公开(公告)号：US10312504B2

公开(公告)日：2019-06-04

申请号：US15480911

申请日：2017-04-06

Applicant: STOREDOT LTD.

Inventor： Doron Burshtain ,  Nir Kedem ,  Daniel Aronov

IPC: H01M4/134 ,  H01M10/0525 ,  H01M4/38 ,  H01M4/36 ,  H01M4/1395 ,  H01M4/04 ,  H01M4/62 ,  H01M4/02

Abstract: Improved anodes and cells are provided, which enable fast charging rates with enhanced safety due to much reduced probability of metallization of lithium on the anode, preventing dendrite growth and related risks of fire or explosion. Anodes and/or electrolytes have buffering zones for partly reducing and gradually introducing lithium ions into the anode for lithiation, to prevent lithium ion accumulation at the anode electrolyte interface and consequent metallization and dendrite growth. Various anode active materials and combinations, modifications through nanoparticles and a range of coatings which implement the improved anodes are provided.

公开(公告)号：US10297872B2

公开(公告)日：2019-05-21

申请号：US15706829

申请日：2017-09-18

Applicant: StoreDot Ltd.

Inventor： Ron Paz ,  Nir Kedem ,  Doron Burshtain ,  Nir Baram ,  Nir Pour ,  Daniel Aronov

IPC: H01M10/42 ,  H01M10/0525

Abstract: Systems and methods are provided, in which the level of metal ions in cells stacks and lithium ion batteries is regulated in situ, with the electrodes of the cell stack(s) in the respective pouches. Regulation of metal ions may be carried out electrochemically by metal ion sources in the pouches, electrically connected to the electrodes. The position and shape of the metal ion sources may be optimized to create uniform metal ion movements to the electrode surfaces and favorable SEI formation. The metal ion sources may be removable, or comprise a lithium source for lithiating the anodes or cathodes during operation of the battery according to SoH parameters. Regulation of metal ions may be carried out from metal ion sources in separate electrolyte reservoir(s), with circulation of the metal-ion-containing electrolyte through the cell stacks in the pouches prior or during the formation.

公开(公告)号：US10256650B2

公开(公告)日：2019-04-09

申请号：US14574409

申请日：2014-12-18

Applicant: StoreDot Ltd.

Inventor： Daniel Aronov ,  Leonid Krasovitsky ,  Maxim Liberman ,  Vadim Sabayev ,  Leonid Spindler ,  Alan Weisleder

IPC: H02J7/00

Abstract: The present invention discloses devices and methods for adaptive fast-charging of mobile devices. Methods include the steps of: firstly determining whether a first connected component is charged; upon firstly determining the first connected component isn't charged, secondly determining whether the first connected component is adapted for rapid charging; and upon secondly determining the first connected component is adapted for rapid charging, firstly charging the first connected component at a high charging rate via a charging device. Preferably, the charging device is selected from the group consisting of: a rapid charger and a slave battery. Preferably, the first connected component is selected from the group consisting of: a mobile device and a slave battery. Preferably, the high charging rate is selected from the group consisting of: greater than about 4 C, greater than about 5 C, greater than about 10 C, greater than about 20 C, greater than about 30 C, and greater than about 60 C.

公开(公告)号：US09472804B2

公开(公告)日：2016-10-18

申请号：US14926012

申请日：2015-10-29

Applicant: StoreDot Ltd.

Inventor： Doron Burshtain ,  Ronny Costi ,  Carmit Ophir ,  Daniel Aronov

IPC: H01M4/38 ,  H01M4/36 ,  H01M10/0525 ,  H01M4/133 ,  H01M4/134 ,  H01M4/587 ,  H01M4/02

CPC classification number: H01M4/38 ,  H01G11/06 ,  H01G11/08 ,  H01G11/50 ,  H01G11/52 ,  H01G11/56 ,  H01G11/58 ,  H01G11/74 ,  H01M2/1653 ,  H01M4/133 ,  H01M4/134 ,  H01M4/136 ,  H01M4/364 ,  H01M4/386 ,  H01M4/587 ,  H01M4/622 ,  H01M4/623 ,  H01M4/625 ,  H01M10/0525 ,  H01M10/0565 ,  H01M10/0569 ,  H01M2004/027 ,  H01M2220/20 ,  H01M2220/30

Abstract: An anode material for a lithium ion device includes an active material including germanium and boron. The weight percentage of the germanium is between about 45 to 80 weight % of the total weight of the anode material and the weight percentage of the boron is between about 2 to 20 weight % of the total weight of the anode material. The active material may include carbon at a weight percentage of between 0.5 to about 5 weight % of the total weight of the anode material. Additional materials, methods of making and devices are taught.

Abstract translation: 用于锂离子装置的负极材料包括包括锗和硼的活性材料。 锗的重量百分比在阳极材料的总重量的约45至80重量％之间，硼的重量百分比为阳极材料总重量的约2至20重量％。 活性材料可以包括重量百分比为阳极材料总重量的0.5至约5重量％之间的碳。 教授其他材料，制作方法和装置。

公开(公告)号：US09325201B1

公开(公告)日：2016-04-26

申请号：US14735280

申请日：2015-06-10

Applicant: StoreDot Ltd.

Inventor： Daniel Aronov ,  Maxim Liberman ,  Leonid Spindler

IPC: H02J7/00 ,  H02J7/06 ,  H02J7/04

CPC classification number: H02J7/045 ,  H02J7/041

Abstract: The present invention discloses charging devices for charging energy-storage devices. Charging devices include: an Electro-Magnetic Interference/Radio-Frequency Interference (EMI/RFI) filter for passively suppressing conducted interference present on an alternating-current (AC) power source; optionally, a transformer for transforming power from the AC power source without changing frequency; a rectifier for converting an AC input to a direct-current (DC) output; and a voltage-controlled charger for providing a high-power output having an output voltage and an output current from the AC power source, wherein the output voltage and the output current from the voltage-controlled charger are pulsating DC signals. Preferably, the high-power output has a power-factor value of: greater than about 0.70, greater than about 0.80, greater than about 0.90, greater than about 0.95, or greater than about 0.97. Preferably, the high-power output is a wattage of: greater than about 40W, greater than about 50W, greater than about 60W, or greater than about 70W.

Abstract translation: 本发明公开了一种用于对储能装置进行充电的充电装置。 充电装置包括：用于被动抑制交流（AC）电源上存在的传导干扰的电磁干扰/射频干扰（EMI / RFI）滤波器; 可选地，用于在不改变频率的情况下从AC电源变换功率的变压器; 用于将AC输入转换为直流（DC）输出的整流器; 以及用于提供具有来自AC电源的输出电压和输出电流的高功率输出的电压控制充电器，其中来自压控充电器的输出电压和输出电流是脉动的DC信号。 优选地，高功率输出具有：大于约0.70，大于约0.80，大于约0.90，大于约0.95或大于约0.97的功率因数值。 优选地，高功率输出是：大于约40W，大于约50W，大于约60W或大于约70W的功率。

公开(公告)号：US20150288206A1

公开(公告)日：2015-10-08

申请号：US14675771

申请日：2015-04-01

Applicant: StoreDot Ltd.

Inventor： Daniel Aronov ,  Leonid Krasovitsky

IPC: H02J7/00 ,  G01R31/36

CPC classification number: G01R31/382 ,  H02J7/0054 ,  H02J7/345 ,  H02J2007/005

Abstract: The present invention discloses systems and methods for adaptive fast-charging for mobile devices and devices having sporadic power-source connection. Methods include the steps of: firstly determining whether a supercapacitor of a device is charged; upon detecting the supercapacitor is charged, secondly determining whether a battery of the device is charged; and upon detecting the battery is not charged, firstly charging the battery from the supercapacitor. Preferably, the step of firstly determining includes whether the supercapacitor is partially charged, and the step of secondly determining includes whether the battery is partially charged. Preferably, the step of firstly charging is adaptively regulated to perform a task selected from the group consisting of: preserving a lifetime of the battery by controlling a current to the battery, and discharging the supercapacitor in order to charge the battery. Preferably, the discharging enables the supercapacitor to be subsequently recharged.

Abstract translation: 本发明公开了用于具有偶发电源连接的移动设备和设备的自适应快速充电的系统和方法。 方法包括以下步骤：首先确定装置的超级电容器是否被充电; 一旦检测到超级电容器被充电，其次确定装置的电池是否被充电; 并且在检测到电池未被充电时，首先从超级电容器对电池充电。 优选地，首先确定的步骤包括超级电容器是否被部分充电，并且第二确定步骤包括电池是否部分充电。 优选地，首先充电的步骤被自适应地调节以执行选自以下的任务：通过控制电池的电流来保持电池的寿命，并且对超级电容器进行放电以对电池充电。 优选地，放电使得超级电容器随后能够再充电。

公开(公告)号：US11831012B2

公开(公告)日：2023-11-28

申请号：US16394112

申请日：2019-04-25

Applicant: StoreDot Ltd.

Inventor： Ohad Goldbart ,  Nitzan Shadmi ,  Hani Farran ,  Daniel Aronov

IPC: H01M4/38 ,  H01M10/0525 ,  H01M4/36 ,  H01M4/62 ,  H01M4/136 ,  H01M4/1397 ,  H01M4/02 ,  H01M4/04 ,  H01M4/134

CPC classification number: H01M4/386 ,  H01M4/136 ,  H01M4/1397 ,  H01M4/364 ,  H01M4/621 ,  H01M4/625 ,  H01M10/0525 ,  H01M4/0471 ,  H01M4/134 ,  H01M4/366 ,  H01M4/622 ,  H01M4/623 ,  H01M2004/027 ,  H01M2004/028 ,  Y02E60/10

Abstract: Methods, anode material particles, mixtures, anodes and lithium-ion batteries are provided, having passivated silicon-based particles that enable processing in oxidizing environments such as water-based slurries. Methods comprise forming a mixture of silicon particles with nanoparticles (NPs) and a carbon-based binders and/or surfactants, wherein the NPs comprise at least one of: metalloid oxide NPs, metalloid salt NPs and carbon NPs, reducing the mixture to yield a reduced mixture comprising coated silicon particles with a coating providing a passivation layer (possibly amorphous), and consolidating the reduced mixture to form an anode. It is suggested that the NPs provide nucleation sites for the passivation layer on the surface of the silicon particles—enabling significant anode-formation process simplifications such as using water-based slurries—enabled by disclosed methods and anode active material particles.

公开(公告)号：US11652200B2

公开(公告)日：2023-05-16

申请号：US16735721

申请日：2020-01-07

Applicant: StoreDot Ltd.

Inventor： Shaked Rosenne ,  Ron Paz ,  Nir Kedem ,  Doron Burshtain ,  Nir Baram ,  Nir Pour ,  Daniel Aronov

IPC: H01M4/04 ,  H01M10/0525 ,  H01M4/02

CPC classification number: H01M4/0447 ,  H01M10/0525 ,  H01M2004/028

Abstract: Systems and methods are provided, in which the level of metal ions in cells stacks and lithium ion batteries is regulated in situ, with the electrodes of the cell stack(s) in the respective pouches. Regulation of metal ions may be carried out electrochemically by metal ion sources in the pouches, electrically connected to the electrodes. The position and shape of the metal ion sources may be optimized to create uniform metal ion movements to the electrode surfaces and favorable SEI formation. The metal ion sources may be removable, or comprise a lithium source for lithiating the anodes or cathodes during operation of the battery according to SoH parameters. Regulation of metal ions may be carried out from metal ion sources in separate electrolyte reservoir(s), with circulation of the metal-ion-containing electrolyte through the cell stacks in the pouches prior or during the formation.

公开(公告)号：US11128152B2

公开(公告)日：2021-09-21

申请号：US15678143

申请日：2017-08-16

Applicant: StoreDot Ltd.

Inventor： Daniel Aronov ,  Leonid Krasovitsky

IPC: H02J7/00 ,  H02J7/34

Abstract: The present invention discloses systems and methods for adaptive fast-charging for mobile devices and devices having sporadic power-source connection. Methods include the steps of: firstly determining whether a supercapacitor of a device is charged; upon detecting the supercapacitor is charged, secondly determining whether a battery of the device is charged; and upon detecting the battery is not charged, firstly charging the battery from the supercapacitor. Preferably, the step of firstly determining includes whether the supercapacitor is partially charged, and the step of secondly determining includes whether the battery is partially charged. Preferably, the step of firstly charging is adaptively regulated to perform a task selected from the group consisting of: preserving a lifetime of the battery by controlling a current to the battery, and discharging the supercapacitor in order to charge the battery. Preferably, the discharging enables the supercapacitor to be subsequently recharged.

公开(公告)号：US10916811B2

公开(公告)日：2021-02-09

申请号：US16268527

申请日：2019-02-06

Applicant: StoreDot Ltd.

Inventor： Doron Burshtain ,  Daniel Aronov ,  Eran Sella

IPC: H01M10/42 ,  H01M10/0525 ,  H01M10/0567 ,  H01M10/0562

Abstract: Electrolytes, anode material particles and methods are provided for improving performance and enhancing the safety of lithium ion batteries. Electrolytes may comprise ionic liquid(s) as additives which protect the anode material particles and possibly bind thereto; and/or may comprise a large portion of fluoroethylene carbonate (FEC) and/or vinylene carbonate (VC) as the cyclic carbonate component, and possibly ethyl acetate (EA) and/or ethyl methyl carbonate (EMC) as the linear component; and/or may comprise composite electrolytes having solid electrolyte particles coated by flexible ionic conductive material. Ionic liquid may be used to pre-lithiate in situ the anode material particles. Disclosed electrolytes improve lithium ion conductivity, prevent electrolyte decomposition and/or prevents lithium metallization on the surface of the anode.