Abstract: An automated food frying system includes a plurality of functional stations for dispensing a predetermined amount of raw food, transferring the raw food to a fry basket, frying the raw food, transferring the cooked food to a mixing bowl, mixing the cooked food with seasonings, transferring the cooked food to a receiving pan, and cleaning the mixing bowl. Related methods are described.

Abstract: A robotic kitchen system for preparing food items in combination with at least one kitchen appliance such as a fryer comprises an automated bin assembly, a robotic arm, and a basket held by the robotic arm. The automated bin assembly comprises at least one automated bin for holding the food items. A camera or sensor array collects image data of the food items in the bin(s). A central processor is operable to compute and provide directions to the first robotic arm and automated bin assembly based on the image data and stored data to (a) move the robotic arm to the bin; (b) actuate the bin to drop the food items from the bin into the basket; (c) and to move the basket into the fryer all without human interaction. Related methods are also described.

Abstract: Described herein is an automated beverage dispensing system for dispensing a beverage into a cup based on an order. The automated beverage dispenser may include a conveyor and a plurality of functional stations along the conveyor route. Exemplary stations include a cup singulation or placement station, an ice dispensing station, a beverage dispensing station, and a sealing station for covering the top of the cup with a liquid tight film. Related methods are described.

Abstract: A robotic kitchen system for preparing food items in combination with at least one kitchen appliance such as a fryer comprises an automated bin assembly, a robotic arm, and a basket held by the robotic arm. The automated bin assembly comprises at least one automated bin for holding the food items. A camera or sensor array collects image data of the food items in the bin(s). A central processor is operable to compute and provide directions to the first robotic arm and automated bin assembly based on the image data and stored data to (a) move the robotic arm to the bin; (b) actuate the bin to drop the food items from the bin into the basket; (c) and to move the basket into the fryer all without human interaction. Related methods are also described.

Abstract: A robotic kitchen system for preparing food items in combination with at least one kitchen appliance such as a fryer comprises an automated bin assembly, a robotic arm, and a basket held by the robotic arm. The automated bin assembly comprises at least one automated bin for holding the food items. A camera or sensor array collects image data of the food items in the bin(s). A central processor is operable to compute and provide directions to the first robotic arm and automated bin assembly based on the image data and stored data to (a) move the robotic arm to the bin; (b) actuate the bin to drop the food items from the bin into the basket; (c) and to move the basket into the fryer all without human interaction. Related methods are also described.

Abstract: A driven wheel assembly to provide a zero turn radius without wheel scrubbing. The assembly includes a vertical axis motor driving a vertical drive shaft to drive first and second spaced-apart wheels that are oriented horizontally or perpendicular to the vertical drive shaft for lateral motion of the vehicle. This is combined with an off-axis vertical motor and gear, which rotates or steers, the driven wheel assembly. Instead of a right angle gear drive as found in a conventional drive unit, the driven wheel assembly employs a center differential coupled to the output end of the vertical drive shaft and a hub of each of the first and second wheels and that is positioned in the space between the two wheels. The center differential drives the first and second wheels, and each of the first and second wheels can turn at a different rotational velocity or even in opposite directions.

Abstract: A six degree of freedom (DOF) motion platform system is described that, in contrast to Stewart platforms, is adapted to include redundant load paths or to be without non-redundant load paths. During operation of the six DOF motion platform system, a controller may employ motion control software to provide desired movement of a ride vehicle supported on the upper plate or motion platform of the system. This makes the six DOF motion platform system particularly well suited for use in amusement or theme park rides and similar applications where it is desirable to provide redundant load paths because this reduces significant design constraints and also lowers fabrication and maintenance/operation costs when compared to rides using Stewart platforms. The actuation system used in the motion platform system include four pairs of linear actuators arranged as a rectangular truss instead of a more conventional triangular truss used in six DOF motion platforms.