The invention relates to a floor drain comprising a drain compartment having a bottom, at least one side and an open upper portion. The bottom and the at least one side together define a space to collect waste water. The bottom comprises an opening for a drain trap. The floor drain further comprises a heat exchanger element, receivable in the space of the drain compartment, for transferring heat present in the waste water to fresh water. The heat exchanger element is provided with a first connection and a second connection. The first connection and the second connection are arranged inside the space of the drain compartment. A first conduit is connected to the first connection and a second conduit is connected to the second connection.

The present invention relates to a heat recovery system, of a part of the energy spent in the preparation of waste water, e.g. water from baths or kitchens, energy that is usually lost when the water is drained into the sewer. This energy can be recovered and reused to heat water that is readily used, for example in the shower, or can be stored in a water heater. This system is designed in such a way that, together with any tub or shower base, constitutes a heat recovery shower base or a heat recovery bath, for example. The energy recovery system is composed, preferably, by a coil generally made of copper inside a PVC pipe that has at one end a throttle plate also made of PVC, a filter for the protection of the system against impurities, turbulence fins, and an external casing. The system has a compact structure which benefits its rapid adaptation.

A flushing assembly comprising a foundation and a heat exchanging member. The foundation comprises a bowl shape providing an envelope surface defining an upper inlet and a lower outlet, the lower outlet being arranged to communicate with a drainage. The heat exchanging member comprises a helical channel defined between an upper and a lower wall, the helical channel having an extension along the envelope surface of the bowl shaped foundation, and the helical channel being arranged to be provided with a through flow of a secondary fluid. The flushing assembly is configured to provide a helical channel for a primary fluid extending between the envelope surface of the foundation and the lower wall of the heat exchanging member for guiding the primary fluid there through from the upper inlet to the lower outlet towards the drainage, thereby allowing heat exchange between the primary fluid and the secondary fluid.

A heat exchanger that includes a portion for heat exchange with gray water, a portion for heat exchange with clean water, the heat exchanger being arranged to transfer heat between the gray water heat-exchange portion and the clean water heat-exchange portion during a distribution of water and thereby heat a feedwater to a first temperature, wherein the heat exchanger includes a first heating means arranged to achieve the heating of the feedwater, for heating the feedwater to a second temperature, and wherein the heat exchanger includes a second heating means arranged to keep the clean water heat-exchange portion at a temperature greater than or equal to the first temperature during a period without water distribution.

A tank for waste water partially or fully buried in the ground or immersed in water includes a wall made of a high thermal conductivity material, which in turn has a pair of walls forming a cavity creating a circuit of a convective fluid for heat exchange with both the waste water contained inside the tank and with the ground and/or groundwater external to the tank.

Described herein are systems and methods for wastewater heat recovery, including a system for heat recovery, the system comprising: (i) a heat exchanger that is configured to heat water with thermal energy recovered from a wastewater stream, wherein the wastewater stream is treated by a wastewater treatment system that is in fluidic communication with the heat recovery system, and (ii) a device configured to control a flow rate of wastewater in the heat recovery system based at least in part on real-time sensor data.

A plumbing fixture includes a water passage configured to hold water, a first plate shaped according to a cross section of the water passage and spaced at a first distance from the water passage, and a second plate shaped according to the cross section of the water passage and spaced at a second distance from the water passage. A voltage between the first plate and the second plate is generated based on the water in the water passage.

The present disclosure relates to a heat pump system for transferring heat using a body of water. The heat pump system includes a water pumping system and a heating and cooling loop that directs a working fluid through a heat exchanger where heat is transferred between the working fluid and water from the body of water. The water pumping system includes an inlet line, an outlet line, and a pump. The pump moves the water from the body of water through the inlet line to the heat exchanger then through the outlet line and back to the body of water. A biocide generating device is positioned along the inlet line for providing real-time generation of biocide in the water flowing through the inlet line. A recirculation line directs water from a tap location on the inlet line positioned downstream from the biocide generating device to the water intake.

Provided herein are water distribution systems and methods of operating water distribution systems that include a heat pump transferring heat between a first water stream dispensed into a space and a second water stream collected after use of the first water stream in the space. The heat pump can efficiently and effectively raise the temperature of the first water stream to a comfortable level for a user. In some embodiments, the first water stream may be further conditioned and/or processed downstream from the heat pump prior to being dispensed, e.g., using a mixing valve, a water storage tank, and/or a thermal storage device. In some embodiments, one or more operating parameters of the heat pump may be controlled according to a desired temperature of the first water stream being dispensed into the space.

A grey water heat recovery apparatus is disclosed in which heat is transferred between a grey water stream and a fresh water stream. The apparatus comprises: a grey water flow path leading from a source inlet to a drain outlet; a plurality of heat exchangers arranged in said grey water flow path; a separator arranged upstream of said heat exchangers, arranged to separate grey water from the source inlet into a plurality of parallel sub-paths, each sub-path being lead to one of the heat exchangers; and a collector arranged downstream of said heat exchangers, arranged to reassemble the grey water from the sub-paths into a single flow path. Each heat exchanger comprises a grey water tube extending from the separator to the collector, and an outer tube surrounding at least a part of the grey water tube, the outer tube defining an annular space around the grey water tube. A fresh water flow path formed within the annular spaces around the grey water tubes in the heat exchangers has a flow direction being opposite to the flow direction of the grey water.