Abstract: In various examples, a system for wirelessly transmitting power using resonant magnetic field power transfer includes a device including at least one component to be wirelessly powered. The device includes an elongate shaft and a capture element including a capture coil. A source element for wirelessly supplying power to the device includes a source coil disposed around an opening. The opening is sized to allow the elongate shaft of the device to fit therein. The source is located proximate a surgical access point, wherein, with insertion of the elongate shaft within the opening of the source for surgical access, the capture coil is disposed sufficiently proximate the source coil to allow power to be wirelessly transmitted from the source coil to the capture coil to power the at least one component of the device.

Abstract: In various examples, a system includes a power generating device configured to generate and transfer power to an electrical device. A sterilizable vessel is configured to accommodate the electrical device. The vessel is configured to allow power to be at least partially wirelessly transferred from the power generating device, through the vessel, and to the electrical device. In other examples, a method includes wirelessly powering and/or charging an electrical device disposed within a sterilizable vessel.

Abstract: In various examples, a system includes a power generating device configured to generate and transfer power to an electrical device. A sterilizable vessel is configured to accommodate the electrical device. The vessel is configured to allow power to be at least partially wirelessly transferred from the power generating device, through the vessel, and to the electrical device. In other examples, a method includes wirelessly powering and/or charging an electrical device disposed within a sterilizable vessel.

Abstract: In various examples, a system includes a power generating device configured to generate and transfer power to an electrical device. A sterilizable vessel is configured to accommodate the electrical device. The vessel is configured to allow power to be at least partially wirelessly transferred from the power generating device, through the vessel, and to the electrical device. In other examples, a method includes wirelessly powering and/or charging an electrical device disposed within a sterilizable vessel.

Abstract: A system for wirelessly charging an electrical energy storage device such as an electrochemical cell or battery pack is described. The system comprises a transmitting base unit having a charging tray that is capable of wirelessly transmitting electrical power received from an external electrical energy source. In addition, the system comprises an electrical energy capture assembly that is electrically incorporatable with an energy storage device. The energy capture assembly comprises a receiving coil that is electrically connected to various sub-circuits that condition and modify the wirelessly received electrical energy so that it re-charges the energy storage device. The system is primarily designed to be used with electrical power that is wirelessly transmitted by near field magnetic induction. The circuitry of the system is designed to accommodate for fluctuations in magnitude of wirelessly transmitted electrical power.

Abstract: A system for wirelessly charging an electrical energy storage device such as secondary electrochemical cell or battery pack of at least two electrically connected secondary cells is described. The system comprises an electrical energy capture circuit and capture coil that is electrically incorporatable with an energy storage device. The system is primarily designed to be used with electrical power that is wirelessly transmitted by near field magnetic induction. The energy transmitting circuit and coil may be incorporated within a container designed to hold or enclose an energy storage device during an autoclave sterilization process. In addition, a wireless energy adapter configured with the energy capture circuit designed to facilitate wireless charging of an energy storage device is disclosed. Furthermore, a cart designed to provide a mobile wireless energy source is disclosed.

Abstract: In various examples, a system includes a power generating device configured to generate and transfer power to an electrical device. A sterilizable vessel is configured to accommodate the electrical device. The vessel is configured to allow power to be at least partially wirelessly transferred from the power generating device, through the vessel, and to the electrical device. In other examples, a method includes wirelessly powering and/or charging an electrical device disposed within a sterilizable vessel.

Abstract: In various examples, a system includes a power generating device configured to generate and transfer power to an electrical device. A sterilizable vessel is configured to accommodate the electrical device. The vessel is configured to allow power to be at least partially wirelessly transferred from the power generating device, through the vessel, and to the electrical device. In other examples, a method includes wirelessly powering and/or charging an electrical device disposed within a sterilizable vessel.

Abstract: In various examples, a system for wirelessly transmitting power using resonant magnetic field power transfer includes a device including at least one component to be wirelessly powered. The device includes an elongate shaft and a capture element including a capture coil. A source element for wirelessly supplying power to the device includes a source coil disposed around an opening. The opening is sized to allow the elongate shaft of the device to fit therein. The source is located proximate a surgical access point, wherein, with insertion of the elongate shaft within the opening of the source for surgical access, the capture coil is disposed sufficiently proximate the source coil to allow power to be wirelessly transmitted from the source coil to the capture coil to power the at least one component of the device.

Abstract: A circuit for transferring wireless electrical energy through a lossy material is described. The circuit comprises a first inductive winding portion connected electrically in series to a second inductive winding portion and at least one capacitor. Interaction of the first or second inductive winding portions with an electromagnetic field emanating from an electrical power source causes electrical energy to be induced within the circuit. The first inductive winding portion is preferably positionable adjacent a first sidewall of a lossy material and the second inductive winding portion is preferably positionable adjacent the second and opposite sidewall of the lossy material. At least one intermediate substrate composed of a ferrite material is preferably positioned between the first and second inductive winding portions as a shield that minimizes electromagnetic field interference.

Abstract: A system for wirelessly charging an electrical energy storage device such as secondary electrochemical cell or battery pack of at least two electrically connected secondary cells is described. The system comprises an electrical energy capture circuit and capture coil that is electrically incorporatable with an energy storage device. The system is primarily designed to be used with electrical power that is wirelessly transmitted by near field magnetic induction. The energy transmitting circuit and coil may be incorporated within a container designed to hold or enclose an energy storage device during an autoclave sterilization process. In addition, a wireless energy adapter configured with the energy capture circuit designed to facilitate wireless charging of an energy storage device is disclosed. Furthermore, a cart designed to provide a mobile wireless energy source is disclosed.

Abstract: In various examples, a system includes a power generating device configured to generate and transfer power to an electrical device. A sterilizable vessel is configured to accommodate the electrical device. The vessel is configured to allow power to be at least partially wirelessly transferred from the power generating device, through the vessel, and to the electrical device. In other examples, a method includes wirelessly powering and/or charging an electrical device disposed within a sterilizable vessel.

Abstract: A power control circuit for wirelessly powering a device is described. The circuit comprises a series of sub-circuits that condition and modify electrical power received from near-field resonant inductive coupling. In addition, the power control circuit consists of a reserve power source of at least one capacitor. A switching circuit consisting of an ideal diode OR-ing circuit is provided that receives and selects between the primary and secondary electrical power sources based on their measured voltages.

Abstract: A system for harnessing and conditioning wirelessly transmitted electrical energy by near field magnetic induction configured with various magnetic field shielding embodiments is disclosed. The shielding embodiments are designed to minimize electromagnetic interference and induced electrical current. The system comprises an electrical energy capture circuit and an RF communication circuit. The electrical energy capture circuit conditions and modifies the wirelessly received electrical energy. The RF communication circuit enables the system to wirelessly communicate with its sub-circuits and other energy capture systems. The system comprises a tunable band stop filter that is electrically connected to the RF communication sub-circuit. In addition, the RF communication sub-circuit is configured with opposing electrically conductive plates that isolate and shield the circuit from an oscillating magnetic field.

Abstract: A system for harnessing and conditioning wirelessly transmitted electrical energy by near field magnetic induction configured with various magnetic field shielding embodiments is disclosed. The shielding embodiments are designed to minimize electromagnetic interference and induced electrical current. The system comprises an electrical energy capture circuit and an RF communication circuit. The electrical energy capture circuit conditions and modifies the wirelessly received electrical energy. The RF communication circuit enables the system to wirelessly communicate with its sub-circuits and other energy capture systems. The system comprises a tunable band stop filter that is electrically connected to the RF communication sub-circuit. In addition, the RF communication sub-circuit is configured with opposing electrically conductive plates that isolate and shield the circuit from an oscillating magnetic field.

Abstract: A system for wirelessly charging an electrical energy storage device such as an electrochemical cell or battery pack is described. The system comprises a transmitting base unit having a charging tray that is capable of wirelessly transmitting electrical power received from an external electrical energy source. In addition, the system comprises an electrical energy capture assembly that is electrically incorporatable with an energy storage device. The energy capture assembly comprises a receiving coil that is electrically connected to various sub-circuits that condition and modify the wirelessly received electrical energy so that it re-charges the energy storage device. The system is primarily designed to be used with electrical power that is wirelessly transmitted by near field magnetic induction. The circuitry of the system is designed to accommodate for fluctuations in magnitude of wirelessly transmitted electrical power.

Abstract: A circuit for transferring wireless electrical energy through a lossy material is described. The circuit comprises a first inductive winding portion connected electrically in series to a second inductive winding portion and at least one capacitor. Interaction of the first or second inductive winding portions with an electromagnetic field emanating from an electrical power source causes electrical energy to be induced within the circuit. The first inductive winding portion is preferably positionable adjacent a first sidewall of a lossy material and the second inductive winding portion is preferably positionable adjacent the second and opposite sidewall of the lossy material. At least one intermediate substrate composed of a ferrite material is preferably positioned between the first and second inductive winding portions as a shield that minimizes electromagnetic field interference.

Abstract: An electrical circuit designed to dynamically connect or disconnect an electrochemical cell to or from an electrical load based on the measured value of the discharge voltage generated by the cell is discussed. When the measured discharge voltage of an electrochemical cell is less than the threshold voltage, the cell is disconnected from an electrical load and when the discharge voltage is the same as, or greater than, the threshold voltage, the electrochemical cell is connected to an electrical load. The circuit is configured so that the value of the threshold voltage increases from an initial value when the electrochemical cell is first disconnected from the electrical load.