DE19940992A1 - Water purification plant powered exclusively by solar energy employs coolant circuit evaporating e.g. salt water, without use of coolant compressor or coolant pumping - Google Patents

Abstract

Sea-, salt-, brackish-, river or lake water is evaporated by a solar energy heated- and operated coolant circuit, without use of a coolant compressor and/or without using a pump in the coolant circuit. Note: an explanatory diagram is included. Preferred features: The coolant circuit of the plant, for maintaining and/or operation of the coolant circuit process (Carnot process), and/or to increase the energy content of the coolant, and/or in this way to raise the evaporation temperature of the water to be evaporated, is equipped and operated with a pump. A number of similar variants based on these principles are described. Salient features include modular construction to vary plant capacity. The plant is containerized (shipping container), with pipework and connections, optionally quick-fastening. Various conventional solar collection equipment and plant items are listed. The coolant circuit recycles heat into the evaporator and/or partly or entirely evaporates water to be evaporated. The plant is further detailed. Condensate is enriched with natural salts and minerals, in accordance with international and/or national standards. Various types of container confer mobility. Static, non-mobile construction is feasible e.g. in buildings. Any kind of vehicle or craft may be so equipped, including airships. The solar electrical generation plant employed for operation and control is further detailed. Conventional refrigerant fluids for the plant are listed.

Description

The idea

Production of fresh water according to standard of the German "Drinking Water Ordinance" (TVO) for areas with inadequate or no drinking water supply, with help Seawater desalination plants powered by solar energy.

The technical prerequisites for this are available on the world market. The individual techniques just have to be put together. on several occasions Some companies in this field have already experimented with the results However, they did not live up to expectations. This was because of fundamentally different Paths were taken.

This is exactly where our idea starts. We combine existing and proven Techniques and thus achieve our goal in terms of cost / benefit and sufficient amount of water in very good drinking water quality.

We want to build small, easy-to-transport facilities that are capable of Hotel facilities, hospitals, communities, island regions, disaster areas etc. supply locally with drinking water. And with drinking water to the quality of the TVO.  

Why drinking water from seawater?

There are basically 3 water tanks on earth.

the sea 71% of the earth's surface the continents Groundwater, in living things, in plants the air the atmosphere

The total amount of water on earth can be divided as a percentage as follows:

sea (Salt water) 97,200% Polar and glacier ice (Fresh water) 2,200% Groundwater in the water cycle (Fresh water) 0.588% Lakes, rivers, biosphere (Freshwater) 0.012% Source: Saudi Arabia, No. 4 in the bibliography.

Only about 4% of the existing amount of fresh water (of about 350,000 bn m ³ ) can be reached and recycled by humans. Through further intensive use and pollution of the water, the drinking water reserves become increasingly smaller and must be cleaned and treated with considerable effort to be suitable for human consumption at all. The drinking water production is already today, also in Germany and other European countries, with big problems. The requirements for drinking water can no longer be met in many places.
Source: Saudi Arabia, No. 4 in the bibliography.

In some industrialized, emerging and, in particular, developing countries, secure drinking water supply is one of the major tasks of the future that must be mastered. In less than 25 years, water will be more important than crude oil. Even today, certain populations in some countries do not even have 2 to 3 liters of water per person for daily care. Water consumption has tripled since 1950. In Africa, less than 50% of the population has access to drinking water. In the foreseeable future, 40 countries on earth will be without adequate water supply.
Source: Crisis continent Africa, No. 1 in the bibliography.

The increasing number of the earth population demands an increased food requirement. Many countries on earth are unable to provide the self-sufficiency of their population sure. This is a bottleneck for adequate food production Water needed to irrigate the fields.

In Indonesia z. For example, to extend the year-round irrigation field, increased measures are required to obtain drinking water or irrigation water for the fields from rivers, lakes and the sea. The temporarily insufficient or even lack of water supply is an essential limiting factor for food cultivation in large parts of the country.
Source: Indonesia, No. 3 in the bibliography.

Lack of water is not an African problem, only in Africa does it seem most obvious: we all know the pictures from television. There seems to be a lack of water almost everywhere on this continent. The consequences that we all know are:

• 1. diarrhea
• 2. cholera
• 3. typhoid
• 4. Ruhr
• 5. Hepatitis A

Source: Ecological destruction in Africa and aging. Strategies, # 2 in the bibliography.

Every development, even in the industrialized countries, must be geared to the key resources of water, energy and land for building in order to maintain or build a livable environment for its population for the future. Bottleneck factors such as climate and lack of water supply are absolutely hindering for any development.
Source: Indonesia, No. 3 in the bibliography.

Here are some water consumption data from different countries around the world. this is the annual water consumption in m ³ per household (as of 1998):

- Australia 607 - Kuwait 336 - Canada 288 - New Zealand 271 - UNITED STATES 244 - Saudi Arabia 224 - Italy 138 - Japan 125 - France 106 - Germany 64 - Brazil 54 - UK 41 - China 28 - Netherlands 26 - India 18 - Cambodia 3 - Mali 3 - Haiti 2 - Gambia 2 Source: Crisis continent Africa, No. 1 in the bibliography.

There are more dams from year to year in Africa and other parts of the world built to receive drinking water and water for irrigation. These dams are but not only a blessing for the region in question. For one thing, big ones Land areas, primarily in the river areas concerned with trees and Pastureland flooded. The trees are lost because they are not cleared and the Population is provided as fuel. And that in countries, in which firewood is in short supply. For another, because these dams are stationary Are waters in which certain pathogens spread, such as for example Malaria or schistosomiasis.

Some examples of bilharzia infections:

• - Egypt
  After completion of the Aswan Low Dam, bilharziasis increased from 21% to 75% in some areas. The high dam increased this infestation in some villages to 100% of the population.
• - Sudan
  In the area of the Gezira-cotton project of 900000 ha, the infection rate is 60 to 70%, for schoolchildren more than 90%.
• - Kenya
  Almost all children in the irrigated region around Lake Victoria are infected.
• - South Africa
  For the Africans who work on the farms of the "white" immigrants, mostly irrigated farms, the rate is 68.5%, for the farmers in the so-called homelands (not irrigated), the rate is 33.5%.

Source: Ecological destruction in Africa and aging. Strategies, # 2 in the bibliography.

conclusion

From the above points, there is an increasing problem for the Humanity, namely the supply of drinking water to the population. What would happen closer than the ocean as a future water supplier, at least for the coastal regions of the countries. The water from the oceans is in the Comparison with the natural drinking water supplies almost inexhaustible.

However, we are aware that we are thirsting with the entire earth population can not erase our idea. But we can with our technique, at least in The coastal regions and archipelagos are limited locally, for a sufficient and good Provide drinking water. This goal may even be achieved without the use of fossil fuels or at least with little use of fossil fuels. Because in most countries with lack of water, the sun is as Energy supplier abound.

These energy suppliers are now, meaningful and effective in the drinking water generation from seawater.  

technology introduction

The system of drinking water production developed by us is about a modular construction that is lightweight and easy to carry because of it standardized exterior dimensions used in the worldwide transport system become (sea container). This ensures that these systems can be used with any truck, Sea ship, barge and the train can be transported. When Main energy source is solar energy, but this fresh water of course, can also be used with other energy sources than the Solar energy to be operated.

Alternatives are z. B .:

• - Waste heat from CHPs (exhaust gases, engine cooling water)
• - exhaust steam from process heat in dairies, breweries etc.
• - Exhaust gases from mobile power generators

This plant developed by us is primarily for export to sunny areas Countries thought, in which no or only inadequate drinking water supply consists. For the export but also countries in the European Community come in Question. On the Spanish islands z. B. prevails constantly in the summer months Water scarcity. It must be awkward and expensive from the mainland with ships be brought. Also in the coastal regions of the Spanish mainland prevails in the summer months also water shortage, so it's already in protests Spain has come.  

State of the process engineering

Mechanical processes for water purification (filtration, etc.) run on one Phase separation addition. Dissolved substances are produced by mechanical processes but not eliminated.

Biological purification processes eliminate all contaminants from biological cultures are used as nutrients, or of biological Active ingredients can be decomposed. These are primarily organic substances, but also inorganic salts. A complete cleaning of the water is not possible. In addition, the biological cultures are only in certain water qualities viable.

Chemical methods of water purification show a wide range of Cleaning options on. In all cases of dry cleaning, the Amount of waste products by the addition of chemicals, ion exchangers or other substances.

Physical methods (osmosis, electrolysis, evaporation) allow a very good separation of impurities (suspended matter and dissolved substances) from the water. The evaporation (distillation) has become the most widespread. In the Evaporation, the water is generally under atmospheric pressure until the Boiling point heated. After condensation, pure water (distillate) is produced. to Generation of water via evaporation, however, involves greater amounts of energy necessary, these are by steam boiler or by exhaust gases from CHP's provided. When using solar energy, this is so far directly to Heating of the water to be evaporated used. The evaporation is in the essential in recent years through the use of an open heat pump process become more economical.  

Advantage of the new process technology

The object of our invention (development) is a fresh water generator for To provide small to larger quantities of drinking water (fresh water) produced by evaporation. This becomes the local supply of hotel facilities, Hospitals, municipalities, island states, etc. in the local or in-house Supply network fed. The produced drinking water has such a good quality that it needs no further chemical treatment (chlorination).

The o. G. Task is solved by the combination of a Refrigeration circuit provided the energy for evaporation in the fresh water generator becomes. Those with a refrigerant cycle, by solar energy and the Ambient temperature absorbs its evaporation energy, operated plant is in able to reach a higher evaporation temperature and thereby a distillate to produce higher quality. This is a chlorination of the product as far as possible or completely avoided.

Due to the modular design of the fresh water generator plant is also a later Enlargement of the amount of drinking water produced easily and inexpensively possible.

function structure seawater circuit

About a main seawater pump, the seawater or river water is sucked in and via pipelines and various heat exchangers, which preheat the Serve feed water, fed to the fresh water generator. The fed preheated seawater is in the evaporator room of the fresh water generator evaporated. The energy required for evaporation is supplied by a refrigerant Provided. This is to achieve the highest possible evaporation temperature become, ≧ 100 ° C. The non-evaporated seawater about 65%, is used as brine (Brain) via a pump or a radiator back into the sea (river). If necessary can the seawater evaporation temperature also be lowered. This can be done by  Generation of a negative pressure in the evaporator chamber of the fresh water generator achieved become. However, it is important to pay attention to the seawater or river water quality beforehand (Check water samples for harmful substances and pathogens). In a good, Low pollutant and pathogen-poor quality, the evaporation temperature be lowered about 80 ° C. Below this evaporation temperature of approx. 80 ° C there is insufficient protection against pollutants and pathogens in the produced fresh water.

Refrigerant circuit

About a heat exchanger (solar collector o. Ä.) That is about one or more Expansion valves injected refrigerant evaporates. This is to the refrigerant as much solar energy as possible to maximize overheating to reach the refrigerant. After leaving the heat exchanger (solar collector o. Ä.), The now overheated refrigerant via pipes a compressor fed. This compressor is now supposed to compress the refrigerant to a higher one Bring energy level.

Note: For economic reasons, it is desirable in the refrigerant circuit on the To dispense with compressor. If possible, the refrigerant circuit without compressor or Pump put into operation and kept going. This is possible if the Temperature and pressure differences are sufficiently large to a self-sufficient Maintain circular process. However, if it is not quite enough, so should A small pump is used to facilitate this cycle.

In general, a refrigerant circuit without chiller and / or pump is desirable. For a trouble-free, safe and economical operation at night and at To ensure unfavorable weather conditions can be a second refrigerant circuit that is electrically heated will be installed and operated.

After leaving the compressor, the refrigerant reaches the evaporator of the Fresh water generator. Here, the superheated refrigerant gives its energy to the  fed and preheated seawater and evaporates it. That now back cooled and liquefied refrigerant passes through pipelines to a Refrigerant condenser with collector and is with further heat to the over the main seawater pump further cooled and liquefied seawater. As a result, the now liquid refrigerant undergoes a further subcooling. The supercooled liquid refrigerant passes through pipes to the heat exchangers (Solar collectors o. Ä.) Back and is by means of an expansion valve in one or several heat exchangers (solar collectors o. Ä.) injected. The Refrigerant cycle process starts again.

Fresh water circuit

The pumped via the main seawater pump and preheated over several heat exchangers seawater passes through pipes to the evaporator section of the fresh water generator. In the evaporator heat is supplied to the seawater through the hot refrigerant. This added heat causes the seawater to evaporate. Of the fed amount of seawater about 35% are evaporated. The non-evaporated portion of seawater passes through a pump or a radiator back into the sea or into the river. The vaporized seawater fraction rises in the evaporator room as a Brüdendampf and reaches the vapor condenser. In the vapor condenser, the heat is removed from the broth steam and fed to the seawater, which is conveyed through the main seawater pump. Cooling converts the vapor into vapor condensate. This vapor condensate is fed to a vapor condensate pump, which in turn promotes it via pipes and a measuring section to the hardening container. The measuring section is equipped with a salt measuring cell and an electrical three-way valve. The salt measuring cell has the task of controlling the extracted vapor condensate for its salt content. If the salt content in the target range (which is to be adjusted via a potentiometer) is correct, the vapor condensate is conducted to the hardening tank. If the measured salinity is outside the target range, the salt measuring device switches the electrical three-way valve and the saline vapor condensate is returned to the sea or into the river. At the same time an alarm is given to a person or a central control center, which then initiates appropriate measures and corrects the fault. Only after leaving the hardening container is on the steps

• - seawater
• - flash steam
• - vapor condensate

Fresh water emerged that does not compare with one from a source funded Drinking water needs to be avoided.

Claims (29)

1. Frischwassererzeugeranlage for different power levels, based on the principle of evaporation of water, by the use and operation of a refrigerant circuit, which draws its energy from solar energy and the ambient temperature, characterized in that the sea, salt, brackish, River or seawater is vaporized by a solar energy heated and operated refrigerant circuit without using a refrigerant compressor and / or without the use of a circulation, circulation or feed pump for the refrigerant circuit. 2. Fresh water generator system for different power levels, according to protection claim 1, characterized, that the refrigerant circuit for the maintenance and / or operation of the Refrigerant cycle process (Carnot process) and / or to increase the energy of the refrigerant and / or thereby to increase the evaporation temperature of the vaporized Water of the fresh water generator plant with a pump (of whatever type) is equipped and operated. 3. Fresh water generator system for different power levels, according to protection claim 1, characterized, that the refrigerant circuit for the maintenance and / or operation of the Refrigerant cycle process (Carnot process) and / or to increase the energy of the refrigerant and / or thereby to increase the evaporation temperature of the vaporized Water of the fresh water generator plant with a refrigerant compressor (whichever Type) is equipped and operated.   4. Fresh water generator system for different power levels, according to protection claim 1-3, characterized, that the refrigerant circuit for the maintenance and / or operation of the Refrigerant cycle process (Carnot process) and / or to increase the energy of the refrigerant and / or thereby to increase the evaporation temperature of the vaporized Water of the fresh water generator plant with a pump (of any type) and with a refrigerant compressor (of any type) equipped and operated. 5. fresh water generator system according protection claim 1-4, characterized, that the fresh water generator system is designed in modular design and in a modular system principle of the respective amount of fresh water required (amount of drinking water) Extension or reduction of one or more modules can be adapted. 6. fresh water generator system according to protection claim 1-5, characterized, that the fresh water generator system is mounted in a module (sea container) and the Supply and disposal connections through one or more exterior walls to the outside guided by quick-release fasteners, couplings, flanges, connectors, Cable and pipe feedthroughs and screw connections quickly and inexpensively existing or to be created supply and disposal networks can be connected.   7. fresh water generator system according to protection claim 1-6, characterized, that the refrigerant circuit its reference to heat (energy) over a heat exchanger (plate heat exchanger, tube heat exchanger, tube solar collectors, flat solar collectors, etc.), which is sufficiently dimensioned on the fresh water generator module and / or directly next to the fresh water generator module and / or arranged at some distance to the fresh water generator module and / or in Connection with the fresh water generator plant is operated (the aforementioned Procedure also applies to a mounting of the fresh water generator system in a fixed Building, z. B. if the fresh water generator system is not designed in modular design becomes.). The heat exchanger draws its amount of heat (amount of energy) from the einstrahlenden solar energy and / or from the ambient temperature of the respective Site. The heat exchanger should have a favorable for the heat quantity reference Have an angle of attack to the sun. 8. fresh water generator system according to protection claim 1-7, characterized, that the refrigerant circuit its heat quantity reference (amount of energy) to a Evaporator of the fresh water generator system and / or to be evaporated Water partially or completely evaporated. 9. fresh water generator system according to protection claim 1-8, characterized, that the cooled in the evaporator of the fresh water generator system and all or partially liquefied refrigerant is supplied to a Kältemittelverflüssiger and / or is further liquefied and / or supercooled under further heat release. The hereby  amount of heat gained (amount of energy) is wholly or partly for preheating the used in whole or in part to evaporate water. 10. fresh water generator system according to protection claim 1-9, characterized, that the refrigerant liquefied in the refrigerant liquefier is a refrigerant collector, the is arranged directly on the refrigerant condenser or structurally as a unit to the cold is assigned to the medium liquefier or separately at some distance to the Kältemittelver liquid is arranged for operation, is supplied. 11. fresh water generator system according to protection claim 1-10, characterized, that the refrigerant collected in the refrigerant receiver using one or more Control and / or control devices, by hand and / or electric and / or be operated electronically (expansion valve, throttle, valve, slide or a other techn. Device capable of regulating or controlling take over) the heat exchanger from protection claim 7 wholly or partially supplied becomes. 12. fresh water generator system according to protection claim 1-11, characterized, that the generated vapor condensate via a vapor condensate pump a Re- Mineralization tank is fed, where it deals with salts, minerals and Trace elements enriches and thereby to a high-quality food  international and / or national freshwater standards (Drinking water standards) is. 13. fresh water generator system according to protection claim 1-12, characterized, that the fresh water generator system according to protection claim 6 in or on a other transport, storage and operating equipment and / or another container, serving the purpose of mobility and / or modular design, housed, mounted and / or can be operated. 14. fresh water generator system according to protection claim 1-13, characterized, that the fresh water generator system for different power levels in one stationary building without module (stone house, wooden house, etc.) accommodated, mounted and / or operated and / or housed according to protection claim 6 and 13, mounted and / or operated, but as a stationary unit on a solid surface (Foundation, floor slab, racks, ground, etc.) is set up and fixed and / or a fixed permanent or detachable connection is received or it is only for installation a solid ground, as described above. 15. fresh water generator system according to protection claim 1-14, characterized, that the fresh water generator system in whole or in part in modular design and / or completely or partially not in modular design on trucks, trailers, swimming equipment,  Ships, boats, aircraft, planes, zeppelins etc. housed, transported, mounted and / or operated. 16. fresh water generator system according to protection claim 1-15, characterized, that the module, according to protection claim 6, in which the fresh water generator plant whole or partially housed, mounted and / or operated, with ventilation openings and / or is equipped with ventilation and equipment and facilities and can be equipped with one or more doors, as well as with boarding aids (Stairs, platforms, pedestals, etc.) may be equipped, if the module after Protection claim 14 has an elevated position from the site (ground), to allow safe and easy access to the module. 17. Fresh water generator system according to protection claim 1-16, characterized, that required for the operation of the fresh water generator system electrical energy a solar power system and / or with battery buffer and / or with voltage and Frequency converter can be equipped and provided. 18. fresh water generator system according to protection claim 1-17, characterized, that the fresh water generator system with an automatic and / or manual order Switching device may be equipped, which inadequate or completely failing  Power supply through the solar power system switches to the local electrical grid and thus allows further operation. 19. fresh water generator system according to protection claim 1-18, characterized, that the entire fresh water generator system with an electric and / or a electronic and / or a manual control, regulation and monitoring device can be equipped and operated (regardless of which type and / or which Principle / program subject to this device). 20. fresh water generator system according to protection claim 1-19, characterized, that the fresh water generator plant in particular the protection claim 19 described device for regulation, control and monitoring with a techn. Device for forwarding operating data, monitoring data and fault messages to a central control center and / or to a person or other entity affiliated with the Monitoring of the equipment is commissioned and with a device for remote control can be equipped and operated.   21. fresh water generator system according to protection claim 1-20, characterized, that required for the operation of the fresh water generator system electrical energy a wind turbine can be made available and / or continue to Protection claim 17 can be equipped and operated. 22. Fresh water generator system according to protection claim 1-21, characterized, that required for the operation of the fresh water generator plant electrical energy after Protection claim 17 and 21 equipped with both systems (solar power and wind power) can be and is operated. 23. Fresh water generator plant according to protection claim 1-22, characterized, that a second refrigerant circuit is installed and operated at insufficient performance of the first refrigerant circuit heating the fresh water generator system takes over. 24 fresh water generator system according to protection claim 23, characterized, that the second refrigerant circuit with a container for receiving the liquid and / or the gaseous refrigerant from the second refrigerant circuit is equipped and  is operated and the container for heating the refrigerant with a electrical heating element is equipped and operated. 25. Fresh water generator plant according to protection claim 23-24, characterized, that the second refrigerant circuit with techn. Facilities (fittings, multipath valves, safety devices, etc.) is equipped and operated, the one Simultaneous operation of both refrigerant circuits allows or one of the first Refrigerant circuit ensures independent operation of the second refrigerant circuit. To ensure safe, trouble-free and economical operation of the fresh water generator system even at night and / or unfavorable weather conditions. 26 fresh water generator system according to protection claim 1-25, characterized in that for the first and / or the second refrigerant circuit, a refrigerant is used, which is already available on the market or will be available in the market in a few years or produced is offered (even in small quantities), but not on the market and sold.
Examples of refrigerants
27. Fresh water generator system according to protection claim 23-25, characterized, that the second refrigerant circuit according to protection claim 1, 2, 3 and 4 is equipped or can be equipped and operated. 28. Fresh water generator system according to protection claims 23-25 and 27, characterized, that the second refrigerant circuit without a container for holding the liquid and / or or gaseous refrigerant is equipped and operated and that for heating the refrigerant in the second refrigerant circuit one or more Heating elements (pipe trace heating, Anlegeheizelemente, etc.) on or in the Refrigerant tubes of the second refrigerant circuit are mounted and operated. 29. fresh water generator system according to protection claim 1-28, characterized, that the fresh water generator system only with a Kältitteitteikreislauf after protection claim 23, 24, 26, 28 is equipped and operated.