DE3830647A1 - Water recovery from natural air humidity for cultivating plants, breeding animals and for human needs - Google Patents

Abstract

In areas of high air humidity and high insolation with a simultaneous lack of a natural occurrence of water, the intention is to recover water, by means of suitable devices, from the air with small or large, mainly self-sufficient systems. These are distinguished in that the required temperature differences are achieved in most cases by direct or indirect utilisation of the insolation and/or of the radiation towards the night sky. The outlay for assisting the natural air movement and for other drives and controls such as may be required is comparatively low. Provision of additional cover by photovoltaics is possible in all cases.

Description

Basic idea

In areas of high humidity and high solar radiation simultaneous lack of natural water resources is said to be due to suitable Facilities water can be extracted from the air.

Applications

Areas to which the above Conditions apply, e.g. B. the Coastline around the Persian Gulf. Here water is common won in large seawater desalination plants, which for Plant breeding is too expensive. A failure of these systems, e.g. B. by Power supply interruption, malfunctions, oil contamination of sea water or other circumstances leads directly to Lack of water.

As an alternative to the systems mentioned, water in self-sufficient, occasionally also mobile facilities - independent of sea water and its immediate vicinity - in small and large quantities for the Plant breeding and human needs can be obtained.

conditions

• - Supply of plant and animal breeding facilities
• - Care of individual households in emergencies and normal cases
• - High reliability
• - Ease of use
• - Low maintenance
• - Cost / benefit equivalence

Examples of some possible design variants

These variants are based in particular on the utilization of the Day / night temperature gradient and the associated increase in relative humidity after sunset. In general, the Removal of moisture from the air mainly in the evening and Night hours happens. It can be both immediate Water separation take place as well as storage in absorbent media with expulsion delayed by many hours. Electrical energy is required as additional energy, from all conceivable suitable energy sources - also with Caching - can be obtained. In the For example, block diagrams is one as an energy source Solar energy system shown.  

Water extraction through condensation using Peltier elements

This variant is in block diagram 1 and in schematic diagram 1 shown schematically.

The humid air is ventilated on the cold side with the help of fans led by Peltier elements and cools below the dew point from. The moisture that condenses is collected. in the Block diagram 1 shows fans and Peltier elements for example powered by accumulators that are powered by solar generators during the day to be charged.

The aggregate shown in sketch 1 consists of the Peltier elements operated heat exchanger and the fans for Drifting through the humid air. It has few moving parts and is thereby low wear.

The disadvantage of this system is that the entire heat of condensation must be dissipated from the Peltier elements, which only one Have an efficiency of approx. 50%. This results in a relatively high one Power requirement. Furthermore, the Peltier elements require due to their Build a relatively expensive design of the heat exchanger.

Water extraction through condensation using compressors

Principle and structure correspond to the system with Peltier elements. However is the evaporator of a compressor instead of the Peltier elements Cooling unit installed. The heat of condensation is thereby Compressor discharged. The advantage of this variant is that the Compressor with a performance figure of two to three works, so that with the drive energy expended two to three times Amount of heat can be dissipated. Here too, if with much better efficiency than in the aforementioned version, the entire heat of condensation is provided as energy. The Number of wearing parts is due to the compressor naturally higher.

Condensation due to heat radiation against the night sky

Any surface on Earth that faces cryogenic space is at a higher temperature than this and therefore experiences one Heat loss due to radiation. During the day this heat loss covered by the much higher solar radiation. At night however, it is clearly noticeable. Dew z. B. opens first Car roofs.  

In this system, shown in schematic diagram 2, the described heat radiation used against the night sky.

An example is a trine with higher surfaces Emission constant executed, horizontally around a central axis is rotatably arranged. The surface at the top is directed towards the sky. To enlarge the Radiation surface are also flaps on the sides with highly emissive surfaces arranged at such an angle be made to reflect optimally on the trine. During the day and in wind, the flaps are folded over the trine and protect the emission surfaces from pollution, which Would result in reduction of the emission rate. In addition, this can Fold in during transport.

Due to radiation, the temperature of the radiation surfaces drops at night below the condensation point. On the flaps and up surface of the Trigon is reflected in the dew. Because this dew to a certain extent the radiation is reduced by a A third turn of the Trigon after a long time a fresh one Radiation area provided. From the then turned away The surface of the rope, in the same way as from the oblique installed flaps, drain into a collecting zone. This draining can possibly be supported by vibration. A corresponding However, the device is not shown in the sketch. Likewise is one Ventilation and humid air access support a use of the cold inner surface of the upward facing Trigon area conceivable.

The advantage of this system is that only the energy for the Turning the Trigon and operating the associated automatic timer, and possibly for the vibration system and the fans must be supplied. This is compared to the condensation energy comparatively very low. However, the radiation areas sensitive to pollution and injury.

Variant for condensation through heat radiation

Principle sketch 3 shows a variant of the aforementioned example. The geometric rotatable body is here by a radiation band replaced, which is stretched over two rollers. The tape comes with a Speed driven, which corresponds to the condensation rate. The Condensate is removed from the end of the belt by a device stripped and caught. The radiation area is also through Flaps enlarged against the tape when decommissioned Protect contamination. An automatic system can be used in both variants be cultivated, which closes the flaps in wind.

The energy requirement of this system is similar to that of the aforementioned Variant. Here too the preservation of the emissivity of the Radiation body important.  

Water extraction through adsorption

Moisture-adsorbing substances are relatively common in technology used. Areas of application are mentioned, for. B. drying of Process gases (compressed air, natural gas, etc.), keeping packaged dry Goods and dehumidification of organic fluids.

Bentonites (natural active clays) are suitable as adsorbers, Active aluminum oxide, silica gel and molecular sieves (natural and artificial zeolites). Moisture adsorption takes place through physical binding forces in the narrow cavities, of which the Adsorbents are crossed. Moisture absorption can be up to 40 Percentages by weight. The adsorbents themselves experience through the Water absorption no change and are chemically inert. The absorbed water can be expelled again through the action of heat will.

This process is reversible and is intended for water extraction from the Air can be used.

Principle sketch 4 shows a conceivable device for the posed Task. The pearl-shaped adsorber is located in a container with a flat cuboid shape. At the bottom of the container is a second room arranged about the same size. Both rooms are on connected to each other on a narrow side, on the contact surface however thermally insulated from each other. The rear container is trained inside and outside as a heat exchanger. The top of the Adsorber container is coated to absorb radiation well to achieve the highest possible temperatures in the desiccant during the day. This arrangement is oriented at an optimal angle to the sun, with the narrow side connected. At night after separation the connection to the back through a flap the damp Air is pushed through the adsorber with the help of fans. Here it releases its moisture to the adsorber and passes through the bottom open the lower flap again. In the daily cycle the upper air inlet and the lower narrow side are closed. The The adsorber container is now exposed to more than 100 by solar radiation Degrees Celsius warmed so that the adsorbed water is expelled becomes. These conditions require an adsorber, which is a has the highest possible water absorption in order to keep the construction volume small, and on the other hand has low binding forces to the water already to be released at temperatures that are not too high. Of the above Adsorbents are best suited to silica gel, which is also inexpensive is. The escaping water condenses in the back, cooler heat exchanger and is collected in a tank.

Because the energy for expelling the water is supplied by the sun only the power has to be provided for the fans. The construction can be done as an inexpensive sheet metal construction. The System has few moving parts. The high may be disadvantageous Weight and volume.

Claims (12)

1. Device for water extraction in areas without sufficient natural fresh water but high humidity, characterized in that the water is obtained from the natural humidity. 2. Device according to claim 1, characterized in that the Humidity is extracted in a condensation device, the Cold surfaces through Peltier elements, gas, adsorber or Compressor units are cooled. 3. Device according to claim 1, characterized in that the withdrawal the air humidity occurs at a condensing device, the Cold surfaces by radiation against colder rooms, e.g. B. against Night sky, be cooled, and that they condensed to drain Moisture is brought into a suitable position. 4. Device according to claim 1, characterized in that the withdrawal the air humidity occurs at a condensing device, the Cold surfaces by radiation against colder rooms, e.g. B. against Night sky, are cooled, and that they, after wetting through Condensation, to drain the moisture into a suitable, the colder rooms facing away. 5. Device according to claim 1, characterized in that the Withdrawal of air humidity in hygroscopic media / adsorbents happens, from which they are expelled again in a further step becomes. 6. Device according to claim 1 and 5, characterized in that it is combined with a device according to claim 2, 3 or 4. 7. Device according to claims 1-6, characterized in that the air flow through suitable facilities to support natural convection is supported. 8. Device according to claims 1-6, characterized in that the air flow through the device by fans, Blower or the like, is increased. 9. Device according to claim 1 u. 5, characterized in that the Expelling the stored moisture with solar heat happens. 10. Device according to claims 1-9, characterized in that the drainage of the condensate from the cold surfaces by stripping or mechanical impulses or vibrations or relaxation agents, also in combination of several measures. 11. Device according to claims 1-10, characterized in that the water obtained is sterilized by downstream facilities and if necessary taste is improved. 12. Device according to claims 1-11, characterized in that this is supplied directly or by stored solar energy be, e.g. B. by solar generators, with the aim of the above To be able to operate facilities independently.