A heat pump system includes a heat source unit having a variable-capacity compressor and a heat-source-side heat exchanger that functions as an evaporator for a refrigerant, and a plurality of usage units connected to the heat source unit and having usage-side heat exchangers that function as radiators for the refrigerant. The operating capacity of the compressor is controlled to bring the discharge pressure of the compressor, or a state quantity equivalent to the discharge pressure, to a first target value. The first target value is determined based on an equivalent target value equivalent to a usage temperature required in individual usage units.

A first circulation channel connects a first heat demand part and first supply heat exchanger with its forward route and return route. Supply and discharge channels are connected to a first heat accumulation tank, which accommodates a second heat medium heated in the first supply heat exchanger and supplied via the supply channel. A heat accumulation switching valve changes over communication of the second heat medium serving as hot heat or cold heat flowing from the first supply heat exchanger and supplied to the first heat demand part without branching to the supply channel or branching to the supply channel and supplied to the first heat accumulation tank. A heat-accumulating hot-water-supplying air conditioner operates at a first temperature when the second heat medium from the first supply heat exchanger branches to the supply channel, and at a second lower temperature when the second heat medium does not branch to the supply channel.

Embodiments of the invention utilize the geothermal energy exchanger and battery (GEEB) to recover and store thermal energy from the dwelling, from the ground, and from the Earth's atmosphere, reuse the thermal energy in another season of the year, and consume electrical energy to heat and cool the structure at electrical Off Peak time periods. The GEEB may be constructed of a compact steel, ribbed and waterproof permanent container that is set at a depth beneath the surface of the ground where the normal soil temperature is virtually constant year round. The container can then be encased in poured concrete, with the exception of piping or conduits. The container is then filled with a heat transfer fluid so that the entire thermal mass of the GEEB and heat transfer fluid reaches the ambient ground temperature and efficiently couples the load and source sides of a heating and cooling system.

The present disclosure discloses a heating adjustment method and device, which belongs to the field of thermal system management technologies. The method includes: calculating an average indoor temperature of a cell, wherein the average indoor temperature of the cell is an average value of a real-time indoor temperature of each dwelling unit in the cell; judging whether the average indoor temperature is within a standard temperature range; and adjusting at least one of a water pump flow and a water temperature supplied to the cell when the average indoor temperature is not within the standard temperature range. When the average indoor temperature of the current cell is abnormal, the temperature of the cell is restored to a standard value by adjusting the water pump flow and the water temperature for heating, thus the response speed is fast, the reliability is high, the user experience is improved and energy is saved.

A system for selectively heating and cooling including a three-way heat exchange apparatus, a source apparatus for selectively heating and cooling a source fluid, a phase change material for selectively storing heating and cooling potential, and a distribution apparatus for selectively distributing heating and cooling a distribution fluid, wherein the three-way heat exchange apparatus is connected to the phase change material by an interface between the heat exchange apparatus and the phase change material.

Embodiments of the invention are directed to a hydronic heating system utilized to heat a mobile living unit. The mobile living unit may include a bottom floor and a raised floor separated by a conditioned basement which funnels cold air from the conditioned basement through a convector. The convector heats the air causing the air to rise through the walls in the mobile living unit. The warm air is then released out through one or more vents in the walls into the interior living space of the mobile living unit.

A reversible heat pump assembly (100) is disclosed. The heat pump assembly (100) comprises a heat pump (110) having a first side (120) and a second side (130), the heat pump (110) being configured to transfer heat from the first side (120) to the second side (130) or vice versa; a first side inlet valve assembly (126) having a heat pump connection (126a) connected to the first side (120), and hot and cold conduit connections (126b; 126c) arranged to be connected to a thermal energy grid (10) comprising hot and cold conduits (12; 14); a second side outlet valve assembly (136) having a heat pump connection (136a) connected to the second side (130), and heating and cooling circuit connections (136b; 136c) arranged to be connected to heating and cooling circuits (130; 140), respectively. The reversible heat pump assembly (100) is configured to be selectively set in either a heating mode or a cooling mode. In the heating mode the heat pump (110) is configured to transfer heat from the first side (120) to the second side (130), the first side inlet valve assembly (126) is configured to fluidly connect the hot conduit connection (126b) and the heat pump connection (126a), and the second side outlet valve assembly (136) is configured to fluidly connect the heat pump connection (136a) and the heating circuit connection (136b). In the cooling mode the heat pump (110) is configured to transfer heat from the second side (130) to the first side (120), the first side inlet valve assembly (126) is configured to fluidly connect the cold conduit connection (126c) and the heat pump connection (126a), and the second side outlet valve assembly (136) is configured to fluidly connect the heat pump connection (136a) and the cooling circuit connection (136c). Also a district thermal energy distribution system comprising a plurality of reversible heat pump assemblies (100) is disclosed.

In a split system heat pump cooling and heating system, an auxiliary hot water storage tank is provided as an energy storage bank. Two sets of coils run through this storage tank, a first set carrying hot refrigerant from the heat pump to deposit energy and a second set carrying hot potable water to remove energy. Valve and switch matrixes are operated at the heat pump to provide hot potable water from the energy storage bank during both normal space heating and cooling operations of the heat pump.

There is herein described energy storage systems. More particularly, there is herein described thermal energy storage systems and use of energy storable material such as phase change material in the provision of heating and/or cooling systems in, for example, domestic dwellings.

In a split system heat pump cooling and heating system, an auxiliary hot water storage tank is provided as an energy storage bank. Two sets of coils run through this storage tank, a first set carrying hot refrigerant from the heat pump to deposit energy and a second set carrying hot potable water to remove energy. Valve and switch matrixes are operated at the heat pump to provide hot potable water from the energy storage bank during both normal space heating and cooling operations of the heat pump.