Method for generating electrical power from municipal wastewater

Abstract

An electrical generating assembly 10 which may be selectively used in combination with and/or as part of a municipal wastewater treatment facility 12 and which allows the wastewater treatment facility 12 to generate electrical energy 48,62, 13 as received wastewater 14 is cleaned according to a plurality of diverse energy generating strategies.

Description

GENERAL BACKGROUND

1. Field of the Invention

The present invention generally relates to a municipal wastewater electrical power generating assembly and to a method for generating electrical power and, more particularly, to an assembly and to a method which allows for the efficient generation of electrical power and electrical energy from a wastewater treatment facility according to a variety of generating strategies which may be selectively used in a desired manner.

2. Background of the Invention

A wastewater treatment facility typically receives waste laden water based liquid (generally and most typically denoted as “wastewater”) and is adapted to and actually treats the contained waste by removing undesirable waste constituents from the received liquid (e.g., organic type constituents) and returns or generates or “creates” substantially “clean” water which may be further processed to create what is often referred to as “drinkable” Water. Typically, such a treatment facility is owned and operated by a municipality and the treated liquid which emanates from that municipality (i.e., the generated or produced “clean” water) is transmitted back to citizens or residents of that municipality.

While these wastewater treatment facilities do indeed desirably treat such waste liquid, they undesirably utilize a lot of electrical energy and the cost of such energy is increasing. Moreover the cost and use of such electrical energy for all purposes is vastly increasing throughout the world.

The present invention enhances the operational performance of such wastewater treatment facilities by allowing for the efficient generation of electrical power as part of the overall wastewater treatment process, wherein such generated electrical power may be used for a variety of purposes and in a variety of applications.

SUMMARY OF THE INVENTION

It is a first non-limiting object of the present invention to provide an assembly which may be used within a wastewater treatment facility and which allows for the generation of electrical power as part of the overall wastewater treatment process.

It is a second non-limiting object of the present invention to provide a method for generating electrical power as part of a wastewater treatment process.

It is a third non-limiting object of the present invention to provide an assembly and a method which is adapted to employ a plurality of diverse electrical energy generating strategies and to allow several or all or a selected singular strategy to be selectively employed.

According to a first non-limiting aspect of the present invention an assembly is provided for use in combination with a wastewater treatment facility of the type which receives waste containing liquid and which produces substantially clean water and waste, the assembly of the present invention including a first portion which selectively receives the substantially clean water and which selectively generates electricity by use of the received substantially clean water; a second portion which receives the waste and which selectively generates electricity by use of the received waste; and a third portion which controls the operation of the first and second portions, thereby controlling the generation of electricity by use of the waste containing liquid.

According to a second non-limiting aspect of the present invention, a method for generating electrical energy is provided. Particularly, the method includes receiving wastewater which comprises a combination of water and waste; removing the waste from the wastewater, thereby producing substantially clean water; causing the substantially clean water to flow through a first turbine assembly and to thereafter enter a retention pond, producing gas from the received waste; and using the gas to operate a second turbine assembly, wherein the first and second turbine assemblies are each adapted to selectively produce electrical energy.

According to a third non-limiting aspect of the present invention an assembly is provided for use in combination with a wastewater treatment facility of the type which receives waste containing liquid and which produces substantially clean water and waste, the assembly of the present invention including a first portion which selectively receives the substantially clean water and which selectively generates electricity by use of the substantially clean water; a second portion which receives the waste and which generates waste gas; a third portion which selectively receives the waste gas and which selectively generates electricity by use of the waste gas; a controller which is coupled to said first, second, and third portions and which controls the operation of the first, second, and third portions, thereby controlling the generation of electricity by use of the waste containing liquid.

According to a fourth non-limiting aspect of the present invention a method for generating electrical energy is provided. Particularly, the method comprises a plurality of electric energy generating strategies involving wastewater; and selectively utilizing the predetermined control strategies in a manner which allows a substantially constant amount of electric energy to be produced.

These and other aspects, features, and advantages of the present invention will become apparent from a reading of the detailed description of the preferred embodiment of the invention and by reference to the following drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram of the assembly and method for generating electrical power according to the teachings of the preferred embodiment of the invention; and

FIG. 2 is a flowchart illustrating the methodology of the preferred embodiment of the invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT OF THE INVENTION

Referring now to FIG. 1, there is shown an electrical power generation assembly 10 which is made in accordance with the teachings of the preferred, although non-limiting, invention and which is operatively deployed within and which operates in combination with and/or which forms a part of an overall wastewater treatment facility 12, such as but not-limited to a municipal wastewater treatment facility.

Particularly, as should be known to those of ordinary skill in the art, the wastewater treatment facility 12 receives wastewater 14 and produces water 16 which has a reduced amount of organic material. This “cleaned” water 16 (i.e., sometimes referred to as “substantially clean water) is typically sent to a holding tank assembly 48 which may agitate the water and/or further process the water, before it is deemed to be “drinkable” or potable. The substantially “drinkable” water 5 is then transmitted and/or delivered to the various residents, citizens, and business/other entities which operate within that municipality. The combination of the organic removal assembly and the holding tank assembly 30 cooperatively form the wastewater treatment facility 12, according to one non-limiting embodiment.

The treatment system 12 includes an organic removal assembly 18 (such as an agitator assembly) which is adapted to receive the wastewater 14 and to selectively remove the organic material from the received wastewater 14, thereby creating substantially clean water 16. It should be appreciated that the present invention is independent of the actual organic material removal process and that substantially any desired organic removal process may be utilized, of which there may be many. Importantly, according to the known and utilized strategies, the substantially clean water 16 is transmitted, in one noon-limiting embodiment, to holding tanks 30 while the removed organic material 36 is typically discarded.

According to the teachings of the present invention, the substantially clean water 16, on its way to the holding tanks or pond 30, is made to first traverse a first turbine assembly 40 and such traversal causes the generation of electrical energy or electrical power 48. That is, the turbine assembly 40 includes the combination of a turbine 101 and a generator 102 and the moving water 16 causes the blades of the turbine 101 to move, and such movement is transferred to the generator 102 which causes the generator to generate electricity or electrical power 48. The obtained organic material 36 is transmitted, in one non-limiting embodiment, to a digester assembly 50 (e.g., comprising in one non-limiting embodiment, a plurality of holding tanks) and the organic material subsequently produces digester gas 55. This digester gas 55 is then used to operate a second turbine assembly 60 which may be substantially similar to assembly 40 and which produces electrical power 62 (e.g., the produced gas is made to turn/move the blades of the turbine of this second assembly 40, which causes concomitant movement within a second generator which is effective to produce electricity or electrical power 62). Both of the turbine assemblies 40, 60 operate under the direction and control of controller assembly 70 and may each be selectively connected to the power grid of the municipality where the generated electrical power 48,62 may be sold and utilized. Alternatively the produced electrical power 48, 62 may be utilized by the wastewater treatment plant itself.

Moreover, the organic material may alternatively be utilized/processed as fertilizer and the digester gas may be transmitted to a heat exchanger assembly and the produced heated air may be used within/outside of the plant 12.

Alternatively or concurrently with the foregoing operation of the turbine assemblies, 40, 60, some or all of the organic material 36 may be transmitted to a furnace assembly 100 where the received organic material 36 is combusted and made to produce steam 102. The steam 102 may then be selectively communicated to a third turbine assembly 110 (which may be substantially similar to assembly 40) and the gas 102 causes the blades of the turbine portion of the third turbine assembly 110 to move, which in turn causes the generator portion of the third turbine assembly 110 to generate electricity 13. Alternatively, the created gas 102 may be selectively communicated to the second turbine assembly 60 and/or to the first turbine assembly 40 which causes this turbine assembly 60 to produce electricity.

It should be appreciated that the foregoing electric power generator system 10 has three separate and unique power generator strategies (e.g., each strategy, in one non-limiting embodiment uses a unique turbine assembly 40, 60, 110) which may be singularly or cooperatively employed in any manner (e.g., each strategy may respectively and singularly be utilized, any two strategies may be utilized, or all three strategies may be utilized as desired).

It should further be appreciated that the control assembly 70 may comprise a computer which is operable under stored program control and is coupled to a first control valve 120, a second control valve 130, and a third control valve 140. Particularly, the control assembly 70 is coupled to valve 120 by bus 119 and by use of valve 120, assembly 70 allows the substantially clean water 16 to either flow through the first turbine assembly 40 or to bypass the assembly and enter into holding tank assembly 30. If no water 16 flows trough assembly 40, electrical power 48 is not produced. The control assembly 70 is coupled to valve 130 by bus 131 and by use of valve 130, assembly 70 either allows or prevents the emitted gas 55 to enter the turbine assembly 60. If no gas 55 flows through assembly 60, no electrical power 62 is produced. The control assembly 70 is coupled to valve 140 by bus 141 and by the use of control valve 140, assembly 70 either allows or prevents material 36 from entering the furnace or combustion chamber 100. If no material 36 enters furnace 100, no electrical power 13 is produced. In this manner, the selective activation of the control valves 120, 130, 140 allows for the use of the diverse strategies and such use is important because there may be an interruption or uneven supply in the substantially clean water 16, and/or there occurs a fault in one or more of the turbine assemblies 40, 60,110, with such multiple strategies, electrical power, to some extent, may continue to be produced even if such a fault or interruption occurs. Moreover, the control assembly 70 may be programmed to provide a substantially constant amount of electric power. That is, in this production it is highly undesirable to have “spikes” (i.e., increases) or troughs (i.e., decreases) in the desired amount of electrical power production. The three strategies may be selectively employed by the controller assembly 70 to provide a substantially constant amount of electrical power. That is, controller assembly 70 constantly, in one non-limiting embodiment, monitors the amount of produced electrical power 48, 62, and 13 (by the use of a power meter assembly which is coupled to each of the turbine assemblies 40, 60, 110) and, through the control of valves, 120130, 140, selects which strategies to use and the respective duration of use, in order to maintain an overall constant amount of generated electrical power. In yet a further non-limiting embodiment, heat which is exhausted from the furnace assembly 100 may be used/sold to heat homes or other buildings. In yet another non-limiting embodiment, a business method is provided whereby the electric power generation assembly 12 is provided to a municipality and operated by a private entity which provides some of the produced electrical power to that municipality and sells the rest, thereby comprising a profitable business venture.

It is to be understood that the present inventions are not limited to the scope or content of the subjoined claims but that various modifications may be made without departing from the spirit and the scope of the various inventions which are set forth in the following claims.

Claims

1. A method for generating electrical energy from a wastewater treatment facility, comprising the steps of: receiving wastewater, said wastewater comprising a combination of water and solid waste;separating said solid waste from said wastewater, thereby producing substantially clean water;directing said substantially clean water flow through a hydraulic turbine assembly to produce electrical power;directing said substantially clean water to flow to a holding tank;selectively directing said solid waste to enter a digester assembly;producing a gas from said solid waste which has entered said digester assembly; andoperating a gas turbine assembly to produce electrical power.

2. A method for generating electrical energy as recited in claim 1, said method further comprising the steps of: monitoring the amount of electrical power generated by said hydraulic turbine; andmonitoring the amount of electrical power generated by said gas turbine.

3. A method for generating electrical energy as recited in claim 2, said method further comprising the step of: maintaining a predetermined constant total electrical power generated by selecting the operation of one of the hydraulic and gas turbines on the basis of the individual amount of electrical power generated.

4. A method for generating electrical energy as recited in claim 2, said method further comprising the steps of: selectively directing said solid waste to enter a furnace assembly;producing steam from combustion of said solid waste which has entered said furnace assembly; andoperating a steam turbine assembly to produce electrical power.

5. A method for generating electrical as recited in claim 4, said method further comprising the step of: monitoring the amount of electrical power generated by said steam turbine.

6. A method for generating electrical energy as recited in claim 5, said method further comprising the step of: maintaining a predetermined constant total electrical power generated by selecting the operation of one of the hydraulic, gas and steam turbines on the basis of the individual amount of electrical power generated.

7. A method for generating electrical energy from a wastewater treatment facility, comprising the steps of: receiving wastewater, said wastewater comprising a combination of water and solid waste;separating said solid waste from said wastewater, thereby producing substantially clean water;directing said substantially clean water flow through a hydraulic turbine assembly to produce electrical power;directing said substantially clean water to flow to a holding tank;selectively directing said solid waste to enter a furnace assembly;producing steam from combustion of said solid waste which has entered said furnace assembly; andoperating a steam turbine assembly to produce electrical power.

8. A method for generating electrical energy as recited in claim 7, said method further comprising the steps of: monitoring the amount of electrical power generated by said hydraulic turbine; andmonitoring the amount of electrical power generated by said steam turbine.

9. A method for generating electrical energy as recited in claim 8, said method further comprising the step of: maintaining a predetermined constant total electrical power generated by selecting the operation of one of the hydraulic and steam turbines on the basis of the individual amount of electrical power generated.

10. A method for generating electrical as recited in claim 8, said method further comprising the steps of: selectively directing said solid waste to enter a digester assembly;producing a gas from said solid waste which has entered said digester assembly; andoperating a gas turbine assembly to produce electrical power.

11. A method for generating electrical as recited in claim 10, said method further comprising the step of: monitoring the amount of electrical power generated by said gas turbine.

12. A method for generating electrical energy as recited in claim 11, said method further comprising the step of: maintaining a predetermined constant total electrical power generated by selecting the operation of one of the hydraulic, steam and gas turbines on the basis of the individual amount of electrical power generated.