DESALINATION METHODS AND DEVICES USING GEOTHERMAL ENERGY

Abstract

A method of and apparatus for desalinating sea water using geothermal energy. A low voltage (such as less than 0.9V) is applied to a hydrogen generating catalysts to generate hydrogen and oxygen, wherein geothermal heat is used as a heat source. The hydrogen and oxygen are used to drive a gas turbine to generate electricity. The oxygen and hydrogen are transported away and combusted to generate heat and pure water, as such salt are separated from the pure water.

Description

FIELD OF THE INVENTION

The present invention relates to hydrogen and oxygen production. More specifically, the present invention relates to hydrogen and oxygen production using geothermal heat, water, and an environmentally safe catalyst.

BACKGROUND OF THE INVENTION

Typical methods and devices for desalinating sea/salt water require much energy to push the salt water through an ion exchange membrane. Distillation of salt water is inefficient in terms of its energy use. More energy efficient methods and device for desalination are needed.

SUMMARY OF THE INVENTION

Methods of and apparatuses for producing H₂ and O₂ from salt water using geothermal heat are disclosed. In one aspect, the apparatus comprises a main reactor, a gas turbine, and a source of geothermal heat.

In one aspect, a method of desalination comprising applying a voltage to a solution containing sodium chloride and a hydrogen producing catalyst, generating an amount of hydrogen with the hydrogen producing catalyst, and generating an amount of pure water by combusting the amount of hydrogen and oxygen. In some embodiments, the method further comprises providing geothermal heat. In other embodiments, the voltage is equal or less than 1V. In some other embodiments, the solution comprises water having salt. In some embodiments, the solution comprises sea water. In some other embodiments, the hydrogen producing catalyst contains aluminium, silver, and copper. In some embodiments, the oxygen is generated by the hydrogen producing catalyst. In other embodiments, the method further comprises driving an electricity generating turbine using the hydrogen generated.

In another aspect, a hydrogen producing system comprises a non-acidic solution containing a hydrogen generating catalyst, wherein the hydrogen generating catalyst contains a charge-treated aluminium metal, a charge-treated copper metal, and a charged-treated silver metal, wherein the charge-treated aluminium, copper, and silver metals are treated by a voltage not less than 1V, and wherein the hydrogen generating catalyst is capable of generating hydrogen gas in a catalytic manner with an applied voltage no greater than 1V, an electric energy providing device, and a geothermal heating device providing heat to the non-acidic solution.

In some embodiments, the system comprises a light source. In other embodiments, the light source comprises LED. In some other embodiments, the light source provides lights having wavelengths approximately in the visible light region. In some embodiments, the geothermal heating device receives a amount of geothermal heat from the earth. In other embodiments, the hydrogen generating catalyst comprises aluminium hydroxide. In some other embodiments, the hydrogen generating catalyst comprises copper hydroxide. In some embodiments, the hydrogen generating catalyst comprises silver hydroxide. In other embodiments, the system further comprises a computer automating a transportation of the non-acidic solution.

In another aspect, a method of generating electricity comprises applying a voltage less than 1V to a solution having a catalyst, wherein the catalysts containing aluminium complex, cupper complex, and silver complex, and providing heat from a geothermal heat source to the solution. In some embodiments, the solution is a non-acidic solution. In other embodiments, the solution has a pH value equal or great than 7. In some other embodiments, the method further comprises turning a turbine to generate electricity by using one or more gases that are generated at the solution. In some embodiments, the method further comprises using the electricity generated as an energy source to be applied to the solution. In other embodiments, the one or more gases comprise hydrogen, oxygen, or a combination thereof. In some other embodiments, the method further comprises combusting the hydrogen and oxygen to generate heat and water. In some embodiments, the method further comprises transporting the heat and the water to add to the solution.

In another aspect, a hydrogen generating method comprises generating hydrogen gas and oxygen gas by applying a pulsed voltage less than 1V to a solution, wherein the solution containing a catalyst having aluminium, copper, and silver, and heating the solution by a geothermal heat and a heat generated by combusting the hydrogen gas and the oxygen gas.

In some embodiments, the method further comprises regenerating the catalyst by providing an amount of light. In other embodiments, the light comprises LED.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates a hydrogen producing system in accordance with some embodiments.

FIG. 2 illustrates another hydrogen producing system in accordance with some embodiments.

FIG. 3 is a flow chart illustrating a hydrogen producing process using geothermal as a heat source in accordance with some embodiments.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

FIG. 1 illustrates a hydrogen producing system 100 in accordance with some embodiments. The hydrogen producing system 100 is able to use geothermal heat as the heat source for chemical reactions. In some embodiments, the hydrogen producing system 100 comprises a reactor 102. The reactor 102 allows an active ion displacement reaction to occur. In some embodiments, the chemical reactions in the reactor 102 generate hydrogen gas and oxygen gas. Details of the compositions, starting materials, and catalysts that are used in the reactor 102 are described in the following. In some embodiments, the hydrogen gas producing reaction occurs in the reactor 102. A heat source 106, such as a geothermal source, having heat to be provided to the reactor 102. The geothermal source is able to provide/supply heat to the reactor 102. The geothermal heat is able to be pre-stored before providing heat to the reactor 102. A person of ordinary skill in the art appreciates that any other sources of heat from nature are within the scope of the present invention. The water source of the reaction is able to be from the water tank 101. The hydrogen producing reaction in the reactor 102 generates hydrogen gas 108 and oxygen gas 110. The hydrogen gas 108 and oxygen gas 110 are sent to drive a gas turbine 104 to generate electricity by using the gas pressure/gas flow generated at the hydrogen producing reaction. The hydrogen gas 108 and the oxygen gas 110, after passing through the gas turbine 104, are triggered to be combusted/reacted at a combustion chamber 112. The hydrogen gas is able to react with the oxygen gas by using electric sparks. Heat that is generated through reacting hydrogen gas 108 and the oxygen gas 110 is able to be transferred to a heat exchanger 114, which is able to be applied back to the reactor 102 for recycling and reusing the heat. The combustion reaction of the oxygen gas 110 and the hydrogen gas 108 produces pure water, which is able to be condensed and collected at the condenser 116, such that the system 100 is able to be used as a desalination device to produce pure water. In some embodiments, the water is able to be recycled back to the reactor 102, so no new water or external water is needed for continuously running the hydrogen producing reaction.

FIG. 2 illustrates a hydrogen producing system 200 in accordance with some embodiments. In some embodiments, the system 200 comprises a preparation reactor 203 and a main reactor 214. The main reactor 214 comprises a photochemical/oxidizer reacting device 232, and a thermal source 230, which is able to be a geothermal source. A hydrogen producing reaction is able to begin from preparing a solution 201 containing Al metal 202 (250 mg), Cu metal 204 (250 mg), Ag metal 206 (250 mg), a graphite electrode 212 and 1 liter of water 208 having 1.5% NaCl 210 by weight. A negative voltage −2.5V is applied to the graphite electrode 212 and a first positive voltage 1.7V is applied to the Al metal 202 for 15 minutes.

Next, the first positive voltage applied to the Al metal 202 is removed, and a second positive voltage of 1.4V is applied to the Cu metal 204 for 10 minutes while the negative voltage of −2.5V is applied to the graphite electrode 212. Next, the second positive voltage is removed from the Cu metal 204, and a third positive voltage of 1.0V is applied to the Ag metal 206 for 5 minutes with the negative voltage still applied to the graphite electrode 212. The temperature of the solution is maintained at 88° F. by controlling the heat source 230.

Next, the solution 201 is transferred to the main reaction vessel 214, so that the main reaction vessel 214 contains aluminium complex 215, copper complex 217, silver complex 220, sodium ions 222, and chloride ions 224 from the preparation vessel 203. Water is able to be input from a water tank 251. The term “complex” comprises all ligand states of a metal. For example, an aluminium complex includes Al³⁺ or Al(OH)_x, where the x represents the coordinated ligand numbers of the aluminium ion. In some embodiments, a voltage between 0.4V and 0.9V is applied to the cathode of the electrodes. In alternative embodiments, a voltage of 0.85V is applied to the cathode of the electrodes. In other embodiments, a voltage not exceeding 0.9V is applied to the cathode of the electrodes. Some experiments indicate that hydrogen production is reduced when a voltage exceeding 0.9V is applied. In some embodiments, the applied voltage of the anode is at 0V compared with a voltage on the standard hydrogen electrode. In some embodiments, the voltage is applied in a way that a negative charge is applied to the stainless steel electrode 216 and a positive charge is applied to the graphite electrode 218. A hydrolysis reaction begins to occur when sufficient voltage is applied, and hydrogen gas 236 is generated at the stainless steel electrode 216 when the voltage is applied to the stainless steel electrode 216 and the graphite electrode 218. While the hydrogen producing reaction is going, heat is provided through the heat source 230 and lightings 232 (such as, LED lights) are applied to the main reactor 214 for assisting a photolysis reaction.

Oxygen gas 240 and hydrogen gas 236 are output to the gas turbine 244 to generate electricity. The oxygen gas 240 and the hydrogen gas 236 are able to react at the combustion chamber 246 to generate electricity through a combustion reaction. The heat generated at the combustion chamber 246 is able to be collected at the heat exchanger 248 and the water generated is able to be collected at the condenser 250. The water collected at the condenser 250 is able to be used as pure water or recycled back to the main reactor 214. The whole reaction is able to be automatically controlled by a computer system to maintain a continuous operation of the reaction, including maintaining an optimized reaction condition for the hydrogen producing reaction.

FIG. 3 is a flow chart illustrating a hydrogen producing process 300 using geothermal as a heat source. The process 300 is able to begin from preparing a reaction solution at Step 302. The solution preparation is able to be performed at the preparation reactor 203 (FIG. 2) with the procedures described above. At Step 304, voltage is applied to the solution to generate hydrogen gas and oxygen gas. At Step 306, the hydrogen gas and the oxygen gas are sent to a gas turbine to generate electricity. At Step 308, the hydrogen gas and the oxygen gas are combusted to generate heat and pure water. At Step 310, the heat and water is recycled back to the main reactor for running the reaction. All the steps that are contained in the methods/procedures described above are some embodiments of the present application. All the steps are optional and all the steps when applicable are able to be performed in any sequences or orders. Additional steps are also able to be added when a person skilled in the art deems proper.

Geothermal Heat Storing and/or Desalination Devices and Systems

In some embodiments, the systems and methods use the hydrogen and/or oxygen as an intermediate energy storage device. In other words, it can be used as a device or method for storing heat from a geothermal source. Heat in general is a type of energy that is more difficult to store than storing energy in a form of gases, which are more stable and storable when compared with heat. Here, the hydrogen and oxygen gases are able to be generated using thermal energy, which are used to drive one or more gas turbines via gas flow or pressure difference to generate electricity. Next, the hydrogen and oxygen are combusted to release their potential energy and make water. Since hydrogen and oxygen are generated and consumed without additional gases generated or consumed, the hydrogen and oxygen are able to be used as a form of energy storage.

Additionally, the systems and devices are used as a desalination device or method, wherein a geothermal heat is used to perform the process. Since the unique property of the hydrogen generating catalysts (e.g., an aluminium complex, a copper complex, and a silver complex), a low temperature (e.g., below 40° C.) is used to perform the hydrogen generating reaction. In some embodiments, the low temperature (e.g., below 40° C.) is used for the entire reaction, including the catalysts preparation and hydrogen generating catalysts regeneration reaction. In some embodiments, 31° C. is the temperature that is used for generating the hydrogen gas. In some embodiments, an amount of sea water is used as a source of the water supply. By using the desalination methods and devices described herein, salts that are contained in the sea water are left at the main reactor and pure water is generated by combining and combusting the hydrogen and oxygen gases generated. A regular cleaning or removal of the salts at the reactor where the salts are left is performed (e.g, once a day, once a week, or any other predetermined duration). As described above, the methods and devices disclosed herein are configured to generate hydrogen/oxygen gases, serve as a desalination device, and/or a geothermal storage using an amount of the geothermal heat, sea water, or a combination thereof.

In one of the exemplary cases as illustrated by the FIG. 2, a main reactor 214 is coupled with or located at or near a source of the geothermal heat 230. In some embodiments, the main reactor 214 is a geothermal power plant. An amount of the geothermal heat 230 is conducted via one or more thermal paths, such as by direct contact, to be transferred to the main reactor 214, such as a wall or a bottom surface of a reactor. In some embodiments, a continuous supply of the geothermal heat 230 is provided to the main reactor 214.

In the reactor, one or more of the light sources 232 (e.g., LED light) are in the main reactor 214, so that a regeneration reaction of the hydrogen generating catalysts can be performed inside the main reactor 214. In some embodiments, the light sources 232 are included in a separate chamber, reactor, or container, so that the regeneration of the hydrogen generating reaction can be performed in a regeneration reactor that is separated or independent from the solution of the main reactor 214. In some embodiments, an additional heat source, such as a heating coil heater, is used to provide heat needed for the regeneration reaction of the hydrogen generating catalysts.

In some embodiments, the preparation of the hydrogen generating catalysts is able to be followed by the description in the FIG. 2 and its accompanying text. In some embodiments, the preparation of the hydrogen generating catalysts including applying a first voltage to a graphite electrode (e.g., a voltage greater than −2.0V, such as −2.0 to −2.5V) and one or more voltages to the metal catalysts (e.g., aluminium metal, copper metal, and silver metal respectively). In some embodiments, the voltage that is applied to the metals is greater than 1V. In some embodiments, the voltage that is applied to the metals is 0.9V or greater (e.g., 0.9V-1.9V). For example, a voltage of 1.1V-1.9V, 1.7V, or 1.5-2.0V is applied to the aluminium metal. A voltage of 1.1V-1.9V, 1.4V, or 1.2-2.0V is applied to the copper metal. A voltage of 1.1V-1.9V, 1.4V, or 1.2-2.0V is applied to the silver metal.

In some embodiments, a voltage for generating hydrogen gas, oxygen gas, or both is applied to the electrodes/solution containing the hydrogen generating catalysts. In some embodiments, the voltage for generating the above mentioned gases is configured to or limited to a voltage that is equal or below 0.9V. For example, a voltage between 0.4V to 0.9V is applied to the electrodes and solutions for generating a continuous stream of hydrogen gas and oxygen gas. In some embodiments, a voltage of 0.85V is configured to be applied to the electrodes for driving the catalysts to produce the gases mentioned above.

The systems and procedures are able to be utilized to produce electricity, hydrogen, oxygen, pure water on-demand using a geothermal heat. In operation, a low voltage (such as less than 0.9V) is applied to a prepared solution having active catalysts (hydrogen generating substances) to generate hydrogen and oxygen. The hydrogen and oxygen are used to move a gas turbine to generate electricity. The oxygen and hydrogen are combusted to generate heat and pure water. This process is advantageous in many aspects including desalinating salt/sea water using a geothermal heat.

The present invention has been described in terms of specific embodiments incorporating details to facilitate the understanding of principles of construction and operation of the invention. Such reference herein to specific embodiments and details thereof is not intended to limit the scope of the claims appended hereto. It will be readily apparent to one skilled in the art that other various modifications may be made in the embodiment chosen for illustration without departing from the spirit and scope of the invention as defined by the claims.

Claims

1. A method of desalination using geothermal heat comprising: a. performing a catalytic electrolysis reaction in a reaction vessel by applying a voltage to a solution containing sea water and a hydrogen generating catalyst, wherein the sea water contains amount of sea salt, and wherein the hydrogen generating catalyst contains aluminium, copper, and silver;b. applying an electric voltage to the hydrogen generating catalyst between 0.4V to 0.9V for generating an amount of oxygen and an amount of hydrogen; andc. generating an amount of pure water by combusting the amount of oxygen and the amount of hydrogen.

2. The method of claim 1, further comprising providing an amount of geothermal heat to the reaction vessel.

3. The method of claim 1, further comprising leaving the salt in the solution.

4. The method of claim 1, wherein the electric voltage is 0.85V.

5. The method of claim 1, further comprising driving an electricity generating turbine using the hydrogen, the oxygen, or both.

6. The method of claim 1, further comprising separating the pure water generated and an amount of heat generated, wherein the pure ware and the heat are generated through a combustion reaction of the hydrogen and the oxygen.

7. The method of claim 6, wherein the water is condensed using a condenser.

8. The method of claim 6, wherein the heat is collected using a heat exchanger.

9. The method of claim 6, further comprising separately recycling back the heat and the water to the reaction vessel.

10. The method of claim 1, wherein the solution is a non-acidic solution.

11. A desalination system comprising: a. a hydrogen generating catalyst in a reaction vessel configured to convert water into hydrogen and oxygen when a voltage between 0.4V to 0.9V is applied, wherein the hydrogen generating catalyst comprises aluminium, copper, and silver;b. a combustion vessel for generating water vapor and heat of combustion by combusting the hydrogen and oxygen;c. a condenser for condensing the water vapor into water; andd. a heat exchanger for collecting the heat of combustion.

12. The system of claim 11, further comprising a gas turbine fluidically connected between the reaction vessel and the combustion vessel.

13. The system of claim 11, further comprising a geothermal heat source configured to transfer geothermal heat to the reaction vessel.

14. The system of claim 11, further comprising a light source configured to regenerate the hydrogen generating catalyst.

15. The system of claim 11, further comprising a light source configured to generate a wavelength that reduces an oxidation state of silver oxide, copper oxide, or both, wherein the silver oxide and copper oxide are generated from the silver and the copper.

16. A method of storing an amount of energy comprising: a. storing an amount of energy including an amount of geothermal heat, an amount of electricity, or both in a reaction vessel by converting an amount of water into hydrogen and oxygen;b. transporting the hydrogen and oxygen away from the reaction vessel; andc. releasing the amount of energy by combusting the hydrogen and oxygen.

17. The method of claim 16, wherein the water comprises sea water.

18. The method of claim 16, further comprising driving a gas turbine using the hydrogen, the oxygen, or both.

19. The method of claim 16, wherein the electricity is provided in a voltage between 0.4V to 0.9V to a solution.

20. The method of claim 19, further comprising performing a electrohydrolysis reaction using a hydrogen generating catalyst containing aluminium, copper, and silver.