A fluid-cooled battery system includes at least one battery module which includes a plurality of rows of battery cells, an outer casing, and at least one cell fixture. The outer casing defines therein an accommodation space. The cell fixture includes a holding web fitted inside the accommodation space, and formed with a plurality of rows of retaining holes. The retaining holes of each row are configured to retain cell bodies of a respective row of the battery cells so as to permit the battery cells to be held in the accommodation space by the holding web, to thereby keep the battery cells in stable position against undesired vibration.

A fluid-cooled battery system includes at least one battery module which includes a plurality of rows of battery cells, an outer casing, and at least one cell fixture. The outer casing defines therein an accommodation space. The cell fixture includes a holding web fitted inside the accommodation space, and formed with a plurality of rows of retaining holes. The retaining holes of each row are configured to retain cell bodies of a respective row of the battery cells so as to permit the battery cells to be held in the accommodation space by the holding web, to thereby keep the battery cells in stable position against undesired vibration.

The present invention relates to a battery pack having a refrigerant circulation channel, and more particularly to a battery pack having a refrigerant circulation channel provided in a pack case, the battery pack including at least one battery module; a pack case configured to receive the battery module therein; and a cooling unit located between an inside upper surface of the pack case and the battery module, the cooling unit being configured to discharge heat generated from the battery module, wherein the pack case is provided with a refrigerant circulation channel configured to supply and collect a refrigerant to and from the cooling unit.

The present invention relates to a battery pack having a refrigerant circulation channel, and more particularly to a battery pack having a refrigerant circulation channel provided in a pack case, the battery pack including at least one battery module; a pack case configured to receive the battery module therein; and a cooling unit located between an inside upper surface of the pack case and the battery module, the cooling unit being configured to discharge heat generated from the battery module, wherein the pack case is provided with a refrigerant circulation channel configured to supply and collect a refrigerant to and from the cooling unit.

A cooling structure includes a plurality of bars arranged separately from each other and configured to press a battery cell, a support configured to support the plurality of bars, flow paths defined by a first surface of the battery cell and one pair of neighboring bars, and configured to guide a flow of a cooling medium, with the cooling medium being in direct contact with the first surface of the battery cell, and a separation wall provided in at least one of the flow paths and being configured to separate each of the at least one flow path into sub-flow paths.

A cooling structure includes a plurality of bars arranged separately from each other and configured to press a battery cell, a support configured to support the plurality of bars, flow paths defined by a first surface of the battery cell and one pair of neighboring bars, and configured to guide a flow of a cooling medium, with the cooling medium being in direct contact with the first surface of the battery cell, and a separation wall provided in at least one of the flow paths and being configured to separate each of the at least one flow path into sub-flow paths.

Methods and systems are provided for providing thermal management for components of a vehicle. In one example, a method may include exchanging heat between different coolant systems via a heat exchanger using predicted data indicating estimated coolant temperatures for a vehicle trip and measured data indicating dynamic conditions for the vehicle trip.

Methods and systems are provided for providing thermal management for components of a vehicle. In one example, a method may include exchanging heat between different coolant systems via a heat exchanger using predicted data indicating estimated coolant temperatures for a vehicle trip and measured data indicating dynamic conditions for the vehicle trip.

An onboard-battery temperature controller to be disposed inside a vehicle, near a battery including a plurality of battery cells, is configured to control the temperature of the battery cells. The onboard-battery temperature controller includes a fluid heater, a heat generating body, and an arithmetic and control unit. The fluid heater is configured to heat the battery cells through heat exchange between a heating fluid circulating therein and the battery cells. The heat generating body is configured to be energized and generate heat, to be conducted to the battery cells to heat the battery cells. The arithmetic and control unit is configured to control operations of the fluid heater and the heat generating body on the basis of the temperature of the battery.

An onboard-battery temperature controller to be disposed inside a vehicle, near a battery including a plurality of battery cells, is configured to control the temperature of the battery cells. The onboard-battery temperature controller includes a fluid heater, a heat generating body, and an arithmetic and control unit. The fluid heater is configured to heat the battery cells through heat exchange between a heating fluid circulating therein and the battery cells. The heat generating body is configured to be energized and generate heat, to be conducted to the battery cells to heat the battery cells. The arithmetic and control unit is configured to control operations of the fluid heater and the heat generating body on the basis of the temperature of the battery.