RU109753U1 - SUNNY DESALER (OPTIONS) - Google Patents

Abstract

 1. Solar desalination plant, comprising an external translucent layer and subsequent layers of a heat-absorbing absorber and a heat insulator, water inlet and outlet pipes, characterized in that it is additionally equipped with a membrane unit for distillation of saline solution, which is placed between the layers of the absorber and heat insulator and is composed of a layer of microporous membrane, which on both sides is covered with a fixing mesh layer, and from a layer of a plate having a condensing surface, and all successive layers of desalination are hermetically attached s to each other at their edges. ! 2. Solar desalination plant according to claim 1, characterized in that the membrane unit for the distillation of saline solution is multi-stage and composed of layers of successive identical steps. ! 3. Solar desalination plant according to claim 1 or 2, characterized in that all successive layers are made flat. ! 4. Solar desalination plant according to claim 1 or 2, characterized in that all successive layers are cylindrical. ! 5. Solar desalination plant according to any one of claims 1 to 4, characterized in that the inlet pipe of the saline solution is installed between the outer translucent layer and the layer of the heat-absorbing absorber. ! 6. Solar desalination plant according to any one of claims 1 to 4, characterized in that the inlet pipe of the saline solution is installed between the layers of the heat-absorbing absorber and the distillation membrane unit. ! 7. Solar desalination plant according to any one of claims 1 to 4, characterized in that the outer translucent layer is made two-layer with a gap between the layers. ! 8. Solar desalination plant containing an external translucent layer and subsequent layers of a heat-absorbing absorber and heat insulator, �

Description

The proposed desalination plant relates to desalination devices for salt-containing water (salt solutions) with solar energy and can be used in coastal areas, in emergency situations - on ships, in the army, in hospitals, in isolation, as well as in individual farms.

Known solar desalination plants contain an external translucent layer and layers of a heat-absorbing absorber and heat insulator. Their work in most cases is based on the principles of the greenhouse effect and distillation (Solar water desalination plants - one of the ways to supply drinking water to people in remote regions http://energy.econews.uz, April 24, 2009).

Closest to the proposed is a desalination plant, comprising a housing, a translucent layer mounted on the housing and layers of an absorber and heat insulator placed in the housing, as well as water inlet and outlet pipes (RU 2142913, C02F 1 / 14.1999).

The work of the famous desalination plant is based on the principles of the greenhouse effect and distillation and has all the drawbacks inherent in this type of device: inefficient use of solar energy (efficiency 0.3-0.4), large net weight and volume.

The inefficient use of solar energy is caused by large losses of thermal energy: reflection from the surface of the translucent layer, from the surface and from the bottom of the saline solution, from the surface of the condensed droplets of the distillate, loss of the latent heat of vaporization during condensation, losses from the secondary evaporation of condensed drops, heat losses from the surfaces of the casing. Due to these losses, the known desalination plant has a low specific productivity J _0S (the amount of distillate per unit of work surface per day), which is 2.5-3 l / m ² per day.

Taking into account that the well-known desalination plant can be made in different sizes and have different intrinsic weight and volume, it is advisable to use such comparisons as specific mass productivity J _0M (amount of distillate per unit of intrinsic weight per day) during comparisons. This characteristic is especially low in the well-known multi-stage tower structures (RU 2080141, B01D 1/28, 1997), which indicates their poor transportability. It should also be noted the complexity of the design of the well-known desalination plant, especially its multi-stage tower design - the presence of control devices, pumps, a separate water heater, etc.

The technical result of the proposed technical solution is to increase the efficiency desalination plant and its specific productivity.

In this application, the utility model is presented in two versions.

According to the first embodiment, the essence of the technical solution lies in the fact that the desalination unit, comprising an external translucent layer and subsequent layers of a heat-absorbing absorber and heat insulator, water inlet and outlet pipes, according to the invention, is additionally equipped with a membrane unit for the distillation of saline solution, which is located between the layers of the absorber and heat insulator and composed of a layer of microporous membrane, which is coated on both sides with a fixing mesh layer, and of a layer of a plate having a condensing surface, all successive desalination layers are hermetically attached to each other by their edges.

The essence of the technical solution according to the first embodiment also consists in the fact that the membrane unit for the distillation of saline solution is multi-stage and is composed of layers of successive identical steps.

According to the second embodiment, the essence of the technical solution consists in the fact that the desalination plant, comprising an external translucent layer and subsequent layers of a heat-absorbing absorber and heat insulator, water inlet and outlet pipes, according to the invention, is additionally equipped with a membrane unit for the distillation of saline solution and a water heating chamber, which are successively installed between the layers absorber and heat insulator, the membrane unit is composed of a layer of microporous membrane, which is coated on both sides with a fixing mesh layer m, and a layer of a plate having a condensing surface, wherein all successive layers distiller sealingly attached to each other with their kryami and the upper and lower parts of the water-heating chamber are connected with the nozzles of hot water system.

The essence of the technical solution, both in the first and in the second options, also includes the ability to make all successive layers flat or cylindrical, the ability to install the inlet of the saline solution between the outer translucent layer and the layer of the heat-absorbing absorber, or between the layers of the heat-absorbing absorber and the distillation membrane unit, and also the ability to perform an external translucent layer two-layer.

The essence of the utility model is illustrated by schematic drawings.

Figure 1 shows a General view of the desalination plant with flat layers.

Figure 2 shows a General view of the structure of a set of desalination plants with cylindrical layers.

Figure 3 shows a section of the desalination plant with the location of the inlet pipe between the outer translucent layer and the absorber layer.

Figure 4 shows a section of the desalination plant with the location of the inlet pipe between the absorber and the membrane unit.

Figure 5 shows a section of a desalination plant with a two-layer translucent layer.

Figure 6 shows a section of a desalination plant with a multi-stage membrane unit.

Figure 7 shows a section of a desalination plant with flat layers and a water heating chamber.

On Fig shows a section of a desalination plant with cylindrical layers.

Figure 9 shows a section of a desalination plant with cylindrical layers and with a water heating chamber.

The proposed solar desalination plant has a layered structure and contains successively an external translucent layer 1, a layer of heat-absorbing absorber 2, a membrane unit for the distillation of saline solution and a layer of heat insulator 3. There is a gap 4 between the translucent layer 1 and the absorber layer 4. A membrane node is located between the absorber and heat insulator layers and contains a layer of microporous membrane 5, which is coated on both sides with a fixing mesh layer 6, and a layer of a plate 7 having a condensing surface. All successive desalination layers are sealed to each other by their edges, for example, using silicone sealant 8. The desalination unit also includes an inlet pipe 9 of saline solution, an outlet pipe 10 of the concentrate and an outlet pipe 11 of the distillate.

According to the first embodiment of the desalination plant, the membrane unit can be made either single-stage (Figs. 3, 4, 5) or multi-stage (Fig. 6).

In versions with a multi-stage membrane unit, the steps are sequential, their layers are the same and each step is equipped with its own nozzles 9, 10 and 11. The number of steps is preferably 3-4, as our studies have shown, a greater number of them are ineffective.

According to the second variant, the desalination plant is also equipped with a water heating chamber 12, installed next to the membrane unit. The lower and upper parts of the chamber 12 with pipes 13 and 14 are connected to the hot water supply system.

All successive desalination layers can be made both flat and cylindrical. Such versions of the first embodiment are shown in FIGS. 4 and 8, respectively, and in the second embodiment in FIGS. 7 and 9. When desalination layers are flat, it is a flat bag. During operation, it is oriented at an angle to the horizon at the corresponding geographical latitude of the area so that the sun's rays fall perpendicular to the desalination plane (Fig. 1). When desalination layers are cylindrical, it is a cylindrical rod, and for its operation it is advisable to manufacture the device in the form of a set of rods covered by a frame, as shown in Fig. 2, and the rods in the set can be installed close to each other or with a gap between them.

The inlet pipe 9 of the saline solution can be installed between the outer translucent layer 1 and the absorber layer 2. In this embodiment, the absorber has an inlet 15 and 16 outlet for supplying the saline solution to the surface of the membrane 5. Another possible location for the pipe 9 is to place it between the layers the absorber 2 and the membrane 5. These versions of the first embodiment are shown in figure 3 and 4. The corresponding versions of the second variant have the same design. The drawings show only one of them (Fig.7).

The external translucent layer 1 of the desalination plant can be made two-layer, with a gap 17 between the layers. Such a performance equally applies to both the first embodiment and the second. The drawings show only one of them (figure 5).

The outer translucent layer 1 can be glass or from any other translucent material, such as organic glass, various films, etc.

The absorber 2 is made of a material with a high coefficient of heat absorption. It can be made in the form of a metal plate (steel, copper, aluminum, etc.) or foil, which is blackened with paint or electrochemical method.

The membrane 5 is a microporous film of a hydrophobic material. This, for example, polytetrafluoroethylene (PTFE), polypropylene (PP), polyvinylidene fluoride (PVDF), which have an average hole diameter of 0.15-0.6 microns.

As the fixing layer 6, a mesh of polyethylene, lavsan, kapron and other fibers with a fiber diameter of about 0.2 mm, mesh mesh sizes of about 1 mm × 1 mm and heat resistance of 80-150 ° C can be used.

Plate 7 with the function of condensing water vapor is made in the form of a metal foil - aluminum or other metal with high thermal conductivity.

Desalination works as follows.

In the embodiment shown in Fig. 3, the saline solution fills both the gap 4 and the gap between the absorber 2 and the membrane 5, since they communicate through the openings 15 and 16. When heated from sunlight, the absorber evaporates water, a pressure difference is created across both sides of the membrane, which contributes to the diffusion passage of vapors through the pores of the membrane. After passing through the pores of the membrane, water vapor condenses on the surface of the layer 7. The obtained distillate flows through the pipe 11. A feature of this embodiment is that it excludes the possibility of condensation of water vapor on the inner surface of the translucent layer 1, and hence the associated loss of thermal energy .

The same distillation process with the effect of reducing heat energy losses occurs in the execution forms shown in FIGS. 4 and 8, where the gap 4 is sealed, and also in FIG. 5, where the translucent layer is made two-layer.

The principle of operation of the multi-stage form of execution shown in Fig.6 is as follows. During condensation of water vapor in the first stage of the membrane unit, latent heat of vaporization is released, which, passing to layer 7, heats it. Thus, the condensing layer 7 of the previous stage serves as a source of thermal energy for the next stage, that is, there is a process of energy recovery.

In the second embodiment of the utility model, which relates to forms of execution with a water heating chamber, the latent heat of vaporization released in the membrane distillation unit is transferred to the chamber 12 for recovery.

Both execution forms with flat layers and execution forms with cylindrical layers work on the same principle.

Compared with well-known desalination plants, the proposed utility model provides the following advantages.

The design has a small lateral surface, due to which the loss of thermal energy through the lateral surface is minimized.

All gaps in which heating of the brine takes place are filled with the solution and the mass transfer is directed downward. Due to this, the desalination plant can be oriented at any desired angle to the horizon.

Due to the small distance between the layers, the mass transfer resistance is small, there is no phenomenon of secondary (re) evaporation of the distillate and the associated loss of thermal energy.

The small distance between the layers leads to a large surface mass transfer per unit volume.

The low own weight of the desalination plant ensures its portability and accessibility.

Eliminated the need for auxiliary devices: pumps, control units and other consumers of electricity.

The specific productivity is increased, both in relation to the unit of the working surface, and in relation to the unit of its own mass.

Claims (13)

1. Solar desalination plant, comprising an external translucent layer and subsequent layers of a heat-absorbing absorber and a heat insulator, water inlet and outlet pipes, characterized in that it is additionally equipped with a membrane unit for distillation of saline solution, which is placed between the layers of the absorber and heat insulator and is composed of a layer of microporous membrane, which on both sides is covered with a fixing mesh layer, and from a layer of a plate having a condensing surface, and all successive layers of desalination are hermetically attached s to each other at their edges. 2. Solar desalination plant according to claim 1, characterized in that the membrane unit for the distillation of saline solution is multi-stage and composed of layers of successive identical steps. 3. Solar desalination plant according to claim 1 or 2, characterized in that all successive layers are made flat. 4. Solar desalination plant according to claim 1 or 2, characterized in that all successive layers are cylindrical. 5. Solar desalination plant according to any one of claims 1 to 4, characterized in that the inlet pipe of the saline solution is installed between the outer translucent layer and the layer of the heat-absorbing absorber. 6. Solar desalination plant according to any one of claims 1 to 4, characterized in that the inlet pipe of the saline solution is installed between the layers of the heat-absorbing absorber and the distillation membrane unit. 7. Solar desalination plant according to any one of claims 1 to 4, characterized in that the outer translucent layer is made two-layer with a gap between the layers. 8. Solar desalination plant, comprising an external translucent layer and subsequent layers of a heat-absorbing absorber and a heat insulator, water inlet and outlet nozzles, characterized in that it is additionally equipped with a membrane unit for the distillation of saline solution and a water heating chamber, which are sequentially installed between the layers of the absorber and the heat insulator, a membrane unit composed of a layer of microporous membrane, which is coated on both sides with a fixing mesh layer, and of a layer of a plate having a condensing surface, than all the successive layers distiller sealingly attached to each other with their kryami, and the upper and lower parts of the water-heating chamber are connected with the nozzles of hot water system. 9. Solar desalination plant according to claim 8, characterized in that all successive layers are made flat. 10. Solar desalination plant according to claim 8, characterized in that all successive layers are cylindrical. 11. Solar desalination plant according to any one of claims 8 to 10, characterized in that the inlet pipe of the saline solution is installed between the outer translucent layer and the layer of the heat-absorbing absorber. 12. Solar desalination plant according to any one of claims 8 to 10, characterized in that the inlet of the saline solution is installed between the layers of the heat-absorbing absorber and the distillation membrane unit. 13. Solar desalination plant according to any one of paragraphs.8-10, characterized in that the outer translucent layer is made two-layer with a gap between the layers.