A building heating system, including for heating water, such as tap water and/or utility water, of a building water system. The embodiments also relate to a kit of part to realize such a building heating system. The embodiments further relate to a method for controlling the building heating system.

A heating installation for premises includes a controller coupled to an air source heat pump; a premises heating arrangement; and a local weather sensing arrangement. The controller is configured to receive weather forecast data from an external source, and local weather status information from the local weather sensing arrangement. The controller is also configured to set a control algorithm based on both the weather forecast data and the local weather status information, and control a supply of energy from the air source heat pump to the heating arrangement based on the set control algorithm; and increasing energy input into the heating arrangement in anticipation of a forecast fall in the temperature of the air from which the air source heat pump extracts energy. A method of controlling a premises heating installation is also disclosed.

A control apparatus for a heat pump hot water supply system of the indirect heating method is provided such that a change in heat transfer efficiency of a second heat exchanger is estimated by using either or both of a tank water temperature and a temperature of a second refrigerant flowing through a water circuit. When the heat transfer efficiency is determined to be high, an operation switching unit raises an output of a heat source device. When the heat transfer efficiency is determined to be low, the operation switching unit lowers the output of the heat source device.

A hybrid heat pump system comprise a geothermal heat pump system, an air source heat pump system, and a buffer heat-storage configured to exchange a heat with the geothermal heat pump system and the air source heat pump system and to store therein the exchanged heat. The buffer heat-storage comprises fluid circulation lines fluid-coupled to and between an air heater and the buffer heat-storage to realize a circulation of a refrigerant fluid therebetween, which receives a heat energy from the buffer heat-storage, wherein the air heater is configured to heat the air thereto from an outdoor using the refrigerant fluid.

A hot-water supply and heating system includes: a first pump that circulates a first heat medium between a heat source unit and a heat-medium heat exchanger; a second pump that causes a second heat medium to flow between a load-side device and the heat-medium heat exchanger; a first temperature sensor that detects a primary fluid temperature that is a temperature of the first heat medium that flows out of the heat source unit; a heat-source-unit controller; and a pump controller. The heat-source-unit controller transmits information indicating the heating capacity of the heat source unit reaches an upper limit value to the pump controller, when it is determined that the primary fluid temperature is lower than a target temperature and the heating capability of the heat source unit is equal to the upper limit value. The pump controller reduces an operation frequency of the second pump when receiving the above information.

A system for heating an indoor environment comprising: a primary heat source for heating a heat transfer fluid; at least one remotely actuatable valve for stepped or continuous control of the flow rate of a heat transfer fluid through a return pipe outlet of a heat emitter; a pipe temperature sensor for measuring the temperature of a return pipe outlet of a heat emitter; an optional room temperature sensor for measuring the ambient temperature of an indoor environment; an optional user interface for receiving instructions from a user including at least one target ambient temperature; an electronic controller configured to receive temperature measurement information from each of the pipe temperature sensors and (optionally) temperature measurement information from each of the room temperature sensors, and further configured to provide control instructions to each of the remotely actuatable valves relating to flow rate control; wherein the electronic controller comprises a processor configured to determine the control instructions based at least in part on the temperature measurement information.

A thermal system for providing thermal conditioning to a facility includes a facility air circuit for circulating a facility air throughout the facility and a downhole fluid circuit for circulating a downhole fluid. The facility air circuit is thermally connected to a heat pump for exchanging heat with the facility air. The downhole fluid circuit includes the heat pump for exchanging heat with the downhole fluid, a main loop, including a borehole heat exchanger (BHE) for exchanging heat between the downhole fluid and a geological formation, and an exhaust loop including an exhaust heat exchanger coupled to an exhaust of the facility air circuit, wherein the exhaust loop is configured to circulate at least some of the downhole fluid through the exhaust heat exchanger to exchange heat between the downhole fluid and an exhaust flow of the facility air exhausted from the facility at the exhaust.

An energy storage system and method for operating same are provided. The system comprises a first heat exchanger for heating a first heat transfer fluid in fluid communication with a ground heat exchanger and a heat pump; and a first circulation device for circulating the first heat transfer fluid. An energy collector is in fluid communication with the first heat exchanger for transferring energy collected by an energy collector to the first heat exchanger with a second heat transfer fluid circulate by a second circulation device. A controller actuates the first and second circulation devices to circulate the first and second heat transfer fluids. If temperature sensor data of the first and second heat transfer fluids entering the first heat exchanger is above a threshold valve, the controller continues to actuate first and second circulation devices to circulate the first and second heat transfer fluids.

A hydronic system includes a partition, a first conduit embedded in a first side of the partition, a second conduit embedded in a second side of the partition, a first sheet of finishing material covering the first conduit, a second sheet of finishing material covering the second conduit, and at least one valve and at least one pump. The at least one valve and at least one pump are configured to control a flow of a fluid inside the first conduit and the second conduit. When the hydronic system is operating in an isolating mode, the fluid flows in a first closed loop through the first conduit and the fluid flows in a second closed loop through the second conduit. When the hydronic system is operating in a heat exchange mode, the fluid flows between the first conduit and the second conduit in a third closed loop.