A staggered and crossed heat storage adsorption bed and a seawater desalination waste heat storage system are provided, which relate to the field of seawater desalination and the technical field of thermochemical adsorption heat storage. The adsorption bed includes a bed body, wherein an adsorption cavity is arranged in the bed body; two sides of the adsorption cavity are respectively communicated with an inlet cavity and an outlet cavity; the adsorption cavity includes a vacuum heat insulation layer arranged at an outermost side; the vacuum heat insulation layer is embedded with an adsorption box fixing layer; a corner end adsorption box, a central adsorption box and a side adsorption box are staggered and crossed arranged in an inner cavity of the vacuum heat insulation layer through the adsorption box fixing layer.

The invention relates to a heat exchanger comprising a first free space (7) for a first fluid (3), a thermally conductive wall (11) which, at least locally, delimits said first free space (7), in such a way that an exchange of heat can occur between the first fluid and the thermally conductive wall (11) which is hollow and encloses a material (13) for storing thermal energy by accumulation of latent heat, by heat exchange with at least the first fluid. The first free space (7) is divided into at least two separated channels (7a, 7b) in which two streams of the first fluid (3) can circulate at the same time but separately, the thermally conductive wall (11) which encloses the thermal energy storage material (13) being interposed between the two channels (7a, 7b).

In one aspect, thermal energy storage systems are described herein. In some embodiments, such a system includes at least one active thermal storage battery and at least one passive thermal storage battery. The at least one active thermal storage battery includes a container, a heat exchanger disposed within the container, and a first phase change material disposed within the container and in thermal contact with the heat exchanger. The at least one passive thermal storage battery comprises a plurality of thermal storage cells, individual thermal storage cells comprising a container having an interior volume, and a second phase change material disposed within the interior volume of the container.

A pouch (100) filled with phase-change material, wherein the pouch comprises a preformed first wall (110) and a second wall (120), wherein the first wall comprises a bowl-shaped part, in which the phase-change material is accommodated, and a peripheral part, wherein the second wall is attached to the peripheral part of the first wall, wherein a high vacuum prevails in the pouch, and wherein the pouch is intended for placing against a wall to be heated or cooled.

An evaporator is provided with a refrigerant pipe, a cold storage case which has inner fins mounted therein, and air-side fins. The evaporator is characterized in that the cold storage case is provided with: a filling opening for filling the cold storage case with a cold storage material; a first flow passage connecting to the filling opening and extending in the same direction as the direction of inflow of the cold storage material; and a second flow passage connecting to the first flow passage and extending in the direction intersecting the first flow passage.

The invention relates to a method for heat exchange. At a first point in time, in a thermal energy storing device, at least part of the previously accumulated thermal energy is discharged to a first fluid by heat exchange, and subsequently, at a second later point in time, when the first fluid has been heated to a temperature higher than the temperature of a second fluid, the second fluid receives heat energy by heat exchange with said first fluid which then circulates on the other side of a first wall that prevents the first and second fluids from mixing.

An inverter device includes a radiator that includes a latent heat storage material transitioning between a solid phase region, a phase transition region, and a liquid phase region, in accordance with a temperature of the latent heat storage material, and that absorbs heat generated in switching elements, a temperature sensor that detects the temperature of the latent heat storage material, and a microcomputer. The microcomputer includes a determining unit that determines whether a condition is satisfied, the condition being that the temperature of the latent heat storage material is close to a melting point of the latent heat storage material, and that the temperature of the latent heat storage material is on a rising trend, and a supercooling suppressing unit that limits a motor current when the determining unit determines that the condition is satisfied.

Heat storage devices suitable for storing solar energy, and associated systems and methods are disclosed. A representative system includes a storage housing that contains a working fluid. A working fluid inlet pipe is coupled to the storage housing. A plurality of concrete plates are positioned in the housing, with the adjacent plates at least partially forming individual flow passages. A working fluid outlet pipe is coupled to the housing. A controller maintains a predominantly laminar flow of the working fluid in the flow passages. In some embodiments, the working fluid can be thermal oil having a boiling temperature of 300 C. or higher.

A building panel system is provided. The building panel system include a panel structure having a first surface and a second surface opposite the first surface; a mounting system attached to the panel structure; at least one container detachably coupled to the mounting system at one of a plurality of selectable coupling positions so as to be in conductive thermal cooperation with the first surface of the panel structure; and a phase change material contained within the at least one container.

A heat storage laminate includes an inorganic substrate and an organic heat storage layer, wherein the inorganic substrate and the organic heat storage layer are laminated to one another. The inorganic substrate has a thickness of 8 mm or more and a mass reduction ratio of 4% by mass or more, as measured when the inorganic substrate is held at a temperature of 105 C. until a constant mass is obtained.