ZA200908980B - Process for the generation of algal oil and electricity from human and animal waste, and other hydrocarbon sources - Google Patents

Description

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PROCESS FOR THE GENERATION OF ALGAL OIL AND ELECTRICITY FROM HUMAN

AND ANIMAL WASTE, AND OTHER HYDROCARBON SOURCES

Field of the Invention

[0001] The invention is a process that facilitates the generation of electricity and algal oil from human and animal waste, and other hydrocarbon sources. The process facilitates the capture and recycling of all the carbon dioxide produced via algal aquaculture.

Background

[0002] There is a growing worldwide demand for a transformation in the production of energy, from fossil fuels to renewable resources and for a concurrent reduction in the emission of pollutants. Different enabling technologies such as wind power, geothermal, hydroelectric, solar, tidal, and various agricultural technologies have been developed to harness energy with varying degrees of success and various strategies have been developed to curb pollutants; however a commercially viable and intrinsically safe method has yet to be developed. This invention describes a process that has the potential to deliver renewable energy competitively with no pollutant emissions.

[0003] The use of animal and human waste for the generation of useful energy has been investigated extensively and is currently pursued as a commercial activity in many countries of the world. Various patents have been issued for processes that enable these objectives.

Nielsen et al (US Patent 2009/0064581A1) for example recently published a paper describing the use of plasma assisted destruction of municipal waste stream reaction residues. The gasification process (via various combustion methods including plasma torch) is currently employed in commercial applications particularly in Japan, where landfill disposal of waste is expensive due to the limited availability of space. The gasification process produces a synthesis gas containing carbon monoxide, carbon dioxide, water, and hydrogen. The synthesis gas is often combusted in combined heat and power (CHP) plants. 1:40099\50006\ZA PTO\091208 dat.patapps.doc

[0004] Removal of hydrogen from hydrogen rich streams has been widely reported using a variety of mechanisms, the most prevalent being Pressure Swing Adsorption (PSA) and more recently the use of membrane technology. Membrane separation techniques employ a variety of membrane materials amongst which palladium or palladium alloys are the most prevalent.

Some, as in Munschau et al (US Patent 2008/0000350 A1) incorporate the simultaneous removal and production of hydrogen via the water gas shift reaction (WGS):

[0005] CO + HO « CO, +H, Equation 1: Water Gas Shift Reaction

[0006] Munschau et al have reported an invention that incorporates the use of a catalyst deposited on the outer surface of the membrane to promote the water gas shift reaction and simultaneously allow the adsorption and removal of the hydrogen on the membrane surface. As the catalyst is poisoned by small amounts of sulphur, the use of these membranes is typically restricted to streams with sulphur concentrations of less than 20ppm.

[0007] The sequestration of carbon has received much recent attention and papers discussing algae aquaculture as a viable method have been published extensively. So has the treatment of wastewater using aerobic and anaerobic photobioreactors. Patents and other papers on both topics have been summarized by Elefritz et al (US Patent 7,455,765).

[0008] Lewnard et al (US Patent Appin. No. 2008/0178739) provide a comprehensive review of both open and closed system designs, as well as a hybrid method for cultivating algae in large closed spaces. The main issues cited by most authors are the propensity for contamination in open systems as well as a fairly low yield in terms of algal growth per unit land area compared to closed systems which have the comparative high capital cost per unit of land area. Closed systems have the advantage of increased carbon dioxide availability. Freeman (US Patent

Appin. No. 2008/0254529) describes a process whereby liquid culture mediums are exposed to closed carbon dioxide/air mixtures. Whitton (US Patent Appin. No. 2008/0286851) describes a flexible integrated closed system constructed of thin plastics which can potentially be folded up and transported to different sites or mounted on earthen bearms. The inclusion of gas spargers 1:40099\50006\ZA PTO\091208.dat.patapp$.doc is discussed. Howard et al (US Patent 2008/0299643) discloses a variant on the hybrid open/closed system with plastic pond covers and the introduction of diffused CO,.

Summary of the Invention

[0009] In the process described, moist waste solids are delivered to a pyrolysis unit (pyrolysis is the chemical decomposition of a substance by heating) employing one or more gas plasmolysis torches (plasmolysis is the chemical decomposition of matter employing high temperature gas plasma). The moist solids have been macerated to a suitable particle size fraction and, in the moist condition, constitute a paste. The paste is introduced into the pyrolysis chamber through either 1) concentric cylinders (the “waste feed former”) forming a paste cylinder with an internal : diameter greater than that of the plasmolysis torch external diameter or 2) through a feed tube : in the form of a solid cylinder with two or more plasmolysis torches arranged so that the flames impinge on the cylinder at an acute angle to the axis of the cylinder. In the case of the concentric cylinder feed, a plasmolysis torch is situated inside the paste cylinder at a sufficient height above the waste former so as not to cause any thermal damage of the equipment.

Secondary torches are placed outside of the paste cylinder such that the combined effect of the plasmolysis torches completely renders the waste into a gaseous product stream. Other gas inlet nozzles allow gas into the chamber in sufficient quantities that all suspended solids are entrained. The gases flow through the radiant heat exchanger which conveys energy to superheated steam. The steam drives a steam turbine and is condensed and recycled.

Following the radiant heat exchanger, the gases flow through a particle filter (which may be a centrifuge or bag filter or other suitable device known in the art) and into a combined secondary heat exchanger and catalytic converter. In this unit, further energy is extracted from the gases and water is converted to hydrogen via the water gas shift reaction. Methane is converted to carbon monoxide and hydrogen via the steam reformer reaction: :

[0010] CH, + HO «& CO + 3H, Equation 2: Steam Reformer Reaction

[0011] The reacted gases flow to a condensing heat exchanger wherein water is condensed and removed. The remaining gases are compressed in a three stage reciprocating compressor with interstage cooling and interstage removal of hydrogen via membrane separation. The interstage removal of hydrogen is incorporated in this invention. The final stage of compression 1:40099\50006\ZA PTO\091208 dat patapps.doc

EER ©2009/0894g increases the partial pressure of the water vapour and carbon dioxide to such a degree that upon cooling in the post compression heat exchangers the water vapour condenses and with further cooling the carbon dioxide subsequently liquefies. The liquefied carbon dioxide is stored in a high pressure storage tank. The residual gas stream is recycled to the pyrolysis chamber and to the plasmolysis torches. Carbon dioxide from the storage tank is expanded through a heat exchanger (which may be situated in a cold storage chamber) and delivered to the in line mixers for mixing with the algal aquaculture water feed during daytime operation.

[0012] The algal aquaculture feed stream is heated by the condensate steam from the process.

[0013] In the process described, carbon dioxide containing gas is injected into sufficient water under pressure to dissolve the carbon dioxide using in line mixers. Carbon Dioxide rich water is pumped to a Plastic Disposable Reactor (“PDR”) train, consisting of multiple units of the PDRs. ~The PDRs have been inoculated with and contain growing algae. The nutrient rich waters are fed upwards at low linear velocities through the PDRs and the resultant oxygen enriched water is drawn through a filter at the top of the PDR. The design of the filtration device and its fixture - to the PDR is incorporated in this invention. The water is preheated to between about 24°C and about 32°C for optimal algae growth. (This temperature may change for other species of microbes). The internal diameter of the PDR may vary from just greater than 0 to about 5 or more inches but is not limited to this upper limit. The height of the PDR may vary from just greater than 0 to about 24 or more feet but is not limited to this upper limit. The wall thickness of the PDR may vary from just greater than 0 to about 74 inch or more but is not limited to this upper limit. The thickness of the reactor wall is determined by the design operating pressure, the internal diameter and height of the vessel using typical engineering considerations. The inlet and exit of the PDR may have an internal pipe thread, an external pipe thread, or an external tube connector. This may be Imperial (BSP), metric (ISO), or US National Pipe Thread (NPT) and may be more or less than the typical 1 inch diameter. The design of the PDR and the filtration device is incorporated in the invention. The material of choice for the PDR for the purpose of aquaculture of algae is polyethylene teraphthalate (PET); however the PDR may be made of other suitable materials including, but not limited to, clear polyvinyl chloride (PVC),

Polypropylene (PP), polyethylene (PE), high density polyethylene (HDPE), cross linked polyethylene (PEX), clear polycarbonate and other plastics. 1:40099\50006\ZA PTO\091208.dat.patapp5.doc

[0014] FIGURE 3 shows a plant layout which removes carbon dioxide from an incoming gaseous stream by dissolution in water at ambient or elevated temperature and pressure. The carbon dioxide rich water stream is conveyed through a series of three way ball valves (all valves with the exception of valve 3 which is a flow control valve) to the PDR units. In train 1 the valves are configured to allow the carbon dioxide rich water stream to pass upwards through the PDR train containing algae. The algae in the course of photosynthetic metabolism convert the carbon dioxide to various complex organic molecules and oxygen. The oxygen (dissolved and gaseous) is conveyed from the algae by the continued upward motion of the water.

[0015] In the second PDR train, the valves are configured such that potable water is fed to the : top of the PDR train allowing water and algae to be drawn from the bottom of the train and “harvested.” Once a fraction (in one embodiment, but not limited to, about one-half) of the algae has thus been withdrawn from each PDR, the valves are reconfigured to allow either carbon dioxide enriched water or potable water (depending on the light cycle — i.e. either day or night) up through the PDR. A further embodiment of the described operation allows for the use of a bleaching agent in conjunction with potable water to clean the interior surface of the PDRs.

Once this cycle has been completed, the cleaned PDRs will have to be re-inoculated with growing algae. This cleaning is helpful for continued maximum availability of light throughout the

PDR. After a period of time has elapsed, wherein the reactors may need to be replaced, the ‘reactors are disconnected from the train and replaced with new reactors. The old reactors may be washed and sent for recycling. The number of PDRs in a train and the number of trains employed for any given site will depend on various factors including, but not limited to, the quantity of gas to be treated, the availability of land space, the size distribution of the PDR units and the climatic conditions where the facility is to be situated.

[0016] FIGURE 4 shows a PDR with the filtration mechanism attached. The filtration device is a porous filtration medium in the shape of a plug that is affixed to the tube which is fitted into the interior thread of the PDR. The bottom of the PDR is affixed to the fluid conveying pipe by means of a suitable sized male threaded connection and flexible hose. FIGURE 5 shows a

CC LM0099\50006ZA PTO\091208 dat patapp5.doc

[ series of connected PDRs forming a “Train.” The trains are suspended by external supports which attach to the top water conveying pipe.

[0017] Oxygenated water from the PDRs flows to a degassing reservoir where entrained oxygen is released. The oxygen is combusted in the Gas Turbine Unit and the plasmolysis unit.

Degassed water from the reservoir is pumped back to the static in line mixers.

Brief Description of the Drawings

[0018] Further features, benefits and advantages of the invention will become evident from the following description of exemplary embodiments with reference to the drawings, in which: :

[0019] FIGURE 1 shows a schematic of the plasmolysis unit waste feed former; . [0020] FIGURE 2 shows a process flow diagram for the gasification of waste, the generation of electricity and the dissolution of carbon dioxide in water,

[0021] FIGURE 3 shows a process flow diagram for the removal of carbon dioxide from a carbon dioxide rich stream and subsequent treatment of the carbon dioxide saturated or partially saturated water in two trains of PDRs;

[0022] FIGURE 4 shows a detailed cross section of a PDR; and,

[0023] FIGURE 5 shows a schematic of a PDR train.

Detailed Description

[0024] FIGURE 1 shows one embodiment of a plasmolysis unit waste feed former. The waste feed is introduced from the waste solid maceration tank by the action of a mechanical auger and/or a positive displacement device that allows delivery to the unit at an operating pressure of between 0 to 10 bar (g). The waste (in the form of a paste) is fed through the delivery system to a cylindrical device resulting in a continuously formed cylinder of paste that moves upwards at a specified linear velocity. The cylinder may surround a primary gasification torch or the cylinder may be solid and may also be fired upon by two or more secondary plasmolysis torches, 1:40099\50006\ZA PTO\091208.dat.patapp5.doc situated externally to the cylinder and at such impingement angles as to optimally and completely gasify the waste feed cylinder.

[0025] FIGURE 2 shows one embodiment of a plant layout which conveys waste from the maceration tank to a plasmolysis combustion furnace. In the furnace, secondary gas inlet nozzles allow sufficient gas to circulate upwards in the gasification unit thereby retaining any suspended solids (carbon and ash) that form in the plasmolysis of the waste and generate a circular flow path for maximum residence time within the radiant heat exchanger. FIGURE 2 shows a process flow diagram for the transport of the moist waste solid feed to plasmolysis unit, Co gasification of the waste solid stream, generation of superheated steam in the radiant section of the gasification unit, generation of electricity from the steam, recirculation of condensate steam, convection of the plasmolysis unit exhaust through a suitable device to a secondary heat exchanger and catalytic converter, to a three stage reciprocating compressor with interstage hydrogen extraction and cooling, to condensing heat exchangers where water condenses, the residual gases are subsequently cooled and carbon dioxide condenses and is stored in a high pressure tank, the residual gases from the carbon dioxide condenser are split into two streams — one being a gas turbine fuel feed and the other a recycle stream to the plasmolysis unit. Gas turbine exhaust is injected into the algae aquaculture feed stream which flows into a degassing chamber, releasing entrained gases (nitrogen and oxygen) to atmosphere. Carbon dioxide and residual water from the high pressure carbon dioxide storage tank are passed through an expansion valve and a heat exchanger (which may be enclosed by a cold storage unit) and injected into the algae aquaculture feed stream. The operating pressure of the algae aquaculture feed stream and algae aquaculture unit may be 1 or more bar absolute.

[0026] Hydrogen generated by the process as well as the gas turbine fuel feed are combined and combusted in the gas turbine unit to generate electricity.

[0027] Algae extracted from the algae aquaculture unit is dewatered and pressed to extract algae oil (“algal oil’) which may be used in a variety of processes including conversion to biodiesel using conventional methods known in the art. The pressed algae solids may be returned to the waste macerator for reprocessing or used for other purposes.

[0028] The above examples have been depicted solely for the purpose of exemplification and are not intended to restrict the scope or embodiments of the invention. The invention is further illustrated with reference to the claims that follow thereto. [:\40099N\50006\ZA PTO\091208.dat.patappS.doc

' w ’

[0029] Other than in the operating examples, or where otherwise indicated, all numbers expressing quantities of ingredients, reaction conditions, and so forth used in the specification and claims are to be understood as being modified in all instances by the term "about."

Accordingly, unless indicated to the contrary, the numerical parameters set forth in the following specification and attached claims are approximations that may vary depending upon the desired properties sought to be obtained by the present invention. At the very least, and not as an attempt to limit the application of the doctrine of equivalents to the scope of the claims, each numerical parameter should at least be construed in light of the number of reported significant digits and by applying ordinary rounding techniques.

[0030] Notwithstanding that the numerical ranges and parameters setting forth the broad scope of the invention are approximations, the numerical values set forth in the specific examples are reported as precisely as possible. Any numerical value, however, inherently contain certain errors necessarily resulting from the standard deviation found in their respective testing measurements.

[0031] The invention has been described with reference to several embodiments. Obviously, modifications and alterations will occur to others upon a reading and understanding of the specification. It is intended by applicant to include all such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof. :

[0032] Having thus described the invention, it is now claimed: 1°\4009NS0006\ZA PT0\091208 dat patappS doc

Claims (10)

HIM 20 Hl 09/08980 What is claimed is:

1. A method for the generation of algal oil and electricity, the method comprising the steps of: combining and macerating various moist hydrocarbon wastes into a paste; delivering the paste to a pyrolysis unit, the pyrolysis unit having at least one gas plasmolysis torch having an external diameter, wherein the paste is delivered into the pyrolysis unit through concentric cylinders forming a paste cylinder with an internal diameter greater than that of the plasmolysis torch external diameter, wherein at least a second torch is located outside of the paste cylinder such that the plasmolysis torches completely renders the paste into a gaseous product stream; : : allowing gas into the unit, via at least one gas inlet nozzle, in sufficient quantities that all : suspended solids are entrained, wherein the gas flows through a radiant heat exchanger which _ conveys energy to superheated steam, wherein the steam drives a steam turbine and is condensed and recycled, : allowing the gaseous product stream to flow through a suitable filter device and into a combined secondary heat exchanger and catalytic converter, wherein further energy is extracted from the gaseous product stream and water is converted to hydrogen via a water gas shift reaction; allowing the reacted stream to flow to a three stage reciprocating compressor with interstage membrane hydrogen extraction following at least a first stage of compression; - allowing any remaining gaseous stream to pass through a third stage of compression, cooling, condensing, and storing the carbon dioxide in a high pressure tank; : allowing any remaining gaseous stream to be split, one part being combusted in a gas turbine and the other part being recycled to the plasmolysis unit; allowing exhaust from the gas turbine unit to be injected into an algae aquaculture feed stream which flows to a degasification chamber, the released gas being allowed to vent to atmosphere; allowing carbon dioxide and residual water from a high pressure storage tank to be expanded, passed through the heat exchanger and injected into the algae aquaculture feed stream using in line mixers for mixing with the algal aquaculture water feed; and, allowing the algal aquaculture feed stream to be sent to an algal aquaculture unit to facilitate the growth of the algae and carbon sequestration. [N\4009N50006\ZA PTON09 1208 .dat.patappS.doc

' 4-4 C2 The method of claim 1, wherein the step of delivering the paste to a pyrolysis unit, the pyrolysis unit having at least one gas plasmolysis torch having an external diameter, wherein the paste is delivered into the pyrolysis unit through concentric cylinders forming a paste cylinder with an internal diameter greater than that of the plasmolysis torch external diameter, wherein at least a second torch is located outside of the paste cylinder such that the plasmolysis torches completely renders the paste into a gaseous product stream comprises: delivering the paste to a pyrolysis unit, the pyrolysis unit having at least one gas plasmolysis torch, wherein the paste is delivered into the pyrolysis unit through a tube forming a : solid cylinder of the paste and at least two plasmolysis torches are located outside of the paste cylinder with the flames impinging at an acute angle to the axis of the cylinder such that the combined effect of the plasmolysis torches completely renders the waste into a gaseous product stream.

3. A method for the generation of algal oil and electricity, the method comprising the steps of: producing a paste from hydrocarbon waste; delivering the paste to a pyrolysis unit, the pyrolysis unit having at least one gas plasmolysis torch; rendering the paste into a gaseous product stream; allowing the gaseous product stream to flow through a suitable filter device; : extracting energy from the gaseous product stream and converting water to hydrogen via a water gas shift reaction; : allowing the reacted stream to flow to a reciprocating compressor; allowing any remaining gaseous stream to pass through compression, cooling, condensing, and storing carbon dioxide in a high pressure tank; allowing any remaining gaseous stream to be split, one part being combusted in a gas turbine and the other part being recycled to the plasmolysis unit; injecting exhaust gas into an algae aquaculture feed stream which flows to a degasification chamber; and, allowing carbon dioxide and residual water from a high pressure storage tank to be expanded, passed through the heat exchanger and injected into the algae aquaculture feed stream thereby delivering a purge stream to in line mixers for mixing with the algal aquaculture water feed. 1:40099\50006\ZA PTO\091208 dat patappS.doc

4, An apparatus for facilitating the generation of energy from solid waste, the apparatus comprising: a pyrolysis unit, the pyrolysis unit having at least one gas plasmolysis torch, wherein the pyrolysis unit has concentric cylinders forming a paste cylinder with an internal diameter greater : than that of a plasmolysis torch external diameter; : . at least one gas inlet nozzle operatively connected to the pyrolysis unit; a radiant heat exchanger operatively connected to a steam turbine; a filter device operatively connected to the radiant heat exchanger; : : a convective heat exchanger operatively connected to the filter device; : a condensing heat exchanger operatively connected to the convective heat exchanger; a three stage reciprocating compressor with interstage membrane hydrogen separation and cooling devices operatively connected to the condensing heat exchanger, wherein the condensing heat exchanger is operatively connected to an outlet of the reciprocating compressor; and, a. a high pressure storage tank operatively connected to the condensing heat exchanger.

5. . An apparatus for facilitating the generation of energy from solid waste, the apparatus comprising: a pyrolysis unit, the pyrolysis unit having at least two gas plasmolysis torches, wherein the pyrolysis unit has a tube forming a solid paste cylinder and the plasmolysis torches are arranged such that the impingement angle of the flames is acute to the axis of the cylinder and the number of torches is sufficient to completely gasify the solid cylinder; at least one gas inlet nozzle operatively connected to the pyrolysis unit; a radiant heat exchanger operatively connected to a steam turbine; a filter device operatively connected to the radiant heat exchanger; a convective heat exchanger operatively connected to the filter device; a condensing heat exchanger operatively connected to the convective heat exchanger; a three stage reciprocating compressor with interstage membrane hydrogen separation and cooling devices operatively connected to the condensing heat exchanger, wherein the condensing heat exchanger is operatively connected to an outlet of the reciprocating compressor; and, a high pressure storage tank operatively connected to the condensing heat exchanger. 1:40099\50006\ZA PTO\091208 dat patapps doc

6. An apparatus for facilitating the generation of energy from solid waste, the apparatus comprising: a pyrolysis unit, the pyrolysis unit having at least one gas plasmolysis torch; at least one gas inlet nozzle operatively connected to the pyrolysis unit; a radiant heat exchanger operatively connected to a steam turbine; a three stage reciprocating compressor with interstage membrane hydrogen separation and cooling devices; and, a high pressure storage tank operatively connected to the condensing heat exchanger.

: 7. The apparatus of claims 4-6 wherein the apparatus further comprises a gas expansion valve, a heat exchanger and static in line mixers sequentially and operatively connected to the high pressure storage tank.

8. The apparatus of claims 4-7, wherein the apparatus further comprises: So at least two degasification units for the removal of entrained gases from water.

9. A method for facilitating the generation of electricity and algal oil from solid waste substantially as herein described with reference to FIGURES 1 and 2.

10. An apparatus for facilitating the generation of electricity and algal oil from : solid waste substantially as herein described with reference to FIGURES 1 and 2. Mn Dated this!Y..... day of December 2000 VON SEIDELS For the applicant [:\40099N\50006\ZA PTO091208.dat.patapp5.doc