The present technology is directed to a kiosk for storing, displaying, and distributing a plurality of baked products. The kiosk may include, for example, a housing defining a chamber therein and configured to receive a plurality of baked products. The kiosk may include one or more sensors configured to analyze the individual baked products to determine one or more baked unit parameters and adjust one or more baking inputs based on the measured parameters.

An automatic vending machine is provided with a storage compartment or the like having a thermally insulating construction in which a number of product columns for accommodating products aligned side-by-side in one column are provided in different levels in such a way that the most downstream products in each product column are aligned side-by-side in a vertical direction, and an in-compartment fan for cooling an internal atmosphere of the storage compartment or the like by blowing air that has been cooled by means of an evaporator disposed in the storage compartment or the like, wherein the automatic vending machine is also provided with a control unit which drives the in-compartment fan for a predefined time if the internal temperature of the storage compartment or the like reaches to or above a predefined reference temperature in a state in which driving of a freezer and of the in-compartment fan are stopped.

An inline vending machine for ice and water vending installed within a store wall allowing a user to purchase ice and water without entering the store. A shipping frame for shipping and installation of the insulated wall into the store wall is also disclosed.

A self-serve kiosk system comprising a controller interfacing an order configuration interface and a scoop subsystem comprising a robotic arm having a scoop mechanism at a distal end thereof. The scoop mechanism has a coplanar rim about the interior and the controller controls the robotic arm in a particular manner to position the scoop mechanism in relation to an ice cream container in accordance with an order received via the order configuration interface, to lower the scoop mechanism into the ice cream container and to stroke until the coplanar rim hits flat against an opposing inner side wall surface of the container thereby entrapping a fixed volume of ice cream between the opposing inner side wall surface and the interior of the scoop so that a fixed volume of ice cream can be extracted from the ice cream container for dispensing.

A method for dispensing a beverage container to a consumer. The method includes receiving in a beverage container dispenser a first beverage container that contains a beverage corresponding to a beverage selection of a user. The method further includes dispensing a second beverage container containing the beverage from a temperature-regulated compartment of the beverage container dispenser. The second beverage container that is dispensed from the temperature-regulated compartment corresponds to the beverage selection of the user.

A programmatically integrated cooling module and freezing module. In the cooling module, the front and rear racks with cantilever storage slots for transportation baskets are installed in parallel and have a spacing greater than the width of the transportation basket. In the vertical plane of symmetry between the racks, there is a Cartesian frame manipulator with a trolley and a gripping mechanism. The internal space of the cooling module is circulated with cooling air at a stabilised temperature in the range between 1° C. and 8° C. (optimally 4° C.), produced by a refrigeration unit. On the front wall of the cooling module housing, below the storage slots of the front rack, there are sending and collecting windows. The windows are designed as sluices with a drawer whose rear opening is periodically closed by a movable rear partition and which at the front has a single-leaf door hinged vertically and locked by an electromagnetic lock. In the freezing module, lockers have walls perforated with holes and the number of the order currently available for pickup is illuminated on the door.

An automatic vending machine is provided with a storage compartment or the like having a thermally insulating construction in which a number of product columns for accommodating products aligned side-by-side in one column are provided in different levels in such a way that the most downstream products in each product column are aligned side-by-side in a vertical direction, and an in-compartment fan for cooling an internal atmosphere of the storage compartment or the like by blowing air that has been cooled by means of an evaporator disposed in the storage compartment or the like, wherein the automatic vending machine is also provided with a control unit which drives the in-compartment fan for a predefined time if the internal temperature of the storage compartment or the like reaches to or above a predefined reference temperature in a state in which driving of a freezer and of the in-compartment fan are stopped.

An on-demand and efficient ice delivery unit is described. In an aspect, the unit is comprises a cabinet that further comprises an ice storage bin and an icemaker. The ice delivery unit provides a user with compressed chewable nuggets of ice. In an aspect, the unit comprises an icemaker that is ideally located below the ice storage bin. The location of the icemaker, which may also be remote, is designed to enable the ice storage bin to be of a larger capacity than ice delivery units currently known in the art. Additionally, the location of the icemaker reduces the overall size, particularly the height, of the unit in comparison to other ice distribution units known in the art.

Systems and methods are provided herein for producing and vending ice in an energy-efficient manner. A system for producing and vending ice comprises: an ice-making device configured to manufacture ice; a reservoir coupled to the ice-making device and configured to store the manufactured ice manufactured; and a control circuit communicatively coupled to the ice-making device, the control circuit configured to: determine a beginning ice inventory at a first time; determine a predicted ice demand for a first period, wherein the predicted ice demand is a function of at least a historical factor, a weather factor, a customer social event factor, and a public social event factor; determine an ice manufacturing quantity based on the beginning ice inventory, the predicted ice demand, and a manufacturing capacity of the ice-making device; and cause the ice-making device to produce an amount of ice consistent with the determined ice manufacturing quantity.

An automatic frozen food product vending machine includes a frozen food product dispensing station for dispensing at least one frozen food product into a frozen food container, an arm movable to transfer the dispensed frozen food product container to a user access platform, and a user access door located adjacent to the user access platform. The user access door is configured to be vertically driven between a closed position and an open position.