RU2648057C1 - Vacuum desalination and electrical power generation unit - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: invention relates to liquid desalination. Vacuum desalination and electrical power generation unit for water comprises a sealed chamber with water bath (1), inside which, below the liquid level, there is evaporator (2) connected to solar collector (3) through pump (13), pump system comprising at least three vacuum pumps (5) connected by the pump system to three-way valves (6), (7), heat exchanger (4) connected via three-way valve (8) to the line for feeding source liquid and to distillate collector (9) which is connected to one of the vacuum pumps via reverse valve (15), recuperative heat exchanger (10), current converter (11) and electric accumulator (2) connected to pump system (5), pump (14) for feeding the source water.

EFFECT: invention provides reduced energy consumption for desalination due to efficiency of using solar energy, as well as universality of desalination units.

1 cl, 1 dwg

Description

The invention relates to the technology of desalination of water and can be used for local water supply with fresh water and power supply of settlements, housing, public and industrial buildings.

Known solar desalination plant containing at least one vacuum solar collector, at least one atomizer, a multi-section vacuum evaporator with a vertical arrangement of sections interconnected using pipelines with natural circulation, evaporative heat exchangers made in the form of spiral tubes, storage tank and condensation tank characterized in that induction heaters are installed in the lower section of the vacuum evaporator, and vacuum is installed in the upper section pump, fans are installed between the evaporator sections (RU 127063 U1, 04/20/2013).

A known solar collector desalination plant, comprising a glass enclosure in a thermally insulated casing, a light-absorbing coating of absorbent dark fabric placed on a metal sheet, a flexible pipe for supplying salt or cold water, a flexible pipe for draining hot water into the heat accumulator, the fabric is reinforced with metal threads, the metal sheet is perforated and provided with stops, pressing fabric to the glass fence to form a vapor zone between the sheet and the bottom of the housing, flexible pipes water inlet and outlet are connected to the heat accumulator and in them, also in the heat accumulator itself, a similar fabric is placed, reinforced with metal threads, connected to the fabric on a perforated sheet, two heat exchangers are additionally introduced into the heat accumulator, one of them is connected to the consumer’s heat supply, the output of the second heat exchanger is connected through the valves to the additional tank of distilled water, and the steam zone is connected through an additional thermally insulated flexible hollow pipe with the inlet of the second heat oobmennika (RU 115451 U1, 27.04.2012).

Known solar-wind desalination plant containing pipelines for supplying desalinated water, a pipe with a tap for draining the brine, a circulation pump, a heat electric heater, further comprises a circular cone-shaped solar collector, including a tubular spiral heat sink, cone-shaped support, transparent thermal insulation and a transparent cone-shaped external floor, dome, photovoltaic modules, internal hemispherical dome, confuser-diffuser, wind power installation, outside rotary rotor, internal fixed rotor, cavity located between the external hemispherical dome and the internal hemispherical dome, circular tray, temperature sensor, pressure sensor (vacuum), vacuum pump, electrovalve, heat collector, parabolic circular reflector of solar radiation, designed heat exchanger tank for desalinated water, air intake windows, circular swirl, cylindrical evaporation basin, heater manifold grate, spherical bottom, inv Torr, the electronic control unit, the charge-discharge controller, an annular lower cap insulation round the brine collection tray; the heat storage agent is made in the form of aluminum chips, the heat exchanger is designed for desalinated water (RU 2567324 C1, 10.11.2015).

The closest analogue is a solar desalination plant containing at least one tube of a vacuum solar collector, a desalination plant, a sun tracking device, three discrete sensors for the presence of water, a temperature sensor and a piping system, while the desalination unit is multi-sectional and contains desalination, condensation and distillate sections , vacuum manifold tubes are installed in the desalination section, discrete sensors are installed in the condensation section and in the desalination section and through electromagnetic relays s pipeline system with electromagnetic valves (RU 144 634 U1, 27.08.2014).

A significant disadvantage of the known devices is the complexity of the proposed designs and as a result of their unreliability in the process.

The problem to which the invention is directed, is the creation of an effective stand-alone desalination power plant of low productivity.

The technical result achieved in solving the problem is to reduce the energy consumption for desalination, due to the efficient use of solar energy and increasing the universality of desalination plants.

To achieve the technical result, a vacuum desalination plant for water with electricity generation is proposed, characterized in that it contains a sealed chamber with a water bath (1), inside of which a vaporizer (2) is placed below the water level, connected to the solar collector (3) through a pump ( 13), intended for circulation of the coolant; a pump system comprising at least three vacuum pumps (5) connected by a piping system with three-way valves (6), (7), (8) installed on them; a heat exchanger (4) for condensation of distillate vapor, connected via a three-way valve (8) to the source water supply pipe and to the distillate collector (9), which is connected through a non-return valve (15) to one of the vacuum pumps that is included in the vacuum pump system (5), a recuperative heat exchanger (10) for transferring heat from the brine removed from the unit to the source water supplied to the unit, a current transducer (11) and an electric accumulator (12) connected to the pump system (5), a pump (14) for supplying the source water.

In FIG. 1 shows a diagram of a device.

Vacuum desalination plant with electricity generation contains:

1 - sealed chamber with a water bath;

2 - evaporator;

3 - solar collector;

4 - heat exchanger for condensation of vapors of the distillate with a flowing initial liquid;

5 - vacuum pump;

6, 7, 8 - three-way valves;

9 - a collection of distillate;

10 - recuperative heat exchanger for transferring heat from brine removed from the installation to the source water supplied to the installation;

11 - current transducer;

12 - electric accumulator;

13, 14 - pump;

15 - check valve.

Vacuum desalination plant with electricity generation works as follows:

The sealed chamber 1 is pre-filled with water by the pump 14. A system consisting of three vacuum pumps 5 pumps air out of the installation, while the three-way valves 6 and 7 are in such a position that the suction of the pump 5 is communicated with the distillate collector 9, and the discharge with the atmosphere. Upon reaching the required vacuum for operation, the three-way valves 6 and 7 are switched in such a way that they connect the vacuum pump 5 to the vapor circuit of the distillate. Moreover, in the future, during the operation of the installation, when the pressure in the device increases, due to the accumulation of air dissolved in the make-up water, one of the pumps 5, by switching valves 6 and 7, performs the function of an auxiliary vacuum pump.

The coolant preheated in the solar collector 3 is pumped 13 to the evaporator 2, as a result of which the water in the heat chamber 1 heats up and when it reaches the saturation temperature corresponding to the vacuum level, it begins to boil. Condensation of the distillate vapor in the heat exchanger 4 by removing heat from the flowing source water supplied by the pump 14 causes the steam to flow from the sealed chamber 1 to the distillate collector 9 through the vacuum pump 5. The steam flow passing through the pump 5 drives the rotors, the moment of movement of which allows generate electric current and, through the converter 11, store energy in the electric accumulator 12.

In the sealed chamber 1, a constant water level is maintained by continuously supplying the source water with a flow rate equal to the sum of the flow rates of the distillate and brine discharged during operation of the installation. Intake water is supplied to the heat chamber 1, passing through a recuperative heat exchanger 10, in which it is heated by heat exchange with a brine stream leaving the sealed chamber 1. The brine is removed from the unit in an amount necessary to maintain a given degree of concentration or fraction of the evaporated distillate.

The implementation of the claimed invention allows to reduce the energy consumption for desalination due to the efficient use of solar energy and to increase the universality of the use of desalination plants.

Claims (1)

A vacuum desalination plant for water with electricity generation, characterized in that it contains a sealed chamber with a water bath (1), inside of which below the water level there is an evaporator (2) connected to the solar collector (3) through a pump (13) designed for circulation coolant system, a pump system containing at least three vacuum pumps (5) connected by a piping system with three-way valves installed on them (6), (7), a heat exchanger (4) for condensing distillate vapor, connected by Using a three-way valve (8) with a source water supply pipe and a distillate collector (9), which is connected through a non-return valve (15) to one of the vacuum pumps, which is a part of the vacuum pump system (5), a regenerative heat exchanger (10) for transmission heat from the brine removed from the unit to the source water supplied to the unit, a current transducer (11) and an electric accumulator (12) connected to the pump system (5), a pump (14) for supplying the source water.

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