SU859312A1 - Heliodistiller - Google Patents

Description

(54) GEL SUPPRESSOR

I

The invention relates to a technique for the distillation of salt water by the method of distillation using solar energy by converting it to heat due to the greenhouse effect, and more specifically to small-sized, portable and personalized desalination plants for autonomous replenishment of

. Stock fresh stock.

Floating portable gelophoresites are known, consisting of a flexible solar permeable shell, for example, of thin film synthetic material and placed under a black (well absorbing solar radiation) hygroscopic evaporative sheet with a forced system to feed it with desalinated salt water. In such solar presses, the envelope is inflated with iQ air or is pulled over an inflatable frame t2J.

The common disadvantages of these portables. helium desalinators are the uneven wetting of the surface of the evaporating element and the unreliability of the apparatus as a whole. Various system improvements, make-ups do not identify this drawback.

Also known inflatable floating

THAT helium desalinator with natural capillary feed of the evaporator, comprising a case made in the form of a shell of optically transparent film forming inclined walls dp of a distillate, placed in the case of an evaporation element made of a hygroscopic material with its wicks, a collection of fresh water and a ballast tank to resist it afloat. In this solar dummy, the inflatable casing also maintains s in working position due to the overpressure of the air Sz3385

; The disadvantage of this solar thermal plant is that the evaporation element becomes saline over time, which leads to a decrease in its capillary characteristics, i.e. at the same time, the moisture content required for its Normal operation is not provided, and the limited capillary potential and, thus, the height of the liquid in the wick, makes it necessary to position the evaporator element close to the water mirror. In the absence of a reliable heat shield between the bottom and the evaporator, this leads to an increase in the heat loss of the latter and a decrease in its temperature, which reduces the productivity and service life of the solar helium-presses -.

The purpose of the invention is to increase the efficiency and service life of the solar pressure sensor.

This goal is achieved by the fact that in a heliopressor containing a body made in the form of a shell of transparent film forming inclined walls, an evaporation element made of a hygroscopic material placed in the body with powering wicks and heat insulation, a collection of fresh water and a ballast capacity are heat Insulation of each evaporating element is made in the form of hermetic vacuum-evacuated packages of perforated polymer films with a shielding coating. In addition, in order to observe the eclipse of the periodic rotation of the evaporating elements through 180 °, the latter are attached to the body by means of a flexible fastener.

FIG. 1 shows the proposed solar desalination unit; in fig. 2 view A in FIG. one; in fig. 3 - a separate section of the evaporating element with wicks and a screen-vacuum thermal insulation package.

The solar thermal cleaner contains a shell-shaped case 1 made of a transparent film of the evaporator element 2 with wicks 3, made symmetrically with respect to the horizontal plane and insulated with screen-vacuum thermal insulation packages 4, stretched by means of nylon filaments on an inflatable frame made of a ring 5 and stand 6 , a valve 7 for venting non-condensable gases, mounted on the shell 1, tensioned in the working

,four

Placement on an inflatable ring 8 and a 9 liter of distillate collection and a 10 liter pipe of 10 l of distillate in a collection of 11 fresh water supplied at the bottom of the gutter. The tube 12 serves to attach to the stand 6 of the collector 11 and drain (suck) fresh water from it, and the hygroscopic bundle 13 ensures uninterrupted flow of water through the tube 10 to the collector 11. The rings 5 and 8 are interconnected by means of a flexible fastener 14, for example type of plastic zipper.

The evaporating element 2 in the form of separate sections is made of absorbing good absorbing solar energy, for example, from black thin flannel. Each section consists of an evaporator web passing into the wicks 3 (side walls) and the bottom connected along the seam 15 and provided with a sealed package of screen-vacuum thermal insulation, which is a reliable heat radiation screen of the evaporator element 2 and consists of several layers of mirror For example, with aluminum fusing of thin corrugated polymeric films with perforations, sealed along the edges and well evacuated. The individual sections are stitched together to form the even lower and upper surfaces of the evaporation element.

The elastic shell 1 is made of a solar wettable, transparent for solar radiation, synthetic strip, e.g., polyester alcohol treated with polyvinyl alcohol to improve wettability. Both ends of the central inflatable rack 6 are equipped with fittings 16 with plugs. A rack 6, having a membrane 17 in the center with a hole through which ballast water 18 is poured, is connected through pipe 19 to ring 5. A nipple 20 is provided on ring 8. Helicopter fits into the rescue raft 21. Since all the main elements of the proposed desalination plant are made from flexible thin materials, it achieves its good compactness and small dimensions in the folded for transportation position.

Claims (3)

To bring the solar analyzer to working condition in the rack 6, through the fittings 16, ballast salt 18 is poured and the whole frame through fittings 16 and the nipple 20 is inflated with air. The valve 7 for venting the non-condensing gas (air) is open. Saline intake water washing the bottom of the desalination plant under the action of the capillary potential of the wick 3 constantly feeds the evaporation element 2, where it is heated due to the heat of solar radiation passed through the shell absorbed by element 2 and evaporation. Inside the solar pressure tank, an overpressure is created due to an increase in the partial pressure of water vapor, and the vapor-air mixture through the valve 7 is released. After 30 minutes after the desalination plant starts operation, the valve 7 is closed. This time is enough to release more than 50% of the air from the volume of the solar pressure detector. Water vapor condenses on the inclined walls of the shell 1, cooled by outside air, and flows into the chute and through the tube 10 - into the collector 11. Over time, the surface of the evaporation element 2 is salinated. To remove the precipitated salt, the shell 1 is removed by ring 8, the evaporator assembly is inverted so that the surface of the evaporation element 2 is B1 and washed with seawater. Fresh water collection 1 is fixed on the lower part of the stand 6 on which shell 1 is put on and fastener 14 is closed. Thus, good thermal insulation of the working surface of the evaporation element 2 makes it possible to increase the evaporation rate by reducing the heat loss of the evaporator and increasing its temperature, which generally increases the performance of the proposed heliopressor compared to the known by 40%. In addition, the possibility of repeated cleaning, i.e. desalting the surface of the evaporation element allows to improve the desalination capacity by restoring the wicks capillary potential and uniformly moistening the surface of the evaporation element and increasing its service life. The use of rack 6 as a ballast device to improve the stability of the desalination plant and immerse freshwater collection 11 in water significantly reduces its weight and size, since there is no need for metal weights. Claim 1. Helicopter freshener, comprising a case, executed in the form of a shell. From a transparent film forming inclined walls, an evaporating element made of a hygroscopic material placed in the case, with powering fuses and thermal insulation, a collection of fresh water and a ballast tank differing in teM, that, in order to increase its efficiency and service life by providing alternate work on evaporation surfaces and wicks, the heat insulation of the evaporating element is designed as airtight coated packages of perforated polymer films with a shielding coating. 2. The solarium desalinator according to claim 1, namely, in order to periodically rotate the evaporation elements by 180, the evaporation elements are attached to the body by means of a flexible fastener. Sources of information taken into account in the examination 1. US Patent No. 2455835, cl. 292-34, 1948. 2. US patent 2397117, l. 292-234,1946. 3. US patent number 2412466, l. 2SG2-234, 1947. View/ (Puf, 3