A heat accumulator device for accumulating sensible heat in molten salts, including: -a heat accumulator vessel for receiving molten salt, a separating layer being disposed in the heat accumulator vessel in order to separate a cold region, in which cold molten salt is present, from a hot region, in which hot molten salt is present, and the cold region being located below the hot region; - a device for loading and unloading the heat accumulator vessel, which device is connected to the cold region and to the hot region; and - a volume compensation device for compensating a temperature-related change in the volume of the molten salt, the volume compensation device interacting with the cold region and/or with the separating layer.

A thermal energy storage system including an enclosure having an internal volume. An incompressible phase change material (PCM) is provided within the internal volume of the enclosure, where the PCM contracts into a solid state when its temperature falls below a certain temperature and expands into a liquid state when its temperature goes above the certain temperature. An elastic bladder is positioned adjacent to the PCM within the internal volume of the enclosure and is filled with a compressible material, where the PCM pushes against the bladder when it is expanded to the liquid state and causes the compressible material to be compressed within the bladder and the enclosure.

An arrangement for storing thermal energy, which has a three-dimensionally configured heat accumulator is provided. The latter contains a solid natural material for heat storage. The heat-storage material is enclosed by a fluid-impermeable, flexible layer such that the heat-storage material is insulated at least in a pressure-tight manner with regard to the environment of the heat accumulator. A flexible cover layer is provided, which is coupled to the fluid-impermeable flexible layer such that the flexible cover layer applies a surface force to the fluid-impermeable flexible layer. As a result, the fluid-impermeable flexible layer is pressed areally onto the heat-storage material. The flexible cover layer (i) has the form of a mesh or (ii) is configured in the form of sheet-metal plates overlapping one another in an imbricated manner.

An enclosed storage tank for the simultaneous addition and removal, and storage, of two liquid layers of different density has a bottom wall, a cylindrical side wall, a roof, and a central column extending from the bottom wall to the roof. An upper perforated flexible tensile fabric diaphragm is disposed in the upper portion of the tank, and a low-density liquid conduit extends from outside the tank into communication with the upper portion of the tank above the upper diaphragm. A lower perforated flexible tensile fabric diaphragm is disposed in the lower part of the tank, and a high-density liquid conduit extends from outside the tank shell into communication with the lower portion of the tank below the lower liquid diaphragm. The diaphragms minimize internal mixing through thermoclines as liquid is introduced into and/or discharged from the tank, and reduce overall costs of tank installations and operations.

A thermal energy storage system including an enclosure having an internal volume. An incompressible phase change material (PCM) is provided within the internal volume of the enclosure, where the PCM contracts into a solid state when its temperature falls below a certain temperature and expands into a liquid state when its temperature goes above the certain temperature. An elastic bladder is positioned adjacent to the PCM within the internal volume of the enclosure and is filled with a compressible material, where the PCM pushes against the bladder when it is expanded to the liquid state and causes the compressible material to be compressed within the bladder and the enclosure.

Provided is a thermal energy storage including a housing having a fluid inlet and a fluid outlet, and a thermal energy storage structure arranged within the housing between the fluid inlet and the fluid outlet, the thermal energy storage structure including thermal energy storage elements and flexible separator elements, the flexible separator elements being arranged such that the thermal energy storage elements are separated into layers, each layer forming a channel between the fluid inlet and the fluid outlet. Furthermore, a method of manufacturing a thermal energy storage and a power plant for producing electrical energy is provided.

A device for flexibly separating cold and hot fluid media, including: a tank body, where the tank body is cylindrical and disposed vertically, upper and lower ends of the tank body are respectively provided with a hot fluid inlet and a cold fluid inlet to provide storage space for hot and cold fluids, at least one adsorption layer is provided on a side wall of the tank body, and the adsorption layer is made of a ferromagnetic material or iron; and a thermal insulation board, where the thermal insulation board is of a plate structure and set on a horizontal cross-section of the tank body, with a shape and area matching a horizontal cross-section of the tank body, a sealing strip is arranged along a circumferential direction of the thermal insulation board, the sealing strip is of a hollow structure, the hollow part is evenly filled with adsorption blocks.

A system and method for providing hot water to a point of use such as a shower. Waste warm water from said point of use passes through a heat exchanger, where it initially warms incoming mains water, typically to about 34 C. The initially warmed water is heated to its final temperature, typically about 42 C., in a smart boiler. The smart boiler, which typically has a volume of about 40 liters, comprises two chambers with a flexible barrier therebetween. Each chamber is separately heated as needed. Hot water is drawn from one of the two chambers; simultaneously, the other chamber fills with initially warmed water and is heated to its final temperature. When the volume of water in the chamber from which water is being drawn reaches a minimum, the system begins to fill that chamber and to draw water from the other one.

A cooling system for a heat source, such as a laser system, that includes a mixing valve mixing a cooling fluid from a hot line and a cold line and providing the mixed cooling fluid to the heat source, and a bladder tank having a bladder and including a hot side on one side of the bladder in fluid communication with the hot line and a cold side on an opposite side of the bladder in fluid communication with the cold line. A heat exchanger cools the cooling fluid flowing through the cold line. The cooling system is configured so that when the heat source is on and generating heat, cold cooling fluid from the cold side of the bladder tank is provided to the mixing valve and when the heat source is off and not generating heat, cold cooling fluid from the cold line fills the cold side of the bladder tank.

The present invention relates to a buffer store comprising a closed vessel housing for accommodating a storage fluid, in particular water, wherein the vessel housing has at least one inlet opening, for the filling of the vessel housing with the storage fluid, and at least one equalization opening, which fluidically connects the vessel housing to the surroundings and permits a fluidic equalization with the surroundings. According to the invention, a gas-tight cover is also provided in the interior of the vessel housing, which cover is capable of reliably protecting the storage fluid against mixing with other fluids, for example the ambient air.