A grain-popping machine and associated pod-based popping method is disclosed. The grain-popping is configured to receive a pod. Each pod includes a plurality of cells, with each cell preferably containing a single grain kernel or seed, flavoring, and a cooking medium such as oil or shortening. In a preferred embodiment, the pod is loaded into the grain-popping machine through a slot so that it is held in position adjacent to a heating element. The heating element is activated to begin a popping sequence. When each grain kernel or seed in the pod reaches popping temperature, it absorbs the flavoring in its cell and ejects through the bottom of the pod, which can be weakened to ease ejection, into a bowl positioned in a receiving area of the grain-popping machine. The pod is then removed and disposed of.

A grain-popping machine and associated pod-based popping method is disclosed. The grain-popping is configured to receive a pod. Each pod includes a plurality of cells, with each cell preferably containing a single grain kernel or seed, flavoring, and a cooking medium such as oil or shortening. In a preferred embodiment, the pod is loaded into the grain-popping machine through a slot so that it is held in position adjacent to a heating element. The heating element is activated to begin a popping sequence. When each grain kernel or seed in the pod reaches popping temperature, it absorbs the flavoring in its cell and ejects through the bottom of the pod, which can be weakened to ease ejection, into a bowl positioned in a receiving area of the grain-popping machine. The pod is then removed and disposed of.

The invention relates to hydraulic control for carrying out a method of producing a cracker from cereals, which are pressure-baked in a heated mold and expanded afterwards. In particular the hydraulic control system, comprising of a plurality of hydraulic cylinders, will lead to an increased expansion speed or an increased speed for opening the dies, resulting in constant high-quality food products.

A grain-popping machine and associated pod-based popping method is disclosed. The grain-popping is configured to receive a pod. Each pod includes a plurality of cells, with each cell preferably containing a single grain kernel or seed, flavoring, and a cooking medium such as oil or shortening. In a preferred embodiment, the pod is loaded into the grain-popping machine through a slot so that it is held in position adjacent to a heating element. The heating element is activated to begin a popping sequence. When each grain kernel or seed in the pod reaches popping temperature, it absorbs the flavoring in its cell and ejects through the bottom of the pod, which can be weakened to ease ejection, into a bowl positioned in a receiving area of the grain-popping machine. The pod is then removed and disposed of.

A grain-popping machine and associated pod-based popping method is disclosed. The grain-popping is configured to receive a pod. Each pod includes a plurality of cells, with each cell preferably containing a single grain kernel or seed, flavoring, and a cooking medium such as oil or shortening. In a preferred embodiment, the pod is loaded into the grain-popping machine through a slot so that it is held in position adjacent to a heating element. The heating element is activated to begin a popping sequence. When each grain kernel or seed in the pod reaches popping temperature, it absorbs the flavoring in its cell and ejects through the bottom of the pod, which can be weakened to ease ejection, into a bowl positioned in a receiving area of the grain-popping machine. The pod is then removed and disposed of.

A food baking apparatus includes a compressible die and a mechanical stop for controlling a die spacing of the compressible die. The mechanical stop includes a supporting system and a mounting element mounted onto the supporting system. The mounting element includes at least one protrusion having a particular amount of protrusion from the mounting element, which amount of protrusion may be adjustable for any single protrusion. By translation or rotation of the supporting system and/or the mounting element during operation of the apparatus, a protrusion is selected. The protrusions mechanically stop further compression of the dies during an operation of the food baking apparatus. Thus, the selection determines the die spacing applicable for the baking process, based on the amount of protrusion of the selected protrusion.

A food baking apparatus includes a compressible die and a mechanical stop for controlling a die spacing of the compressible die. The mechanical stop includes a supporting system and a mounting element mounted onto the supporting system. The mounting element includes at least one protrusion having a particular amount of protrusion from the mounting element, which amount of protrusion may be adjustable for any single protrusion. By translation or rotation of the supporting system and/or the mounting element during operation of the apparatus, a protrusion is selected. The protrusions mechanically stop further compression of the dies during an operation of the food baking apparatus. Thus, the selection determines the die spacing applicable for the baking process, based on the amount of protrusion of the selected protrusion.

A process of forming a crispy pressed snack includes combining at least one expandable plant product having a pre-gelled starch with a plurality of inclusions to form a mixture. The process also includes pressing the mixture together in a mold while applying heat at a temperature less than 220° C. to the mold to steam-cook the inclusions and cook the pre-gelled starch in the expandable plant product. The process further includes expanding the mold to reduce the pressure in the mold, thereby expanding the expandable plant product and forming the crispy pressed snack. A crispy pressed snack includes a mixture including an expanded plant product and pieces of at least one steamed low-starch vegetable. The steamed low-starch vegetable is present at about 10% to about 20%, by weight of the mixture. A starch of the expanded plant product holds the mixture together.

A process of forming a crispy pressed snack includes combining at least one expandable plant product having a pre-gelled starch with a plurality of inclusions to form a mixture. The process also includes pressing the mixture together in a mold while applying heat at a temperature less than 220° C. to the mold to steam-cook the inclusions and cook the pre-gelled starch in the expandable plant product. The process further includes expanding the mold to reduce the pressure in the mold, thereby expanding the expandable plant product and forming the crispy pressed snack. A crispy pressed snack includes a mixture including an expanded plant product and pieces of at least one steamed low-starch vegetable. The steamed low-starch vegetable is present at about 10% to about 20%, by weight of the mixture. A starch of the expanded plant product holds the mixture together.

A dough-based food product, an apparatus and method for production thereof. A food product matrix to be foamed includes a proportion of a starch-containing raw material and a proportion of water. Gas that has been dissolved or is to be dissolved is introduced into the food product matrix to be foamed. The gas is dissolved under pressure in the food product matrix to be foamed. Gas bubbles are formed by expansion and increasing the volume with a resulting reduction in density of the dough as a result of bubble growth for formation of a foamed food product matrix of the food product to be produced. The foam is then stabilized. Gas is introduced into and dissolved in the aqueous component of the food product matrix to be foamed in a subcritical state below the critical point and at a pressure of 10 bar≤p<gas critical pressure.