A low-cost and high-precision current sensing device and methods for use and manufacturing. In one embodiment, the current sensing apparatus comprises a Rogowski-type coil which is manufactured in segments so as to facilitate the manufacturing process. In an exemplary embodiment, the current sensing
A low-cost and high-precision current sensing device and methods for use and manufacturing. In one embodiment, the current sensing apparatus comprises a Rogowski-type coil which is manufactured in segments so as to facilitate the manufacturing process. In an exemplary embodiment, the current sensing apparatus segments comprise a number of bobbin elements that are wound and subsequently formed into complex geometric shapes such as torus-like shapes. In an alternative embodiment, bonded windings are utilized which allow the segments to be formed without a bobbin or former. In yet another alternative embodiment, the aforementioned current sensing devices are stacked in groups of two or more. Methods of manufacturing and using the aforementioned current sensing apparatus are also disclosed.
대표청구항▼
1. A current sensing inductive device, comprising: a plurality of bobbin elements, each element having at least a portion of a conductive winding wound thereon; anda return conductor configured to electrically couple a leading one of the plurality of bobbin elements with a trailing one of the plural
1. A current sensing inductive device, comprising: a plurality of bobbin elements, each element having at least a portion of a conductive winding wound thereon; anda return conductor configured to electrically couple a leading one of the plurality of bobbin elements with a trailing one of the plurality of bobbin elements;wherein a first bobbin element of the plurality of bobbin elements includes a first conductive element, the first conductive element configured to electrically couple the return conductor to a first end of the conductive winding;wherein at least two of the plurality of bobbin elements are physically coupled to one another via a hinged coupling; andwherein the hinged coupling comprises: a pair of outer hinge features disposed on a first one of the plurality of bobbin elements;a pair of inner hinge features disposed on a second one of the plurality of bobbin elements; anda hinge pin disposed within the pairs of inner and outer hinge features. 2. The inductive device of claim 1, further comprising a second conductive element disposed on a third one of the plurality of bobbin elements, the second conductive element attached to an end of the conductive winding that is opposite from the first end of the conductive winding. 3. The inductive device of claim 2, wherein the second conductive element is bent at a defined angle with respect to an exterior surface of the third one of the plurality of bobbin elements. 4. The inductive device of claim 1, wherein the first bobbin element comprises a winding barrel and a flange disposed on an end portion of the winding barrel; and wherein the first conductive element is disposed on the flange of the first bobbin element. 5. The inductive device of claim 1, further comprising a housing that encases the plurality of bobbin elements, the housing including a hinge pin receiving aperture sized to accommodate the hinge pin. 6. The inductive device of claim 5, wherein the housing further comprises a plurality of hinge pin receiving apertures, the hinge pin receiving apertures configured to position and align the plurality of bobbin elements with respect to one another. 7. The inductive device of claim 1, wherein each of the plurality of bobbin elements further comprises a pair of flanges with a winding spool disposed there between, the conductive winding wound onto the winding spool. 8. The inductive device of claim 1, wherein the conductive winding of each bobbin element further comprises a portion of a continuous winding conductor. 9. A current sensing inductive device, comprising: one or more bobbin elements, each bobbin element having at least one winding disposed thereon, the at least one winding disposed in one or more layers of windings; anda return conductor configured to electrically couple a leading one of the one or more bobbin elements with a trailing one of the one or more bobbin elements;wherein at least a first one of the bobbin elements is physically coupled to a second one of the bobbin elements via a hinged coupling; andwherein the hinged coupling comprises: a pair of outer hinge features disposed on the first one of the bobbin elements;a pair of inner hinge features disposed on the second one of the bobbin elements; anda hinge pin disposed within the pairs of inner and outer hinge features. 10. The inductive device of claim 9, wherein the at least one winding of each bobbin element comprises a portion of a continuous winding conductor. 11. The inductive device of claim 9, further comprising a housing configured to encase the one or more bobbin elements, the housing including a hinge pin receiving aperture sized to accommodate the hinge pin. 12. A current sensing inductive device, comprising: a plurality of bobbin elements, each bobbin element having at least one winding disposed thereon, the at least one winding disposed in one or more layers of windings;wherein at least a first one of the plurality of bobbin elements comprises a pair of flanges configured to have a winding spool disposed there between, the at least one winding wound onto the winding spool;wherein the at least first one of the plurality of bobbin elements is physically coupled to a second one of the plurality of bobbin elements via a hinged coupling; andwherein the hinged coupling comprises: an outer hinge feature disposed on the first one of the bobbin elements, the outer hinge feature comprises an aperture and a cavity; andan inner hinge feature disposed on the second one of the bobbin elements, the inner hinge feature comprises a coupling element comprised of a winding spool portion and an insertable portion;wherein the outer hinge feature is configured to be coupled to the inner hinge feature; andwherein the winding spool portion of the second one of the plurality of bobbin elements fits within the cavity of the first one of the plurality of bobbin elements, while the insertable portion of the second one of the plurality of bobbin elements simultaneously fits within the aperture of the first one of the plurality of bobbin elements. 13. The inductive device of claim 12, wherein the hinged coupling comprises a moveably hinged coupling. 14. The inductive device of claim 13, wherein the at least one winding of each bobbin element comprises a portion of a continuous winding conductor. 15. The inductive device of claim 14, further comprising a housing configured to encase the plurality of bobbin elements. 16. The inductive device of claim 15, wherein the housing further comprises a plurality of alignment apertures, the alignment apertures adapted to position and align the plurality of bobbin elements with respect to one another. 17. The inductive device of claim 16, further comprising a first conductive element that is disposed on a flange of at least one of the plurality of bobbin elements. 18. A current sensing inductive device, comprising: a plurality of segmented winding elements that are disposed adjacent one another, the plurality of segmented winding elements comprised of a start segmented winding element disposed at one end of the plurality of segmented winding elements and a finish segmented winding element disposed at the other end of the plurality of segmented winding elements, each of the plurality of segmented winding elements comprising a plurality of turns of a conductive winding that runs between the start segmented winding element and the finish segmented winding element, the plurality of turns disposed in a plurality of layers;a shielding layer comprising a plurality of shielding layer turns of the conductive winding on each of the plurality of segmented winding elements, the plurality of shielding layer turns being disposed atop the plurality of turns of the conductive winding, the shielding layer being secured to a conductive terminal disposed proximate the finish segmented winding element and comprising an open connection disposed within the start segmented winding element;a return wire that runs continuously between the finish segmented winding element of the plurality of segmented winding elements and the start segmented winding element of the plurality of segmented winding elements, the return wire traversing continuously along each of the plurality of segmented winding elements; anda start portion for the plurality of turns of the conductive winding and a finish portion for the return wire is disposed adjacent the start segmented winding element. 19. The current sensing inductive device of claim 18, wherein the plurality of segmented winding elements each comprise a discrete bobbin element. 20. The current sensing inductive device of claim 19, wherein the discrete bobbin element associated with the finish segmented winding element comprises the conductive terminal upon which the shielding layer is secured; and wherein the discrete bobbin element associated with the start segmented winding element comprises a second conductive terminal upon which the start portion for the plurality of turns of the conductive winding is secured. 21. The current sensing inductive device of claim 20, wherein each of the discrete bobbin elements comprises a winding barrel and a pair of flanges; and wherein the conductive terminal and the second conductive terminal are each disposed within respective flanges on the discrete bobbin element associated with the finish segmented winding element and the discrete bobbin element associated with the start segmented winding element. 22. The current sensing inductive device of claim 21, wherein the shielding layer and the plurality of layers are comprised of an identically-sized conductive wire. 23. The current sensing inductive device of claim 22, wherein the open connection of the shielding layer is disposed within the winding barrel associated with the discrete bobbin element associated of the start segmented winding element. 24. The current sensing inductive device of claim 20, further comprising a housing; wherein the plurality of segmented winding elements are disposed in an interior of the housing; andwherein a finish wire is coupled to the start portion for the plurality of turns of the conductive winding, the finish wire extending from the interior of the housing to a point external to the housing.
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