is substantially completely atomized. Alternatively, the nozzles  118  may be adjusted such that less atomization takes place and the cooling liquid droplets are of a larger size providing for a heavier mist. Further, a user may adjust the nozzles  118  to emit the cooling liquid in a cloud, cone, stream or other shape. 
   It should be noted that to achieve proper dispersion of the cooling liquid from nozzles  118 , an appropriate level of liquid pressure must be ordinarily maintained inside of irrigation tubing  116 . As such, alternate embodiments of the invention described herein may include a pressure regulator. A pressure regulator suitable for the invention may ensure that the liquid pressure is maintained relatively constant in tank  107 , tubing  116 , and/or at the nozzles  118 , so as to ensure proper dispersing of the liquid cooling agent. 
     FIG. 1  depicts a suitable pressure regulator  111  in communication with the tubing  116 . As shown, the pressure regulator  111  may be an in-line pressure regulator configured to ensure that the liquid pressure in tubing  116  is maintained at a sufficient level to promote dispersion of the liquid from nozzles  118 . Preferably, the pressure is maintained at a sufficient level to promote dispersion of the liquid in the desired dispersion pattern. A suitable in-line pressure regulator, which may be used in exemplary embodiments of this invention, is disclosed in U.S. Pat. No. 5,035,260, issued Jul. 30, 1991, to Davey. 
   Although,  FIG. 1  depicts an in-line pressure regulator, the invention is not so limited. For example, other suitable pressure regulators capable of regulating the liquid pressure in the portable system  100 , thereby promoting dispersion of the liquid from the tubing  116  and/or nozzles  118 , may be used. For example, system  100  may include a pressure regulator configured to regulate the pressure at an outlet of a tank  107  containing a liquid, such as a liquid coolant. The regulator (not shown) may be disposed or fitted in the housing of the tank, wherein the regulator is not in contact with the liquid, but instead regulates the pressure in the tank by, for example, comparing the pressure inside the tank with ambient pressure and adjusting the pressure in the tank accordingly to a predetermined target pressure. Alternatively, the regulator (not shown) for regulating the output pressure of the tank may be positioned in the housing  102  and in-line with the tubing  116 . In one particular example, the regulator may be positioned in proximity to the connector  117 . The regulator thusly positioned may regulate the output pressure by measuring the pressure in the tank relative to the pressure in the tubing. Suitable exemplary pressure regulators, which may be used in accordance with the above, are disclosed in U.S. Pat. No. 6,186,168 B1, issued Feb. 13, 2001, to Shultz et al., and U.S. Pat. No. 5,595,209, issued Jan. 21, 1997, to Atkinson et al., for example. 
   One key advantage of the present invention over the prior art is the ability of the system  100  user to include a fragrance in the misting cooling liquid. The fragrance may be included in the cooling liquid prior to providing the liquid to tank  107 . Alternatively, the fragrance may be included in the liquid after the liquid is filled into tank  107 . Further still, the fragrance may be added when the cooling liquid traverses through, or is emitted from, irrigation tubing  116 . By adding a fragrance to the cooling liquid, a user is able to include in the cooling mist a pleasant experience enhancing smell. For example, a user could add a rose or springtime fragrance which may be included in the mist, and which may be perceived by the casual observer. 
   Referring now to  FIG. 4 , an alternate exemplary embodiment of the system  100  is depicted including a fragrance container  122  which may be connected to pump  106  via a conduit  124 , and to cooling tank  107 , in waterproof fashion. Container  122  may be any suitable container for holding a liquid, such as, a fragrance. The fragrance may be any suitable fragrance which may be readily mixed in a liquid. Preferably the fragrance may be mixed with the cooling liquid in tank  107  such that no “clumping” exists. That is, the liquid and the fragrance are mixed such that they may not be easily physically separated. In that regard, the fragrance is preferably a liquid. In addition, container  122  may be in communication with tank  107  via conduit  126 , such that the fragrance held in container  122  may be added to the cooling liquid contained therein. As such, container  122  may include means for providing the fragrance to the tank  107 , such as, a conventional fluid ejector nozzle as are known in the art. The ejector nozzle may be included in the conduit  126  disposed inside tank  107 . The ejector nozzle may be included, for example, in a pneumatically operated sprayer, as are found in the art. 
   In one exemplary embodiment, container  122  includes a pump (not shown) for facilitating the providing of the fragrance to the tank  107 . The fragrance container  122  pump may be any suitable pump for pumping a liquid. The container  122  pump may preferably include an inlet in communication with the fragrance, preferably via a hose. The container  122  pump also preferably includes an outlet which is in communication with the tank  107  for providing the fragrance therein. In one exemplary embodiment, the container  122  pump is electrical and may be powered via alternating or direct current (e.g., battery). Alternatively, the container  122  pump may be pneumatic. Where the container  122  pump is pneumatic, it may be powered by air provided by pump  106 . For example, attached to pump  106  may be a conduit  124  for diverting some of the air generated by pump  106  to the container pneumatic pump. The container  122  pump may be such that the air from pump  106  causes the container  122  pump to pump fragrance into the tank  107 . Preferably the fragrance is pumped in a liquid or solid (powder-like) form, and most preferable, the fragrance is pumped into the tank  107  in a liquid solid mixture or the like. 
   In an alternative embodiment, the fragrance container  122  may not include a pump, but instead may include a pneumatic sprayer in communication with pump  106  via conduit  124 . Conduit  124  may divert a portion of the air generated to the pneumatic sprayer for spraying the fragrance into the tank  107 . Suitable sprayer/mixer arrangements which may be used with this invention to include a fragrance in the liquid coolant are disclosed for example in U.S. Pat. No. 6,156,159, issued Dec. 5, 2000, to Ekholm et al.; U.S. Pat. No. 6,103,128, issued Aug. 15, 2000, to Koso et al., U.S. Pat. No. 5,902,042, issued May 11, 1999, to Imaizumi et al.; U.S. Pat. No. 6,305,580 B1, issued Oct. 23, 2001, to Chen; U.S. Pat. No. 6,296,151,B1, issued Oct. 2, 2001, to Chen; U.S. Pat. No. 5,676,283, issued Oct. 14, 1997, to Wang; U.S. Pat. No. 6,598,803 B1, issued Jul. 29, 2003, to Haas et al.; and U.S. Pat. No. 6,216,966 B1, issued Apr. 17, 2001, to Prendergast et al. Those skilled in the art will recognize that various modifications may be made to the above noted patents without departing from the scope of the invention. 
   With continued reference to  FIG. 4 , housing  102  may include a mixer  130  for ensuring substantially complete mixing of the fragrance and cooling liquid combination when the fragrance is added. Mixer  130  may be any suitable mixer capable of mixing two liquids, a solid and a liquid or any similar configuration capable of mixing a fragrance promoting composition with cooling agent. Mixer  130  may be electric and may include its own motor (not shown). Alternatively, mixer  130  may be pneumatic, and may be powered by air provided by pump  106  via conduit  132 , in similar manner as was discussed with respect to the container  122  pump. Suitable mixers which may be used with the invention include for example, any mixer operable to blend, mix, or aerate a liquid such as a cooling liquid. 
     FIG. 7  depicts another exemplary embodiment of the present invention wherein system  100  includes a pump  706 . Pump  706  pumps the cooling liquid from tank  107 , and provides the liquid to tubing  116 . In this exemplary embodiment, the pump  706  may be an in-line diaphragm pump of sufficient pumping capacity to ensure that the cooling liquid may mist from nozzles  118 . The pump  706  may be a high-pressure self-priming pump, such as, for example, those manufactured by SHURflo®. 
   It should be noted, that where an in-line pump  706  is used as described above, it may not be necessary for the cap  112  and the tank  107  to form an airtight seal. That is, it may be required that the pump  706  experience minimal pressure inside tank  107  during operation to enable the pump  706  to efficiently draw the liquid from the tank  107 . More particularly, when the liquid is removed from tank  107 , the volume of the free space in the tank must also increase to ensure proper liquid removal. As such, the housing  102 , tank  107  and/or cap  112  may be provided with air holes or openings (e.g., apertures) (not shown) in the housing  102 , tank  107 , or cap  112  top surface to permit air to be drawn into the tank  107  as the cooling liquid level decreases. Alternatively, the invention may be operated with the cap  112  removed or loosened to permit air to be drawn into the tank as the level of the coolant decreases. Further still, pump  706  may be configured such that the needed air is provided by the pump  706 , as described below. 
   As shown in  FIGS. 3 and 7 , housing  102  may further include a second compartment  138 . Compartment  138  may be of sufficient size to store flexible irrigation tubing  116 . In addition, compartment  138  may be of sufficient size to store any tubing supports such as those which are depicted in  FIG. 2 . 
   System  100  may further include sensors  132  shown in  FIG. 3 , for reporting the operational status of various elements of the invention. In that regard, sensors  132  may be any micro or macrosensors capable of translating a physical occurrence in an environment to a perceptive analog or digital signal. The sensors  132  may include, for example, pressure, temperature, or positional sensors, transducers, or the like. For example, a sensor  132  may be any suitable sensor (i.e., pressure sensor or temperature sensor) for sensing and reporting the level of the cooling liquid in tank  107 . A sensor (not shown), such as a pressure sensor, may also be included adjacent to the nozzles  118  for detecting the emission of the cooling liquid from the nozzles  118 . In addition, a position sensor (not shown) may be included adjacent to cap  112  for detecting whether the cap  112  is tightly affixed to tank  107 . 
   The aforementioned sensors may be in communication with a processor  134  which may be in further communication with a control panel  130 , as best shown in  FIG. 5 . Processor  134  may be any suitable processor capable of receiving a signal from a sensor and providing a responsive signal to a control panel  130 . For example, processor  134  may be any conventional processor or microprocessor configured to provide a “safe operation” or “unsafe operation” signal to the control panel  130 . In addition, processor  134  may be any conventional processor or microprocessor for providing an “enable signal” or a “disable signal” for operation of the various system components as described below. Conventional sensors, such as these, are known in the art, and will not be discussed herein for brevity. 
   Control panel  130  includes means for activating/deactivating system  100  operation. For example, control panel  130  may include a power switch  506  for turning the system  100  off and on. The control panel  130  may further include visual indicators  504  for indicating the status of the sensed components. The visual indicators  504  may be, for example, lights or a LED display. The indicators  504  may flash intermittently or not at all. Additionally, the indicators  504  may change colors. For example, where the indicator flashes the color red, the indicator may inform the user that a particular condition exists which is not preferred. For example, the cooling liquid level may too low for safe operation of the invention. Alternatively, the visual indicator may flash green to indicate that safe operation of the invention is permitted. 
   In addition to the visual indicators  504 , control panel  130  may include means for providing an audible notification of operational status. For example, the control panel  130  may include a speaker  508  for audibly indicating that a status of the invention has changed. On the other hand, the speaker  508  may notify a user that safe operation of the invention is permitted. The audible indications may be, for example, one or more tones perceptible by the human ear. 
   It should be noted, that the present invention may include alternate means for informing a user of system status. For example, the visual and audible indications may be used simultaneously. Alternatively, the system  100  may include means for providing tactile indications of system operational status, which may or may not be used in conjunction with one or more of the visual and audible indications. For example, the tactile indications may be perceived as a mild or moderate vibration of the system housing  102 . In that regard, system  100  may include means for facilitating a shaking of a portion of system  100  housing when, for example, the system  100  is to be placed in an inoperable state. 
   The processor  134  may additionally be connected to at least one of the elements of system  100  for controlling the operational status of these elements. For example, processor  134  may be connected or in communication with pump  106 ,  706 , container  122  pump, and/or mixer  130 . The processor  134  may be configured to enable or disable those elements as required. Processor  134  may enable or disable the operation of an element by providing an appropriate signal to the element. 
   Control panel  130  may additionally include switches, buttons, or the like, for use in notifying the user that an element is to be disabled by processor  134 . For example, one button may give indication that a signal is provided to the processor, which disables operation of the mixer  130 . The signal may be received from an appropriate sensor (e.g., motion, positional) and provided to the processor  134 , which may then provide a signal to the mixer  130  causing the mixer  130  to cease operation. In similar manner, control panel  130 , may include indicators for notifying a user that a signal is provided by processor  134  for disabling/enabling the operation of the pump  106 ,  706 . 
     FIG. 6  is an illustration of an exemplary method  600  of operating the portable mister system  100  in accordance with the invention. The method may begin with a user filling the tank  107  with a cooling agent, such as, for example, water (step  602 ). However, it should be noted that the present invention is not so limited. That is, although the invention is described with respect to a water misting agent, any liquid or aqueous cooling agent capable of misting may be employed. Typical liquid or aqueous cooling agents for use with the invention may include additives for facilitating cooling. Such cooling agents are well known, and as such, will not be discussed herein for brevity. 
   The user may then arrange the irrigation tubing  116  including the nozzles  118  such that a mist emitted from the nozzles  118  will blanket a predetermined area (step  604 ). For example, where a user wishes to cool the environment surrounding a back yard patio, the user may place the irrigation tubing  116  on a patio awning or overhang to ensure that those persons positioned on or around the patio experience the evaporative cooling affects of the misting cooling agent. Once the irrigation tubing  116  is properly arranged, the user may then turn on the mister by, for example, activating a power button  506 , or the like (step  606 ). 
   Where the invention includes sensors  132 , the sensors  132  may be arranged to provide indication of the status of certain components of the system  100 . The sensors  132  may be configured to ensure safe operation of the invention by reporting the status of, for example, the level of coolant, whether the nozzles  118  are functional, and/or whether the cap  112  is securely fastened, etc. As such, more or less sensors may be included in the invention as needed. In the exemplary embodiment shown, the system  100  may include a sensor for sensing the level of cooling liquid (e.g., cooling agent) included in the tank  107  (step  608 ). 
   Where the cooling agent falls below a predetermined level inside tank  107 , the motor  106  may overheat thereby increasing the risk that a fire safety hazard would result. As such, the tank sensor  132  is configured to provide an “unsafe operation” signal to the processor  134  when the liquid falls below the predetermined level inside tank  107 . The processor  134  may receive the “unsafe operation” signal and disable the pump  106  preventing the pump  106  from initiating or continuing operation (step  610 ). The processor  134  may further provide an “unsafe operation” signal to the control panel  130 . The control panel  130  may then provide a visual or audible (or tactile) indication to the user thereby informing the user that an unsafe condition exists which prevents safe operation of the system  100  (step  612 ). The unsafe operation indication may be provided to the user in the form of warning lights  504  or an audible tone or message emitted from a speaker  508 . The user is then permitted to correct the unsafe condition and the system processor  134  re-checks the sensor to determine if the unsafe condition remains (e.g., step  608 ). The processor  134  may check and/or the sensor  132  may provide the status signal at some predetermined period or continuously. If the unsafe condition remains, then the pump  106  remains disabled. Further, where the system  100  includes more than one pump, such as, for example, a fragrance pump  122 , the processor  134  may disable one or all of the pumps as desired. For example, if the operation of only one pump may cause an unsafe operation condition, then that one pump may be disabled while the other pumps included in system  100  remain in operation. Alternatively, processor  134  may disable all pumps until the identified unsafe condition is corrected. 
   In similar manner as with tank  107 , the system  100  may include sensors for detecting whether the nozzles  118  are operational or open (step  614 ). In this context, the nozzles  118  may be considered “operational” or in “safe operation” when one ore more of the nozzles is arranged, positioned and/or configured to permit a cooling liquid to be emitted therefrom (e.g., nozzles are “open”). In contrast, the nozzles  118  may be considered “nonoperational” or in “unsafe operation” where one or more of the nozzles  118  is arranged, positioned and/or configured to prohibit the free flow of a cooling liquid therefrom (e.g., nozzles are “closed”). 
   For example, one suitable sensor may detect a pressure or temperature change at the nozzle  118  opening due to the dispensing of the cooling agent into the atmosphere. That is, since the pressure and/or temperature at the opening of the nozzle  118  changes as the cooling agent is emitted therethrough, such change may be reported to the processor  134  in the form of a “safe operation” or “unsafe operation” signal. Where the safe operation signal is received by the processor  134 , the system  100  may continue with additional safety checks. Alternatively, if no change in pressure or temperature is detected/sensed at the nozzles  118  opening, then the sensor may provide the processor  134  with an unsafe operation (e.g., nozzles  118  are closed) signal and the processor  134  may disable the pump  106  accordingly (step  610 ). The processor  134  may then provide a warning signal to the user (step  612 ) and perform additional checks to see if the unsafe condition has been corrected (e.g., nozzles  118  are open) (step  614 ). 
   As noted with respect to one exemplary embodiment of the invention, the pump  706  may be an in-line self-priming pump which provides the coolant directly to the irrigation tubing  116 . In this case, it may be required that there be provided means for increasing the volume of free space in the tank  107 , once the cooling liquid is pumped out (e.g., removed) from the tank. As noted, this particular embodiment may require there to be air holes (not shown) included in the top surface of the housing  102 , tank  107 , cap  112 , or the like, for permitting ambient air to be drawn into the tank  107  during system  100  operation. 
   On the other hand, when pump  106  is configured to operate to remove the cooling liquid by forcing air into tank  107 , thereby forcing the cooling liquid into tubing  116 , there ordinarily needs to be an airtight seal created in tank  107 . More particularly, there may ordinarily need to be an airtight seal created between cap  112  and tank  107 . The airtight seal, for example, permits the air pressure in the tank be controlled so that the pressure in the tubing  116  for proper dispersion of the liquid at nozzles  118  may be maintained. As such, the system  100  may include a sensor (e.g., positional sensor) for detecting whether the cap  112  is tightly secured to tank  107  so as to create the needed airtight seal (step  616 ). 
   If the cap  112  is not tightly secured, a cap sensor may provide an “unsafe operation” (e.g., cap  112  is open) signal to the processor  134 . The processor  134  may then provide a disable signal to the pump  106  for disabling pump  106  operation (step  610 ) and may also provide an indication signal to the appropriate control panel  130  indicator for notifying a user that the cap  112  is not tightly affixed to tank  107  (step  612 ). The system  100  processor  134  may then check and re-check the signal received from the cap sensor to determine if the unsafe condition still exists (step  610 ). If so, then the processor  134  continues disabling pump  106  and the system  100  is not operational. 
   In some instances, the invention may include a pressure regulator, as noted above. In certain exemplary embodiments, the pressure regulator may be used to enhance the safe operation features of the invention. For example, the pressure regulator may be in communication with the processor  134 , such that when the processor receives an unsafe operation signal, the processor  134 , may provide a “disable pressure regulator signal” to the pressure regulator for disabling regulator operation. In this instance, “disabling operation” of the regulator may mean prohibiting normal regulator function, by for example, operating the regulator such that pressure build up in the tank  107 , tubing  116 , or at the nozzles  118 , is not achieved. More particularly, the disabled pressure regulator may be operated such that minimal pressure exists in system  100 , and even more particularly, the pressure in system  100  is such that dispersion of the liquid from nozzles  118  is interrupted. 
   It should be noted that the present checks for unsafe conditions could include checking the status of any component of system  100 . Preferably, the system sensors check to determine if any of the components may be operated in an unsafe manner. As such, system  100  may include sensors for checking any number of the system  100  components and the sensors may be in communication with the processor  134  and control panel  130  in similar manner as discussed above. 
   Further, the processor  134  may be configured to check one or more sensor components simultaneously or in a predetermined order. The processor  134  may check the sensors one or more times during system operation. For example, the processor  134  may check the sensors when the operation of the system  100  is initiated, and may additionally check periodically throughout the operation of the system  100 , such that if an unsafe condition results, the operation of one or more of the system components or the entire system  100  may be disabled. In any event, where the processor  134  detects that an unsafe condition does not exist or has been corrected, the processor  134  may provide an enable signal to the pump(s) or other system element, permitting the system  100  to operate (step  616 ). 
   Once the pump  106  is initiated and permitted to operate, the pump  106  pumps air into the tank  107 , thereby forcing the cooling liquid contained therein into irrigation tube  116 . For example, pump  106  may provide ambient air from outside the housing  102  (via port  136 ), to the tank  107  via conduit  108 . The air may fill the tank causing pressure to rise in the free space therein. As the air is provided, the tank  107  may become pressurized, and the cooling liquid may escape through the tubing  116 , thereby creating additional free space for the pumped in air. 
   In an alternative embodiment, pump  706  may be an in-line self-priming pump, which pumps the cooling liquid from the tank  107  into the tubing  116 . The cooling liquid may be pumped directly from the tank  107  into the tube  116 . During pumping, air may be provided to the tank  107  passively. That is, as the liquid moves into the tubing  116  from the tank  107 , free space may be created in the tank by the escape of the cooling liquid into the tube  116 . Air holes may be provided in the tank  107 , housing  102  or cap  112 , for example, for permitting the air to enter the tank  107 , thereby allowing the liquid to be provided to the tubing  116 . Alternatively, air may be provided to the system  100  via operation of the pump  706 . For example, the pump  706  may be affixed with a first opening for receiving the cooling liquid, a second opening for providing the liquid to the tubing  116 , and a third opening for drawing in additional air. Such pumps are well known and will not be discussed herein for brevity. 
   Upon entering the tubing  116 , the cooling liquid becomes pressurized in part, because the liquid is forced into tubing  116  having a relatively small cross-sectional area as compared to the area of the tank  107 . Additionally, the pumping action of the pump  106 ,  706  causes the liquid to assume a certain velocity when traveling through the irrigation tubing  116 . Thus, the velocity of the liquid and the forcing/pumping action of the pump  106 ,  706  causes the cooling liquid to be delivered to the nozzles  118  in a pressurized state. Once the nozzles  118  are opened, the pressurized liquid may be provided from the dispensing end of the nozzles  118  into the ambient air at a higher velocity than when the liquid entered the tubing  116 . The cooling liquid may be emitted from any one of the nozzle  118  openings in, for example, the shape of a spray, which may assume any desired shape or spray pattern. Preferably, the nozzles  118  emit the cooling liquid in the shape of a cloud, and most preferably, the liquid is emitted in the shape of a mist. 
   Having been emitted into the atmosphere, the cooling agent may begin descending and may begin evaporation. The cooling agent may evaporate when emitted into the atmosphere or when it settles on a surface waiting below. As noted, the evaporative quality of the mist is such that the surface receiving the mist may be readily cooled. 
   In summary, the present invention provides a portable mister which has advantages over the prior art in that the invention is more portable and more convenient to use. For example, the invention is substantially self-contained, in that the cooling liquid is included in a part of the system housing, thereby eliminating the need to provide a source of cooling liquid to the system during operation. The invention additionally may include a means for providing in the mist, an experience enhancing fragrance. Further, the invention provides advantages over the prior art in that means for determining safe operation of the invention are included therein. 
   The preceding detailed description of exemplary embodiments of the invention makes reference to the accompanying drawings, which show the exemplary embodiments of the invention by way of illustration. While these exemplary embodiments are described in sufficient detail to enable those skilled in the art to practice the invention, it should be understood that other embodiments may be realized and that logical and mechanical changes may be made without departing from the spirit and scope of the invention. For example, the steps recited in any of the method or process claims may be executed in any order and are not limited to the order presented. Additionally, the present invention may include any construction or arrangement of a control panel and sensors for sensing unsafe operating conditions of the system and reporting unsafe operation indications to the user. Further, the invention may include any conventional nozzles, irrigation tubing, couplings, connectors, processors, pneumatic, electrical or mechanical sprayers as are found in the art. Further still, the housing of the present invention may assume any shape, and may include any form of irrigation tubing storage, wheels or handles as desired. For example, the housing may be oval, square, polygonal, oblong, or the like, and the tubing may be stored on the outside of the system housing. The housing may include disposed therein, means for eliminating any standing cooling agent remaining in the cooling liquid tank thereby prohibiting the growth of bacteria therein. The means may, for example, be a removable plug positioned in a bottommost portion of the system housing or tank for draining any cooing liquid remaining in the cooling liquid tank when the system is not in use. Even further, the cooling liquid tank  107  may take any shape or construction suitable for holding a liquid, and may take the shape of the system housing. Yet further, the components included herein may be mechanical, electrical, pneumatic, or any combination of the above as is dictated by the environment the portable misting system uses. 
   The invention in its broadest aspects is therefore not limited to the specification details, preferred embodiment, and illustrative examples shown and described. The above aspects and embodiments of the present invention are understood with reference to the attached claims, specification and drawings included herewith.