A method for preparing frozen or refrigerated fried eggs from whole, fresh eggs, the method comprising: breaking whole, fresh eggs (1) into a support (3) impregnated with edible fat; introducing the support (3) carrying the broken whole fresh eggs (2) into an oven (4) comprising ventilation means; heating the oven until the inner part of the yolk of the broken whole fresh eggs reaches a temperature of 65 to 73 C.; taking said support carrying the eggs out of the oven, wherein said eggs are fried eggs; cooling the fried eggs for reducing their residual heat in order to prevent the inner part of the yolk to exceed 73 C.; freezing or refrigerating the cooled fried eggs.

The present invention concerns an ethanol with an alcohol by volume between 85% and 99%, and comprising a Hydroxy-Alkyl-Cellulose, the dosage of Hydroxy-Alkyl-Cellulose being limited so as to obtain a dynamic viscosity of less than 100 Pa.Math.s.

This invention also concerns the use of such ethanol as combustible for cooking a foodstuff, or part of a foodstuff, in particular for safely cooking in the immediate vicinity of the person for whom the food is intended, so as to use cooking as a show.

Methods and devices for determining the cooked state of eggs. These are characterised in particular in that the cooked state of the egg can be monitored and/or the cooking process can be ended when a desired cooked state has been reached. To this end, an egg is positioned in a vessel, the temperature is increased, and at least one light source is positioned on or in the direct vicinity of the egg. The transmission of light through the egg is determined and a transmission of at least 96% of the maximum transmission degree of a raw egg is achieved for a runny yolk, of at least 94% is achieved for a soft yolk, of at least 90% is achieved for a medium soft yolk, and at least 85% is achieved for a hard yolk.

Methods and devices for determining the cooked state of eggs. These are characterised in particular in that the cooked state of the egg can be monitored and/or the cooking process can be ended when a desired cooked state has been reached. To this end, an egg is positioned in a vessel, the temperature is increased, and at least one light source is positioned on or in the direct vicinity of the egg. The transmission of light through the egg is determined and a transmission of at least 96% of the maximum transmission degree of a raw egg is achieved for a runny yolk, of at least 94% is achieved for a soft yolk, of at least 90% is achieved for a medium soft yolk, and at least 85% is achieved for a hard yolk.

Packaged aquafaba having a protein content by weight of at least 0.5%. The packaged aquafaba is provided in liquid form and packaged in a pouch. Methods of making aquafaba and of using aquafaba and the products resulting therefrom are also disclosed.

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 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.

The present invention relates to frozen liquid egg whites in which are admixed 0.01-0.4 parts of egg yolks for every 100 parts of egg whites, wherein 0.1-2 parts inclusive of -cyclodextrin are added for every 100 parts of liquid egg whites, and the turbidity H1 (degrees) calculated by means of the belowmentioned formula (1) is 18 or more: H1=H2H3 . . . (1). Here, H2 indicates the turbidity (degrees) of the frozen liquid egg whites measured immediately after being defrosted, and H3 indicates the egg-derived turbidity y (degrees) calculated by means of the belowmentioned approximation formula (2): y=380.75x.sup.2+272.42x+17.257 . . . (2). Here, x indicates the admixed amount (parts) of egg yolks for every 100 parts of liquid egg whites.

The present invention relates to frozen liquid egg whites in which are admixed 0.01-0.4 parts of egg yolks for every 100 parts of egg whites, wherein 0.1-2 parts inclusive of -cyclodextrin are added for every 100 parts of liquid egg whites, and the turbidity H1 (degrees) calculated by means of the belowmentioned formula (1) is 18 or more: H1=H2H3 . . . (1). Here, H2 indicates the turbidity (degrees) of the frozen liquid egg whites measured immediately after being defrosted, and H3 indicates the egg-derived turbidity y (degrees) calculated by means of the belowmentioned approximation formula (2): y=380.75x.sup.2+272.42x+17.257 . . . (2). Here, x indicates the admixed amount (parts) of egg yolks for every 100 parts of liquid egg whites.

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).