CROSS REFERENCE TO RELATED APPLICATIONS This application is a divisional of U.S. patent application Ser. No. 16/548,693, filed Aug. 22, 2019, which is a continuation-in-part of U.S. patent application Ser. No. 16/174,248, filed Oct. 29, 2018, now U.S. Pat. No. 11,419,356, which is a continuation-in-part of U.S. patent application Ser. No. 15/960,383, filed Apr. 23, 2018, now U.S. Pat. No. 10,674,754, all of which are incorporated herein by reference in their entirety.
BACKGROUND This invention relates to a grain popping apparatus and methods of popping grains. More particularly, the invention relates to pod-based systems and methods of preparing popcorn and other popped and puffed grains that remedy the undesirable aspects of existing popping machines and methods.
Popcorn is often made in bags pre-packaged with popcorn that are then heated in a microwave, or in difficult-to-use machines that require manual loading of kernels, flavoring, and oils. Both solutions are less than ideal and achieve inadequate results. For example, it is difficult, if not impossible, to achieve even popping or flavoring of all kernels in microwavable bags. A user must stand next to the microwave to listen for particular popping patterns to try to guess when most of the kernels have popped. As a result, microwaving popcorn results in a high number of unpopped kernels, uneven flavoring, and burning. The interior of the bag is also covered in oil and flavoring, making it undesirable and messy to eat directly from the bag. Portion sizes are also unnecessarily large, which often results in wasted, uneaten popcorn. Existing countertop popping machines are complex to use, requiring manual measuring and loading of ingredients. They are difficult to clean because several parts must be dismantled to clean the entire machine after each use. Finally, because they use bulk flavoring and cooking of kernels, flavor can be uneven and, like microwave popcorn, existing countertop machines frequently result in unpopped kernels, uneven flavoring, and burning.
SUMMARY The present invention resolves the myriad problems associated with existing popcorn popping systems and methods. A grain-popping machine is described that is configured to receive a pod. Each pod includes a plurality of cells, with each cell preferably containing a single grain kernel or seed, flavoring, and a cooking medium such as oil or shortening. In a preferred embodiment, the pod is loaded into the grain-popping machine through a slot so that it is held in position below a heating element. The heating element is activated to begin a popping sequence. When each grain kernel or seed in the pod reaches popping temperature, it absorbs the flavoring in its cell and ejects through the bottom cover of the pod into a bowl positioned in a receiving area of the grain-popping machine. The pod is then removed and disposed of.
The system and methods described herein therefore are easier to use and clean than existing methods of popping grains, avoid burning grains, and provide even flavoring for all grains in the pod.
BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a front view of one embodiment of a grain popping machine according to the present invention;
FIG. 2 is a top view of the grain popping machine of FIG. 1;
FIG. 3 is a perspective view of a grain pod according to one embodiment of the present invention;
FIG. 4 is a top perspective view of the grain pod of FIG. 3;
FIG. 5 is a bottom perspective view of the grain pod of FIG. 3;
FIG. 6 is a perspective view of a grain pod and a heating element;
FIG. 7 is a front and limited interior view of a grain popping machine according to an embodiment of the present invention;
FIG. 8 is a front and limited interior view of a grain popping machine according to another embodiment of the present invention;
FIG. 9 is a bottom perspective view of the grain pod of FIG. 3 illustrating kernels individually exiting the grain pod;
FIGS. 10A and 10B are top perspective and cross-section views, respectively, of the grain pod of FIG. 3;
FIGS. 11A and 11B are top perspective and cross-section views, respectively, of a grain pod according to another embodiment of the present invention;
FIG. 12 is a cross-section view of a grain pod according to another embodiment of the present invention;
FIG. 13 is a cross-section view of a grain pod according to another embodiment of the present invention;
FIG. 14 is another cross-section view of the grain pod of FIG. 13;
FIG. 15 illustrates a grain popping machine and method of popping grains in accordance with another embodiment of the present invention;
FIG. 16 illustrates a grain popping machine and method of popping grains in accordance with another embodiment of the present invention;
FIG. 17 illustrates a grain popping machine and method of popping grains in accordance with another embodiment of the present invention;
FIG. 18 illustrates a perspective view of a grain pod insert or partial grain pod according to another embodiment of the present invention;
FIG. 19 is a cross-section view of a grain pod according to the embodiment shown in FIG. 18;
FIG. 20 is a perspective view of a grain pod according to the embodiment shown in FIG. 18;
FIG. 21 is a bottom perspective view of a grain pod according to the embodiment shown in FIG. 18 with a corresponding heating element 602;
FIG. 22 is a top perspective view of a grain pod according to the embodiment shown in FIG. 18 with a corresponding heating element 602;
FIG. 23 is an exploded side view of a grain pod with separately formed cells;
FIG. 24 is a top perspective view of a docking tray of the grain pod shown in FIG. 23;
FIG. 25 is a side view of the docking tray of FIG. 24 with cells;
FIG. 26 is a top perspective view of a clamshell type grain pod;
FIG. 27 is a side perspective view of a grain pod;
FIG. 28 is a side perspective view of half shell type grain pod;
FIG. 29 is another side perspective view of the grain pod shown in FIG. 28 with grains positioned in the pod;
FIG. 30 is a side view of the grain pod shown in FIG. 28;
FIG. 31 is a side perspective view of a grain pod construction;
FIG. 32 is a top perspective view of a partial grain pod with a honeycomb cell array; and
FIG. 33 is a front and limited interior view of a grain popping machine according to an embodiment of the present invention.
DETAILED DESCRIPTION Turning now to the drawings, in which like reference characters indicate corresponding elements throughout the several views, FIG. 1 is a perspective view of a grain-popping machine 100 according to an embodiment of the present invention. Grain popping machine 100 has an upper chamber 102. Upper chamber 102 includes a pod slot 108, which can be located at various positions on grain popping machine 100. FIG. 1 illustrates two locations on grain popping machine 100 on which pod slot 108 can be formed. While FIG. 1 illustrates two pod slots 108, it is understood that, in most embodiments, only one pod slot 108 would be required. Thus, if the upper location of pod slot 108 is chosen, the lower location would generally not be included. Pod slot 108 can receive grain pods of various shapes and sizes, as will be described in further detail herein.
In the embodiment shown in FIG. 1, pod slot 108 is rectangular. The slot could be in various other shapes in accordance with embodiments of the present invention. For example, the slot could be square, oval, or circular. Pod slot 108 can also be formed in different lengths and widths, regardless of the shape. In other embodiments, pod slot 108 is formed in different locations on upper chamber 102. For example, pod slot 108 could be formed higher or lower on the front face of upper chamber 102 or could be positioned on the side of upper chamber 102. In other embodiments, pod slot 108 is formed on the top surface of upper chamber 102. Pod slot 108 can be configured so that pods can be introduced horizontally into the grain-popping machine 100. In other embodiments, pod slot 108 is angled slightly upward so that pods are introduced into grain popping machine 100 at an angle. Angling pod slot 108 and interior guiding system for the pods allows for gravity to pull the pod down to the desired position within grain popping machine 100, and can also isolate heating elements inside the grain-popping machine 100 from exposure to the pod slot 108. Pod slot 108 can also be formed on the top of grain popping machine 100, and the pod can be inserted vertically, horizontally, or at an angle into the pod slot. Gravity or automated mechanism can be used to pull the pod into the appropriate position within upper chamber 102 in such embodiments, as explained in further detail herein.
A pod dock, not shown, is preferably included inside upper chamber 102 to receive grain pod 300 after the pod has been inserted into upper chamber through pod slot 108. When a grain pod has been inserted into upper chamber 102 through pod slot 108, it is received in the pod dock either through a user pushing the pod fully through the pod dock. Grain popping machine 100 can signal to a user that the pod has been fully received in the correct position in the pod dock through a variety of feedback mechanisms. For example, grain-popping machine can include haptic or audio feedback, for example, a mechanical click or other sound. Visual feedback, for example, a light indicator, could also be provided. Any combination of visual, audio, and haptic feedback can be used. Grain popping machine 100 can also include automatic means of positioning the pod properly in the pod dock. For example, an automated guide can be included inside upper chamber 102. When a user inserts a pod into pod slot 108, grain popping machine 100 senses that a pod has been inserted and activates the automated guide, which mechanically moves the pod into the proper position in the pod dock by, for example, actuating a clamp that grabs the pod and moves it to the proper position.
In other embodiments, a door or tray is provided in upper chamber 102 instead of pod slot 108. Upon activation by a user, the door or tray opens, exposing a pod dock. A user then inserts the pod into the pod dock. When the door or tray is pushed fully closed, the pod dock will be in the proper location in upper chamber 102 below or above a heating element, as discussed in further detail herein. The pod dock may also be positioned to the side of a heating element or in any other orientation, but is preferably positioned adjacent to a heating element. The door or tray may slide out horizontally from upper chamber 102, may swing open vertically, or may swing open pivoting on the lower or upper edges of the door.
Grain popping machine 100 also includes a dock area 103. A receiver 104 is preferably provided with grain popping machine 100. Receiver 104 can be a bowl or cup as shown in FIG. 1, and is designed to receive popped grains exiting from upper chamber 102, as will be described in further detail. The receiver could be made out of various materials and can be disposable or reusable. In some embodiments, receiver 104 is a disposable cup or bowl made of a paper or plastic material. In other embodiments, receiver 104 can be formed of a ceramic or other type of reusable material. Grain popping machine 100 further includes a base 106 and an activation button 110. In a preferred embodiment, activation button 110 is centered along the front top edge of grain popping machine 100. However, it is understood that activation button 110 can be located at other locations on grain popping machine 100. Activation button 110 can physically displace when pressed, providing tactile feedback. In other embodiments, activation button 110 can be a static button that senses touch and provides haptic, visual, or audio feedback when touched. Preferably, grain-popping machine 100 is configured so that activation button 110 is the only physical button on the machine in order to provide for streamlined operation. Grain popping machine 100 can automatically turn on when a grain pod is inserted into pod slot 108, or pressing the activation button 110 can turn on the machine. In either case, pushing activation button 110 after a grain pod has been inserted into pod slot 108 can initiate a popping sequence.
Grain popping machine 100 may not feature any physical buttons and can both power on and initiate a popping sequence by sensing, either mechanically or through motion sensing technology, when a grain pod has been inserted into pod slot 108. A physical button as described above can be included to power on the grain popping machine 100 and the popping sequence can be initiated when a grain pod is inserted into pod slot 108. Grain popping machine 100 can also trigger start up or power on when a pod door opens or closes, or when a plunger is activated.
Grain popping machine 100 is operated by inserting into pod slot 108 a pod of kernels or seeds of various types of poppable grains (corn, for example) or puffable grains (rice, for example). Pod slot 108 is heated inside upper chamber 102 by a heating element, as described in further detail herein. Once the desired heat is reached, the kernels and seeds in the pod pop or puff and can be released from the pod in various ways. The popped grains exit upper chamber 102 through outlet 105 into receiver 104 for consumption by a consumer. As mentioned previously, various types of grains can be popped in grain popping machine 100. In a preferred embodiment, the grain to be popped in grain popping machine 100 is popcorn, however, other types of grains can be popped or puffed in the machine, including quinoa, wheat berries, barley, amaranth, millet, sorghum, rice, and any other grain that pops or puffs at heat or by any other activation method. As used herein, a grain is an individual fruit, kernel, grist, or seed of a cereal or grass crop, whether cultivated or wild.
Grain popping machine 100 can provide lighting and other feedback to guide and optimize the user experience. For example, grain popping machine 100 can be provided with various lighting sources that illuminate in different patterns, different colors, and at different times to signify certain events in the operating cycle of grain popping machine 100 or to signal to a user that action is required. One type of lighting source that can be included on grain popping machine 100 is a horizontal array 112 of light-emitting diodes stretching across the front of grain popping machine 100, as illustrated in FIG. 1. Other types of lighting can be used in place of the light-emitting diodes, as one skilled in the art would appreciate. Activation button 110 and dock area 103 can also be provided with light-emitting diodes or other light sources. Grain popping machine 100 can also include a power switch, which can be provided at various locations on the machine.
As one example of a user experience guided by light sources on grain popping machine 100, a user first switches the power switch to an on position. Powering grain popping machine 100 on results in horizontal array 112 lighting up to display, for example, blue flashing lights that indicate that grain popping machine 100 is running a self-diagnostic start-up procedure. Horizontal array 112 can also progressively illuminate from left to right or right to left to indicate the progress made during the self-diagnostic start-up procedure. Activation button 110 may also light up in, for example, a white light. When the self-diagnostic procedure is complete, activation button 110 and horizontal array 112 illuminate in green to signal to the user that grain popping machine 100 is ready for further interaction. Activation button 110 can flash in either green or white light to draw the user's attention. Prior to a user pressing activation button 110, pod slot 108 may be rendered inoperative to prevent insertion of a grain pod therein. A door may be provided to cover pod slot 108, with the door remaining closed until the machine is ready to accept a grain pod. Other pod receiving methods can be utilized. For example, a slidable tray can be inserted into pod slot 108. The slidable tray can be automatically and mechanically operated by grain popping machine to slide out to receive a grain pod and slide back inside grain popping machine 100 once a pod has been inserted into the appropriate slot on the slidable tray.
When the user presses the flashing activation button 110, pod slot 108 becomes available to the user by, for example, an access door opening to provide access to pod slot 108 for insertion of a pod or a slidable tray sliding out of grain popping machine 100 to accept a grain pod. Pod slot 108 can also be provided with light sources that illuminate green or another color to indicate that grain popping machine 100 is ready for a grain pod to be inserted into pod slot 108. Once a grain pod is inserted into grain popping machine, horizontal array 112 can flash or progressively light from left to right to indicate that grain popping machine 100 is performing an analysis of the inserted grain pod prior to beginning the popping sequence. This analysis can include checking to ensure that the grain pod has been inserted properly, confirming that the grain pod is authentic and not a generic version of a grain pod, and analyzing various coding included on the pod that can provide, for example, popping instructions unique to the particular type of grain pod inserted.
If the pod analysis confirms that the inserted grain pod is permitted to and ready to be popped, horizontal array 112 can present green lighting to indicate that the machine is ready to begin the popping sequence. Activation button 110 can also flash green to indicate readiness to begin popping sequence. If receiver 104 is properly positioned in dock area 103, a user can press activation button 110 to begin the popping sequence. If receiver 104 is not positioned in dock area 103, a light source illuminating dock area 103 can flash or otherwise illuminate dock area 103 and horizontal array 112 can flash to indicate to the user that receiver 104 should be placed in dock area 103. Once receiver 104 is properly positioned, the light source in dock area 103 and horizontal array 112 can show a solid, non-flashing color to indicate that the missing receiver 104 is now recognized. A weight or visual sensor can be included in dock area 103 to detect the presence or absence of receiver 104. The user can press activation button 110 to begin the popping sequence.
Once the popping sequence has begun, horizontal array 112 can progressively light from left to right or right to left to indicate the progress of the popping sequence. Horizontal array 112 can also blink in increasing or decreasing frequency to indicate popping progress. During the popping sequence, activation button 110 may display a red light, blinking or otherwise, which indicates that a user can press activation button 110 to cancel or pause the popping sequence. Once the popping sequence has completed, horizontal array 112 may blink to indicate such to the user. The light source in dock area 103 can also blink or display a green light to indicate that receiver 104, containing the popped grain, can be removed. Horizontal array 112 can display blue lights, progressive, blinking, or solid, to indicate that grain popping machine is cooling. Once cooling has completed, all or some portion of the light sources included on grain popping machine 100 can display a green light indicating that the used grain pod can be removed and that grain popping machine 100 is ready to begin the next popping sequence. While the user interface as described herein references specific colors and lighting patterns, it is understood that the various lighting techniques, lighting combinations, and lighting colors described herein can be used to indicate and stage the user experience.
FIG. 2 shows top view 200 of grain popping machine 100. As shown in FIG. 2, the top 200 of grain popping machine 100 has heat and aroma vents 202, formed therein. The vents 202 can take various forms. In a preferred embodiment, shown in FIG. 2, the heat and aroma vent 202 forms a circle on the outside of top 200. In other embodiments, the entire top 200 of grain machine 100 could have venting slots formed therein. Vents 202 can be formed in various shapes, for example, in the center of the top or along the outer edge of top 200. Vents 202 could also be formed in addition to or in place of vent 202 on the sides of grain popping machine 100. Vent 202 allows heat to escape the upper chamber 102 and also allows popcorn aroma to escape upper chamber 102. In some embodiments, filters are included inside grain popping machine 100, preferably between any heating elements included therein and vents 202. The filters reduce escaping aroma, which is useful in environments where there is a concern that the aroma of popped grains would be distracting. Insulation is also included inside upper chamber 102 in some embodiments. Including insulation reduces the considerable heat generating during popping by isolating the exterior of grain popping machine from heating elements and lowering the temperature of heat escaping through vents 202.
In a preferred embodiment, grain-popping machine 100 includes sensors (not shown) for sensing various parameters that could affect popping. For example, grain-popping machine 100 preferably includes an atmospheric pressure sensor that can provide feedback to the grain popping machine 100 so that cooking times can be adjusted as necessary based on the altitude at which a particular popping sequence is initiated. Other sensors included in grain popping machine 100 include temperature sensors for both ambient air and internal temperatures. Grain popping machine 100 can also include a processor, timer, database, and associated hardware for interpreting and acting on the information provided by the various sensors. The processor is preferably in communication with a network allowing for remote updates to software provided with the processor. This can include a wireless Internet network or cellular network. The processor can include a storage medium and machine-executable instructions stored thereon that cause the grain popping machine 100 to perform various actions, for example, shortening or lengthening popping time, based on pre-set instructions and taking into account information about the surrounding environment gathered by the various sensors. The processor can also include instructions that cause the grain popping machine 100 to vary the heat applied to grain pod 300 by a heating element, the length of time heat is applied to grain pod 300, etc., based on indicators included on the pod or manually or remotely entered by a user. Examples of such indicators and methods of communicating the indicators to grain popping machine 100 are provided below. Grain popping machine 100 can also include audio sensors and corresponding machine-readable instructions to monitor when and how many kernels have popped and adjust the cooking temperature or time based on that audio feedback. Machine learning and artificial intelligence programs can be used to optimize the various sensors.
FIG. 3 shows a preferred embodiment of a grain pod 300. Grain pod 300 includes kernels or seeds of one or more types of grains, as described previously. Although not shown in FIG. 3, in a preferred embodiment the grains are contained in individual cells inside grain pod 300. Grain pod 300 has a top cover 302, a bottom cover 306, and a sidewall 304. Grain pod 300 can be formed of various materials. In a preferred embodiment, grain pod 300 is formed of a high temperature tolerant plastic. In alternate embodiments, grain pod 300 can be formed of various metals, preferably a lightweight metal, for example, aluminum. Grain pod 300 could also be formed of a non-flammable, paper-based material or any other natural or manufactured material that is resistant to high temperatures. In one embodiment, grain pod 300 is between 7 and 12 millimeters tall as measured from the top cover 302 to bottom cover 306. In other embodiments, grain pod 300 is either 9 or 10 millimeters tall between top cover 302 and bottom cover 306. Grain pod 300 can also be formed with additional insulating material between millimeters tall between top cover 302 and bottom cover 306. The insulating material can aid in stacking the pods for storage and shipment and helps to reduce the heat transmitted to the outside of grain pod 300 when it is removed from grain popping machine after a popping sequence has concluded. Grain pod 300 can also be formed with extended tabs on its periphery to aid in handling grain pod 300.
Top cover 302 of grain pod 300 is preferably formed of a heat conductive material. In a preferred embodiment, the top cover 302 is formed of a thin aluminum material or other heat conductive material. Although grain pod 300 is shown in a circular shape, it is understood that various pod shapes could be used to achieve similar results. For example, grain pod 300 could take a square or oval or rectangular form instead of the circular form showed in FIG. 3. Grain pod 300, as shown in FIG. 3, also includes a channel 308 between a raised outer lip 310 and an inner wall 312. Both top cover 302 and bottom cover 306 are sealed to grain pod 300 in order to seal in the grain kernels, flavoring, cooking medium (for example, cooking oils, shortening, lard, etc.) and other edible materials contained inside grain pod 300, as will be shown in further detail herein. Various methods can be used to seal top cover 302 and bottom cover 306 to grain pod 300. For example, the covers can be sealed to grain pod 300 by friction welding, including horizontal friction welding, sonic welding, radio frequency (RF) welding, application of heat, horizontal scrubbing, gluing, folding connecting taps, or spindling, among other methods known in the art, can be used.
Grain pod 300 can include numerous combinations of poppable or puffable grains and various flavorings, or can include kernels or seeds of only one particular type of grain. In preferred embodiments, grain pod 300 includes text, coloring, or graphics, or a combination thereof, to indicate the particular grain or grains inside the grain pod 300 and the flavoring and cooking medium included therein. In other embodiments, grain pod 300 includes a variety of grains, with each grain included having the same flavoring or with different grains in the grain pod 300 having different flavorings. Although not shown in FIG. 3, grain pod 300 may include machine-readable indicators that can communicate to grain popping machine 100 the type of grain or grains in grain pod 300, the flavor or flavors included in grain pod 300, and the type or types of oil, shortening, or other cooking medium included in grain pod 300. In a preferred embodiment, grain pod 300 includes a bar code, QR code, or other type of machine-readable coding pattern that serves as the machine-readable indicator discussed previously. In such embodiments, grain popping machine 100 includes a reader (not shown) for reading the coding pattern included on grain pod 300. The reader can be positioned inside upper chamber 102 or at the entry to pod slot 108. In other embodiments, the reader can be positioned on the outside of grain popping machine 100 so that a user can scan the code on the reader prior to inserting grain pod 300 into grain popping machine 100. The code can be printed on the grain pod 300, can be a textured pattern elevated off the surface of grain pod 300, or could simply be a color pattern on the grain pod. It is understood that the machine-readable code can be positioned anywhere on grain pod 300. However, in a preferred embodiment, the machine-readable code is formed on the bottom of grain pod 300.
In other embodiments, grain pod 300 includes spaced notches or indentations along the periphery thereof that serve as an indicator to grain popping machine 100 of the type of grain or grains in grain pod 300, the flavor or flavors included in grain pod 300, and the type or types of oil, shortening, or other cooking facilitator included in grain pod 300. The notches or indentations can be provided on grain pod 300 in a particular number, with specific distances between each notch or indentation, or in different widths, depths, or shapes, all of which, or a combination of which, can serve as the indicator discussed previously. Similar to the previous embodiment, grain-popping machine 100 can include a reader configured to read and interpret the machine-readable code formed by the notches or indentations, either mechanically, optically, or using any of a variety of sensing methods.
In still other embodiments, grain pod 300 could be formed in different shapes, thicknesses, diameters, widths, and lengths. Small variations in these variables can indicate to a reader on or inside grain popping machine 100 the type of grain or grains in grain pod 300, the flavor or flavors included in grain pod 300, and the type or types of oil, shortening, or other cooking facilitator included in grain pod 300. Alternately, or in addition to, using machine-readable indicators as described above, grain pod 300 can be formed with a simple human-readable code thereon. A human-readable code could also be provided on the packaging of a group of grain pods 300 and recorded at a central website or user guide provided with grain pod 300. In such embodiments, grain-popping machine 100 includes a user interface that allows a user to enter the human-readable code. Alternately, a mobile device application or remote control is provided to allow a user to interface with grain popping machine 100. The mobile device application or remote control could allow the user to perform a variety of functions, including powering on/off grain popping machine 100, initiating a popping sequence, emergency power off, indicating the type of grain or grains in grain pod 300, the flavor or flavors included in grain pod 300, and the type or types of oil, shortening, or other cooking facilitator included in grain pod 300, ordering additional grain pods 300, submitting a help request, submitting a service call, etc.
FIG. 4 shows an exploded view of grain pod 300 with the top cover 302 hovering above the grain pod 300. As shown in FIG. 4, numerous cells 402 are formed on the interior of grain pod 300. Each cell 402 is designed to hold a kernel or seed of a grain, for example, corn. In addition to the kernels, cells 402 hold flavoring and a cooking medium to facilitate popping of the corn when exposed to heat for a prolonged period. As shown in FIG. 4, cells 402 are formed in a generally honeycombed pattern at even distances from each other. As will be described in other embodiments herein, cells 402 could also be formed in circular, square, oval, polygonal, or other shapes. FIG. 4 also shows cell walls 404, which separate cells 402. In other embodiments, cell walls 404 could be thinner or thicker than shown in FIG. 4. In addition, grain pod 300 could be formed without cells and cell walls and instead have one layer of kernels or seeds distributed roughly equally across the interior surface area of grain pod 300. For example, grain pod 300 could be formed with a flat chamber therein to hold kernels in a single layer or multiple layers inside grain pod 300. During manufacturing, grain kernels are placed within cells 402 along with flavoring and cooking medium and any other desired ingredient to enhance the flavor, appearance, or popping qualities of the grain. Once the kernels are inside cells 402, the top 302 is sealed onto grain pod 300.
In a preferred embodiment, grain pod 300 includes approximately 1.5 to 3.5 tablespoons of grains or kernels, with each cell including a single kernel or grain. More preferably, each grain pod 300 includes 2.5 tablespoons of grains or kernels, with the result that each popping sequence produces between 4.5 and 5 ounces of popped grains. However, in other embodiments larger or smaller pods containing additional or fewer kernels or grains can be provided while still retaining the benefits of pod-based popping.
FIG. 5 shows an exploded view from below grain pod 300. As shown in FIG. 5, bottom cover 306 has not yet been affixed to grain pod 300. Bottom cover 306 can be formed of a variety of materials. In a preferred embodiment, bottom cover 306 is formed of a high temperature compatible paper that will allow for easy exit of popped kernels from cells 402. In other embodiments, bottom cover 306 is formed of a lightweight metal foil, preferably aluminum foil. As described in further detail herein, bottom cover 306 can be formed with perforations or other mechanically weakened points to facilitate escape of popped kernels from grain pod 300. Bottom cover 306 could also be formed of a material that weakens as it gets hotter so that the material is weakened once grains reach a certain temperature, thereby allowing the grains to escape from cells 402. As shown in FIG. 5, the sidewall 304 of grain pod 300 may have an inner lip 502 formed on the bottom side thereof. Grain pod 300 may also include a notch 504 on the bottom side of sidewall 304. The mechanical use of inner lip 502 and bottom 504 will be explained in further detail herein.
FIG. 6 shows a heating element 602 positioned above a grain pod 300. Heating element 602 can be formed of a metal ceramic polymer or composite material. Heating element 602 could also be formed of a combination of any of the previously mentioned types of heating elements. In a preferred embodiment, heating element 602 is formed of a metal material such as nichrome. In other embodiments, heating element 602 can be formed of metal such as kanthal or cupronickel. Heating element 602 may also be formed of an etched foil. While heating element 602 is shown as a solid circular slab in FIG. 6, in some embodiments of the invention, heating element 602 could be formed as a collection of wires, ribbons, or strips. Heating element 602 can be covered or sandwiched between layers of materials selected from the mica group of sheet silicates to provide insulation. Heating element 602 can also be or include cartridge heaters. Heating element 602 can be provided in a variety of orientations relative to grain pod 300, i.e., below, above, side-by-side, at an angle etc., provided that heating element 602 is in close enough proximity to grain pod 300 to transfer heat thereto.
Heating element 602, regardless of the material from which it is made, can also be formed in different shapes. For example, it can be formed in a square shape, a rectangular shape, a polygon shape, oval shape, or any non-symmetric shape, and can be formed in various thicknesses. Preferably, the shape of heating element 602 matches that of grain pod 300. This configuration allows for even heating across the surface of grain pod 300, resulting in more even popping of the kernels or grains therein. In addition, heating element 602 could be formed to wrap around grain pod 300 so that grain pod 300 nests within heating element 602, or a second heating element could be provided underneath grain pod 300 for all or a portion of the popping sequence. In such embodiments, the second, lower heating element could be automatically removed at a designated time or point during the popping sequence so as not to interfere with the popped kernels or grains as they exit grain pod 300. The second heating element can be formed with holes aligning with the cells 402 of grain pod 300. When the second heating element is formed with such holes, it can be left in place for the duration of the popping cycle, as the popped grains can pass through the holes in the second heating element and into the receiver 104. It is also understood that more than two heating elements can be used, and that heating elements can be applied from a variety of distances from grain pod 300 and can be positioned at a variety of angles to the grain pod 300.
When two heating elements are included, they can be positioned in a clamshell configuration, such that one or both of the heating elements can pivot at an angle to the other heating element at one or more stages of the popping process. When a clamshell configuration is used, the two heating elements can be physically hinged together or can be held in place relative to each other by other mechanical or vacuum structures inside grain popping machine 100. For example, when the clamshell configuration is implemented such that the two heating elements and grain pod 300 are positioned horizontally within grain popping machine 100, the top heating element can pivot upwards from one point or side to an angle relative to the position of the bottom housing element when the grains are sufficiently heated to a popping temperature or close thereto. When this configuration is used, the popped kernels exit from the top of grain pod 300, deflect off the bottom surface of the top heating element, and down into the receiver 104. Alternately, the bottom heating element in such a configuration can pivot while the grain pod 300 and the top heating element remain in a roughly horizontal position, such that the kernels can exit down from the grain pod 300 and into receiver 104. Similarly, the two heating elements and grain pod 300 can all be positioned at an angle relative to the surface on which grain popping machine 100 sits, and one or both of the heating elements can hinge open when the kernels have reached a desired temperature or when heat has been applied for a pre-determined time.
Heating element 602 can also be formed with cavities corresponding to and aligning with the cells 402 of grain pod 300. The cavities are of a size and shape that allow each cell 402 to partially or completely nest within a cavity formed in the surface of heating element facing grain pod 300. This configuration applies heat to the grains inside cells 402 from a variety of angles instead of only from above or below. Heating element 602 with cavities can be positioned underneath or above grain pod 300. When heating element 602 with cavities is used, grain pod 300 is preferably formed such that the cells 402 protrude at least partially from the body of the pod. One example of such a pod construction is detailed herein with respect to FIG. 12. When heating element 602 with cavities is positioned above the grain pod 300 inside grain popping machine 100, grain pod 300 is preferably formed such that the cells 402 protrude upward instead of downward when positioned inside grain popping machine 100.
In other embodiments, heating element 602 is formed of ceramic heating element such as molybdenum disilicide or various PTC ceramic elements. Heating element 602 could also be formed of polymer PTC heating elements including PTC rubber materials. Heating element 602 may also be a radiative heating element, such as a high-powered incandescent lamp or other type of radiant or infrared heating elements, for example, an R40 reflector lamp or similar lamps. In operation, heating element 602 is placed directly above or in contact with top cover 302 of grain pod 300. As heating element 602 heats to an appropriate temperature depending on the type of grain and other factors, the kernels inside grain pod 300 heat, eventually heating to a temperature at which the specific grain pops and the grains then exit the grain pod 300. In some embodiments, a conductor material, for example, copper, is positioned between heating element 602 and grain pod 300. The conductor material ensures that heat from heating element 602 is evenly applied across the top surface of grain pod 300, and also helps moderate the speed at which maximum cooking temperature is reached.
Positioning heating element 602 above grain pod 300 and configuring grain pod 300 so that popped grains escape grain pod 300 through the bottom cover 306 provides several advantages. For example, allowing the popped grains to exit the bottom cover 306 directly into receiver 104 greatly reduces the surface area of grain popping machine 100 that requires cleaning. Only the relatively small portion of upper chamber 102 between the bottom of grain pod 300 and receiver 104 is contacted by popped grains. That portion of upper chamber is easily reached for cleaning without disassembling grain popping machine 100. In contrast, in prior art systems using free loaded grains instead of pods, the heating element was placed below the grains, so that when the grains popped they would exit up and around a heating element to fall into a bowl. In doing so, the grains contact almost the entire interior surface area of a machine, which must then be dismantled regularly for detailed cleaning and disinfecting. In addition, positioning grain pod 300 below heating element 602 ensures that no popped grains fall back into or on top of grain pod 300 after being popped, thereby reducing the risk of overcooked or burnt kernels, which negatively affect a user's experience. Popped grains exit their particular cell 402 immediately upon popping and are removed from the area of heating element 602 to receiver 104, reducing the chance of overcooking or burning and accommodating for slight variances in popping times between individual grains.
FIG. 7 shows grain-popping machine 100 with heating element 602 and grain pod 300 positioned within upper chamber 102. The circular opening shown in FIG. 7 is included as a window to the inside of upper chamber 102 for purposes of illustration. In preferred embodiments, only pod slot 108 is formed on the exterior of upper chamber 102 so that heating element 602 and grain pod 300 are not visible from the exterior of upper chamber 102. As shown in FIG. 7, heating element 602 is positioned directly above, and in some embodiments, in contact with the top of grain pod 300 inside upper chamber 102. As heating element 602 heats the kernels inside grain pod 300 to a target temperature for a prolonged time, both of which vary depending on the type of grain used, flavoring, cooking medium, and other environmental conditions such as pressure and altitude, the kernels pop and the popping of the kernels causes them to eject from the bottom of grain pod 300 through bottom cover 306, out of upper chamber 102, and into receiver 104. By having the kernels exit grain pod 300 through the bottom, the surface area of upper chamber 102 contacted by popped grains and liquids is kept at a minimum because the popped kernels do not contact any of the other surfaces of upper chamber, which reduces cleaning time and difficulty and makes grain popping machine 100 operate more cleanly than prior art machines. After popping, grain pod 300 is ejected from grain popping machine 100 and can be disposed of in a trash receptacle so that the machine is immediately able to receive another grain pod. The popped kernels can be removed from the grain-popping machine by removing receiver 104, which can serve as a bowl for serving the popped kernels. Preferably, each grain pod 300 includes only enough popped kernels to form a single serving of the particular popped grain chosen. As detailed above with respect to FIG. 1, the popped kernels exit upper chamber 102 through outlet 105, which is open to the bottom of grain pod 300.
Ideal cooking times and temperatures for a particular grain pod 300 vary based on the types of grains, flavorings, and cooking medium included in cells 402, as well as ambient temperature, pressure, altitude, and other variables. As detailed above, grain popping machine 100 can include a processor and associated hardware and software to account for these variables and automatically alter cooking times and temperatures accordingly. However, in preferred embodiments, heating element 602 is heated to between approximately 325 degrees Fahrenheit and 600 degrees Fahrenheit, and more preferably to a constant temperature of 400 degrees Fahrenheit, with a variance of plus or minus 10 degrees. In other embodiments, heating element 602 can vary temperatures during the popping sequence to achieve a max temperature earlier or later in the sequence.
Temperature sensors can also be provided to directly sense the temperature inside cells 402 and the processor can include instructions to dynamically alter the temperature of heating element 602 during a popping sequence to optimize the temperature reached by grains in the cells 402 and ensure that no grains are overcooked or burned. Humidity sensors can also be included in grain popping machine 100, either to measure ambient humidity outside or inside upper chamber 102, or more preferably to measure humidity inside cells 402 to determine whether a predetermined cooking time and temperature should be altered to optimize popping of grains in a particular grain pod 300. In a preferred embodiment, the entire popping sequence is completed in less than one hundred and twenty seconds. More preferably, the popping sequence from insertion of grain pod 300 to the time at which all grains have popped and entered receiver 104 is completed in approximately sixty seconds, or less. In other embodiments, the popping sequence is completed in approximately one hundred and eighty seconds, that is, one hundred eighty seconds plus or minus thirty seconds to accommodate for variables.
FIG. 8 shows an alternate embodiment of grain popping machine 100. In this embodiment, heating element 602 is positioned below grain pod 300. The circular opening shown in FIG. 8 is included as a window to the inside of upper chamber 102 for purposes of illustration. As heating element 602 reaches the temperature to pop the kernels in grain pod 300, the kernels pop and exit the grain pod 300 and are funneled back down by gravity through outlet 105 and into receiver 104, as shown by the arrows in FIG. 8.
Popping grains requires high temperatures, which presents issues for a countertop consumer device. Various methods are contemplated to address this safety issue. For example, whatever configuration of heating elements is chosen, grids or gates can be provided inside grain popping machine 100 to prevent children from contacting the surface of the heating elements if they insert their fingers through pod slot 108 or any other opening to the interior of grain popping machine 100. A safety interlock can also be provided such that a door to pod slot 108 or other pod insertion opening on grain popping machine 100 can only be opened when a pod is being inserted, with no extra space for insertion of fingers or other body parts. Child proof safety switches can also be provided to prevent access to or operation of grain popping machine when the safety switch has not been manipulated into a position that allows such access or operation. All openings to the interior of grain popping machine 100 can also be automatically disabled when the temperature inside the machine is above a safe level, and the opening can be automatically made functional again once the temperature has dropped below a safe level. Various methods can be used to more quickly cool grain popping machine 100 and heating elements 602 after a popping cycle. For example, heat sinks or heat pipes can be used to remove heat from heating elements 602. Cooling fluid can also be circulated over or around heating elements 602 to accelerate cooling. Because grain popping machine 100 may be heavier towards the top than at the bottom, a heat sink can be positioned under the receiving tray to balance the weight distribution while providing cooling.
FIG. 9 illustrates popped kernels 902 exiting through bottom cover 306 of grain pod 300. The orientation of heating element 602 above grain pod 300 is similar to the orientation shown in the grain-popping machine of FIG. 7. Because each cell 402 contains a single kernel, each kernel is free to pop when that particular kernel reaches the appropriate temperature for the particular kernel. This allows for slight variations in the popping time for different kernels in the same grain pod 300 so that kernels that might pop earlier than other kernels are not burned by being kept in contact with a heat source after popping.
FIGS. 10A and 10B illustrate a preferred embodiment of grain pod 300. As shown in FIG. 10A, grain pod 300 is formed in a generally circular or cylindrical shape with cells 402 and cell walls 404. The cells of the grain pod shown in FIG. 10A are formed in a hexagonal shape similar to a honeycomb. In a preferred embodiment, the cells 402 shown in FIG. 10A are sized to hold a single grain seed or kernel in addition to any desired flavoring or cooking medium. As the kernels heat and pop, they absorb the flavoring placed in the cells. The cooking medium can be an oil infused with a flavor or combination of flavors, or dry flavoring can be added separately to the cell prior to sealing. Instead of or in addition to providing flavoring inside each cell 402, flavoring can be added as or after the popped grains exit cells 402. The post-exit flavoring can be achieved by a misting or spraying device that ejects flavoring, either dry or liquid, onto the popped grains as they exit the pod or after they have been received in receiver 104. The misting or spraying device can be automatic, i.e., it can operate without user intervention, or controls can be provided to allow a user to active the device to add the desired flavoring. Flavoring shakers or packets can also be provided separately with grain popping machine 100 to allow a user to customize flavoring.
FIG. 10B shows a cross-section of FIG. 10A, showing the vertical shape of cell walls 404. As shown in FIG. 10B, each cell is formed so that it is narrower towards the top cover 302 of grain pod 300 and becomes wider moving towards bottom cover 306. As the kernel is heated by heating element 602 and eventually reaches its popping temperature, the kernel expands, or pops. As the kernel expands, the shape of cells 402 in FIG. 10B apply pressure to the portion of the kernel towards top cover 302, thereby ejecting the popped kernel through the bottom cover 306 of grain pod 300. The change in diameter or width of cells 404 from the top of grain pod 300 to the bottom of grain pod 300 can be altered to achieve more or less pressure on the kernel in the pod upon popping. The vertical angle of cell walls 404, shown in FIG. 10B, are preferably between 1 and 45 degrees. More preferably, the angle is between 6 and 16 degrees, and most preferably approximately 9 to 11 degrees. The angling of cell walls 404 direct much of the energy created by a popping grain towards the bottom cover 306 to increase the pressure on the material forming bottom cover 306. In addition to or in place of angling, the shape of the cells can include a conical section, a conical section with the flat bottom, a parabola with the wider portion positioned toward bottom cover 306, or any combination of the above. The angling can be reversed for grain pods where exit through top cover 302 is desired. Cells 404 can also be formed to have the same, or substantially the same, that is, within acceptable manufacturing variations, diameters and widths from the top of the grain pod 300 to the bottom of grain pod 300.
FIG. 10B also illustrates an alternate embodiment of sidewall 304. As shown in FIG. 10B, raised lip 310 of sidewall 304 extends upward from the top of grain pod 300. Sidewall 304 is formed with a notch 1002 towards the bottom thereof. When grain pods 300 are stacked in a package containing multiple grain pods, upper lip 310 rests inside notch 1002 to secure the stacked grain pods together and to provide a resting surface for the pods so that the top and bottom covers of grain pods 300 stacked together in a package remain slightly apart from each other. This helps prevent breakage or damage to of the top and bottom cover during shipping, delivery, and storage of grain pods 300.
FIGS. 11A and 11B illustrate another embodiment of grain pod 300. As shown in FIG. 11A, the cells 402 are circular when viewed from the top. Cell walls 404 divide the cells 402. FIG. 11B shows a cross-section of the grain pod 300 illustrated in FIG. 11A. As with the grain pod 300 shown in FIGS. 10A and 10B, the cells 402 of the FIG. 11B grain pod are wider towards the bottom of the grain pod than they are at the top. The cell walls 404 are slightly curved so that each cell is generally in the shape an inverted U with the open part of the U facing the bottom of grain pod 300 and being wider than the diameter of the bottom of the U, which is positioned near or in contact with top cover 302 of the grain pod. As with the embodiments shown in FIGS. 10A and 10B, the grain pod 300 shown in FIGS. 11A and 11B feature a raised upper lip 310 and a notch 1002 in the bottom of the sidewall. These features, as described above, aid in stacking packaging and delivering the grain pods.
FIG. 12 illustrates a cross-section of another embodiment of grain pod 300. The grain pod shown in FIG. 12 is similar to the previously described grain pods, with the exception that the cells are approximately half as high as the cells of the previous embodiments. As a result, the grains or kernels placed in each cell protrude, at least partially, from the cell out from the bottom of the grain pod 300. The grains are still sealed into the cells by a bottom cover, but in this embodiment the bottom cover is, preferably, a flexible membrane 1204 that holds the grain kernels in their cells 402 and seals each cell off from other cells 402, but that conforms to the shape of the kernels protruding from the cells 402. The grain pod 300 shown in FIG. 12 also features an extended inner lip 1202, which extends slightly beyond the lowest point of flexible membrane 1204. The extended inner lip 1202 rests on the top of the sidewall so that when the pods are stacked, the membrane cover 1204 does not make contact with the top cover 302 of grain pod 300. In doing so, the extended inner lip 1202 prevents unwanted tearing or damage to the flexible membrane 1204 or top cover 302 during packaging, shipment, delivery, and storage. Configuring the cells so that they are less deep than the height required to accommodate a full kernel aids in ejecting the kernels from the cells as they pop. Because they are already partially out, the pressure created by the open cells facilitates the kernels breaking through the flexible membrane 1204 as they pop. Ideally, fifty percent or more of the kernel protrudes from cells 402. Configuring grain pod 300 such that between sixty and seventy-five percent of the kernel protrudes from cell 402 further aids ejection of the kernels from the cells and can also provide heating advantages, as discussed elsewhere herein. The cells 402 may also be shaped so that they have a wider diameter towards the flexible membrane 1204 of grain pod 300 than towards the top cover 302. It is understood that various cell shapes and sizes can be used with the flexible membrane shown in 1204, and that various materials and manufacturing methods, as discussed elsewhere herein, can be used to form the grain pod 300 illustrated in FIG. 12.
FIG. 13 illustrates another embodiment of grain pod 300. As shown in FIG. 13, the cells 402 have a bulbous shape, but still with the top portion of the cells 402 closest to top cover 302 being narrower than the bottom portion of cells 402. Again, as in previous embodiments, this encourages the kernel to exit the pod downward as it pops. Also shown in FIG. 13 are a series of perforations or weakened areas 1306 in the bottom cover 306 of grain pod 300. In a preferred embodiment, these perforations allow the bottom cover 306 to tear as the kernel pops and exits the bottom cover 306. As shown in FIG. 14, for example, the bottom cover is easier to pierce by the kernel than if it did not have a perforation. Embodiments of these weakened areas will be described in further detail with respect to FIG. 14. Also shown in FIG. 13 is an alternate embodiment of the stacking and mating systems described earlier. As seen in FIG. 13, inner lip 502 extends downward, creating a male mating end, and channel 308 on the top portion of grain pod 300 is adapted to receive the inner lip 502.
FIG. 14 illustrates various methods of weakening bottom cover 306 of grain pod 300 so that the kernels can more easily break through the bottom cover 306. The kernel designated as 1404 has exited through the bottom cover 306. The portion of bottom cover 306 next to the cell that kernel 1404 is exiting from has been weakened, either mechanically or by other means, approximately in the center of the cell 402, so that when the kernel breaks through bottom cover 306, the bottom cover 306 splits approximately in the middle of the cell and the edges of the bottom cover 306 remain attached to the top of cell walls 404 so that the material that forms the bottom cover 306 does not exit into the receiver 104. The material of the bottom cover 306 thereby stays attached to the grain pod 300 instead of falling into the receiver 104 with the popped grain. Similar results are achieved if a flexible membrane 1204 is used.
In another embodiment, as shown with reference to kernel 1402 in FIG. 14, the bottom cover 306 can be weakened, for example, by physical perforations or other weakening, along only one side or portion of a cell 402. In operation, this is similar to the perforation described with respect to kernel 1404, except that instead of the ripped pieces of the bottom cover 306 remaining attached to all sides of the cell walls 404, the bottom cover 306 may be held to only a portion of the top of cell walls 404. For example, one half of the bottom cover corresponding to a particular cell 402 may remain attached to the cell walls 404, while the other half may be pre-perforated or otherwise weakened so that it breaks off, easily allowing the kernel to escape when it pops. Although thus far discussion of weakening the bottom cover 306 has focused mostly on physical perforation of the bottom cover 306, that is merely one example of potential ways to weaken portions of the bottom cover 306 to facilitate escape of a kernel. Instead of perforating at particular locations, the bottom cover could be formed of a thinner material at those particular locations or it could be formed of a different material at those locations that weakens faster than the main body of bottom cover 306 as temperature increases. In other embodiments, the material that fastens bottom cover 306 to the top of cell walls 404 may be varied at certain locations in order to facilitate breaking of the bottom cover 306. For example, a portion of the material bonding bottom cover 306 to the cell walls 404 could be a different bonding material than other portions. The bonding material in the weakened portions might be chosen so that it melts and creates a weaker bond at higher temperature than other portions of the bonding material to achieve similar results to perforation or mechanical weakening. For embodiments that feature mechanical perforation, or some other type of mechanical weakening of bottom cover 306, various methods can be used to achieve that perforation. For example, the bottom cover 306 could be pre-perforated during manufacturing and before shipment. In alternate embodiments the grain-popping machine 100 can be formed with a mechanical perforator or weakener inside, so that when a user inserts grain pod 300 into grain popping machine 100, the bottom cover 306 of grain pod 300 is perforated in grain popping machine 100 or during insertion into the grain-popping machine 100.
FIGS. 15-17 illustrate alternate embodiments of grain popping machine 100 according to the present invention. In FIG. 15, grain pod 300 is positioned inside grain popping machine 100 so that it is above heating element 602 instead of below heating element 602. Grain pod 300 is flipped from the configuration shown in previous embodiments where the kernel exits from the bottom of grain pod 300. In the embodiment shown in FIG. 15 of the grain pod 300, the kernels exit towards the top of the grain-popping machine 100 instead of straight down. As heating element 602 heats the kernels within grain pod 300 to the appropriate temperature for that particular grain, the grains would pop; exiting the grain pod 300, and gravity causes the popped kernels to fall down into receiver 104, as shown in step 1504. In the embodiment shown in FIG. 15, a fan, preferably a silent fan, could be used to help the kernels exit the grain pod 300 and filter down to receiver 104. Once the receiver 104 is full of the popped grains, it can be removed from dock 103 as shown in step 1506.
FIG. 16 shows another embodiment of grain popping machine 100. In the embodiment in FIG. 16, grain pod 300 is positioned inside the machine above heating element 602 instead of below. As shown in step 1602, grain pod 300 is configured so that as the grains pop, the grain pod expands and the sidewall 304 of the grain pod expands. Once the grains have popped, the heating element is mechanically removed, preferably automatically, from underneath grain pod 300. The bottom of grain pod 300 is pulled with heating element and the popped kernels are pulled by gravity into the receiver 104 and can then be removed from the dock 103, as shown in step 1608.
FIG. 17 shows another embodiment of grain popping machine 100 according to the present invention. In FIG. 17, grain pod 300 is inserted into grain popping machine 100 so that it is positioned above heating element 602. As heating element 602 heats the kernels in grain pod 300 to the popping temperature, grain pod 300 expands into a bucket shape. The bucket formed by the grain pod 300 in this embodiment serves as a receiver 104 and grain pod 300 itself, in its bucket shape, can be removed from grain popping machine 100 for serving the popped grains. As shown in step 1706, heating element 602 is mechanically moved, in some embodiments, from the bottom of grain pod 300, and a cooling fan cools the expanded grain pod 300 so that it is safe for handling by a consumer. It is understood that grain pod 300 shown in FIG. 17 could take various shapes on expansion and is not strictly confined to the shape shown in FIG. 17.
FIG. 18 illustrates a portion of a grain pod insert 401. Grain pod insert 401 is preferably formed of a thermoplastic polymer, although other materials compatible with use in the food industry can be used. Various types of polymers are contemplated for grain pod insert 401, including natural polymers and synthetic thermoplastic polymers, including but not limited to nylon. Additives can be included in the polymers used to form grain pod insert 401.
Grain pod insert 401 includes cells 402 and cell walls 404 similar to those described with respect to other embodiments of the present invention. As shown in FIG. 18, cells 402 are formed with a generally circular cross section and a rounded bottom. However, it is understood that cells 402 could be formed in a variety of cross-sectional shapes, including, but not limited to, the hexagonal and square cross-sectional shapes described with respect to other embodiments herein. Cells 402 could also be formed with a flat bottom instead of the rounded bottom shown in FIG. 18. Because grain pod insert 401 is preferably formed of a polymer, e.g., a nylon material, it can be formed by heating a flat sheet of polymer to a temperature at which the polymer can be stretched into the form shown in FIG. 18 by application of mechanical force to the polymer sheet. For example, grain pod insert 401 can be formed partially or completely through the use of thermoforming. Grain pod insert could also be formed by directly applying the polymer sheet to an array of grains. When this method is used, the polymer sheet stretches closely around the shape of each individual grain. When top cover is applied over the stretched polymer sheet, closed cells 402 are formed around the grain, with little, if any, airspace within the cells. Vacuum sealing could be used to remove all air from cells 402 formed in this manner. Forming grain pod insert 401 in this manner simplifies manufacturing. In addition, polymers such as nylon are known to weaken as they are heated, and through polymer compounding, which involves mixing or blending polymers and additives to alter certain properties of the resulting material, the polymers can be engineered to reach a desired weakness at desired temperatures. As a result, a grain pod 300 constructed with grain pod insert 401 does not require a bottom cover 306. The cells 402 of grain pod insert 401 are closed at the bottom portion thereof, which serves to retain grains, flavoring, and cooking medium within the cells 402. The polymer forming grain pod insert 401 is engineered to weaken to near breaking point at the ambient temperature at which grains contained in cells 402 will being to pop. As a result, the popping grains can easily break through the bottom of cells 402, while unpopped grains remain in their cell 402 until they begin to pop.
It is understood that grain pod insert 401 and grain pod 300, which is described with reference to other figures herein, could also be formed using extrusion or injection molding. Formable foils can also be used to form grain pod insert 401, with similar benefits to those described with respect to FIG. 18. For example, cold formable foils, e.g., cold formable aluminum foil, can be used to form grain pod insert 401 and grain pod 300. Foils can allow for more efficient heat transfer between heating element 602 and grains in cells 402. The thickness of the foil can be chosen such that the force of the popping grain tears the foil, permitting the popped grain to escape through the foil. The use of formable foils can eliminate the need for a bottom cover on grain pod insert 401 or grain pod 300. Grain pod insert 401 and grain pods 300 described herein could also be made from thermoforming, aluminum stamping, or other suitable methods of manufacture.
FIG. 19 is a cross-sectional view of a grain pod 300 formed with grain pod insert 401. After it is formed, grain pod insert 401 can be attached to a sidewall 304 by various methods known in the art. Grain pod 300 as shown in FIG. 19 can also be formed as a single piece using the same methods detailed with respect to grain pod insert 401, that is, by heating and mechanically manipulating a polymer, or by extrusion or injection molding. Attaching grain pod insert 401 to a separately formed sidewall 304 in order to form grain pod 300 allows for a different material to be used for the sidewall 304. It can be desirable to use a stronger and less heat-sensitive material for the sidewall 304, which is subject to forces during shipping and user manipulation that grain pod insert 401 may not experience. FIG. 20 is a top perspective view of the grain pod 300 described with respect to FIGS. 18 and 19. As noted above, grain pod insert 401 may be formed separately and attached to sidewall 304, or the entire grain pod 300 can be formed as a single unit. As shown in FIG. 20, grain pod 300 can include a tab 2001 formed with or attached to sidewall 304. Tab 2001 facilitates user handling of grain pod 300.
FIG. 21 illustrates grain pod 300 as described with respect to FIGS. 18-20 with a heating element 602. As shown, heating element 602 has protrusions 2101 extending from its bottom surface. Protrusions 2101 provide targeted heating to cells 302. Preferably, protrusions 2101 match the cross-sectional shape of cells 402, here, a circular shape. In addition, protrusions 2101 are arranged on heating element 602 such that, when grain pod 300 is positioned in a pod dock, described herein, protrusions 2101 are positioned so that each protrusion 2101 is centered on a cell 402, thereby providing targeted heat to the opening at the top of each cell 402. In operation, heating element 602 can be mechanically lowered onto the top of grain pod 300 so that protrusions 2101 press down onto top cover 302 (not shown). Heating element 602 and grain pod 300 can also be held together by applying a vacuum, thereby ensuring a firm seal. The portions of top cover 302 directly above each cell 402 can be formed to depress into the cell 402 as the protrusions 2101 on heating element 602 apply pressure to top cover 302. This provides more focused and direct heat transfer from heating element 602 because heat is applied in closer proximity to the grains and cooking medium in each cell 402. The contents of cells 402 can also be vacuum sealed, so that heat from protrusions 2101 transfers directly through top cover 302 and is applied directly to the grains and cooking medium in the cells 402.
FIG. 22 illustrates heating element 602 positioned above grain pod 300, with the top cover 302 covering the top of cells 402. However, heating element 602 with protrusions can also be positioned below grain pod 300, and two heating elements, one positioned above and one positioned below the grain pod 300, can be used, with one or both having protrusions or cavities.
Instead of protrusions extending from the main body of heating element 602, as depicted in FIG. 21, a plurality of separate, unconnected, heating elements can be used. For example, each protrusion 2101 could be a separate heating element, such that each cell 402 can be heated by an individually-controllable heating element. Such an array of heating elements allows for pinpoint heating control depending on variables such as position of the cell 402 in the cell array. For example, cells 402 on the interior of grain pod 300 may heat faster than cells 402 on the periphery of grain pod 300 when the heating element 602 and grain pod 300 are arranged horizontally inside grain popping machine 100. Using individually-controllable heating elements allows more control of temperature distribution. For example, the temperature of each individual heating element can be pre-programmed to vary during each popping cycle such that the grains in interior cells are heating at roughly the same rate and to roughly the same temperature as the grain in peripheral cells, helping to ensure even popping and prevent burning of the grains. Similarly, the plurality of individual heating elements can each be formed with a cavity, as with the unitary heating element with cavities described above with respect to FIG. 6. In such configurations, the cavities can be formed to roughly approximate the shape of cells 402 such that each cell 402 is at least partially inside a cavity during the popping process.
FIG. 23 illustrates a grain pod 300 formed from a metal. Preferably grain pod 300 is formed of a malleable metal foil, for example, aluminum foil, copper foil, or tin foil, though other foldable metals and metal foils can be used. The cells 402 of this grain pod 300 are formed as separate pockets of the same material, each made to receive one grain. Cells 402 are independent of each other, and each is preferably formed by folding or forming a single piece of foil into a shape that is sufficient to hold a single grain. The single piece of foil used to form each cell 402 is preferably circular in shape, though by overlapping portions of the piece of foil the desired cell shape and dimensions can be achieved by folding a sheet of foil that was originally other shapes, e.g., rectangular, square, polygonal, triangular, etc. Cells 402 can be formed by using a press and mold, whereby pressure on the piece of foil around the pre-formed mold causes the foil to bend around the mold into the desired shape. While FIG. 23 illustrates cells 402 in a roughly conical shape, cells 402 can be formed in a variety of shapes consistent with the purposes of grain popping machine 100. The cells can be more or less rounded at the lower ends thereof compared to cells 402 as illustrated in FIG. 23. For example, cells 402 could be squared off at the bottom thereof, or could be formed in a semi-sphere shape. Moreover, while cells 402 as shown in FIG. 23 are circular in horizontal cross-section, they can be formed with a square, rectangle, or polygonal cross-section or any other cross-sectional shape and dimension discussed herein with respect to other grain pod forms. The foil forming cells 402 is selected such that the force of a grain expanding inside each cell 402 is sufficient to tear the foil open, allowing the grain to escape as or immediately before it pops.
During assembly, the individual cells 402 shown in FIG. 23 are placed into a docking tray 2304. Openings 2305 are formed in docking tray 2304. Each opening 2305 is sized to receive a cell 402. Preferably, the horizontal cross-sectional diameter of cells 402 increases from the bottom portion 2308 to lip 2302 of the cell such that an entire cell 402 cannot pass fully through the opening 2305, but instead hangs from docking tray 2304. Lip 2302 of cell 402 can have a larger diameter than the body of cell 402 so that when cell 402 is placed through opening 2305 bottom first, the lip rests on the top surface 2402 of docking tray 2304, as shown in FIG. 24. Lip 2302 can be sealed or attached to the top surface 2402, which is also preferably formed of a metal, e.g., aluminum foil, by a variety of methods described elsewhere herein. In addition to, or instead of, attaching lip 2302 to top surface 2402, a separate sealing sheet 2306 can be used to sandwich lips 2302 between docking tray 2304 and sealing sheet 2306. Sealing sheet 2306, which is also preferably formed of a metal, e.g., aluminum foil, can be attached to lips 2302 or docking tray 2304, or both, by a variety of methods described elsewhere herein. Sealing sheet 2306 can be formed with openings 2307 corresponding to openings 2305 on docking tray 2304. Grain pod 300, as shown in FIG. 23, can also be formed without sealing sheet 2306. A top cover, which is also preferably formed of a metal, e.g., aluminum foil, is attached to sealing sheet 2306 or directly to docking tray 2304, and functions in the manner described herein with respect to other top covers for grain pods 300 described herein. Sheets 3102 formed of high temperature pressure sensitive adhesive, for example, acrylic adhesives, silicone, or other high temperature adhesives, can be used to attach the various layers of metal, e.g., aluminum, together, as shown in FIG. 31. High temperature pressure sensitive adhesive sheets 3102 can also be used to attach metal layers in the other grain pods described herein.
FIG. 24 illustrates a top view of docking tray 2304 as described with reference to FIG. 23. As shown in FIG. 24, lips 2302 of formed cells 402 rest on the top surface of docking tray 2304. Lips 2302 can be attached to docking tray 2304 by friction welding, including horizontal friction welding, sonic welding, radio frequency (RF) welding, application of heat, horizontal scrubbing, gluing, folding connecting taps, or spindling, among other methods known in the art, can be used. As discussed above with reference to FIG. 23, a sealing sheet 2306 or top cover 302 can be used instead of or in addition to direct attachment of lips 2302 to docking tray 2304. FIG. 25 is a side view of grain pod 300 as described with reference to FIGS. 23 and 24. As shown in FIG. 25, individual cells 402 hang from docking tray 2304.
FIG. 26 illustrates a clamshell type grain pod 2600. As shown in FIG. 26, top cover 2601 is attached to the top surface of tray 2604 along one side. Cells 2602 are formed or provided in tray 2604 according to any of the various methods described herein, and grain pod 2600 can be formed of any of the various materials discussed herein with reference to other figures. For example, cells 2602 could be formed integrally with tray 2604 or could be individual pod cells as described herein with reference to FIGS. 23-25. The clamshell design of grain pod 2600 facilitates manufacturing by simplifying the process of sealing top cover 2601 to the top surface of tray 2604.
FIG. 27 illustrates a grain pod 2700. As shown in FIG. 2, grain pod 2700 includes a top cover 2701, cells 2702, which are formed or provided in tray 2704 according to any of the various methods described herein. Grain pod 2700 can be formed of any of the various materials discussed herein with reference to other figures. For example, cells 2702 could be formed integrally with tray 2704 or could be individual pod cells as described herein with reference to FIGS. 23-25. Cells 2702 are fully cylindrical in construction, with approximately the same diameter from top to bottom of each cell. Cells 2702 can be manufactured by forming the cylindrical walls 2703 out of one piece of material and then fixing an end cap 2705 to one end of the cylindrical walls 2703 to close off that end.
FIG. 28 illustrates a half shell type grain pod 2800. As shown in FIG. 28, grain pod 2800 is formed of a top piece 2801 and bottom piece 2804. Unlike most of the other grain pods described herein, which have full cells formed or affixed to a tray, the cells of grain pod 2800 are formed when top piece 2801 is attached to bottom piece 2804. Each piece is formed with a plurality of partial cells 2806 that align with corresponding partial cells 2806 on the other piece such that when top piece 2801 is aligned with and affixed to bottom piece 2804, a plurality of cells are formed, each large enough to receive a grain, flavoring, and a cooking medium. In manufacture, a grain is placed in each of the partial cells of bottom piece 2804 along with flavoring and a cooking medium, and then top piece 2801 is affixed to bottom piece 2804 to enclose the grain, flavoring, and cooking medium and form a full cell. At the time when top piece 2801 is affixed to bottom piece 2804, grains 2807 can be protruding from partial cells 2806 in bottom piece 2804, as shown in FIG. 29. FIG. 30 shows a side view of an assembled grain pod 2800, in which top piece 2801 has been affixed to bottom piece 2806, thereby creating full cells 3002 composed of partial cells 2806 from each of top piece 2801 and bottom piece 2804. As illustrated in FIGS. 28-30, each full cell 3002 is comprised of two evenly sized partial cells 2806, one from bottom piece 2804 and one from top piece 2801, hence the reference to a half shell grain pod. However, it is understood that the size and volume of partial cells 2806 on bottom piece 2804 can be larger or smaller than the size and volume, respectively, of partial cells 2806 on top piece 2801. For example, partial cells 2806 formed in bottom piece 2804 could form three quarters of the full volume of each full cell 3002. It is also understood that full cells 3002 can be formed in a variety of shapes and dimensions, as described herein with reference to other grain pods. It is also understood that bottom piece 2804 and top piece 2801 can be formed from any of the materials disclosed herein for forming the various described grain pods, and can be affixed to each using the various methods described herein with respect to other grain pods. For example, partial cells 2806 can be formed separately from aluminum or other foils and then attached to bottom piece 2804 and top piece 2801.
FIG. 32 illustrates a partial grain pod 3200. As with other grain pods described herein, partial grain pod 3200 includes a plurality of cells 402 adapted to receive grains, flavoring, and a cooking medium. In partial grain pod 3200, cells are formed by creating a grid 3202 of a metal material, preferably aluminum foil. Grid 3202 is formed by cutting the foil into strips and folding the strips to form walls that, when combined with other strips to form a generally honeycomb shape as shown in FIG. 32, form cells 402. A bottom cover 306 closes off the bottom of cells 402, and a top cover, not shown, closes off the top of cells 402. Grid 3202 can be formed from other materials instead of metals. For example, grid 3202 can be formed of paper-based materials, plastics, etc. Bottom cover 306 and any top cover provided with partial grain pod 3200 can be formed of any of the materials disclosed herein with reference to other grain pods, and can be formed of a different material than grid 3202.
FIG. 33 shows grain-popping machine 3300 similar the grain popping machine shown in FIG. 7, but with a different heating system. Instead of heating element 102, grain-popping machine 3300 uses a heating chamber 3302 to apply heat to grain pod 3301. Grain pod 3301 can be inserted into grain-popping machine 3300 in a variety of ways, as described previously. Grain pod 3301 can be inserted into grain-popping machine 3300 such that the majority of grain pod 3301 is positioned inside heating chamber 3302 and only, or substantially only, a bottom cover 3306 of grain pod 3301 extends from the bottom of heating chamber 3302. Grain pod 3301 can include lips 3308 that contact the lower exterior surface 3310 of heating chamber 3302. Such a construction aids in preventing heat from escaping heating chamber 3302 during the popping process.
Lower exterior surface 3310 of heating chamber 3302 can be formed with holes sized to receive cells 402, such that each cell 402 extends through an individual hole in the lower exterior surface 3310 instead of all cells 420 extending into heating chamber 3302 through a single large opening. For example, grain pod 3301 can be formed in the manner described with respect to FIGS. 23 and 24 herein. Docking tray 2304 can be inserted into grain popping machine 3300 such that each cell 402 is disposed completely, or substantially completely, inside heating chamber 3302, with only the surface of the docking tray 2304 being positioned outside heating chamber 3302. In this manner, heat is applied evenly around each cell 402 during the popping cycle. Grain pod 3301 can also be formed consistent with other grain pods described herein. In addition to faster and more even heating, the use of heating chamber 3302 with the described hearing methods results in a pod surface that is cooler to the touch and therefore safer for consumers. Grain pod 3301 can be mated with heating chamber 3302 using a variety of mechanisms, both automated and manual, as described herein with reference to other constructions of grain popping machines.
Heating chamber 3302 can be heated by a variety of heat sources. For example, a resistive heating source, also known as a Joule or Ohmic heating, can be used. The heating source can also be electromagnetic, radio frequency, inductive, electronic, high frequency, microwave, or dielectric heating. These heating sources can heat kernels 3307 to the required popping temperature faster than other heat sources and can also provide more even heating of kernels 3307. These heating sources can be located external to heating chamber 3302, and a variety of methods can be used to transmit energy from the heating sources into heating chamber 3302. For example, energy from the heating sources can be transmitted into heating chamber 3302 by mechanical waveguide, antenna, or electrodes. If electrodes are used, they can be positioned in parallel or not in parallel.
As heating chamber 3302 heats the kernels inside grain pod 3301 to a target temperature for a prolonged time, both of which vary depending on the type of grain used, flavoring, cooking medium, and other environmental conditions such as pressure and altitude, the kernels pop and the popping of the kernels causes them to eject from the bottom of grain pod 3301 through its bottom cover, out of upper chamber 102, and into receiver 104. As detailed above with respect to FIG. 1, the popped kernels exit upper chamber 102 through outlet 105, which is open to the bottom of grain pod 3301.
Systems, methods and apparatus are provided herein. References to “preferred embodiments,” “another embodiment,” “one embodiment,” “an embodiment,” “an example embodiment,” etc., indicate that the embodiment described may include a particular feature, structure, or characteristic, but every embodiment may not necessarily include the particular feature, structure, or characteristic. Moreover, such phrases are not necessarily referring to the same embodiment. Further, when a particular feature, structure, or characteristic is described in connection with an embodiment, it is submitted that it is within the knowledge of one skilled in the art to affect such feature, structure, or characteristic in connection with other embodiments, whether or not explicitly described. After reading the description, it will be apparent to one skilled in the relevant art how to implement the disclosure in alternative embodiments.
Furthermore, no element, component, or method step in the present disclosure is intended to be dedicated to the public regardless of whether the element, component, or method step is explicitly recited in the claims. No claim element is intended to invoke 35 U.S.C. 112(f) unless the element is expressly recited using the phrase “means for.” As used herein, the terms “comprises,” “comprising,” or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.