A high efficiency heating apparatus for heating fluids and cooking mediums, such as oil or shortening within a fryer, includes a natural draft (non powered) combustion chamber that is affixed to an exterior surface of a fry tank.

A system for delivering a cooling agent to cooking appliance to aid in fire suppression is disclosed, which includes a fuel delivery path extending from a source of cooking fuel to a heating element of the cooking appliance, a source of cooling agent selectively in fluid communication with the fuel delivery path, and a valve assembly associated with the fuel delivery path and the source of cooling agent, wherein the valve assembly is configured to control the delivery of cooling agent to the heating element of the cooking appliance and shut off the heating element from the source of cooking fuel in the event of a fire.

A fryer unit combination includes a frying fluid vat and an associated heat exchange system whereby increased or greater efficiencies and/or heat transfers can be obtained and realized. The heat exchange system includes a first heat exchanger arrangement at least in part disposed within the frying fluid vat and a second heat exchanger arrangement disposed externally to the frying fluid vat. In the first heat exchanger arrangement, a heat exchange tube is in heat flow communication with a combustion chamber wherein an associated gaseous fuel burner is at least in part housed. The second heat exchanger arrangement includes at least a first side heat exchanger disposed externally adjacent the first side of the frying fluid vat. The side heat exchanger(s) may permit intake of an oxygen-containing gas such to preheat the oxygen-containing gas prior to entrance into the combustion chamber.

Systems and methods for delivering a cooking medium in a cooking apparatus are disclosed. A delivery system includes a rotary valve having a rotary inlet and a plurality of rotary outlets. The rotary inlet is configured to be in fluid communication with a source of cooking medium and the plurality of rotary outlets are configured to be in fluid communication with a corresponding plurality of receptacles. A rotary position sensor generates a signal, having continuous angular position resolution, based on an angular position of the rotary valve. A controller receives the signal generated by the rotary position sensor and selectively places the rotary inlet in fluid communication with one of the plurality of rotary outlets based on the signal generated by the rotary position sensor. The rotary position sensor may include a Hall-effect sensor that functions at elevated operating temperatures associated with the cooking medium.

A high efficiency heating apparatus for heating fluids and cooking mediums, such as oil or shortening within a fryer, includes a natural draft (non powered) combustion chamber that is affixed to an exterior surface of a fry tank.

A high efficiency heating apparatus for heating fluids and cooking mediums, such as oil or shortening within a fryer, includes a natural draft (non powered) combustion chamber that is affixed to an exterior surface of a fry tank.

A high efficiency heating apparatus for heating fluids and cooking mediums, such as oil or shortening within a fryer, includes a natural draft (non powered) combustion chamber with internal baffles that is affixed to an exterior surface of a fry tank.

Systems, methods, and computer program products are disclosed for controlling a fryer. In response to determining a filtration cycle is scheduled to occur after a current cooking cycle, a temperature set-point for a cooking medium is increased to pre-heat the cooking medium prior to the end of the cooking cycle. A heating element used to heat the cooking medium may be deactivated prior to entering the filtration cycle, and reactivated during the filtration cycle in response to the filtered cooking medium in the fry pot reaching a predetermined level. Activating the heating element during the filtration cycle may further heat the cooking medium prior to starting the next cooking cycle, thereby reducing the total time needed for filtration and reheating for a subsequent cooking cycle.

A metal heat exchange tube assembly for a fryer cooking channel of a hot oil fryer for food-process lines has a plurality of elongate, rectangular, longitudinally-extending heat exchange tubes with open inflow and outflow ends; a laterally-extending abbreviated rectangular inflow-manifold tube with a plurality of apertures in a sidewall; and a laterally-extending abbreviated rectangular outflow-manifold tube with the same. The plurality of heat exchange tubes are joined to the inflow-manifold and outflow-manifold tubes with respective alignment among the open ends of the heat exchange tubes and the apertures in the sidewalls of the manifold tubes. The heat exchange tubes comprise a composite construction of an elongate, square-U shaped channel having a web bottom wall and flange sidewalls of a given uniform thickness, and an elongate closure strip welded along spaced seams to the exposed upper edges of the flanges of the channel, thereby forming a thermal oil conduit.

Method and a deep frying device for deep frying a food product in a deep frying device, wherein the deep frying device comprises a container for fat. For reducing the chances of damaging the deep frying device by the deep frying and increasing the availability, use is made of a deep frying device comprising a pipe section for hot flue gas which protrudes into the lumen of the container but is not connected to an opposite wall. The pipe section comprises—a plurality of supply pipes for the relatively hot flue gas, and—at least one outlet pipe for the relatively cold flue gas coming from the plurality of supply pipes.