Title of Invention	A SYSTEM AND METHOD FOR DESALINATION OF SEAWATER
Abstract	A system and method for desalination of seawater W having an original water salinity and a original water concentration of scale forming components, the system comprising: a pre-treatment sub-system for at least partial removal from said water W of said scale forming components, producing thereby a pre-treated feed water having a first concentration of scale forming components lower than said original concentration of scale forming components; a forward feed flow multi-effect evaporator adapted for distillation of said pre-treated feed water, producing thereby main desalted water product WM having a desalted water salinity lower than said water salinity, and main brine having a salt concentration of approximately 10%; a concentrator adapted for receiving therein said main brine and concentrating it, producing thereby more concentrated brine with an increased salt concentration of approximately 20%-22%, and releasing a first additional desalted water product W1; and a crystallizer for receiving said more concentrated brine, adapted for crystallization thereof to obtain at least solid salt products and releasing a second additional desalted water product W2.

Title of Invention

A SYSTEM AND METHOD FOR DESALINATION OF SEAWATER

Abstract

A system and method for desalination of seawater W having an original water salinity and a original water concentration of scale forming components, the system comprising: a pre-treatment sub-system for at least partial removal from said water W of said scale forming components, producing thereby a pre-treated feed water having a first concentration of scale forming components lower than said original concentration of scale forming components; a forward feed flow multi-effect evaporator adapted for distillation of said pre-treated feed water, producing thereby main desalted water product WM having a desalted water salinity lower than said water salinity, and main brine having a salt concentration of approximately 10%; a concentrator adapted for receiving therein said main brine and concentrating it, producing thereby more concentrated brine with an increased salt concentration of approximately 20%-22%, and releasing a first additional desalted water product W1; and a crystallizer for receiving said more concentrated brine, adapted for crystallization thereof to obtain at least solid salt products and releasing a second additional desalted water product W2.

Full Text	FIELD OF THE INVENTION This invention relates to desalination systems and methods, in particular a method using multi-effect evaporators. BACKGROUND OF THE INVENTION Distillation of water, being a commonly used method of desalination, is a process in which various soluble materials such as salt, contaminants etc. are eliminated from water containing these materials, leaving clean, usually drinkable water. One known method for achieving such distillation relies on water evaporation, much like salt and scale being accumulated on the bottom of an electric kettle after water has evaporated. In this process during evaporation of the water, soluble materials that are not volatile remain in a solid state residue, usually in the form of salt and scale, and are disposed of. The vapor can then be condensed back into the state of liquid, resulting in contaminant free water. One of the problems in the above process is scale formation on the surfaces of the evaporation equipment, caused by compounds of the seawater such as, for example, calcium carbonate and sulfate. These and other scale formation compounds are usually removed from the seawater by means of different pre-treatment processes. Also, disposal of the residual brine, i.e. concentrated solution of salts remaining after the distillation process, may cause an ecological problem. Moreover, the disposal of brines presents significant costs and challenges for the desalination industry, which increase the time required for permits and construction of new plants and result in higher cost of water treated thereby. One way to deal with brines from seawater desalination is making use of zero liquid discharge (ZLD) systems. A ZLD system evaporates brine leaving a salt residue for disposal or reuse. SUMMARY OF THE INVENTION In. accordance with one aspect of the present invention, there is provided a system for desalination of seawater W having an original water salinity and a original water concentration of scale forming components, the system comprising: - a pre-treatment sub-system for at least partial removal from said water W of said scale forming components, producing thereby a pre-treated feed water having a first concentration of scale forming components lower than said original concentration of scale forming components; - a forward feed flow multi-effect evaporator adapted for distillation of said pre- treated feed water, producing thereby main desalted water product Wm having a desalted water salinity lower than said water salinity, and main brine having a salt concentration of approximately 10%. - a concentrator adapted for receiving therein said main brine and concentrating it, producing thereby more concentrated brine with an increased salt concentration of approximately 20%-22%, and releasing a first additional desalted water product W1; and - a crystallizer for receiving said more concentrated brine, adapted for crystallization thereof to obtain at least solid salt products and releasing a second additional desalted water product W2. Any one or more of the following features may be included in the system according to the present invention: ¦ The amount of said main water product WM approximately equals to 0.65W. ¦ The amount of said first additional water W1 approximately equals to 0.15W. ¦ The amount of said second additional water W2 approximately equals to 0.15W. ¦ The scale forming components are at least sulfate ions. ¦ The pre-treatment system may further comprise at least de-carbonization columns adapted for removing said sulfate ions. ¦ The scale forming components are at least calcium ions. ¦ The pre-treatment system may further comprise a reactor adapted for creating calcium carbonate by reacting said calcium ions with soda ash. ¦ The pre-treatment system may further comprise a clarifier adapted for removing said calcium carbonate. ¦ The concentrator may further constitute a part of a single multi-effect evaporator/concentrator installation. ¦ The concentrator may further constitute a part of a single multi-effect concentrator/crystallizer installation. According to a further aspect of the present invention, there is provided a method of desalination of a seawater having a original water salinity and a concentration of scale forming components, the method comprising: - at least partial removal from said seawater of said scale forming components and producing a pre-treated feed water having a first concentration of scale forming components lower than said feed water concentration of scale forming components; - distillation of said pre-treated feed water by a forward feed flow multi-effect evaporator and producing main desalted water product Wm having a desalted water salinity lower than said original water salinity, and main brine having a salt concentration of approximately 10%; - producing from said main brine a more concenrated brine with increased salt concentration of approximately 20%-22%; and - crystallizing said more concentrated brine and obtaining at least one salt product therefrom. Any one or more of the following features may be included in the method according to the present invention: ¦ The method may further comprise removing said scale forming components by means of de-carbonization columns. ¦ The method may further comprise removing said scale forming components by means of a reactor and a clarifier. ¦ The method may further comprise producing said main brine by said evaporator. ¦ The method may further comprise providing a concentrator. ¦ The method may further comprise producing said more concentrated brine by said concentrator. BRIEF DESCRIPTION OF THE DRAWINGS In order to understand the invention and to see how it may be carried out in practice, embodiments will now be described, by way of non-limiting examples only, with reference to the accompanying drawings, in which: Fig. 1 schematically illustrates one example of a system according to the present invention; and Fig. 2 schematically illustrates another example of a system according to die present invention. DETAILED DESCRD7TION OF EMBODIMENTS Figs. 1 and 2 schematically show two examples of a system for seawater desalination according to the present invention, designated as 10 and 30, respectively. The system 10 comprises a pre-treatment sub-system 11, a multi-effect evaporator 13 with its associated feed heater 21, a concentrator 17 (not shown) combined with a crystallizer 19 (not shown) in one common multi-effect concentrator/crystallizer installation 15, which has a succession of corresponding primarily concentrating (PC) effects and primarily crystallizing (PCR) effects. The concentrator 17 and the crystallizer 19 may further be two distinct separate installations. Similarly, the system 30 comprises a pre-treatment sub-system 31, a multi- effect evaporator 33 with its associated feed heater 41, the evaporator 33 (not shown) incorporating a concentrator 37 (not shown) in one common multi-effect installation 35, having a succession of corresponding primarily desalinating (PD) effects and primarily concentrating (PC) effects, and a crystallizer 39. Each of the systems 10 and 30 further comprises three condensers 12, 14 and 16. The condenser 12 is a falling film condenser and the condensers 14 and 16 are forced circulation condensers. The construction of the condensers 12, 14 and 16 is known per se. The systems 10 and 30 further comprise a steam supply system 50 (not shown) for supplying vapor to the systems, as will be explained below. Witii reference to Fig. 1, in operation of the system 10, seawater W first enters the pre-treatment sub-system 11 where predetermined scale forming components, such as carbonate, are removed therefrom and it is fed as feed water WF, via the condenser 12 and the feed heater 21, to the multi-effect evaporator 13, where main desalination process takes place and three main products are produced: main desalted water WM (not shown) which constitutes a majority of total water product Wtotal outcoming from the multi-effect evaporator 13, main brine BM proceeding to further treatment in the desalination system, and a first condensate return R1 flowing back to the steam supply system 50 and then is supplied as a vapor V1 to the multi-effect evaporator 13. The condensers 12 and 14 produce additional desalted water WA12 and WA14, which is produced from a vapor V1' and withdrawn as a part of the total water product Wtotal- The vapor V1' satisfies V1'=V1+D, in which D refers to energy losses in the system. Further treatment of the main brine Bm is performed in the multi-effect concentrator/crystallizer installation 15, in which concentration process, and subsequent crystallization process, take place in the corresponding PC and PCR effects of the concentrator/crystallizer installation 15, resulting in the production of: (i) salts generally designated S, and a bitterns solution BS which are men withdrawn from the system as products having a potential of being used in the desalination plant or outside thereof; (ii) additional desalted water Wa1 and Wa2, which is then fed to the multi-effect evaporator 13 together with an additional desalted water WAi6 coming from the condenser 16. Wai, Wa2 and WA16 constitute together additional desalted water WA, which is brought in the evaporator 13 to the same temperature as the main water product Wm, and from where it is then withdrawn as a part of the total water product Wtotal so that Wtotal= Wm +WA+WA12+WA14; and (iii) second condensate return R2 flowing to the steam supply system 50 and then is supplied as a vapor V2 to the concentrator/crystallizer installation 15. The additional desalted water W16 discharged from the condenser 16 is produced from a vapor V2', which satisfies V2'=V2+D, in which D refers to energy losses in the system. WA1, which is a majority of the additional desalted water WA is obtained as a result of the concentration process which takes place in the concentrator 17 [or PC effects 17 of the of the multi-effect concentrator/crystallizer installation 15], during which a brine Bc (not shown) more concentrated than the main brine Bm is produced. The brine Bc is then used in the crystallization process, resulting in the production of the salts S, the bitterns solution BS and some more additional desalted water WA2. To operate as described above, the multi-effect evaporator 13 has evaporator inlets 13a to 13c. The inlet 13a is adapted for receiving therein the feed water Wf, the second inlet 13b is adapted for receiving therein the vapor V1 for use in the desalination process, and the third inlet 13c is adapted for receiving therein the additional desalted water Wa coming from the multi-effect concentrator/crystallizer installation 15. The evaporator 13 further comprises four evaporator outlets, namely, the outlet 13d for discharging therefrom the main product Wtotal, the outlet 13e for discharging therefrom the main brine Bm, the outlet 13f for discharging therefrom the first condensate return R1 and the outlet 13g for discharging therefrom vapor V1' to the condensers 12 and 14. The concentrator/crystallizer installation 15 has two inlets, 15a and 15b, for receiving therein the main brine Bm and the vapor V2, respectively. It further has five outlets 15c to 15g, for discharging therefrom vapor V2' that goes to the condenser 16, the additional desalted water Wa, the bitterns solution BS, salts S and the second condensate return R2, respectively. The outlet 15f refers to a group of outlets for discharging therefrom of different kinds of salts. In one specific example of the system 10, salts S produced as a result of the crystallization process in the multi-effect concentrator/crystallizer installation 15 from the brine product Bc are industrial salt NaCl and calcium sulfate CaSO4. In such system 10, the pre-treatment sub-system 11 is adapted to remove from the seawater W mostly sulfate ions SO42-. For this purpose, the pre-treatment system 11 may comprise de-carbonization columns 18, where acid is added to the seawater feed W and most of the sulfate ions SO42- are removed. The sulfate ions may be substituted with anions such as chloride Cl-. Alternatively, the sulfate may be regenerated with a salt, such as Potash KC1 or common salt NaCl. In this case, the solution of the respective sulfate will be created, from which a saleable commodity may be recovered by means known per se. During the pre-treatment process the alkalinity is further removed from the seawater feed together with the sulfate. One particular example of the multi-effect evaporator 13 that may be used in the system 10 is of so-called 'forward feed flow' type, in which the feed water and the vapor both move downstream during the process. The evaporator may for example be of the kind described in detail in PCT/IL2006/000302, which in its entirety is incorporated herein by reference. This evaporator 13 in the described example is adapted to desalt the water flowing therethrough so that the main brine BM released from the evaporator 13 has a salt concentration of approximately 10%. The evaporator according to the present invention may comprise tubes as described in the above publication or fluted oval tubes. The concentrator 17 [or PC effects 17 of the multi-effect concentrator/crystallizer installation 15] used in the system 10 may be of any appropriate type known in the art, capable to concentrate the main brine Bm of the above salt concentration, to the extent that the brine product Bc released therefrom has a salt concentration of approximately 20%-22%, allowing it to be further used in the production of salt products, in particular those indicated above, in the crystallizer 19. With reference to Fig. 2, in the operation of the desalination system 30, seawater W first enters the pre-treatment sub-system 31 where predetermined scale forming components are removed therefrom, and is fed as feed water Wf, via the condenser 12 and the feed heater 41, to the combined multi-effect evaporator/concentrator installation 35. In this installation 35, the following processes take place: the feed water Wf undergoes a desalination process in the PD effects 33, which results in the production of main desalted water Wm constituting a majority of total water product WTOtal outcoming from the multi-effect installation 35, and of main brine Bm (not shown); and the main brine Bm undergoes concentration in the PC effects 37 of the multi- effect installation 35, to produce brine Bc and additional desalted water WA1, which is then withdrawn as a part of the total water product Wtotal. The condensers 12 and 14 produce additional desalted water Wa12 and Wa14, which is withdrawn as a part of the total water product Wtotal. The evaporator/concentrator installation 35 further produces a first condensate return R1 which flows back to the steam supply system 50 and then is supplied as a vapor V1 to thereto. The brine Bc from the multi-effect installation 35 flows to the crystallizer 39, in which a crystallization process takes place, resulting in the production of: (i) salt S and bitterns solution BS, which are then withdrawn from the system as products having a potential of being used in the desalination plant or outside thereof; (ii) additional desalted water Wa2, which is then fed to the multi-effect installation 35, constituting together with an additional water WA16 from the condenser 16 an additional water WA, so that Wa=Wa2+WA16, where it is brought to the same temperature as the main water product Wm, and from where it is then withdrawn as a part of the total water product WTOtal so that Wtotal= Wm + WA1 + WA12+WA14+ WA'; and (iii) second condensate return R2 flowing to the steam supply system 50 similarly to be then supplied to the crystallizer 39 as a vapor V2. To operate as described above, the multi-effect installation 35 has multi-effect installation inlets 35a to 35c. The inlet 35a is adapted for receiving therein the feed water Wf, the second inlet 35b is adapted for receiving therein the vapor V1 for use in the desalination process, and the third inlet 35c is adapted for receiving therein the additional desalted water WA' coming from the crystallizer 39. The installation 35 further comprises four multi-effect installation outlets, namely, the outlet 35d for discharging therefrom the main product Wtotal, the outlet 35e for discharging therefrom the brine product Bc, the outlet 35f for discharging therefrom the first condensate return R1 and the outlet 35g for discharging therefrom vapor Vc that goes to the condensers 12 and 14. The crystallizer 39 has two crystallizer inlets, 39a and 39b, for receiving therein the brine product Bc and the vapor V2, respectively. It further has five crystallizer outlets 39c to 39g, for discharging therefrom vapor Vc that goes to the condenser 16, the additional desalted water Wa2, the bitterns solution BS, salts S and the second condensate return R2, respectively. The outlet 39f refers a group of outlets for discharging therefrom of different kinds of salts, is desired. In one particular example of the system 30, the salt S produced by the crystallizer 39 is industrial salt NaCl. The pre-treatment sub-system 31 in such system 30 is adapted to remove substantially all calcium ions from the seawater W. For this purpose, the pre-treatment system 31 may comprise a reactor 43 and a clarifier 44. During the pre-treatment process calcium ions from the seawater W react with soda ash Na2CO3 in the reactor 43 and hardly-soluble calcium carbonate CaCO3 is created and then precipitates and removed from the seawater W in the clarifier 44. Optionally, a soluble base, such as caustic soda NaOH, in an amount substantially equivalent to the content of bicarbonate ion HCO3- in the seawater W, may be added thereto, thereby saving about one fourth of the required amount of soda ash. During the above process sulfates is removed together with calcium carbonate. The multi-effect evaporator/concentrator installation 35 may have a configuration similar to that of the multi-effect evaporator 13, with a difference being mainly in that its PD effects 33 (not shown) are followed by the PC effects 37 (not shown). In the present example, the brine BM produced by the PD effects 33 may have salt concentration of approximately 10%, and the brine Bc which produced therefrom by the PC effects 37 may have salt concentration of approximately 20%-22%. An additional difference between the PD and PC effects in the installation 35 may be in that at least a part of the pipes and tubes in the PC effects 37 may be made of material different from the material of the pipes and tubes in the PD effects, to better withstand increased salt concentration of the brine passing therethrough. The pre-treatment processes of sub-systems 11 and 31 of the systems 10 and 30 in the examples described above prevent scale and corrosion of the equipment used in the systems 10 and 30. Removing both calcium carbonate and sulfate in the sub-system 31, in addition, allows the multi-effect evaporator 33 to run smoothly even though brine having a high salt concentration flows therein. Table 1 summarizes, in a non-limiting manner, parameters which the systems 10 and 30 may have, in accordance with the examples described above with reference to Fig. 1 and Fig. 2. Table 1 As summarized in Table 1, there are differences between consumptions of the cooling water supplied to the condensers 14 and 16 and the steam supplied to different parts of the two systems 10 and 30. In particular, in the system 10 the steam consumption is 76,560 kg/hr and cooling water consumption is 4,482,000 kg/hr. In the system 30 the steam consumption is 61,100 kg/hr and cooling water consumption is 2,222,000 kg/hr. The main reason for this difference is the configurations of the multi- effect evaporators 13 and 33. The evaporator 33 consumes less steam. Consequently, less cooling water is required. Based on the above Table 1, water and brine rates may be approximately calculated for the systems 10 and 30. System 10 Main desalted water discharged from the evaporator 13 is calculated as follows: Additional desalted water discharged from the concentrator and the crystallizer: System 30 Main desalted water Wm and additional desalted water WA1 discharged from the multi- effect installation 35 is calculated as follows: Desalted water discharged from the crystallizer is calculated as follows: Total water recovery is calculated as follows: As shown above, both systems 10 and 30 are adapted for recovering of almost 95% of the water content of the feed seawater W. It can be further roughly estimated from the above calculations, that water recovery is divided between different parts of the system as follows: evaporator/PD effects - about 65% (66.6%) of the total recovery, crystallizer/PCR effects - about 15% (11.3%) of the total recovery, and concentrator/PC effects - about 15% of the total recovery (95-65-11.3 = 18.7%). The remaining 5% are salts and bitterns solution, whose contents are determined by the kind of the pre-treatment that is applied to the feed water W. Those skilled in the art to which this invention pertains will readily appreciate that numerous changes, variations, and modification can be made without departing from the scope of the invention, mutatis mutandis. We Claim: 1. A system for desalination of seawater W having an original water salinity and a original water concentration of scale forming components, the system comprising: - a pre-treatment sub-system for at least partial removal from said water W of said scale forming components, producing thereby a pre-treated feed water having a first concentration of scale forming components lower than said original concentration of scale forming components; - a forward feed flow multi-effect evaporator adapted for distillation of said pre- treated feed water, producing thereby main desalted water product WM having a desalted water salinity lower than said water salinity, and main brine having a salt concentration of approximately 10%; - a concentrator adapted for receiving therein said main brine and concentrating it, producing thereby more concentrated brine with an increased salt concentration of approximately 20%-22%, and releasing a first additional desalted water product W1; and - a crystallizer for receiving said more concentrated brine, adapted for crystallization thereof to obtain at least solid salt products and releasing a second additional desalted water product W2. 2. A system according to Claim 1, wherein amount of said main water product Wm approximately equals to 0.65W. 3. A system according to Claims 1 or 2, wherein amount of said first additional water W1 approximately equals to 0.15W. 4. A system according to anyone of Claims 1 to 3, wherein amount of said second additional water W2 approximately equals to 0.15W. 5. A system according to anyone of Claims 1 to 4, wherein the scale forming components are at least sulfate ions. 6. A system accprding to Claim 5, wherein the pre-treatment system comprises at least de-carbonization columns adapted for removing said sulfate ions. 7. A system according to anyone of Claims 1 to 6, wherein the scale forming components are at least calcium ions. 8. A system according to Claim 7, wherein the pre-treatment system comprises a reactor adapted for creating calcium carbonate by reacting said calcium ions with soda ash. 9. A system according to Claim 8, wherein the pre-treatment system comprises a clarifier adapted for removing said calcium carbonate. 10. A system according to anyone of Claims 1 to 9, wherein the concentrator constitutes a part of a single multi-effect evaporator/concentrator installation. 11. A system according to anyone of Claims 1 to 10, wherein the concentrator constitutes a part of a single multi-effect concentrator/crystallizer installation. 12. A method of desalination of a seawater having a original water salinity and a concentration of scale forming components, the method comprising: - at least partial removal from said seawater of said scale forming components and producing a pre-treated feed water having a first concentration of scale forming components lower than said feed water concentration of scale forming components; - distillation of said pre-treated feed water by a forward feed flow multi-effect evaporator and producing main desalted water product WM having a desalted water salinity lower than said original water salinity, and main brine having a salt concentration of approximately 10%; - producing from said main brine a more concenrated brine with increased salt concentration of approximately 20%-22%; and - crystallizing said more concentrated brine and obtaining at least one salt product therefrom. 13. A method according to Claim 12, further comprising removing said scale forming components by means of de-carbonization columns. 14. A method according to Claims 12 or 13, further comprising removing said scale forming components by means of a reactor and a clarifier. 15. A method according to anyone of Claims 12 to 14, further comprising producing said main brine by said evaporator. 16. A method according to anyone of Claims 12 to 15, further comprising providing a concentrator. 17. A method according to Claim 16, further comprising producing said more concentrated brine by said concentrator. A system and method for desalination of seawater W having an original water salinity and a original water concentration of scale forming components, the system comprising: a pre-treatment sub-system for at least partial removal from said water W of said scale forming components, producing thereby a pre-treated feed water having a first concentration of scale forming components lower than said original concentration of scale forming components; a forward feed flow multi-effect evaporator adapted for distillation of said pre-treated feed water, producing thereby main desalted water product WM having a desalted water salinity lower than said water salinity, and main brine having a salt concentration of approximately 10%; a concentrator adapted for receiving therein said main brine and concentrating it, producing thereby more concentrated brine with an increased salt concentration of approximately 20%-22%, and releasing a first additional desalted water product W1; and a crystallizer for receiving said more concentrated brine, adapted for crystallization thereof to obtain at least solid salt products and releasing a second additional desalted water product W2.

Full Text

FIELD OF THE INVENTION
This invention relates to desalination systems and methods, in particular a
method using multi-effect evaporators.
BACKGROUND OF THE INVENTION
Distillation of water, being a commonly used method of desalination, is a
process in which various soluble materials such as salt, contaminants etc. are eliminated
from water containing these materials, leaving clean, usually drinkable water. One
known method for achieving such distillation relies on water evaporation, much like salt
and scale being accumulated on the bottom of an electric kettle after water has
evaporated. In this process during evaporation of the water, soluble materials that are
not volatile remain in a solid state residue, usually in the form of salt and scale, and are
disposed of. The vapor can then be condensed back into the state of liquid, resulting in
contaminant free water.
One of the problems in the above process is scale formation on the surfaces of
the evaporation equipment, caused by compounds of the seawater such as, for example,
calcium carbonate and sulfate. These and other scale formation compounds are usually
removed from the seawater by means of different pre-treatment processes.
Also, disposal of the residual brine, i.e. concentrated solution of salts remaining
after the distillation process, may cause an ecological problem. Moreover, the disposal
of brines presents significant costs and challenges for the desalination industry, which
increase the time required for permits and construction of new plants and result in
higher cost of water treated thereby.
One way to deal with brines from seawater desalination is making use of zero
liquid discharge (ZLD) systems. A ZLD system evaporates brine leaving a salt residue
for disposal or reuse.

SUMMARY OF THE INVENTION
In. accordance with one aspect of the present invention, there is provided a system
for desalination of seawater W having an original water salinity and a original water
concentration of scale forming components, the system comprising:
- a pre-treatment sub-system for at least partial removal from said water W of said
scale forming components, producing thereby a pre-treated feed water having a
first concentration of scale forming components lower than said original
concentration of scale forming components;
- a forward feed flow multi-effect evaporator adapted for distillation of said pre-
treated feed water, producing thereby main desalted water product Wm having a
desalted water salinity lower than said water salinity, and main brine having a
salt concentration of approximately 10%.
- a concentrator adapted for receiving therein said main brine and concentrating it,
producing thereby more concentrated brine with an increased salt concentration
of approximately 20%-22%, and releasing a first additional desalted water
product W1; and
- a crystallizer for receiving said more concentrated brine, adapted for
crystallization thereof to obtain at least solid salt products and releasing a second
additional desalted water product W2.
Any one or more of the following features may be included in the system
according to the present invention:
¦ The amount of said main water product WM approximately equals to
0.65W.
¦ The amount of said first additional water W1 approximately equals to
0.15W.
¦ The amount of said second additional water W2 approximately equals to
0.15W.
¦ The scale forming components are at least sulfate ions.
¦ The pre-treatment system may further comprise at least de-carbonization
columns adapted for removing said sulfate ions.
¦ The scale forming components are at least calcium ions.
¦ The pre-treatment system may further comprise a reactor adapted for
creating calcium carbonate by reacting said calcium ions with soda ash.

¦ The pre-treatment system may further comprise a clarifier adapted for
removing said calcium carbonate.
¦ The concentrator may further constitute a part of a single multi-effect
evaporator/concentrator installation.
¦ The concentrator may further constitute a part of a single multi-effect
concentrator/crystallizer installation.
According to a further aspect of the present invention, there is provided a method of
desalination of a seawater having a original water salinity and a concentration of scale
forming components, the method comprising:
- at least partial removal from said seawater of said scale forming components and
producing a pre-treated feed water having a first concentration of scale forming
components lower than said feed water concentration of scale forming
components;
- distillation of said pre-treated feed water by a forward feed flow multi-effect
evaporator and producing main desalted water product Wm having a desalted
water salinity lower than said original water salinity, and main brine having a
salt concentration of approximately 10%;
- producing from said main brine a more concenrated brine with increased salt
concentration of approximately 20%-22%; and
- crystallizing said more concentrated brine and obtaining at least one salt product
therefrom.
Any one or more of the following features may be included in the method
according to the present invention:
¦ The method may further comprise removing said scale forming
components by means of de-carbonization columns.
¦ The method may further comprise removing said scale forming
components by means of a reactor and a clarifier.
¦ The method may further comprise producing said main brine by said
evaporator.
¦ The method may further comprise providing a concentrator.
¦ The method may further comprise producing said more concentrated
brine by said concentrator.

BRIEF DESCRIPTION OF THE DRAWINGS
In order to understand the invention and to see how it may be carried out in
practice, embodiments will now be described, by way of non-limiting examples only,
with reference to the accompanying drawings, in which:
Fig. 1 schematically illustrates one example of a system according to the present
invention; and
Fig. 2 schematically illustrates another example of a system according to die
present invention.
DETAILED DESCRD7TION OF EMBODIMENTS
Figs. 1 and 2 schematically show two examples of a system for seawater
desalination according to the present invention, designated as 10 and 30, respectively.
The system 10 comprises a pre-treatment sub-system 11, a multi-effect
evaporator 13 with its associated feed heater 21, a concentrator 17 (not shown)
combined with a crystallizer 19 (not shown) in one common multi-effect
concentrator/crystallizer installation 15, which has a succession of corresponding
primarily concentrating (PC) effects and primarily crystallizing (PCR) effects. The
concentrator 17 and the crystallizer 19 may further be two distinct separate installations.
Similarly, the system 30 comprises a pre-treatment sub-system 31, a multi-
effect evaporator 33 with its associated feed heater 41, the evaporator 33 (not shown)
incorporating a concentrator 37 (not shown) in one common multi-effect installation 35,
having a succession of corresponding primarily desalinating (PD) effects and primarily
concentrating (PC) effects, and a crystallizer 39.
Each of the systems 10 and 30 further comprises three condensers 12, 14 and
16. The condenser 12 is a falling film condenser and the condensers 14 and 16 are
forced circulation condensers. The construction of the condensers 12, 14 and 16 is
known per se.
The systems 10 and 30 further comprise a steam supply system 50 (not shown)
for supplying vapor to the systems, as will be explained below.
Witii reference to Fig. 1, in operation of the system 10, seawater W first enters
the pre-treatment sub-system 11 where predetermined scale forming components, such
as carbonate, are removed therefrom and it is fed as feed water WF, via the condenser
12 and the feed heater 21, to the multi-effect evaporator 13, where main desalination
process takes place and three main products are produced: main desalted water WM (not
shown) which constitutes a majority of total water product Wtotal outcoming from the
multi-effect evaporator 13, main brine BM proceeding to further treatment in the
desalination system, and a first condensate return R1 flowing back to the steam supply
system 50 and then is supplied as a vapor V1 to the multi-effect evaporator 13.
The condensers 12 and 14 produce additional desalted water WA12 and WA14,
which is produced from a vapor V1' and withdrawn as a part of the total water product
Wtotal- The vapor V1' satisfies V1'=V1+D, in which D refers to energy losses in the
system.
Further treatment of the main brine Bm is performed in the multi-effect
concentrator/crystallizer installation 15, in which concentration process, and subsequent
crystallization process, take place in the corresponding PC and PCR effects of the
concentrator/crystallizer installation 15, resulting in the production of:
(i) salts generally designated S, and a bitterns solution BS which are men
withdrawn from the system as products having a potential of being used in
the desalination plant or outside thereof;
(ii) additional desalted water Wa1 and Wa2, which is then fed to the multi-effect
evaporator 13 together with an additional desalted water WAi6 coming from
the condenser 16. Wai, Wa2 and WA16 constitute together additional desalted
water WA, which is brought in the evaporator 13 to the same temperature as
the main water product Wm, and from where it is then withdrawn as a part of
the total water product Wtotal so that Wtotal= Wm +WA+WA12+WA14; and
(iii) second condensate return R2 flowing to the steam supply system 50 and then
is supplied as a vapor V2 to the concentrator/crystallizer installation 15.
The additional desalted water W16 discharged from the condenser 16 is produced
from a vapor V2', which satisfies V2'=V2+D, in which D refers to energy losses in the
system.
WA1, which is a majority of the additional desalted water WA is obtained as a
result of the concentration process which takes place in the concentrator 17 [or PC
effects 17 of the of the multi-effect concentrator/crystallizer installation 15], during
which a brine Bc (not shown) more concentrated than the main brine Bm is produced.

The brine Bc is then used in the crystallization process, resulting in the production of
the salts S, the bitterns solution BS and some more additional desalted water WA2.
To operate as described above, the multi-effect evaporator 13 has evaporator
inlets 13a to 13c. The inlet 13a is adapted for receiving therein the feed water Wf, the
second inlet 13b is adapted for receiving therein the vapor V1 for use in the desalination
process, and the third inlet 13c is adapted for receiving therein the additional desalted
water Wa coming from the multi-effect concentrator/crystallizer installation 15. The
evaporator 13 further comprises four evaporator outlets, namely, the outlet 13d for
discharging therefrom the main product Wtotal, the outlet 13e for discharging
therefrom the main brine Bm, the outlet 13f for discharging therefrom the first
condensate return R1 and the outlet 13g for discharging therefrom vapor V1' to the
condensers 12 and 14.
The concentrator/crystallizer installation 15 has two inlets, 15a and 15b, for
receiving therein the main brine Bm and the vapor V2, respectively. It further has five
outlets 15c to 15g, for discharging therefrom vapor V2' that goes to the condenser 16,
the additional desalted water Wa, the bitterns solution BS, salts S and the second
condensate return R2, respectively. The outlet 15f refers to a group of outlets for
discharging therefrom of different kinds of salts.
In one specific example of the system 10, salts S produced as a result of the
crystallization process in the multi-effect concentrator/crystallizer installation 15 from
the brine product Bc are industrial salt NaCl and calcium sulfate CaSO4.
In such system 10, the pre-treatment sub-system 11 is adapted to remove from
the seawater W mostly sulfate ions SO42-. For this purpose, the pre-treatment system 11
may comprise de-carbonization columns 18, where acid is added to the seawater feed W
and most of the sulfate ions SO42- are removed. The sulfate ions may be substituted with
anions such as chloride Cl-. Alternatively, the sulfate may be regenerated with a salt,
such as Potash KC1 or common salt NaCl. In this case, the solution of the respective
sulfate will be created, from which a saleable commodity may be recovered by means
known per se. During the pre-treatment process the alkalinity is further removed from
the seawater feed together with the sulfate.
One particular example of the multi-effect evaporator 13 that may be used in the
system 10 is of so-called 'forward feed flow' type, in which the feed water and the vapor
both move downstream during the process. The evaporator may for example be of the

kind described in detail in PCT/IL2006/000302, which in its entirety is incorporated
herein by reference. This evaporator 13 in the described example is adapted to desalt the
water flowing therethrough so that the main brine BM released from the evaporator 13
has a salt concentration of approximately 10%. The evaporator according to the present
invention may comprise tubes as described in the above publication or fluted oval tubes.
The concentrator 17 [or PC effects 17 of the multi-effect
concentrator/crystallizer installation 15] used in the system 10 may be of any
appropriate type known in the art, capable to concentrate the main brine Bm of the
above salt concentration, to the extent that the brine product Bc released therefrom has a
salt concentration of approximately 20%-22%, allowing it to be further used in the
production of salt products, in particular those indicated above, in the crystallizer 19.
With reference to Fig. 2, in the operation of the desalination system 30,
seawater W first enters the pre-treatment sub-system 31 where predetermined scale
forming components are removed therefrom, and is fed as feed water Wf, via the
condenser 12 and the feed heater 41, to the combined multi-effect
evaporator/concentrator installation 35. In this installation 35, the following processes
take place:
the feed water Wf undergoes a desalination process in the PD effects 33, which
results in the production of main desalted water Wm constituting a majority of total
water product WTOtal outcoming from the multi-effect installation 35, and of main
brine Bm (not shown); and
the main brine Bm undergoes concentration in the PC effects 37 of the multi-
effect installation 35, to produce brine Bc and additional desalted water WA1, which is
then withdrawn as a part of the total water product Wtotal.
The condensers 12 and 14 produce additional desalted water Wa12 and Wa14,
which is withdrawn as a part of the total water product Wtotal.
The evaporator/concentrator installation 35 further produces a first condensate
return R1 which flows back to the steam supply system 50 and then is supplied as a
vapor V1 to thereto.
The brine Bc from the multi-effect installation 35 flows to the crystallizer 39, in
which a crystallization process takes place, resulting in the production of:

(i) salt S and bitterns solution BS, which are then withdrawn from the system
as products having a potential of being used in the desalination plant or
outside thereof;
(ii) additional desalted water Wa2, which is then fed to the multi-effect
installation 35, constituting together with an additional water WA16 from the
condenser 16 an additional water WA, so that Wa=Wa2+WA16, where it is
brought to the same temperature as the main water product Wm, and from
where it is then withdrawn as a part of the total water product WTOtal so that
Wtotal= Wm + WA1 + WA12+WA14+ WA'; and
(iii) second condensate return R2 flowing to the steam supply system 50 similarly
to be then supplied to the crystallizer 39 as a vapor V2.
To operate as described above, the multi-effect installation 35 has multi-effect
installation inlets 35a to 35c. The inlet 35a is adapted for receiving therein the feed
water Wf, the second inlet 35b is adapted for receiving therein the vapor V1 for use in
the desalination process, and the third inlet 35c is adapted for receiving therein the
additional desalted water WA' coming from the crystallizer 39. The installation 35
further comprises four multi-effect installation outlets, namely, the outlet 35d for
discharging therefrom the main product Wtotal, the outlet 35e for discharging
therefrom the brine product Bc, the outlet 35f for discharging therefrom the first
condensate return R1 and the outlet 35g for discharging therefrom vapor Vc that goes to
the condensers 12 and 14.
The crystallizer 39 has two crystallizer inlets, 39a and 39b, for receiving therein
the brine product Bc and the vapor V2, respectively. It further has five crystallizer
outlets 39c to 39g, for discharging therefrom vapor Vc that goes to the condenser 16,
the additional desalted water Wa2, the bitterns solution BS, salts S and the second
condensate return R2, respectively. The outlet 39f refers a group of outlets for
discharging therefrom of different kinds of salts, is desired.
In one particular example of the system 30, the salt S produced by the
crystallizer 39 is industrial salt NaCl.
The pre-treatment sub-system 31 in such system 30 is adapted to remove
substantially all calcium ions from the seawater W. For this purpose, the pre-treatment
system 31 may comprise a reactor 43 and a clarifier 44. During the pre-treatment
process calcium ions from the seawater W react with soda ash Na2CO3 in the reactor 43
and hardly-soluble calcium carbonate CaCO3 is created and then precipitates and
removed from the seawater W in the clarifier 44. Optionally, a soluble base, such as
caustic soda NaOH, in an amount substantially equivalent to the content of bicarbonate
ion HCO3- in the seawater W, may be added thereto, thereby saving about one fourth of
the required amount of soda ash. During the above process sulfates is removed together
with calcium carbonate.
The multi-effect evaporator/concentrator installation 35 may have a
configuration similar to that of the multi-effect evaporator 13, with a difference being
mainly in that its PD effects 33 (not shown) are followed by the PC effects 37 (not
shown). In the present example, the brine BM produced by the PD effects 33 may have
salt concentration of approximately 10%, and the brine Bc which produced therefrom
by the PC effects 37 may have salt concentration of approximately 20%-22%.
An additional difference between the PD and PC effects in the installation 35
may be in that at least a part of the pipes and tubes in the PC effects 37 may be made of
material different from the material of the pipes and tubes in the PD effects, to better
withstand increased salt concentration of the brine passing therethrough.
The pre-treatment processes of sub-systems 11 and 31 of the systems 10 and 30
in the examples described above prevent scale and corrosion of the equipment used in
the systems 10 and 30. Removing both calcium carbonate and sulfate in the sub-system
31, in addition, allows the multi-effect evaporator 33 to run smoothly even though brine
having a high salt concentration flows therein.
Table 1 summarizes, in a non-limiting manner, parameters which the systems 10
and 30 may have, in accordance with the examples described above with reference to
Fig. 1 and Fig. 2.
Table 1

As summarized in Table 1, there are differences between consumptions of the
cooling water supplied to the condensers 14 and 16 and the steam supplied to different
parts of the two systems 10 and 30. In particular, in the system 10 the steam
consumption is 76,560 kg/hr and cooling water consumption is 4,482,000 kg/hr. In the
system 30 the steam consumption is 61,100 kg/hr and cooling water consumption is
2,222,000 kg/hr. The main reason for this difference is the configurations of the multi-
effect evaporators 13 and 33. The evaporator 33 consumes less steam. Consequently,
less cooling water is required.
Based on the above Table 1, water and brine rates may be approximately
calculated for the systems 10 and 30.
System 10
Main desalted water discharged from the evaporator 13 is calculated as follows:
Additional desalted water discharged from the concentrator and the crystallizer:

System 30
Main desalted water Wm and additional desalted water WA1 discharged from the multi-
effect installation 35 is calculated as follows:

Desalted water discharged from the crystallizer is calculated as follows:

Total water recovery is calculated as follows:

As shown above, both systems 10 and 30 are adapted for recovering of almost
95% of the water content of the feed seawater W. It can be further roughly estimated
from the above calculations, that water recovery is divided between different parts of
the system as follows: evaporator/PD effects - about 65% (66.6%) of the total recovery,
crystallizer/PCR effects - about 15% (11.3%) of the total recovery, and concentrator/PC
effects - about 15% of the total recovery (95-65-11.3 = 18.7%).
The remaining 5% are salts and bitterns solution, whose contents are determined
by the kind of the pre-treatment that is applied to the feed water W.
Those skilled in the art to which this invention pertains will readily appreciate
that numerous changes, variations, and modification can be made without departing
from the scope of the invention, mutatis mutandis.
We Claim:
1. A system for desalination of seawater W having an original water salinity and a
original water concentration of scale forming components, the system comprising:
- a pre-treatment sub-system for at least partial removal from said water W of said
scale forming components, producing thereby a pre-treated feed water having a
first concentration of scale forming components lower than said original
concentration of scale forming components;
- a forward feed flow multi-effect evaporator adapted for distillation of said pre-
treated feed water, producing thereby main desalted water product WM having a
desalted water salinity lower than said water salinity, and main brine having a
salt concentration of approximately 10%;
- a concentrator adapted for receiving therein said main brine and concentrating it,
producing thereby more concentrated brine with an increased salt concentration
of approximately 20%-22%, and releasing a first additional desalted water
product W1; and
- a crystallizer for receiving said more concentrated brine, adapted for
crystallization thereof to obtain at least solid salt products and releasing a second
additional desalted water product W2.
2. A system according to Claim 1, wherein amount of said main water product Wm
approximately equals to 0.65W.
3. A system according to Claims 1 or 2, wherein amount of said first additional
water W1 approximately equals to 0.15W.
4. A system according to anyone of Claims 1 to 3, wherein amount of said second
additional water W2 approximately equals to 0.15W.
5. A system according to anyone of Claims 1 to 4, wherein the scale forming
components are at least sulfate ions.
6. A system accprding to Claim 5, wherein the pre-treatment system comprises at
least de-carbonization columns adapted for removing said sulfate ions.
7. A system according to anyone of Claims 1 to 6, wherein the scale forming
components are at least calcium ions.

8. A system according to Claim 7, wherein the pre-treatment system comprises a
reactor adapted for creating calcium carbonate by reacting said calcium ions with soda
ash.
9. A system according to Claim 8, wherein the pre-treatment system comprises a
clarifier adapted for removing said calcium carbonate.
10. A system according to anyone of Claims 1 to 9, wherein the concentrator
constitutes a part of a single multi-effect evaporator/concentrator installation.
11. A system according to anyone of Claims 1 to 10, wherein the concentrator
constitutes a part of a single multi-effect concentrator/crystallizer installation.
12. A method of desalination of a seawater having a original water salinity and a
concentration of scale forming components, the method comprising:
- at least partial removal from said seawater of said scale forming components and
producing a pre-treated feed water having a first concentration of scale forming
components lower than said feed water concentration of scale forming
components;
- distillation of said pre-treated feed water by a forward feed flow multi-effect
evaporator and producing main desalted water product WM having a desalted
water salinity lower than said original water salinity, and main brine having a
salt concentration of approximately 10%;
- producing from said main brine a more concenrated brine with increased salt
concentration of approximately 20%-22%; and
- crystallizing said more concentrated brine and obtaining at least one salt product
therefrom.
13. A method according to Claim 12, further comprising removing said scale
forming components by means of de-carbonization columns.
14. A method according to Claims 12 or 13, further comprising removing said scale
forming components by means of a reactor and a clarifier.
15. A method according to anyone of Claims 12 to 14, further comprising producing
said main brine by said evaporator.
16. A method according to anyone of Claims 12 to 15, further comprising providing
a concentrator.
17. A method according to Claim 16, further comprising producing said more
concentrated brine by said concentrator.

A system and method for desalination of seawater W having an original water salinity and a
original water concentration of scale forming components, the system comprising: a pre-treatment
sub-system for at least partial removal from said water W of said scale forming
components, producing thereby a pre-treated feed water having a first concentration of
scale forming components lower than said original concentration of scale forming
components; a forward feed flow multi-effect evaporator adapted for distillation of said pre-treated
feed water, producing thereby main desalted water product WM having a desalted
water salinity lower than said water salinity, and main brine having a salt concentration of
approximately 10%; a concentrator adapted for receiving therein said main brine and
concentrating it, producing thereby more concentrated brine with an increased salt
concentration of approximately 20%-22%, and releasing a first additional desalted water
product W1; and a crystallizer for receiving said more concentrated brine, adapted for
crystallization thereof to obtain at least solid salt products and releasing a second additional
desalted water product W2.

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Patent Number

279364

Indian Patent Application Number

1349/KOLNP/2011

PG Journal Number

03/2017

Publication Date

20-Jan-2017

Grant Date

19-Jan-2017

Date of Filing

30-Mar-2011

Name of Patentee

I.D.E. TECHNOLOGIES LTD.

Applicant Address

HAMATECHET STREET, P.O. BOX 5016, HASHARON INDUSTRIAL PARK, 60920 KADIMA (IL)

Inventors:

#	Inventor's Name	Inventor's Address
1	OPHIR, AVRAHAM	34 NAVE OVED STREET, 46602 HERZLIA (IL)
2	WEINBERG, JOSEPH	29 BRODEZKI STREET, 42408 NETANAYA (IL)
3	ROTSTEIN, YESHAYAHU	77/C' HERZEL ST. 44213 KFAR SABA (IL)

PCT International Classification Number

B01D 1/26

PCT International Application Number

PCT/IL2009/000864

PCT International Filing date

2009-09-06

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	61/136,425	2008-09-04	U.S.A.