A switch-mode power supply waste heat recovery and utilization system includes a switch-mode power supply unit, an air conditioner and a water storage tank that are all connected with pipes. The switch-mode power supply unit, the air conditioner and the water storage tank are in communication with each other through the pipes. The switch-mode power supply unit includes a cabinet. Fixed plates are fixedly connected to an inner side wall of the cabinet and arranged at equal intervals. A top and a bottom of the cabinet and respective interiors of the fixed plates are formed with cavities. The pipes are in communication with the cavities. A fan is fixedly connected to a side wall of the water storage tank, and is matched with the water storage tank. A filter screen is insertedly connected to an inner side wall of the water storage tank. A filter cotton is horizontally provided under the filter screen.

A distributed composite refrigeration system includes a multichannel heat exchanger and at least two refrigeration units. The at least two refrigeration units are connected to at least two indoor areas in one-to-one correspondences. Each refrigeration unit includes a refrigeration part, a heat exchange part, and a heat dissipation part. A refrigerant flows between the refrigeration part and the heat exchange part, an intermediate medium flows in the heat exchange part, and the refrigerant and the intermediate medium implement heat exchange at the heat exchange part. The heat exchange part delivers the intermediate medium obtained after heat exchange to the heat dissipation part and/or the multichannel heat exchanger for heat dissipation. The multichannel heat exchanger is thermally connected to an external pipe network, and the intermediate medium performs heat exchange with a heat carrying body in the external pipe network.

A composite refrigeration system includes a refrigeration part, a heat dissipation part, a first pipeline, a second pipeline, and a refrigerant. The refrigeration part uses the refrigerant to cool air sent into indoor space, and the heat dissipation part is configured to perform heat dissipation on the refrigerant. In addition, in two heat dissipation modes, the heat exchanger may exchange heat between the refrigerant and a heat carrier in an external pipeline network to implement heat dissipation. The composite refrigeration system implements, by using the heat exchanger, a function of exchanging heat with the external pipeline network, so that heat generated during operation of the composite refrigeration system can be at least partially transferred to the heat carrier in the external pipeline network, to implement the energy recycle and reuse.

There is disclosed a system and method for transferring waste heat from integrated circuits. In an embodiment, the system comprises: a self-contained enclosure having integrated circuits therein, the self-contained enclosure further including: a first fluid circuit configured for removing waste heat from the integrated circuits; an inlet for connection from an external water tank and an outlet for connection to the external water tank, that when connected with the external water tank forms a second fluid circuit; a heat exchanger operatively connected to the first fluid circuit and the second fluid circuit, and configured to transfer thermal energy therebetween; and a control for regulating a temperature gradient and a flow rate in each of the first and second fluid circuits, such that both a desired integrated circuit operating temperature and a desired water tank temperature is achieved. A plurality of self-contained enclosures co-located with water tanks may form nodes of a distributed computing and heating network.

A system for exchanging electrical energy between an electrical energy source and an electrical energy store of a vehicle, wherein the system includes an electrical connection, at least one electronic component, and a cooling device having a heat transfer medium, wherein, when the electrical energy store of the vehicle is connected to the electrical connection and electrical energy is exchanged between the energy source and the electrical energy store via the at least one electronic component, the heat transfer medium of the cooling device is designed to provide heat, which arises during the exchange of electrical energy in the system, to a consumer of the heat, which is coupled to the system and is arranged in a building.

One illustrative energy recovery system disclosed herein includes a facility and a closed chilled water loop including a chilled water stream delivered to the facility and a returning water stream that is received from the facility. In this example, the system also includes a primary heat exchanger having a first fluid side and a second fluid side, the first fluid side is adapted to receive supply water and the second fluid side is adapted to receive at least a portion of the returning return water stream. The primary heat exchanger is adapted to effectuate heat transfer between the supply water flowing in the first fluid side and the returning water stream flowing in the second fluid side.

A cooling and heating energy saving system includes a cooling and heating device, a data center, a boiler, a heat exchanger, and a circulating pump. The boiler receives excess heat of the data center and heat generated by the cooling and heating device, and then generates high-temperature heat and transfers the high-temperature heat to an indoor heating device. The heat exchanger receives heat from the cooling and heating device and the data center. The circulating pump receives the heat generated by the data center and transmits the heat to an outdoor cold source, and further transmits the outdoor cold source to an indoor device through the heat exchanger.

A modularized combined intelligent heat collector system, comprising a PTCR-xthm electric heating chip heat source main engine, a data control template, a constant-temperature and constant-pressure device and a variable-frequency pump; the variable-frequency pump and the PTCR-xthm electric heating chip heat source main engine are connected to the data control template; the outlet end of the PTCR-xthm electric heating chip heat source main engine is connected to the constant-temperature and constant-pressure device; the outlet end of the constant-temperature and constant-pressure device is connected to the PTCR-xthm electric heating chip heat source main engine through the variable-frequency pump; the PTCR-xthm electric heating chip heat source main engine directly leads out a user heating pipeline; and/or the PTCR-xthm electric heating chip heat source main engine leads out the user heating pipeline through the constant-temperature and constant-pressure device, and is connected to a heat exchanger of a user water heater.

An electric radiator is provided using calculating processors as a heat source and includes a heating body where the heat transfer between the heat source and the ambient air takes place; a number of processors distributed over a number of printed circuit boards forming the heat source of the radiator and a power resource carrying out calculations by external computer systems; a man-machine interface enabling the control of the calculating and calorific power supplied by the radiator; a power source stabilized for the different electrical components; and a network interface for connecting the radiator to the external networks.

A temperature control apparatus for a building, the apparatus comprising: an electricity generator, operable to contribute to an electrical power supply for consumer appliances at the building; a heat transfer circuit adapted to circulate heat transfer fluid to cool the electricity generator; a heating system comprising a heat source for providing heat energy to a space heater for heating at least one zone of the building and to a hot water tank arranged to store a supply of hot water for the building, and a heat exchanger adapted to supplement the heat energy from the heat source with heat energy obtained from the heat transfer circuit; a user interface adapted to enable a user to select at least one of (a) a desired temperature for the at least one zone of the building, and a first time period during which the desired temperature is to be maintained; and (b) a second time period for the supply of hot water from the hot water tank; and the apparatus further comprising: a controller configured to determine when to operate the electricity generator based on at least one of: (i) the thermal capacity of the hot water tank; and (ii) the first time period, the desired temperature and the current temperature of the at least one zone of the building.