BEVERAGE COOLER WITH AUTOMATIC DISPENSER

Abstract

A cooler assembly includes an insulted main container and a pump assembly configured to pump contents of the main container through a tube to a spigot. An electronic control board includes a pressure-sensing switch that senses pressure differentials or fluid movement when the spigot is opened and closed, causing a triggering event. Triggering events are used to activate and deactivate the pump to dispense fluid from the main container.

Claims

1. A beverage cooler, comprising: a thermally-insulated container body configured to store a liquid; a pump configured to receive the liquid from the container body and deliver the liquid to a pump outlet; a length of tubing having a proximal end connected to the pump outlet and a distal end connected to a manually-actuated spigot; and a tubing path disposed on an exterior surface of the container body along which at least a portion of the tubing is routed, wherein the tubing path extends upwardly around the container body such that the spigot is positioned above all other portions of the tubing, thereby reducing accidental drainage and bubble formation within the tubing.

Description

DESCRIPTION OF DRAWINGS

[0019] The present embodiments are illustrated by way of the figures of the accompanying drawings, which may not necessarily be to scale, in which like references indicate similar elements, and in which:

[0020] FIG. 1 is a perspective view of a cooler assembly according to one embodiment;

[0021] FIG. 2 is front view of the cooler assembly shown in FIG. 1;

[0022] FIG. 3 is a rear view of the cooler assembly shown in FIG. 1;

[0023] FIG. 4 shows select internal components of a cooler assembly according to one embodiment;

[0024] FIG. 5 shows select pump components of a cooler pump, according to one embodiment; and

[0025] FIG. 6 illustrates select electronic components of a cooler assembly according to one embodiment.

DETAILED DESCRIPTION OF ILLUSTRATIVE EMBODIMENTS

[0026] FIG. 1 is a cooler assembly (hereinafter cooler) 100 according to one embodiment. In this embodiment, the cooler 100 includes a thermally insulated container body 101 having a thermally insulated lid portion 102. In this embodiment, the lid portion 102 and an upper portion 110 of the container body 101 are configured to engage with one another, so that the lip portion 102 may be secured onto the container body 101. For example, in this embodiment, first (175) and second (176) elastic handle members are attached to the lid portion. Each handle member includes an aperture configured to engage a respective finger 177, 178 disposed on the container body 101 as illustrated. In this embodiment, the handles may be stretched such that the apertures engage the fingers to hold the lid securely on the container body. An elastomer gasket is disposed in the interface where the lid 102 and container body 101 confront in a closed configuration as illustrated, e.g., in FIG. 1. In a different embodiment, the container body 101 and the lid portion 102 can be formed with cooperating threads so that the lid portion can be threaded onto the upper portion 110 of the container body 101 to form an air-tight seal therebetween.

[0027] In this embodiment, the container body 101 includes a recessed tube channel 103 that extends from a distal pump outlet 108 to a spigot 105. In this embodiment, at least a portion of the recessed channel 103 is configured to frictionally engage and hold a tube 104 that connects the distal pump outlet 108 to the spigot 105. For example, the recessed tube channel 103 can have a diameter C .sub.d as illustrated in FIG. 2 that is equal, or nearly equal to the cross-sectional diameter of the tube 104. Referring to FIG. 3, in this or other embodiments, the partial cross-sectional circumference C .sub.c of the tube channel 103 can be greater at one or more locations than the diameter T .sub.d of the tube 104 such that the tube channel 103 adopts a C shape around the tube 104. In such an embodiment, the tube 104 can be urged into the tube channel 103 and held in place, similar to a snap-fit connection. In this embodiment, the pump output 108 is in the form of a barb connection 122; however, it should be understood that other alternative tube attachments may be used.

[0028] Referring to FIGS. 1-3, in this embodiment the recessed tube channel 103 extends circumferentially around the exterior of the container body 101, such that the tube 104 terminates at spigot 105 at an uppermost tube elevation. In other words, the spigot 105 and the terminal end of tube 104 where the spigot is connected, is disposed above all other portions of the tube 104. This configuration can reduce the likelihood of accidental drainage and formation of bubbles within the tube 104. The wrap-around configuration of the tube 104 also provides a convenient and tidy storage location for the tube 104 and spigot 105.

[0029] In this embodiment, a spigot stowage recess 150 is formed in the combination of the lid portion 102 and the upper portion 110 of the container body 101; a first half 150a of the stowage recess is disposed in the lid portion 102, while a second half 150b of the stowage recess is disposed in the container body 101 as particularly shown in FIG. 2. In embodiments with a screw-on lid, the lid portion 102 can be threaded onto the upper portion 110 until the recess halves 150a, 150b line up to form the spigot stowage recess 150, thereby allowing the spigot 105 to be stored therein. In such an embodiment, lid portion 102 is thereby prevented from being unthreaded (i.e., unscrewed) from the container body 101 when the spigot 105 is firmly engaged within recess 150. In this way, the stored spigot 105 serves to lock the lid portion 102 to the container body 101.

[0030] In this embodiment, like recess channel 103, the spigot stowage recess is configured to frictionally engage the spigot, thereby holding it in place. In one example, the stowage recess 150 can be formed from a semi-malleable plastic that allows a snap-fit between the spigot and the recess 150.

[0031] Referring now to FIGS. 4 and 5, in this embodiment, the cooler 100 includes a battery-operated pump (hereinafter pump) 120. The pump 120 is disposed beneath a floor 160 of the main container 101 such that it is housed in a liquid-proof environment. (For clarity, the floor of the main container 101 is not expressly illustrated in the figures; however, the approximate location is illustrated by the dashed line in FIG. 2.)

[0032] In this embodiment, the pump 120 is configured to receive liquid contents from the main container 101 through an inlet orifice 121 in fluid communication with the main container 101. The inlet orifice 121 can be configured as a direct inlet into the main container 101 or an extension member such as a barb may be used to span the inlet orifice 121 and an inlet aperture of the main container 101. In this embodiment, the pump 120 is further configured to pump the liquid contents received from the inlet orifice 121 to the distal pump outlet 108 with ample force to reach the spigot 105. In this embodiment, the pump 120 is powered by two sets of three rechargeable batteries 115; however, it should be understood that alternative options for powering pump 120 are equally contemplated. For example, pump 120 could be configured to be powered by an AC power source; alternatively, the main container 101 or the lid portion 102, or both, could include one or more solar arrays configured to deliver solar-generated electric current to the batteries 115 for charging.

[0033] In this embodiment, the main container 101 includes a power inlet 113. In this embodiment, the power inlet 113 is configured to receive both 12V and 110V, although other configurations are equally contemplated. The power inlet 113 can be configured to charge the rechargeable batteries 115, power an electronic logic board 130 (discussed below) or

[0034] both. A USB power outlet 107 is configured to provide power output for powering accessory devices such as radios, personal electronic devices, etc. Front plate 111 allows access to the electronics chamber, should the need arise.

[0035] Referring now to FIG. 6, select electronic components of the cooler 100 are illustrated. Other components of the cooler 100 are excluded for the purpose of figure clarity. In this embodiment, the cooler 100 includes an electronic logic board 130. The logic board 130 is configured to receive operating power from the batteries 115 and serves to control operation of the pump 120, among other functions. A main ON/OFF switch 114 is configured to toggle the electronic components of the cooler on and off.

[0036] In this embodiment, the logic board 130 is in electronic signal communication with a micro-pressure switch 164 (illustrated by way of the dashed line in FIG. 6) that is plumbed into the pump outlet 190 via a tee 191 shared between the micro-pressure switch 164 and tube 104 as illustrated. The logic board 130 is configured to activate or deactivate the pump 120 upon receiving certain triggering signals. A first triggering event (signal) can be caused, e.g., by a user depressing the plunger 162 of spigot 105, thereby causing a decrease in pressure within the tube 104. The micro-pressure switch 164 senses the pressure drop and transmits a trigger signal to the logic board 130 to turn the pump 120 on to dispense the contents of the main container 101. When a user subsequently releases the plunger 162 of spigot 105, pressure within the tube 104 rises, causing a second triggering event to turn the pump off. One non-limiting example of a micro-pressure switch that may be used in this and other embodiments is part number XYK-114S-N1-O-005-W-260 available from Yueqing Sencon Electrical Co., Ltd., Yueqing, Zhejiang, China.

[0037] In this embodiment, the logic board 130 is further configured to activate the pump 120 upon detecting a first micro-pressure switch triggering event, and stop the pump upon receiving a second, subsequent micro-pressure switch triggering event. The first triggering event can be, for example, a pressure differential caused by opening the spigot as described; the second triggering event can be, e.g., a subsequent pressure differential caused by closing the spigot. Accordingly, a user may activate the pump 120 to dispense the contents of the main container 101 by opening spigot 105 and stop the pump 120 by closing spigot 105.

[0038] In this and other embodiments, actions of the logic board and components of the cooler (e.g., pump 120) can be controlled by software instructions stored in a memory such as RAM or ROM memory on the logic board. The logic board can also include one or more processors in signal communication with the memory and output channels configured to activate the pump and carry out any other functions of the stored software.

[0039] In this and other embodiments, cooler 100 is operable to dispense any type of liquid from spigot 105 that the pump 120 is capable of pumping. One advantage, of many, of the cooler system 100 is that the main container 101 can be filled with a pre-mixed beverage, such an alcoholic beverage and dispensed easily from any height relative to the user. This advantage eliminates the need to bend down to reach the spigot of traditional gravity-fed coolers disposed on a bottom portion. Another advantage pertains to carbonated beverages such as beer, in that the main container 101 does not need to be pressurized to dispense liquids therefrom. Accordingly, foaming and over-pressurization issues that can occur with kegs can be eliminated.

[0040] A number of illustrative embodiments have been described. Nevertheless, it will be understood that various modifications may be made without departing from the spirit and scope of the various embodiments presented herein. Accordingly, other embodiments are within the scope of the following claims.