JP2023530528A - Personal evaporative air cooler with clip - Google Patents

Abstract

An evaporative air cooler is described. The evaporative air cooler comprises a housing defining an interior of the evaporative air cooler and a tank positioned adjacent the top of the housing, the tank configured to receive, store and discharge liquid; The evaporative air cooler further comprises an atomizer in fluid communication with the tank, the atomizer configured to generate a mist from the liquid, the evaporative air cooler further including a filter structure having a filter. the filter configured to absorb fog; and the evaporative air cooler further comprising a fan configured to draw air therein, the air being cooled by at least one of the fog and the filter. The fan directs air from the inside through the filter structure, and the evaporative air cooler further comprises a clip coupled to the housing.

Description

CROSS-REFERENCE TO RELATED APPLICATIONS This application is a continuation-in-part of U.S. patent application Ser. Priority to and benefit from application Ser. No. 16/897,678 is claimed, the entire disclosure of which is incorporated herein by reference.

FIELD OF THE DISCLOSURE The present disclosure relates generally to personal evaporative air coolers with clips.

BACKGROUND Personal evaporative air coolers are commonly used to cool air in homes, offices, or other hot, dry air environments. Conventional evaporative air coolers operate by drawing ambient air into the evaporative air cooler and passing it through a water immersion filter device. As warm air passes through the immersion filter, heat from the ambient air evaporates the water trapped within the immersion filter device. The evaporated water cools the air as it exits the immersion filter device and exits the evaporative air cooler.

A conventional evaporative air cooler typically includes a fan, a filter device, and a water distribution system. The fan draws ambient air into the evaporative air cooler, passes it through a filter device to create cooler air, and then forces the cooler air out of the evaporative air cooler. More specifically, the water distribution system supplies water to the filter device such that the filter device is submerged in water. The water distribution system includes a water pump that draws water from a reservoir and distributes the water to the bottom surface of the upwardly submerged filter device. Depending on the type of filter and the amount of water in the reservoir, water will only partially move up the filter. If the filter is not completely submerged in water, the evaporative air cooler is less effective at producing cooler air. Filter devices typically include filters made of paper-like material that must be replaced frequently. Filters cannot be reused or easily cleaned.

Some of the water distributed to the filter device evaporates as the air flows through the filter. As the evaporative air cooler operates by evaporation, the water in the reservoir is depleted. Non-absorbed water that recirculates within the evaporative air cooler returns to the reservoir. When the reservoir is completely depleted of water, but the filter device is submerged in water, the evaporative air cooler can still produce cooler air, but less effectively. Evaporative air coolers stop producing cooler air when the filter device dries. Therefore, additional water must always be added to replace the evaporated water.

Conventional evaporative air coolers typically take a significant amount of time to begin cooling the air because the filter device must draw water from the reservoir before the cooling process can begin. . In other words, conventional evaporative air coolers do not instantly produce cooler air.

Additionally, conventional evaporative air coolers are typically placed on a flat surface such as a table, countertop, or desk to cool people in the room. Conventional evaporative air coolers are not configured to attach to devices such as shelf ends or stroller handles.

Overview This section provides a general overview of the disclosure and is not a comprehensive disclosure of its full scope or all of its features, aspects, and objectives.

An evaporative air cooler implementation is disclosed herein. The evaporative air cooler includes a housing defining an interior of the evaporative air cooler and a tank positioned adjacent the top of the housing, the tank configured to receive, store, and discharge liquid; The evaporative air cooler further includes an atomizer in fluid communication with the tank, the atomizer configured to generate a mist from the liquid, the evaporative air cooler further including a filter structure having a filter. the filter configured to absorb fog, the evaporative air cooler further including a fan configured to draw air into the interior, the air being cooled by at least one of the fog and the filter The fan directs air from the inside through the filter structure, and the evaporative air cooler further includes clips coupled to the housing.

Also disclosed herein is an implementation of an evaporative air cooler comprising a housing defining an interior of the evaporative air cooler, a tank positioned adjacent the top of the housing, The tank is configured to receive, store and release a liquid, and the evaporative air cooler further includes an atomizer in fluid communication with the tank, the atomizer to generate a mist from the liquid. The evaporative air cooler further includes a filter structure having a filter, the filter configured to absorb fog, and the evaporative air cooler further including a fan configured to draw air into the air cooler. wherein the air is cooled by at least one of a fog and a filter, the fan directs the air internally through the filter structure, the evaporative air cooler further comprising an angled member coupled to the housing; The angled member is configured to rotate the housing, and the evaporative air cooler further includes a clip coupled to the angled member.

Also disclosed herein is an implementation of an evaporative air cooler comprising a housing defining an interior of the evaporative air cooler, a tank positioned adjacent the top of the housing, The tank is configured to receive, store and release a liquid, and the evaporative air cooler further includes an atomizer in fluid communication with the tank, the atomizer to generate a mist from the liquid. wherein the evaporative air cooler further includes a filter structure having a filter and a second filter, the filter and the second filter configured to absorb fog, the evaporative air cooler further comprising: a fan configured to draw inwardly, the air being cooled by at least one of a fog, a filter and a second filter, the fan directing the air from the interior through the filter structure for evaporative air cooling; The instrument further includes a clip coupled to the housing.

BRIEF DESCRIPTION OF THE FIGURES The present disclosure is best understood from the following detailed description when read in conjunction with the accompanying drawings. It is emphasized that, according to common practice, the various features of the drawings are not to scale. On the contrary, the dimensions of various features are arbitrarily enlarged or reduced for clarity.

1 is a perspective view of a personal evaporative air cooler in accordance with aspects of the present disclosure; FIG. 1 is a side view of a personal evaporative air cooler in accordance with aspects of the present disclosure; FIG. 1 is a front view of a personal evaporative air cooler in accordance with aspects of the present disclosure; FIG. 1 is a perspective view of the internal assembly of a personal evaporative air cooler in accordance with aspects of the present disclosure; FIG. 1 is a perspective view of the interior of a personal evaporative air cooler in accordance with aspects of the present disclosure; FIG. 1 is a perspective view of a filter structure of a personal evaporative air cooler in accordance with aspects of the present disclosure; FIG. 1 is a perspective view of a filter structure of a personal evaporative air cooler in accordance with aspects of the present disclosure; FIG. 1 is a top view of a filter structure of a personal evaporative air cooler in accordance with aspects of the present disclosure; FIG. 1 is a front perspective view of the personal evaporative air cooler after the internal assembly has been removed, in accordance with aspects of the present disclosure; FIG. 1 is a front view of a fan cover assembly of a personal evaporative air cooler in accordance with aspects of the present disclosure; FIG. 1 is a top view of a personal evaporative air cooler water tank in accordance with aspects of the present disclosure; FIG. 1 is a perspective view of an exemplary embodiment of a personal evaporative air cooler attached to an exemplary stroller in accordance with aspects of the present disclosure; FIG. 1 is a side view of a personal evaporative air cooler in accordance with aspects of the present disclosure; FIG. 1 is a side view of an evaporative air cooler with an open lid, according to aspects of the present disclosure; FIG. 1 is a top view of an evaporative air cooler with an open lid, according to aspects of the present disclosure; FIG. 1 is a front view of an evaporative air cooler in accordance with aspects of the present disclosure; FIG. 1 is an exploded view of an evaporative air cooler in accordance with aspects of the present disclosure; FIG. FIG. 3 is an illustration of a filter structure for an evaporative air cooler in accordance with aspects of the present disclosure; FIG. 2 is an illustration of a filter structure for an evaporative air cooler in accordance with aspects of the present disclosure; FIG. 2 is an illustration of a filter structure for an evaporative air cooler in accordance with aspects of the present disclosure; 1 is a front perspective view of the personal evaporative air cooler after the internal assembly has been removed, in accordance with aspects of the present disclosure; FIG. 1 is a rear perspective view of an evaporative air cooler in accordance with aspects of the present disclosure; FIG. 1 is a perspective view of a clip of an evaporative air cooler in accordance with aspects of the present disclosure; FIG.

DETAILED DESCRIPTION The following description is merely exemplary in nature and is not intended to limit the disclosure in its application or uses. For clarity, the same reference numbers are used in the description and drawings to identify similar elements.

The present disclosure relates generally to a personal evaporative air cooler that draws in ambient air, cools the ambient air, and blows out the cooled ambient air. In this disclosure, a personal evaporative cooler may be referred to as an evaporative cooler, a portable evaporative cooler, or any other desired air cooler.

The evaporative air cooler 10 may include a housing 20 having a power adapter, a water tank 40, a v-shaped shroud 44, a fan 48, a drawer 50 and a filter structure 56.

FIG. 1 shows an exemplary evaporative air cooler 10 . The evaporative air cooler may include a housing 20 having a top surface 22 , a bottom surface 24 and four lateral sides such as front surface 26 , rear surface 28 and side surface 30 . Housing 20 may be formed as a cubical housing, a rectangular housing, or any other desired configuration or shape. Housing 20 may be formed from plastic or any other desired material.

Top surface 22 may include a lid, such as hinged lid 32 . FIG. 2 shows evaporative air cooler 10 with hinged lid 32 opened for access to water tank 40 . A hinged lid 32 may be positioned along the front of top surface 22 . Hinged lid 32 may include a lid tab 76 positioned in front of hinged lid 32 or in any other desired location. The hinged lid 32 can be opened to allow water to fill the water tank 40 . For example, a user can pull the lid tab 76 upward to open the hinged lid 32 . Hinged lid 32 may be formed from plastic or any other desired material. The opening to the water tank 40 can be any desired opening and is not limited to the hinged lid 32 described in this disclosure.

Top surface 22 may also include buttons such as power button 34, light button 36, or any other desired button. Top surface 22 may also include one or more lights, such as indicator light 38 or any other desired light or indicator. Indicator lights 38 may be used to indicate fan speed, the level of water located within water tank 40, whether filter 58 should be replaced, or any other desired indication. For example, at high speed, all three indicator lights 38 can be ON. At medium speed, two indicator lights 38 can be turned ON. At low speed, one indicator light 38 can be ON. In one embodiment, indicator lights 38 may all turn off if power button 34 is pressed for at least three seconds. Indicator lights 38 may include one or more lights. Indicator light 38 may display a flashing light or a continuous light. Indicator lights 38 may display different light colors such as green, red, amber, or any other desired color.

The power button 34 may be configured to activate (eg, power ON), change the fan speed of the fan 48 , and deactivate (eg, power OFF) the evaporative air cooler 10 . For example, once the power button 34 is activated, the indicator lights 38 (e.g., three indicator lights 38) can be turned on, the fan 48 can be turned on (e.g., fast), and the water tank 40 can be turned on. An aperture 42 positioned therein allows water to flow out of the tank 40 to initiate the evaporative air cooling process. If the power button 34 is activated twice, one of the indicator lights 38 can be turned OFF (e.g., two indicator lights 38 remain ON) and the fan speed can be reduced. At (eg medium speed), the aperture 42 allows less water to flow out of the tank 40 . When the power button 34 is actuated three times, one of the indicator lights 38 can be OFF (e.g., one indicator light 38 remains ON) and the fan speed can be decreased. At low speeds (eg, low speed), the aperture 42 allows less water to flow out of the tank 40 . When the power button 34 is activated four times, one of the indicator lights 38 can be OFF (e.g., no indicator lights 38 remain ON), the fan 48 can be OFF, Aperture 42 can stop the flow of water from tank 40 . In other words, the power button 34 can be activated to deactivate or power off the evaporative air cooler 10 . In one embodiment, indicator light 38 and evaporative air cooler 10 can be turned off when power button 34 is activated (eg, pressed downward) for more than three seconds.

A fan 48 may be wired to the evaporative air cooler 10 . Wiring may be soldered to electrically connect the fan 48 to the evaporative air cooler 10 or attached in any other desired manner. The wiring may be hidden within a wiring compartment within the evaporative air cooler 10 or any other desired compartment.

A light, such as a blue LED light, may be positioned within the water tank 40 , such as under the power button 34 , or any other desired area to illuminate the water tank 40 . The lights can be used for ambience, as night lighting, or for any other desired purpose. The light may be on by default when the evaporative air cooler 10 is powered on. The user can dim the light or turn off the blue LED completely by pressing the light button 36 . For example, after the power button 34 is pressed, the lights are in high brightness mode. Once the user presses the light button 36, the light can reduce its brightness (eg, to low brightness mode). If the user presses the light button a second time, the light can be turned off. In one embodiment, lighting settings may be selected and/or locked if the light button 36 is activated for a minimum amount of time (eg, 3 seconds).

As shown in FIG. 2, bottom surface 24 may include legs 62 projecting outwardly from bottom surface 24 . Feet 62 may be configured to lift evaporative air cooler 10 from the surface on which it is placed. Legs 62 may also be configured to prevent evaporative air cooler 10 from damaging surfaces. For example, the legs 62 can prevent the surface from being scratched as the evaporative air cooler 10 slides across the surface. Legs 62 may be formed from rubber, plastic, grips, or any other desired material. Bottom surface 24 may include a plurality of legs 62 . Legs 62 may be formed as circular legs 62, oval legs 62, square legs 62, rectangular legs 62, or any other desired shape. Legs 62 may be positioned toward each corner of bottom surface 24 or in any other desired location. In an alternative embodiment, bottom surface 24 does not include legs 62 .

The lateral sides can include a front surface 26 , a back surface 28 and two side surfaces 30 . The lateral sides can be positioned about their perimeter between top surface 22 and bottom surface 24 . The lateral sides may be positioned adjacent each other. The lateral sides can include framed portions 64 and face portions 66 . A framed portion 64 may be positioned about the perimeter of the lateral sides, and a face portion 66 is positioned within the framed portion 64 . For example, the side 30 has a top portion 68 , a framed portion 64 adjacent the top 68 and positioned along the side and bottom edges of the side 30 , and a face portion 66 positioned within the framed portion 64 . can contain.

As shown in FIG. 3 , the front surface 26 may include a top portion 68 and framed portions 64 adjacent the top portion 68 and positioned along the side and bottom edges of the top surface 22 . Front face 26 may also include an exit vent 52 positioned within framed portion 64 . Outlet vent 52 may include a plurality of vents 70 , air direction tabs 72 and filter withdrawal tabs 120 . Multiple vents 70 may include fixed vents 122 and adjustable vents 124 . For example, fixed vent 122 may be positioned as lowest vent 70 above exit vent 52 . The remainder of the plurality of vents 70 may consist of adjustable vents 124 . Each of the plurality of vents 70 can be horizontally positioned at the exit vent 52 . Each adjustable vent 124 may be movably connected to an air direction tab 72 . Air direction tabs 72 may be positioned to direct air flowing from the interior of evaporative air cooler 10 through outlet vent 52 . For example, if air direction tab 72 is positioned upward, adjustable vent 124 may be positioned upward to direct airflow upward. Similarly, if air direction tab 72 is positioned downward, adjustable vent 124 may be positioned downward to direct airflow downward. When air direction tab 72 is positioned in a central position, adjustable vent 124 may be positioned in a substantially horizontal position, directing air to flow horizontally from evaporative air cooler 10 . The air direction tabs 72 can direct air flow at any angle between a downward angle and an upward angle.

A face portion 66 of front surface 26 , such as outlet vent 52 , may be connected to an internal assembly 74 that is removable from housing 20 . As shown in FIGS. 4 and 5, the internal assembly 74 of the evaporative air cooler 10 may include a filter structure 56 including a filter 58 and a drawer 50 including a water tray 54. As shown in FIG. The inner assembly 74 can fit tightly around the perimeter of the fan 48 . For example, internal assembly 74 may form a seal around fan 48 to direct air out of evaporative air cooler 10 . The internal assembly 74 may be configured to increase the force of the air as it exits the evaporative air cooler 10 to increase the cooling effectiveness of the evaporative air cooler 10 . Internal assembly 74 may also be configured to reduce noise generated during operation of evaporative air cooler 10 . For example, sealing, such as hermetic sealing, reduces the amount of air escaping from evaporative air cooler 10 and reduces air vibrations of other components or walls of evaporative air cooler 10 .

Drawer 50 may be attached to outlet vent 52 . Outlet vent 52 can be removed from evaporative air cooler 10 . For example, fixed vent 122 can include filter withdrawal tab 120 . A user can pull the filter pullout tab 120 to remove the outlet vent 52 from the evaporative air cooler 10 . The outlet vent 52 may have one or more tabs or any other desired device for removing the outlet vent 52 from the evaporative air cooler 10 . The inside of side 30 can include a drawer guide 108 . Drawer guide 108 is configured to assist a user in slidably removing the drawer from housing 20 and slidably inserting the drawer into housing 20 .

Drawer 50 may include a water tray 54 . A water tray 54 may be positioned within the drawer 50 . A water tray 54 may be formed as the bottom of the housing 20 . Water tray 54 may be angled so that any liquid on water tray 54 flows in a direction toward filter structure 56 . For example, the water tray 54 can be taller toward the rear end 78 of the drawer 50 than toward the front end 80 of the drawer. The water tray 54 can be configured for cleaning. For example, when drawer 50 is removed from evaporative air cooler 10 and filter structure 56 is removed from water tray 54, water tray 54 is readily accessible for cleaning. A user may wipe, dry, or otherwise clean the water tray 54 . Cleaning the water tray 54 may result in a reduction of mold or other bacteria.

Drawer 50 may be configured to support filter structure 56 . Filter structure 56 may be removably attached to drawer 50 . The drawer 50 can have drawer notches 128 to secure the filter structure 56 in place. For example, filter structure 56 may be positioned between outlet vent 52 and drawer notch 128 on the top surface of water tray 54 .

As shown in FIGS. 6A-6C, filter structure 56 may include a filter frame 82 and a plurality of filter holders 84 attached to opposite sides of filter frame 82 . In one exemplary embodiment, the filter frame 82 can include a top opening 86 and a bottom opening 88, as shown in FIG. 6C. Top opening 86 may be configured to allow mist 118 to contact top 112 of filter 58 . Bottom opening 88 may be configured to allow mist 118 and/or liquid such as water to contact bottom 114 of filter 58 . For example, if liquid collects in water tray 54 , the liquid may contact bottom 114 of filter 58 . The sponge material 60 of the filter 58 may soak up liquid. Sponge material 60 may also soak up mist 118 as mist 118 contacts filter 58 . Filter holder 84 may define a plurality of holes or filter openings 90 . Each filter opening 90 can be configured such that one filter 58 is positioned within the filter opening 90 . The filter holders 84 can be positioned substantially parallel to each other within the filter structure 56 . Filter holder 84 may be configured to hold filter 58 in place. Filters 58 may be positioned substantially parallel to each other and to opposite sides of filter structure 56 . Filter holders 84 may be configured to have a space, such as void 92 , between each filter holder 84 to allow mist 118 and/or liquid to contact filter 58 . Air and/or mist 118 may also exit evaporative air cooler 10 through air gap 92 . Filter structure 56 may be formed from plastic, metal, or any other desired material.

As shown in FIGS. 4-6, filter structure 56 may include a plurality of vertically mounted filters 58 . Filter 58 may be positioned parallel to the direction of airflow. Filter 58 may be formed from sponge material 60 . Filter 58 can be soaked before use. For example, a user can pull filter drawer tab 120 over outlet vent 52 to draw out inner assembly 74 including drawer 50 , water tray 54 , and filter structure 56 . The internal assembly 74 can be slid out from within the evaporative air cooler 10 . Filter structure 56 can be removed from drawer 50 . Filter structure 56 can be placed in a liquid such as water, placed under running water, or any other desired method for immersing filter 58 can be used. After wetting the filter 58, the filter structure 56 can be placed in a freezer or any other desired cooling device. By freezing the wet filter 58, the cooling effect of the evaporative air cooler 10 can be enhanced. When complete, the user can place the filter structure 56 onto the drawer 50 and slide the inner assembly 74 back into the evaporative air cooler 10 . If the filter 58 is pre-moistened, the initial cooling effect may be increased as air moves through the wet filter 58 when the evaporative air cooler 10 first begins to operate. If the filter 58 is not pre-soaked, the evaporative air cooler 10 can produce cooling air, but it may not be at full capacity.

Filter structure 56, which includes a plurality of filters 58, may be constructed of sponge material 60, plastic and sponge material 60, or any other desired material. Filter structure 56, along with filter 58, can be configured for cleaning. For example, the plastic and sponge material 60 can be cleaned using a variety of methods such as hand washing, soaking, dishwasher, or any other desired method. Filter structure 56, including filter 58, may be disinfected. For example, filter structure 56, including filter 58, can be sterilized by microwave or any other desired method. Filter 58 can be handled, cleaned, and used more vigorously than filters formed from paper materials. The filter 58 is reusable, can be used longer while wet, remoistened, and redried, and has an overall longer life and utility than paper filters. The filter structure 56 can be replaced, for example, after 3-6 months of use.

The evaporative air cooler 10 can also be powered on without water in the water tank 40 to dry the filter 58 and the interior of the evaporative air cooler 10 . For example, if the user plans not to use the evaporative air cooler 10 for a long period of time, the user may empty the water tank 40, press the power button 34 to turn on the evaporative air cooler 10, and for a period of, for example, four hours. You can put it in high mode.

Back surface 28 may include top portion 68 and framed portion 64 . Back surface 28 may include a power port for a power adapter. The power adapter includes a cord having at one end a first power adapter plug configured to plug into a power port and at an opposite end of the cord to a power outlet such as a wall outlet or power strip. and a second power adapter plug configured to be plugged. The power port may be located at the top 68 of the back surface 28 or any other desired location on the evaporative air cooler 10 . In another embodiment, the evaporative air cooler 10 can be powered using a battery or another power source.

Back surface 28 may also include a grid 94 . A grid 94 may be positioned within the framed portion 64 . Grate 94 may include a plurality of ribs positioned horizontally or vertically along back surface 28 . As shown in FIGS. 5 and 6, grid 94 includes both horizontal ribs 96 and vertical ribs 98 that define a plurality of grid openings 100 . The plurality of grid openings 100 are configured to allow air to flow from the outside of the evaporative air cooler 10 to the inside of the evaporative air cooler 10 . Lattice 94 may also have cord guides for securing the cord of the power adapter in place. The cord guides may be located along one side of grid 94, adjacent framed portion 64, or in any other desired location. Grid 94 may have one or more cord guide tabs. Additionally, some of the horizontal ribs 96 can be made shorter to allow the cords to be positioned flush with the horizontal ribs 96 .

As shown in FIGS. 7 and 8, fan cover assembly 102 may include grill 94 , fan 48 , and fan cover 46 . Fan cover assembly 102 may be configured to reduce vibration and other motion within evaporative air cooler 10 . Thereby, the fan cover assembly 102 can reduce the operating noise of the evaporative air cooler 10 . The fan cover assembly 102 can also effectively direct airflow. For example, the fan cover assembly 102 can effectively direct air outward from the evaporative air cooler 10 .

For example, fan 48 may direct airflow from back surface 28 toward front surface 26 . Fan 48 may be positioned within housing 20 between grill 94 and fan cover 46 . Fan cover 46 may be configured to further direct the airflow. For example, fan cover 46 may provide optimal airflow for the size and type of evaporative air cooler 10 . Fan cover 46 may be configured to maximize the technical and electrical specifications of fan 48 .

The user can control the speed of fan 48 . For example, a user can press the power button 34 to toggle the fan speed between three different speeds (eg, high, medium and low speed). By varying the fan speed, the water flow rate through the aperture 42 can be varied. Changes in water flow can be proportional to changes in fan speed. At high speeds, the water flow rate can be high. At medium speed, the water flow rate can be medium. At low speeds, the water flow rate can be low.

Accordingly, the atomizing structure 104 can be configured to produce varying amounts of mist 118 . The amount of fog 118 produced can be based on the fan speed. For example, as fan speed increases, the amount of fog 118 may increase. Increasing the amount of mist 118 can allow an optimal amount of moisture to enter the air, resulting in better cooling effect. As the fan speed slows down, the amount of fog may also decrease.

For example, when the power button 34 is pressed, the evaporative air cooler 10 can be turned on. Fan 48 may begin to rotate and mist 118 may begin to spray from atomizing structure 104 . The default fan speed may be high when the evaporative air cooler 10 is first powered on, or may be any other desired fan speed. A user can use the power button 34 to adjust the cooling effect of the evaporative air cooler 10, including the amount of fog 118 and/or the airflow velocity. A user can adjust the direction of the airflow (eg, top to bottom) with the air direction tab 72 on the outlet vent 52 . The power button 34 can be pressed again to turn off the evaporative air cooler 10 .

As shown in FIG. 7, a v-shaped shroud 44 may be positioned on the underside of top inner panel 110 to allow liquid to transform into mist 118 . The top interior panel 110 can be the wall between the evaporative air cooler 10 and the water tank 40, the bottom of the water tank 40, or any other desired structure. V-shaped shroud 44 may be configured to evenly distribute mist 118 toward filter 58 . Even distribution of liquid on filter 58 provides an effective cooling effect to the user. The v-shaped shroud 44 can be configured to maximize airflow to the user.

For example, a v-shaped shroud 44 may extend from the bottom of the water tank 40 into the evaporative air cooler 10 . A fan 48 used with the v-shaped shroud 44 can turn the liquid into a mist 118 and direct the mist 118 towards the filter structure 56 and filters 58 . Some of the mist 118 may evaporate and some of the mist 118 may travel between the sponge material 60 and through the exit vents 52 to cool the air outside the housing 20 . Some of the mist 118 can soak into the sponge material 60, allowing for later evaporative cooling. A portion of the mist 118 falls into the water tray 54 where it can be collected and become liquid. Liquid can be absorbed into the filter 58 via capillary action to allow additional evaporative cooling. The water tray 54 can be configured with a slight angle. This slight angle allows excess liquid or non-absorbent liquid to flow toward filter 58 . Excess liquid is absorbed and wicked by filter 58, allowing for a longer cooling effect. It also reduces water spillage when the evaporative air cooler 10 is moved or the drawer 50 is removed from the evaporative air cooler 10 as a result of wicking excess water.

As shown in FIGS. 4 and 9, housing 20 may include a container or tank, such as water tank 40 positioned below top surface 22 . A liquid such as water can be placed in the water tank 40 . For example, when hinged lid 32 is open, liquid can be poured into water tank 40 using a jug or any other desired means. Water tank 40 may have an opening, such as aperture 42 , for discharging liquid from water tank 40 into evaporative air cooler 10 . Aperture 42 may be positioned at the bottom of water tank 40 . Aperture 42 may be positioned between v-shaped shroud 44 and front surface 26 . More specifically, aperture 42 may be positioned between v-shaped shroud 44 and filter structure 56 .

The evaporative air cooler 10 can use two-stage cooling in its cooling process. A first stage may incorporate an atomizing structure 104 . Atomizing structure 104 can include a microporous atomizer, such as atomizer 106 . A second stage may incorporate a filter structure 56 having an evaporative sponge filter, such as filter 58 made from sponge material 60 . A combination of both stages can provide immediate and long-term cooling effects.

Atomizer 106 can provide an immediate cooling effect. For example, when evaporative air cooler 10 is turned on, mist 118 begins to spray from atomizer 106 . The power of fan 48 may be positioned behind fog 118 to distribute fog 118 into the ambient air or atmosphere and onto filter 58 . As the atomizer 106 operates for a sustained period of time, the filter 58 becomes wetter (eg wet filter). Air encountering fog 118 may feel cooler to the user due to the evaporative cooling process. As air continues to pass through wet filter 58, the cooling effect can be extended. When liquid is consumed from water tank 40, fog 118 may cease, but filter 58 may remain wet for a period of time, allowing at least some evaporative cooling to continue.

The atomizing structure 104 may be located or partially located within the water tank 40 . For example, atomizer 106 can be assembled through opening 42 of water tank 40 . The atomizing structure 104 can be attached to the bottom of the water tank 40, the top inner panel 110, or any other desired location using the atomizing structure attachment 126. FIG. The atomizing structure coupling 126 can include screws inserted through threaded holes or any other desired attachment. The atomizer 106 can be positioned upside down in the top-fill water tank 40 . The atomizer 106 can emit water downward into the interior of the evaporative air cooler 10 . Liquid can be supplied directly to the atomizer 106 . The atomizer 106 can dispense a mist 118 (eg, moisture) to the sponge filter. By atomizing the filter 58 from the top of the evaporative air cooler 10, the mist 118 can penetrate the filter 58 more effectively. Atomizer 106 is capable of providing a uniform distribution of mist 118 to filter 58 , including top 112 of filter 58 . The walls of the water tank 40 can have angles configured to allow an increased amount of liquid to reach the atomizer 106 .

Atomizer 106 may be configured to restrict water flow from aperture 42 when evaporative air cooler 10 is turned off.

The atomizing structure 104 can be wired to the evaporative air cooler 10 . Wiring may be soldered or attached in any other desired manner to electrically connect the atomizing structure 104 to the evaporative air cooler 10 . The wiring may be hidden within a wiring compartment within the evaporative air cooler 10 or any other desired compartment.

Evaporative air cooler 10 may operate for a period of time. This period of time depends on various factors such as the amount of water in the water tank 40, whether the filter 58 is pre-soaked, whether the filter 58 was initially frozen, and the cooling mode selected based on fan speed. can depend. In one embodiment, the evaporative air cooler 10 can operate on high mode for 8 hours, medium mode for 10 hours, and low mode for 12 hours without refilling the water tank 40 .

Evaporative air cooler 10 may include additional and/or fewer components and is not limited to those shown in the figures.

In the exemplary embodiment, evaporative air cooler 10 includes water tank 40 , atomizing structure 104 , filter structure 56 and fan 48 . Water tank 40 may include a liquid inlet (eg, via hinged lid 32) and a liquid outlet (eg, via opening 42). Liquid can enter the water tank 40 through the liquid inlet and exit the water tank through the liquid outlet. Atomization structure 104 may be in fluid communication with water tank 40 . Atomizing structure 104 may be configured to generate mist 118 as liquid flows through the liquid outlet. Filter structure 56 may include a plurality of filters 58 positioned substantially parallel to each other and defining air gaps 92 therebetween. The fan 48 may be configured to draw ambient air into the evaporative air cooler 10 and direct the ambient air out of the evaporative air cooler 10 through the filter structure. The ambient air can thus be cooled before exiting the evaporative air cooler 10 .

The atomizing structure 104 can distribute the mist 118 into the ambient air and over the multiple filters 58 . Atomization structure 104 may include an atomizer 106 . Atomizer 106 may be positioned adjacent to water tank 40 . Atomizer 106 may also be positioned within water tank 40 . Liquid can flow from the water tank 40 through the top of the atomizer 106 toward the bottom of the atomizer 106 . The atomizer 106 can emit a mist 118 from the atomizing structure 104 into the ambient air within the evaporative air cooler 10 . Fog 118 can cool the ambient air.

Atomizing structure 104 is capable of producing a first amount of mist 118 when fan 48 is at a first speed. The atomizing structure 104 can produce a second amount of mist 118 when the fan is at the second speed. The first amount may be greater than the second amount and the first speed may be greater than the second speed. In other words, more mist 118 can be sprayed from the atomizer 106 when the fan is on high.

Evaporative air cooler 10 may include fan 48 and internal assembly 74 configured to form seal 116 . Seal 116 allows ambient air to exit evaporative air cooler 10 with greater force than it enters evaporative air cooler 10 . Internal assembly 74 may include at least one of filter structure 56 and drawer 50 . The inner assembly 74 can be removably attached to the evaporative air cooler 10 . Internal assembly 74 may include drawer 50 attached to outlet vent 52 . Drawer 50 may include a water tray 54 angled toward outlet vent 52 . A filter structure 56 may be positioned adjacent the outlet vent 52 on the water tray 54 . Condensation or liquid in drawer 50 can flow toward exit vent 52 . A plurality of filters 58 may be formed from a sponge-like material, such as sponge material 60 . Thus, when filter structure 56 is positioned adjacent outlet vent 52 , multiple filters 58 are capable of wicking liquid as it flows toward outlet vent 52 . If multiple filters 58 are at full liquid capacity, the sponge material 60 may not soak up additional liquid. The liquid in filter 58 can be used to cool the ambient air. As liquid in filter 58 cools the ambient air, liquid may evaporate from filter 58 . The filter 58 may not be at full liquid capacity after evaporation has occurred, and thus can pick up more liquid.

Filter structure 56 may be configured to be removed from evaporative air cooler 10 . Filter structure 56 and plurality of filters 58 are washable and reusable. A plurality of filters 58 can be pre-soaked with liquid and inserted into the evaporative air cooler 10 . By presoaking the filter 58, the cooling of the evaporative air cooler 10 can be extended.

The evaporative air cooler 10 may include a shroud, such as a v-shaped shroud 44 that adjoins the underside of the water tank 40 . The shroud can be v-shaped or any other desired shape.

In the exemplary embodiment, portable evaporative air cooler 10 for cooling ambient air includes atomizing structure 104 , filter structure 56 and fan 48 . Atomization structure 104 may be configured to evaporate liquid within portable evaporative air cooler 10 . Filter structure 56 may include a plurality of filters 58 configured to absorb liquid. Fan 48 may be configured to draw ambient air into portable evaporative air cooler 10 . Ambient air may be cooled by at least one of fog 118 and filter structure 56 . Fan 48 may direct ambient air through filter structure 56 and out of portable evaporative air cooler 10 .

A plurality of filters 58 may be formed from sponge material 60 and positioned to define gaps, such as voids 92 , between the plurality of filters 58 . A plurality of filters 58 may be removable from the portable evaporative air cooler 10 . A plurality of filters 58 may be soaked with liquid prior to entering portable evaporative air cooler 10 .

Filter structure 56 may be positioned within drawer 50 . Drawer 50 may be removable from portable evaporative air cooler 10 . Portable evaporative air cooler 10 includes a front grille such as outlet vent 52 with air direction tabs 72 for directing airflow and filter drawer tabs 120 for pulling drawer 50 out of portable evaporative air cooler 10 . , can include

In the exemplary embodiment, personal air cooler 10 comprises housing 20 , a tank such as water tank 40 , atomization structure 104 , filter structure 56 and v-shaped shroud 44 . The housing can define the interior of the personal air cooler 10 with a top panel (e.g., top surface 22), a bottom panel (e.g., bottom surface 24), and side panels (e.g., front surface 26, rear surface 28, and sides 30). A tank can be positioned adjacent to the top panel and at least one of the side panels and can be configured to receive, store, and release liquid. Atomization structure 104 may be in fluid communication with the tank and configured to generate mist 118 . Filter structure 56 may be adjacent to the bottom panel and at least one of the side panels. A v-shaped shroud 44 may be positioned below the tank and configured to direct mist 118 toward filter structure 56 .

The personal air cooler 10 may include a fan 48 positioned adjacent one of the side panels. The personal air cooler 10 may also include a fan cover 46 adjacent the fan 48 and configured to direct air from outside the personal air cooler 10 toward the v-shaped shroud 44 . V-shaped shroud 44 may direct mist 118 through filter structure 56 toward the top of filter structure 56 .

Filter structure 56 may include a plurality of filters 58 positioned substantially parallel to each other. Each of the plurality of filters 58 may be separated by a particular distance, such as 1 cm, or any other desired distance. Thus, multiple filters 58 may define multiple voids 92 . A plurality of filters 58 can store fog 118 . The air can be cooled by fog 118 . Cooled air can travel through void 92 and exit the personal air cooler through one of the side panels. A side panel is the side panel adjacent to the filter structure 56 and may include the outlet vent 52 .

10-19 show an evaporative air cooler 200 for cooling air. The evaporative air cooler 200 may include a housing 220 having a top surface 222 , a bottom surface 224 and four lateral sides such as a front surface 226 , a rear surface 228 and a side surface 230 . Housing 220 may be formed into a cube, cuboid, hemisphere, or any other suitable shape. Housing 220 may be formed from plastic or any other desired material.

Top surface 222 can include a lid, such as lid 232 . 12 and 13 show evaporative air cooler 200 with lid 232 opened for access to tank 240 . A lid 232 may be positioned along the front of top surface 222 . Lid 232 may include a lid tab 276 formed as a rear portion of lid 232 or any other desired location. Lid 232 can be opened to allow water to fill tank 240 . For example, a user can pull lid tab 276 upward to open lid 232 . Lid 232 may be formed from plastic or any other desired material. Tank opening 244 to tank 240 can be any desired opening. When in the closed position, lid 232 may be configured to form a seal over tank opening 244 . Lid 232 and tank opening 244 may be oval or any other suitable shape or configuration.

Front face 226 may also include buttons such as power button 234 or any other desired button. Power button 234 may be configured to activate (eg, power ON), change the fan speed of fan 248 , and deactivate (eg, power OFF) evaporative air cooler 200 . For example, once the power button 234 is activated, the indicator light 238 can be turned on, the fan 248 can be turned on (e.g., fast), and the aperture 242 positioned within the water tank 240 can be turned on. , water can flow out of tank 240 to begin the evaporative air cooling process. When the power button 234 is activated twice, the fan speed is reduced (eg, to medium speed) and the aperture 242 allows less water to flow out of the tank 240 . When the power button 234 is actuated a third time, the fan speed is reduced (eg, to a low speed) and the aperture 242 allows less water to flow out of the tank 240 . When the power button 234 is activated four times, the indicator light 238 can be OFF (e.g., no indicator light 238 remains ON), the fan 248 can be OFF, and the aperture 242 is in the tank. The outflow of water from 240 can be stopped. In other words, the power button 234 can be activated to deactivate or power off the evaporative air cooler 200 . In one embodiment, indicator light 238 and evaporative air cooler 200 can be turned off when power button 234 is activated (eg, pressed) for more than three seconds.

Front face 226 may be configured to emit one or more lights, such as indicator light 238 or any other desired light or indicator. The front surface 226 can include translucent portions such as windows 250 . Indicator lights 238 may include one or more lights, such as blue LED lights, positioned within tank 240 or any other desired area to illuminate tank 240 and/or window 250 . The lights may be used for ambience, such as night lights, to indicate fan speed, to indicate that the evaporative air cooler 200 is on, or for any other desired purpose. The light may be on by default when the evaporative air cooler 200 is powered on. The intensity of indicator light 238 may be configured to vary. For example, after the power button 234 is pressed, the lights may be in high brightness mode. When the user presses the power button 234 a second time, the light can reduce its brightness (eg, to medium brightness mode). When the user presses the light button for a third time, the light can reduce its brightness (eg, to low brightness mode). When the user presses the power button 234 a fourth time, the indicator light 238 can be turned off. In one embodiment, lighting settings may be selected and/or locked if the power button 234 is activated for a minimum amount of time (eg, 3 seconds).

Power indicator light 236 may be used to indicate whether evaporative air cooler 200 is low, charging, or fully charged, whether filter 258 should be replaced, or any other desired indication. can be used. Power indicator light 236 may display a flashing light or a continuous light. Power indicator light 236 may display different light colors such as green, red, amber, or any other desired color.

Evaporative air cooler 200 may include housing 220 . Housing 220 may define an interior 254 of evaporative air cooler 200 . Interior 254 may be configured to receive filter structure 256 . Filter structure 256 may include a filter frame 282 . Filter frame 282 may be formed from plastic or any other desired material. Filter structure 256 may be square, rectangular, or any other desired shape. Filter frame 282 may include a bottom wall 330 , two side walls 332 and a top wall 334 . As shown in FIGS. 15 and 16A-16C, bottom wall 330 may be coupled to base 336 . Bottom wall 330 can be configured to lock within base 336 . Bottom wall 330 can include a bottom bar 338 that defines a bottom opening 340 . FIG. 15 shows the filter structure 256 with the second filter 262 removed. The top wall 334 can include an upper top wall 342 and a lower top wall 344 . Upper top wall 342 and lower top wall 344 may be configured to lock together. Upper top wall 342 and lower top wall 344 may define a top opening 346 . Upper top wall 342 may include one or more slits 370 between top openings 346 . Lower top wall 344 may include one or more bars 368 . Each of the one or more bars 368 may be positioned within one of the one or more slits 370 . Lower top wall 344 may include one or more tabs 372 . Each of the one or more tabs 372 may be positioned within one of the top openings 346 . Each of the one or more tabs 372 can include snaps 374 . Snap 374 can be configured to overlap the edge of top opening 346 . Snaps 374 can be configured to secure upper top wall 342 and lower top wall 344 in a locked position. Upper top wall 342 and lower top wall 344 may be coupled together via snaps or any other suitable means. Tabs 372 may be configured to angle downward toward the central portion of filter structure 256 . Tabs 372 may be configured to direct fog 118 , water, etc. toward the back of filter structure 256 . When filter structure 256 is within interior 254 of evaporative air cooler 200 , tabs 372 can direct water, fog 118 , etc. toward fan 248 .

Filter structure 256 may include one or more filters, such as filters 258 and 262 . A filter 258 can be positioned from one side of one of the bottom bars 338 to the other side of that bottom bar 338 through one of the bottom openings 340 . Filter 258 may be positioned around the top of one of top bars 368 . Filter 258 and top bar 368 are positioned within slit 370 when upper top wall 342 and lower top wall 344 are in the locked position. Filter 258 may include this configuration for each of bars 338 , 368 to form a zigzag configuration of filter 258 . Each of the ends of filter 258 may be coupled to one of sidewalls 332, bottom wall 330, or any other suitable component. For example, sidewall 332 can include hooks 364 and each end of filter 258 can include an opening configured to insert one of hooks 364 .

Filter structure 256 may include a filter holder 284 . Filter holder 284 may be coupled to filter frame 282 . For example, filter holder 284 can be snapped onto each of sidewalls 332 of filter frame 282 . A filter holder 284 may be coupled to filter frame 282 at an intermediate portion of each of sidewalls 332 . Filter structure 256 can be configured to be removed from interior 254 . Filter holder 284 may include pull tab 272 . A pull tab 272 may be positioned on the front side 348 of the filter structure 256 . Pull tab 272 may be configured such that a user pulls pull tab 272 to remove filter structure 256 from interior 254 of housing 220 and/or insert filter structure 256 into interior 254 . In this example, a user can remove grille 252 from housing 220 and pull on pull tab 272 to remove filter structure 256 . Filter structure 256, including filters 258, 262, is reusable. Filter structure 256 and filters 258, 262 can be washed. Filter structure 256 and filters 258, 262 are interchangeable.

Interior 254 may include filter structure stopper 308 . Filter structure stop 308 can be coupled to or formed on interior portions of side 230 and/or back 228 . Filter structure stopper 308 may be formed from plastic or any other desired material. Filter structure stop 308 can be configured to position filter structure 256 at a desired location within interior 254 . In other words, filter structure stop 308 stops and/or generally holds filter structure stop 308 in place adjacent to fan 248 but not in contact with fan 248 . As illustrated in FIGS. 15 and 16A-16C, the filter structure 256 can include a filter structure stopper tab 310 coupled to or formed within the front portion of the filter structure 256. As shown in FIGS. . Filter structure stopper tab 310 may be formed from plastic or any other desired material. Filter structure stop tabs 310 may be configured to position filter structure 256 at a desired location within interior 254 . In other words, filter structure stop tabs 310 stop and/or generally retain filter structure stop 308 in place adjacent to fan 248 but not in contact with fan 248 .

Filter holder 284 may include a bar 296 defining an opening such as slit 298 . Bar 296 of filter holder 284 extends from one side of filter holder 284 to the opposite side of filter holder 284 . A filter 258 can be positioned through each of the filter holders 284 . Filter holder 284 can provide additional support for securing filter 258 to filter frame 282 . Filter holder 284 can also help maintain the configuration of filter 258 in a zig-zag fashion when filter 258 is dry, wet, wet, or a combination thereof.

A second filter 262 may be coupled to at least a portion of the perimeter 302 of the filter structure 256 . In one embodiment, second filter 262 is positioned adjacent perimeter 302 of top wall 334 and sidewall 332 . Each end of second filter 262 can be coupled to the bottom of each sidewall 332 . For example, sidewall 332 can include hooks 364 and each end of second filter 262 can include an opening configured to insert one of hooks 364 . Second filter 262 may be configured to absorb fog 118 . Second filter 262 may be formed from the same material as filter 258, such as sponge material 260, or any other suitable material. A second filter 262 may be in fluid communication with filter 258 . Filter 258 may absorb liquid and/or mist 118 absorbed by second filter 262 . For example, a portion of filter 258 can be positioned through top wall 334 of filter structure 256 and positioned adjacent top wall 334 (eg, along perimeter 302 of a portion of filter frame 282). adjacent to the second filter 262 . Filters 258, 262 may be in contact with each other or in close proximity to each other. Second filter 262 may be coupled to two side walls 332, bottom wall 330, any other suitable wall portion, or a combination thereof. In one embodiment, filters 258, 262 are the same filter. In another embodiment, second filter 262 is not included in filter structure 256 .

Filter 258 may be configured in a zigzag fashion to define air gaps 292 . Filter 258 may be configured to retain liquids such as mist 118, water, any other suitable liquid, or combinations thereof. The filter may absorb mist 118 from the atomizer, absorb liquid from being pre-soaked, retain liquid by being frozen, or any other suitable means for absorbing or retaining liquid. is configured to perform Air gap 292 is configured to allow air to flow through filter structure 256 , contact filters 258 , 262 to cool the air, and exit interior 254 .

Filter structure 256 may include fan cover 246 . Fan cover 246 may be coupled to rear side 278 of filter structure 256 . A fan cover 246 may be positioned adjacent to the fan. Fan cover 246 may be configured to direct air from the fan toward filter structure 256 . Fan cover 246 may be configured to form suction with the fan to provide additional force in directing air from outside housing 220 through fan cover 246 , filter structure 256 , and grill 252 . In this manner, fan cover 246 may be configured to direct airflow through interior 254 of evaporative air cooler 200 .

Fan 248 may be positioned adjacent one of the sides of housing 220 , such as back surface 228 . Fan 248 may be configured to draw air into evaporative air cooler 200 , such as through grid openings 300 in back surface 228 of housing 220 . The air may be cooled by at least one of fog 118 and filters 258,262. Fan 248 may include blades 264 . Fan 248 may include four blades 264 or any other suitable number of blades. Fan 248 may include motor 266 . Motor 266 may be used to control fan 248 to rotate blades 264 . A motor 266 can rotate the blades 264 at various speeds. The rotational speed of blades 264 can change the amount (eg, volume) of air and the rate at which air exits interior 254 of evaporative air cooler 200 through filter structure 256 . The evaporative air cooler 200 can include different levels of velocity, each of which can be configured to direct the air. A higher level can direct a greater amount of air at the first velocity. A mid-range level can direct a mid-range amount of air at a second velocity. A lower level can direct a smaller amount of air at a third velocity. The first speed may be greater than the second speed. The second speed may be greater than the third speed. Evaporative air cooler 200 may be configured to have a predefined speed, variable speed, or any combination thereof.

A fan 248 may be wired to the evaporative air cooler 200 . Wiring 322 may be soldered to electrically connect fan 248 to evaporative air cooler 200 or attached in any other desired manner. Wiring 322 may be hidden within a wiring compartment within evaporative air cooler 200 or any other desired compartment.

As shown in FIG. 18, back surface 228 can include a grid 294 that defines grid openings 300 . Grid openings 300 may be configured throughout grid 294 . Grid 294 can be a portion of back surface 228 , such as a central portion of back surface 228 . Grid 294 may be rectangular, square, circular, oval, or any other suitable shape. Grid openings 300 can include one or more shapes (eg, circular, rectangular, oval, any other suitable shape, or combinations thereof). Air, such as ambient air, can enter interior 254 of evaporative air cooler 200 from outside housing 220 through grid openings 300 in grid 294 . A grid 294 may be configured to protrude from the rear surface 228 . Fan 248 may be coupled to back surface 228 . More specifically, grid 294 may include fan couplings 288 that couple to fan 248 . The protrusion of grid 294 from back surface 228 can be configured to accommodate fan 248 .

Evaporative air cooler 200 may be powered by a power source such as a battery or any other suitable power source. The battery may be a rechargeable battery such as a Lithium Ion Battery (LIB) or any other rechargeable power source. Evaporative air cooler 200 may include a charging port (not shown) to charge a rechargeable battery. The charging port may be located on the back surface 228 or any other desired location on the evaporative air cooler 200 . A charging port (not shown) may be configured to receive charger 268 . Evaporative air cooler 200 can operate using rechargeable batteries and/or when plugged into an electrical outlet.

As shown in FIGS. 14 and 17, front surface 226 of housing 220 may define an opening, such as forward opening 286 . A grille 252 may be coupled to the front face 226 and cover the front opening 286 . Grill 252 may include grill tabs 274 configured to secure grill 252 to housing 220 . Grill tabs 274 may be coupled to grill 252 or formed within grill 252 . A grill tab 274 may be positioned at each corner of grill 252 . Grille 252 may be configured to removably couple to front surface 226 of housing 220 . Each grill tab 274 can be inserted into one of the openings 324 in housing 220 . Opening 324 may be located on bottom surface 224 , front surface 226 , or any other desired location within housing 220 . When coupled to housing 220 , grill 252 can provide a front side of housing 220 . Grill 252 may include vents 270 (eg, bars). Vent 270 may be configured in a horizontal configuration, an angled configuration, any other suitable configuration, or combinations thereof. Vent 270 may be stationary. Vent 270 can be configured to rotate. Each of the vents 270 may be aligned parallel to each other such that the vents 270 are configured to allow air to pass through the vents 270 .

Evaporative air cooler 200 may include angled member 210 . An angled member may be coupled to the housing 220 . The angling member can include arms 352 , 354 and base 356 . A first arm may be rotatably coupled to one of the sides 230 of housing 220 . A second arm 354 may be rotatably coupled to the opposing side surface 230 . In one embodiment, first and second arms 352 , 354 are coupled to a central portion of side 230 . The arms may be coupled to the sides via couplings 358 such as a ratchet system or any other desired rotatable attachment. The angling member may be configured to rotate housing 220 . The angulation member can rotate the housing 220 to position the housing 220 at an angle desired by the user. The angling member can be configured to rotate the housing 220 vertically. The angling member 210 can be configured to rotate the housing 220 360 degrees. Angled member 210 can maintain the position or angle of housing 220 relative to angled member 210 . For example, if a user wants the evaporative air cooler 200 to blow cooling air toward the user's face, the user can rotate the housing 220 upward to direct the cooled air upward. Similarly, the user can rotate the housing 220 downward to direct cooled air downward. Arms 352, 354 may be coupled at the sides such that housing 220 is stationary and cannot rotate about the arms.

First and second arms 352 , 354 can project from opposite sides of base 356 . First and second arms 352 , 354 may be formed with base 356 or may be coupled to base 356 . Base 356 may be formed from plastic or any other suitable material. Base 356 may be coupled to clip 202 via coupling 360, such as a ratchet system or any other desired rotatable attachment. Coupling 360 can be configured to rotate housing 220 through base 356 in either direction (eg, right or left) 360 degrees or any other desired degree of rotation.

Evaporative air cooler 200 may include fasteners such as clips 202 . Clip 202 can be a device that is rotatable or acted upon by spring 380 to hold an object or objects together or in place. For example, clip 202 may be configured to removably couple evaporative air cooler 200 to handle 206 of stroller 204, countertop 208, desk, table, or any other suitable object. Clip 202 may include grips 382 , 384 on one or more components of clip 202 . For example, grip 382 may be configured on grip side 388 of clip 202 and grip 384 may be configured on grip side 390 of clip base 376 . Grips 382, 384 may be configured to more securely attach evaporative air cooler 200 to an object. Grips 382, 384 may be formed from rubber, plastic, or any other desired material. Grips 382, 384 may be formed as ridges and/or smooth surfaces. The smooth surface may be configured to protect the object to which clip 202 is attached so that clip 202 does not damage (eg, scrape, scratch, etc.) the object.

Clip 202 may be coupled to clip base 376 via coupling 392 . Coupling portion 392 may include a rod 386 configured to be inserted into rod holders 394,396. A rod holder 394 may be coupled to or formed at the end of one of the sides of the clip. A rod holder 396 may be coupled to or formed on the grip side 390 of the base. Each of the rod holders 394, 394 can define an opening into which the rod 386 is inserted. Spring 380 may define an opening through which rod 386 is configured. A spring 380 may tension the clip 202 against the clip base 376 . In the closed position, clip 202 may be configured such that one end of clip 202 (eg, grip end 398 ) extends further than clip base 376 . Grip end 398 is configured such that a user rotates clip 202 by applying a force to grip end 398 to rotate clip 202 about coupling portion 392 . A user can open clip 202 to insert an object into clip 202 . When the user releases clip 202, the tension provided by spring 380 binds clip 202 to the object and secures evaporative air cooler 200 in the desired location.

Clip 202 can include one or more support members 400 . One or more support members 400 can be configured on either side of clip 202, along clip 202, or in any other desired location. The one or more support members 400 can be configured to support the evaporative air cooler 200 in an upright position when the clips 202 are in the closed position. In other words, the one or more support members 400 support the evaporative air cooler 200 so that the evaporative air cooler 200 does not easily tip over when placed on a surface. Similarly, the clip base 376 includes a front surface 378 configured to support the evaporative air cooler 200 when the evaporative air cooler 200 is placed on a surface (eg, with the clip in the closed position). It's okay. The front face 378 may protect the components of the coupling portion 392 from damage. For example, the front face 378 can stop the clip 202 from being over-rotated such that the spring 380 overextends.

Clip 202 may be coupled to angulation member 210 . Specifically, clip base 376 may be coupled to base 356 of angulation member 210 . Clip base 376 may be rotatably coupled to base 356 , such as the bottom of base 356 . Clip base 376 may be coupled to base 356 via coupling 360, such as a ratchet system or any other desired rotatable attachment. Base 356 can be configured to horizontally rotate housing 220 about clip base 376 . The base 356 can rotate 0-360 degrees horizontally in any direction around the clip base 376 . For example, a user may attach evaporative air cooler 200 to countertop 208 via clips 202 . A user can rotate housing 220 of evaporative air cooler 200 horizontally toward the user via base 356 . The user can also rotate housing 220 vertically toward the user via angulation member 210 . In this way, when the evaporative air cooler 200 is turned on, cooled air can be directed to the user. In another embodiment, the housing 220 can be coupled to the angling member 210, the base 356 can be coupled to the clip base 376, and the housing 220 can be stationary and rotated horizontally and/or vertically. is made impossible.

As shown in FIGS. 13 and 14, evaporative air cooler 200 may include tank 240 . Tank 240 may be positioned adjacent top surface 222 of housing 220 . Portions of the interior of top 222 , front 226 , back 228 , and sides 230 of housing 220 may form part of tank 240 . For example, tank 240 may be configured within housing 220 such that the top of tank 240 is below top surface 222 of housing 220 . Tank 240 may include a front side and a bottom side coupled to housing 220 . The front and bottom sides of tank 240 may include windows 250 . A light, such as power indicator 236, can be located adjacent the bottom side of tank 240, or in any other desired location. The bottom side of tank 240 and the front of tank 240 may include windows 250 and may be configured to illuminate the light generated by power indicator 236 across tank 240 . Power indicator 236 may also be configured to illuminate into interior 254 and toward the exterior of evaporative air cooler 200 .

Tank 240 may include liquid inlet 312 and liquid outlet 314 . The top of housing 220 can define an opening, such as liquid inlet 312 . Liquid inlet 312 may be oval, circular, or any other desired shape. The bottom of tank 240 can define an opening, such as liquid outlet 314 . The liquid outlet can be oval, circular, or any other desired shape. Liquid outlet 314 may be positioned at the bottom of tank 240 . Liquid outlet 314 may be positioned at a central location on the bottom of tank 240 . A liquid outlet may be positioned adjacent to the filter structure 256 . Liquid outlet 314 may be configured to receive atomizing structure 304 including atomizer 306 . A liquid such as water can enter tank 240 through liquid inlet 312 and exit tank 240 through liquid outlet 312 . In response to liquid flowing through the liquid outlet 314 , the atomizer 306 may be configured to generate a mist within the interior 254 of the evaporative air cooler 200 from the liquid.

As shown in FIGS. 12 and 13, lid 232 may be coupled to top surface 222 or any other suitable portion of housing 220 . Lid 232 may be coupled to top surface 222 via a hinge, cord, or any other suitable attachment. A portion of lid 232 may be configured to fit within liquid inlet 312 . For example, if liquid inlet 312 is elliptical, lid 232 may be slightly smaller elliptical to fit within liquid inlet 312 and form seal 316 when lid 232 is in the closed position. can be done. Lid 232 may include oval seal 316 to form a seal with liquid inlet 312 so that liquid remains in tank 240 . Lid 232 may be formed from plastic or any other desired material. Seal 316 may be formed from rubber or any other desired material. Tank 240 can be configured to receive, store, and release liquid. For example, when lid 232 is open (see FIG. 13), liquid can be poured into tank 240 using a jug, faucet, water bottle, or any other desired filling means.

Atomizer 306 may be positioned adjacent tank 240 . Atomizer 306 may be coupled to liquid outlet 314 . Atomizer 306 can be in fluid communication with tank 240 . Liquid can flow from tank 240 through the top of atomizer 306 toward the bottom of atomizer 306 . Atomizer 306 may be configured to generate mist 118 from liquid stored in tank 240 . Atomizer 306 may distribute mist 118 into the air into interior 254 of evaporative air cooler 200 and onto filters such as second filter 262 . Fog 118 may cool the air within interior 254 .

When the evaporative air cooler 200 is operating, the atomizer 306 can generate the mist 118 . For example, atomizer 306 may be configured to generate first amount of mist 118 when fan 248 is at a first speed. Atomizer 306 operates a second volume when fan 248 is at a second speed (opening 242 of atomizing structure 304 may allow less water to flow out of tank 240). of fog 118 can be configured. Atomizer 306 may be configured to generate a third amount of mist 118 when fan 248 is at a third speed. The first amount may be greater than the second amount and the first speed may be greater than the second speed. In other words, when fan 248 is on, a larger amount of mist 118 can be sprayed from atomizer 306 . Similarly, the first amount and the second amount can be greater than the third amount, and the first rate and the second rate can be greater than the third rate. Evaporative air cooler 200 may have a button, such as power button 234 , to control the speed of fan 248 . For example, when power button 234 is first engaged, fan 248 may operate at a first speed. When the power button 234 is engaged a second time, the fan 248 can operate at a second speed. When power button 234 is engaged for a third time, fan 248 can operate at a third speed. When the power button 234 is engaged a fourth time, the fan 248 can be turned off (ie, cease operation of the fan 248). Evaporative air cooler 200 may have any number of speeds and is not limited to those described in this disclosure. Evaporative air cooler 200 may have a light (eg, power indicator 236) such as an LED light or any other desired light to indicate that evaporative air cooler 200 is operating. Power indicator 236 may be configured to indicate the speed of operation.

Evaporative air cooler 200 may include safety interlock 320 . Safety interlock 320 may be configured to prevent operation of evaporative air cooler 200 . For example, safety interlock 320 may block operation of evaporative air cooler 200 if at least one of grill 252 and filter structure 256 is removed from housing 220 . The safety interlock 320 can serve as a safety feature to prevent the user from touching the blades of the fan while the fan is spinning during operation.

In one embodiment, an evaporative air cooler 200 for cooling air comprises a housing 220 , a tank 240 , an atomizer, a filter structure 256 , a fan, and clips 202 . Housing 220 defines the interior of evaporative air cooler 200 . Tank 240 is positioned adjacent the top of housing 220 . Tank 240 is configured to receive, store and release liquid. The atomizer is configured to be in fluid communication with tank 240 . The atomizer is configured to generate a mist 118 from the liquid. Fog 118 can be generated internally. Filter structure 256 includes a filter. The filter is configured to absorb fog. The fan is configured to draw air inside. The air is cooled by fog 118 and/or filters. The fan directs air out of evaporative air cooler 200 through filter structure 256 . Clip 202 is coupled to housing 220 . The angled member is coupled to housing 220 . The angling member is configured to rotate housing 220 . The angling member is configured to rotate the housing 220 in at least one of the vertical and horizontal directions. The angulation member is configured to rotate the housing 220 vertically from 0 to 360 degrees. The angling member is configured to rotate the housing 220 horizontally from 0 to 360 degrees. Clips 202 are configured to removably couple evaporative air cooler 200 to an object. This embodiment may have fewer or additional features and is not limited to this configuration.

In another embodiment, an evaporative air cooler 200 for cooling air comprises a housing 220 , a tank 240 , an atomizer, a filter structure 256 , a fan, and clips 202 . Housing 220 defines the interior of evaporative air cooler 200 . Tank 240 is positioned adjacent the top of housing 220 . Tank 240 is configured to receive, store and release liquid. The atomizer is configured to be in fluid communication with tank 240 . The atomizer is configured to generate a mist 118 from the liquid. Fog 118 can be generated internally. Filter structure 256 includes a filter and a second filter. The filter and the second filter are configured to absorb fog. The filter is configured in a zigzag fashion to define air gaps. A second filter is coupled to at least a portion of perimeter 302 of filter structure 256 . A second filter is in fluid communication with the filter. The fan is configured to draw air inside. The air is cooled by at least one of fog, a filter, and a second filter. The fan directs air from the inside through the filter structure 256 . Clip 202 is coupled to housing 220 . This embodiment can have fewer or additional features and is not limited to this configuration.

Consistent with the above disclosure, the examples of systems and methods listed in the following sections are specifically contemplated and are intended as a non-limiting set of examples.

Section 1. An evaporative air cooler for cooling ambient air, comprising:
a housing having a top panel, a bottom panel, and side panels defining an interior of an evaporative air cooler;
a tank positioned adjacent to at least one of the top panel and the side panels, the tank configured to receive, store and discharge liquid, the evaporative air cooler further comprising:
an atomizing structure including an atomizer and an atomizing structure coupling, the atomizing structure configured to generate a mist within the evaporative air cooler, the evaporative air cooler further comprising:
A filter structure having a plurality of filters, the plurality of filters configured to absorb fog, the evaporative air cooler further comprising:
A fan configured to draw ambient air into the evaporative air cooler, the ambient air being cooled by at least one of a mist and a filter structure, the fan directing the ambient air through the filter structure and into the interior. Evaporative air cooler directing from.

Section 2. An evaporative air cooler according to any preceding clause, wherein the plurality of filters are formed from a sponge material and positioned to define gaps between the plurality of filters.

Section 3. The filter structure is positioned within the drawer,
An evaporative air cooler according to any preceding clause, wherein the drawer is removable from the evaporative air cooler.

Section 4. An evaporative air cooler according to any preceding clause, further comprising a front grille having tabs for pulling a drawer out of the evaporative air cooler.

Section 5. An evaporative air cooler according to any preceding clause, wherein the plurality of filters is removable from the evaporative air cooler and configured to be soaked with liquid prior to entering the evaporative air cooler.

Section 6. the plurality of filters aligned parallel to each other defining a gap between the plurality of filters;
An evaporative air cooler according to any preceding clause, wherein the ambient air is cooled prior to exiting the evaporative air cooler.

Section 7. An evaporative air cooler according to any preceding clause, wherein the atomizing structure distributes the mist into the ambient air and onto a plurality of filters.

Section 8. the tank includes a liquid inlet and a liquid outlet;
Liquid enters the tank through the liquid inlet and exits the tank through the liquid outlet,
an atomizing structure in liquid communication with the tank and configured to produce a mist as the liquid flows through the liquid outlet;
An evaporative air cooler according to any preceding clause, wherein the atomizer is positioned within the tank and liquid flows from the tank towards the atomizer.

Section 9. the atomizing structure produces a first amount of fog when the fan is at a first speed;
An evaporative air cooler according to any preceding clause, wherein the atomizing structure produces a second amount of fog when the fan is at the second speed.

Section 10. the first quantity is greater than the second quantity;
An evaporative air cooler according to any preceding clause, wherein the first speed is higher than the second speed.

Section 11. moreover,
Any preceding term comprising an internal assembly configured to form a seal with the fan, the seal forcing ambient air out of the evaporative air cooler with greater force than when it entered the evaporative air cooler. The evaporative air cooler described in .

Section 12. An evaporative air cooler according to any preceding clause, wherein the internal assembly includes a filter structure and a drawer.

Section 13. the filter structure is configured to be removed from the interior,
An evaporative air cooler according to any preceding clause, wherein the filter structure and the plurality of filters are washable and reusable.

Section 14. An evaporative air cooler according to any preceding clause, wherein the plurality of filters are formed from a sponge-like material.

Section 15. moreover,
An evaporative air cooler according to any preceding clause, comprising a shroud adjacent the underside of the tank, the shroud being v-shaped.

Section 16. An evaporative air cooler for cooling ambient air, comprising:
a housing having a top panel, a bottom panel, and side panels defining an interior of an evaporative air cooler;
a tank positioned adjacent to at least one of the top panel and the side panel and configured to receive, store and release liquid;
an atomizing structure including an atomizer and an atomizing structure coupling, the atomizing structure in fluid communication with the tank, the atomizing structure configured to generate a mist within the evaporative air cooler; In addition, the air cooler
a filter structure having a plurality of filters, the plurality of filters configured to absorb fog, the filter structure adjacent the bottom panel and at least one of the side panels; furthermore,
A fan configured to draw ambient air into the evaporative air cooler, the ambient air being cooled by at least one of fog and the filter structure, the fan directing the ambient air through the filter structure and into the interior. Oriented from, the evaporative air cooler further
An evaporative air cooler comprising a v-shaped shroud positioned below the tank and configured to direct mist towards the filter structure.

Section 17. moreover,
a fan cover adjacent to the fan and configured to direct air from outside the evaporative air cooler toward the v-shaped shroud, the fan positioned adjacent to at least one of the side panels; The evaporative air cooler of any preceding paragraph, wherein

Section 18. An evaporative air cooler according to any preceding clause, wherein the v-shaped shroud directs the mist toward and through the top of the filter structure.

Section 19. the filter structure includes a plurality of filters aligned parallel to each other and defining voids;
Multiple filters store fog,
An evaporative air cooler according to any preceding clause, wherein air is cooled by fog, travels through an air gap and exits the evaporative air cooler through one of the side panels.

Section 20. moreover,
an internal assembly attached to one of the side panels, one of the side panels configured to be removed from the evaporative air cooler;
the inner assembly includes a drawer attached to one of the side panels;
the drawer includes a water tray angled toward one of the side panels;
An evaporative air cooler according to any preceding clause, wherein the filter structure is positioned on the water tray and the filter structure is positioned adjacent one of the side panels.

Section 21. An evaporative air cooler for cooling air,
a housing defining an interior of the evaporative air cooler;
a tank positioned adjacent the top of the housing, the tank configured to receive, store and discharge liquid; the evaporative air cooler further comprising:
an atomizer in fluid communication with the tank, the atomizer configured to generate a mist from the liquid; the evaporative air cooler further comprising:
A filter structure having a filter, the filter configured to absorb fog, the evaporative air cooler further comprising:
a fan configured to draw air inwardly, the air being cooled by at least one of a fog and a filter, the fan directing the air from the interior through the filter structure; ,
An evaporative air cooler comprising clips coupled to a housing.

Section 22. An evaporative air cooler according to any preceding clause, wherein the filter is formed of a sponge material.

Section 23. An evaporative air cooler according to any preceding paragraph, wherein the filter is arranged in a zigzag fashion to define an air gap.

Section 24. An evaporative air cooler according to any preceding clause, further comprising a second filter coupled to at least a portion of the periphery of the filter structure, the second filter configured to absorb fog.

Section 25. An evaporative air cooler according to any preceding clause, wherein the second filter is in fluid communication with the filter.

Section 26. the filter structure is configured to be removed from the interior,
the filter structure and filter are washable and reusable;
An evaporative air cooler according to any preceding clause, wherein the filter is configured to retain liquid.

Section 27. An evaporative air cooler according to any preceding clause, further comprising an angled member coupled to the housing, the angled member configured to rotate the housing.

Section 28. An evaporative air cooler according to any preceding clause, wherein the angled member is configured to rotate the housing in at least one of vertical and horizontal directions.

Section 29. An evaporative air cooler according to any preceding clause, wherein the angled member is configured to rotate the housing 360 degrees.

Section 30. An evaporative air cooler according to any preceding clause, wherein the clip is coupled to the angled member.

Section 31. An evaporative air cooler according to any preceding clause, wherein the clip is configured to removably couple the evaporative air cooler to an object.

Section 32. An evaporative air cooler according to any preceding clause, further comprising a grill configured to be removably coupled to the housing.

Section 33. Evaporative type according to any preceding paragraph, further comprising a safety interlock configured to prevent operation of the evaporative air cooler when at least one of the grill and filter structure is removed from the housing. air cooler.

Section 34. the tank includes a liquid inlet and a liquid outlet;
Liquid enters the tank through the liquid inlet and exits the tank through the liquid outlet,
An evaporative air cooler according to any preceding clause, wherein the atomizer is configured to generate a mist in response to liquid flowing through the liquid outlet.

Section 35. moreover,
An evaporative air cooler according to any preceding clause, comprising a fan cover adjacent to the fan, the fan cover configured to direct air from the fan towards the filter structure.

Section 36. An evaporative air cooler for cooling air,
a housing defining an interior of the evaporative air cooler;
a tank positioned adjacent the top of the housing, the tank configured to receive, store and discharge liquid; the evaporative air cooler further comprising:
an atomizer in fluid communication with the tank, the atomizer configured to generate a mist from the liquid; the evaporative air cooler further comprising:
A filter structure having a filter, the filter configured to absorb fog, the evaporative air cooler further comprising:
a fan configured to draw air inwardly, the air being cooled by at least one of a fog and a filter, the fan directing the air from the interior through the filter structure; ,
The evaporative air cooler further comprises an angled member coupled to the housing, the angled member configured to rotate the housing, the evaporative air cooler further comprising:
An evaporative air cooler comprising a clip coupled to an angled member.

Section 37. An evaporative air cooler according to any preceding clause, wherein the angled member is configured to rotate the housing in at least one of vertical and horizontal directions.

Section 38. An evaporative air cooler according to any preceding clause, wherein the clip is configured to removably couple the evaporative air cooler to an object.

Section 39. An evaporative air cooler for cooling air,
a housing defining an interior of the evaporative air cooler;
a tank positioned adjacent the top of the housing, the tank configured to receive, store and discharge liquid; the evaporative air cooler further comprising:
an atomizer in fluid communication with the tank, the atomizer configured to generate a mist from the liquid; the evaporative air cooler further comprising:
a filter structure having a filter and a second filter, the filter and the second filter configured to absorb fog, the evaporative air cooler further comprising:
a fan configured to draw air into the interior, the air being cooled by at least one of a fog, a filter, and a second filter, the fan directing the air from the interior through the filter structure; The evaporative air cooler also
An evaporative air cooler comprising clips coupled to a housing.

Section 40. The filter is configured in a zigzag fashion to define an air gap,
a second filter coupled to at least a portion of the perimeter of the filter structure;
An evaporative air cooler according to any preceding clause, wherein the second filter is in fluid communication with the filter.

No part of the description in this application should be read as implying that any particular element, step, or function is an essential element that must be included in the claims. The scope of patented subject matter is defined only by the claims. Moreover, none of the claims are intended to invoke 35 U.S.C. §112(f) unless the term "means for" itself is followed by a participle.

The foregoing description, for purposes of explanation, uses specific terminology to provide a thorough understanding of the described embodiments. However, it will be apparent to those skilled in the art that the specific details are not required to practice the described embodiments. Accordingly, the foregoing descriptions of specific embodiments are presented for purposes of illustration and description. They are not intended to be exhaustive or to limit the described embodiments to the precise forms disclosed. It will be apparent to those skilled in the art that many modifications and variations are possible in light of the above teachings.

Although the present disclosure has been described in connection with particular embodiments, the present disclosure is not limited to the disclosed embodiments, but rather various modifications and equivalents that fall within the scope of the claims. It is understood that the scope is to be given the broadest interpretation so as to encompass all such modifications and equivalent constructions permitted under law. be done.

Claims (20)

An evaporative air cooler for cooling air,
a housing defining an interior of the evaporative air cooler;
a tank positioned adjacent the top of said housing, said tank configured to receive, store and discharge liquid; said evaporative air cooler further comprising:
an atomizer in fluid communication with the tank, the atomizer configured to generate a mist from the liquid; the evaporative air cooler further comprising:
a filter structure having a filter, the filter configured to absorb the fog, the evaporative air cooler further comprising:
a fan configured to draw the air into the interior, the air being cooled by at least one of the fog and the filter, the fan drawing the air from the interior through the filter structure; Orienting, said evaporative air cooler further:
An evaporative air cooler comprising a clip coupled to said housing. The evaporative air cooler of claim 1, wherein said filter is formed of a sponge material. 2. The evaporative air cooler of claim 1, wherein the filter is configured in a zigzag fashion to define air gaps. 2. The evaporative air cooler of claim 1, further comprising a second filter coupled to at least a portion of the periphery of said filter structure, said second filter configured to absorb said fog. . 5. The evaporative air cooler of claim 4, wherein said second filter is in fluid communication with said filter. the filter structure is configured to be removed from the interior;
said filter structure and said filter are washable and reusable;
2. The evaporative air cooler of claim 1, wherein the filter is configured to retain liquid. 2. The evaporative air cooler of claim 1, further comprising an angled member coupled to the housing, the angled member configured to rotate the housing. 8. The evaporative air cooler of claim 7, wherein the angled member is configured to pivot the housing in at least one of vertical and horizontal directions. 8. The evaporative air cooler of claim 7, wherein the angled member is configured to rotate the housing 360 degrees. 8. The evaporative air cooler of claim 7, wherein said clip is coupled to said angled member. 2. The evaporative air cooler of claim 1, wherein the clip is configured to removably couple the evaporative air cooler to an object. 2. The evaporative air cooler of claim 1, further comprising a grill configured to removably couple to said housing. 13. The claim 12, further comprising a safety interlock configured to prevent operation of the evaporative air cooler when at least one of the grill and filter structure is removed from the housing. Evaporative air cooler. the tank comprises a liquid inlet and a liquid outlet;
liquid enters the tank through the liquid inlet and exits the tank through the liquid outlet;
2. The evaporative air cooler of claim 1, wherein the atomizer is configured to generate fog in response to the liquid flowing through the liquid outlet. moreover,
2. The evaporative air cooler of claim 1, comprising a fan cover adjacent said fan, said fan cover configured to direct said air from said fan towards said filter structure. An evaporative air cooler for cooling air,
a housing defining an interior of the evaporative air cooler;
a tank positioned adjacent the top of said housing, said tank configured to receive, store and discharge liquid; said evaporative air cooler further comprising:
an atomizer in fluid communication with the tank, the atomizer configured to generate a mist from the liquid; the evaporative air cooler further comprising:
a filter structure having a filter, the filter configured to absorb the fog, the evaporative air cooler further comprising:
a fan configured to draw the air into the interior, the air being cooled by at least one of the fog and the filter, the fan drawing the air from the interior through the filter structure; Orienting, said evaporative air cooler further:
further comprising an angled member coupled to the housing, the angled member configured to rotate the housing, the evaporative air cooler further comprising:
An evaporative air cooler comprising a clip coupled to said angled member. 17. The evaporative air cooler of claim 16, wherein the angled member is configured to rotate the housing in at least one of vertical and horizontal directions. 17. The evaporative air cooler of claim 16, wherein the clip is configured to removably couple the evaporative air cooler to an object. An evaporative air cooler for cooling air,
a housing defining an interior of the evaporative air cooler;
a tank positioned adjacent the top of said housing, said tank configured to receive, store and discharge liquid; said evaporative air cooler further comprising:
an atomizer in fluid communication with the tank, the atomizer configured to generate a mist from the liquid; the evaporative air cooler further comprising:
a filter structure having a filter and a second filter, the filter and the second filter configured to absorb the fog, the evaporative air cooler further comprising:
a fan configured to draw the air into the interior, the air being cooled by at least one of the fog, the filter, and the second filter, the fan pulling the air into the directed from the interior through a filter structure, the evaporative air cooler further comprising:
An evaporative air cooler comprising a clip coupled to said housing. the filter is configured in a zigzag fashion to define an air gap;
the second filter is coupled to at least a portion of the periphery of the filter structure;
20. The evaporative air cooler of claim 19, wherein said second filter is in fluid communication with said filter.

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