阅读说明：本技术 饮料搅拌器系统 (Beverage blender system ) 是由 克里斯托弗·伯奇 于 2019-08-19 设计创作，主要内容包括：搅拌器系统包括搅拌器和容器。所述搅拌器包括：一瓶结构,所述瓶结构包括搅拌室,所述搅拌室带有瓶结构开口和环绕瓶结构开口的瓶肩；一瓶盖结构,所述瓶盖结构被构造成与瓶结构耦接,且所述瓶盖结构包括容器接收器。所述容器包括一营养物接收器,所述营养物接收器具有封闭端和与所述封闭端相对的接收器开口以容纳内容物；一唇结构,所述唇结构围绕在接收器开口上；和至少两个翼片,通过唇铰链连接至所述唇,并设置成覆盖部分所述开口。耦接瓶盖结构与带有处于容器接收器中的容器的瓶结构的过程会将唇结构推至封闭端,使得至少两个翼片会被推开以至于内容物可以排出至搅拌室。(The blender system includes a blender and a container. The agitator includes: a jar structure including a stir chamber having a jar structure opening and a jar shoulder surrounding the jar structure opening; a bottle cap structure configured to couple with a bottle structure, the bottle cap structure including a container receiver. The container includes a nutrient receptacle having a closed end and a receptacle opening opposite the closed end to contain contents; a lip structure surrounding the receiver opening; and at least two flaps hingedly connected to the lip by the lip and arranged to cover a portion of the opening. The process of coupling the closure structure with the bottle structure with the container in the container receiver pushes the lip structure to the closed end so that the at least two wings are pushed open so that the contents can be discharged to the stir chamber.)

1. An agitator for mixing a composition from a container with a fluid, comprising:

a bottle structure comprising:

a stir chamber comprising an opening for receiving a fluid and a shoulder surrounding the opening;

a bottle cap structure coupled with the bottle structure, the bottle cap structure comprising:

a container receiver, wherein the container receiver is configured to receive a content comprising an ingredient and to abut a lip structure of the container against the shoulder when the cap structure is coupled to the bottle structure, wherein the shoulder is configured to have a shape and size for receiving and housing the lip structure, and wherein the container receiver is further configured to apply pressure to an end of the container when the cap structure is connected to the bottle structure to move the container toward the opening while the shoulder holds the lip structure stationary to discharge the ingredient from the container into the fluid in the stir chamber.

2. The blender of claim 1 further comprising an identification information reader to read container identification information from said container.

3. The blender as recited in claim 1, further comprising a blending assembly in the blending chamber.

4. The blender of claim 3 wherein connecting said bottle cap structure to said bottle structure actuates said blending assembly to blend said ingredient and said fluid.

Technical Field

The present disclosure relates generally to portable blenders.

Background

Different types of fixed and portable blenders allow consumers to blend entire fruits, vegetables, nuts, seeds, milk and other ingredients to make a nutritious smoothie. However, it is still quite inconvenient and expensive to purchase and prepare these materials. Existing portable mixers require the purchase, handling, and preparation of large volumes of high mass ingredients to mix and produce smoothies. There is therefore a need for a portable blender that can be used for conveniently making nutritional smoothies and other foods.

Disclosure of Invention

The invention discloses a stirrer system, which is characterized by comprising: an agitator, the agitator comprising: a jar structure including a stir chamber having a jar opening; and a bottle cap structure, the bottle cap structure being structurally coupled to the bottle structure, the bottle cap structure including a container receiver; and a container, comprising: a nutrient receptacle having a closed end and a receptacle opening opposite the closed end to contain contents; a lip structure surrounding the container opening; and at least two flaps connected to the lip and arranged to cover a portion of the receptacle opening, wherein connecting the lip to the bottle structure (with the container in the container receptacle) presses the lip to the closed end such that the at least two flaps are pushed apart to discharge the contents into the stir chamber.

Wherein the container further comprises container identification information, and wherein the blender further comprises an identification information reader to read the container identification information from the container.

Wherein, still include a stirring subassembly.

Wherein coupling the bottle cap structure to the bottle structure drives the agitation assembly.

Wherein, still include the battery for stirring subassembly power supply.

Wherein, still include a liquid level sensor, wherein, stirring subassembly actuates based on the liquid level information that is confirmed by liquid level sensor.

Wherein a transceiver is included to transmit information about the blender and the container.

The invention also discloses a stirrer, which is characterized by comprising: a bottle structure comprising: a stir chamber comprising an opening for receiving fluid and a shoulder surrounding the opening; the stirring component is arranged on the inner surface of the stirring chamber according to the seal; and a bottle cap structure configured to be coupled to the bottle structure, the bottle cap structure comprising: a container receiver, wherein the container receiver is configured to receive a container containing contents such that connection of the cap structure to the bottle structure presses the container against the shoulder to open the container and expel the contents into the stir chamber for stirring with the fluid by the stirring assembly.

Wherein the bottle closure structure further comprises an ejector to press the container against the shoulder when the bottle closure structure is connected to the bottle structure.

Wherein the bottle cap structure is connected to the bottle cap structure by pressing the bottle cap structure against the bottle structure.

Wherein the bottle cap structure and the bottle structure further comprise complementary threads, wherein the bottle cap structure is connected to the bottle structure by rotating the bottle cap structure relative to the bottle structure to engage the complementary threads.

Wherein connecting the bottle cap structure to the bottle structure actuates the blending assembly.

Wherein, still include the battery for stirring subassembly power supply.

Wherein the container identification reader is used for reading the identification information from the container.

Wherein a transceiver is included for transmitting information about the agitator and the container.

Wherein, still include a liquid level sensor, wherein, stirring subassembly actuates based on the liquid level information that is confirmed by liquid level sensor.

The invention further discloses a stirrer, which is characterized by comprising: a bottle structure comprising: a stir chamber comprising an opening for receiving fluid and a shoulder surrounding the opening; and a bottle cap structure configured to be coupled to the bottle structure, the bottle cap structure comprising: a container receiver, wherein the container receiver is configured to receive a container and place a lip of the container against the shoulder when the lip is connected to the bottle structure, wherein connecting the bottle cap structure to the bottle structure presses the container toward the opening while the shoulder holds the lip stationary.

Wherein an identification information reader is included to read the container identification information from the container.

Wherein, still include a stirring subassembly.

Wherein the bottle cap structure is coupled to the bottle structure to drive the agitator assembly.

Drawings

FIG. 1 is an exploded cross-sectional side view of a container in an upright closed position;

FIG. 2 is a perspective view of the container of FIG. 1 in an upright closed position;

FIG. 3 is a cross-sectional view of the container of FIG. 1 in an upright open position;

FIG. 4 is a perspective view of the container of FIG. 1 in an upright open position;

FIG. 5 is a perspective view of the container of FIG. 1 with a sealing lid in an upright, closed position;

FIG. 6 is a cross-sectional view of the agitator in an upright position;

FIG. 7 is a perspective view of the blender of FIG. 6 in an upright position;

FIG. 8 is an exploded cross-sectional view of the blender and the container of FIG. 1 of FIG. 6;

FIG. 9 is a cross-sectional view of the blender and the container of FIG. 1 of FIG. 6;

FIG. 10 is a block flow diagram showing the use of the mixer of FIG. 6 and the vessel of FIG. 1.

Throughout the specification, elements appearing in the figures are assigned a three-digit reference number, with the most significant digit being the figure number and the two least significant digits being specific to the element. It can be assumed that: elements not described in connection with the figures have the same features and functions as previously described elements having the same reference number, the least significant digit.

Detailed Description

Disclosed herein is a portable blender for easily and conveniently making a blended beverage or food having a smooth mouthfeel (hereinafter, collectively referred to as "smoothie") using a container (e.g., a jug). The container contains nutrients such as powdered fruits and vegetables or other food items and is very convenient for the consumer to carry with the blender. The container may be placed in a blender and the contents of the container may be discharged into the blending chamber. The contents may be agitated with a pourable fluid, suspension or mixture, such as water, fruit juice, milk, soy milk or almond milk, to form a nutritionally-rich smoothie. The stirring assembly in the blender can properly blend the ingredients to eliminate clumping and achieve the desired viscosity and aeration, thereby providing a superior stock for protein shaker bottles (e.g., bottles with wire balls for blending). The stirring assembly is powered by a battery.

An exploded cross-sectional view of the container 100 in an upright closed position is shown in fig. 1. FIG. 2 is a perspective view of the container 100 of FIG. 1 in an upright, closed position; FIG. 3 is a cross-sectional view of the container 100 of FIG. 1 in an upright open position; fig. 4 is a perspective view of the container 100 of fig. 1 in an upright, open position. The container 100 includes a nutrient receptacle 101 that can receive and hold nutrients. The nutrient receptacle 101 has a closed end 109 and an opening 112 opposite the closed end 109. The nutrient receptacle 101 may have a frustoconical shape (as shown). Other suitable shapes may be cylindrical, cubical or prismatic with an opening at one end that can receive and contain nutrients.

The inner lip 106 is at the periphery of the opening 112. Outer lip 107 is located outside of inner lip 106 and is captured on nutrient receiver 101 at inner lip 106 by lip hinge 108 such that slot 111 is located between outer lip 107 and inner lip 106. The outer lip 107 may also include a ledge or widening of the outer lip 107 that extends outwardly in the direction of the opening 112 from a location at the end of the outer lip 107 opposite the closed end 109.

The freestanding outer cover 102 includes an apron 110, which apron 110 can fit into a slot 111, for example by a snap fit, a press fit or a friction fit. The skirt 110 may include ridges 113 configured in a complementary fashion to the grooves 114 on the outer lip 107 in the slots 111 to further secure the outer cover 102 to the outer lip 107. Preferably, the skirt 110 may include a groove configured to complement a ridge on the outer lip 107 in the slot.

The edge 105 is located on the edge of the panel 110 opposite the closed end 109. The flap 103 is a wide flat protrusion and is assembled to the rim 105 by a flap hinge 104, wherein the flap hinge 104 extends along only a portion of the flap 103. The flaps 103 are positioned to cover the openings 112, with each flap covering a portion of the opening 112. Four tabs 103 are shown in this embodiment, but other suitable numbers of tabs, such as two tabs, three tabs, five tabs, or six tabs, that cover the opening 112 in a certain shape and mounting position may be used.

To prepare the container 100 for consumer use, food ingredients (i.e., nutrients) such as fruits and vegetables, proteins, vitamins, and minerals or supplements are loaded into the nutrient receptacle 101 before the lid 102 is secured in place. The ingredient may be or include one or more non-food products such as acidity regulators, anti-caking agents, antifoaming agents, antioxidants, bleaching agents, fillers, carbonating agents, carriers, pigments, colorants, color retention agents, emulsifiers, emulsifying salts, solidification agents, flavor enhancers, flour treatment agents, foaming agents, gelling agents, polishing agents, humectants, packaging gases, preservatives, propellants, leavening agents, chelating agents, stabilizers, sweeteners, and thickeners; the ingredients may be monolithic, crumb, powdered, wet, moist or dry, active or inert.

Once the ingredients are loaded into the nutrient receptacle 101, the lid 102 is placed onto the nutrient receptacle 101, as shown in fig. 2, and when the lid 102 is secured to the nutrient receptacle 101, the skirt 110 is slid into the slot 111 until the edge 105 is substantially flush with the outer lip 107. In the sealed container 100, the flap 103 covers the opening 112 and the nutrients are contained in the sealed container 100.

The contents may be released from the closed container 100 for use and consumption. As shown in fig. 3 and 4, when the outer lip 107 and rim 105 are pushed toward the closed end 109, the flap 103 is pushed away by the inner lip 106 to a position away from the nutrient receptacle 101. The lip hinge 108 enables the outer lip 107 to move or "collapse" relative to the inner lip 106. The outer lip 107 that collapses down pushes the rim 105 toward the closed end 109. As the rim 105 moves towards the closed end 109, the inner lip 106 presses on the flaps 103 which then rotate on the respective flap hinges 104 and open and move away from the nutrient receptacle 101. With the flap 103 open, the nutritional ingredients may exit the container 100 through the opening 112. The container 100 should reliably discharge its contents without the discharge process being accompanied by powder clumping, sticking or bursting.

While a particular configuration of the container 100 has been described above, the container may have various other configurations. The container may have four flaps, two flaps or other number of flaps. The container may have ribs for additional structural support. The tabs may be hinged to the outer lip and the tabs may overlap or the tabs may be assembled together with a membrane. The container can be constructed from only one or more pieces. The container may include an internal knife mechanism that may apply pressure on the closed end of the nutrient receptacle causing the internal knife mechanism to push the tab out of or through the seal to allow the nutrient contents to be expelled from the container. The closed end may be deformed from one structural configuration (e.g., convex) to another (e.g., concave) to further assist in the expulsion of the nutritional composition.

The container may be formed of any suitable material, such as plastic, metal, degradable material, waxed cardboard, bioplastic, and the like.

The container 100 may also be sealed, which may prevent moisture and contaminants from damaging the contents, lock freshness (e.g., to keep the contents from clumping or hardening), or secure and protect the contents. Fig. 5 is a perspective view of the container of fig. 1 with the closure 150 in an upright, closed position. A seal 150 may be placed over the flaps and secured to the outer lip 107, for example by glue or heat sealing, to prevent nutrients from escaping between the flaps 103, to keep the flaps 103 clean, and to prevent other contaminants from escaping. The seal may be paper, plastic, cellophane and/or foil, or any other durable material that provides protection and containment to the container 100. The sealing member may further include: a tab, ring, strip or other graspable portion to allow for easy removal by the consumer. A cover (not shown) may also be used to lock freshness and protect the seal 150 or as a substitute for the seal and may snap into place around the outer lip 107. The consumer first needs to remove the seal 150 and/or the lid to use the container 100.

The container 100 may include identification information 151, the identification information 151 being used to provide various information about the container and its contents, such as a unique identifier for a particular container, a date of manufacture, authenticity information, nutritional ingredients, and/or blends/descriptions. The identification information 151 may simply be printed on the container 100 or on a label affixed to the container 100. Alternatively, the identification information may be stored on the container 100 in the form of a Near Field Communication (NFC) label, a printed memory label, or a bar code. For example, an NFC tag may be affixed to the container 100 so that an NFC reader and antenna (e.g., in a blender) may read the identification information from the container 100 when a smoothie is made using the container 100.

In other embodiments, the barcode on the container may be read by a barcode reader or camera in the blender. The identification information may be read when the container is inserted into the blender before, and/or during, and/or after the blending cycle is performed. The identification information may be used by the blender in a variety of ways, including determining whether the container is genuine or counterfeit, and/or whether it is fresh or expired.

The identification information may be read to be stored locally in the blender (e.g., in non-volatile memory) and then transferred to cloud storage (i.e., accessible online) by a communication method, such as bluetooth low energy (B L E), in a proxy device (e.g., a smartphone or tablet).

The identification information may be based on a machine-generated universally unique identifier ("UUID") (i.e., any alphanumeric identifier) or may be based on a well-defined coding structure that contains one or more facts about the container 100. The identification information may be encrypted (e.g., using advanced encryption standard ("AES")) such that the blender needs to be decrypted. The identification information may contain special characters or coded structures that indicate that the container 100 is valid. The container may have a digital rights management ("DRM") indicia that uses a special ink to reflect light at a wavelength (e.g., responsive to exposure to infrared light) that can be read to determine authenticity.

A cross-sectional view of the blender 600 in an upright position is shown in fig. 6. Fig. 7 is a perspective view of the blender of fig. 6 in an upright position, and fig. 8 is an exploded cross-sectional view of the blender of fig. 6 and the container of fig. 1. The blender 600 includes a jar structure 620 and a cap structure 630. The jar structure has an exterior 621, a mixing chamber 622, an exterior wall 623, a mixing assembly 624, wherein the mixing assembly further comprises at least one blade 625 driven by a motor 626, an opening 627 and a jar shoulder 628, and a jar structure assembly 629 coupled by the opening 627. The bottle cap structure 630 has a container receiver 631, a bottle structure assembly 632 formed by coupling a container receiver 632, an ejector 633 and electronics 634.

The blender 600 may also include buttons 635 for controlling its operation. Although the button 635 is shown at the top of the bottle structure 635 in fig. 6, the button or buttons may be located at any suitable location accessible to the consumer, such as the bottom of the bottle structure 620, or the sides of the bottle structure 620 or the bottle cap structure 630. The button 635 may also be placed inside the bottle structure 620 or the cap structure 630 so that it can be actuated by closing the cap structure. In one embodiment, button 635 may be mechanically actuated. Pressing button 635 (e.g., when rotating the bottle cap structure) may or may not require that container 100 be installed in position inside blender 600. In another embodiment, the blender 600 does not have a button and is electrically driven by a reed switch or a hall sensor.

The exterior 621 of the bottle structure 620 and the bottle cap structure 630 may be made of one or more suitable materials that are durable and rigid, such as plastic, rubber, metal, coated materials, wood, foam. The vial structure 620 and the vial cap structure 630 may be formed of the same material or different materials.

Stir chamber 622 is located inside of bottle structure 620. The stir chamber 22 is adapted to contain fluid without leakage. Stir chamber 622 may be formed from any suitable durable and rigid material, such as metal, plastic, coated materials, glass, and the like. The mixing chamber 622 includes a shoulder 628 at an opening 627 to engage the container 100. Opening 627 allows fluids and nutrients to be placed into stir chamber 622 and allows the consumer to remove the mixed juice from stir chamber 622. Stirring chamber 622 may be a double-walled structure, with stirring chamber 622 located within outer wall 623. Air or another insulating material may be located between stir chamber 622 and outer wall 623. The double wall construction may thus provide an insulating effect to maintain a desired temperature of the fluid and smoothie. Stir chamber 622 may also include fill line markings to indicate to the consumer how much fluid should be injected into stir chamber 622.

An agitator assembly 624 is mounted in the agitator chamber 622. An agitation assembly 624 is shown mounted at the end of the agitation chamber 622 opposite the opening 627. However, the blending assembly 624 may be mounted at any suitable location within the blending chamber 622 to achieve the desired blending of the nutrients and fluids. The blending assembly 624 may have any suitable number of blades 625, such as one blade, two blades, three blades, four blades, etc., having any suitable shape to achieve the desired blending of nutrients and fluids. The vanes 625 may be formed of any suitable material that is rigid and durable, such as metal or plastic. The stirring assembly 624 is driven by a motor 626. The motor 626 may be any suitable motor that can achieve torque and RPM to achieve the desired agitation of nutrients and fluids, such as a brush motor, a brushless motor, a 2-phase motor, a 3-phase motor, a motor with or without an internal control panel. The motor controller (not shown in the drawings) may be located outside the motor or may be incorporated inside the motor.

The blender 600 includes a bottle structure assembly 629 and a lid assembly 632 of a coupling mechanism. A vial structure assembly 629 and cap assembly 632 removably couples vial structure 620 and vial cap structure 630. For example, assemblies 629 and 632 may be complementary threads, bayonet-type connections, complementary grooves and posts, or any other suitable type of connection to allow removable attachment of bottle cap structure 630 to bottle structure 620. For complementary threads, the threads may be located on the outer surface of bottlecap structure 630 and the inner surface of bottle structure 620, or the threads may be located on the inner surface of bottlecap structure 630 and the outer surface of bottle structure 620.

The bottle cap structure 630 includes a container receiver 631 configured to have a complementary shape to the container 100. The cap structure 630 may optionally further include an ejector 633, the ejector 633 allowing the container 100 to be opened and the contents thereof to be ejected when the cap structure 630 is coupled to the bottle structure 620. In one example, as the bottle cap structure 630 is coupled to the bottle structure 620, the eductor 633 presses the container 100 against the bottle structure 620 to expel the nutritional composition from the container 100. The discharger 633 may operate in any suitable manner to include discharging nutrients from the container 100 by a spring mechanism and/or a screw mechanism. For example, a spring mechanism may be deployed in the ejector 633 to squeeze the closed end 109 of the container 100 in the coupling of the vial structure cap 630 and the vial structure 620. In another embodiment, coupling the bottle cap structure 630 to the bottle structure 620 may cause a screw mechanism in the ejector 633 to rotate, thereby causing the ejector 633 to squeeze the closed end 109 of the container 100. In another embodiment, the ejector 633 may simply provide a firm, fixed surface to apply pressure to the closed end 109 of the container 100.

The blender 600 may also include various other electronic devices 634. In one embodiment, the electronics 634 may include a battery 654 that powers the blender 600, which may be charged by a conventional wired charger or a wireless inductive charging cradle. For inductive charging, the receiver and coil may be located in the blender 600 and the transmitter may be located in a separate charging pad. In another embodiment, the battery may be charged by direct contact, for example, by having a charger based on a contact charger node and a charging loop located on the agitator 600. In another embodiment, the battery may be replaced once depleted, or may be charged using a charging cable that may be plugged into a power source through a USB connector or wall plug. The batteries may be located in the bottle structure 620 and/or the bottle cap structure 630.

The electronic device 634 may also include a communication device, such as a bluetooth transceiver, to send and receive information. The bluetooth transceiver may communicate with other bluetooth-connected devices, such as computers, tablets, and mobile phones, to receive information such as customer information, registration information, operating instructions, and firmware updates, and to transmit information such as the operating state of the blender, including blender and container usage related to nutrients consumed by the user. The information may come from cloud storage or the internet. The communication device may be located in the bottle structure 620 and/or the bottle cap structure 630.

The electronics 634 may also include a sensor for determining whether the bottle cap structure 630 has been coupled to the bottle structure 620. The sensor may include a hall sensor, a reed switch, or may be any other suitable sensor that may be used to determine whether the bottle cap structure 630 is properly attached to the bottle structure 620 and may determine whether the blender 600 is ready to be actuated.

The electronics 634 may include electronics 652 for reading the identification information 151 from the container 100. for example, reading the identification information 151 may be performed via an NFC tag reader, a camera, a bar code reader, a light emitting diode or laser reader, or a printed memory tag reader in other embodiments, electronics for reading the identification information may be located in the bottle structure 620 and/or the bottle cap structure 630. the blender 600 may store the identification information locally in memory (e.g., in non-volatile memory) and/or transmit the identification information to cloud storage (i.e., online accessible) via a communication method such as bluetooth low power (B L E) in an agent device (e.g., a smartphone or tablet computer.) the identification information transmitted to the cloud storage may be used for nutritional consumption analysis by a user.

The electronics 634 may also include a microcontroller unit, memory, and hardware such that control of the blender and storage of information may be accomplished, such as operating the blender (e.g., driving the blender and controlling blending time and speed), determining freshness of the contents based on date/time and container identification information, and controlling indicators regarding blender operation. For example, the microcontroller unit may be a single chip containing a processor, a non-volatile memory (read-only memory or flash memory) for programs, a volatile memory (e.g., random access memory) for input and output, a clock, and an input/output (I/O) control unit. In another embodiment, the memory may be a micro SD card.

To ensure that the container 100 is not reused or refilled, the unique identifier in the identification information may be read and stored locally on the blender 600. When the identification information of a particular container is read, the unique identifier will be checked against this list, and if the unique identifier is in the list, the blender may not be operational.

The blender 600 may have indicators, including indicator lights and/or sounds, to inform the consumer of the status of the blender 600. For example, different sounds, lights colors, or lights may indicate different states, such as determining whether the container 100 is expired or counterfeit, whether the battery is low or fully charged, whether there is a problem with the alignment of the bottle cap structure 630, whether the blending assembly is jammed, and the like. In one embodiment, the indicator light may emit a color to indicate certain conditions, such as red for a stuck blending assembly, yellow for a low battery, or green for a fully charged battery. In another example, the agitator may sound some sort of sound to indicate some sort of status, such as a continuous beep to indicate a stuck agitator assembly or intermittent beep to indicate a low battery.

The blender 600 may have hardware to track and communicate abnormal and unsafe conditions, so that the consumer may be notified and/or the blender itself may respond appropriately.hardware may control an indicator to indicate the abnormal and unsafe conditions.the indicator may use L ED color, intensity, and pulse combinations, as well as sound to indicate the abnormal and unsafe conditions.

The abnormal and unsafe conditions may also include: battery needs to be charged, equipment commissioning, equipment charging (also possibly indicated by a charging pad), charging pad, on-board and charging, incorrect on-board, uncharged, completed charging, emergency mode, factory settings restored, equipment restored, unable to read container, counterfeit container, motor blade stuck, overheated, water level too low/added, content stirring, completed stirring, hardware update, stirrer tilt (i.e., bad angle), error.

The hardware updates may be received wirelessly via B L E (e.g., via an agent device such as a smartphone or tablet computer) in one embodiment.

Blender 600 may have a hardware managed state to conserve battery power. The blender 600 may enter a "sleep mode" after a period of inactivity. An accelerometer may be used to detect activity to wake up the blender 600 and place it in an "active mode". In another embodiment, the coupling of the bottle cap structure 630 to the bottle structure 620 may wake up the blender. In another embodiment, when the bottlecap structure 630 is coupled to the bottlecap structure 620, the whisk 600 is awakened and the whisk 600 remains in the "activated mode" until the bottlecap structure 630 is removed. In the "activated mode," the blender 600 detects an activity, such as movement, activation of a button, or insertion of a container, so that the blender can respond accordingly. In another example, blender 600 may deliver it to a consumer in a "blending mode" to consume minimal energy during shipping, distribution, fulfillment, and the like. The blender 600 may be withdrawn from the blending mode when the consumer first unpacks it and places it on a charging pad for charging.

The blender 600 may have a level sensor 653. for example, the blending chamber may have a capacitance based level sensor rigid-flex circuit design allows the sensor to be placed against the inner wall of the blending chamber 622. alternatively, the level may be determined using a digital infrared L ED sensor solution, the infrared L ED and phototransistor are optically coupled when the sensor is in air, the optical coupling may change when the sensor head is immersed in fluid. the blender 600 may use information from the sensor to determine if the level of liquid in the blending chamber 622 is within acceptable limits.

In different examples of the blender 600, the electronic components may be located in different locations. For example, the microcontroller unit, memory, PCB board, battery, charging coil, transceiver and sensors may be located in the bottle cap structure 630 and bottle structure 620.

In one embodiment, the electronic components are located in the bottle cap structure 630 so that the bottle structure can be washed with a dishwasher. In an embodiment, the wireless charging pad for the bottle cap structure 630 may be configured in a shape similar to the container 100 for inductive charging. The bottle cap structure 630 receives a charging pad in a similar manner as the receiving container 100 so that the battery 654 in the bottle cap structure 630 can be inductively charged via the charging pad.

Additionally, electrical contacts may be provided on the jar structure assembly 629 and the jar structure assembly 632 of the coupling mechanism so that power may be delivered from the battery 654 in the cap 630 to the motor 626 to drive the stirring assembly 624. In one embodiment, at least a portion of bottle structure assembly 629 and bottle cap structure assembly 632 are formed from a non-conductive material (e.g., plastic). Electrical contacts may then be positioned in the non-conductive material of bottle structure assembly 629 and bottle cap structure assembly 632, respectively, such that when bottle cap structure 630 is coupled to bottle structure 620, the electrical contacts may align with each other and conduct electrical current. In embodiments where the coupling mechanism includes threads, the electrical contacts of vial structure assembly 629 and vial structure assembly 632 align with one another when the vial cap structure 630 is rotated to a particular orientation relative to the vial structure 620 on the coupling device. Further, one or more of the electrical contacts may include a spring to securely press the respective electrical contacts against each other and to facilitate the conduction of electrical power.

The blender 600 is configured to have a suitable size and shape so that a consumer having a typical palm size can manipulate and consume smoothies from the blender. In addition, blender 600 is configured in a portable size and shape, such as may be carried by hand or may be carried in a purse, backpack, or other bag. For example, the agitator 600 may have a length of three inches to twelve inches, and a diameter of one inch to six inches. In one embodiment, agitator 600 has a length of approximately eight inches and a diameter of three inches. The blender 600 is configured to have a suitable weight so that the blender 600 is portable and easy to operate with typical palm sizes. For example, blender 600 may weigh from 4 ounces to 3 pounds. Blender 600 may have a weight of about 8 ounces. In one implementation, the jar structure 620 is heavier than the cap structure 630 so the blender is less likely to tip over.

Blender 600 is configured with a blending chamber 622, which blending chamber 622 has the ability to produce a desired volume of smoothie for human consumption. For example, the stir chamber 622 may have a capacity of 6 fluid ounces to 32 fluid ounces. In one implementation, the stir chamber 622 has a capacity of about 10 fluid ounces. The container 100 is configured to have a size of nutrient content complementary to the fluid content of the blender so that a smoothie having a desired viscosity and flavor can be blended. For example, the container 100 may have a capacity of from 1 fluid ounce to 8 fluid ounces. In one example where the blender has a capacity of 10 fluid ounces, the container 100 may have a capacity of 2 fluid ounces.

Figure 9 shows a cross-sectional view of the blender and the container of figure 1 of figure 6. Fig. 10 shows a flowchart process of a method 1000 of making a smoothie using the blender of fig. 6 and the container of fig. 1.

In step 1001, the consumer adds fluid to stir chamber 622. The consumer may pour the desired amount of the desired fluid. In one embodiment, stir chamber 622 includes a fill line that can indicate to the consumer how much fluid should be added to stir chamber 622. Although the step of adding fluid to the stirring chamber 622 is described first herein, fluid may be added to the stirring chamber 622 at any point prior to driving the stirring assembly 624.

In step 1002, the consumer prepares the container 100 for use with the blender 600 by first removing any seals 150, cap/bottle structures, or other packaging. In one embodiment, the seal on outer lip 107 may be removed by pulling or peeling the seal forcefully therefrom.

In step 1003, the container 100 is then placed on the jar structure 620 such that the outer lip 107 rests on the jar shoulder 628. When the outer lip 107 is fitted over the vial shoulder 628, the tab and the inner lip 106 are positioned over the opening 627 of the vial structure 620. In one embodiment, when the container 100 is placed on the bottle structure 620, the rim 105 also rests on the bottle shoulder 628. In another embodiment, when the container 620 is placed over the bottle structure 620, the rim 105 is positioned over the opening 627. Alternatively, the container 100 may be placed in the cap structure 630. In one embodiment, the container 100 may remain in the capping structure 630 so that the container 100 does not fall off when the capping structure 630 is placed right side up. The container 100 may be retained in the closure structure 630, for example, by a friction fit, or a snap fit between a portion of the container 100 and a portion of the closure structure 630, or an adhesive surface.

In step 1004, the bottle cap structure 630 is coupled to the bottle structure 620 via the bottle structure assembly 629 and the bottle cap structure assembly 629 of the coupling mechanism. When the bottle cap structure 630 is coupled to the bottle structure 620, the outer lip 107 and a portion of the rim 105 of the container 100 remain on the bottle shoulder 628 and the tab 103 and the inner lip 106 are positioned over the opening 627. In one example where the discharger 633 comprises a spring loaded mechanism, the spring loaded mechanism will exert sufficient force to push the container 100 open to discharge the contents into the mixing chamber 622 when the bottle cap structure 630 is connected to the bottle structure 620.

In another alternative embodiment, a stationary eductor applying pressure to the closed end 109 to expel the nutritional composition will apply sufficient pressure to the closed end 109 after a certain number of revolutions of the cap structure 630. The eductor 633 presses the closed end 109 against the bottle structure 620 while the bottle shoulder 628 presses against the outer lip 107 and rim 105. The lip hinge 108 allows the outer lip 107 and rim 105 to collapse or move back toward the closed end 109 as the closed end 109 moves toward the bottle structure 62. As a result, the inner lip 106 presses on the flaps 103, which then rotate on the respective flap hinge 104 and away from the nutrient receiver 101. When the flap 103 is opened. When the blender 600 is in the upright position, the contents are expelled from the container 100 by gravity and/or the force of the expeller 633 deployment and enter the bottle structure 620 through the opening 627. For a fixed ejector, the ejection process relies on the force of gravity when the agitator 600 is in an upright position.

The cap structure 630 may be coupled to the bottle structure 620 by pressing the cap structure 630 onto the bottle structure 620, thereby causing the ejector 633 to engage the container 100 and expel the nutritional composition. In another configuration, capping structure 630 may be coupled to bottle structure 620 by rotating capping structure 630 relative to bottle structure 620 to engage coupling members 629 and 632 such that ejector 633 engages container 100 and ejects the nutritional composition. In another alternative configuration, cap structure 630 may be coupled to bottle structure 620 by rotating cap 630 relative to bottle structure 620 to engage coupling members 629 and 632, and then pressing cap structure 630 and bottle structure 620 together to engage ejector 633 and expel the nutritional composition. The rotation may be any number of rotations or partial rotations so that the cap structure 630 may be removably coupled to the bottle structure, such as half rotation, full rotation, double rotation, etc.

In another embodiment, the bottle cap structure 630 may be coupled to the bottle structure 620, for example, by rotation, sufficient to prevent fluid from leaking from the blender 600, but without draining the contents of the container 100. After rotation to prevent leakage, the closure structure 630 may be pressed downward, rotated further, or both pressed and rotated to allow the contents to be discharged from the container 100.

In step 1005, the blender 600 reads the identification information from the container 100. Although this step is shown after the bottle cap structure 630 is coupled to the bottle structure 620 and before the blending assembly 624 is actuated, the identification information may be read at any time. For example, the identification information may be read when the container is placed on the bottle structure or the bottle cap structure, or after the stirring assembly 624 has been actuated. The battery 654 of the blender 600 must be fully charged before operating the reader's identification information. In another embodiment, this step may be skipped and the identification information not read.

In step 1006, the stirring assembly 624 is activated to stir the contents with the fluid. In one embodiment, pressing the bottle cap structure 630 toward the bottle structure 620 or further pressurizing the bottle structure 620 drives the stirring assembly 624. In another embodiment, rotating or further rotating the bottle cap structure 630 relative to the bottle structure 620 may drive the stirring assembly 624. Any combination of rotation and pressurization may be used to expel the nutrients from the container 100 and drive the stirring assembly 624. The blending assembly 624 will be actuated when the sensors on the bottle cap structure 630 and the bottle structure 620 are aligned to indicate that the contents have been discharged and the consumer is ready to blend the smoothie, or when an internal button is pressed (e.g., when the bottle cap structure 630 is rotated or pressed onto the bottle structure 620). In another embodiment, the stirring assembly 624 may be actuated by an external action, such as pressing a button, moving the stirrer 600 (e.g., movement may be detected by an accelerometer), or waving a hand or other object over a camera or other sensor. In one embodiment, the stirring assembly 624 will not be driven unless the stirrer 600 is in a substantially vertical position. Before the stirring assembly 624 operates, the battery 654 must be fully charged.

The agitation process can take a variety of forms. The stirring process may be fixed, for example, stirred with only one rotational speed and one torque for a certain period of time. Alternatively, the speed, torque and/or time may be varied during the stirring process. The change in speed, torque and/or time may vary depending on the particular container contents and/or consumer preferences. In another embodiment, the blending process may vary based on changes in the contents, vial configuration, temperature and/or outside air, humidity and/or pressure of the container (e.g., as measured by sensors on blender 600 or as input by the consumer).

The agitation cycle performed by the agitation assembly 624 may be based on a predetermined RPM and duration. This information may be hard coded into the hardware or retained in a local configuration file or database. For example, a default agitation period may be used, or a new agitation period may be downloaded. In an alternative, this information may be contained in identification information stored on the container 100 and may vary based on the contents of the container 100. In another alternative, various blending cycles may be stored on the blender 600, and a particular blending cycle may be implemented based on the identity of a particular container 100. The blending period may be based on consumer defined preferences, i.e., the consumer may set a desired RPM and duration for a particular container 100. These settings may be received by blender 600 and written to local storage.

In step 1007, the capping structure 630 is removed from the bottle structure 620 so that smoothies can be removed from the bottle structure 620. The consumer can drink the smoothie directly from the bottle structure 620 or can pour the smoothie into another container. The container 100 may be removed from the cap structure 630 or the vial structure 620 and then discarded or recycled.

Concluding sentence

Throughout the specification, the embodiments and examples shown should be considered as exemplars, rather than limitations on the apparatus and processes disclosed or claimed. Although many of the examples presented herein involve specific combinations of method acts or system elements, it should be understood that these acts and those elements may be combined in other ways to accomplish the same objectives.

Discussion of only one embodiment is not intended to be excluded from a similar role in other embodiments.

As used herein, "plurality" refers to two or more. As used herein, a "set" of items may include one or more of such items. As used herein, the term "a" or "an" refers to,

the terms "comprising," "carrying," "having," "containing," "involving," and the like, whether in written description or in the claims, are to be construed as open-ended, i.e., meaning including but not limited to. For the claims, the transition phrases "consisting of … …" and "consisting essentially of … …" alone are closed or semi-closed transition phrases, respectively. Use of ordinal terms such as "first," "second," "third," etc., in the claims to modify a claim element does not by itself connote any priority, precedence, or order of one claim element over another or the temporal order in which acts of a method are performed, but are used merely as labels to distinguish one claim element from another element having a same particular name. As used herein, "and/or" means that the listed items are alternatives, but alternatives also include any combination of the listed items.