An apparatus for cooking at least one egg with an eggshell, comprises a housing provided with a device for providing microwave radiation in a confined space in the housing and a holder located in the confined space. The holder is provided with at least one cavity adapted to the shape of the egg with the eggshell. The holder comprises at least a first holder part and a second holder part being movable with respect to each other between a first position in which an egg with an eggshell can be positioned in the cavity to a second position wherein the holder parts enclose the cavity. The apparatus further comprises means to insert a liquid into the holder for filling the cavity with the liquid to at least partly surround the eggshell of the egg located in the cavity. The apparatus comprises a container for holding the liquid and a dosing unit to add at least one component to the liquid.

Structures and methods of using a microwave pasteurization device, as well as related non-linear waveguides. In some embodiments, an in-shell egg pasteurization device with a non-linear slotted waveguide. In some embodiments the non-linear slotted waveguide comprises shaped waveguide applicators. The shaped waveguide applicators may employ oval, lens, or plum shaped non-linear slots to improve efficiency and efficacy of pasteurizing in-shell eggs, live oysters, tomatoes, or blueberries while maintianly the quality and functional attributes of the raw product.

An apparatus and method for cooking at least one egg with an eggshell. The apparatus comprises a housing provided with a device for providing microwave radiation in a confined space in the housing and a holder located in the confined space. The holder is provided with at least one cavity adapted to the shape of the egg with the eggshell. The holder comprises at least a first holder part and a second holder part being movable with respect to each other between a first position in which an egg with an eggshell can be positioned in the cavity to a second position wherein the holder parts enclose the cavity. The apparatus further comprises means to insert a liquid into the holder for filling the cavity with the liquid to at least partly surround the eggshell of the egg located in the cavity. The housing comprises at least a first housing part provided with the first holder part and a second housing part provided with the second holder part. The first housing part is located at least partly below the second housing part. The first housing part with the first holder part is movable between the first and second position with respect to the second housing part with the second holder part.

An in-shell egg pasteurization process includes, in a temperature-raising stage (12), raising the temperature of yolk of a plurality of in-shell eggs (40), simultaneously and at least predominantly by means of microwave radiation, to a pasteurization temperature, the temperature-raising stage (12) including a plurality of elongate or longitudinally extending microwave cavities that are isolated from one another so that microwaves fed into an elongate or longitudinally extending microwave cavity do not leak into any other elongate or longitudinally extending microwave cavity. The in-shell eggs (40) are displaced along the lengths of the elongate or longitudinally extending microwave cavities whilst being irradiated with microwaves. In a pasteurization stage (14), the raised temperatures of the in-shell eggs (40) are maintained for a pasteurization time sufficient to pasteurize the in-shell eggs (40).

[Object] To provide a method of producing dried egg white capable of easily and stably obtaining dried egg white having high gel strength, and the dried egg white.

[Solving Means] In this dried egg white, a proportion of an egg white protein having a molecular weight of not less than 97,400 and not more than 340,000 is not less than 35% of a proportion of an egg white protein having a molecular weight of not less than 20,100 and not more than 340,000

A system includes a vacuum chamber, a vacuum source, and a mixture flow path adapted to be connected to receive the output of a direct steam injector. The vacuum source is operatively connected to a vacuum port of the vacuum chamber, while a product outlet port from the vacuum chamber is adapted to be connected to an arrangement for removing treated product from the vacuum chamber. The mixture flow path includes a flow path segment outside of the vacuum chamber volume and a flow path segment within the vacuum chamber volume. At least some of a surface defining the flow path segment within the vacuum chamber is in substantial thermal communication with one or more cooling structures.

A system includes a vacuum chamber, a vacuum source, and a mixture flow path adapted to be connected to receive the output of a direct steam injector. The vacuum source is operatively connected to a vacuum port of the vacuum chamber, while a product outlet port from the vacuum chamber is adapted to be connected to an arrangement for removing treated product from the vacuum chamber. The mixture flow path includes a flow path segment outside of the vacuum chamber volume and a flow path segment within the vacuum chamber volume. At least some of a surface defining the flow path segment within the vacuum chamber is in substantial thermal communication with one or more cooling structures.

An article includes a mixture release component defining a mixture release volume and also includes a heated mixture located within the mixture release volume. The heated mixture includes undenatured meat protein and water condensed from steam. A mixture release opening is included at an outlet end of the mixture release volume and this mixture release opening defines a passage from the mixture release volume to a vacuum chamber volume defined by a vacuum chamber. A vacuum is applied to the vacuum chamber volume. The steam from which the water has condensed comprises steam that has been placed in direct contact with a stream of undenatured meat protein in a direct steam injector having a mixture outlet operatively connected to the mixture release component.

An article includes a mixture release component defining a mixture release volume and also includes a heated mixture located within the mixture release volume. The heated mixture includes undenatured meat protein and water condensed from steam. A mixture release opening is included at an outlet end of the mixture release volume and this mixture release opening defines a passage from the mixture release volume to a vacuum chamber volume defined by a vacuum chamber. A vacuum is applied to the vacuum chamber volume. The steam from which the water has condensed comprises steam that has been placed in direct contact with a stream of undenatured meat protein in a direct steam injector having a mixture outlet operatively connected to the mixture release component.

A heating medium injector includes an injector structure defining a heating medium flow path and a product flow path. The heating medium flow path extends to a contact location, while the product flow path also extends to the contact location. The contact location comprises a location at which the heating medium flow path and product flow path merge within the injector. A mixture flow path is defined within the injector structure between the contact location and an injector outlet of the injector structure and is defined at least in part by a mixture flow path outer surface comprising a mixture flow path wall. A cooling structure extends along both a product flow path boundary wall and the mixture flow path wall so as to traverse a plane extending transverse to the foodstuff flow path at the contact location.