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Title:
METHOD AND SYSTEM FOR PROCESSING EXHAUST GAS
Document Type and Number:
WIPO Patent Application WO/2017/030866
Kind Code:
A1
Abstract:
A method of processing exhaust gas includes receiving incoming exhaust gas and cooling it in at least one heat exchanger to create cooled exhaust gas. The cooled exhaust gas is compressed in a compressor to liquefy CO2 leaving a remaining exhaust gas. The remaining exhaust gas is circulated through the heat exchanger to cool subsequent incoming exhaust gas and warm the remaining exhaust gas. At least a portion of the liquid CO2 may be pelletized in a pelletizer.

Inventors:
JATKAR JAY (US)
Application Number:
PCT/US2016/046325
Publication Date:
February 23, 2017
Filing Date:
August 10, 2016
Export Citation:
Click for automatic bibliography generation   Help
Assignee:
JATKAR JAY (US)
International Classes:
F01N13/02; F01N3/035; F01N3/08
Foreign References:
US5233837A1993-08-10
US5642630A1997-07-01
US5385023A1995-01-31
US20100292524A12010-11-18
US20100024472A12010-02-04
US20080156035A12008-07-03
US3677019A1972-07-18
Attorney, Agent or Firm:
BECK, Ryann, H. et al. (US)
Download PDF:
Claims:
CLAIMS

I claim:

1. A method of processing exhaust gas, the method comprising:

receiving incoming exhaust gas;

cooling the incoming exhaust gas in at least one heat exchanger to create cooled exhaust gas; compressing the cooled exhaust gas in a compressor to liquefy CO3 leaving a remaining exhaust gas;

circulating the remaining exhaust gas through the heat exchanger to cool subsequent incoming exhaust gas and warm the remaining exhaust gas.

2. The method of claim 1 wherein the cooled exhaust gas is primarily comprised of CO2, CH4, and Ns, and wherein the remaining exhaust gas is primarily comprised of CH4 and N2.

3. The method of claim 2 wherein the incoming exhaust gas is from a landfill.

4. The method of claim 2 wherein the incoming exhaust gas is between 80 degrees

Fahrenheit and 120 degrees Fahrenheit, and the cooled exhaust gas is between -10 degrees Fahrenheit and -SO degrees Fahrenheit.

5. The method of claim 3 further comprising utilizing the remaining exhaust gas to fuel an internal combustion engine.

6. The method of claim 1 further comprising pelletizing at least a portion of the liquid CO2 in a pelletizer.

7. The method of claim 5 wherein the liquid CO2 not pelletized becomes CO* gas, and further comprising returning the COj gas to the compressor.

8. The method of claim I further comprising filtering the liquid CO2 with activated carbon to remove odorous material.

9. The method of claim I wherein the step of cooling the incoming exhaust gas includes collecting liquid condensation from the heat exchanger to remove contaminants.

10. The method of claim 7 further including spraying water into the incoming exhaust gas.

11. The method of claim 1 wherein the incoming exhaust gas is from an internal combustion engine.

12. The method of claim 11 wherein the cooled exhaust gas is primarily comprised of CO2 and N2, and wherein the remaining exhaust gas is primarily comprised of N2.

13. The method of claim 12 wherein the incoming exhaust gas is between 1000 degrees Fahrenheit and 800 degrees Fahrenheit, and the cooled exhaust gas is between -10 degrees Fahrenheit and -SO degrees Fahrenheit.

14. The method of claim 13 further comprising filtering the incoming exhaust gas with granular carbon.

15. A system for processing exhaust gas, the system comprising;

at least one heat exchanger that cools incoming exhaust gas;

a compressor that compresses the cooled exhaust gas to liquefy CO2 therein;

a tank that captures the liquid CO2 and allows removal of a remaining exhaust gas; and a circulation track that passes the remaining exhaust gas through the heat exchanger to cool subsequent incoming exhaust gas and warm the remaining exhaust gas.

16. The system of claim 15 further comprising a pelletizer that pelletizes at least a portion of the liquid CO2, wherein the liquid CO2 not pelletized becomes COj gas that is returned to the compressor.

17. The method of claim 16 further comprising an activated carbon filter that filters odorous material from the liquid CO2.

18. The system of claim 15 wherein the incoming exhaust gas is from a landfill and is between 80 degrees Fahrenheit and 120 degrees Fahrenheit, the cooled exhaust gas is primarily comprised of CC2, C H4, and N2 and is between - 10 degrees Fahrenheit and -50 degrees

Fahrenheit, and the remaining exhaust gas is primarily comprised of CH4 and N2.

19. The system of claim 18 further comprising a sprayer that sprays water into the incoming exhaust gas, and a collector that collects liquid condensation from the heat exchanger to remove contaminants.

20. The system of claim 15 wherein the incoming exhaust gas is from an internal combustion engine and is between 1000 degrees Fahrenheit and 800 degrees Fahrenheit, the cooled exhaust gas is primarily comprised of CO2 and N2 and is between -10 degrees Fahrenheit and -50 degrees Fahrenheit, and the remaining exhaust gas is primarily comprised of N2.

Description:
METHOD AND SYSTEM FOR PROCESSING EXHAUST GAS

FIELD

[0001] This disclosure relates to processing and separating exhaust gases. More specifically, this disclosure relates to a method and system for efficiently separating exhaust gases, such as exhaust from landfills and/or engines, into reusable component parts, including carbon dioxide and other purified gasses.

BACKGROUND

[0002] As wastes decompose in landfills, gases are generated as byproducts. These gases include carbon dioxide (CO 2 ). nitrogen (N 2) , water vapor (H 2 O), and other gases, as well as hydrocarbons, particularly methane (CH 4 ). Likewise, such exhaust gases containing methane may be produced by certain digesters, such as from the decomposition of grass, and from animal waste, such as Cow Dung. Similarly, engines that burn hydrocarbons, including gas turbines, produce exhaust that includes carbon dioxide, nitrogen, water vapor, and other gases. These gases in their combined form are generally emitted into the atmosphere creating pollution. However, the exhaust gases may be broken into component parts which may be useful in various industrial applications.

SUMMARY

[0003] In one embodiment, a method of processing exhaust gas includes receiving incoming exhaust gas and cooling it in at least one heat exchanger to create cooled exhaust gas. The cooled exhaust gas is compressed in a compressor to liquefy carbon dioxide (CO¾, leaving a remaining exhaust gas. The remaining exhaust gas is circulated through the heat exchanger to cool subsequent incoming exhaust gas and warm the remaining exhaust gas. At least a portion of the liquid CO 2 may be pelletized in a peiletizer.

[0004] A system for processing exhaust gas includes at least one heat exchanger that cools incoming exhaust gas and a compressor mat compresses the cooled exhaust gas to liquefy CO 2 therein. The system further includes a tank that captures the liquid CO 2 and allows removal of a remaining exhaust gas. A circulation track posses the remaining exhaust gas through the heat exchanger to cool subsequent incoming exhaust gas and warm the remaining exhaust gas.

[0005] Various other features, objects and advantages of the invention will be made apparent from the following description taken together with the drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

[0006] The drawings illustrate the best mode presently contemplated of carrying out the disclosure. In the drawings:

[0007] Fig. 1 provides a system diagram of one embodiment of a system and method for processing exhaust gas.

[0008] Fig. 2 provides a system diagram of another embodiment of a system and method for processing exhaust gas.

[0009] Fig. 3 provides a system diagram of another embodiment of a system and method for processing exhaust gas.

[0010] Fig. 4 is a flow chart depicting one embodiment of a method for processing exhaust gas.

[0011] Fig. 5 is a flow chart depicting another embodiment of a method tor processing exhaust gas.

[0012] Fig. 6 is a flow chart depicting another embodiment of a method for processing exhaust gas.

DETAILED DESCRIPTION OF THE DRAWINGS

[0013] Fig. 1 provides one embodiment of a system 1 and method for processing exhaust gases that include carbon dioxide (COj). Incoming exhaust gas 11 is passed through a heat exchanger IS where it is cooled. The cooled exhaust gas 16 is passed from the heat exchanger 15 into a compressor 17. In one embodiment, the cooled exhaust gas 16 is -20°F. The incoming exhaust gas 11 may be at various temperatures depending on the source of the exhaust gas and how the exhaust gas is transferred into the system 1. The compressor 17 compresses me cooled exhaust gas 16 sufficiently to liquefy the CO? therein, thus separating the cooled exhaust gas 16 into liquid CQ. 22 and remaining exhaust gas 23. The compressed mixture of liquid CO 2 22 and remaining exhaust gas 23 collects in tank 21, where the liquid CO 2 22 sinks to the bottom of the tank. The remaining exhaust gas 23, which remains at a cold temperature, is removed from the tank 21 and circulated in circulation track 24. Circulation track 24 passes the remaining exhaust gas 23 through the heat exchanger 15 in order to cool subsequent incoming exhaust gas and warm the remaining exhaust gas 23. Thereby, the amount of energy needed to coo! the subsequent incoming exhaust gas is reduced by utilizing the cold remaining exhaust gas 23 to absorb the heat from the incoming gas. The resulting warmed remaining exhaust gas 2$ may then be utilized in certain applications, examples of which are described herein, or may be further processed to prepare them for use in a particular industrial application.

[0016] The liquid CO 2 22 from the tank 21 is sent to pelletizer 27. lite pelletizer 27 pelletizes at least a portion of the liquid CO 2 22 into solid CO 2 29. As will be understood by a person of ordinary skill in the art in light of this disclosure, the sol id CO 2 29, or dry ice, may be in any number of shapes or sizes, such as dry ice blocks, cylindrical dry ice pellets of any size, shaved dry ice, or the like. Any remaining CO 2 not pelietized becomes CO 2 gas 28. The CO 2 gas 28 is recirculated to the compressor 17, where it joins the cooled incoming exhaust gas 16 in being compressed and transferred to the tank 21. Accordingly, all of the CO 2 from the incoming exhaust gas H is maintained in the system 1 or outputted as solid CO 2 29.

[0016] Accordingly, the present inventor has recognized that certain exhaust gasses may be distilled into component parts that can be utilized in various industrial applications, with little waste or creation of polluting matter. Furthermore, the amount of energy consumed by the system 1 is minimized by recapturing the cold from the processed remaining gases before they are outputted from the system 1.

[0016] Figure 2 depicts one embodiment of the system 1 wherein the incoming exhaust gas 11 is from a landfill 5. As an example, the incoming exhaust gas 11 may be at approximately 100°F and the incoming exhaust gas 11 from the landfill may be primarily comprised of CO 2 , methane (CFij), and nitrogen (Nj ) . A small amount of contaminants may also be present in the incoming landfill gas 11. In an exemplary embodiment, the incoming landfill gas is comprised of approximately 50% CH 4 , 45% CO 2 , and 5% N 2 , not accounting for any contaminants which may comprise a very small percentage of roe incoming landfill gas U. For example, contaminants may include mercury, formaldehyde, PCBs, or other inorganic materials, and/or unwanted gas combinations formed during cooling, such as nitrogen dioxide (NO2) or sulfur dioxide (SO2).

[0017] In the embodiments depicted in Figs. 2 and 3, some or all of the contaminants may be removed from the incoming landfill gas during the cooling process by way of being trapped in condensation of any water vapor in the incoming landfill gas 11. Additionally, water may be sprayed into the incoming exhaust gas 11 by the sprayer 12 prior to the entrance of the gas into the heat exchanger I Sy. In an exemplary embodiment, the sprayer 12 is a standard misting system. The heat exchanger 15y cools, and thus condenses, the incoming exhaust gas 11 in an initial cooling phase. During that initial cooling phase, the water vapor condenses taking contaminants along with it. The condensed water carrying the contaminants is collected from the heat exchangers 15y and/or ISz in the collector 13, such as a storage tank. For example, the water carrying the contaminants may have a pH of about 3 when it is collected from the heat exchangers 15. After collection, it may be neutralized with an alkaline material until it has a pH of around 7. The neutralized water mixture may then be safely disposed of.

[0018] In the embodiment depicted in Fig. 2, the incoming exhaust gas 1 1 is cooled from approximately 100°F to approximately -20°F by the use of two heat exchangers 15y and 15z. It should be understood that these temperatures may vary, and that the gas exiting the landfill may be between 120°F, or even warmer, and 80°F, or cooler, depending on the configuration and conditions of the landfill and how the gas is transferred to the system 1. The first heat exchanger 15y cools the incoming exhaust gas 11 from its initial temperature to a lower temperature, which in the depicted embodiment is approximately 40°F. Again, this temperature may be varied. The gas then enters a second heat exchanger ISz that cools it to approximately -20° F. Again, the temperature of the cooled exhaust gas 16 may be varied, and may, for example, be anywhere between ~10°F and as low as ~50°F.

[0019] As will be recognized by one of skill in the art in light of this disclosure, any number of heat exchangers may be util ized to cool the incoming gas, which may be a single heat exchanger or several heat exchangers. Further, the heat exchangers I Sy and 15z may be any heat exchangers known in the art. in one embodiment, the heat exchangers 15 y and 1 Sz are shell and tube heat exchangers, such as u-tube heat exchangers.

[0020] The cooled exhaust gas 16, which in the example of Fig, 2 is CO 2 , CH 4 , and N 2 at approximately -20°F, is then compressed by a compressor 17. In the depicted example, the compressor 17 compresses the cooled exhaust gas 16 to approximately 300 IbsJin 2 (psi) at The CO 2 is liquefied at that pressure and temperature, thereby separating the cooled exhaust gas 16 into liquid CO 2 22 and a remaining gas 23 comprised primarily of CH 4 and N 2 .

[0021] The compressed mixture of liquid CO 2 22 and remaining exhaust gas 23 may be filtered through an activated carbon filter 19 to remove odorous material therefrom. Odorous material, such as hydrogen sulfide (H 2 S), may be present in the incoming exhaust gas 11 from the landfill 5 and may be removed in order to provide a clean, non-odorous CO 2 product.

[0022] The filtered liquid CO 2 22 and remaining gas 23 mixture is collected in the tank 21 , where the liquid CO 2 22 is collected and separated from the remaining gas 23. In an exemplary embodiment, the tank 21 will contain about 35% liquid CO 2 , and about 65% gaseous CO 2 .

[0023] The liquid CO 2 22 collected in the tank 21 may be further filtered, such as in activated carbon filter 26, to further remove any remaining odorous material. The liquid CO 2 22 is then processed in a pelletizer 27 which solidifies at least a portion of the liquid CO 2 22 into a solid CO 2 29. In an exemplary embodiment, the pelletizer 27 pelietizes approximately 40% of the liquid CO 2 22 into solid CO 2 29. Any CO 2 not solidified would be CO 2 gas 28 recovered and circulated back to the compressor 17. Thereby, the conversion of CO 2 into its solid form, dry ice, is max imized.

[0024] The cooled remaining exhaust gas 23, which in the depicted embodiment is comprised primarily of CH 4 and N 2 , is circulated in circulation track 24 to recover the cold from the cooled remaining exhaust gas 23. Specifically, the cooled remaining CH* and N 2 , which in the depicted example is at approximately 0°F, is circulated through the heat exchangers 1 Sz and 15y. In the heat exchanger 15z the cooled remaining exhaust gas 23 transfers cold into the incoming exhaust gas 11 , which brings the temperature of the incoming gas down and warms the cooled remaining exhaust gas 23. In the depicted embodiment, the remaining exhaust gas 23 is warmed from 0°F to approximately 40ºF. The remaining exhaust gas 23, which is now at approximately 40°F, is then passed through the first heat exchanger 15y. Thereby, the cold from the remaining exhaust gas 23 is transferred to the incoming exhaust gas 11, and the remaining exhaust gas 23 is further warmed, such that warmed remaining exhaust gas 25 is outputted from the system 1. In the depicted embodiment, the warmed C¾ and N 2 mixture 25 is utilized as fuel for internal combustion engine 7.

[0025] Fig. 3 depicts another embodiment of a system 1 for processing exhaust gas from an internal combustion engine 7. The incoming exhaust gas 1 I from the engine 7 may be, for example, a mixture of H 2 O, O 2 , CO 2 The incoming exhaust gas 11 from the engine 7 may be at a very high temperature, such as between 800°F and 1,000°F. In a common example, the incoming exhaust gas 1 1 is at about 900°F. The hot incoming exhaust gas 1 1 may be passed through a filter 9, such as comprised of granular carbon, to remove C½ from the gas mixture by converting it to CO 2

[0026] The incoming exhaust gas 11 is men primarily comprised of H 2 O, CO 2 . and N 2 and is fed through a series of heat exchangers 15x-15z to reduce the temperature to -20ºF.. In the depicted embodiment, the incoming exhaust gas 11 is first cooled from about 900ºF. to about 100°F in a first heat exchanger 15x. The gas is then transferred to a second heat exchanger 15y, which cools the incoming exhaust gas 11 from about 100°F to about 40°F. At this stage, a large portion of the water condenses in the heat exchanger and is collected in the collector 13. The gas is then passed to a third heat exchanger 15z where it is further cooled to -20ºF. Any remaining water in the gas condenses in the heat exchanger and is collected in the collector 13. As described above, one of skill in the art will recognize that any of a number of types of heat exchangers may be appropriate for this application, including shell and tube heat exchangers.

[0027] The cooled exhaust gas 16 is comprised primarily of CO 2 and N 2 and is then compressed by the compressor 17, such as to 300 psi and 0°F. The CO 2 is liquefied and thus separates from the N 2, which remains a gas. The liquid CO 2 22 and the remaining N 2 23 collects in the tank 21. The liquid CO 2 22 is then converted to a solid CO? 29 in a pelletizer 27. Any CO 2 not pelletized in the pelletizer 27, is captured as CO 2 gas 28 and recirculated to toe compressor 17. [0028] The cold remaining N 2 23 follows the recirculation track 24 to recapture the cold therefrom in one or more of the heat exchangers 1 Sx, 15y, 15z. In the depicted embodiment, die cold remaining Nj 23 passes through each of the three heat exchangers 15x, 15y, and 15z.

However, in other embodiments, the recirculation track 24 may only pass through a subset of the heat exchangers 15x- i 5z. The warmed N 2 25 then exits the system 1 , and may be collected and stored for use in other applications. Thus, the presently disclosed system 1 and method 40 offers a beneficial way of removing and distilling N 2 from exhaust gas without the use of very high pressure or extreme cold temperatures. As Na is a commonly used gas in a range of industrial applications, it may men be transferred for use in any number of a broad range of industries, including chemical manufacture, pharmaceutical manufacture, petroleum processing, glass and ceramic manufacture, steel making and metal refining and fabrication, pulp and paper manufacture, healthcare, etc.

[0029] Fig. 4 depicts one embodiment of a method 40 of processing exhaust gas that includes CO 2 .. At step 41, incoming exhaust gas is received, such as from a landfill or an internal combustion engine. The incoming exhaust gas is cooled in a heat exchanger at step SO, and is then compressed at step 57 to liquefy any CO 2 therein. The remaining exhaust gas is circulated at step 58, and is warmed in the heat exchanger at step 54. The warmed remaining exhaust gas is then outputted at step 48. The CO 2 that is liquefied at step 57 is sent to a pelletizer, where at least a portion is pelletized at step 63. Any gaseous remaining CO 2 is recirculated at step 64 to the compressor, thus cycling through steps 57 and 63 again. The solid CO 2 from the pelletizer is outputted at step 65.

[0030] Fig. 5 depicts another embodiment of a method 40 of processing exhaust gas. Exhaust gas is received from a landfill at step 41, wherein the exhaust gas is primarily comprised of CH 4 , N 2 , CQ., along with some contaminants. The exhaust gas is, for example, at about 100°F. Water is sprayed, or misted, into the incoming exhaust gas at step 45. At step 51, the incoming exhaust gas is cooled to approximately 40°F in a first heat exchanger. During that cooling process, water condenses in the heat exchanger and extracts contaminants from the gassed mixture in the process. For example, any formaldehyde that may be in the incoming exhaust gas will be condensed into the water. The condensed water with contaminants is collected at step 53, which may then be removed from the system. At step 55, the remaining CH 4 , N 2 , and CO? gas is further cooled to about -20°F in a second heat exchanger. The cooled gas is then compressed at step 57 to liquefy the CO 2 . The remaining CH 4 and N 2 gas mixture is then circulated at step 58. It is passed through the second heat exchanger at step 56 where it is warmed to approximately 40°F, and then passed through the first heat exchanger at step 52 where it is warmed to approximately100ºF. The warmed CH 4 and N 2 gas mixture may then be used for another purpose, such as to fuel a gas turbine at step 48. Returning to step 57, the liquefied CO 2 may then be filtered at step 61, such as with activated carbon. The filtering removes odorous material which may be in the liquid CO 2 . At step 63, the liquid CO 2 is pelletized by the pellctizer, where about 40% of the liquid CO 2 is converted to solid CO 2 . The remaining CO 2 gas is circulated at step 64 back to the compressor. At step 65, the solid CO 2 is outputted.

[0031] Another embodiment of a method of processing exhaust gas includes receiving exhaust from an engine that includes N 2 , CO 2 , O 2 and contaminants and is at about 900°F. The exhaust gas is filtered to remove O 2 at step 43, such as with a filter comprising granular activated carbon that transforms the O 2 to CO?. At step 51 , the gas mixture of N 2 CO 2 , and contaminants is cooled in a heat exchanger to approximately 40°F. As is described above, mis cooling step may be performed using any number of heat exchangers, and may be performed using two heat exchangers as exhibited in Fig. 3. As is described above, water condenses during the cooling process and brings contaminants with it, removing them from the gas mixture. The condensed water with contaminants is collected at step 53. At step 55, the N 2 and CO 2 gas is further cooled to -20°F in a second heat exchanger. The cooled exhaust gas is then compressed to liquefy the CO 2 therein. In the embodiment of Fig. 6, the liquid CO 2 is outputted at step 59, which may be used in any number of industrial applications, such as in oil recovery processes, fertilizer production, food processing and preservation, cold storage application, beverage carbonation, coffee decaffeination, pharmaceutical manufacture, horticulture, fire suppression, and many more. The remaining Nj. gas is circulated at step 58 to recapture the cold therefrom. At step 56, the remaining N? gas is warmed in the second heat exchanger, and at step 52 the N 2 is further warmed in the first heat exchanger. The remaining N 2 gas is then outputted at step 48, and may be used in any number of industrial applications as is described above.

[0032] This written description uses examples to disclose the invention, including the best mode, and also to enable any person skilled in the art to make and use the invention. The patentable scope of the invention is defined by the claims, and may include other examples mat occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they have structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal languages of the claims.