A battery module includes a cell stack including a plurality of a battery cell, a module case at least partially accommodating the cell stack, and a cooling unit disposed at one side of the cell stack. The battery cell includes a cell case, an electrode assembly and an electrolyte accommodated in the cell case, and an electrolyte storage unit inserted into the cell case to supply a supplementary electrolyte. The electrolyte storage unit is disposed between the electrode assembly and the cooling unit in a cross-sectional view.

The high thermal conduction resistances of a lithium-ion battery (LIB) severely limit the effectiveness of a conventional external thermal management system (TMS). A method for a new thermal management system for lithium-ion batteries that utilizes a multi-functional electrolyte (MFE) to remove heat locally inside the cell by evaporating a volatile component of the MFE is disclosed. These new electrolyte mixtures comprise a high vapor pressure co-solvent. The characteristics of a previously unstudied high vapor pressure co-solvent HFE-7000 (65 kPa at 25° C.) in an MFE (1 M LiTFSI in 1:1 HFE-7000/EMC), and other possible MFE compositions that can be utilized in a custom electrolyte boiling facility, are disclosed.

Provided is a rechargeable battery system comprising at least a battery cell and an external cooling means, wherein the battery cell comprises an anode, a cathode, an electrolyte disposed between the anode and the cathode, a protective housing that at least partially encloses the anode, the cathode and the electrolyte, and at least one heat-spreader element disposed partially or entirely inside the protective housing and wherein the external cooling means is in thermal contact with the heat spreader element configured to enable transporting internal heat of the battery through the heat spreader element to the external cooling means. Also provided is a method of operating a rechargeable battery system, the method comprising implementing a heat spreader element in one or each of a plurality of battery cells and bringing the heat spreader element in thermal contact with one or a plurality of external cooling means.

An electrochemical cell includes an anode, a cathode, one or more surfaces surrounding the anode and the cathode, and a heat shunt. The heat shunt covers at least a portion of the one or more surfaces and is configured to distribute heat generated by the electrochemical cell across the one or more surfaces.

This application provides a lithium-ion battery and a device. The lithium-ion battery includes a positive electrode plate, a negative electrode plate, a separator located between the positive electrode plate and the negative electrode plate, and an electrolytic solution. A lithium-supplementing layer and a first functional coating are sequentially disposed on a surface of the negative electrode plate facing the separator. A second functional coating is disposed on a surface of the separator facing the negative electrode plate. Both the first functional coating and the second functional coating contain an organic porous particulate material. In the lithium-ion battery provided in this application, the first functional coating and the second functional coating are added to enhance stability of the lithium-ion battery, improve safety of the lithium-ion battery, and effectively improve cycle performance of the lithium-ion battery.

In accordance with one embodiment, a solid-state battery system includes a first anode, a first cathode, a first solid-state electrolyte layer positioned between the first anode and the first cathode, a housing enclosing the first anode, the first cathode, and the first solid-state electrolyte layer, and at least one thermal control wire positioned within the housing and configured to modify a temperature within the housing.

In accordance with one embodiment, a solid-state battery system includes a first anode, a first cathode, a first solid-state electrolyte layer positioned between the first anode and the first cathode, a housing enclosing the first anode, the first cathode, and the first solid-state electrolyte layer, and at least one thermal control wire positioned within the housing and configured to modify a temperature within the housing.

A battery is provided having heat transfer bars that directly transfer heat between the interior layers of a battery cell and the case that encloses the battery cell. The battery does not transfer significant heat from its interior layers to the posts of the battery that reside outside of the battery case. A temperature-controlled power system also is provided that uses multiple, active thermoelectric devices paired with multiple batteries to provide individual temperature control of the individual batteries forming the power system. The multiple, active thermoelectric devices preferably transfer heat to a single radiator on each side of the power system. A method of transferring heat from a battery interior using conductive, active, and convective heat transfer is also described.

A cell module assembly is provided. The cell module assembly may include a plurality of cells that generates electrical energy, at least one heat plate interposed between the plurality of cells, to absorb heat from the plurality of cells, the at least one heat plate having a cooling channel defined at both ends thereof, and at least one cartridge to accommodate the plurality of cells and the at least one heat plate, the cooling channel being internally defined in the cartridge.

A cell module assembly is provided. The cell module assembly may include a plurality of cells that generates electrical energy, at least one heat plate interposed between the plurality of cells, to absorb heat from the plurality of cells, the at least one heat plate having a cooling channel defined at both ends thereof, and at least one cartridge to accommodate the plurality of cells and the at least one heat plate, the cooling channel being internally defined in the cartridge.