WO2015078863A1 - Apparatus for generating service water by means of an evaporation tank - Google Patents

Abstract

The present invention relates to an apparatus for obtaining service water from contaminated water, comprising a condensation tank (2) with a service water outlet (4) and a process air outlet (36), an evaporation tank (6) with a residual water outlet (8) and a process air inlet (38), a separation device (10) with controllable permeability, which separation device forms a horizontal passage between condensation tank (2) and evaporation tank (6), a condenser (12) which is arranged in the condensation tank and which has a coolant inlet (14) for contaminated water and a coolant outlet (16), a heating device (18, 28, 30) which is connected to the coolant outlet (16) and which is designed to heat the contaminated water, a spraying device (20) which is connected to the heating device (18) and which is designed to spray the heated contaminated water into the evaporation tank (6), and a controllable air delivery device (22) which is designed to feed process air to the evaporation tank (6).

Description

 DEVICE FOR PRODUCING WASTE WATER WITH THE HELP OF AN EVERYDING VESSEL

The present invention relates to a device for recovering service water by desalination of seawater or salt water in general or purification of contaminated waters such as brackish or oil-contaminated groundwater or wastewater. The device should preferably be powered by solar energy.

State of the art

A known process for desalination of seawater is based on the basic principle of the so-called Fuchtuchtde sti 11 tion. This is also well suited for small, decentralized systems and the energy supply by solar energy.

Single-stage processes for solar thermal desalination of seawater are known in which the evaporator and condenser each have only at the top and bottom an air and water inlet or outlet. It can only be achieved a heat recovery of about 50%. However, the expenditure on equipment is relatively low, so that the use in structurally weak areas offers.

To achieve higher heat recovery, multiple stages of evaporation and condensation are required. This method is therefore often used in seawater desalination plants. For high-performance fossil-fueled plants, more than 12 stages and more than 96% heat recovery are possible. However, the equipment cost is very high in such systems. For structurally weak areas, such systems are therefore less suitable.

Another known method for the thermal desalination of seawater is the so-called multi-effect humidification / Dehumidification- method (MEH). Systems based on the MEH process are based on thermal energy supply from low-temperature sources (eg solar collectors). The heat becomes a sealed desalination tank fed, in which the natural water cycle with evaporation and condensation is modeled.

Preheated seawater is further heated by the supply of solar energy and evaporated in a part of the desalting tank, whereby brine is deposited with concentrated salt content. In the other part of the desalting tank, the steam for condensing the distillate or service water is condensed by means of a cooler, the cold seawater is supplied as a cooling medium and this is preheated. This process runs in the cycle, with cold seawater and solar energy supplied and Brine and hot water are withdrawn.

By transferring the thermal energy released during condensation on the supplied seawater in the process, a large part of the thermal energy used in the evaporation of condensing back again recovered and used for preheating the seawater. By preheating in turn, the energy is reduced, which is needed to further heat the seawater.

The document DE 43 40 745 C2 uses such Feuchtluftdestillations- process for hot water production.

However, this system has certain disadvantages. On the one hand, the evaporation takes place by applying heated sea or generally contaminated water to nonwoven or fabric towels, so as to increase the available surface area for evaporation. However, this requires that the contaminated water must not contain significant amounts of solids or suspended matter, otherwise the cloths would clog up quickly and thus become unusable. The system is therefore for cleaning polluted water with amounts of solids and suspended solids, eg. B. of brackish groundwater, not suitable.

Furthermore, it is a system with a process container without inner partitions. So there is no separation between the evaporation room and Condensation chamber. A control of the mass flows involved is therefore not possible. The method relies on a convection roller forming between the evaporation space and the condensation space. The performance of the plant is therefore limited by the volume of the process vessel needed to ensure this convection, which is modeled on nature. The air circulation takes place predominantly laminar. In addition, the convection roller is substantially limited, since the heated moist air flowing from the evaporator to the condenser flows back after cooling from the condenser to the evaporator within the process vessel.

The object of the present invention is to provide an improved hot water producing apparatus based on wet air distillation, which is more efficient for a given volume of the process container, i. can produce more process water per unit of time, and which nevertheless retains the fundamental advantages of the MEH process. The proposed device should continue to be suitable to process contaminated water with fractions of solids and suspended matter. In the present invention, the cooled moist air to be returned outside the process container.

Brief description of the invention

According to a first aspect of the invention there is provided an apparatus for producing industrial water from contaminated water, comprising:

 a condensation tank with a process water drain and a

Prozessluftabfiuss;

 an evaporation tank with a residual water drain and a process air inlet;

 a controllable-permeability separator which forms a horizontal passage between the condensation container and the evaporation container;

a condenser disposed in the condensation vessel and having a contaminated water coolant inlet and a coolant outlet; a heater connected to the coolant outlet and configured to heat the contaminated water;

 a spray device connected to the heater and configured to spray the heated contaminated water into the evaporation tank; and a controllable air conveying device configured to supply process air to the evaporation tank.

With the device according to the invention, the amount of air circulated and the amount of brine and thus the power can be controlled specifically, the functional principle used according to the invention can therefore be referred to as Controlled Multi-Effect Humidification / Dehumidification (CMEH). As a result of the air delivery device, substantially more process air per unit of time can be circulated over the same space requirement of the evaporation container and the condensation container, thereby allowing more water to evaporate. By located between the evaporation tank and Kondensati onsbehälter separation device with variable controllable permeability, the formation of a desired air circulation can be selectively influenced, so that the air circulation takes place predominantly in the turbulent range. The advantages of the nearly stepless MEH process are retained despite a considerable increase in performance in the CMEH process.

According to one embodiment, the permeability of the separating device can be controlled at different positions from substantially closed to substantially completely open, so that the air flow within the evaporation container and condensation container can be specifically influenced in such a way that the air flow is substantially turbulent.

The air circulation can be controlled so preferably about the top and bottom separately. In a preferred embodiment, the separating device is designed such that at each vertical position the permeability is independently controllable. This can be specifically influenced the desired shape of the air roll, which is within evaporation tank and condensation tank, driven by the air conveyor, forms.

According to one embodiment, the separating device is a Venetian blind with a plurality of horizontally extending slats, wherein preferably each slat is individually controllable. Alternatively, other types of separation devices come into consideration, such as rotatable or movable slats, sliding panels and associated openings, etc. The adjustment can be done by hand, but preferred is the control of a suitable drive.

A Venetian blind represents a very simple separating device, which can be controlled from essentially closed to substantially completely open. In addition to the degree of permeability, the air flow here can also be influenced by the orientation of the respective lamellae. For example, there may be a substantially obliquely upward directed air flow in the upper region of the evaporation tank. Depending on the desired control, the lamellae can be aligned parallel to achieve the best possible undisturbed flow, or perpendicular to it, if a more turbulent flow is to be achieved due to the higher resistance.

Due to the different water content of hot saturated air (340 g / nr at 85 ° C) and cold saturated air (30 g / m ³ at 30 ° C), the air requirement in the upper part of the evaporation and condensation tank is about 10 times lower than in the lower one Area. Accordingly, the air flow that can be controlled by the variable separator accordingly varies. By changing the amount of air and the amount of process water, the performance of the system can be regulated.

According to one embodiment, the Luftfördereinriehtung is a fan.

According to one embodiment, the process air outflow of the condensation tank with the process air inflow of the evaporation tank through an outboard Piping connected so that preferably a closed air circuit is formed. Alternatively, however, the air circuit may also be open, so that process air is taken from the environment of the device and returned to the environment after passing through the device.

According to one embodiment, the process air outlet and the process air inlet are each arranged in the lower region, preferably on the underside of the condensation container or the evaporation container.

According to one embodiment, the device further comprises:

 an adjustable air line, which is adapted to discharge process air in the upper region, preferably at the top of the evaporation container and to supply the upper region, preferably the upper side of the condensation container.

This measure has the purpose, a portion of the air flow, preferably about 8-10%, mandatory to pass through the spray. This ensures a very intensive humidification of the air. In addition, while the full beam with the total heat carried by the injected heated water heat energy is passed through only 8-10% of the amount of air. An outlet temperature of the air near the corresponding water inlet temperature can be achieved. The lower this temperature difference, the sooner a higher heat recovery or a higher efficiency can be achieved.

According to one embodiment, the heating device comprises a solar collector which is adapted to heat the contaminated water directly or via a heat exchanger.

Preferably, the plant is powered by solar energy, which is sufficiently available especially in areas such as the Sahara. As a result, the energy required to be supplied can be covered in a cost-effective and environmentally friendly manner. The water to be purified can be heated directly in the solar field to the required temperature, or it can be transferred by means of a heat exchanger, the heat energy to the contaminated water. The former allows a very simple construction with low Losses. The latter makes it possible to use in the solar collectors another liquid, such as oil, so that a separation from the contaminated water is achieved.

According to one embodiment, the device further comprises:

 a cooler which is connected between the residual water drain and the condenser and arranged to cool the residual water and supply it to the condenser.

The cooler has the task to cool the process water from the evaporation tank and zuzulühren the condenser. Cooling can be done using cold contaminated water, or alternatively through a cooling tower or chimney. The cooling power preferably corresponds to the heating power of the heater, so that a closed heat cycle is formed.

According to one embodiment, the device further comprises:

 a heat accumulator configured to store heat energy and supply it to the heater as needed.

In order to ensure, for example, solar thermal energy supply to the plant operation outside the hours of sunshine, a heat storage can be provided, which serves for the intermediate storage of heat energy. In the case of the use of solar collectors, the power or area must be increased accordingly. In general, the heat accumulator serves to temporarily store accumulating and / or economically usable heat energy only at certain times in order to provide it to the service water generating device as needed. This also applies to other forms of energy such as industrial waste heat etc. Short description of the drawing

Fig. 1 is a schematic view of a first embodiment of the invention;

Fig. 2 is a schematic view of a second embodiment of the invention;

Fig. 3 is a schematic view of a third embodiment of the invention;

Fig. 4 is a schematic view of a fourth embodiment of the invention; and

Fig. 5 is a schematic view of an exemplary pilot plant according to the invention.

Detailed description

In the following, reference is made, by way of example, to seawater or, in general, salt water as a possibility for contaminated water. Other contaminated waters with other undesirable ingredients than salt, especially those with shares of oil, solids and suspended matter, but can be processed in the same way.

Figure 1 is a schematic cross-sectional view of a first embodiment of the present invention. A Verdunsterbehälter 6 has the task to bring the process air to a relative humidity of nearly 100%, ie saturated, and a temperature of about 85 ° C. For this purpose, salt water is sprayed finely distributed by means of a spray device 20 in the evaporator container 6.

The water content at this temperature is then about 340 g / m ³ . The required amount of air for the transport of 1 m ^{J of} water is therefore about 3000 m ³ / h in single-stage operation, in multi-stage operation about 6000 m ³ / h. The evaporator receives the required energy through 10 m ³ / h of process water (brine) with a temperature of, for example, 86 ° C. This temperature is achieved by preheating in the condenser and supplying additional heat energy, preferably solar energy achieved. During condensation, for example, the process water cools to about 32 ° C, the released energy is transferred to the salt water used as a coolant, thereby achieving preheating and heat recovery.

In order to be able to transfer the heat energy from the process water to the process air, a large transition area between the two media is required. In an estimate, the following assumptions are made:

 Temperature difference between process water and process air: 3 ° C.

Heat energy for the evaporation of 1 m of seawater: 700 kW.

Heat transfer coefficient a: 0.05 kW / (m ² * AT).

Required transitional area: 4667 m ² .

The heat transfer or heat transfer coefficient is of crucial importance in seawater desalination, since it significantly influences the areas for cooling and evaporation. The above assumption would require a heat exchanger with a huge surface or a huge water surface, which is so unrealistic for a corresponding plant. In the prior art, this has been solved by the use of cloths or webs that provide surface enlargement but are problematic with suspended and solids.

According to the invention, this problem is therefore solved instead by Tropfenbesprühung. With suitable nozzles, the sprayer 20 can thus produce a large amount of minute droplets having a 10 times larger area of about 50,000 m ² . In this way, a process air saturated with water is produced in the evaporator container 6. Not absorbed by the process air, concentrated salt water or Brine can be removed by a residual water outlet 8 from the evaporator tank 6.

By using a sprayer there is no problem with water containing oil, solid or suspended matter. The process water may therefore also have coarse particles, but the diameter should not exceed about 1/3 of the nozzle opening be. The plague bodies are filtered out in the process. This is a huge technical and economic advantage, since the filtering of such substances would otherwise be complicated and expensive.

The following pollutants contained in the process water are completely or partially filtered out in the process of the invention, these substances are usually very harmful to the environment:

Drug residues;

 Fertilizer residues and toxins;

 Chemical residues such as e.g. Dyes and oils.

By filtering out even the finest solids, any radiation exposure is reduced.

Wastewater loaded with fine substances can be thickened with the device according to the invention to the extent that it can no longer be sprayed. The thus thickened wastewater can be removed separately and fed to a further treatment with conventional methods such as pressing, drying and combustion.

The saturated with water process air is guided horizontally from the evaporator tank 6 to the condensation tank 2. Between the evaporator container 6 and the condensation container 2, a separating device 10, for example, a blind with a plurality of fins 24, according to the invention is arranged. The shutter 10 can control the opening between evaporator tank 6 and condensation tank 2 from fully open to fully closed. In a preferred embodiment, each slat of the blind can be controlled individually. In the example shown in Figure 1, some slats in the lower half of the blind are closed while all the other slats are partially open. Thus, the flow between evaporator 6 and condensation tank 2 can be influenced. In the condensation vessel 2, a capacitor 12 is arranged. The condenser 12 has the task to cool the process air and bring to a temperature of about 32 ° C. Distillate is separated, which can be discharged through a drain 4 and processed about to drinking water. In this case, no spray system can be used, otherwise a mixing between salt water and distillate would occur.

Preferably, therefore, a metal or multiwall capacitor is used. Between saturated air and metal condenser, the heat transfer coefficient α would normally be 0.05. However, it is likely that film or droplet condensation will occur, which would increase the value of α to 3. Therefore, the transition area is only about 78 m ² .

In the condenser 12, seawater is used as the coolant. The seawater remains within the condenser 12, the distillate is separated from the outside of the condenser and can be removed. The process water used as coolant heats up by the heat energy released in the condensation of the saturated air to about 79 ° C and is a heater 18, for example, a solar collector with optional heat exchanger, fed to be heated to the required 86 ° C. The heated process water is then supplied to the spray device 20.

Furthermore, according to the invention a process air inlet 38 is provided in the lower region of the evaporator container 6, in which an air conveyor device 22 is arranged. The air conveying device 22 is preferably a fan. The amount of air transported by the fan 22 process air can be controlled specifically. The condensation tank 2 has a corresponding process air outlet 36. In the embodiment of Figure 1, the air circuit of the device is therefore designed to be open. Process air is sucked from the environment and released to the environment after passing through the device. In alternative embodiments, the air circuit can also be realized closed, process air outlet 36 and process air inlet 38 then being connected via an air line are. See, for example, the embodiments of Figures 2-5, each showing exemplary closed air circuits.

Process air outlet 36 and process air inlet 38 are arranged in the lower region of the respective containers. FIG. 1 shows the preferred variant according to which process air outflow 36 and process air inflow 38 are located on the underside of the respective containers, which essentially corresponds to the main direction of the air flow. Alternative arrangements are also possible, for example laterally in the lower region of the respective container.

In the interaction of the fan 22 and the blind 10, it is thus possible to achieve a significantly higher air throughput per unit of time in a controlled manner, the flow preferably being substantially turbulent. As a result of the CMEH process according to the invention in the industrial water production apparatus, a multiple of seawater per unit time can be evaporated compared with conventional MEH plants, and thus a multiple of distillate can be obtained.

FIG. 2 shows a development of the embodiment of FIG. Here, an air line between the upper part of the Verdunsterbehälters 6 and the condensation vessel 2 is further arranged. About 8-10% of the process air is thus supplied to the condensation tank 2. The air volume is adjustable.

It can thereby be achieved that this portion of the process air is forcibly guided through the spray jet, which leads to a very intensive humidification of this proportion of air. Furthermore, due to the contact between a small proportion of the process air with the entire sprayed heated seawater and thus the total heat energy transported, the outlet temperature of the process air is brought to a value close to the temperature of the sprayed seawater. The lower the temperature difference, the higher the recoverable heat recovery. The air circuit for the process air is executed here closed, but it may alternatively (not shown), however, as shown in Figure 1 open. In general, each embodiment of the invention may be implemented with open or closed process air circulation as needed.

FIG. 3 shows a development of the embodiment of FIG. In general, the required supply of heat energy to heat the preheated process water from the condenser to the required 86 ° C may come from any suitable sources. Industrial waste heat, geothermal energy, heat energy from combined heat and power plants or the like can be used. For cost and environmental reasons, however, solar energy is preferably used. For this purpose, the embodiment of Figure 3 as a heating device to a solar collector 28 which heats the preheated process water via a heat exchanger 30. The heat exchanger 30 is optional here, alternatively, the water can also be heated directly in the solar collector.

Not shown is another embodiment. Since the use of solar energy only during the daily hours of sunshine operation of the system is possible, in addition, a W ^r ärmespeicher be provided which holds enough heat energy for night hours to operate the device continuously or at least substantially longer. For this purpose, it is necessary to increase the power of the solar collector accordingly to fill the heat accumulator and at the same time to supply the device.

It should be emphasized that the heat accumulator is of course also available to ensure the operation of all other types of heat supply or to be able to make the heat more evenly. It is also possible to use and store heat energy that is available only occasionally and / or is inexpensive only at certain times.

FIG. 4 shows a development of the embodiment of FIG. 3. Here, a cooler 32 is provided in the inlet of the seawater. The cooler has the task of the process water which is 32 ° C from the Verdunstungsbehältcr to cool to 26 ( ^'and supplied to the condenser twelfth The cooling can with, for example, 18 ° C done cold seawater. Alternatively, other cooling methods are conceivable, such as a cooling tower or chimney.

In the embodiment shown from ührungsform a mixing container 34 is further provided. The mixing tank 34 makes it possible to mix the Brine water discharged from the evaporation tank 6 as needed to the fresh seawater. However, it can also be removed as required via an adjustable sequence.

FIG. 5 shows an exemplary test plant which operates on the principle according to the invention. The system has an output of 13 liters of process water per hour. The gross output is 9.3 kW. the additional solar power is 0.9 kW. The area of the solar collector is 3 m ² . The temperatures and performances shown are only examples.

Claims

claims

1 . An apparatus for producing industrial water from contaminated water, comprising: a condensation tank (2) having a service water drain (4) and a process air drain (36); an evaporation tank (6) with a residual water drain (8) and a process air inlet (38); a controllable-permeability separator (10) forming a horizontal passage between the condensation vessel (2) and the evaporation vessel (6); a condenser (12) disposed in the condensation vessel and having a contaminated water coolant inlet (14) and a coolant outlet (16); a heater (18) connected to the coolant outlet (16) and configured to heat the contaminated water; a spraying device (20) connected to the heater (18) and arranged to spray the heated contaminated water into the evaporation tank (6); and an adjustable air conveying device (22) arranged to supply process air to the evaporation tank (6),

2. Device according to claim 1, wherein the permeability of Trenneinri rect (10) from substantially closed to substantially fully open controllable, wherein preferably the permeability at different positions in the separating device is independently controllable.

3. Apparatus according to claim 1 or 2, wherein the separating device (10) is a blind with a plurality of horizontally extending slats (24), wherein preferably each slat (24) is individually controllable.

4. Device according to one of the preceding claims, wherein the air conveying device (22) is a fan.

5. Device according to one of the preceding claims, wherein the process air outlet of the condensation container (2) with the process air flow of the evaporation container (6) is connected, wherein preferably a closed air circuit is formed.

6. Device according to one of the preceding claims, wherein the process air outlet and the process air inlet are each arranged in the lower region, preferably on the underside of the condensation container (2) or the evaporation container (6).

7. Device according to one of the preceding claims, further comprising: an adjustable air line (26) which is adapted to discharge process air in the upper region, preferably at the top of the evaporation container (6) and the upper region, preferably the upper side of the condensation container

(2).

8. Device according to one of the preceding claims, wherein the heating device (18) comprises a solar collector (28) which is adapted to heat the contaminated water directly or via a heat exchanger (30).

9. Device according to one of the preceding claims, further comprising: a cooler (32) connected between the residual water drain (8) and the condenser (12) and adapted to cool the residual water and the capacitor (12) to supply.

10. Device according to one of the preceding claims, further comprising: a heat accumulator which is adapted to store heat energy and, if necessary, to supply the heating device (18).