WO2014099407A1 - Heating for indirect boiling - Google Patents

Heating for indirect boiling Download PDF

Info

Publication number
WO2014099407A1
WO2014099407A1 PCT/US2013/073485 US2013073485W WO2014099407A1 WO 2014099407 A1 WO2014099407 A1 WO 2014099407A1 US 2013073485 W US2013073485 W US 2013073485W WO 2014099407 A1 WO2014099407 A1 WO 2014099407A1
Authority
WO
WIPO (PCT)
Prior art keywords
solid particulate
vessel
water
steam
heating
Prior art date
Application number
PCT/US2013/073485
Other languages
French (fr)
Inventor
David W. Larkin
Scott D. Love
Scott Macadam
Peter N. Slater
Edward G. Latimer
Richard B. Miller
Original Assignee
Conocophillips Company
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from US14/097,496 external-priority patent/US20140165930A1/en
Application filed by Conocophillips Company filed Critical Conocophillips Company
Priority to CA2894864A priority Critical patent/CA2894864A1/en
Publication of WO2014099407A1 publication Critical patent/WO2014099407A1/en

Links

Classifications

    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F22STEAM GENERATION
    • F22BMETHODS OF STEAM GENERATION; STEAM BOILERS
    • F22B1/00Methods of steam generation characterised by form of heating method
    • F22B1/02Methods of steam generation characterised by form of heating method by exploitation of the heat content of hot heat carriers
    • F22B1/04Methods of steam generation characterised by form of heating method by exploitation of the heat content of hot heat carriers the heat carrier being hot slag, hot residues, or heated blocks, e.g. iron blocks
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F22STEAM GENERATION
    • F22BMETHODS OF STEAM GENERATION; STEAM BOILERS
    • F22B27/00Instantaneous or flash steam boilers
    • F22B27/16Instantaneous or flash steam boilers involving spray nozzles for sprinkling or injecting water particles on to or into hot heat-exchange elements, e.g. into tubes

Definitions

  • Embodiments of the invention relate to methods and systems for generating steam which may be utilized in applications such as bitumen production.
  • Costs associated with building a complex, large, sophisticated facility to process water and generate steam contributes to economic challenges of oil sands production operations. Such a facility represents much of the capital costs of these operations. Chemical and energy usage of the facility also contribute to operating costs.
  • a method of vaporizing water includes introducing a gaseous fluid into a first vessel and in contact with solid particulate within the first vessel to transfer heat from the gaseous fluid to the solid particulate.
  • the gaseous fluid Upon recovering and then reheating the gaseous fluid from the first vessel, the gaseous fluid circulates back into the first vessel for continued heating of the solid particulate that is circulating between the first vessel and a second vessel.
  • the water introduced into the second vessel contacts the solid particulate heated to a temperature that results in vaporizing the water into steam, which is then separated from the solid particulate.
  • a system for vaporizing water includes a first vessel having an inlet and an outlet for a gaseous fluid and containing solid particulate in contact with the gaseous fluid that passes from the inlet to the outlet for transference of heat from the gaseous fluid to the solid particulate.
  • a heater coupled to the inlet and the outlet of the first vessel reheats the gaseous fluid that is recovered from the outlet of the first vessel and circulated back to the inlet of the first vessel for sustained heating of the solid particulate.
  • a second vessel couples to the first vessel by conduits through which the solid particulate is circulated between the first vessel and the second vessel.
  • An injection line coupled to the second vessel supplies the water into the second vessel and in contact with the solid particulate heated to a temperature that results in vaporization of the water into steam.
  • a steam output line coupled to the second vessel conveys the steam that is separated from the solid particulate.
  • Figure 1 is a schematic of a steam generating system that includes dual vessels arranged to alternate between heating and steam generation cycles, according to one embodiment of the invention.
  • Figure 2 is a schematic of a steam generating system with an exemplary heating vessel through which solid particulate circulates to regain thermal energy used to vaporize water, according to one embodiment of the invention.
  • Figure 3 is a schematic of a steam generating system with a heating vessel in which heat is transferred to solid particulate via recycled gaseous fluid, according to one embodiment of the invention.
  • Figure 4 is a schematic of a steam generating system with a heating vessel in which heat is transferred to solid particulate via recycled gaseous fluid that is condensed before reheating, according to one embodiment of the invention.
  • Figure 5 is a schematic of a steam generating system with a heating vessel having an internal heat exchanger to transfer heat to solid particulate from hot fluids without direct contact, according to one embodiment of the invention.
  • FIG. 6 is a schematic of a steam generating system with a single vessel for vaporizing water upon contact with fluidized solid particulate disposed in the vessel and in thermal contact with a heat exchanger, according to one embodiment of the invention.
  • Figure 7 is a schematic of the steam generating system shown in Figure 3 and in a side -by-side vessel configuration, according to one embodiment of the invention.
  • Embodiments of the invention relate to systems and methods for vaporizing water into steam, which may be utilized in applications such as bitumen production.
  • the methods rely on indirect boiling of the water by contact with a substance such as solid particulate heated to a temperature sufficient to vaporize the water. Heating of the solid particulate may utilize pressure isolated heat exchanger units or a hot gas recirculation circuit at a pressure corresponding to that desired for the steam.
  • the water may form part of a mixture that contacts the solid particulate and includes a solvent for the bitumen in order to limit vaporization energy requirements and facilitate the production.
  • the water may come from separated production fluid associated with a steam assisted gravity drainage (SAGD) bitumen recovery operation.
  • SAGD steam assisted gravity drainage
  • the water at time of being generated into the steam may still contain: at least about 1000 parts per million (ppm), at least 10,000 ppm or at least 45,000 ppm total dissolved solids; at least 100 ppm, at least 500 ppm, at least 1000 ppm or at least 15,000 ppm organic compounds or organics; and at least 1000 ppm free oil.
  • ppm parts per million
  • Figure 1 illustrates a steam generating system that includes a first vessel 101 and a second vessel 102 that each contains solid particulate.
  • the solid particulate include sand, metal spheres, cracking catalyst and mixtures thereof.
  • fluidization of the solid particulate keeps the solid particulate moving within the vessels 101, 102 during operation to generate steam. Such fluidization may involve circulation of the solid particulate and may rely on addition of supplemental steam.
  • Each of the vessels 101, 102 couples to a water injection line 104 and a heat source line 106.
  • a manifold system controls flow through the vessels 101, 102 to a steam output 108 and an exhaust 110 and includes first through eighth valves 111-118.
  • the valves 111-118 alternate between heating and steam generation cycles with the first vessel 101 being shown in the steam generation cycle while the second vessel 102 is in the heating cycle.
  • the first and fifth valves 111, 115 on the water injection line 104 and the steam output 108 thus remain open to flow of the water through the first vessel 101 to generate the steam while the third and seventh valves 113, 117 block flow of the water through the second vessel 102.
  • the steam exits the first vessel 101 through the steam output 108, which may couple to the injection well, and is separated from the solid particulate that remains in the first vessel 101 and may be trapped by filters or cyclones.
  • the second and sixth valves 112, 116 block flow from the heat source line 106 to the first vessel 101 at this time while the fourth and eighth valve 114, 118 are open to flow of oxygen and fuel, such as methane, from the heat source line 106 through the second vessel 102 to the exhaust 110.
  • oxygen and fuel such as methane
  • the oxygen and fuel passing through the second vessel 102 combusts to reheat the solid particulate.
  • contaminants such as organic compounds deposited on the solid particulate from the water, may partially or fully convert into carbon dioxide and water, and some salts deposited on the solid particulate from the water may come off and be swept out of the second vessel 102.
  • the combustion heats the solid particulate to a temperature that results in vaporizing the water upon contact therewith in the steam generation cycle that follows.
  • the heat source line 106 can supply the oxygen and fuel without compression to pressures desired for the steam to be injected into the formation. This relative lower pressure combustion facilitates economic production of the steam. Alternating each of the vessels 101, 102 between the steam generation cycle and the heating cycle also eliminates need for conveying the solid particulate to units dedicated to one particular cycle.
  • the water mixes with a solvent 120 for the bitumen prior to vaporization due to contact with the solid particulate.
  • the solvent 120 (common reference number depicted in all figures) thus may flow as a liquid into the water supply line 104 to form a resulting mixture of the water with the solvent 120. Vaporization of the water along with the solvent 120 results in the steam output 108 also containing both water and solvent vapors, as may be desired for injection into the formation.
  • the solvent 120 may include hydrocarbons having between 3 and 30 carbon atoms, such as butane, pentane, naphtha and diesel. Temperatures associated with the indirect boiling described herein limit potential problems of cracking the hydrocarbons, which can tend to occur if passed through direct fired boilers that may thus require injection of any wanted solvents into steam rather than boiler feed. Such injection of the solvent into the steam instead of the water feed may either cause loss of some steam due to condensation or require superheating of the steam. Conventional superheating of the steam also suffers from fouling problems. Therefore, the solvent 120 may flow into steam superheated by steam generation methods described herein in some embodiments since the fouling issues from the superheating are overcome in the same manner as those associated with steam generation.
  • the mixture in the water supply line 104 may include between 5 and 30 percent of the liquid hydrocarbon by volume.
  • the mixture may further provide an energy requirement for vaporization that is at least 10 percent lower than water alone. For example, a 28:72 ratio of butane to water reduces steam generator duty by 22 percent as compared to water alone.
  • FIG. 2 shows a steam generating system with a steam generating riser 200 and/or vessel 201 and a heating vessel 202 through which solid particulate are circulated.
  • a heat source line 206 supplies reactants for combustion within the heating vessel 202 in order regain thermal energy used to vaporize water. Flue gases from the combustion exit the heating vessel 202 through exhaust 210 following any filtering to retain the solid particulate.
  • Multiple alternating heating vessels with flow control similar to Figure 1 or lockhoppers may enable operation of the heating vessel 202 at a lower pressure than the steam generating riser 200 and/or vessel 201.
  • the solid particulate heated in the heating vessel 202 transfers to the steam generating vessel 201 by gravity since the heating vessel 202 is disposed above the steam generating vessel 201.
  • a water supply line 204 then inputs the water into contact with the solid particulate that is heated to result in vaporizing the water and providing a steam output 208.
  • Some of the steam output 208 may provide lift for the solid particulate being returned up the riser 200 to the heating vessel 202.
  • the water vaporizes in the riser 200 such that the steam generating vessel 201 is not even required and the steam is recovered at a riser output 209.
  • Figure 3 illustrates a steam generating system with a heating vessel 302 in which heat is transferred to solid particulate via recycled gaseous fluid circulating in a circuit. Similar to systems in other figures, the solid particulate once heated transfers to a steam generating vessel 301 where water 304 is input to contact the solid particulate and generate steam 308. Embodiments may therefore implement various features and attributes explained in detail with respect to another particular figure or elsewhere herein without being repeated in order to be as succinct as possible. [0031] The gaseous fluid that exits the heating vessel 302 through an outlet 310 passes through heat exchanger(s) 350 and a fin-fan cooler 352, if necessary.
  • the heat exchanger 350 may transfer heat with the gaseous fluid post compression boosting and/or with the water 304 being input into the steam generating vessel 301. Such heat exchange helps maintain efficiency while bringing the temperature of the gaseous fluid below temperature limits of a compressor 358 through which the gaseous fluid is sent downstream in the circuit.
  • a purge 354 allows removal of a portion of the gaseous fluid, which may pick up contaminants, such as from cracking or entrainment.
  • Makeup gas 356 combines with the gaseous f uid to replace that purged.
  • the gaseous fluid includes an inert gas such as nitrogen and may also include air or oxygen for burning of the deposits. Methane may provide the gaseous fluid for some embodiments and may be desired due to its relative higher thermal capacity.
  • the compressor 358 only boosts pressure of the gaseous fluid circulating through the circuit.
  • the compressor may provide between 50 and 150 kilopascals (kPa) boost in pressure, which is achievable without making steam generation uneconomical by requiring levels of compression needed to increase atmospheric pressure to above 2500 kPa.
  • the gaseous fluid in the circuit may thus always remain above 2500 kPa, in some embodiments.
  • the gaseous fluid from the compressor 358 then flows through the circuit to a furnace 360.
  • the furnace 360 burns fuel to reheat the gaseous fluid that reenters the heating vessel 302 through a heat source line 306 for sustained heating of the solid particulate within the heating vessel 302.
  • the heating vessel 302 may include multiple (e.g., 6 as shown) bed stages 362 or trays such that the solid particulate passing through the heating vessel 302 counter current with the gaseous fluid achieves efficient heat cross exchange.
  • Pressure of the steam desired for injection into the formation dictates pressure inside the steam generating vessel 301.
  • both the steam generating vessel 301 and the heating vessel 302 may operate at this pressure, such as above 2500 kPa, provided there may be sufficient differences in pressure in the vessels 301, 302 or other such arrangements described herein to maintain fluid flows.
  • a slipstream 364 of the gaseous fluid also at necessary pressure provides lift for transporting the solid particulate from the steam generating vessel 301 to the heating vessel 302.
  • FIG 4 shows a steam generating system with a heating vessel 402 in which heat is transferred to solid particulate via recycled gaseous fluid that is circulating in a circuit and condensed before reheating. While shown as being recycled, the gaseous fluid in some embodiments passes once through the vessel 402 and may then be utilized in another application. Like the system in Figure 3, the solid particulate once heated transfers to a steam generating vessel 401 where water 404 is input to contact the solid particulate and generate steam 408. The gaseous fluid that exits the heating vessel 402 through an outlet 410 passes through heat exchanger(s) 450 that transfer heat from flow along the circuit post pumping and/or with the water 404 being input into the steam generating vessel 401.
  • heat exchanger(s) 450 that transfer heat from flow along the circuit post pumping and/or with the water 404 being input into the steam generating vessel 401.
  • the heat exchange 450 condenses the gaseous fluid, such as propane, butane or naphtha, to a liquid phase for pressurization by a pump 458.
  • a separator 454 may enable venting off gasses that are not condensed, such as may result from cracking of the gaseous fluid.
  • Outflow from the pump 458 and any makeup 456 then flows through the circuit to a furnace 460.
  • the furnace 460 burns fuel to vaporize and reheat the gaseous fluid that reenters the heating vessel 402 through a heat source line 406 for sustained heating of the solid particulate within the heating vessel 402.
  • the pump 458 may influence efficiency if used in place of compression.
  • Use of the pump 458 with the gaseous fluid that is condensed may further enable economic once through heating (i.e., without the circuit) at the desired pressure similar to approaches depicted in Figures 1 or 2 (i.e. replace oxygen and methane for combustion with a higher hydrocarbon pumped and then heated as in Figure 4) except that resulting exhaust may have further application for its energy content.
  • FIG. 5 illustrates a steam generating system with a heating vessel 502 having an internal heat exchanger 562 to transfer heat to solid particulate from hot fluids without direct contact. Similar again to systems in other figures, the solid particulate once heated transfers to a steam generating vessel 501 where water 504 is input to contact the solid particulate and generate steam 508. Both the steam generating vessel 501 and the heating vessel 502 may operate in open pressure communication with one another at an internal pressure desired for injection of the steam into a formation while pressure isolated flow through the heat exchanger 562 may be at a lower pressure.
  • oxygen and fuel react in a combustor 560 to generate a flue gas conveyed to the heat exchanger 562 by a heat source line 506.
  • the flue gas passes through the heat exchanger 562 and exits via an exhaust 510.
  • a thermally conductive material forms the heat exchanger 562 such that heat from the flue gas transfers to the solid particulate in the heating vessel 502.
  • the thermally conductive material forms a tube of the heat exchanger.
  • the tube may coil within the heating vessel 510 to provide the heat exchanger 562 with either the solid particulate flowing through an inside of the tube or the flue gas flowing through the inside of the tube.
  • a fluidization gas such as air, passes through the inside of the heating vessel 502. This gas may help remove contaminants from the solid particulate as well. Use of the gas for only fluidization while relying on heating by the heat exchanger 562 limits quantity and compression requirements for the gas whether the gas is used once through or circulated in a circuit.
  • FIG. 6 shows a steam generating system with a single vessel 600 for vaporizing water upon contact with fluidized solid particulate disposed in the single vessel 600 and in thermal contact with a heat exchanger 662.
  • the solid particulate heated by the heat exchanger 662 contacts water 604 that is input into the single vessel to generate steam 608.
  • a circulating liquid such as sodium or sodium and potassium, passes through the heat exchanger 662, exits the heat exchanger via an outlet 610 and is pumped by an pump 658 to a furnace 660 that reheats the circulating liquid prior flowing back to the heat exchanger 662 via inlet 606.
  • the heat exchanger 662 transfers heat from the circulating liquid to the solid particulate and may have a design such as described with respect to the heat exchanger 562 shown in Figure 5. Vaporization of the water 604 still occurs upon contacting the solid particulate that is heated. While the solid particulate thus should receive deposits from the water 604, movement of the solid particulate along the heat exchanger 662 provides abrasion to ensure that the heat exchanger 662 does not become fouled.
  • the heat exchangers 562, 662 in Figures 5 and 6 may each operate with either the flue gas or the circulating liquid as described herein providing hot fluid thereto.
  • systems may incorporate both the heat exchanger 662 where the steam is being generated along with additional heating of the solid particulate such as provided in the heating vessel 302 shown in Figure 3. Sharing this thermal load may enable efficient operation.
  • FIG. 7 shows the system illustrated in Figure 3 with the steam generating vessel 301 disposed at a common elevation with the heating vessel 302 as opposed to a stacked vertical arrangement.
  • This side -by-side configuration limits or eliminates need to use lift gas for transfer of the solid particulate.
  • the solid particulate transfers between the steam generating vessel 301 and the heating vessel 302 via dense phase gravity drain as a result of such at least partial overlapping height.
  • an upper outlet of the steam generating vessel 301 couples to a relative lower inlet of the heating vessel 302 for flow from the steam generating vessel 301 to the heating vessel 302.
  • a bottom outlet of the heating vessel 302 couples to a relative lower inlet of the steam generating vessel 301 for flow from the heating vessel 302 to the steam generating vessel 301.

Landscapes

  • Engineering & Computer Science (AREA)
  • Physics & Mathematics (AREA)
  • Thermal Sciences (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Life Sciences & Earth Sciences (AREA)
  • Sustainable Development (AREA)
  • Sustainable Energy (AREA)
  • Production Of Liquid Hydrocarbon Mixture For Refining Petroleum (AREA)

Abstract

Systems and methods relate to vaporizing water into steam, which may be utilized in applications such as bitumen production. The methods rely on indirect boiling of the water by contact with a substance such as solid particulate heated to a temperature sufficient to vaporize the water. Heating of the solid particulate may utilize pressure isolated heat exchanger units or a hot gas recirculation circuit at a pressure corresponding to that desired for the steam. Further, the water may form part of a mixture that contacts the solid particulate and includes a solvent for the bitumen in order to limit vaporization energy requirements and facilitate the production.

Description

HEATING FOR INDIRECT BOILING
FIELD OF THE INVENTION
[0001] Embodiments of the invention relate to methods and systems for generating steam which may be utilized in applications such as bitumen production.
BACKGROUND OF THE INVENTION
[0002] Several techniques utilized to recover hydrocarbons in the form of bitumen from oil sands rely on generated steam to heat and lower viscosity of the hydrocarbons when the steam is injected into the oil sands. One common approach for this type of recovery includes steam assisted gravity drainage (SAGD). The hydrocarbons once heated become mobile enough for production along with the condensed steam, which is then recovered and recycled.
[0003] Costs associated with building a complex, large, sophisticated facility to process water and generate steam contributes to economic challenges of oil sands production operations. Such a facility represents much of the capital costs of these operations. Chemical and energy usage of the facility also contribute to operating costs.
[0004] Past approaches rely on once through steam generators (OTSGs) to produce the steam. However, boiler feed water to these steam generators requires expensive de- oiling and treatment to limit boiler fouling problems. Even with this treatment, fouling issues persist and are primarily dealt with through regular pigging of the boilers. This recurring maintenance further increases operating costs and results in a loss of steam production capacity, which translates to an equivalent reduction in bitumen extraction.
[0005] Therefore, a need exists for methods and systems for generating steam that enable efficient hydrocarbon recovery from a formation.
BRIEF SUMMARY OF THE DISCLOSURE
[0006] In one embodiment, a method of vaporizing water includes introducing a gaseous fluid into a first vessel and in contact with solid particulate within the first vessel to transfer heat from the gaseous fluid to the solid particulate. Upon recovering and then reheating the gaseous fluid from the first vessel, the gaseous fluid circulates back into the first vessel for continued heating of the solid particulate that is circulating between the first vessel and a second vessel. The water introduced into the second vessel contacts the solid particulate heated to a temperature that results in vaporizing the water into steam, which is then separated from the solid particulate.
[0007] For one embodiment, a system for vaporizing water includes a first vessel having an inlet and an outlet for a gaseous fluid and containing solid particulate in contact with the gaseous fluid that passes from the inlet to the outlet for transference of heat from the gaseous fluid to the solid particulate. A heater coupled to the inlet and the outlet of the first vessel reheats the gaseous fluid that is recovered from the outlet of the first vessel and circulated back to the inlet of the first vessel for sustained heating of the solid particulate. A second vessel couples to the first vessel by conduits through which the solid particulate is circulated between the first vessel and the second vessel. An injection line coupled to the second vessel supplies the water into the second vessel and in contact with the solid particulate heated to a temperature that results in vaporization of the water into steam. A steam output line coupled to the second vessel conveys the steam that is separated from the solid particulate.
BRIEF DESCRIPTION OF THE DRAWINGS
[0008] A more complete understanding of the present invention and benefits thereof may be acquired by referring to the following description taken in conjunction with the accompanying drawings.
[0009] Figure 1 is a schematic of a steam generating system that includes dual vessels arranged to alternate between heating and steam generation cycles, according to one embodiment of the invention.
[0010] Figure 2 is a schematic of a steam generating system with an exemplary heating vessel through which solid particulate circulates to regain thermal energy used to vaporize water, according to one embodiment of the invention.
[0011] Figure 3 is a schematic of a steam generating system with a heating vessel in which heat is transferred to solid particulate via recycled gaseous fluid, according to one embodiment of the invention.
[0012] Figure 4 is a schematic of a steam generating system with a heating vessel in which heat is transferred to solid particulate via recycled gaseous fluid that is condensed before reheating, according to one embodiment of the invention. [0013] Figure 5 is a schematic of a steam generating system with a heating vessel having an internal heat exchanger to transfer heat to solid particulate from hot fluids without direct contact, according to one embodiment of the invention.
[0014] Figure 6 is a schematic of a steam generating system with a single vessel for vaporizing water upon contact with fluidized solid particulate disposed in the vessel and in thermal contact with a heat exchanger, according to one embodiment of the invention.
[0015] Figure 7 is a schematic of the steam generating system shown in Figure 3 and in a side -by-side vessel configuration, according to one embodiment of the invention.
DETAILED DESCRIPTION
[0016] Turning now to the detailed description of the preferred arrangement or arrangements of the present invention, it should be understood that the inventive features and concepts may be manifested in other arrangements and that the scope of the invention is not limited to the embodiments described or illustrated.
[0017] Embodiments of the invention relate to systems and methods for vaporizing water into steam, which may be utilized in applications such as bitumen production. The methods rely on indirect boiling of the water by contact with a substance such as solid particulate heated to a temperature sufficient to vaporize the water. Heating of the solid particulate may utilize pressure isolated heat exchanger units or a hot gas recirculation circuit at a pressure corresponding to that desired for the steam. Further, the water may form part of a mixture that contacts the solid particulate and includes a solvent for the bitumen in order to limit vaporization energy requirements and facilitate the production.
[0018] In any embodiments disclosed herein, the water may come from separated production fluid associated with a steam assisted gravity drainage (SAGD) bitumen recovery operation. The water at time of being generated into the steam may still contain: at least about 1000 parts per million (ppm), at least 10,000 ppm or at least 45,000 ppm total dissolved solids; at least 100 ppm, at least 500 ppm, at least 1000 ppm or at least 15,000 ppm organic compounds or organics; and at least 1000 ppm free oil. Injecting the steam through an injection well into the formation during the bitumen recovery operation thus enables sustainable recycle of the water without stringent treatment requirements of conventional boiler feed. [0019] Figure 1 illustrates a steam generating system that includes a first vessel 101 and a second vessel 102 that each contains solid particulate. As used herein, examples of the solid particulate include sand, metal spheres, cracking catalyst and mixtures thereof. In some embodiments, fluidization of the solid particulate keeps the solid particulate moving within the vessels 101, 102 during operation to generate steam. Such fluidization may involve circulation of the solid particulate and may rely on addition of supplemental steam.
[0020] Each of the vessels 101, 102 couples to a water injection line 104 and a heat source line 106. A manifold system controls flow through the vessels 101, 102 to a steam output 108 and an exhaust 110 and includes first through eighth valves 111-118. In operation, the valves 111-118 alternate between heating and steam generation cycles with the first vessel 101 being shown in the steam generation cycle while the second vessel 102 is in the heating cycle.
[0021] As shown, the first and fifth valves 111, 115 on the water injection line 104 and the steam output 108 thus remain open to flow of the water through the first vessel 101 to generate the steam while the third and seventh valves 113, 117 block flow of the water through the second vessel 102. The steam exits the first vessel 101 through the steam output 108, which may couple to the injection well, and is separated from the solid particulate that remains in the first vessel 101 and may be trapped by filters or cyclones. The second and sixth valves 112, 116 block flow from the heat source line 106 to the first vessel 101 at this time while the fourth and eighth valve 114, 118 are open to flow of oxygen and fuel, such as methane, from the heat source line 106 through the second vessel 102 to the exhaust 110. As thermal load of the solid particulate in the first vessel 101 becomes depleted, position of each of the valves 111-118 switches such that steam is generated in the second vessel 102 while the solid particulate is reheated in the first vessel 101.
[0022] The oxygen and fuel passing through the second vessel 102 combusts to reheat the solid particulate. During such combustion, contaminants, such as organic compounds deposited on the solid particulate from the water, may partially or fully convert into carbon dioxide and water, and some salts deposited on the solid particulate from the water may come off and be swept out of the second vessel 102. The combustion heats the solid particulate to a temperature that results in vaporizing the water upon contact therewith in the steam generation cycle that follows.
[0023] Not all embodiments rely on such cleaning of the solid particulate. Surface area of the solid particulate provides enough dispersion of the deposits to limit heat transfer interference. As needed over time, replacing some or part of the solid particulate may ensure desired performance is maintained at minimal cost and with limited to no interruption. For example, a lockhopper system employed with embodiments where the solid particulate is always in a pressurized environment can enable such withdrawal and replacement while in continuous operation.
[0024] Due to the first and second vessels 101, 102 with the manifold system, the heat source line 106 can supply the oxygen and fuel without compression to pressures desired for the steam to be injected into the formation. This relative lower pressure combustion facilitates economic production of the steam. Alternating each of the vessels 101, 102 between the steam generation cycle and the heating cycle also eliminates need for conveying the solid particulate to units dedicated to one particular cycle.
[0025] In some embodiments, the water mixes with a solvent 120 for the bitumen prior to vaporization due to contact with the solid particulate. The solvent 120 (common reference number depicted in all figures) thus may flow as a liquid into the water supply line 104 to form a resulting mixture of the water with the solvent 120. Vaporization of the water along with the solvent 120 results in the steam output 108 also containing both water and solvent vapors, as may be desired for injection into the formation.
[0026] The solvent 120 may include hydrocarbons having between 3 and 30 carbon atoms, such as butane, pentane, naphtha and diesel. Temperatures associated with the indirect boiling described herein limit potential problems of cracking the hydrocarbons, which can tend to occur if passed through direct fired boilers that may thus require injection of any wanted solvents into steam rather than boiler feed. Such injection of the solvent into the steam instead of the water feed may either cause loss of some steam due to condensation or require superheating of the steam. Conventional superheating of the steam also suffers from fouling problems. Therefore, the solvent 120 may flow into steam superheated by steam generation methods described herein in some embodiments since the fouling issues from the superheating are overcome in the same manner as those associated with steam generation.
[0027] The mixture in the water supply line 104 may include between 5 and 30 percent of the liquid hydrocarbon by volume. The mixture may further provide an energy requirement for vaporization that is at least 10 percent lower than water alone. For example, a 28:72 ratio of butane to water reduces steam generator duty by 22 percent as compared to water alone.
[0028] Figure 2 shows a steam generating system with a steam generating riser 200 and/or vessel 201 and a heating vessel 202 through which solid particulate are circulated. Similar to the system in Figure 1 , a heat source line 206 supplies reactants for combustion within the heating vessel 202 in order regain thermal energy used to vaporize water. Flue gases from the combustion exit the heating vessel 202 through exhaust 210 following any filtering to retain the solid particulate. Multiple alternating heating vessels with flow control similar to Figure 1 or lockhoppers may enable operation of the heating vessel 202 at a lower pressure than the steam generating riser 200 and/or vessel 201.
[0029] In some embodiments, the solid particulate heated in the heating vessel 202 transfers to the steam generating vessel 201 by gravity since the heating vessel 202 is disposed above the steam generating vessel 201. A water supply line 204 then inputs the water into contact with the solid particulate that is heated to result in vaporizing the water and providing a steam output 208. Some of the steam output 208 may provide lift for the solid particulate being returned up the riser 200 to the heating vessel 202. For some embodiments, the water vaporizes in the riser 200 such that the steam generating vessel 201 is not even required and the steam is recovered at a riser output 209.
[0030] Figure 3 illustrates a steam generating system with a heating vessel 302 in which heat is transferred to solid particulate via recycled gaseous fluid circulating in a circuit. Similar to systems in other figures, the solid particulate once heated transfers to a steam generating vessel 301 where water 304 is input to contact the solid particulate and generate steam 308. Embodiments may therefore implement various features and attributes explained in detail with respect to another particular figure or elsewhere herein without being repeated in order to be as succinct as possible. [0031] The gaseous fluid that exits the heating vessel 302 through an outlet 310 passes through heat exchanger(s) 350 and a fin-fan cooler 352, if necessary. The heat exchanger 350 may transfer heat with the gaseous fluid post compression boosting and/or with the water 304 being input into the steam generating vessel 301. Such heat exchange helps maintain efficiency while bringing the temperature of the gaseous fluid below temperature limits of a compressor 358 through which the gaseous fluid is sent downstream in the circuit.
[0032] A purge 354 allows removal of a portion of the gaseous fluid, which may pick up contaminants, such as from cracking or entrainment. Makeup gas 356 combines with the gaseous f uid to replace that purged. In some embodiments, the gaseous fluid includes an inert gas such as nitrogen and may also include air or oxygen for burning of the deposits. Methane may provide the gaseous fluid for some embodiments and may be desired due to its relative higher thermal capacity.
[0033] The compressor 358 only boosts pressure of the gaseous fluid circulating through the circuit. For example, the compressor may provide between 50 and 150 kilopascals (kPa) boost in pressure, which is achievable without making steam generation uneconomical by requiring levels of compression needed to increase atmospheric pressure to above 2500 kPa. The gaseous fluid in the circuit may thus always remain above 2500 kPa, in some embodiments.
[0034] The gaseous fluid from the compressor 358 then flows through the circuit to a furnace 360. The furnace 360 burns fuel to reheat the gaseous fluid that reenters the heating vessel 302 through a heat source line 306 for sustained heating of the solid particulate within the heating vessel 302. The heating vessel 302 may include multiple (e.g., 6 as shown) bed stages 362 or trays such that the solid particulate passing through the heating vessel 302 counter current with the gaseous fluid achieves efficient heat cross exchange.
[0035] Pressure of the steam desired for injection into the formation dictates pressure inside the steam generating vessel 301. With the recycled gaseous fluid circulating in the circuit to reheat the solid particulate, both the steam generating vessel 301 and the heating vessel 302 may operate at this pressure, such as above 2500 kPa, provided there may be sufficient differences in pressure in the vessels 301, 302 or other such arrangements described herein to maintain fluid flows. For some embodiments, a slipstream 364 of the gaseous fluid also at necessary pressure provides lift for transporting the solid particulate from the steam generating vessel 301 to the heating vessel 302.
[0036] Figure 4 shows a steam generating system with a heating vessel 402 in which heat is transferred to solid particulate via recycled gaseous fluid that is circulating in a circuit and condensed before reheating. While shown as being recycled, the gaseous fluid in some embodiments passes once through the vessel 402 and may then be utilized in another application. Like the system in Figure 3, the solid particulate once heated transfers to a steam generating vessel 401 where water 404 is input to contact the solid particulate and generate steam 408. The gaseous fluid that exits the heating vessel 402 through an outlet 410 passes through heat exchanger(s) 450 that transfer heat from flow along the circuit post pumping and/or with the water 404 being input into the steam generating vessel 401. The heat exchange 450 condenses the gaseous fluid, such as propane, butane or naphtha, to a liquid phase for pressurization by a pump 458. Before the pump 458, a separator 454 may enable venting off gasses that are not condensed, such as may result from cracking of the gaseous fluid.
[0037] Outflow from the pump 458 and any makeup 456 then flows through the circuit to a furnace 460. The furnace 460 burns fuel to vaporize and reheat the gaseous fluid that reenters the heating vessel 402 through a heat source line 406 for sustained heating of the solid particulate within the heating vessel 402. While pressure in the circuit again stays at a level similar to that desired for the steam to be injected into the formation, the pump 458 may influence efficiency if used in place of compression. Use of the pump 458 with the gaseous fluid that is condensed may further enable economic once through heating (i.e., without the circuit) at the desired pressure similar to approaches depicted in Figures 1 or 2 (i.e. replace oxygen and methane for combustion with a higher hydrocarbon pumped and then heated as in Figure 4) except that resulting exhaust may have further application for its energy content.
[0038] Figure 5 illustrates a steam generating system with a heating vessel 502 having an internal heat exchanger 562 to transfer heat to solid particulate from hot fluids without direct contact. Similar again to systems in other figures, the solid particulate once heated transfers to a steam generating vessel 501 where water 504 is input to contact the solid particulate and generate steam 508. Both the steam generating vessel 501 and the heating vessel 502 may operate in open pressure communication with one another at an internal pressure desired for injection of the steam into a formation while pressure isolated flow through the heat exchanger 562 may be at a lower pressure.
[0039] In operation, oxygen and fuel react in a combustor 560 to generate a flue gas conveyed to the heat exchanger 562 by a heat source line 506. The flue gas passes through the heat exchanger 562 and exits via an exhaust 510. A thermally conductive material forms the heat exchanger 562 such that heat from the flue gas transfers to the solid particulate in the heating vessel 502. In some embodiments, the thermally conductive material forms a tube of the heat exchanger. The tube may coil within the heating vessel 510 to provide the heat exchanger 562 with either the solid particulate flowing through an inside of the tube or the flue gas flowing through the inside of the tube.
[0040] For some embodiments, a fluidization gas, such as air, passes through the inside of the heating vessel 502. This gas may help remove contaminants from the solid particulate as well. Use of the gas for only fluidization while relying on heating by the heat exchanger 562 limits quantity and compression requirements for the gas whether the gas is used once through or circulated in a circuit.
[0041] Figure 6 shows a steam generating system with a single vessel 600 for vaporizing water upon contact with fluidized solid particulate disposed in the single vessel 600 and in thermal contact with a heat exchanger 662. The solid particulate heated by the heat exchanger 662 contacts water 604 that is input into the single vessel to generate steam 608. In operation, a circulating liquid, such as sodium or sodium and potassium, passes through the heat exchanger 662, exits the heat exchanger via an outlet 610 and is pumped by an pump 658 to a furnace 660 that reheats the circulating liquid prior flowing back to the heat exchanger 662 via inlet 606.
[0042] The heat exchanger 662 transfers heat from the circulating liquid to the solid particulate and may have a design such as described with respect to the heat exchanger 562 shown in Figure 5. Vaporization of the water 604 still occurs upon contacting the solid particulate that is heated. While the solid particulate thus should receive deposits from the water 604, movement of the solid particulate along the heat exchanger 662 provides abrasion to ensure that the heat exchanger 662 does not become fouled.
[0043] The heat exchangers 562, 662 in Figures 5 and 6 may each operate with either the flue gas or the circulating liquid as described herein providing hot fluid thereto. In some embodiments, systems may incorporate both the heat exchanger 662 where the steam is being generated along with additional heating of the solid particulate such as provided in the heating vessel 302 shown in Figure 3. Sharing this thermal load may enable efficient operation.
[0044] Figure 7 shows the system illustrated in Figure 3 with the steam generating vessel 301 disposed at a common elevation with the heating vessel 302 as opposed to a stacked vertical arrangement. This side -by-side configuration limits or eliminates need to use lift gas for transfer of the solid particulate. The solid particulate transfers between the steam generating vessel 301 and the heating vessel 302 via dense phase gravity drain as a result of such at least partial overlapping height. As shown, an upper outlet of the steam generating vessel 301 couples to a relative lower inlet of the heating vessel 302 for flow from the steam generating vessel 301 to the heating vessel 302. In a similar manner, a bottom outlet of the heating vessel 302 couples to a relative lower inlet of the steam generating vessel 301 for flow from the heating vessel 302 to the steam generating vessel 301.
[0045] Overall volumetric gas flow rate reduces as demand for the lift gas decreases. This flow rate reduction enables utilizing smaller recycle power requirement of the compressor 358 and cross exchanger surface area defined by the heating vessel 302, which both lower costs. Further, these benefits may facilitate selection of the gaseous fluid that otherwise may lack suitable thermal properties for heating the solid particulate.
[0046] Although the systems and processes described herein have been described in detail, it should be understood that various changes, substitutions, and alterations can be made without departing from the spirit and scope of the invention as defined by the following claims. Those skilled in the art may be able to study the preferred embodiments and identify other ways to practice the invention that are not exactly as described herein. It is the intent of the inventors that variations and equivalents of the invention are within the scope of the claims, while the description, abstract and drawings are not to be used to limit the scope of the invention. Each and every claim below is hereby incorporated into this detailed description or specification as additional embodiments of the present invention. The invention is specifically intended to be as broad as the claims below and their equivalents.

Claims

1. A method of vaporizing water, comprising:
introducing a gaseous fluid into a first vessel and in contact with solid particulate within the first vessel to transfer heat from the gaseous fluid to the solid particulate; recovering the gaseous fluid from the first vessel;
reheating the gaseous fluid recovered from the first vessel prior to circulating the gaseous fluid back into the first vessel for continued heating of the solid particulate; circulating the solid particulate between the first vessel and a second vessel;
introducing the water into the second vessel and in contact with the solid particulate heated to a temperature that results in vaporizing the water into steam; and separating the steam from the solid particulate.
2. The method according to claim 1, wherein the gaseous fluid includes at least one of nitrogen, methane, propane, butane, naphtha and oxygen.
3. The method according to claim 1, wherein the first and second vessel are maintained at pressures above 2500 kilopascals.
4. The method according to claim 1, wherein the gaseous fluid recovered from the first vessel is condensed into a liquid and pumped for pressurization prior to being reheated.
5. The method according to claim 1, wherein the gaseous fluid includes oxygen such that the reheating burns off organics from the water that are deposited on the solid particulate.
6. The method according to claim 1, wherein the first vessel is disposed beside the second vessel and the solid particulate transfers between the first vessel and the second vessel by dense phase gravity drain.
7. The method according to claim 1, wherein at least part of the gaseous fluid is directed to provide lift for transporting the solid particulate between the first and second vessels.
8. The method according to claim 1, wherein the first vessel includes multiple bed stages that the solid particulate passes through countercurrent with the gaseous fluid.
9. The method according to claim 1, further comprising also heating the solid particulate in the second vessel by heat exchange with hot fluids separated from the solid particulate by a thermally conductive material.
10. The method according to claim 1, wherein a riser forms the second vessel.
11. A system for vaporizing water, comprising:
a first vessel having an inlet and an outlet for a gaseous fluid and containing solid particulate in contact with the gaseous fluid that passes from the inlet to the outlet for transference of heat from the gaseous fluid to the solid particulate;
a heater coupled to the inlet and the outlet of the first vessel for reheating the gaseous fluid that is recovered from the outlet of the first vessel and circulated back to the inlet of the first vessel for sustained heating of the solid particulate;
a second vessel coupled to the first vessel by conduits through which the solid particulate is circulated between the first vessel and the second vessel;
an injection line coupled to the second vessel to supply the water into the second vessel and in contact with the solid particulate heated to a temperature that results in vaporization of the water into steam; and
a steam output line coupled to the second vessel for conveying the steam that is separated from the solid particulate.
12. The system according to claim 11, wherein the gaseous fluid includes at least one of nitrogen, methane, propane, butane, naphtha and oxygen.
13. The system according to claim 11, wherein the first and second vessel are at pressures above 2500 kilopascals.
14. The system according to claim 11, further comprising a condenser and pump coupled together such that the gaseous fluid recovered from the first vessel is condensed into a liquid and pumped to a preset pressure prior to being reheated.
15. The system according to claim 11, wherein the gaseous fluid includes oxygen to burn off organics from the water that are deposited on the solid particulate.
16. The system according to claim 11, further comprising a bypass for at least part of the gaseous fluid to provide lift for transporting the solid particulate between the first and second vessels.
17. The system according to claim 11 , wherein the first vessel is disposed above the second vessel such that the solid particulate transfers from the first vessel to the second vessel by gravity.
18. The system according to claim 11, wherein the first vessel includes multiple bed stages that the solid particulate passes through countercurrent with the gaseous fluid.
19. The system according to claim 11, further comprising a heat exchanger disposed in the second vessel that also heats the solid particulate by heat transfer with hot fluids separated from the solid particulate by thermally conductive material of the heat exchanger.
20. The system according to claim 11, wherein a riser forms the second vessel.
21. A method of vaporizing water, comprising:
heating solid particulate by heat exchange with hot fluids separated from the solid particulate by a thermally conductive material; introducing the water into contact with the solid particulate heated to a temperature that results in vaporizing the water into steam; and
separating the steam from the solid particulate.
22. The method according to claim 21, wherein the solid particulate is fluidized during the introducing of the water into contact therewith.
23. The method according to claim 21, wherein the hot fluids include one of combustion exhaust and heated liquid sodium.
24. The method according to claim 21, wherein the hot fluids include heated liquid sodium.
25. The method according to claim 21, wherein the hot fluids are at a lower pressure than that surrounding the solid particulate during the heating.
26. The method according to claim 21, wherein the heating of the solid particulate and the introducing of the water occurs in a single vessel.
27. The method according to claim 21, further comprising circulating the solid particulate between a first vessel where the heating of the solid particulate occurs and a second vessel where the introducing of the water occurs.
28. The method according to claim 21, wherein the heating of the solid particulate and the introducing of the water occur in separate vessels maintained at a common pressure.
29. The method according to claim 21, wherein the water vaporizes in a riser that circulates the solid particulate back to a vessel for the heating of the solid particulate.
30. The method according to claim 21, wherein the solid particulate includes at least one of sand, metals and cracking catalyst.
31. The method according to claim 21, further comprising supplying the water from separated production fluid associated with a steam assisted gravity drainage bitumen recovery operation and injecting the steam into a formation during the bitumen recovery operation.
32. A system for vaporizing water, comprising:
a heat exchanger for heating solid particulate with hot fluids separated from the solid particulate by a thermally conductive material;
an inlet to a steam generating vessel to supply the water into contact with the solid particulate heated to a temperature that results in vaporizing the water into steam; and an output to the steam generating vessel to convey the steam separated from the solid particulate.
33. The system according to claim 32, wherein the hot fluids include one of combustion exhaust and heated liquid sodium.
34. The system according to claim 32, wherein the heat exchanger is disposed inside the steam generating vessel.
35. The system according to claim 32, further comprising a heating vessel that contains the heat exchanger and is coupled for circulation of the solid particulate between the steam generating vessel and the heating vessel.
36. The system according to claim 32, further comprising a heating vessel that contains the heat exchanger and is in open pressure communication with the steam generating vessel.
37. The system according to claim 32, wherein the steam generating vessel includes a riser that circulates the solid particulate back to a heating vessel for the heating of the solid particulate.
38. The system according to claim 32, wherein the solid particulate includes at least one of sand, metals and cracking catalyst.
39. The system according to claim 32, wherein the water is separated from production fluid associated with steam assisted gravity drainage bitumen recovery and the output is coupled to inject the steam into a formation.
40. The system according to claim 32, wherein the thermally conductive material forms a tube of the heat exchanger through which one of the hot fluids and the solid particulate flow.
41. A method of vaporizing water, comprising:
introducing a solvent for bitumen into the water to form a mixture;
injecting the mixture into contact with solid particulate heated to a temperature that results in vaporizing the mixture; and
separating water and solvent vapors from the solid particulate.
42. The method according to claim 41, wherein the solvent includes hydrocarbons having between 3 and 30 carbon atoms and is introduced into the water as a liquid.
43. The method according to claim 41, further comprising injecting the water and solvent vapors into a formation during a steam assisted gravity drainage operation.
44. The method according to claim 41, wherein the solid particulate is fluidized during the injecting of the mixture into contact therewith.
45. The method according to claim 41, further comprising heating the solid particulate by direct contact with a hot fluid.
46. The method according to claim 41, further comprising heating the solid particulate by heat exchange with hot fluids separated from the solid particulate by a thermal conductive material.
47. The method according to claim 41, wherein the water contains at least 1000 parts per million (ppm) total dissolved solids and at least 100 ppm organics.
48. The method according to claim 41, wherein organics and dissolved solids in the water are retained in solid phase with the solid particulate following the separating.
49. The method according to claim 41 , further comprising alternating between passing the mixture through a vessel containing the solid particulate in order to vaporize the mixture and passing a hot fluid through the vessel to reheat the solid particulate.
50. The method according to claim 41 , further comprising alternating between passing the mixture at a first pressure through a vessel containing the solid particulate in order to vaporize the mixture and passing oxidant and fuel through the vessel for combustion therein at a second pressure below the first pressure.
51. The method according to claim 41, wherein the solid particulate is divided between first and second vessels operating in corresponding alternation between receiving the mixture for the vaporizing and receiving hot fluid for reheating the solid particulate.
52. A method of vaporizing water, comprising:
supplying the water from separated production fluid associated with a steam assisted gravity drainage bitumen recovery operation; introducing a liquid hydrocarbon into the water to form a mixture having an energy requirement for vaporization that is at least 10 percent lower than water alone; injecting the mixture into contact with a moving substance heated to result in vaporizing the mixture while at least some organics and dissolved solids in the water are retained with the moving substance; and
separating water and hydrocarbon vapors from the moving substance for injection of the vapors in the bitumen recovery operation.
53. The method according to claim 52, wherein the liquid hydrocarbon includes butane.
54. The method according to claim 52, wherein the mixture includes between 5 and 30 percent of the liquid hydrocarbon by volume.
55. The method according to claim 52, wherein the moving substance includes at least one of sand, metals and cracking catalyst.
56. The method according to claim 52, further comprising burning off the organics from the moving substance during reheating thereof.
57. A system for vaporizing water, comprising:
a steam generator coupled to receive liquids including a solvent for bitumen and the water;
solid particulate disposed in the steam generator and in thermal communication with a heat source for vaporization of the liquids that contact the solid particulate that is heated; and
an output coupled to the steam generator and through which the water and solvent vapors exit separated from the solid particulate.
58. The system according to claim 57, wherein the solid particulate is divided between first and second vessels that operate in corresponding alternation between receiving the liquids for the vaporization and hot fluid for reheating the solid particulate.
59. The system according to claim 57, further comprising valves coupled to the steam generator to alternate between passing the liquids at a first pressure through the steam generator for the vaporization and passing oxidant and fuel through the steam generator for combustion therein at a second pressure below the first pressure.
60. The system according to claim 57, wherein the solid particulate includes at least one of sand, metals and cracking catalyst fluidized in the steam generator.
PCT/US2013/073485 2012-12-17 2013-12-06 Heating for indirect boiling WO2014099407A1 (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CA2894864A CA2894864A1 (en) 2012-12-17 2013-12-06 Heating for indirect boiling

Applications Claiming Priority (8)

Application Number Priority Date Filing Date Title
US201261737973P 2012-12-17 2012-12-17
US201261737948P 2012-12-17 2012-12-17
US201261737967P 2012-12-17 2012-12-17
US61/737,967 2012-12-17
US61/737,948 2012-12-17
US61/737,973 2012-12-17
US14/097,496 US20140165930A1 (en) 2012-12-17 2013-12-05 Heating for indirect boiling
US14/097,496 2013-12-05

Publications (1)

Publication Number Publication Date
WO2014099407A1 true WO2014099407A1 (en) 2014-06-26

Family

ID=50979025

Family Applications (1)

Application Number Title Priority Date Filing Date
PCT/US2013/073485 WO2014099407A1 (en) 2012-12-17 2013-12-06 Heating for indirect boiling

Country Status (2)

Country Link
CA (1) CA2894864A1 (en)
WO (1) WO2014099407A1 (en)

Citations (11)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US5442919A (en) * 1993-12-27 1995-08-22 Combustion Engineering, Inc. Reheater protection in a circulating fluidized bed steam generator
US20060107587A1 (en) * 2004-10-12 2006-05-25 Bullinger Charles W Apparatus for heat treatment of particulate materials
US20100037835A1 (en) * 2008-02-26 2010-02-18 Ex-Tar Technologies Direct contact rotating steam generator using low quality water with zero liquid discharge
CA2676717A1 (en) * 2008-08-28 2010-02-28 Maoz Betzer-Zilevitch Fluid bed direct contact steam generator system and process
US20100212894A1 (en) * 2009-02-20 2010-08-26 Conocophillips Company Steam generation for steam assisted oil recovery
US20110120673A1 (en) * 2009-09-17 2011-05-26 Xiaodong Xiang Systems and methods of thermal transfer and/or storage
US20110259586A1 (en) * 2010-04-23 2011-10-27 Conocophillips Company Water treatment using a direct steam generator
WO2011114127A9 (en) * 2010-03-18 2011-12-15 William Curle Developments Limited Solids heat exchanger
US20120111109A1 (en) * 2010-11-05 2012-05-10 ThermoChem Recovery International Solids Circulation System and Method for Capture and Conversion of Reactive Solids
US20120241375A1 (en) * 2010-07-01 2012-09-27 Alexander Fassbender Wastewater treatment
CA2776389A1 (en) * 2011-05-06 2012-11-06 Maoz Betzer Non-direct contact steam generation

Patent Citations (12)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US5442919A (en) * 1993-12-27 1995-08-22 Combustion Engineering, Inc. Reheater protection in a circulating fluidized bed steam generator
US20060107587A1 (en) * 2004-10-12 2006-05-25 Bullinger Charles W Apparatus for heat treatment of particulate materials
US20100037835A1 (en) * 2008-02-26 2010-02-18 Ex-Tar Technologies Direct contact rotating steam generator using low quality water with zero liquid discharge
CA2676717A1 (en) * 2008-08-28 2010-02-28 Maoz Betzer-Zilevitch Fluid bed direct contact steam generator system and process
US20100050517A1 (en) * 2008-08-28 2010-03-04 Maoz Betzer Tsilevich Fluid bed direct contact steam generator system and process
US20100212894A1 (en) * 2009-02-20 2010-08-26 Conocophillips Company Steam generation for steam assisted oil recovery
US20110120673A1 (en) * 2009-09-17 2011-05-26 Xiaodong Xiang Systems and methods of thermal transfer and/or storage
WO2011114127A9 (en) * 2010-03-18 2011-12-15 William Curle Developments Limited Solids heat exchanger
US20110259586A1 (en) * 2010-04-23 2011-10-27 Conocophillips Company Water treatment using a direct steam generator
US20120241375A1 (en) * 2010-07-01 2012-09-27 Alexander Fassbender Wastewater treatment
US20120111109A1 (en) * 2010-11-05 2012-05-10 ThermoChem Recovery International Solids Circulation System and Method for Capture and Conversion of Reactive Solids
CA2776389A1 (en) * 2011-05-06 2012-11-06 Maoz Betzer Non-direct contact steam generation

Also Published As

Publication number Publication date
CA2894864A1 (en) 2014-06-26

Similar Documents

Publication Publication Date Title
JP6784455B2 (en) Integrated crude oil diesel hydrogen treatment and power generation from waste heat in aromatic facilities
JP2018534460A (en) Power generation from waste heat in an integrated crude oil refining and aromatics facility using three independent organic Rankine cycles
JP6750004B2 (en) Diesel hydrotreating, hydrocracking and continuous catalytic cracking, power generation from waste heat using two independent organic Rankine cycles in an aromatics facility
JP2018534459A (en) Power generation using two organic Rankine cycles independent of waste heat systems in diesel hydroprocessing, hydrocracking and atmospheric pressure distillation cracking, naphtha hydrotreating, and aromatics facilities
JP6784752B2 (en) Power generation from waste heat at integrated aromatic and naphtha block facilities
US8739866B2 (en) Method for extracting bitumen and/or ultra-heavy oil from an underground deposit, associated installation and operating method for said installation
US20120000830A1 (en) Process for upgrading heavy oil and bitumen products
US20080093264A1 (en) Steam generation apparatus and method
JP6808719B2 (en) Power generation from waste heat at integrated aromatic, crude oil distillation and naphtha block facilities
JP6702655B2 (en) Coal burning oxygen boiler power plant
JP6784457B2 (en) Integrated crude oil hydrocracking and power generation from waste heat in aromatic facilities
US8007729B2 (en) Apparatus for feed preheating with flue gas cooler
CN109844068B (en) Method and system for hydrocarbon steam cracking
RU2491321C2 (en) Method and device for preliminary heating of raw materials by means of cooler of waste gases
US11845706B2 (en) Method and plant for preparing vinyl chloride from 1,2-dichloroethane
US20140165930A1 (en) Heating for indirect boiling
US20140165929A1 (en) Water with solvent indirect boiling
WO2014099407A1 (en) Heating for indirect boiling
US20140165928A1 (en) Heat exchange for indirect boiling
US20150096754A1 (en) Indirect boiling for water treatment
CA2834946C (en) Heat exchange system
US20140166263A1 (en) Brine based indirect steam boiler
US20140166538A1 (en) Bitumen based indirect steam boiler
US8999146B2 (en) Process for feed preheating with flue gas cooler
WO2008049201A1 (en) Steam generation apparatus and method

Legal Events

Date Code Title Description
121 Ep: the epo has been informed by wipo that ep was designated in this application

Ref document number: 13864132

Country of ref document: EP

Kind code of ref document: A1

ENP Entry into the national phase

Ref document number: 2894864

Country of ref document: CA

NENP Non-entry into the national phase

Ref country code: DE

122 Ep: pct application non-entry in european phase

Ref document number: 13864132

Country of ref document: EP

Kind code of ref document: A1