SU857002A1 - Hygroscopic distillation unit - Google Patents

Description

The invention relates to a device for desalination, as well as demineralization of water, and may find application in the chemical, metallurgical, food industries, as well as in the energy sector. . . . ⁵

Evaporative desalination plants with an intermediate gas coolant are known that provide the maximum degree of fresh water extraction with the release of salts in the form of dry residue p].

Such plants have high energy efficiency, but are technologically complex, metal-intensive.

Also known and found application for desalination and demineralization of water hygroscopic desalination plants C 23 ·

These settings are technologically pros- _m you are quite reliable, but in them there is a process of scaling. In addition, the energy efficiency of such plants is not high enough, and the degree of fresh water extraction (degree of concentration _{f of the} solution) is small due to the contact of the solution with the heating surface.

The closest to the proposed technical essence is a hygroscopic desalination plant, in which the energy efficiency and the degree of fresh water extraction are increased by utilizing the heat of brine and fresh water and increasing the number of stages of evaporation and condensation of water. This installation includes an evaporator, a condenser, which is also a source water heater, a heater, a gas blower, source water pumps, distillate and brine, as well as heat exchangers for heating the source water with distillate and brine. In it, the source water is heated in the steps of the condenser due to the heat of condensation of water from the air coming from the steps of the evaporator, is additionally heated in the heater and fed to the evaporator, where it cools and partially evaporates, heats and moistens the air.

To carry out heat recovery in the specified installation, the solution heater and condenser are made in the form of one surface apparatus, which determines scale formation on the surface washed by the solution [h].

The disadvantage of this installation is its low efficiency due to the increased scale formation on the heat transfer surfaces.

The purpose of the invention is to increase the efficiency of the installation by reducing scale formation on heat transfer surfaces.

This goal is achieved by the fact that the hygroscopic desalination plant, comprising a source water heater, an evaporator, a condenser, a gas blower, and pumps for the initial water distillate and brine, is equipped with a gas heater located along the gas between the condenser and the water heater.

In addition, in the indicated installation, the initial water heater is made in the form of a contact apparatus.

The drawing shows a diagram of a hygroscopic desalination plant.

The installation consists of a source water heater I, a gas heater 2, a condenser 3, a cooler 4, an evaporator 5, a blower 6, a gas blower 7, a source water pump 8, a brine pump 9 and a distillate pump 10.

The working process of desalination is as follows.

The source water is pumped 8 to the source water heater 1, in which the water is heated in contact with the gas, for example, to 120 ° C, and then: it is supplied to the evaporator 5, where it partially evaporates and concentrates when interacting with air. After that, part of the brine pump 9 is removed from the installation, and part is fed to recirculation, mixing at the inlet of the source water heater 1 with the newly incoming source raster. Air from the evaporator enters the annulus of the condenser 3, where water assimilated by air in the evaporator 5 condenses and flows through the tubes, heating the gas passing inside the pipes and then entering the gas heater 2. Here, the gas is heated, for example, to 160 ° C, and enters the source water heater 1, after which it is supplied to the gas blower 7 and then, after re-cooling in the cooler 4, again enters the condenser

3. The distillate from the condenser is discharged by the pump 10 and removed from the unit, and the dried air by the blower is again fed to the evaporator 5 for humidification.

The proposed hygroscopic desalination plant15 is characterized by increased efficiency by reducing scale formation on heat transfer surfaces. This is due to a decrease in plant downtime associated with cleaning surfaces 20 of heat transfer from scale (up to 10% in the structure of the cost of distillate) and the consumption of materials for cleaning surfaces (up to 2% in the structure of the cost of production), reducing the need for backup equipment by 30-40%, as well as a decrease in the share of manual labor in the operation of the installation, which generally leads to a reduction in the cost of producing distillate by 15-20% ₃₀ compared with the known hygroscopic installation.

Claims (3)

The invention relates to devices for desalination, as well as demineralization of water, and can be used in the chemical, metallurgical, food industries, as well as in the energy sector. Evaporative desalination plants with an intermediate gas coolant are known that provide a limited degree of fresh water extraction with discharge salts in the form of a dry residue) J. Such plants have high energy efficiency, but technologically complex, metal-intensive. Dd desalination and demineralization of water are also known and have been used hygroscopic desalination plants 23 These plants are technologically simple, reliable enough, but they form a scale formation process. In addition, the energy efficiency of such facilities is insufficiently high, and the degree of extraction of fresh water (the degree of concentration of the solution) is small due to the contact of the solution with the heating surface. Closest to the proposed technical entity is a hygroscopic desalination plant, in which the energy efficiency and the degree of extraction of fresh water are increased by utilizing the heat of brine and fresh water and increasing the number of evaporation and condensation stages of water. This installation includes an evaporator, a condenser, which is also a source water heater, a preheater, a gas blower, a source water pump, a distillate and brine pumps, and heat exchangers for heating the source water by distillate and brine. In it, the initial water is heated in the steps of the condenser due to the heat of condensation of water from the air coming from the evaporator steps, is additionally heated in the preheater and fed to the evaporator, where it cools and partially evaporates, heats and moistens the air. In this installation, the solution heater and condenser are made in the form of a single surface apparatus, which predetermines scale formation on the surface washed by solution Z. The disadvantage of this installation is its low and efficiency due to, the increased scale formation on heat transfer surfaces. The purpose of the invention is to increase the efficiency of the installation by reducing scale formation on the heat exchange surfaces. This goal is achieved by the fact that a hygroscopic desalination plant containing a source water heater, an evaporator, a gas blower condenser, source water pumps and distillate is equipped with a gas heater located along the hectare between the condenser and the water heater. In addition, in the above, the installation of the initial heater, water is made in the form of a contact apparatus. The drawing shows a diagram of a hygroscopic desalination plant. The installation consists of source water heater 1, gas heater 2, condenser 3, cooler 4, evaporator 5, blower 6, gas blower 7, source water pump 8, brine pump 9, and distillate pump 10. The desalination process proceeds as follows. The source water is pumped to pump 8 to source water heater 1, in which water is heated by contact with gas, for example, up to 120 ° C, and then fed to evaporator 5, where it is partially evaporated and concentrated by contact with air. After that, a part of the brine is withdrawn from the installation by the pump 9, and a part is fed to the recycling, mixing at the entrance to the heater 1 of the source water with the newly supplied source solution. The air from the evaporator enters the annular space of the condenser 3, where water assimilated by air in the evaporator 5 condenses and flows through the tubes, heating the pelvis passing inside the tubes and the post 8 4 Ayuishch then into the heater 2 here the gas is heated, for example, to and enters the heater 1 of similar water, after cooling in which it is fed into the gas blower 7 and then, after being re-cooled in the cooler 4, again enters the condenser 3, the distillate from the condenser is withdrawn by the pump 10 and removed from the unit blower 6 is supplied again to the evaporator humidification 5 A proposed water-absorbing desalination plant characterized povshennoy efficiency by reducing scale formation on heat transfer surfaces. This is due to the reduction of plant downtime associated with cleaning the heat exchange surfaces from scale (up to 10% in the cost structure of the distillate) and material consumption for cleaning the surfaces (up to 2% in the cost structure), reducing the need for backup equipment by 30-40%, as well as a decrease in the share of manual labor in the operation of the installation, which generally leads to a decrease in the cost of producing distillate by i compared with the known hygroscopic installation. Claim 1. Hygroscopic desalination plant comprising heating, source water tank, evaporator, condenser, gas blower and source water, distillate and brine pumps, which means that in order to increase plant efficiency by reducing scale formation on heat exchange surfaces It is equipped with a gas heater located along the gas between the condenser and the water heater. 2. Installation according to claim 1, characterized in that the source water heater is designed as a contact apparatus. Sources of information taken into account in the examination 1, Taubman E, I., Bilder 3, P. Thermal neutralization of mineralized ones. the crumbed waste M., 1975, p. 86-88. 2. Patent of England No. 2260214, cl. In I, 1972. 857002 waters. 3. Slesarenko V.N. Modern methods of desalination of sea and salt waters. M., 1973, p. 49, 50, fig. 2-24. Brine ref rr