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.

The present disclosure relates to a portable, light weight, and swappable battery module/system comprising an integrated thermal management system. The integrated thermal management system is light weight and compact in part due to use of a thermoelectric cooler. The management system also allows for incorporation of control systems for application in diverse end uses without the need for different control or thermal management systems.

The present disclosure relates to a portable, light weight, and swappable battery module/system comprising an integrated thermal management system. The integrated thermal management system is light weight and compact in part due to use of a thermoelectric cooler. The management system also allows for incorporation of control systems for application in diverse end uses without the need for different control or thermal management systems.

The disclosure relates to an energy storing device for generating a supply voltage for an electric machine, comprising at least one energy supply branch which is connected in parallel and each of which has a plurality of first and second energy storing modules that are connected in series. The first and second energy storing modules each comprise an energy storing cell module, which has at least one energy storing cell, and a coupling device, which is designed to selectively connect the energy storing cell module into the respective energy supply branch or to bridge said energy storing cell module. Each second energy storing module additionally has a cooling element for the at least one energy storing cell, and the cooling element is designed to cool the at least one energy storing cell dependent on a control signal of a cooling controller.

The disclosure relates to an energy storing device for generating a supply voltage for an electric machine, comprising at least one energy supply branch which is connected in parallel and each of which has a plurality of first and second energy storing modules that are connected in series. The first and second energy storing modules each comprise an energy storing cell module, which has at least one energy storing cell, and a coupling device, which is designed to selectively connect the energy storing cell module into the respective energy supply branch or to bridge said energy storing cell module. Each second energy storing module additionally has a cooling element for the at least one energy storing cell, and the cooling element is designed to cool the at least one energy storing cell dependent on a control signal of a cooling controller.

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 temperature control device may include a temperature control structure through which a fluid may be flowable and may have at least one first pipe wall defining an interior, and at least one thermoelectric module, which on a side facing away from the interior chamber of the temperature control structure may be arranged on the first pipe wall. The thermoelectric module may include at least two rows of elements each extending along an extension direction and with at least two thermoelectric elements. The thermoelectric elements of each of the at least two rows of elements may be electrically connected in series to forming a first and a second electric branch conductor. In at least one row of elements, an electric switch switchable between closed and opened states may be provided.

A temperature control device may include a temperature control structure through which a fluid may be flowable and may have at least one first pipe wall defining an interior, and at least one thermoelectric module, which on a side facing away from the interior chamber of the temperature control structure may be arranged on the first pipe wall. The thermoelectric module may include at least two rows of elements each extending along an extension direction and with at least two thermoelectric elements. The thermoelectric elements of each of the at least two rows of elements may be electrically connected in series to forming a first and a second electric branch conductor. In at least one row of elements, an electric switch switchable between closed and opened states may be provided.

An environmental enclosure is disclosed. The environmental enclosure may include sidewalls defining an enclosure volume, each of the sidewalls having an internally facing surface and an externally facing surface, and a solar shield comprising a reflective surface. The solar shield is spaced a first distance externally from the enclosure volume and is connected to a sidewall. The first distance defines a portion of a flow area that is configured to produce stack effect draft.

An environmental enclosure is disclosed. The environmental enclosure may include sidewalls defining an enclosure volume, each of the sidewalls having an internally facing surface and an externally facing surface, and a solar shield comprising a reflective surface. The solar shield is spaced a first distance externally from the enclosure volume and is connected to a sidewall. The first distance defines a portion of a flow area that is configured to produce stack effect draft.