US 20100020633 A1
A variety of embodiments of blending containers are shown herein. In one embodiment, the blending container includes a mixing blade that rotates on an axis adjacent to the bottom of the blending container. The blending container includes one or more walls that extend upward from the bottom and a handle secured to the one or more walls. The blending container may be configured so that a vortex created when liquid is blended inside the container is not positioned over the axis. The blending containers may also be configured to stack inside one another.
1. A blending container comprising:
a mixing blade which rotates on an axis;
a bottom positioned below the mixing blade; and
a first wall, a second wall, a third wall, and a fourth wall each of which extends upward from the bottom and is planar;
wherein the first wall faces the third wall and the second wall faces the fourth wall;
wherein an area where the second wall meets the third wall forms an at least substantially right angle, and an area where the third wall meets the fourth wall forms an at least substantially right angle; and
wherein an area where the first wall meets the fourth wall is positioned closer to the axis than the area where the second wall meets the third wall.
2. The blending container of
3. The blending container of
4. The blending container of
5. The blending container of
6. A blending container comprising:
a mixing blade which rotates on an axis;
a bottom positioned below the mixing blade;
a first wall, a second wall, a third wall, and a fourth wall each of which extends upward from the bottom and is planar; and
means for moving the vortex created when liquid is blended inside the blending container away from being over the axis;
wherein the first wall faces the third wall and the second wall faces the fourth wall; and
wherein the second wall meets the third wall at a corner that extends substantially straight up a side of the blending container.
7. The blending container of
8. A stack of blending containers comprising two of the blending containers recited in
9. The blending container of
10. The blending container of
11. The blending container of
12. The blending container of
13. The blending container of
14. The blending container of
15. The blending container of
16. The blending container of
17. The blending container of
This is a continuation of U.S. patent application Ser. No. 11/823,625, filed on 27 Jun. 2007, now pending, which is a continuation of U.S. patent application Ser. No. 11/318,830, filed 26 Dec. 2005, now U.S. Pat. No. 7,281,842, which is a continuation of U.S. patent application Ser. No. 10/947,682, filed 23 Sep. 2004, now U.S. Pat. No. 6,979,117, which is a continuation of U.S. patent application Ser. No. 10/150,919, filed 17 May 2002, U.S. Pat. No. 6,811,303.
This invention relates to blending devices, and more particularly to blending devices capable of high-volume, rapid-succession production of blended beverages.
Food processors and blending devices have existed for many years. One example of a blending device is shown and described in U.S. Pat. No. 5,655,834, which is incorporated in its entirety by this reference.
Food processors and blending machines are being used now more than ever, particularly in the high-volume, commercial beverage industry. People are increasingly becoming aware of the benefits, in terms of taste and quality, of well-processed beverages. Blended fruit smoothies and similar fruit drinks, popular with all types of people ranging from the fitness conscious to the less active, require a food processor or blending machine. Cold beverages, in particular, which utilize fruit (frozen or fresh) and ice to prepare present unique challenges in beverage preparation. An appropriate blending machine will break down the ice, fruit, and other ingredients in attempting to achieve an ideal uniform drink consistency. In addition, food processors or blending machines are ideal for mixing nutritional supplements into beverages while similarly attempting to achieve an ideal uniform drink consistency.
In addition to the recent increase in the popularity of smoothies, food processors and blending machines are being used to produce many new and different beverages. For example, different types of coffees, shakes, dairy drinks, and the like are now commonly served at many different types of retail business locations. Consumers are demanding more diversity and variety in the beverages available at these smoothie and other retail stores. The keys to producing a high quality beverage, irrespective of the specific type of beverage, are quality ingredients and a high quality blending machine that will quickly and efficiently blend the ingredients to produce a drink with uniform consistency.
One problem associated with businesses that depend on blending machines is the speed with which the beverage or drink is prepared. In the food preparation industry, time equals money. Beverages have traditionally been made by retrieving the appropriate ingredients, placing the ingredients inside a mixing container, and actuating a motor which drives a blade mounted inside the mixing container to blend the contents held within the mixing container. Virtually all traditional blending devices require some type of manual programming by tactile actuation (i.e., actuation by the operator's fingertips) of at least one switch, and commonly several switches (particularly where variable speeds are desired), through a key pad or the like to initiate operation of the blending device. Such programming requires focused action by the operator and, as a result, takes up time in the blending process. Each second of time wasted, even a fraction of a second of time wasted, adds up over time to significant amounts of money lost for any commercial operation.
Another problem with respect to prior blending devices relates to safety. While the potential for the beverage ingredients to be hurled all over the place may provide some incentive to place a lid on the mixing container before blending, any additional incentive to maintain a lid on the mixing container during processing will enhance safety.
Still another traditional problem with respect to blending devices relates to cavitation, which occurs when a pocket of air envelops the area surrounding the blade. Efforts are continually being made to design blending devices to reduce cavitation.
Yet another problem with respect to traditional blending devices relates to the type of ingredients that need to be mixed to create an optimal drink consistency, and the ability of the blending device to handle such ingredients. For example, individually quick frozen (IQF) fruit is now commonly used in making smoothies. Most blending devices are simply not capable of appropriately handling IQF fruit to achieve an optimal, uniform consistency.
In view of the foregoing, there is a need to provide a blending station apparatus and method of blending that will allow beverages to be made quickly and efficiently minimizing the overall time required between ordering a beverage and serving the beverage to the customer. There is also a need to provide a blending apparatus and blending method that will minimize the need to program the blending device just prior to actuating the device. There is still further a need to develop a blending device that reduces cavitation. Yet another need exists to provide a blending device with a blade and jar configuration that will produce a beverage with an optimal, uniform consistency with respect to all desired ingredients.
The present invention relates to a blending apparatus which includes an articulable housing that pivots relative to a surface, which may be a stationary base or the surface supporting the blending apparatus, to actuate at least one switch to initiate a blending cycle. As the switch is actuated, by downward pressure exerted on one side of the blending device, the blade mounted inside the mixing container rotates at a first speed. As the articulable housing is rotated further toward the stationary surface, one or more an additional switches may be actuated to causes the blade mounted within the mixing container to rotate at sequentially higher speeds. After the appropriate mixing, and the operator of the blending device releases the downward pressure on the housing, a bias member, such as a coil spring, urges the housing upward away from engagement with the switches to cut off power supplied to the motor and stop blade rotation.
Another aspect of the present invention relates to the internal shape of the mixing container. The mixing container geometry shifts the center of the fluid-flow vortex off-center relative to the rotational axis of the blade. This reduces cavitation which commonly occurs where the fluid-flow vortex is concentric with the axis of rotation of the blending blade.
Still another aspect of the present invention relates to the relative size of the mixing blade and its orientation relative to the sidewalls of the mixing container. The combined geometry of the mixing container in combination with the blade allows all types of ingredients, including IQF fruit, to be blended in the blending device to produce a drink with a desired, uniform consistency.
The foregoing and other features, utilities and advantages of the invention will become apparent from the following detailed description of the invention with reference to the accompanying drawings.
The present invention relates to a blending apparatus 20 which, in one embodiment, the blending apparatus 20 is a stand-alone, portable blending device.
The blending device 20 comprises a stationary base 22 and a motor housing or cover 24 which articulates relative to stationary base 22 to actuate one or more switches which cause the blender to operate. The description of the manner in which one or more switches are actuated is set forth below. The blending device 20 further comprises a mixing container or jar 26 in which a mixing blade 28 is rotatably mounted. The blending device still further comprises a lid 30 which covers the open end of the jar 26 during operation.
The housing or cover 24, as shown in
A plurality of archways 40 are formed in the bottom of housing 24. The archways 40 allow an appropriate amount of air circulation underneath the blending apparatus 20 and about the motor (described below).
With reference to
A plurality of integral, first locking retainers 46 (
The base 22 defines a central well or concave area 60 which provides a space to allow for articulation of the combined switch plate 50/motor 80 (described below) into the well 60. The base 22 further includes an aperture 62 for receiving a power cord 61 (
A plurality of rigid, integral posts 72, 74, 76 extend upwardly from base 22. The posts 72, 74, 76 are oriented opposite switches secured to the articulable housing 24. As described below, the relatively tall post 72 engages a first switch upon articulation of the housing 24 and switch plate 50 relative to the base 22. As the housing 24 and switch plate 50 are further articulated relative to base 22, relatively shorter posts 74, 76 engage other switches to increase the operational speed of the blending apparatus. To ensure that the base 22 fits snugly and appropriately inside of the bottom of housing 24, a plurality of tabs 78 (only one pair are shown) extend outwardly from the main portion of base 22.
While the embodiment of
After the motor 80 has been positioned in its appropriate location inside motor receiving area 81, the entire assembly is urged upwardly into the articulable housing 24 (
The switch plate 50 further defines a plurality of apertures 96, 98, 100 (
To bias the base 22 away from switch plate 50, bias members in the form of a pair of coil springs 114, 116 are disposed inside of appropriately sized pockets 118, 120 (
As shown in
A benefit relative to the present invention is that the switches 102, 104, 106 serve as the actuation switches for the blending device 20. That is, the articulable housing which actuates switches 102, 104, 106 eliminates the need for a power switch. Switches 102, 104, 106 are, in fact, the power switches. Upon return of the housing 24 to its normal position relative to stationary base 22 (which occurs absent any external force on the lid 30/jar 26 combination), power supplied to the motor 80 (
Another benefit of the blending apparatus with an articulable actuation mode include the speed with which beverages can be made. There are no manual buttons or switches that need to be actuated by the fingers of the operator. Rather, as soon as the appropriate ingredients are introduced into the jar 26 (as understood by those skilled in the art), the jar, in combination with the affixed lid 30, is positioned over the upstanding guide extensions on base 24 (
Another unique aspect of the present invention relates to the jar 26. The jar 26 is sized to hold approximately 3 quarts. As shown in
Another novel aspect of the present jar 26 according to the present invention relates to an additional fifth or truncated wall 135 which is positioned opposite handle 140. Walls 132, 134, 136, 138 may be arranged in a generally rectangular, tapered shape. Wall 135 truncates, in essence, the typical corner that would otherwise be formed between wall 132 and 138. As shown in
The unique blade 28 is relatively large, compared to prior art blades. The single blade construction, as compared to traditional cross-blade construction, allows all types of ingredients, such as IQF fruit, to fall between the ends of blade 28 as it rotates to produce a desired, smooth, and consistent texture of beverage.
The jar further includes lower cavities 158 which correspond in size to upstanding guide walls 36 (
The lid 30 more specifically comprises a top surface 160 and a channel 162 which surrounds top surface 160. The channel 162 defines, on the opposite side, a four-wall extension 164 which seats inside of opening 130 upon installation of the lid 30 onto jar 26. A plurality of tabs 166 extend outwardly from each corner of the lid 30 to provide an easy location for grasping the lid and removing the lid after completion of a blending cycle. A plurality of downwardly extending jar retaining walls 170 extend between tabs 166 so that the lid 30, when installed over jar 26, is retained in its desired location.
Another novel aspect of the present invention is that because articulation of the cover 24 relative to stationary base 22 is required to actuate the blending device 20, downward pressure on top surface 160 of lid 30 is generally required. Such downward pressure will urge the downwardly extending walls 164 of the lid 30 toward the inside surfaces of jar opening 130 to seal the lid 30 tightly against jar 26 and prevent liquids from escaping during the blending process. In addition, because downward pressure on lid 30 is required, as a general matter, to articulate the housing 24 relative to stationary base 22, the likelihood of the operator of the blending apparatus 20 inserting his or her hand into opening 130 during the blending process is greatly reduced.
While this invention has been described with reference to certain specific embodiments and examples, it will be recognized by those skilled in the art that many variations are possible without departing from the scope and spirit of this invention. The invention, as described by the claims, is intended to cover all changes and modifications of the invention which do not depart from the spirit of the invention. The words “including” and “having,” as used in the specification, including the claims, shall have the same meaning as the word “comprising.”