The present application, as a national state application, claims the benefit of PCT Application No. PCT/NL2008/000013, filed Jan. 16, 2008 and foreign priority to Netherlands Application No. 1033253, filed Jan. 18, 2007, which are both incorporated herein by reference.
The present invention relates to a method for purifying a liquid comprising liquid particles and residual particles. It is hereby possible to generate substantially pure water from for instance seawater.
A known system for desalinating seawater, and thereby converting it into fresh water, is membrane distillation. Here salt water is heated, wherein the water evaporates and passes through a membrane, after which the water vapour condenses on a relatively cool condensation surface and relinquishes the heat to the salt water to be heated. The condensation is then discharged as substantially pure fresh water.
The use of membranes is a costly aspect of the whole purification process. Not only are the membranes expensive to produce and purchase, the membranes are also susceptible to contamination, whereby they begin to operate less efficiently. An additional problem is that many membranes are essentially sensitive to temperature and, particularly at higher temperatures, become less efficient in use. The evaporation of the liquid further requires a great deal of energy.
The present invention has for its object to provide a method for purifying a liquid, wherein the purification is performed in a more efficient manner.
The present invention provides a method for purifying a liquid comprising liquid particles and residual particles, comprising the steps of:
Liquid can evaporate efficiently by heating the liquid for purifying and distributing or vapourizing this heated liquid in a purification space. Applying electric charge to the liquid droplets achieves that the droplets become unstable. Once the critical point has been passed, these droplets are then distributed as a type of mist of charged particles. These particles have a diameter in the order of magnitude of 10 μm or even smaller. The process (“Electro-Spraying”) of vapourizing the particles can also be repeated. Liquid evaporates from the particles. An efficient evaporation process is hereby obtained. The evaporated liquid will then seek a surface on which to condense. Applying a charge to the condensation surface similar to that on the residual particles achieves that the residual particles of the liquid are repelled by the condensation surface and only the evaporated liquid particles will condense on this condensation surface. The condensation surface will here have a lower temperature than the particles. A substantially pure liquid flow is obtained by then collecting the condensation and discharging it separately. The unevaporated residual particles are discharged as a residual flow. The applying of said charge has the result, among others, that no membrane is required to separate the evaporated liquid particles from the residual particles. An advantageous process is hereby obtained, the operation of which is not diminished through use as a result of for instance contamination. In an advantageous embodiment the liquid is seawater which is purified into fresh water suitable for consumption.
In a preferred embodiment according to the invention the evaporated liquid particles are guided to the condensation wall.
By guiding the liquid particles to the condensation wall a greater part of the liquid for purifying is separated from the residual particles. This guiding can take place by making use of an extra gas flow and/or a pressure difference. A greater output can hereby be realized from the process. An additional advantage is that the residual flow will comprise fewer liquid particles and will therefore be smaller, with for instance a higher concentration of salt.
In a preferred embodiment according to the invention the step of heating a liquid comprises of carrying the liquid though a heat exchanger and further heating the liquid with an external source.
Owing to the use of a heat exchanger to heat the liquid use can be made of the energy released from, among others, the condensation process and/or the remainder of the residual flow. An external energy source is necessary for the purpose of supplying extra energy in order to maintain the process. In an advantageous embodiment this energy source is embodied as an additional heat exchanger. Energy in the form of heat can be supplied to the liquid in relatively simple manner by using a heat exchanger. The heat exchanger can for instance obtain this heat in the form of a residual energy originating from another process preferably located nearby. Use can herein also be made for instance of solar energy. The heating of the liquid preferably takes place in counter-flow to the evaporation, condensation and/or discharge. The use of the energy required for the process is hereby managed most efficiently. A positive charge is further preferably applied to both the liquid droplets and the condensation surface. The most efficient use is hereby made of properties of the substances involved.
In a preferred embodiment according to the invention the residual particles are repelled by the condensation surface and attracted by a discharge wall to which a charge opposite to that on the condensation wall is applied.
By applying the charge to the liquid and to the condensation surface the residual particles in the liquid are repelled by this condensation surface. The direction of the flow of residual particles can further be directed by the use of a discharge wall to which a charge opposite to that on the condensation wall is applied. The residual particles are hereby attracted and the purification of the liquid is further improved. The charge can be applied by making use of one or more power sources. The discharge wall can for instance also be provided with a charge by an process of induction.
In an advantageous preferred embodiment according to the invention the residual flow is used for energy generation by making use of the pressure difference between salt and fresh water.
A membrane potential is set by for instance making use of an ion-selective membrane which separates salt water from fresh water. This potential amounts to about 80 mV. The small voltage difference can optionally be increased by placing a plurality of compartments in series in order to use a greater voltage difference, whereby electricity can be generated. By using the highly concentrated salt residual flow for this purpose a relatively high voltage difference can be realized using a membrane, whereby electricity can be generated in more efficient manner by making use of this residual flow.
The present invention further also relates to a device for purifying a liquid. The device provides the same effects and advantages as those stated with reference to the method. In an advantageous embodiment of the device according to the invention a double-walled cylinder is provided as heat exchanger and condensation surface. Through the use of a double-walled cylinder the incoming, liquid flow can for instance be heated by the outer edge, after which evaporation, condensation and discharge of the separated flows takes place through the centre of the cylinder. The incoming liquid flow can of course also be guided through the centre of the cylinder and the discharge through the outer edge. An advantageous device can be realized in efficient manner with such a double-walled cylinder.
In a further preferred embodiment the liquid for purifying is heated to about 200° C. in order to intensify the evaporation step.
By heating the liquid for purifying above 100° C., for instance by applying a higher pressure, the heat content of the liquid flow is increased. A greater part of the water will hereby evaporate in the evaporation step. The optimum temperature depends on the specific process conditions, such as magnitude of flow rates, heat-exchanging surfaces and so on. The temperature of the liquid for purifying will preferably be brought above 100° C., to about 125° C., more preferably to about 150° C., and most preferably to 200° C. or even higher. It will be apparent that, when the temperatures are too high, among other things the heat loss will become so great that the process will progress less efficiently.
Further advantages, features and details of the invention are elucidated on the basis of a preferred embodiment, wherein reference is made to the accompanying drawings, in which:
A device 2 for purifying a liquid (
Device 26 according to the invention (
Due to the high temperature of droplet flow 44 water can evaporate and then condense onto the cold surface 48. This process takes place in a space 61. The heat released during this condensation is used to heat ingoing flow 28. The outgoing flows have a temperature of about 28° C. In the shown embodiment about 10% of the water will for instance evaporate in a single purification step, depending of course on the process parameters.
A device 62 for purifying a liquid (
The ingoing flow is heated from a temperature of 25° C. to about 80° C. at outgoing flow 74. Due to the additional heating the extra-heated flow 78 has a temperature of about 95°. The heating from 25° C. to 80° C. can be achieved by making use of the released condensation heat and the cooling of the flows on the inner side of the double-walled cylinder. Flows 86 and 88 cool from 95° C. close to sprayer 80 to about 28° C. when leaving device 62. Power sources 90 and 94 apply the same charge to sprayer 80 and inner wall 68, wherein inner wall 68 functions as condensation surface. Discharge wall 98 is on the other hand provided with an opposite charge by power source 100. The residual particles are hereby attracted by this wall and will not deposit against condensation wall 68. Pure separation of residual flow 88 and pure water flow 86 can hereby be realized. Flows can optionally be forced by fans and/or for instance pressure differences.
In an alternative embodiment of the purifying process the device 104 (
The present invention is in no way limited to the above described preferred embodiment; the rights sought are defined by the following claims, within the scope of which many modifications can be envisaged. It is thus possible for instance to combine the power sources into one source, such as power sources 90 and 94 of
Number | Date | Country | Kind |
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1033253 | Jan 2007 | NL | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/NL2008/000013 | 1/16/2008 | WO | 00 | 11/2/2010 |
Publishing Document | Publishing Date | Country | Kind |
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WO2008/088211 | 7/24/2008 | WO | A |
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Entry |
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International Search Report, completed Jun. 26, 2008, and mailed on Jul. 4, 2008, in International Application No. PCT/NL2008/000013. |
Number | Date | Country | |
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20110042199 A1 | Feb 2011 | US |