Methods and systems are presented for configuring oxygen barriers for controlled access to chemical warming agents such as wood fiber, vermiculite, activated charcoal, iron, and salt. In this way a smart phone, syringe, or other cold-sensitive device may be warmed by such agents to restore or maintain functionality in a frigid environment.

A heat generation system including: a liquid storage tank; a heating element including: a reaction container having a storage space, and a porous body stored in the storage space, and loaded with an exothermic reaction solid that causes an exothermic reaction when being in contact with the liquid; a liquid injection mechanism member including: a liquid flow pipe that communicates between the liquid storage tank and the storage space of the reaction container, through which the liquid flows, and an injection unit that injects the liquid into the storage space; and discharge mechanism member including: a discharge pipe that communicates with the storage space of the reaction container, and a discharge unit that discharges a liquid product generated by the exothermic reaction caused by contact between the liquid and the exothermic reaction solid, and a vaporized material of the liquid, from the storage space through the discharge pipe.

Provided herein are devices and methods for thawing frozen biological material.

Provided herein are devices and methods for thawing frozen biological material.

A self-heating thermal interface material (TIM) may be formed using heating components dispersed within the TIM. The heating components may produce heat when the TIM is compressed. The heating components may be formed from microcapsules and the microcapsules may contain exothermic reactants. The reactants may be isolated from contact within the microcapsule until a compressive force is applied.

A self-heating thermal interface material (TIM) may be formed using heating components dispersed within the TIM. The heating components may produce heat when the TIM is compressed. The heating components may be formed from microcapsules and the microcapsules may contain exothermic reactants. The reactants may be isolated from contact within the microcapsule until a compressive force is applied.

A heating unit comprising an electrically conductive substrate. A solid fuel layer comprising a metal reducing agent, a metal containing oxidizing agent and a binder is coated on a surface of the substrate, the solid fuel layer having a solid fuel surface spaced from the substrate. A first electrode coupled to the substrate. A second electrode coupled to the solid fuel surface. A power supply is configured to be selectively coupled to the first and second electrodes to provide a voltage between the metallic substrate and the solid fuel surface. The voltage acts to propagate an exothermic metal oxidation-reduction reaction without the use of an igniter.

A heating unit comprising an electrically conductive substrate. A solid fuel layer comprising a metal reducing agent, a metal containing oxidizing agent and a binder is coated on a surface of the substrate, the solid fuel layer having a solid fuel surface spaced from the substrate. A first electrode coupled to the substrate. A second electrode coupled to the solid fuel surface. A power supply is configured to be selectively coupled to the first and second electrodes to provide a voltage between the metallic substrate and the solid fuel surface. The voltage acts to propagate an exothermic metal oxidation-reduction reaction without the use of an igniter.

A self-heating assembly includes a product tray for containing a product to be heated and a heater tray outside the product tray and configured relative to the product tray to define a reaction space between the heater tray and the product tray. A frangible container made of a shrink film material is inside the reaction space. The frangible container contains a first reactant that is a liquid. A second reactant is outside the frangible container. The first and second reactants are configured to react exothermically upon contact with each other.

A self-heating assembly includes a product tray for containing a product to be heated and a heater tray outside the product tray and configured relative to the product tray to define a reaction space between the heater tray and the product tray. A frangible container made of a shrink film material is inside the reaction space. The frangible container contains a first reactant that is a liquid. A second reactant is outside the frangible container. The first and second reactants are configured to react exothermically upon contact with each other.