公开(公告)号：US09821112B2

公开(公告)日：2017-11-21

申请号：US15262639

申请日：2016-09-12

Applicant: Medtronic, Inc.

Inventor： David P. Olson ,  William C. Phillips ,  Andrew L. Schmeling

IPC: A61N1/37 ,  A61M5/142 ,  H02J7/02 ,  A61N1/378 ,  A61M5/172 ,  A61N1/365 ,  H02J50/12 ,  H02J7/04

CPC classification number: A61M5/14276 ,  A61M5/142 ,  A61M5/1723 ,  A61M2205/3327 ,  A61M2205/3368 ,  A61M2205/52 ,  A61M2205/8206 ,  A61M2205/8237 ,  A61M2209/01 ,  A61N1/3655 ,  A61N1/3787 ,  H02J7/025 ,  H02J7/047 ,  H02J50/12 ,  H02J50/70

Abstract: A mechanism for transferring energy from an external power source to an implantable medical device is disclosed. A sensor may be used to measure a parameter that correlates to a temperature of the system that occurs during the transcutaneous coupling of energy. For example, the sensor may measure temperature of a surface of an antenna of the external power source. The measured parameter may then be compared to a programmable limit. A control circuit such as may be provided by the external power source may then control the temperature based on the comparison. The programmable limit may be, for example, under software control so that the temperature occurring during transcutaneous coupling of energy may be modified to fit then-current circumstances.

公开(公告)号：US09653935B2

公开(公告)日：2017-05-16

申请号：US13783761

申请日：2013-03-04

Applicant: Medtronic, Inc.

Inventor： Peng Cong ,  Venkat R. Gaddam ,  David P. Olson ,  Erik R. Scott ,  Todd V. Smith ,  Leroy L. Perz

IPC: H02J7/00 ,  A61N1/378 ,  G01K11/20 ,  G01J5/08

CPC classification number: H02J7/047 ,  A61N1/3787 ,  G01J5/0887 ,  G01J5/089 ,  G01K11/006 ,  G01K11/20 ,  H02J7/007 ,  H02J7/0091 ,  H02J7/025

Abstract: Devices, systems, and techniques for monitoring the temperature of a device used to charge a rechargeable power source are disclosed. Implantable medical devices may include a rechargeable power source that can be transcutaneously charged. The temperature of an external charging device and/or an implantable medical device may be monitored to control the temperature exposure to patient tissue. In one example, a temperature sensor may sense a temperature of a portion of a device, wherein the portion is non-thermally coupled to the temperature sensor. A processor may then control charging of the rechargeable power source based on the sensed temperature.

公开(公告)号：US20170065766A1

公开(公告)日：2017-03-09

申请号：US15262639

申请日：2016-09-12

Applicant: Medtronic, Inc.

Inventor： David P. Olson ,  William C. Phillips ,  Andrew L. Schmeling

IPC: A61M5/142 ,  H02J7/04 ,  H02J50/12 ,  H02J7/02

CPC classification number: A61M5/14276 ,  A61M5/142 ,  A61M5/1723 ,  A61M2205/3327 ,  A61M2205/3368 ,  A61M2205/52 ,  A61M2205/8206 ,  A61M2205/8237 ,  A61M2209/01 ,  A61N1/3655 ,  A61N1/3787 ,  H02J7/025 ,  H02J7/047 ,  H02J50/12 ,  H02J50/70

Abstract: A mechanism for transferring energy from an external power source to an implantable medical device is disclosed. A sensor may be used to measure a parameter that correlates to a temperature of the system that occurs during the transcutaneous coupling of energy. For example, the sensor may measure temperature of a surface of an antenna of the external power source. The measured parameter may then be compared to a programmable limit. A control circuit such as may be provided by the external power source may then control the temperature based on the comparison. The programmable limit may be, for example, under software control so that the temperature occurring during transcutaneous coupling of energy may be modified to fit then-current circumstances.

Abstract translation: 公开了一种用于将能量从外部电源传送到可植入医疗装置的机构。 可以使用传感器来测量与能量的经皮耦合期间发生的系统的温度相关的参数。 例如，传感器可以测量外部电源的天线的表面的温度。 然后将测量的参数与可编程限制进行比较。 然后可以由外部电源提供的控制电路可以基于比较来控制温度。 可编程极限可以例如在软件控制下，使得在经皮耦合能量期间发生的温度可以被修改以适应当前的情况。

公开(公告)号：US09463324B2

公开(公告)日：2016-10-11

申请号：US14803563

申请日：2015-07-20

Applicant: MEDTRONIC, INC.

Inventor： David P. Olson ,  William C. Phillips ,  Andrew L. Schmeling

IPC: A61N1/37 ,  A61N1/365 ,  A61M5/142 ,  H02J7/02 ,  A61N1/378 ,  A61M5/172

CPC classification number: A61M5/14276 ,  A61M5/142 ,  A61M5/1723 ,  A61M2205/3327 ,  A61M2205/3368 ,  A61M2205/52 ,  A61M2205/8206 ,  A61M2205/8237 ,  A61M2209/01 ,  A61N1/3655 ,  A61N1/3787 ,  H02J7/025 ,  H02J7/047 ,  H02J50/12 ,  H02J50/70

Abstract: A mechanism for transferring energy from an external power source to an implantable medical device is disclosed. A sensor may be used to measure a parameter that correlates to a temperature of the system that occurs during the transcutaneous coupling of energy. For example, the sensor may measure temperature of a surface of an antenna of the external power source. The measured parameter may then be compared to a programmable limit. A control circuit such as may be provided by the external power source may then control the temperature based on the comparison. The programmable limit may be, for example, under software control so that the temperature occurring during transcutaneous coupling of energy may be modified to fit then-current circumstances.

公开(公告)号：US20150321015A1

公开(公告)日：2015-11-12

申请号：US14803563

申请日：2015-07-20

Applicant: MEDTRONIC, INC.

Inventor： David P. Olson ,  William C. Phillips ,  Andrew L. Schmeling

IPC: A61N1/378 ,  H02J7/02 ,  A61M5/142

CPC classification number: A61M5/14276 ,  A61M5/142 ,  A61M5/1723 ,  A61M2205/3327 ,  A61M2205/3368 ,  A61M2205/52 ,  A61M2205/8206 ,  A61M2205/8237 ,  A61M2209/01 ,  A61N1/3655 ,  A61N1/3787 ,  H02J7/025 ,  H02J7/047 ,  H02J50/12 ,  H02J50/70

Abstract: A mechanism for transferring energy from an external power source to an implantable medical device is disclosed. A sensor may be used to measure a parameter that correlates to a temperature of the system that occurs during the transcutaneous coupling of energy. For example, the sensor may measure temperature of a surface of an antenna of the external power source. The measured parameter may then be compared to a programmable limit. A control circuit such as may be provided by the external power source may then control the temperature based on the comparison. The programmable limit may be, for example, under software control so that the temperature occurring during transcutaneous coupling of energy may be modified to fit then-current circumstances.

Abstract translation: 公开了一种用于将能量从外部电源传送到可植入医疗装置的机构。 可以使用传感器来测量与能量的经皮耦合期间发生的系统的温度相关的参数。 例如，传感器可以测量外部电源的天线的表面的温度。 然后将测量的参数与可编程限制进行比较。 然后可以由外部电源提供的控制电路可以基于比较来控制温度。 可编程极限可以例如在软件控制下，使得在经皮耦合能量期间发生的温度可以被修改以适应当前的情况。

公开(公告)号：US20150073509A1

公开(公告)日：2015-03-12

申请号：US14542032

申请日：2014-11-14

Applicant: Medtronic, Inc.

Inventor： Todd A. Kallmyer ,  John E. Kast ,  David P. Olson ,  Randy S. Roles ,  Venkat R. Gaddam

IPC: H05K7/20 ,  H02J7/02 ,  A61N1/378

CPC classification number: H05K7/20 ,  A61N1/08 ,  A61N1/36142 ,  A61N1/37211 ,  A61N1/375 ,  A61N1/3787 ,  H02J7/025 ,  H02J50/10 ,  Y10T29/4902 ,  Y10T29/49826

Abstract: Devices, systems, and techniques for managing heat generated in coils for wireless energy transmission are disclosed. Inductive coupling between two coils (e.g., a primary coil and a secondary coil) may be used to recharge the power source of an implantable medical device. A phase change material may be thermally coupled to the primary coil to absorb heat generated during the inductive coupling and reduce temperature increases of the primary coil. In one example, the phase change material may be configured to absorb heat from an energy transfer coil. A housing may be configured to contain the phase change material and a coupling mechanism may be configured to removably attach the housing to the energy transfer coil.

Abstract translation: 公开了用于管理用于无线能量传输的线圈中产生的热的装置，系统和技术。 可以使用两个线圈（例如，初级线圈和次级线圈）之间的感应耦合来再充电可植入医疗装置的电源。 相变材料可以热耦合到初级线圈以吸收在电感耦合期间产生的热量并且降低初级线圈的温度升高。 在一个示例中，相变材料可以被配置为从能量传递线圈吸收热量。 壳体可以构造成容纳相变材料，并且联接机构可以被配置为将壳体可移除地附接到能量传递线圈。

公开(公告)号：US20130193914A1

公开(公告)日：2013-08-01

申请号：US13749481

申请日：2013-01-24

Applicant: Medtronic, Inc.

Inventor： Venkat R. Gaddam ,  Reid K. Bornhoft ,  Kevin J. Kelly ,  David P. Olson ,  Todd V. Smith

IPC: H02J7/00

CPC classification number: H02J7/007 ,  A61N1/3787 ,  H02J7/0093 ,  H02J7/025 ,  H02J50/10 ,  H02J50/80

Abstract: Devices, systems, and techniques for selecting a period for charging an implantable rechargeable power source are disclosed. Implantable medical devices may include a rechargeable power source that can be transcutaneously charged. A system may control a charging module to begin charging the rechargeable power source of the implantable medical device with a high power level. The system may then determine an estimated heat loss based on power initially delivered to the rechargeable power source when beginning the charging. Based on this estimated heat loss during the initial period of recharging, the system may select a boost period that includes a duration of time that the rechargeable power source is charged with the high power level.

Abstract translation: 公开了用于选择为可植入可再充电电源充电的周期的装置，系统和技术。 植入式医疗装置可以包括可以经皮充电的可充电电源。 系统可以控制充电模块开始以高功率水平对可植入医疗装置的可再充电电源充电。 然后，系统可以基于在开始充电时最初传送到可再充电电源的功率来确定估计的热损失。 基于在充电初始期间的估计的热损失，系统可以选择包括可再充电电源以高功率电平充电的持续时间的升压时段。

公开(公告)号：US12102833B2

公开(公告)日：2024-10-01

申请号：US17199051

申请日：2021-03-11

Applicant: Medtronic, Inc.

Inventor： Venkat R. Gaddam ,  Reid K. Bornhoft ,  David P. Olson ,  Leroy L Perz ,  Mandla Shongwe

IPC: A61N1/378 ,  A61N1/372

CPC classification number: A61N1/3787 ,  A61N1/37252 ,  A61N1/37223

Abstract: Devices, systems, and techniques for controlling charging power transmitted to an implantable medical device during a recharging process based on patient activity are disclosed. Various example techniques include a method comprising receiving, by processing circuitry, an activity signal generated by an implantable medical device and indicative of an activity level of a patient during charging of a rechargeable power source of the implantable medical device implanted in the patient, determining, by the processing circuitry and based on the activity signal, a patient status for the patient during charging of the rechargeable power source, and controlling, by the processing circuitry and based on the patient status, charging of the rechargeable power source of the implantable medical device.

公开(公告)号：US20210196963A1

公开(公告)日：2021-07-01

申请号：US17199051

申请日：2021-03-11

Applicant: Medtronic, Inc.

Inventor： Venkat R. Gaddam ,  Reid K. Bornhoft ,  David P. Olson ,  Leroy L. Perz ,  Mandla Shongwe

IPC: A61N1/378 ,  A61N1/372

Abstract: Devices, systems, and techniques for controlling charging power transmitted to an implantable medical device during a recharging process based on patient activity are disclosed. Various example techniques include a method comprising receiving, by processing circuitry, an activity signal generated by an implantable medical device and indicative of an activity level of a patient during charging of a rechargeable power source of the implantable medical device implanted in the patient, determining, by the processing circuitry and based on the activity signal, a patient status for the patient during charging of the rechargeable power source, and controlling, by the processing circuitry and based on the patient status, charging of the rechargeable power source of the implantable medical device.

公开(公告)号：US10888703B2

公开(公告)日：2021-01-12

申请号：US16215918

申请日：2018-12-11

Applicant: MEDTRONIC, INC.

Inventor： David P. Olson ,  William C. Phillips ,  Garrett R. Sipple ,  Yu Wang

IPC: A61N1/37 ,  A61N1/372 ,  H02J50/10 ,  H02J50/80 ,  H02J50/90 ,  A61N1/378 ,  G16H40/67 ,  A61B5/00 ,  A61M5/172 ,  H02J7/02 ,  H02J7/00

Abstract: Far field telemetry operations are conducted between an external device and an implantable medical device while power is being transferred to the implantable medical device for purposes of recharging a battery of the implantable medical device. The far field operations may include exchanging recharge information that has been collected by the implantable medical device which allows the external device to exercise control over the recharge process. The far field operations may include suspending far field telemetry communications for periods of time while power continues to be transferred where suspending far field telemetry communications may include powering down far field telemetry communication circuits of the implantable medical device for periods of time which may conserve energy. The far field operations may further include transferring programming instructions to the implantable medical device.