DE3541645A1 - Device for obtaining water from air using the Peltier effect - Google Patents

Abstract

In order to obtain water from air, a device is proposed which is based on a thermoelectric process. It is characterised by the use of the Peltier effect. The device can be connected both to existing power distribution systems and to autonomous power generating and power storage systems. In conjunction with buildings/hot houses, the device permits the creation of a microclimate.

Description

In addition to the sea, the air around us contains the most moisture. In many regions of the world, the water supply does not match that Water requirement. Think z. B. the drought regions like that Sahel region in Africa, the drought periods of more than 7 years must survive on average.

The transport of water to such regions is often over impossible or uneconomical for political reasons. At the same time however, a huge transport system is currently hardly used: the atmosphere. The wind continuously transports moisture-rich air in these areas.

Studies have shown that even in the dry regions the earth's air still contains enough moisture to provide a water supply ensure at least for emergencies. That's how it was Wadi Halfa in North Africa z. B. a relative in the morning of January Humidity of 51% (highest annual value) and a relative in June Moisture of 22% (lowest value) - d. H. contains one cubic meter of air in January at a temperature of 40 ° C approx. 28 g water and in June 13 g at the same temperature.

At the same time, however, it should be noted that in the areas in need the technical staff is scarce; complicated facilities of the Water extraction would have little chance of being used. It is coming The following requirements therefore depend on providing a system enough:

- Operation of the system must also be possible independently; so without Can be connected to an existing power distribution system the system must be able to be operated

- The system power supply must come from locally available sources to be possible

- The device should work with as little wear as possible - d. H. Use of proven assemblies, minimization of rotating components

- The device should be easy to install, operate and to to be waiting

- The system should be inexpensive to purchase and operate

- The system should be expandable as desired, and since it is in the drought areas are also often crisis areas

- The system can also be easily camouflaged in an emergency.  

The extraction of water from wells has been the norm since time immemorial Technology. This process is economical where there is sufficient water Dimensions exist in the ground, be it through natural catch basins or underground rivers / currents. The use of the Procedure when test drilling has to be carried out, or the Soil storage capacity is so low that a in emergency times secure supply is no longer guaranteed.

The extraction of water from the sea is also a tried and tested one Technology. Many of these plants are based on the distillation principle. The water is heated until it rises in the form of steam. The foreign substances z. B. Salt remain. The steam condenses on Heat exchanger, and the condensed water flows into a storage tank. This process can be repeated several times - multi-stage evaporation distillation.

Such a method can work with the help of solar energy. So For example, the following system is implemented on the island of Patmos: A Storage / basin is filled with sea water by pumps. Above everyone The store has a double, sloping glass roof. The heat of the sun penetrates through the glass and calls one on the surface of the water Evaporation. The water vapor condenses on the inside of the glass Water runs to the gutters on the edges of the closed glass boxes and from there to the fresh water storage.

Furthermore, the principle of reverse osmosis is used for water extraction used. Sea water is through a semi-permeable membrane headed. This membrane allows fresh water to pass through, but not salt.

The invention of Mr. Lutz Zacherl is probably the closest to the invention come. His system uses the Carnot cycle (Refrigerator principle). For this he needs a compressor, a condenser Control valve and an evaporator. In contrast to the submitted In addition to the use of the Carnot principle, the invention is the system technically complicated and only under constant supervision of specialist personnel to operate, and the devices (compressors) necessary for air cooling work mainly on the mechanical way. The compressor has many moving parts. Especially in areas with fine-grained sand the danger that the above system would close too quickly.  

The function of the submitted invention is as follows:

Air can absorb more moisture, the higher its temperature is (Mollier diagram). This moisture is not visible until how the air is not saturated. The air only comes out when it cools down in the saturation state. The water vapor condenses on crystallization nuclei - fog is formed. With further cooling, the air is not more able to hold the moisture. The moisture strikes settled in the form of water. This is an effect in air conditioning systems Waste product. However, this waste product is in the present invention the main product. The air conditioners use the compression principle and the absorption principle - Carnot cycle processes in each case.

The present invention is based on the principle of thermoelectric cooling. This process is based on an effect discovered by Peltier in 1834: in a circle made up of two different conductors, heating occurs at one point when a voltage is applied, while cooling occurs at the other end. The arrangement of the Peltier element consists of two legs made of doped semiconductor material as well as a contact bridge on the cold side of the two legs and a contact bridge on the warm side of the two legs ( Fig. 1, 2). The amount of heat absorbed or emitted is proportional to the current and depends on the substances used in the thermocouple.

The cold side of the Peltier element ( 1 ), the warm side 2 , the electron flow 3 , the defect electron flow ( 4 ) and the direction of the current flowing through ( 5 ) can be seen in Figure 1.

Figure 2 shows a Peltier cooling block in its entirety. ( 6 ) and ( 7 ) are the legs made of doped semiconductor material. ( 8 ) are the cold contact bridges and ( 9 ) the warm contact bridges.

The advantage of this method is that there is no cooling rotating parts are required. Only with the air supply and when the water cycle moves, there are mechanically rotating parts in the form of a fan or a circulation pump.

If the energy is not available at the water extraction site, so it is with self-sufficient systems such. B. generated a solar system. Solar energy is likely to be abundant in drought areas. Since it can be useful to determine the time of energy production to separate that from water production, energy storage may be included appropriate control equipment required. So it can e.g. B. quite make sense, the time of water extraction in the evening, Relocate at night or early in the morning since in this Time the temperature level of the air is closer to the dew point. At the same time, this procedure also requires the use of water storage with appropriate treatment plants; because to compensate of the water balance must be water at the time of the habitat to which the evaporation is greatest (e.g. in the Noon hours).

If a microclimate cannot be generated by existing ones Building to which the water is supplied through supply networks it may make sense to use such a water extraction system with a Connect greenhouse. In the greenhouse there can be a natural one Form a cycle. The water supplied to the greenhouse evaporates - it hits the top of the cover / roof, runs off and is returned to the habitat. A combination of the Water extraction principle according to the invention and the principle of evaporation leads to reduced water consumption. It only needs the amounts of water are supplied, which can escape z. B. by that Enter the greenhouse by bringing out water-containing Fruits, through leakage losses etc.

An example of a possible overall system is described in Figure 3.

Figure 3 shows how the warm air ( 11 ) enters the system via a curved intake pipe ( 10 ). B. is introduced in the form of a greenhouse ( 13 ). This can be done either via a fan ( 14 ), which is infinitely variable and draws in more or less air depending on the temperature and humidity, or indirectly via an air exhaust pipe ( 15 ) of a few meters height by utilizing the natural pressure difference (chimney effect). It is provided that a closure mechanism ( 16 ) and a filter ( 17 ) are mounted in the intake duct in order to protect the system. A sand collecting basin ( 18 ) below the intake manifold can also be useful. The natural dust particles can be deposited there. It can also be provided that the suction line ( 19 ) is fed to the system below the surface of the earth. The air can already be pre-cooled by the colder layers of earth. This effect can possibly be enhanced by cooling fins ( 20 ). Alternatively, it is provided for the pre-cooling of the sucked-in air that it is sucked in in the counterflow principle. DH the suction pipe is directly connected to the exhaust pipe by a heat exchanger. The air that has already been cooled in the exhaust air line will then lead to a lowering of the temperature of the supplied air before the sucked-in air is fed to the Peltier cooling blocks.

Furthermore, it is provided that the suction pipe is inclined towards the greenhouse in order to allow the condensate already formed in the pre-cooling phase to drain into the water collecting container ( 21 ).

The air then flows through the individual Peltier cooling blocks ( 22 ) in a meandering manner in a channel which is open at the bottom. The air is gradually cooled, reaches the condensation point and the water drips into the gutter ( 23 ). From there it runs into the water collecting tank ( 21 ). The water is supplied to the ground either via special irrigation pipes or by using the capillary effect. If necessary. irrigation pumps can be useful.

The water supply to the entire system is thus carried out
a) via the Peltier elements
b) by the microclimate created in the greenhouse.

The evaporated water, as can be seen in Figure 4, is deposited on the roof and either runs down into the gutter ( 23 ) or drips from the roof. In addition, it is provided that the roof consists of reflective foils or is provided with darkening units ( 25 ). This can prevent the build-up of heat and thus the risk of burning the plants.

The warm contact bridge of the Peltier elements, connected to cooling fins ( 26 ), is located outside the greenhouse. The cold side of the Peltier elements ( 27 ), connected to the cooling fins, is in the greenhouse.

With the appropriate size, pre-cooling may be necessary be dispensed with, the warm air is thus directly the Peltier elements supplied.

The block diagram of the overall system is shown in Figure 5. It is envisaged that the entire system will be supplied with energy primarily via solar cells ( 28 ). These are connected to an energy store ( 29 ) via a control and setting unit ( 31 ). This makes it possible to separate the phases of energy production from the phases of water production. Alternatively, it is provided that the entire system is additionally or exclusively supplied by an external energy supply ( 30 ).

The control and actuating unit ( 31 ) is connected ( 32 ) to numerous sensors. This includes sensors for measuring the outside temperature, the inside temperature, the humidity, the wind speed etc.

The control and adjustment unit is connected to the air intake ( 33 ), the Peltier elements ( 34 ), the irrigation system ( 35 ) and the darkening ( 36 ).

This presented system is at a relatively low cost can be placed anywhere in the world. It can work independently.

As an overall system it can also be provided that only partial elements of the system shown above. This is useful, for example, as part of a mobile Water supply. In extreme cases, the system could be a compact unit with the components solar cells, energy storage, Control and actuating unit, Peltier element and water collecting tank to be built so compactly that it becomes portable  Suitcase fits.

The invention is not intended to be based on the exemplary embodiments be limited, but is within the scope of the revelation often variable. All new in the description or Drawing revealed individual and combination features are considered essential to the invention.

Claims (8)

1. Device for extracting water from air with the help of electrothermal refrigeration, characterized by the use of Peltier elements coupled with energy supply systems. 2. Device according to claim 1, characterized in that as Energy supply system also use independent systems can come z. B. in the form of a solar system coupled with suitable energy storage and control devices. 3. Apparatus according to claim 1 and 2, characterized in that Facilities are available that allow the time of the Energy generation independent of that of water extraction from air do. 4. Apparatus according to claims 1-3, characterized in that water storage are integrated in the system at the time of water extraction regardless of the time of water consumption. 5. Apparatus according to claim 1-4, characterized in that the Water supply is coupled to water treatment systems to obtain a water quality that meets the requirements. 6. The device according to claim 1-5, characterized in that the System is coupled with pre-cooling units, e.g. B. by in the layer of earth installed heat exchanger to take advantage of natural "cold" the earth. 7. The device according to claim 1-6, characterized in that the Water harvesting system is coupled with greenhouses that enable the establishment of a microclimate and thus the establishment a natural water cycle. 8. The device according to claim 1-7, characterized in that the Climate in the greenhouses is adjustable to the optimum Growth and well-being of people, animals and plants.