Process for the treatment of water

Abstract

Waste water is treated by contacting it with sodium to form hydrogen which is then contacted with air in a combustion chamber to produce clean water and heat.

Claims

1. A process for treating waste water, comprising the step of: contacting the waste water with an alkali metal to form a hydrogen stream and alkali metal hydroxide; and combusting the hydrogen stream to produce clean water and heat; wherein the step of contacting the waste water with the alkali metal is carried out in a two phase liquid system which includes a lower layer comprising a mixture of alkali hydroxide and a water and an upper layer comprising a liquid which is immiscible in and lighter than water and which does not react with the alkali metal.

2. A process according to claim 1 further including the step of utilizing the heat to generate power.

3. A process according to claim 1 further including the step of electrolyzing the alkali metal hydroxide to form the alkali metal.

4. A process according to claim 1 wherein the alkali metal is sodium.

5. A process according to claim 1 further including the steps of: contacting the alkali metal hydroxide with an air stream containing carbon dioxide; and removing carbon dioxide from the air stream.

6. A process for generating hydrogen, comprising the step of contacting waste water with an alkali metal to form a hydrogen stream and alkali metal hydroxide wherein the step of contacting the waste water with the alkali metal is carried out in a two phase liquid system which includes a lower layer comprising a mixture of alkali hydroxide and a water and an upper layer comprising a liquid which is immiscible in and lighter than water and which does not react with the alkali metal.

7. A process according to claim 6 further including the step of electrolyzing the alkali metal hydroxide to form the alkali metal.

8. A process according to claim 6 wherein the alkali metal is sodium.

9. A process for the disposal of an alkali metal, comprising the step of contacting waste water with the alkali metal to form a hydrogen stream and alkali metal hydroxide wherein the step of contacting the waste water with the alkali metal is carried out in a two phase liquid system which includes a lower layer comprising a mixture of alkali hydroxide and a water and an upper layer comprising a liquid which is immiscible in and lighter than water and which does not react with the alkali metal.

10. A process according to claim 9 wherein the alkali metal is sodium.

11. A process according to claim 9 further including the steps of: contacting the alkali metal hydroxide with an air stream containing carbon dioxide; and removing carbon dioxide from the air stream.

Description

BRIEF DESCRIPTION OF THE DRAWING

(1) The preferred exemplary embodiment of the present invention will hereinafter be described in conjunction with the appended drawing, where the sole FIGURE is a schematic representing the process of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

(2) According to the present invention, a process and an apparatus the treatment of water is disclosed. Further a process and apparatus for the removal of carbon dioxide from the air utilizing and alkali hydroxide produced in the water treatment process is disclosed.

(3) Referring now to FIG. 1, waste water stream 1 is contacted with sodium feed 2 in a reactor 10 to generate hydrogen depicted as gas stream 12 and sodium hydroxide depicted as liquid stream 14. The reaction is carried out in a two liquid layer system, the first lower layer comprising a mixture of sodium hydroxide and water and the second upper layer comprising kerosene which is immiscible in water and which does not react with sodium.

(4) The reaction carried out in reactor 10 is represented by reaction 1, as follows:
2Na+2H.sub.2O.fwdarw.2NaOH+H.sub.2(Reaction 1)

(5) The reaction is very exothermic and the heat generated may ignite the hydrogen. For that reason the reaction is carried out in the two liquid layer system. Further, the reaction is controlled by having sufficient amount of sodium hydroxide in the water phase.

(6) Any other alkali metal which is lighter than water may be used in the place of sodium. Accordingly potassium, sodium, lithium, rubidium, and francium may be used to react with the water in the presence of the corresponding alkali hydroxide. Cesium may not be used because it is heavier than water. Further, any other liquid which does not react with the alkali metal and which is immiscible in and lighter than water may be used in the place of kerosene.

(7) Stream 12 containing the generated hydrogen flows to a combustion chamber 20 wherein it is contacted with air provided by air source 22 to generate steam withdrawn as stream 24 which is cooled in cooling stage 26 to form condensed clean water 28 which is drinkable and usable in other applications wherein clean water is required. The combustion is represented by Equation 2:
2H2(g)+O2(g).fwdarw.2H2O(g)(Equation 2)

(8) The heat generated from cooling the steam in cooling stage 26 is removed via heat stream 30 and is used in a steam turbine 32 to generate power 34 usable in the apparatus as described below.

(9) Stream 14 that contains sodium hydroxide flows to a Downs' cell 36 wherein the sodium hydroxide is liquified at a temperature of about 330 C. and voltage is applied to separate it by electrolysis to sodium and hydroxide ions. The sodium is separated and returned to reactor 10 via stream 2 to react with the water to form hydrogen. Stream 3 provides makeup sodium to reactor 10. Downs' cell is powered by power 34.

(10) In alternative embodiment of the present invention, a stream 50 containing sodium hydroxide is used to capture and remove carbon dioxide from air streams containing the same from industrial plants and other sources of carbon dioxide. Stream 50 flows to a carbon dioxide recovery stage 60 wherein the sodium hydroxide contacts an air stream 62 containing carbon dioxide to remove the carbon dioxide and dispose it accordingly. The method is outlined by Zeman and Lackner in F. S. Zeman; K. S. Lackner (2004). Capturing carbon dioxide directly from the atmosphere. World Resour. Rev. 16: 157-172.

(11) In that method, carbon dioxide is absorbed by an alkaline sodium hydroxide solution to produce dissolved sodium carbonate. The absorption reaction is a gas liquid reaction depicted below (Reaction 3):
2NaOH(aq)+CO2(g).fwdarw.Na2CO3(aq)+H2O(Reaction 3)

(12) The sodium carbonate is contacted with calcium hydroxide (Ca(OH)2) to generate sodium hydroxide and calcium carbonate (CaCO3) by the reaction depicted below (Reaction 4).
Ca(OH)2+Na2CO32.fwdarw.2NaOH+CaCO3(Reaction 4)

(13) The sodium hydroxide formed is transported to Downs' cell 6 via line 64 for further use in the process.

(14) The calcium carbonate is formed as a precipitate which is filtered from solution and thermally decomposed to produce gaseous CO2 depicted by Reaction 5:
CaCO3(s).fwdarw.CaO(s)+CO2(g)(Reaction 5)

(15) The thermal decomposition of calcite is preferably performed in a lime kiln fired with oxygen in order to avoid an additional gas separation step. The carbon dioxide produced flows via stream 66 to a storage facility or the like and can be sold to be used in several applications such as enhanced oil recovery applications or for sequestration into depleted oil reservoirs.

(16) Hydration of the lime (CaO) completes the cycle. Lime hydration is an exothermic reaction that can be performed with water or steam. Using water, it is a liquid/solid reaction as shown in Reaction 6:
CaO(s)+H2O(l).fwdarw.Ca(OH)2(s)(Reaction 6)

(17) Reactions 4, 5 and 6 are shown as taking place in stage 63 in FIG. 1.

(18) The process described above can be used for the safe disposal of alkali metals that generated as waste or otherwise in facilities such as nuclear plants. The alkali metal waste is reacted with water as shown in Reaction 1 followed by the remaining steps described above to generate hydrogen, etc.

(19) The following examples further illustrate the invention but are not to be construed as limitations on the scope of the invention contemplated herein.

Example 1

(20) A piece of pure sodium was added into a graduated cylinder which had tap water and kerosene liquid above the water. Sodium was heavier than the kerosene liquid but lighter than water which caused it to float at the interface between the water and the kerosene. The reaction was not very steady or controlled. The encapsulated sodium floated up in the liquid column until it liberated off all the hydrogen and then sank back to the interface. Even though the reaction was not steady or controlled and not ideal for full scale production, the hydrogen was generated without the usual and expected fire and explosion.

Example 2

(21) A piece of pure sodium was added into a graduated cylinder which had concentrated sodium hydroxide mixed with fresh water and liquid kerosene above the water. Because sodium is heavier than kerosene but lighter than sodium hydroxide and water mixture, it floated at the interface between them and did not go up and down. Thus, the reaction was more controlled than that in Example 1, something that was accomplished by controlling the pH of the water.

(22) While the invention is described with respect to specific embodiments, modifications thereof can be made by one skilled in the art without departing from the spirit of the invention. The details of said embodiments are not to be construed as limitations except to the extent indicated in the following claims.