A cooking utensil having a handle and a rigid metal scraper head connected to the handle is disclosed. The scraper head may include a squeegee blade holder formed thereon, or attached thereto. A squeegee blade may be securely disposed in the squeegee blade holder.

A cooking utensil having a handle and a rigid metal scraper head connected to the handle is disclosed. The scraper head may include a squeegee blade holder formed thereon, or attached thereto. A squeegee blade may be securely disposed in the squeegee blade holder.

A foreign substance trap device according to an embodiment of the present disclosure includes: a first member in which at least one fluid intake hole is formed; a second member in which at least a portion of an exhaust channel, through which gas in liquid flowing inside through the fluid intake hole is discharged, is formed; and a movable member movably disposed between the first member and the second member and closing the exhaust channel by being moved by liquid in fluid flowing inside through the fluid intake hole.

A foreign substance trap device according to an embodiment of the present disclosure includes: a first member in which at least one fluid intake hole is formed; a second member in which at least a portion of an exhaust channel, through which gas in liquid flowing inside through the fluid intake hole is discharged, is formed; and a movable member movably disposed between the first member and the second member and closing the exhaust channel by being moved by liquid in fluid flowing inside through the fluid intake hole.

A processing system (10) and corresponding method (158) are provided for processing workpieces (WP), including food items, to cut and remove undesirable components from the food items and/or portion the food items while being conveyed on a conveyor system (12). An X-ray scanning station (14) is located on an upstream conveyor section (20) to ascertain size and/or shape parameters of the food items as well as the location of any undesirable components of the food items, such as bones, fat or cartilage. Thereafter the food items are transferred to a downstream conveyor (20) at which is located an optical scanner (102) to ascertain the size and/or shape parameters of the food items. The results of the X-ray and optical scanning are transmitted to a processor (18) to confirm that the food item scanned by the optical scanner is the same as that previously scanned by the X-ray scanner. Once this identity is confirmed, if required, the data from the X-ray scanner is translated or transformed onto the data from the optical scanner. Such translation may include one or more of the shifting of the food items in the X and/or Y direction, rotation of the food item, scaling of the size of the food item, and sheer distortion of the food item. Next, the location of the undesirable material within the food item is mapped from the X-ray scanning data onto the optical scanning data. Thereafter, the undesirable material is removed by a cutter(s) (28). The food item may also (or alternatively) been portioned by the cutter(s) (28).

A processing system (10) and corresponding method (158) are provided for processing workpieces (WP), including food items, to cut and remove undesirable components from the food items and/or portion the food items while being conveyed on a conveyor system (12). An X-ray scanning station (14) is located on an upstream conveyor section (20) to ascertain size and/or shape parameters of the food items as well as the location of any undesirable components of the food items, such as bones, fat or cartilage. Thereafter the food items are transferred to a downstream conveyor (20) at which is located an optical scanner (102) to ascertain the size and/or shape parameters of the food items. The results of the X-ray and optical scanning are transmitted to a processor (18) to confirm that the food item scanned by the optical scanner is the same as that previously scanned by the X-ray scanner. Once this identity is confirmed, if required, the data from the X-ray scanner is translated or transformed onto the data from the optical scanner. Such translation may include one or more of the shifting of the food items in the X and/or Y direction, rotation of the food item, scaling of the size of the food item, and sheer distortion of the food item. Next, the location of the undesirable material within the food item is mapped from the X-ray scanning data onto the optical scanning data. Thereafter, the undesirable material is removed by a cutter(s) (28). The food item may also (or alternatively) been portioned by the cutter(s) (28).

A cooking appliance is provided. The cooking appliance may include a guide that regulates an installation position of a water supply device with respect to a front panel. The guide may include a first guide coupled to the water supply device to align a relative position of a front surface of the water supply device with respect to the front panel, a second guide coupled to a guide protrusion to align a relative position of the guide with respect to an opening; and a fixer that fixes the guide to the cavity.

A cooking appliance is provided. The cooking appliance may include a guide that regulates an installation position of a water supply device with respect to a front panel. The guide may include a first guide coupled to the water supply device to align a relative position of a front surface of the water supply device with respect to the front panel, a second guide coupled to a guide protrusion to align a relative position of the guide with respect to an opening; and a fixer that fixes the guide to the cavity.

A cooking device includes an outer pot having a mounting cavity, an inner pot assembly removably arranged in the mounting cavity, a first coupler arranged at the inner pot assembly, an accommodation groove arranged at one of the inner pot assembly and the outer pot, an alignment assembly arranged at another one of the inner pot assembly and the outer pot and configured to be arranged in the accommodation groove, and a second coupler arranged at the outer pot and configured to be plugged with the first coupler.

Disclosed is a method for evaluating cooking quality that includes: in response to receiving evaluation information of a food sent by a terminal, retrieving an assessment result corresponding to the food, the assessment result being an assessment result of the cooking quality of a cooking appliance; and determining an evaluation result of the cooking quality of the cooking appliance based on the assessment result, the evaluation information, and a preset evaluation rule. Also disclosed is a device for evaluating cooking quality. With this disclosure, both the assessment result and the evaluation information are weighted in computing the evaluation result of the cooking quality of the cooking appliance. Such an evaluation result not only reflects users' subjective evaluation of the cooking quality, but it also reflects an objective and tenable evaluation of the cooking quality, making the evaluation of the cooking quality more reasonable.