Technologies are described for devices and methods to utilize an ingredient cartridge assembly. The devices may comprise a cooking pot, a heat source, a loading track, a propulsion system, a loading compartment, and a controller. The loading compartment may be located along the loading track. The controller may be in communication with the heat source and the propulsion system. The propulsion system may be configured to receive an ingredient cartridge assembly including a cartridge. A protective film on the cartridge may be contacted with the propulsion system. The propulsion system may pull the protective film to peel the protective film from the cartridge and slide the cartridge along the loading track towards the loading compartment. An ingredient inside of the cartridge may deposit into the loading compartment as the cartridge passes over the loading compartment. The loading compartment may be configured to deposit the ingredient into the cooking pot.

A viscous food dispensing system includes a chute inlet configured to funnel particulate food product into a sleeve and a transport device having an over-center cutout. The transport device is configured to rotate within the sleeve to convey the particulate food product. A processing surface extends downward from the chute inlet towards a curved base of the sleeve along a portion of the transport device. The processing surface is spaced laterally apart from the transport device to define a processing zone between the processing surface and the transport device. The particulate food product is processed as the particulate food product is captured between a leading edge of the over-center cutout and the processing surface while the transport device is rotating.

In an illustrative embodiment, systems for designing and producing customized food products include receiving a request to design a customized food product containing a printed edible medium. The systems may calculate, based on product inventory at a preferred bakery, a preparation lead time for the food product where the product inventory includes availability of printed edible media substrates. The systems may present customization user interface screens that provide customization options for the food product. The systems may convert customization option selections made at the customization user interface screens into decorating instructions for the food product and transmit the decorating instructions to the bakery. The systems may determine a position in a preparation queue for the food product based in part on attributes of pending food product orders in a preparation queue at the bakery.

A retainer for temporarily holding in place a pair of inclined roof panels of a decorative edible structure includes a first hook surface on a body for engaging a first lower edge of a first inclined roof panel and a second hook surface on the body for engaging a second lower edge of a second inclined roof panel. The first and second hook surfaces are spaced apart from each other along the body, and when in use, the body holds the first and second hook surfaces in engagement with the first and second lower edges. Decorative edible structures using such retainers, a kit of parts including such retainers, and corresponding methods of constructing decorative edible structures using such retainers are also disclosed.

A retainer for temporarily holding in place a pair of inclined roof panels of a decorative edible structure includes a first hook surface on a body for engaging a first lower edge of a first inclined roof panel and a second hook surface on the body for engaging a second lower edge of a second inclined roof panel. The first and second hook surfaces are spaced apart from each other along the body, and when in use, the body holds the first and second hook surfaces in engagement with the first and second lower edges. Decorative edible structures using such retainers, a kit of parts including such retainers, and corresponding methods of constructing decorative edible structures using such retainers are also disclosed.

Variable-scale, modular, easily manufacturable, energy efficient, reliable, and computer operated Insect Production Superstructure Systems (IPSS) may be used to produce insects for human and animal consumption, and for the extraction and use of lipids for applications involving medicine, nanotechnology, consumer products, and chemical production with minimal water, feedstock, and environmental impact. An IPSS may comprise modules including feedstock mixing, enhanced feedstock splitting, insect feeding, insect breeding, insect collection, insect grinding, pathogen removal, multifunctional flour mixing, liquid mixing, shaping, cooking, flavoring, biocatalyst mixing, exoskeleton separation, liquid separation, and lipid extraction. An IPSS may be configured to be constructed out of a plurality of containerized modules.

Variable-scale, modular, easily manufacturable, energy efficient, reliable, and computer operated Insect Production Superstructure Systems (IPSS) may be used to produce insects for human and animal consumption, and for the extraction and use of lipids for applications involving medicine, nanotechnology, consumer products, and chemical production with minimal water, feedstock, and environmental impact. An IPSS may comprise modules including feedstock mixing, enhanced feedstock splitting, insect feeding, insect breeding, insect collection, insect grinding, pathogen removal, multifunctional flour mixing, liquid mixing, shaping, cooking, flavoring, biocatalyst mixing, exoskeleton separation, liquid separation, and lipid extraction. An IPSS may be configured to be constructed out of a plurality of containerized modules.

In an illustrative embodiment, systems for designing and producing customized food products include receiving a request to design a customized food product containing a printed edible medium. The systems may calculate, based on product inventory at a preferred bakery, a preparation lead time for the food product where the product inventory includes availability of printed edible media substrates. The systems may present customization user interface screens that provide customization options for the food product. The systems may convert customization option selections made at the customization user interface screens into decorating instructions for the food product and transmit the decorating instructions to the bakery. The systems may determine a position in a preparation queue for the food product based in part on attributes of pending food product orders in a preparation queue at the bakery.

In an illustrative embodiment, systems for designing and producing customized food products include receiving a request to design a customized food product containing a printed edible medium. The systems may calculate, based on product inventory at a preferred bakery, a preparation lead time for the food product where the product inventory includes availability of printed edible media substrates. The systems may present customization user interface screens that provide customization options for the food product. The systems may convert customization option selections made at the customization user interface screens into decorating instructions for the food product and transmit the decorating instructions to the bakery. The systems may determine a position in a preparation queue for the food product based in part on attributes of pending food product orders in a preparation queue at the bakery.

System for the production of animal feed and/or food products, comprising static treatments such as storage, heating, drying, cooling, etc., dynamic treatments such as cleaning, blending, grinding etc., and transport operations. The system comprises a housing and/or framework with vertically stacked, each horizontally extending treatment layers, of which the static treatment layers, arranged for the predominantly static treatment of raw materials and/or intermediates, and the dynamic treatment layers, arranged for intermediate transport and the predominantly dynamic treatment of raw materials and/or intermediates, alternating each other vertically. The static treatment layers comprise static treatment modules for performing predominantly static treatments. The dynamic treatment layers are provided with mobile treatment modules for performing predominantly dynamic treatments, wherein the mobile treatment modules are displaced in the horizontal direction between the docking locations during the treatment of the material. Furthermore, a vertical cleaning channel is provided and the housing is tower-shaped.