The present invention provides a configuration of a multi-stage flash desalination system including a thermal vapor compressor and a condensate flash tank, which allows to extract a vapor from the condensate before it is returned to the power plant and to compress this vapor and use it as part of the heating steam in the brine heater, which reduces the required amount of steam supply from the power plant, while the condensate returned to the power plant at a reduced temperature allows to utilize low grade heat of exhaust gases of a steam generator to re-heat the condensate, which results in a reduced energy consumption allocated to the multi-stage flash desalination plant and an improvement of the energy efficiency of the power plant.

The present disclosure relates to a distillation system using waste heat, the system comprising: a waste heat supply source which receives feedstock and separates the feedstock by a difference of boiling point, wherein waste heat is generated during separation of the feedstock; a heat-exchange unit which receives water from a water supply source and which evaporates the water by heat-exchange of the water with the waste heat supplied from the waste heat supply source; a mechanical vapor recompression module (MVR) which receives water vapor generated in the heat-exchange unit and which compresses the water vapor; and a waste water supply which supplies waste water generated in a separate process to the heat-exchange unit such that the amount of saturated water vapor which is supplied to the mechanical vapor recompression module is increased.

Mechanical vapor recompression (MVR) liquid purification system includes a pressure-tight enclosure having a circular cylindrical elongated shape along a longitudinal axis A, and evaporation compartments E1-E3 arranged within the enclosure. Each compartment has a plurality of longitudinal pipes running from one sidewall to another sidewall, and circular sidewalls having openings for the plurality of pipes. A central tube runs along the axis A through the centers of the compartments E1-E3, and allows steam to flow from the second end to the first end. The number of pipes is highest in the first compartment E1, then gradually fewer in the second E2 and third E3. The pipes allow steam to flow from the first end to the second end. A compressor assembly includes a compressor provided with compressor vane members structured to provide steam flow along the longitudinal axis and a motor for rotating the compressor at a variable rotational speed.

A system for distributed utilities including electrical power and water. A generation device is provided for converting an available resource to a desired utility; the resource may be water, in which case the generator is a purifier for purifying untreated water, or, alternatively, the generator may convert a fuel to electrical power. In either case, an input sensor is provided for measuring input to the generation device, while an output sensor is provided for measuring consumption of output from the generation device. The monitoring system has a controller for concatenating measured input and consumption of output on the basis of the input and output sensors. Measured parameters are telemetered to a remote site where utility generation and use are monitored and may also be controlled. At least a portion of the electrical power capacity of the electric generation unit may power a water purification unit such as a vapor compression distillation unit, and heat output of the electric generation unit may supply heat to the water purification unit.

The duty of internal heat exchange can be flexibly adjusted without impairing energy saving performance of a HIDiC. A method of adjusting the duty of heat exchange in a heat exchange structure of a HIDiC includes totally condensing a portion of the vapor fed to a heat exchange structure in a heat exchange structure; and providing a liquid control valve downstream of the heat exchange structure on the first line, without providing a control valve on a vapor-flowing part of first and second lines of the HIDiC, and adjusting a flow rate of a portion of the compressor outlet vapor flowing into the heat exchange structure by using the control valve, while compensating for a pressure loss needed for the control valve by using a liquid head of a condensate, and/or by using pressurization by a pump.

A fluid vapor distillation system. The system includes a control system for controlling a fluid vapor distillation apparatus including a blow down controller for controlling a blow down valve, a source flow controller for controlling a source flow valve, and a blow down level sensor in communication with a blow down controller and a source flow controller, the blow down level sensor sends signals related to the blow down level to the blow down controller and the source flow controller indicative of the blow down level, wherein the source flow controller actuates the source flow valve based at least on the blow down level sensor signals, and wherein the blow down controller actuates the blow down valve based at least on the blow down level sensor signals, whereby the blow down level and the source flow level are maintained using the blow down level sensor signals as input.

A solar distillation apparatus configured to produce a distillate from a source liquid mixture, including a base member defining at least one flow path, a transparent cover panel spaced apart from the base member to define a volume therebetween; and an intermediate panel positioned between the base member and the transparent cover panel to divide the volume into an evaporation chamber and a condensation chamber, wherein the evaporation chamber communicates with the condensation chamber, the flow path of the base member is configured to carry the source liquid mixture in a first direction in the evaporation chamber to increase evaporation of a liquid from the source liquid mixture, and the evaporated liquid is configured to flow from the evaporation chamber in a second and opposite direction into the condensation chamber where the evaporated liquid condenses into the distillate.

An accelerated vapor recompression apparatus 10 converts incoming flow 35a to a concentrate 35c by developing a concentration profile 146 within a tank 30 holding a liquid 23 containing dissolved solids. The resulting curve 160 of saturation temperature of the stratified liquid 23 (such as a brine 23 or other material 23) moves away from the curve 162 corresponding to fully mixed conditions. The shift 174, 180 in saturation temperature results in increased boiling without increased energy from a heater 70 or compressor 50. A method 90, 200 of control of the system provides interventions 203, 204, 205, 206 at different levels 92, 94, 96, 98 of control, ranging from mass flows 35 to work of a compressor 50, heat from a heater 70, and a predictive processing 215 of feedback 217 for controlling commands 216 algorithmically.

A system for distributed utilities including electrical power and water. A generation device is provided for converting an available resource to a desired utility; the resource may be water, in which case the generator is a purifier for purifying untreated water, or, alternatively, the generator may convert a fuel to electrical power. In either case, an input sensor is provided for measuring input to the generation device, while an output sensor is provided for measuring consumption of output from the generation device. The monitoring system has a controller for concatenating measured input and consumption of output on the basis of the input and output sensors. Measured parameters are telemetered to a remote site where utility generation and use are monitored and may also be controlled. At least a portion of the electrical power capacity of the electric generation unit may power a water purification unit such as a vapor compression distillation unit, and heat output of the electric generation unit may supply heat to the water purification unit.

A fluid vapor distillation system. The system includes a control system for controlling a fluid vapor distillation apparatus including a blow down controller for controlling a blow down valve, a source flow controller for controlling a source flow valve, and a blow down level sensor in communication with a blow down controller and a source flow controller, the blow down level sensor sends signals related to the blow down level to the blow down controller and the source flow controller indicative of the blow down level, wherein the source flow controller actuates the source flow valve based at least on the blow down level sensor signals, and wherein the blow down controller actuates the blow down valve based at least on the blow down level sensor signals, whereby the blow down level and the source flow level are maintained using the blow down level sensor signals as input.