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An improved antenna assembly (66) designed to maintain RF communication between an object (22, 64, 148) to be heated, and a heating assembly (20, 60) such as an induction heater having a hob (34) equipped with an induction work coil (36). The antenna assembly (66) provides substantially continuous R

An improved antenna assembly (66) designed to maintain RF communication between an object (22, 64, 148) to be heated, and a heating assembly (20, 60) such as an induction heater having a hob (34) equipped with an induction work coil (36). The antenna assembly (66) provides substantially continuous RF communication about the entirety of the hob (34), so that the object (22, 64, 148) can be rotated through substantially 360° , or displaced radially, without loss of RF communication. The preferred antenna assembly (66) includes an antenna (67) mounted upon a substrate (68) and presenting a plurality of continuous, conductive antenna loops (70, 72) oriented to cooperatively and substantially surround the hob (34).

대표청구항 ▼

1. An induction heating system comprising: a component for generating a magnetic field in order to inductively heat an object, said component presenting a heating hob, said magnetic field creating a magnetic flux zone through the heating hob;control circuitry operably coupled with said field generat

1. An induction heating system comprising: a component for generating a magnetic field in order to inductively heat an object, said component presenting a heating hob, said magnetic field creating a magnetic flux zone through the heating hob;control circuitry operably coupled with said field generating component in order to control the operation of the component, including an RFID tag reader and an antenna coupled with the RFID tag reader in order to interrogate a proximal RFID tag associated with said object, and to receive information from said RFID tag,said antenna including a plurality of continuous, conductive antenna loops oriented to cooperatively and substantially surround said heating hob, each of said antenna loops having an inner section proximal to said heating hob and defining a respective, enclosed RF communication region outboard of said inner antenna loop section, said RF communication regions cooperatively defining a substantially continuous RF communication zone located in outwardly spaced relationship from said magnetic flux zone and disposed about the heating hob; andcircuitry including at least two conductive paths coupled with said RFID tag reader,said plurality of antenna loops each having one terminal end connected to at least one of said conductive paths, and having a second terminal end connected to at least one other of said conductive paths, in order to operably couple the RFID tag reader with said antenna, the spacing between said magnetic flux zone and said RF communication zone permitting very little penetration of magnetic flux into the RF communication zone. 2. The induction heating system of claim 1, said component comprising an induction work coil. 3. The induction heating system of claim 1, adjacent ends of said antenna loops being overlapped to cooperatively define a continuous RF communication zone outboard of and surrounding said heating hob. 4. The induction heating system of claim 1, including a substrate supporting said antenna loops and presenting a pair of opposed faces, at least one of said antenna loops on one of said faces, and another of said antenna loops on the other of said faces. 5. The induction heating system of claim 1, there being a pair of said antenna loops. 6. The induction heating system of claim 1, said antenna loops each formed of a pair of closely spaced apart, parallel copper traces. 7. The induction heating system of claim 1, one of said conductive paths being a signal input path from a signal generator, and another of said paths being a ground path. 8. The induction heating system of claim 1, said antenna loop inner sections being arcuate in configuration. 9. The combination comprising: an induction heater including a component for generating a magnetic field, said component presenting a heating hob, said magnetic field creating a magnetic flux zone through the heating hob; andcontrol circuitry operably coupled with said field generating component in order to control the operation of the component; andan induction heatable object having a periphery and positioned over said heating hob in order to be heated by said component, and an RFID tag operably coupled with said periphery of said object,said control circuitry including an RFID tag reader and a multiple loop antenna coupled with the RFID tag reader in order to interrogate said RFID tag and to receive information from said RFID tag,said antenna defining a substantially continuous RF communication zone located in outwardly spaced relationship from said magnetic flux zone and disposed about said heating hob in order to establish RF communication between said RFID tag and said RFID tag reader, the spacing between said magnetic flux zone and said RF communication zone permitting very little penetration of magnetic flux into the RF communication zone,whereby said object may be rotated to a plurality of respective positions through substantially 360 degrees of rotation while maintaining said RF communication zone between said RFID tag and said RFID tag reader. 10. The combination of claim 9, said antenna comprising: a plurality of continuous, conductive antenna loops oriented to cooperatively and substantially surround said heating hob, each of said antenna loops having an inner section proximal to said heating hob and defining a respective, enclosed RF communication region outboard of said inner antenna loop section, said RF communication regions cooperatively defining a substantially continuous RF communication zone outboard of and disposed about the heating hob; andcircuitry including at least two conductive paths adapted for coupling with a signal generator,said plurality of antenna loops each having one terminal end connected to at least one of said conductive paths, and having a second terminal end connected to at least one other of said conductive paths. 11. The combination of claim 10, one of said conductive paths being a signal input path from a signal generator, and another of said paths being a ground path. 12. The combination of claim 9, said induction heatable object being a food heating vessel. 13. The combination of claim 9, adjacent ends of said antenna loops being overlapped to cooperatively define a continuous RF communication zone outboard of and surrounding said heating hob. 14. The combination of claim 9, including a substrate supporting said antenna loops and presenting a pair of opposed faces, at least one of said antenna loops on one of said faces, and another of said antenna loops on the other of said faces. 15. The combination of claim 9, there being a pair of said antenna loops. 16. The combination of claim 9, said antenna loops each formed of a pair of closely spaced apart, parallel copper traces. 17. The combination of claim 9, said antenna loop inner sections being arcuate in configuration.