BG62823B1 - Plant for the production of water and dried and cooled air by atmospheric moisture condensation - Google Patents

Abstract

The plant shall be used for the airconditioning of residential and industrial buildings, and at the time supplying them with water for different purposes. It can be used both by individual families and in greenhouses, livetock raising and other farms. The plant includes a cyclone unit for precooling of the atmospheric air (13) to which a unit for start sprinkling of the atmospheric inlet air (16) is mounted having connection with condensation cyclone unit (15). A cold water tank (7) is also connected to an outlet main cold water line (9). A hot water tank (8) is connected to an outlet hot water main line (10). The cyclone unit (13) is connected by means of a supply main line (14) to the outlet of the condensation cyclone unit (15), and the start sprinkling unit (16) is connected, by means of a supply main line (17) to the cold water tank (7). 5 claims, 4 figures

Description

The invention relates to an air conditioning system with accompanying extraction of water and dried and cooled air through 10 condensations of atmospheric humidity and will find application for air conditioning of residential and industrial premises and for supplying water to individual families, settlements, greenhouses and livestock farms and 15 farms in the absence of natural water sources.

BACKGROUND OF THE INVENTION

A device for extracting water from the air is known, consisting of a filtration unit, a cold center and a condensing unit, a cold water tank connected to the outlet means for cold water, a tank for hot water 25 and, respectively, outlet means for hot water / 1 /.

A disadvantage of the known device is that for the condensation of atmospheric moisture it uses only a temperature gradient 30 created in the cold center without high-voltage ionization prior to which no sufficient amount of dried and cooled air can be obtained and a large contact surface is required in 35 condensing unit and fan with very large flow.

Another disadvantage of this device is that it cannot produce condensed water with certain chemical properties. In addition, 40 is required to allow exhaust air to be used by the indirect room air conditioning unit.

SUMMARY OF THE INVENTION

It is an object of the invention to provide an air-conditioning system with concomitant water extraction by condensation of at 50 mospheric moisture in parallel to receive dried and cooled air, allowing intensive extraction of water from its moisture content and full use of the condensed water obtained with predefined properties, qualities and parameters.

According to the invention, the problem is solved by air conditioning with concomitant water extraction by condensation of atmospheric humidity and simultaneous production of cooled and dried air. The air-conditioning system includes an air filtration and cooling unit, a pressure unit, a cooling center connected to a condensing unit, which in turn is connected to a cold water tank and a hot water tank, as well as highways for cold and hot respectively. water.

The condensing unit is designed as a cyclone condensing unit, and the filter unit is connected to a silencer unit, connected in series with the air to a heat exchanger for cold recovery, to the heat exchanger of cold power, to a cyclone cooling unit, to a starting block. and with the cyclone condensing unit.

In this case, the cyclone atmospheric air cooling unit is connected via a supply line to the outlet of the cyclone condensing unit. The latter includes heat exchange sections, which are evaporators of the cold center. A connection is provided between the start-up irrigation unit and the cold water tank on which the pump is located. A mineralization unit is provided to the cold water tank, and in order to recover the mechanical energy, the cyclone condenser unit is connected to a turbo-expander unit and, accordingly, to a stabilizer unit.

The cyclone condensing unit heat exchanger sections consist of high thermal conductivity coils, covered by mesh shaped and dielectric coated heat radiators. In the sections between the coils and between the inner surface of the mesh radiators there is a multilayer strip of porous dielectric material. It ends at the upper part with an electrode (anode) of non-corroding material, and at the bottom with an electrode (cathode), between them depolarizing AC electrode coupled to a low frequency electric generator.

The strip of porous dielectric material and the enclosing part of the sieve radiators are covered and cemented with a highly porous, hydrosorbent compound.

Depolarizing electrodes and ultrasonic emitters are installed in the heat exchange section.

At the inlet of the cyclone condenser block, transversely to the air stream, along its entire cross section, two lattice electrodes for air ionization through a barrier, quiet high-voltage discharge are arranged parallel to each other.

The advantages of the invention are that the installation enables intensive extraction of water masses of different quantities, properties and conditions and produces dried and cooled air, which can be used for indirect indoor air conditioning. As most condensation water is heated, it can be used for domestic consumption and for indoor heating.

Explanation of the annexed figures

The accompanying figures show one of the possible embodiments of the installation according to the invention.

Figure 1 is a block diagram of an air-conditioning system for the extraction of water by condensation of atmospheric moisture and for the production of dried and cooled air.

Figure 2 is a sectional view of the condensation cyclone unit of the installation.

Figure 3 is a sketch of the three-electrode heat exchange section of a cyclone block for condensation of atmospheric moisture water of FIG. 1.

Figure 4 is a section through AA of the three-electrode heat exchange section of FIG. 2.

An embodiment of the invention

According to an exemplary embodiment of the invention, the air-conditioning installation consists of a filter unit 1 for purifying the intake air into the installation 2 connected via an air duct through the forced atmospheric air to a silencer unit 3 connected in series to a heat exchange unit for cold recuperation. the path of the charged atmospheric air includes a suction and discharge unit 5 having an installation connection with the cold center (heat pump) 6, with the cold water tank 7, with a latch hot water tank 8 with cold water outlet line 9, hot water outlet line 10 and outlet air line 11 for dried and cooled air 12. A cyclone block for atmospheric air cooling is located along the forced atmospheric air 13. connected via a supply highway 14 to the outlet of the condensation cyclone unit 15 together with the starter irrigation unit 16, which is connected via a pump 17 to the cold water tank 7. The cyclone condenser unit 15 consists of a cyclone housing 35 in which they are located parallel to each other and one after the other heat exchange sections 19, arranged in a circle. Each heat exchanger section 19 consists of a high-conductivity coil 20 representing the evaporator of the cooling center 6. The inlet 21 and the outlet 22 of the coils 20 are connected to the cold center 6. The coils 20 are enclosed by grid-shaped and dielectric-coated heat-conducting radiators 23. two each of the serpentine sections. In the gaps of the coils 20 and between the inner surfaces of the radiators 23 there is a multilayer strip of porous dielectric material 24 which terminates at the top with an electrode (anode) 25 and at the bottom with an electrode (cathode) 26.

The strip of porous dielectric material 24 and the radiator part 23 surrounding it are covered with a highly porous compound 27 with high hydrosorbent properties. In the middle of the compound there is a tape alternating depolarizing electrode 28 connected to a low-frequency power generator 29. The cyclone pre-cooling unit 13 is connected to a plate heat exchanger-cooler of cold power 30 whose plates are coated with electret lacquer for pre-ionization of the inlet. On the path of the air-pumped atmospheric stream for the recovery of mechanical energy, a turbo-expander unit 31 having high-voltage blades (for "quiet, barrier" discharge) is connected to the inlet of the cyclone condensing unit 15. The turbo expander unit 31 is connected to a power generator. In order to stabilize the parameters of the recuperative energy obtained, the turbo expander unit 31 is connected to a stabilizer unit 32, which in turn is connected to the cold center 6.

The arrangement of the cyclone condensing unit 15 in the composition of the installation shown in FIG. 2, consists of a cyclone housing 35, in which are arranged one after the other and parallel to each other, the heat exchange sections 19, which lie concentrically about an axial turbo expander 31 connected to a stabilizing unit 32.

The heat exchange section 19 of the installation shown in FIG. 3 is located in the cyclone housing 35 and consists of meander-like tubes (coils) 20 which are connected to the cold center 6.

The heat exchange section 19 lying in the housing 35 (shown in Fig. 4 in section AA) includes the coils 20 covered by heat radiators 23, two for each coil section. In the gaps of the coils 20 and between the inner surfaces of the radiators 23 there is a multilayer strip of porous dielectric material 24 terminating at the top with an electrode (anode) 25 and at the bottom with an electrode (cathode) 26. There is impregnation therein. hydrosorbent compound 27 comprising a strip alternating current depolarizing electrode 28 coupled to a low-frequency electrical generator 29.

The installation also includes a unit for the mineralization and sterilization of drinking water 36.

Application of the invention

The operation of the installation described in the example embodiment is as follows.

The humidifying atmospheric air 2 is sucked in from the ground layer of the atmosphere through the filter (purification) block 1 and through the silencer unit 3 by the action of the suction-injection section - block 5, passes through the heat exchange block for cold recuperation 4, through the cyclone block for the pre-cyclone block. 13 and the starting dew unit 16 then pumped into the cyclone condensing unit 15. The air temperature after the pre-cooling unit 13 is close to the dew point. At the same temperature, the suctioned moist air 2 is forced into the cyclone condensation unit 15 by passing through sieve-shaped high-voltage flat electrodes. The barrier "quiet" high-voltage discharge generated by the isolated electrodes ionizes the air, whereby the number of condensation nuclei increases abruptly. The pre-ionization is also realized by the action of the electret lacquer coating of the plates in the regenerative heat exchange unit 30 and by the blades of the turbo expander 31. The movement of ionized air in the condensing unit 15 is turbulent due to the variable cross section of the heat conducting sections.

The surfaces of the grid-shaped radiators 23 have a temperature lower than the dew point of water in the air 2. By circulating the turbulent heat exchangers, the ionized air cools below the dew point and begins to intensively condense its moisture. The hydrosorbent properties of the highly porous compound 27 further accelerate the process of water condensation. The first drainage of water condensate from compound 27 is the result of the simultaneous manifestation of three processes - gravity, cohesion and electro-osmotic.

The electro-osmotic process is carried out by applying a constant voltage between the anode 25 and the cathode 26. The depolarization is carried out by the third alternating electrode 28 fed by a low-frequency generator 29. Cold and dried air is released at the outlet of the cyclone condensation unit 15, which after passing through in front of the cooling unit 13, is a ready-made product for indirect indoor air conditioning. The mechanical energy recuperation from the suction and discharge unit is realized by turbodetender unit 31 and stabilizer 32. The additional electrostatic condensation water removal is realized by ultrasonic emitters not shown in the figures but located in the cyclone condensation unit 15. It is collected in a cold water tank 7 and a hot water tank 8. The cold water is brought to the consumers along the feed water highway 9 and, by mineralization in the block 36, obtains the desired chemical composition and taste. The water from the hot water tank 8 is supplied by the pump 19 and is heated in the condenser of the cooling center 6, and then fed to the consumers on the supply water highway 10. In its complete configuration, the installation for extraction of water and dried and cooled air by condensation of atmospheric moisture produces the following products: distilled water, water with the desired chemical composition and taste, warm chemically pure water and dried and cooled air.

In order to enter the operating mode quickly, the start-up irrigation unit 16 is switched on at the start-up point for a short time in the pump 17. The cooling unit 13 provides an economical operation mode of the installation.

Claims (5)

Claims 1. Installation for extraction of water and dried and cooled air by condensation of atmospheric humidity, including an atmospheric air filter unit, a discharge unit, a cold center connected to a condensing unit connected in turn to cold and hot water tanks, as well as outlet highways with pumps, respectively for cold and hot water, characterized in that the condensation unit is designed as a cyclone condensation unit (15) and the filter unit (5) is connected to a silencer unit (3), such as is consistently connected in the course of air with heat exchanger block for cold recuperation (4 ') with heat exchanger recuperator of cold power (30), cyclone pre-cooling unit (13), start-up irrigation unit (16) and cyclone condensation block (15), with the cyclone the atmospheric air cooling unit (13) is connected via a supply line (14) to the outlet of the cyclone condensing unit (15), which includes heat exchange sections (19) which represent evaporators of the cold center (6), intended connection between 5 starting dew units (16) and the cold water tank (7) to which the pump (17) is located, and a mineralization block (36) is provided to the cold water tank (36), wherein the cyclone 10 condensation block (15) is connected to a turbo expander block (31) connected respectively to a stabilizer block (32). 2. Installation for extraction of water and dried and cooled air by condensation Atmospheric moisture according to claim 1, characterized in that it comprises heat exchange sections (19) consisting of high-conductivity coils (20), enclosed by a network-shaped profiled top20 radiator (23) with a dielectric coating such as the sections between coils (20) and between the inner surfaces of the mesh radiators (2) there is a multilayer strip of porous dielectric material (24) terminating at the top with an electrode (anode) of non-corroding material (25) and at the bottom with electrode (cathode) (26), such as between m x has a depolarizing electrode (28) connected to the low-frequency generator at 30 rotor (29). 3. Installation for extraction of water and dried and cooled air by condensation of atmospheric moisture according to claims 1 and 2, characterized in that 35 rests of dielectric material (24) and the enclosing part of the sieve radiators (23) are poured and cemented with a highly porous hydrosorbent compound (27). 4. Installation for water extraction and 40 dried and cooled air from atmospheric moisture according to claims 1, 2 and 3, characterized in that in addition to depolarizing electrodes (28) and ultrasonic radiators45 (34) are mounted in the heat exchange sections (19). 5. An installation for extracting water and dried and cooled air from atmospheric moisture according to claim 1, characterized in that at the inlet of the cyclone condensate 50 transverse units (15), transversely to the air stream, along its entire cross section are arranged parallel to each other,