RU2185482C2 - Apparatus for receiving biologically pure fresh water at condensation of moisture out of atmospheric air - Google Patents

Abstract

FIELD: processes and equipment for preparing fresh water. SUBSTANCE: apparatus includes solar batteries, cooling system, water collector, air duct, ventilation system and condenser in the form of coiled tube made of stainless steel and having on outer side spheric craters. Rectilinear portions of said tube are arranged vertically and they are flattened in direction normal relative to air flow. Such apparatus provides conditions unfavorable for growing microflora on walls of heat exchanger without decreasing operational efficiency of system. EFFECT: enhanced efficiency of apparatus due to lowered energy consumption for air ventilation, improved quality of fresh water. 5 dwg

Description

 The invention relates to installations for producing fresh water from atmospheric air, in particular to installations using renewable energy sources.

 Known installation in which the accumulation of cold for its use at night [1]. It contains solar electric batteries, a refrigeration unit, a cold accumulator, made in the form of a thermally insulated container filled with water, connected through a hydraulic pump and valve to a refrigeration unit and a heat exchanger-condenser located in the duct, which also contains a droplet eliminator and a fan. Under the hole in the duct there is a water collector.

 Installation works as follows. In the daytime, electricity from solar panels goes to the refrigeration unit, which produces cold. With the help of a valve, the refrigeration unit is connected to a thermally insulated container. The liquid in it is pumped through the refrigeration unit and cooled by means of a hydraulic pump, as a result, cold accumulates in the thermally insulated container. Then, the thermally insulated container with the help of the valve is disconnected from the refrigeration unit and connected to the heat exchanger-condenser. When the air humidity reaches a value close to 100%, the hydraulic pump and fan are turned on. With their help, cold liquid and moist air are passed through a condenser. Water vapor contained in the air condenses on its surface, and the droplets contained in it are captured by a droplet eliminator and trapped moisture flows into the water collector.

 The disadvantages of the installation are the high energy costs in the ventilation system for pumping air and the difficulty of cleaning the surface of the condenser from microscopic dust, which, when collected in the corners of the joints of the fins of the condenser tubes, forms a wet substrate where harmful microflora develop.

 Closest to the invention is a plant for producing biologically pure fresh water by condensation of moisture from atmospheric air, containing solar panels, a refrigeration system, a water collector, an air duct, a ventilation system and a condenser [2]. Her work uses solar energy. In the duct placed the evaporator of the refrigeration unit and the fan. The installation also contains a system for ozonation of water resulting from the operation of the installation.

 Installation works as follows. Due to the electricity received from solar panels, the refrigeration unit produces cold, which is released on the heat exchanger-evaporator. Humid air is blown through a fan through the duct in which the evaporator is located. As a result of contact with the surface of the heat exchanger-evaporator, the air cools, the steam contained in it becomes saturated, partially condenses on the surface of the heat exchanger and flows into the water collector, from where water enters a special tank where water is disinfected by ozonation.

 The disadvantage of this installation is its high energy consumption and low productivity.

Note that the concentration of water vapor in the atmosphere of those regions of the Earth where such systems for producing fresh water are effective varies from 10 g / l to 25 g / l. In this case, not all moisture is extracted. If we assume that 1 g will be extracted from a cubic meter of air, then to get 1 liter of water you will need to pump 1000 m ^{3 of} air. With a pumping speed of 10 m / s and a condenser area perpendicular to the air flow equal to 0.25 m ² , it will take about 7 minutes. The contact time of air with the cooling surface is quite short, and the efficiency of the moisture condensers is determined by the intensity of heat exchange between the refrigerant inside the metal tubes of the condensers and the stream of moist air flowing around it. Improving the heat transfer efficiency is achieved due to the finning of the condenser tubes. However, this significantly increases the fan energy consumption for turbulence of the flow, and microscopic dust settles in addition to moisture on the ribs and places of their connection with the condenser tubes, resulting in the formation of a substrate on which microflora develops and which may contain toxic substances that come with dust.

 The latter circumstance requires routine cleaning of the condensing surface of the condenser, which is hampered by the strong development of the fin surface and the presence of many places at the joints of the ribs and tubes where the substrate accumulates. The use of an ozonizer cannot solve the problem of complete purification of the water received in the system from toxic substances (in particular, heavy metals) and microorganisms that may be contained in pieces of micro suspension suspended from a moisture condenser. The application of antibacterial coatings is unacceptable, since water is then used as drinking water.

 The objective of the invention is to increase the efficiency of the installation by reducing energy costs for air ventilation and improving the quality of the fresh water obtained by creating conditions unfavorable for the growth of microflora on the walls of the heat exchanger, without reducing the efficiency of the installation.

 The technical result is achieved by the fact that in the installation for producing biologically pure fresh water by condensation of moisture from atmospheric air, containing solar panels, a refrigeration system, a water collector, an air duct, a ventilation system and a condenser, a tube made of stainless steel, curved into a coil, is introduced as a condenser, on the outer side of which spherical holes are extruded, and the rectilinear sections of which are vertically and flattened in a direction perpendicular to the air flow.

 A positive effect is achieved due to the fact that the coherent structures in the air flow resulting in this lead to a decrease in the resistance coefficient by a factor of 2, and the coil tube is sufficiently smooth / does not have sharp edges and corners /, is easy to clean, and there is no room for dust accumulation, and when air flows between the holes, vortex structures arise that provide high heat exchange efficiency between the condenser and the incoming air flow. In this case, the intensification of mass and heat transfer is realized when the growth of hydraulic resistance lags behind the flow around such a relief as compared with the flow around an initially smooth surface.

 It is known that with an increase in the Reynolds number (Re = (v1) / ν, where v is the incident flow velocity, l is the characteristic size of the object, and ν is the dynamic viscosity of the medium flowing around the object, a moment arises when the flow structure becomes unstable. in such a way as to reduce the resistance to the incoming flow.The resistance coefficient decreases by two or more times. A similar pattern occurs when the water or air flow moves over the bulk medium, which is built in three-dimensional structures, providing e is the minimum resistance for given Reynolds numbers. B. Shulyak [3] provides spectacular photographs of periodic wave structures when, in addition to the main periodicity along the flow, there is another transverse periodicity. The main feature of this periodicity is the phase matching of the modulation heights of adjacent deformation rows: maxima elevation heights in the ith row are located against the minima of the neighboring i ± 1 rows, therefore a checkerboard structure is created in the periodic system. Such a coordination of the phases of the transverse modulation of waves of the surface of a granular medium is the result of the action of spatial hydrodynamic forces arising between the individual elements of these elevations.

The resulting structures are easily approximated by a system of spherical holes. At the same time, the depth of the hole is much less than its diameter / 5-6 times /. The above facts suggest that the incident flow resistance, at Reynolds numbers characteristic of the formation of such structures, Re ≅ 10 ³ -10 ⁵ , from the side of the correspondingly corrugated surface will be significantly less than over a smooth one, however, heat and mass transfer are intensified . The fact that flow resistance is reduced when forming surfaces with spherical holes is used in the manufacture of golf balls. The dependence on the Reynolds number of the drag coefficient of a smooth ball and golf balls is shown in Fig. 1 [4] (Fig. 1 is a graph of the resistance coefficient (C _D ) versus the Reynolds number (Re). 1 - for a golf ball , 2 - for a rough ball, 3 - for a smooth ball; Fig. 2 - a golf ball with holes). The section on the curve for the ball with holes is noteworthy, which indicates flow processes that differ significantly from the flow of ordinary rough surfaces. In experiments with holes of small diameters conducted by G.A. Kiknadze et al. [5], a complex flow pattern was discovered during flow around wells with different Reynolds numbers. The formation of laminar vortex structures was observed at lower Re numbers, which turned into self-oscillating coherent structures at high Re numbers. We observed similar phenomena with vortex coherent structures. Note that a surface grooved by spherical holes with a large ratio of the diameter of the hole to its depth will be smooth enough to be easy to clean, and does not contain protrusions beyond which the dust substrate can collect. The appearance of vortex structures above the wells of the heat exchanger will naturally intensify heat transfer several times and thus will not lead to a decrease in the efficiency of the device. Figure 3 shows the location of the holes on the coil and shows how flattened vertically arranged coil tubes relative to the flow of incoming air. Figure 5 shows fragments of the pipes of the condenser coil, which depict spherical holes, the arrows show the main air flow. The coil tubes are flattened in a direction perpendicular to the air flow. Figure 4 shows a diagram of streamlines formed in a stream of moist air above the holes (1). The horseshoe-shaped vortices (2) form a coherent structure, which reduces the resistance to the main flow (3) and provides an increase in heat and mass transfer between the air flow and the condenser wall (4). Vortex tubes provide an increase in heat and mass transfer between the main stream and the wall. It is easy to see that the areas shaded from the main flow between the tubes turn out to be inoperative and therefore it is desirable that the tubes be flattened perpendicular to this flow.

 Vertical placement of the condenser tubes contributes to a more intensive drainage of condensed moisture. Note that the use of copper or aluminum as a material for the manufacture of a capacitor is unacceptable, because condensed moisture will be enriched with these elements and will make it unacceptable to use the resulting water as drinking water.

 In FIG. Figure 5 shows a diagram of an installation for moisture condensation, where conditions are created that do not contribute to the formation of places with a substrate on which microorganisms can multiply. It contains a stainless steel sump (1); stainless steel grooved moisture condenser (2); refrigeration system (3); ventilation system (4); air duct (5) and solar panels (6). 5 also shows the flow of moist air (7) and the flow of dried air (8). Condensation heat is removed both due to the refrigeration system, and due to the forced movement of air created by the fan.

 The sump 1 is made of stainless steel and is a bath in which moisture flows from the condenser.

 The moisture condenser 2 is a stainless steel tube bent into a coil corrugated by spherical dimples, which leads to the formation of a coherent structure in the incoming flow, as a result of which, on the one hand, the resistance to the incoming flow is reduced, which reduces the energy consumption of the ventilation system and increases the heat exchange between the refrigeration system and an incoming flow of moist air, and on the other hand, the condenser coil tube is quite smooth, which prevents the accumulation of substrate on its surface and facilitates cleaning during routine maintenance. The straight sections of the coil pipes are arranged vertically, which contributes to a more intensive process of draining condensed moisture and prevents the dust substrate from settling on the surface of the condenser. The condenser tubes are flattened in a direction perpendicular to the main incoming air flow to reduce the area of inefficiently operating sections of the condenser tubes. The refrigerator 3 provides a decrease in the surface temperature of the moisture condenser below the dew point, and the ventilation system 4 - the supply of new portions of moist air.

 The device operates as follows: the refrigeration system 3 reduces the temperature of the moisture condenser 2 below the dew point, through which air is pumped by the fan. Between the holes, corrugated on the surface of the moisture condenser coil, vortex coherent structures arise, the formation of which leads to a decrease in the drag of the condenser coil and increases heat transfer between the wall of the condenser and the incoming flow of moist air. Moisture condensed on the surface of the condenser flows through vertically arranged coil tubes into the water collector. The absence of junction angles on the condenser prevents the accumulation of dust on its surface and allows it to be cleaned, as a result, the water received on this device is biologically pure.

Literature:
1. Patent of Russia 2056479, cl. C1 / prototype /.

 2. Application of Germany 3313711, CL E 03 B 3/28.

 3. B. A. Shulyak. Physics of waves on the surface of a granular medium and liquid. M .: Nauka, 1971.

 4. Bearman P. W., Harvey J.K. Golf ball aerodynamics. Aeronaut, 1976, vol. Q27, pp. 112-122.

 5. Kiknadze G.I., Krasnov Yu.K., Podymako V.F., Khabensky V.B. Self-organization of vortex structures when a hemispherical hole flows around water. DAN USSR, 1986, v.291, pp. 17-20.

Claims (1)

 Installation for producing biologically pure fresh water when condensing moisture from atmospheric air, containing solar panels, a refrigeration system, a water collector, an air duct, a ventilation system and a condenser, characterized in that a tube made of stainless steel is introduced into the coil as a condenser, onto the outer side of which spherical holes are extruded, and the straight sections of which are located vertically and flattened in a direction perpendicular to the air flow.

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