Abstract: Methods, systems, and device for thermal energy storage are provided. For example, some embodiments include a thermal energy storage device that may include: a first casing wall; a second casing wall; and/or multiple support structures located between the first casing wall and the second casing wall. The multiple support structures may provide continuous thermal paths and/or continuous mechanical paths between the first casing wall and the second casing wall. The thermal energy storage device may be fabricated utilizing an additive manufacturing technique, such as direct laser metal sintering. Some embodiments may be manufactured utilizing printed metals, such as an aluminum alloy. In some embodiments, a phase-change material is charged between the first casing wall and the second casing wall. The phase-change material may include paraffin.

Abstract: Devices, methods, and systems for two-phase thermal management are provided in accordance with various embodiments. For example, a two-phase thermal management device is provided that may include two or more containment layers and/or one or more porous layers positioned between at least a portion of each of the two or more containment layers. The portion of each of the two or more containment layers and the one or more porous layers may be bonded with each other. The two or more containment layers and one or more porous layers may be bonded with each other to form an uninterrupted stack of material layers utilizing diffusion bonding. Some embodiments include a method of forming a two-phase thermal management device including arranging multiple materials layers including one or more porous layers positioned with respect to one or more containment layers; and/or bonding the multiple material layers with each other.

Abstract: Passively deployable thermal management devices, systems, and methods are provided in accordance with various embodiments. For example, some embodiments include a passively deployable radiator device that may include: one or more thermally conductive layers; and/or one or more strain energy components configured to deploy passively the one or more thermally conductive layers. The one or more thermally conductive layers may include one or more carbon layers. The one or more carbon layers may include at least one or more graphite layers or one or more graphene layers. At least the one or more graphite layers or the one or more graphene layers include at least one or more pyrolytic graphite sheets or one or more pyrolytic graphene sheets.

Abstract: Devices, methods, and systems for two-phase thermal management are provided in accordance with various embodiments. For example, a two-phase thermal management device is provided that may include two or more containment layers and/or one or more porous layers positioned between at least a portion of each of the two or more containment layers. The portion of each of the two or more containment layers and the one or more porous layers may be bonded with each other. The two or more containment layers and one or more porous layers may be bonded with each other to form an uninterrupted stack of material layers utilizing diffusion bonding. Some embodiments include a method of forming a two-phase thermal management device including arranging multiple materials layers including one or more porous layers positioned with respect to one or more containment layers; and/or bonding the multiple material layers with each other.

Abstract: Methods, systems, and device for two-phase thermal management are provided in accordance with various embodiments. For example, some embodiments include a two-phase thermal management device that may include: a liquid chamber; one or more inlets configured to deliver a liquid to the liquid chamber; an evaporator chamber; a capillary layer positioned within the evaporator chamber and configured to spread the liquid from the liquid chamber; a liquid manifold configured to deliver the liquid from the liquid chamber to at least the capillary layer or the evaporator chamber; and/or one or more outlets configured to remove at least a vapor or a portion of the liquid from the evaporator chamber. Some embodiments that may include a two-phase thermal management device coupled with at least: a heat exchanger, a pump, a heat recuperator, a pre-heater, and/or a variable volume reservoir. Some embodiments include a two-phase thermal management method.

Abstract: Methods, systems, and device for two-phase thermal management are provided in accordance with various embodiments. For example, some embodiments include a two-phase thermal management device that may include: a liquid chamber; one or more inlets configured to deliver a liquid to the liquid chamber; an evaporator chamber; a capillary layer positioned within the evaporator chamber and configured to spread the liquid from the liquid chamber; a liquid manifold configured to deliver the liquid from the liquid chamber to at least the capillary layer or the evaporator chamber; and/or one or more outlets configured to remove at least a vapor or a portion of the liquid from the evaporator chamber. Some embodiments that may include a two-phase thermal management device coupled with at least: a heat exchanger, a pump, a heat recuperator, a pre-heater, and/or a variable volume reservoir. Some embodiments include a two-phase thermal management method.

Abstract: Passively deployable thermal management devices, systems, and methods are provided in accordance with various embodiments. For example, some embodiments include a passively deployable radiator device that may include: one or more thermally conductive layers; and/or one or more strain energy components configured to deploy passively the one or more thermally conductive layers. The one or more thermally conductive layers may include one or more carbon layers. The one or more carbon layers may include at least one or more graphite layers or one or more graphene layers. At least the one or more graphite layers or the one or more graphene layers include at least one or more pyrolytic graphite sheets or one or more pyrolytic graphene sheets.

Abstract: Methods, systems, and device for thermal energy storage are provided. For example, some embodiments include a thermal energy storage device that may include: a first casing wall; a second casing wall; and/or multiple support structures located between the first casing wall and the second casing wall. The multiple support structures may provide continuous thermal paths and/or continuous mechanical paths between the first casing wall and the second casing wall. The thermal energy storage device may be fabricated utilizing an additive manufacturing technique, such as direct laser metal sintering. Some embodiments may be manufactured utilizing printed metals, such as an aluminum alloy. In some embodiments, a phase-change material is charged between the first casing wall and the second casing wall. The phase-change material may include paraffin.