The invention relates to a device and a method for a contactless analysis of a product, in particular for the contactless analysis of a dough product. The device comprises a distance sensor configured for measuring a distance between the device and the product, and a nozzle configured for directing a jet of pressurized fluid to a position on a surface of said product. The distance sensor is arranged for measuring the distance between the device and the position of the surface where the jet of pressurized fluid is directed to. Preferably, the distance sensor is at least partially arranged in the nozzle, preferably substantially in the center of said nozzle.

A method of manufacture of a bread, the bread comprising a pocket and having at least one open edge, the method comprising: preparing a dough; working the dough into a sheet including dusting a surface of the sheet of dough with additional flour; proofing the sheet of dough in a proofing room having a pre-determined humidity level, such that a moisture content of the additional surface flour is increased; cutting the proofed sheet of dough into a plurality of substantially tessellating shaped portions; baking each portion to form a bread, such that steam is generated during baking and forms a pocket in the bread; and cutting each bread into at least two parts, each part forming a pocket bread having at least one open edge, the open edge providing access to the pocket, wherein a secondary opening process is not required to provide access to the pocket.

A method of manufacture of a bread, the bread comprising a pocket and having at least one open edge, the method comprising: preparing a dough; working the dough into a sheet including dusting a surface of the sheet of dough with additional flour; proofing the sheet of dough in a proofing room having a pre-determined humidity level, such that a moisture content of the additional surface flour is increased; cutting the proofed sheet of dough into a plurality of substantially tessellating shaped portions; baking each portion to form a bread, such that steam is generated during baking and forms a pocket in the bread; and cutting each bread into at least two parts, each part forming a pocket bread having at least one open edge, the open edge providing access to the pocket, wherein a secondary opening process is not required to provide access to the pocket.

A heat treatment monitoring system comprises a sensor unit having at least one sensor to determine current sensor data of food being heated; a processing unit to determine current feature data from the current sensor data; and a monitoring unit adapted to determine a current heating process state in a current heating process of the monitored food by comparing the current feature data with reference feature data of a reference heating process.

A heat treatment monitoring system comprises a sensor unit having at least one sensor to determine current sensor data of food being heated; a processing unit to determine current feature data from the current sensor data; and a monitoring unit adapted to determine a current heating process state in a current heating process of the monitored food by comparing the current feature data with reference feature data of a reference heating process.

Ovens and methods for preparing food. An oven includes a cabinet and an oven chamber in the cabinet. A fan is provided for moving gas in the oven. The oven can include a fan scroll housing having multiple fan discharge ducts defining respective gas flow paths from the fan. The oven can include a turning vane configured for turning gas flow and for heating the gas flow.

Ovens and methods for preparing food. An oven includes a cabinet and an oven chamber in the cabinet. A fan is provided for moving gas in the oven. The oven can include a fan scroll housing having multiple fan discharge ducts defining respective gas flow paths from the fan. The oven can include a turning vane configured for turning gas flow and for heating the gas flow.

A cooking appliance includes a body having a first cavity. A sensor is operably coupled with the first cavity to obtain a first data. A humidifier is in fluid communication with the first cavity to control a relative humidity within the first cavity. A controller is in electric communication with the sensor to receive the first data. The controller detects at least one of a surface condition and a growth condition of a food substrate using the first data.

A heat treatment monitoring system comprises a sensor unit having at least one sensor to determine current sensor data of food being heated; a processing unit to determine current feature data from the current sensor data; and a monitoring unit adapted to determine a current heating process state in a current heating process of the monitored food by comparing the current feature data with reference feature data of a reference heating process.

A heat treatment monitoring system comprises a sensor unit having at least one sensor to determine current sensor data of food being heated; a processing unit to determine current feature data from the current sensor data; and a monitoring unit adapted to determine a current heating process state in a current heating process of the monitored food by comparing the current feature data with reference feature data of a reference heating process.