An object of the present invention is to prevent efflux of a heat storage material composition from a porous substrate in a heat reservoir. The heat reservoir of the present invention is characterized in that a porous substrate is impregnated with a latent heat storage material and a hydrogenated styrene-based thermoplastic elastomer. When the weight-average molecular weight of the elastomer is designated as X10.sup.4 and the amount of the elastomer is designated as Y parts by mass relative to 100 parts by mass of the latent heat storage material in the heat storage material composition, the following conditions are satisfied: 5X17; 5Y25; if 5X<10, Y2X+25; and if 14<X17, Y5X+90.

A pallet cover suitable for use in covering at least a portion of a payload on a pallet and a kit for use in making the pallet cover. In one embodiment, the pallet cover includes a top wall, a front wall, a rear wall, a left side wall, and a right side wall, wherein the walls are detachably joined to one another. Each of the top wall, the front wall, the rear wall, the left side wall, and the right side wall includes a first fabric sheet and a second fabric sheet, the first and second fabric sheets being joined together to form a plurality of pockets. Each pocket may removably receive a temperature-control member containing a phase-change material. At least one of the top wall, the front wall, the rear wall, the left side wall and the right side wall may include a plurality of detachably joined portions.

Provided is a heat storage and dissipation apparatus capable of direct heat exchange with a heat storage body. A heat storage and dissipation apparatus (100) comprises: a heat storage body (10) that reacts with a component contained in a primary gas (G1); and a heat storage body housing portion (20) that houses the heat storage body (10), wherein the heat storage body housing portion (20) has: a housing space (S1) that houses the heat storage body (10); a first flow opening (20a) that communicates with the housing space (S1) and is capable of flowing the primary gas (S1); and a second flow opening (20b) that communicates with the housing space (S1) and is capable of flowing the primary gas (S1).

The present invention relates to a thermal battery (1) comprising an enclosure (3) comprising a fluid inlet and outlet and comprising within it tubes (5) of encapsulated phase-change material, said thermal battery (1) further comprising a device (7) for holding and spacing the tubes (5) of encapsulated phase-change material, said holding and spacing device (7) being arranged between the tubes (5) themselves and between the tubes (5) and the enclosure (3), said holding and spacing device (7) being porous.

A heat storage member including a substrate containing a SiC sintered body as a principal ingredient and a heat storage material configured to store and radiate heat by a reversible chemical reaction with a reaction medium or a heat storage material configured to store and radiate heat by physical adsorption to a reaction medium and physical desorption from a reaction medium. The substrate has a three-dimensional network structure including a skeleton having porosity of 1% or less. A void ratio of a void formed in the three-dimensional network structure of the substrate is ranging from 30 to 95%. The heat storage material is disposed at least in a part of a surface of the void in the three-dimensional network structure of the substrate.

The heat storage material storage container comprises a main body having a longitudinal direction and including a plurality of flow channels therein, the flow channels extending parallel to each other in the longitudinal direction and separated from each other by porous walls and a heat storage material contained in only one or some of the plurality of flow channels. The plurality of flow channels include a plurality of first flow channels each having an open end on a first side in the longitudinal direction and a closed end on a second side in the longitudinal direction and a plurality of second flow channels each having open ends on both the first side and the second side in the longitudinal direction. The heat storage material is contained in only the first flow channels.

The invention relates to a method for producing shaped heat storage bodies comprising a thermochemical substance, which bodies comprise a curved surface, the method comprising providing a powder comprising the thermochemical substance and optionally one or more further components, in particular one or more compressing aids; and compressing the powder into the shaped bodies, using a die or a mould, preferably by direct compression.

The invention further relates to shaped heat storage bodies comprising a thermochemical substance, which bodies comprise a curved surface and to a thermochemical energy storage system, comprising said heat storage bodies.

A thermal transfer blanket includes a flexible container comprising a thermally insulating material. A thermal energy storage media is disposed within the flexible container.

A heat storage system using a heat storage container having a tubular body, an adsorbent that is accommodated in the tubular body, generates heat by adsorption of an adsorbate and absorbs heat by desorption of the adsorbate, and a flow channel that penetrates the tubular body in a longitudinal direction, the heat storage system comprising a diffusion layer for transporting the adsorbate in liquid phase from the flow channel to the adsorbent, wherein the adsorbate is transported to the flow channel, the adsorbate is transported to the diffusion layer, a part of the adsorbate transported to the diffusion layer is adsorbed on the adsorbent, the adsorbent releases heat, and the remaining adsorbate is vaporized by the heat to become heat transport fluid.

A method to use high temperature thermal storage for integration into building heating/cooling systems and to meet building's peak power demand. The method can be used to store the thermal energy at any desirable rate and then discharge this stored energy to meet the demand for short or long time intervals. Input energy stored with this method is thermal energy, however, output can be thermal or electric based upon the requirement.