• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    In a method of removing organic contaminants from a liquid, an oxidizing gas is formed into sub-micron size bubbles which are dispersed into an initially contaminated liquid, after which the treated liquid is recovered. The oxidizing gas is preferably selected from a group including ozone and chlorine dioxide and is utilized immediately upon its manufacture. An oxidizing liquid may be employed in conjunction with the oxidizing gas.
    公开号:US20010007314A1
    申请号:US09/767,287
    申请日:2001-01-22
    公开日:2001-07-12
    发明作者:Jeffrey Sherman
    申请人:Sherman Jeffrey H.;
    IPC主号:C02F1-78
    专利说明:
    [0001] This application is a continuation-in-part of application Ser. No. 09/325,503 filed Jun. 3, 1999, currently pending. [0001] TECHNICAL FIELD
    [0002] This invention relates generally to the treatment of contaminated liquids with oxidizing gases and oxidizing liquids, and more particularly to the treatment of liquids of the type having organic contaminants contained therein with oxidizing gases such as ozone and chlorine dioxide and with oxidizing liquids such as hydrogen peroxide. [0002] BACKGROUND AND SUMMARY OF THE INVENTION
    [0003] As is well known, various liquids are contaminated by organic materials. For example, used lubricating oil frequently includes organic materials comprising products of combustion. Waste water is almost always contaminated by organic materials such as human and animal waste, decaying vegetable materials, etc. [0003]
    [0004] As is also well known, organic contaminants can be removed from liquids by exposing the contaminated liquids to oxidizing agents, particularly oxidizing gases. Ozone and chlorine dioxide are among the most potent of the oxidizing gases, and therefore offer tremendous potential with respect to the removal of organic contaminants from used lubricating oil, waste water, and other liquids. Unfortunately, the inherent instability of ozone and chlorine dioxide has heretofore limited the efficient commercial utilization thereof in the removal of organic contaminants from liquids. [0004]
    [0005] Another problem involved in the removal of organic contaminants from liquids is the time duration of the exposure of an oxidizing agent to the contaminants in the liquid. As is known from Stoke's Law, larger bubbles use faster in a given liquid. Because it has heretofore not been possible to generate sub-micron size bubbles of oxidizing gases, much larger bubbles, bubbles in the 100-500 micron range, have necessarily been used. Due to the relatively rapid movement of larger bubbles, towers having substantial vertical height have been required in order to increase the time duration of the exposure of the oxidizing gas to the contaminated liquid. Unfortunately, increasing height of the tower increases the pressure that is necessary to overcome head pressure in order disperse the oxidizing gas in the liquid to be treated. [0005]
    [0006] Organic contaminants can also be removed from liquids by means of oxidizing liquids such as hydrogen peroxide. Oxidizing liquids are typically quite expensive relative to oxidizing gases. For this reason it has heretofore been impractical to utilize oxidizing liquids in wastewater treatment and similar large scale operations. [0006]
    [0007] The present invention comprises a method of and apparatus for utilizing oxidizing gases and oxidizing liquids to remove organic contaminants from liquids which overcomes the foregoing and other problems long since associated with the prior art. In accordance with the one aspect of the invention, oxidizing gas is utilized at its source and is formed into sub-micron size bubbles which are immediately dispersed into a flowing liquid to be decontaminated. Due to the sub-micron size of the bubbles, the surface area of the oxidizing gas is greatly increased, thereby greatly increasing the efficiency of the gas in oxidizing organic contaminants from the liquid. This in turn substantially reduces the vertical height necessary to effectively treat the contaminated liquid, thereby substantially reducing the pressure at which the oxidizing gas is used. [0007]
    [0008] In accordance with a first application of the invention, an oxidizing gas is selected from the group including ozone and chlorine dioxide. The oxidizing gas is formed into sub-micron size bubbles by directing it through a sintered stainless steel, sintered glass, sintered ceramic, or porous ceramic tube. Used lubricating oil is caused to flow past the exterior of the sintered/porous tube. The flowing liquid cleaves sub-micron size bubbles of the oxidizing gas from the surface of the tube. The sub-micron size bubbles of oxidizing gas are dispersed into the used lubricating oil, whereupon organic contaminants contained within the used lubricating oil are efficiently oxidized. [0008]
    [0009] In accordance with a second application of the invention, an oxidizing gas is selected from the group including ozone and chlorine dioxide. The oxidizing gas is formed into sub-micron sized bubbles by directing it through a sintered stainless steel, sintered glass, sintered ceramic, or porous ceramic tube. Waste water is caused to flow past the exterior of the tube. The flowing liquid cleaves sub-micron size bubbles of the oxidizing gas from the surface of the tube. The sub-micron size bubbles of oxidizing gas are dispersed into the waste water, whereupon organic contaminants contained within the waste water are efficiently oxidized. [0009]
    [0010] In accordance with a second aspect of the invention, the exterior surface of the sintered stainless steel, sintered glass, sintered ceramic or porous ceramic tube is provided with a coating of a radiation-activated catalyst such as titanium dioxide. During operation, the catalyst is activated by exposure by ultraviolet radiation, sunlight, visible light, or other electromagnetic radiation. Activation of the catalyst causes the formation of hydroxyl radicals in the contaminated liquid which augment the action of an oxidizing gas or an oxidizing liquid in the removal of organic contaminants from the liquid. [0010] BRIEF DESCRIPTION OF THE DRAWINGS
    [0011] A more complete understanding of the invention may be had by reference to the following Detailed Description when taken in conjunction with the accompanying Drawings, wherein: [0011]
    [0012] FIG. 1 is a flow chart illustrating a first embodiment of the invention; [0012]
    [0013] FIG. 2 is a flow chart illustrating a second embodiment of the invention; [0013]
    [0014] FIG. 3 is a diagrammatic illustration of a first apparatus useful in the practice of the method of the invention; [0014]
    [0015] FIG. 4 is a diagrammatic illustration of a second apparatus useful in the practice of the method of the invention; [0015]
    [0016] FIG. 5 is a diagrammatic illustration of a third apparatus useful in the practice of the method of the invention; [0016]
    [0017] FIG. 6 is a diagrammatic illustration of a third embodiment of the invention. [0017]
    [0018] FIG. 7 is a diagrammatic illustration of a fourth embodiment of the invention; and [0018]
    [0019] FIG. 8 is a further illustration of the embodiment of FIG. 7. [0019] DETAILED DESCRIPTION
    [0020] Referring now to the Drawings, and particularly to FIG. 1 thereof, there is shown a method for the treatment of contaminated liquids with oxidizing gases comprising a first embodiment of the invention. The first step of the method comprises the manufacture of an oxidizing gas utilizing conventional and well known techniques. The oxidizing gas preferably selected from the group including ozone and chlorine dioxide, however, other oxidizing gases may be utilized in the practice of the invention, if desired. Immediately upon its manufacture, the selected oxidizing gas is formed into sub-micron size bubbles. [0020]
    [0021] A quantity of used lubricating oil having organic contaminants contained therein, such as compounds of sulfur, nitrogen, etc., is caused to flow into engagement with the sub-micron size bubbles of oxidizing gas. The oxidizing gas bubbles are dispersed into the used lubricating oil whereupon organic contaminants contained within the oil are immediately oxidized. The sub-micron size of the bubbles of the oxidizing gas greatly increases the surface area of the oxidizing gas/used lubricating oil interface thereby substantially increasing the efficiency of the oxidizing reaction. Upon completion of the oxidation reaction, the treated lubricating oil is recovered for further processing and/or reuse. [0021]
    [0022] Referring to FIG. 2, there is shown a method for the treatment of contaminated liquids with oxidizing gases comprising a second embodiment of the invention. The first step of the method comprises the manufacture of an oxidizing gas utilizing conventional and well known techniques. The oxidizing gas preferably selected from the group including ozone and chlorine dioxide, however, other oxidizing gases may be utilized in the practice of the invention, if desired. Immediately upon its manufacture, the selected oxidizing gases are formed into sub-micron size bubbles. [0022]
    [0023] A quantity of waste water having organic contaminants contained therein is caused to flow into engagement with the sub-micron size bubbles of oxidizing gas. The oxidizing gas bubbles are dispersed into the waste water whereupon organic contaminants contained within the water are immediately oxidized. The sub-micron size of the bubbles of the oxidizing gas greatly increases the surface area of the oxidizing gas/waste water interface thereby substantially increasing the efficiency of the oxidizing reaction. Upon completion of the oxidation reaction, the treated water is recovered for discharge, further processing, and/or reuse. [0023]
    [0024] Referring now to FIG. 3 there is shown an apparatus [0024] 10 which may be utilized in the practice in the method of the invention. The apparatus 10 includes a hollow tube 12 formed from sintered stainless steel, sintered glass, sintered ceramic, or porous ceramic. Those skilled in the art will know and understand that other porous materials not subject to attack by oxidizing agents may be used in the practice of the invention. The sintered/porous tube 12 is positioned within a tank 14.
    [0025] An oxidizing gas is manufactured within a source [0025] 16 utilizing conventional and well known techniques. The oxidizing gas is preferably selected from the group including ozone and chlorine dioxide, however, other oxidizing gases may be utilized in the practice of the invention if desired. Immediately upon its manufacture the oxidizing gas from the source 16 is directed into the interior of the sintered/porous tube 12 through piping 18.
    [0026] Meanwhile a liquid having organic contaminants initially contained therein is caused to flow from a source [0026] 20 through piping 22 and the tank 14 to an outlet 24. The source 20 may comprise a conventional reservoir, tank, etc., which receives contaminated liquid from one or more sources. Alternatively, the source 20 may comprise the discharge from a facility which produces contaminated liquid in its operation.
    [0027] The pressure of the oxidizing gas within in the interior of the sintered/porous tube [0027] 12 is maintained high enough to prevent liquid contained within the tank 14 from flowing inwardly through the tube 12 into the interior thereof. Rather, oxidizing gas flows outwardly from the interior of the tube 12 under substantially less pressure than would be required in prior art apparatus. As the oxidizing gas flows outwardly, it is formed into sub-micron size bubbles which leave the exterior surface of the sintered stainless steel, sintered glass sintered ceramic, or porous ceramic tube 12 and are dispersed in the contaminated liquid.
    [0028] As the initially contaminated liquid from the source [0028] 20 flows through the tank 14, it passes over the exterior surface of the sintered/porous tube 12 thereby cleaving the sub-micron size bubbles of oxidizing gas from the exterior surface thereof. The sub-micron sized bubbles of oxidizing gas are immediately dispersed throughout the flowing liquid, whereupon organic contaminants contained within the liquid are immediately oxidized. It will be appreciated that because of the sub-micron size of the bubbles comprising the oxidizing gas the surface area of the interface between the oxidizing gas and the initially contaminated liquid is greatly increased, thereby greatly increasing the efficiency of the oxidizing reaction.
    [0029] An alternative apparatus [0029] 30 which may be utilized in the practice of the method of the invention is illustrated in FIG. 4. The apparatus 30 includes a sintered stainless steel, sintered glass, sintered ceramic, or porous ceramic tube 32 having a hollow interior which is supported within a tank 34 for rotation about its longitudinal axis. A motor 36 is positioned at one end of the tank 34 and is operatively connected to the tube 32 to effect rotation thereof relative to the tank 34. An annulus 38 is located at one end of the tank 34 and is separated from the tank 34 and from the motor 36 by seals 40. A collar 42 connects the annulus 38 to the interior of the sintered/porous tube 32 through a plurality of passageways 44.
    [0030] In the operation of the apparatus [0030] 30 an oxidizing gas is manufactured within a source 46 utilizing conventional and well known techniques. The oxidizing gas is preferably selected from the group including ozone and chlorine dioxide, however, other oxidizing gases may be utilized in the practice of the invention. Immediately upon its manufacture the oxidizing gases directed into the annalus 38 through piping 48. From the annalus 38 the oxidizing gas flows into the interior of the sintered stainless steel, sintered glass, sintered ceramic, or porous ceramic tube through the passageways 44 of the collar 42.
    [0031] A liquid having organic contaminants contained therein as received from a source [0031] 50. The source 50 may comprise a conventional reservoir or tank which receives the contaminated liquid from one or more sources. Alternatively, the source 50 may comprise the discharge of a facility which produces contaminated liquid as a part of its operation.
    [0032] Liquid having organic contaminants contained therein continuously flows from the source [0032] 50 through piping 52 and through the tank 34 to an outlet 54. The pressure of the oxidizing gas within the hollow interior of the tube 32 is maintained sufficiently high that liquid flowing through the tank 34 does not flow inwardly through the tube 32 into the interior thereof. Rather, oxidizing gas from the source 46 flows outwardly from the interior of the sintered or porous tube 32 to the outer surface thereof.
    [0033] The outwardly flowing oxidizing gas accumulates on the exterior surface of the sintered tube [0033] 32 in the form of sub-micron size bubbles. The sub-micron size bubbles of oxidizing gas are immediately cleaved from the exterior surface of the sintered tube by the flow of the initially contaminated liquid over the exterior surface of the sintered/porous tube 32. The sub-micron sized bubbles are dispersed throughout the flowing liquid whereby the organic contaminants initially contained within the flowing liquid are immediately oxidized. The sub-micron size of the bubbles of the oxidizing gas greatly increases the size of the interface between the oxidizing gas and the initially contaminated liquid, thereby greatly increasing the efficiency of the oxidation reaction.
    [0034] Treated liquid is recovered through the outlet [0034] 54. It is contemplated that all of the oxidizing gas will be consumed by the oxidizing reaction. If not, excess oxidizing gas may be recovered from the treated liquid through an outlet 56 and thereafter properly disposed of.
    [0035] In the operation of the apparatus [0035] 30 shown in FIG. 4, the exterior surface of the tube 32 is rotated relative to the liquid flowing through the tank 34 under the action of the motor 36. By this means the relative movement between the exterior surface of the tube 32 and the initially contaminated liquid flowing through the tank 34 is greatly increased. This in turn increases the number of sub-micron sized bubbles of oxidizing gas which is dispersed into the flowing liquid, thereby increasing the efficiency of the oxidation reaction.
    [0036] An alternative apparatus [0036] 60 which may be utilized in the practice of the method of the invention is illustrated in FIG. 5. The apparatus 60 includes a sintered stainless steel, sintered glass, sintered ceramic, or porous ceramic tube 62 having a hollow interior which is supported within a tank 64 for rotation about its longitudinal axis. One or more turbines 66 are mounted on the sintered/porous tube 62 to effect rotation thereof relative to the tank 64.
    [0037] In the operation of the apparatus [0037] 60 an oxidizing gas is manufactured within a source 76 utilizing conventional and well known techniques. The oxidizing gas is preferably selected from the group including ozone and chlorine dioxide, however, other oxidizing gases may be utilized in the practice of the invention. Immediately upon its manufacture the oxidizing gas is directed into the interior of the sintered or porous tube 62.
    [0038] A liquid having organic contaminants contained therein as received from a source [0038] 80. The source 80 may comprise a conventional reservoir or tank which receives the contaminated liquid from one or more sources. Alternatively, the source 80 may comprise the discharge of a facility which produces contaminated liquid as a part of its operation.
    [0039] Liquid having organic contaminants contained therein continuously flows from the source [0039] 80 through piping 82 and through the tank 64 to an outlet 84. The pressure of the oxidizing gas within the hollow interior of the tube 62 is maintained sufficiently high that liquid flowing through the tank 64 does not flow inwardly through the tube 62 into the interior thereof. Rather, oxidizing gas from the source 76 flows outwardly from the interior of the tube 62 to the outer surface thereof.
    [0040] The outwardly flowing oxidizing gas accumulates on the exterior surface of the sintered/porous tube [0040] 62 in the form of sub-micron size bubbles. The sub-micron size bubbles of oxidizing gas are immediately cleaved from the exterior surface of the sintered tube by the flow of the initially contaminated liquid over the exterior surface of the tube 62. The sub-micron sized bubbles are dispersed throughout the flowing liquid whereby the organic contaminants initially contained within the flowing liquid are immediately oxidized. The sub-micron size of the bubbles of the oxidizing gas greatly increases the size of the interface between the oxidizing gas and the initially contaminated liquid, thereby greatly increasing the efficiency of the oxidation reaction.
    [0041] Treated liquid is recovered through the outlet [0041] 84. It is contemplated that all of the oxidizing gas will be consumed by the oxidizing reaction. If not, excess oxidizing gas may be recovered from the treated liquid through an outlet 86 and thereafter properly disposed of.
    [0042] In the operation of the apparatus [0042] 60 shown in FIG. 5 the exterior surface of the sintered/porous tube 62 is rotated relative to the liquid flowing through the tank 64 under the action of the turbines 66. By this means the relative movement between the exterior surface of the sintered tube 62 and the initially contaminated liquid flowing through the tank 64 is greatly increased. This in turn increases the number of sub-micron sized bubbles of oxidizing gas which are dispersed into the flowing liquid, thereby increasing the efficiency of the oxidation reaction.
    [0043] Those skilled in the art will appreciate the fact that the use of the apparatus [0043] 30 shown in FIG. 4 or the apparatus 60 shown in FIG. 5 provides certain advantages with respect to the use of the apparatus shown in FIG. 3 in the practice of method of the invention. When the apparatus 30 of FIG. 4 is utilized, the relative movement between the exterior surface of the sintered/porous tube 32 and the initially contaminated liquid flowing through the tank 34 depends upon the operation of the motor 36 rather than the flow rate of the liquid. This allows a greater number of sub-micron size bubbles of oxidizing gas to be dispersed into the initially contaminated liquid than would be possible if the cleaving of sub-microns sized bubbles of oxidizing gas from the exterior surface of the tube 32 depended upon the flow of liquid alone. In this manner the efficiency of the oxidation reaction can be further increased.
    [0044] When the apparatus [0044] 60 of FIG. 5 is utilized, the relative movement between the exterior surface of the sintered/porous tube 62 and the initially contaminated liquid flowing through the tank 34 is greatly increased by the operation of the turbines 66. This allows a greater number of sub-micron size bubbles of oxidizing gas to be dispersed into the initially contaminated liquid than would be possible if the cleaving of sub-microns sized bubbles of oxidizing gas from the exterior surface of the tube 62 depended upon the flow of liquid alone. In this manner the efficiency of the oxidation reaction can be further increased.
    [0045] Referring now to FIG. 6, there is shown an apparatus [0045] 90 incorporating a third embodiment of the invention. The apparatus 90 includes many component parts which are substantially identical in construction and function to the component parts of the apparatus 10 illustrated in FIG. 3 and described hereandabove in conjunction therewith. Such identical component parts are designated in FIG. 6 with the same reference numerals utilized in the description of the apparatus 10, but are differentiated thereof by means of a prime (′) designation.
    [0046] The apparatus [0046] 90 differs from the apparatus 12 in that the sintered tube 12′ thereof is provided with a photocatalytic layer 92 on its exterior surface. The photocatalytic layer 92 may be activated by ultraviolet radiation from a source 94. Alternatively, the photocatalytic layer 92 may be activated by sunlight, or by visible light or by other portions of the electromagnetic spectrum.
    [0047] Activation of the photocatalytic layer [0047] 92 results in the formation of hydroxyl radicals in the initially contaminated liquid flowing between the sintered tube 12′ and the tank 14′. The hydroxyl radicals thus formed augment the action of an oxidizing gas or an oxidizing liquid in the removal of organic contaminants from the initially contaminated liquid.
    [0048] Specifically, ozone may be utilized in the operation of the apparatus [0048] 90. Ozone is manufactured by passing oxygen, or air containing oxygen, through an electrically generated corona discharge. Although commonly referred to as “ozone”, the resulting oxidizing gas actually comprises 20% or less of ozone, with the remainder comprising oxygen or air.
    [0049] Upon activation of the photocatalytic layer [0049] 92 on the exterior of the sintered tube 12′, the ozone component of the oxidizing gas generates hydroxyl radicals more efficiently than would otherwise be the case. Additionally, the oxygen component of the oxidizing gas also responds to the activation of the photocatalytic layer 92 to produce hydroxyl radicals. As will be appreciated by those skilled in the art, it is the hydroxyl radicals that actually comprise the oxidizing agent in the operation of the apparatus 90.
    [0050] The apparatus [0050] 90 may also utilize chlorine dioxide as the oxidizing gas. In the operation of the apparatus 90, air or oxygen is mixed into the chlorine dioxide with the resulting mixture directed through the sintered tube 12′ and the photocatalytic layer 92 into the initially contaminated liquid in the tank 14′. The chlorine dioxide generates chlorine species as oxidizing agents. Upon activation of the photocatalytic layer 92, hydroxyl radicals are generated from the oxygen component of the oxidizing gas. Both the chlorine species and the hydroxyl radicals serve as oxidizing agents to remove organic contaminants from the liquid.
    [0051] The apparatus [0051] 90 may also be operated utilizing a liquid oxidizing agent such as hydrogen peroxide. In such instances the liquid oxidizing agent is metered into the liquid stream from a source 96. Air, oxygen, or ozone is directed through the sintered tube 12′ and the photocatalytic layer 92 into the initially contaminated liquid. Activation of the photocatalytic layer 92 forms hydroxyl radicals from the oxygen component of the gas stream. In this manner the quantity of the liquid oxidizing agent necessary to remove organic components from the initially contaminated liquid is substantially reduced.
    [0052] It will be appreciated that the structural components of the apparatus [0052] 90 are virtually identical to those of the apparatus 10 of FIG. 3 except for the addition of the photocatalytic layer 92 and the source of ultraviolet light radiation 94 (if used). Similar modifications can be made to the apparatus 30 of FIG. 4, that is, a photocatalytic layer can be applied to the exterior surface of the sintered/porous tube 32 for activation by a source of ultraviolet radiation or sunlight. Likewise, the exterior surface of the sintered/porous tube 62 of the apparatus 60 of FIG. 5 may be provided with a photocatalytic layer adapted for activation by the source of ultraviolet radiation or sunlight. As indicated hereandabove, the generation of sub-micron bubbles in the initially contaminated liquid is increased by means of the motor of the apparatus 30 or the turbines of the apparatus 60 as well as the fact that the sub-micron size of the bubbles causes them to move more slowly through the contaminant liquid, thereby increasing reaction efficiency.
    [0053] Referring now to FIGS. 7 and 8, there is shown a method of and apparatus for treating contaminated liquid [0053] 100 comprising a fourth embodiment of the invention. In accordance with a fourth embodiment of the invention, there is provided a tank 102 having a quantity of contaminated water or other contaminated liquid 104 contained therein. Water or other liquid us supplied to the tank 102 from a source 106 through piping 107.
    [0054] A hollow disk [0054] 108 is mounted in the lower portion of the tank 102. As is best shown in FIG. 8, the disk 108 includes a gas permeable partition 110 supported on a tube 112 for rotation within the tank 102 under the operation under the motor 114. The partition 110 may comprise sintered stainless steel, sintered glass, sintered ceramic, or porous ceramic materials depending upon the requirements of particular applications of the invention. Oxidizing gas received from a supply 116 is directed through piping 118 and a suitable commutator 120 into the tube 112 and through the tube 112 into the interior of the hollow disk 108. The tube 112 has a hollow interior 121 and the disk 108 has a hollow interior 122 connected in fluid communication therewith.
    [0055] The disk [0055] 108 is supplied with oxidizing gas at a pressure just high enough to overcome the head pressure of the water or other liquid 104. The disk 108 is rotated by the motor 114 at an appropriate speed in contact with the water or other liquid 104 such that a shearing phenomen occurs at the surface of the gas permeable partition 110 thus producing bubbles of extremely small, i.e., sub-micron, size. The extreme small size of the bubbles thus produced results in a surface area to volume ratio of small bubbles which significantly improves the efficiency of the reaction, in particular because the required vertical height of the tank 102 and therefore the pressure of the gas is substantially reduced due to the slower movement of the small bubbles in the liquid. Liquid is recovered from the tank 102 through outlet 123 and any residual gas is recovered from the tank 102 through outlet 124.
    [0056] Although preferred embodiments of the invention have been illustrated in the accompanying Drawings and described in the foregoing Detailed Description, it will be understood that the invention is not limited to the embodiments disclosed, but is capable of numerous rearrangements, modifications, and substitutions of parts and elements without departing from the spirit of the invention. [0056]
    权利要求:
    Claims (20)
    [1" id="US-20010007314-A1-CLM-00001] 1. A method of removing organic contaminants from liquids comprising the steps of:
    providing an oxidizing gas at least a portion of which is oxygen;
    forming the oxidizing gas into sub-micron size bubbles;
    providing a photocatalyst;
    providing a flow of initially contaminated liquid;
    dispersing the sub-micron size bubbles of oxidizing gas into the flowing initially contaminated liquid while simultaneously activating the photocatalyst;
    recovering the treated liquid.
    [2" id="US-20010007314-A1-CLM-00002] 2. The method of
    claim 1 wherein the oxidizing gas is selected from the group including ozone, chlorine dioxide, oxygen, and air.
    [3" id="US-20010007314-A1-CLM-00003] 3. The method of
    claim 2 wherein at least part of the oxidizing gas is formed into sub-micron size bubbles and dispersed into the flowing initially contaminated liquid immediately upon its manufacture.
    [4" id="US-20010007314-A1-CLM-00004] 4. The method according to
    claim 1 wherein:
    the oxidizing gas is directed through sintered material to an exterior surface; and
    the flowing initially contaminated liquid is directed across the exterior surface thereby cleaving sub-micron sized bubbles of oxidizing gas from the exterior surface.
    [5" id="US-20010007314-A1-CLM-00005] 5. The method according to
    claim 4 wherein the photocatalyst is the exterior surface of the sintered material.
    [6" id="US-20010007314-A1-CLM-00006] 6. The method according to
    claim 4 including the additional step of moving the exterior surface relative to the flowing liquid.
    [7" id="US-20010007314-A1-CLM-00007] 7. A method of removing organic contaminants from a petroleum distillate comprising the steps of:
    providing an oxidizing gas, at least a portion of which is oxygen;
    forming the oxidizing gas into sub-micron size bubbles;
    providing a photocatalyst;
    providing a flow of initially contaminated petroleum distillates;
    dispersing the sub-micron sized bubbles of oxidizing gas into the flowing initially contaminated petroleum distillates while simultaneously activating the photocatalyst; and
    recovering the treated petroleum distillates.
    [8" id="US-20010007314-A1-CLM-00008] 8. The method of
    claim 7 wherein the oxidizing gas is selected from the group including ozone, chlorine dioxide, oxygen, and air.
    [9" id="US-20010007314-A1-CLM-00009] 9. The method of
    claim 8 wherein at least part of the oxidizing gas is formed into sub-micron size bubbles and dispersed into the flowing initially contaminated petroleum distillate immediately upon its manufacture.
    [10" id="US-20010007314-A1-CLM-00010] 10. The method according to
    claim 7 wherein:
    the oxidizing gas is directed through sintered material to an exterior surface; and
    the flowing initially contaminated petroleum distillate is directed across the exterior surface thereby cleaving sub-micron sized bubbles of oxidizing gas from the exterior surface.
    [11" id="US-20010007314-A1-CLM-00011] 11. The method according to
    claim 10 wherein the photocatalyst is the exterior surface of the sintered material.
    [12" id="US-20010007314-A1-CLM-00012] 12. The method according to
    claim 10 including the additional step of moving the exterior surface relative to the flowing petroleum distillate.
    [13" id="US-20010007314-A1-CLM-00013] 13. A method of removing organic contaminants from waste water comprising the steps of:
    providing an oxidizing gas;
    forming the oxidizing gas into sub-micron size bubbles;
    providing a photocatalyst;
    providing a flow of initially contaminated waste water;
    dispersing the sub-micron sized bubbles of oxidizing gas into the flowing initially contaminated waste water while simultaneously activating the photocatalyst; and
    recovering the treated water.
    [14" id="US-20010007314-A1-CLM-00014] 14. The method of
    claim 12 wherein the oxidizing gas is selected from the group including ozone, chlorine dioxide, oxygen, and air.
    [15" id="US-20010007314-A1-CLM-00015] 15. The method of
    claim 14 wherein at least part of the oxidizing gas is formed into sub-micron size bubbles and dispersed into the flowing initially contaminated waste water immediately upon its manufacture.
    [16" id="US-20010007314-A1-CLM-00016] 16. The method according to
    claim 13 wherein:
    the oxidizing gas is directed through sintered material to an exterior surface; and
    the flowing initially contaminated waste water is directed across the exterior surface thereby cleaving sub-micron sized bubbles of oxidizing gas from the exterior surface.
    [17" id="US-20010007314-A1-CLM-00017] 17. The method according to
    claim 16 wherein the photocatalyst is the exterior surface of the sintered material.
    [18" id="US-20010007314-A1-CLM-00018] 18. The method according to
    claim 16 including the additional step of moving the exterior surface relative to the flowing liquid.
    [19" id="US-20010007314-A1-CLM-00019] 19. The method according to
    claim 13 including the additional step of dispersing an oxidizing liquid into the waste water.
    [20" id="US-20010007314-A1-CLM-00020] 20. The method according to
    claim 20 wherein the oxidizing liquid includes hydrogen peroxide.
    类似技术:
    公开号 | 公开日 | 专利标题
    US6383399B2|2002-05-07|Treatment of contaminated liquids with oxidizing gases and liquids
    US6030526A|2000-02-29|Water treatment and purification
    US6391272B1|2002-05-21|Method for exhaust gas decontamination
    JP4224817B2|2009-02-18|Method for treating 1,4-dioxane
    KR100581746B1|2006-05-22|System for treating water
    JP2003190976A|2003-07-08|Apparatus and method for treating wastewater
    JPH05228480A|1993-09-07|Device for processing hardly biodegradable substance
    JP2005144352A|2005-06-09|High-speed ozone catalytic reaction apparatus
    US6238628B1|2001-05-29|Photolytic device for breakdown of organic chlorine compounds
    US6103130A|2000-08-15|Treatment of contaminated liquids with oxidizing gases
    JPH05228481A|1993-09-07|Device for processing hardly biodegradable substance
    JP2006272034A|2006-10-12|Contamination gas treatment device and method using photocatalyst
    JP2005152815A|2005-06-16|Sewage treatment apparatus
    US7837952B2|2010-11-23|System and method for removal of hydrogen peroxide from a contaminated media
    JP4285468B2|2009-06-24|Accelerated oxidation treatment equipment using ozone and photocatalyst
    KR100354583B1|2003-03-19|Ozone deodorizer
    JP2888185B2|1999-05-10|UV oxidation equipment
    JP2006281005A|2006-10-19|Apparatus and method for treating water using photocatalyst
    JP3466083B2|2003-11-10|Decomposition method of organic chlorine compounds such as dioxins in landfill leachate
    JP2009112953A|2009-05-28|Method and apparatus for treating water
    JPH11267670A|1999-10-05|Treating device using photocatalyst
    JP2002119982A|2002-04-23|Apparatus, system and method for decomposing dioxins
    JP4172415B2|2008-10-29|Multistage treatment equipment for contaminated water
    JP4569884B2|2010-10-27|Method and apparatus for treating organic matter in water
    JP2002177952A|2002-06-25|Water treatment method using photocatalyst as well as water treating material using photocatalyst and method of manufacturing for the same
    同族专利:
    公开号 | 公开日
    US6444131B1|2002-09-03|
    US20020079272A1|2002-06-27|
    US6251289B1|2001-06-26|
    US6596177B2|2003-07-22|
    US20010015339A1|2001-08-23|
    WO2000075083A1|2000-12-14|
    CA2373896A1|2000-12-14|
    AU5034600A|2000-12-28|
    EP1202937A1|2002-05-08|
    US6383399B2|2002-05-07|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    EP1338565A2|2002-02-26|2003-08-27|United States Filter Corporation|Free Radical Generator and method for water treatment|
    US20050109709A1|2002-02-26|2005-05-26|Usfilter Corporation|Enhanced air and water purification using continuous breakpoint halogenation with free oxygen radicals|
    US20080061006A1|2006-09-07|2008-03-13|Kerfoot William B|Enhanced reactive ozone|
    US20080245738A1|2007-04-03|2008-10-09|Siemens Water Technologies Corp.|Method and system for providing ultrapure water|
    EP2487217A1|2007-03-28|2012-08-15|William B. Kerfoot|Treatment for recycling fracture water - gas and oil recovery in shale deposits|
    WO2012151233A1|2011-05-02|2012-11-08|Lake Country Fracwater Specialists, Llc|Method and apparatus for treating natural gas and oil well drilling waste water|
    US8591730B2|2009-07-30|2013-11-26|Siemens Pte. Ltd.|Baffle plates for an ultraviolet reactor|
    US8652336B2|2006-06-06|2014-02-18|Siemens Water Technologies Llc|Ultraviolet light activated oxidation process for the reduction of organic carbon in semiconductor process water|
    US8741155B2|2007-04-03|2014-06-03|Evoqua Water Technologies Llc|Method and system for providing ultrapure water|
    US8753522B2|2007-04-03|2014-06-17|Evoqua Water Technologies Llc|System for controlling introduction of a reducing agent to a liquid stream|
    WO2014145825A1|2013-03-15|2014-09-18|Sabre Intellectual Property Holdings Llc|Method and system for the treatment of produced water and fluids with chlorine dioxide for reuse|
    US8877067B2|2011-05-26|2014-11-04|Evoqua Water Technologies Llc|Method and arrangement for a water treatment|
    US20140353259A1|2011-12-16|2014-12-04|Sven Strunk|Oxidation Method, Nozzle and System for Treating Waste Water|
    US8961798B2|2007-04-03|2015-02-24|Evoqua Water Technologies Llc|Method for measuring a concentration of a compound in a liquid stream|
    US9238587B2|2013-03-15|2016-01-19|Sabre Intellectual Property Holdings Llc|Method and system for the treatment of water and fluids with chlorine dioxide|
    US9365435B2|2007-04-03|2016-06-14|Evoqua Water Technologies Llc|Actinic radiation reactor|
    US9365436B2|2007-04-03|2016-06-14|Evoqua Water Technologies Llc|Method of irradiating a liquid|
    US9725343B2|2007-04-03|2017-08-08|Evoqua Water Technologies Llc|System and method for measuring and treating a liquid stream|
    EP3092291A4|2014-01-06|2017-11-01|Aquifer Maintenance & Performance Systems, Inc.|Systems and methods for removing sulfur and halogens|
    US10343939B2|2006-06-06|2019-07-09|Evoqua Water Technologies Llc|Ultraviolet light activated oxidation process for the reduction of organic carbon in semiconductor process water|
    US10442711B2|2013-03-15|2019-10-15|Sabre Intellectual Property Holdings Llc|Method and system for the treatment of produced water and fluids with chlorine dioxide for reuse|
    US10494281B2|2015-01-21|2019-12-03|Evoqua Water Technologies Llc|Advanced oxidation process for ex-situ groundwater remediation|
    US10526530B2|2013-04-24|2020-01-07|Sabre Intellectual Property Holdings Llc|Flooding operations employing chlorine dioxide|
    US11161762B2|2015-01-21|2021-11-02|Evoqua Water Technologies Llc|Advanced oxidation process for ex-situ groundwater remediation|US3310380A|1964-02-13|1967-03-21|Universal Oil Prod Co|Bromine recovery|
    US3847800A|1973-08-06|1974-11-12|Kvb Eng Inc|Method for removing sulfur and nitrogen in petroleum oils|
    CA1048733A|1977-02-02|1979-02-20|Anthony J. Last|Ozone/ultraviolet water purifier|
    US4274970A|1979-10-29|1981-06-23|Beitzel Stuart W|Method and apparatus for treating water|
    US4485007A|1982-06-15|1984-11-27|Environmental Research And Technology Inc.|Process for purifying hydrocarbonaceous oils|
    US4494961A|1983-06-14|1985-01-22|Mobil Oil Corporation|Increasing the cetane number of diesel fuel by partial oxidation _|
    US4643820A|1986-02-24|1987-02-17|Oxiprocessing|Process for enhancing the cetane number of diesel fuel|
    US5122312A|1991-03-05|1992-06-16|Mott Metallurgical Corporation|Bubble injection system|
    US5156173A|1991-05-14|1992-10-20|Envirosolv|High-efficiency, low-emissions cleaning method and apparatus|
    US5271810A|1991-05-14|1993-12-21|Environmental Solvents Corporation|Distillation device for purifying liquid mixtures|
    US5152888A|1991-10-24|1992-10-06|Net Co., Ltd.|Apparatus for treatment of organic waste water and contactor for use therein|
    US5151187A|1991-11-19|1992-09-29|Zenon Environmental, Inc.|Membrane bioreactor system with in-line gas micronizer|
    US5316682A|1993-03-25|1994-05-31|Key Solutions, Inc.|Gas micronizer and purification system and related methods|
    US5510544A|1993-08-02|1996-04-23|Environmental Solvents Corporation|Fluorinated terpene compounds|
    US5690482A|1994-11-04|1997-11-25|Integrated Energy Development Corp.|Process for the combustion of sulphur containing fuels|
    US5855775A|1995-05-05|1999-01-05|Kerfoot; William B.|Microporous diffusion apparatus|
    US5658458A|1995-11-08|1997-08-19|Micronair, Inc.|Apparatus for removing suspended inert solids from a waste stream|
    US5910440A|1996-04-12|1999-06-08|Exxon Research And Engineering Company|Method for the removal of organic sulfur from carbonaceous materials|
    US5868945A|1996-08-29|1999-02-09|Texaco Inc|Process of treating produced water with ozone|
    US6030526A|1996-12-31|2000-02-29|Uv Technologies, Inc.|Water treatment and purification|
    US5849201A|1997-06-02|1998-12-15|Mva Inc.|Oxidation of aromatic hydrocarbons|
    US6160193A|1997-11-20|2000-12-12|Gore; Walter|Method of desulfurization of hydrocarbons|
    US6197206B1|1998-09-17|2001-03-06|Eric M. Wasinger|Process and apparatus for purifying methyl tert-butyl ether contaminated water|
    US6368495B1|1999-06-07|2002-04-09|Uop Llc|Removal of sulfur-containing compounds from liquid hydrocarbon streams|USRE43350E1|1995-05-05|2012-05-08|Think Village-Kerfoot, Llc|Microporous diffusion apparatus|
    US5855775A|1995-05-05|1999-01-05|Kerfoot; William B.|Microporous diffusion apparatus|
    US8557110B2|2000-07-06|2013-10-15|Thinkvillage-Kerfoot, Llc|Groundwater and subsurface remediation|
    US6582611B1|2000-07-06|2003-06-24|William B. Kerfoot|Groundwater and subsurface remediation|
    WO2004067456A1|2003-01-28|2004-08-12|Al Be Farm Research & Development Ltd.|A method and system for treating water|
    US8302939B2|2003-02-12|2012-11-06|Thinkvillage-Kerfoot, Llc|Soil and water remediation system and method|
    US6913251B2|2003-02-12|2005-07-05|William B. Kerfoot|Deep well sparging|
    US7442313B2|2003-08-27|2008-10-28|Thinkvillage-Kerfoot, Llc|Environmental remediation method and system|
    US8771507B2|2003-12-24|2014-07-08|Thinkvillage-Kerfoot, Llc|Directional microporous diffuser and directional sparging|
    US7401767B2|2003-12-24|2008-07-22|Kerfoot William B|Directional microporous diffuser and directional sparging|
    JP4559188B2|2003-12-26|2010-10-06|東洋製罐株式会社|Oxide coating method and apparatus|
    US7213642B2|2004-03-05|2007-05-08|Kerfoot William B|Multi-fluid sparging|
    US7666316B2|2004-07-20|2010-02-23|Thinkvillage-Kerfoot, Llc|Permanganate-coated ozone for groundwater and soil treatment with in-situ oxidation|
    US7547388B2|2004-07-20|2009-06-16|Think Village-Kerfoot, Llc|Superoxidant poiser for groundwater and soil treatment with in-situ oxidation-reduction and acidity-basicity adjustment|
    CA2589399A1|2004-12-29|2006-07-06|Bp Corporation North America Inc.|Oxidative desulfurization process|
    WO2007049287A2|2005-10-28|2007-05-03|Indian Oil Corporation Limited|Method for bio-oxidative desulfurization of liquid hydrocarbon fuels and product thereof|
    US20080000821A1|2006-02-15|2008-01-03|Liquid Separation Technologies And Equipment, Llc|Apparatus for water decontamination|
    US20080000819A1|2006-02-15|2008-01-03|Liquid Separation Technologies And Equipment, Llc|Water decontamination systems|
    US20080000839A1|2006-02-15|2008-01-03|Liquid Separation Technologies And Equipment, Llc|Methods of water decontamination|
    US7820137B2|2006-08-04|2010-10-26|Enerdel, Inc.|Lithium titanate and method of forming the same|
    KR100612412B1|2006-06-14|2006-08-16|이재흥|Apparatus for mixing ozone-water|
    US7651611B2|2006-07-12|2010-01-26|Thinkvillage-Kerfoot, Llc|Directional microporous diffuser and directional sparging|
    US20080011599A1|2006-07-12|2008-01-17|Brabender Dennis M|Sputtering apparatus including novel target mounting and/or control|
    US20080179256A1|2007-01-23|2008-07-31|Purifics Environmental Technologies, Inc.|System and method for chemical-free metal particle removal from a liquid media|
    US7691953B2|2007-06-27|2010-04-06|H R D Corporation|System and process for production of polyvinyl chloride|
    US7750188B2|2007-06-27|2010-07-06|H R D Corporation|System and process for the production of aniline and toluenediamine|
    US7592493B2|2007-06-27|2009-09-22|H R D Corporation|High shear process for cyclohexanol production|
    US8304584B2|2007-06-27|2012-11-06|H R D Corporation|Method of making alkylene glycols|
    US7479576B1|2007-06-27|2009-01-20|H R D Corporation|Method of hydrogenating aldehydes and ketones|
    US7491856B2|2007-06-27|2009-02-17|H R D Corporation|Method of making alkylene glycols|
    JP5139523B2|2007-06-27|2013-02-06|エイチアールディーコーポレーション|System and method for producing nitrobenzene|
    US7842184B2|2007-06-27|2010-11-30|H R D Corporation|Process for water treatment using high shear device|
    US7919645B2|2007-06-27|2011-04-05|H R D Corporation|High shear system and process for the production of acetic anhydride|
    US8022153B2|2007-06-27|2011-09-20|H R D Corporation|System and process for production of polyethylene and polypropylene|
    US8278494B2|2007-06-27|2012-10-02|H R D Corporation|Method of making linear alkylbenzenes|
    US20090005619A1|2007-06-27|2009-01-01|H R D Corporation|High shear process for the production of chlorobenzene|
    US7652175B2|2007-06-27|2010-01-26|H R D Corporation|High shear process for the production of acetaldehyde|
    US8080684B2|2007-06-27|2011-12-20|H R D Corporation|Method of producing ethyl acetate|
    US7749481B2|2007-06-27|2010-07-06|H R D Corporation|System and process for gas sweetening|
    US8518186B2|2007-06-27|2013-08-27|H R D Corporation|System and process for starch production|
    US7652174B2|2007-06-27|2010-01-26|H R D Corporation|High shear process for the production of chloral|
    US8101089B2|2007-08-15|2012-01-24|Liquid Separation Technologies And Equipment, Llc|Apparatus for aeration of contaminated liquids|
    EP2042231A1|2007-09-28|2009-04-01|Grundfos BioBooster A/S|Aeration device|
    US20100204964A1|2009-02-09|2010-08-12|Utah State University|Lidar-assisted multi-image matching for 3-d model and sensor pose refinement|
    EP2516337B1|2009-12-24|2019-05-29|BCR Environmental Corporation|Improved digestion of biosolids in wastewater|
    US20110220589A1|2010-03-15|2011-09-15|Verhoeve Milieu B.V.|Fluid treatment apparatus, a fluid treatment system and a method for producing a flow of fluid comprising ozone|
    US9296960B2|2010-03-15|2016-03-29|Saudi Arabian Oil Company|Targeted desulfurization process and apparatus integrating oxidativedesulfurization and hydrodesulfurization to produce diesel fuel having an ultra-low level of organosulfur compounds|
    US20110220550A1|2010-03-15|2011-09-15|Abdennour Bourane|Mild hydrodesulfurization integrating targeted oxidative desulfurization to produce diesel fuel having an ultra-low level of organosulfur compounds|
    KR20130099811A|2010-04-27|2013-09-06|비씨알 엔바이런멘탈 코포레이션|Wastewater treatment apparatus to achieve class b biosolids using chlorine dioxide|
    US9290712B2|2010-09-03|2016-03-22|Her Majesty The Queen In Right Of Canada As Represented By The Minister Of Natural Resources Canada|Production of high-cetane diesel product|
    CA2858727A1|2011-12-13|2013-06-20|Soane Energy, Llc|Treatment of wastewater|
    US8906227B2|2012-02-02|2014-12-09|Suadi Arabian Oil Company|Mild hydrodesulfurization integrating gas phase catalytic oxidation to produce fuels having an ultra-low level of organosulfur compounds|
    US9272924B2|2012-10-25|2016-03-01|ABC Sails, Inc.|Process and apparatus to remove and destroy volatile organic compounds by atomizing water in ozone atmosphere|
    US8920635B2|2013-01-14|2014-12-30|Saudi Arabian Oil Company|Targeted desulfurization process and apparatus integrating gas phase oxidative desulfurization and hydrodesulfurization to produce diesel fuel having an ultra-low level of organosulfur compounds|
    US9694401B2|2013-03-04|2017-07-04|Kerfoot Technologies, Inc.|Method and apparatus for treating perfluoroalkyl compounds|
    SE541036C2|2014-09-15|2019-03-12|Sangair Ab|Apparatus and system for ozonating blood, and method for ozonating blood prior to storage|
    US10604442B2|2016-11-17|2020-03-31|Cardinal Cg Company|Static-dissipative coating technology|
    CN110526396A|2019-07-24|2019-12-03|华电电力科学研究院有限公司|A kind of desulfurization wastewater and sanitary sewage Coordination Treatment technique and its integrated apparatus|
    法律状态:
    2002-10-01| CC| Certificate of correction|
    2005-11-23| REMI| Maintenance fee reminder mailed|
    2006-05-08| LAPS| Lapse for failure to pay maintenance fees|
    2006-06-12| STCH| Information on status: patent discontinuation|Free format text: PATENT EXPIRED DUE TO NONPAYMENT OF MAINTENANCE FEES UNDER 37 CFR 1.362 |
    2006-07-04| FP| Lapsed due to failure to pay maintenance fee|Effective date: 20060507 |
    优先权:
    申请号 | 申请日 | 专利标题
    US09/325,503|US6103130A|1999-06-03|1999-06-03|Treatment of contaminated liquids with oxidizing gases|
    US09/418,445|US6251289B1|1999-06-03|1999-10-15|Treatment of contaminated liquids with oxidizing gases and liquids|
    US09/767,287|US6383399B2|1999-06-03|2001-01-22|Treatment of contaminated liquids with oxidizing gases and liquids|US09/767,287| US6383399B2|1999-06-03|2001-01-22|Treatment of contaminated liquids with oxidizing gases and liquids|
    [返回顶部]