A dispenser for a shippable container is provided, where the shippable container has a hollow body, an opening, a collar adjacent the opening, and a closure sealing the opening. The dispenser has a collar engagement portion configured to engage the collar of the shippable container, a closure engagement portion configured to engage the closure of the shippable container, and a body engagement portion configured to engage a portion of the hollow body of the shippable container. An aperture in the dispenser is configured to dispense contents from the hollow body of the shippable container. The dispenser can be configured to dispense contents from the hollow body of the shippable container when the shippable container is in an inverted position.

The present invention discloses an intelligent seasoning box for a kitchen, comprising a shell, a seasoning conveying component, a temperature monitor and a master controller, wherein the seasoning conveying component is a liquid-seasoning conveying component; both the seasoning conveying component and the master controller are arranged in the shell; the temperature monitor is connected by a universal hose and points to the center of a frying pan; the seasoning conveying component and the temperature monitor are electrically connected with the master controller respectively; the shell is provided with a containing cavity for containing liquid-seasoning bottles; the seasoning conveying component comprises conveying pipes, conveying pumps and a spraying nozzle; the conveying pumps are electrically connected with the master controller. The intelligent seasoning box for the kitchen in the present invention has the beneficial effects that the whole process of cooking can be completed under monitoring of internal application programs.

Some embodiments disclosed herein relate to a device for transferring precise amounts of fluid from at least one source container to at least one target container. In some embodiments, the fluid is first transferred from the source container (e.g., a vial) through a connector to an intermediate measuring container (e.g., a syringe). In some embodiments air can pass through an air inlet and enter the vial to compensate for the volume of fluid withdrawn from the vial. An air check valve or a bag or a filter can prevent the fluid from escaping through the air inlet. The precisely measured amount of fluid can then be transferred from the intermediate measuring container to the target container (e.g., an IV bag). In some embodiments the connector can include a source check valve and a target check valve to direct fluid first from the source container to the intermediate measuring container and then from the intermediate measuring container to the target container. Some embodiments of the device can include a motor and a controller for automatically actuating a plunger of the syringe to transfer the desired amount of fluid.

Automatic toothpaste dispensing device for due tooth care comprises device holder, which can be divided into a control box, and a toothpaste rack. There are installed a camera, display and a control panel respectively in central, upper and lower part of the said control box. Said toothpaste rack with several toothpaste drums fixed thereon is located to the right side of the control box. Said toothpaste drums include housings, and in the middle of the inner wall of the housings are mounted fixing brackets. On the fixing brackets are installed toothpaste extrusion pumps, above them are toothpaste entrances, and below them toothpaste exits. Below the fixing brackets are installed toothbrush hangers, and on the bottom of inner cavity of the toothbrush hangers squeezing buttons are fixed. The present invention analyzes the teeth images, estimates teeth conditions, and subsequently obtains an appropriate tooth care plan with the processor.

A container assembly is disclosed. The container assembly includes a container that contains a volume. Selected portions of the container assembly may be removable. A spigot assembly may be removed and associated with a filter assembly.

A dispenser for a shippable container is provided, where the shippable container has a hollow body, an opening, a collar adjacent the opening, and a closure sealing the opening. The dispenser has a collar engagement portion configured to engage the collar of the shippable container, a closure engagement portion configured to engage the closure of the shippable container, and a body engagement portion configured to engage a portion of the hollow body of the shippable container. An aperture in the dispenser is configured to dispense contents from the hollow body of the shippable container. The dispenser can be configured to dispense contents from the hollow body of the shippable container when the shippable container is in an inverted position.

A refrigerator appliance having a dispensing system, a dispensing system, and a method for dispensing liquid into a container are provided. The dispensing system can be an autofill dispensing system. In one example aspect, the dispensing system includes a vibration generator and a measurement device. When a container is present in a preselected position, liquid is delivered to the container. As liquid fills into the container, the vibration generator propagates vibrations through the container. The measurement device detects one or more characteristics of the vibration and routes one more signals indicative of the characteristics to a controller of the system. The controller determines a liquid fill level of liquid within the container based at least in part on the signals received from the measurement device.

A fluid delivery system for an appliance includes a fluid line in selective communication with a fluid source. A shelf defines a fill zone positioned below an underside of the shelf. A shelf spigot is coupled with the fluid line and disposed proximate the underside of the shelf and over the fill zone. A fluid level sensor is positioned in communication with the fill zone. The fluid level sensor is also in communication with a controller that regulates a flow of fluid through the shelf spigot.

A pour spout, for attaching to a bottle, has a first wireless transceiver and a valve for selectively controlling flow of a beverage from the bottle. A server interface, adapted to be carried by a person who serves beverages, has a second wireless transceiver. A control unit is provided to wirelessly communicate with the second transceiver. In one mode, the pour spout transmits a spout identifier to the server interface, which responds by transmitting the spout identifier and a server identifier to the control unit. The control unit responds with a reply transmission causing the server interface to command the pour spout to open the valve. In another mode, a person selects a cocktail, that results in the control unit sending designations of a plurality of liquor ingredients to the server interface. The server interface controls dispensing each of the plurality of liquor ingredients.

A method for dispensing a beverage from a bottle that includes communicating a dispensing authorization message from a control unit to at least one of a server interface carried by a beverage server and a pour spout secured to a bottle, wherein the dispensing authorization message at least one of includes or initiates a dispensing command, and wherein the pour spout responds to the dispensing command by opening a spout valve through which a beverage flows from the bottle and out of the pour spout.