Method in treating aqueous waste feedstream for improving...

Details Method in treating aqueous waste feedstream for improving... Method in treating aqueous waste feedstream for improving...

2002-06-19

2004-06-29

Lawrence, Frank M. (Department: 1724)

Liquid purification or separation

Processes

Liquid/liquid solvent or colloidal extraction or diffusing...

C210S760000, C210S797000, C210S808000

Reexamination Certificate

active

06755977

ABSTRACT:

BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to the use of ozone to treat and process aqueous waste feedstream, especially as this would relate to treatment at filtration plant facilities; but also in other uses, where the concern or object exists to improve flux rates of feedstream through filter media and effectively change feedstream character so that it is presented in a condition where it will cause less wear or destruction of such media, and provide the added feature of effectively cleaning such filter media.
2. Background Information
It has been determined in the art that Ozone kills many biological agents by oxidizing the organic molecules that form the cell surface and in dealing with the problem of calcium buildup (a major portion of total dissolved solids—TDS), as well as dealing in the past with biocides used to chemically treat water systems.
Those references found which appear to have at least some relationship to the technology of ozone treatment and processing of environmentally significant aqueous waste feedstream include the fllowing: Williams, et al., U.S. Pat. No. 6,183,646; Crisinel, et al., U.S. Pat. No. 6,162,477; Foellmi, U.S. Pat. No. 6,074,564; Shultz, U.S. Pat. No. 6,001,247; Faivre, et al., U.S. Pat. Nos. 5,843,307 and 5,271,830; Busch, Jr., U.S. Pat. No. 5,807,486; Tempest, Jr., U.S. Pat. No. 5,741,416; Bhave, et al., U.S. Pat. No. 5,645,727; Dickerson, U.S. Pat. No. 5,397,480; Ditzler et al., U.S. Pat. No. 5,114,576; Engel et al., U.S. Pat. No. 5,097,556; Cole, et al., U.S. Pat. No. 4,849,115; Hiltebrand, et al., U.S. Pat. No. 4,622,151; Cohen, et al., U.S. Pat. No. 4,595,498; and Johnson, et al., U.S. Pat. No. 4,200,526.
Also having some relevance in terms of discussing some of the chemical principles involved in the present invention's technology (such as solubility aspects, pressure and the application of the Laws of Boyle, Charles, Dalton and Henry, and other chemical aspects), are the following references: (1) Various editions of
Lange's Handbook of Chemistry
, setting forth the “Solubility of Gases in Water,” particularly as this relates to Oxygen and Air into Water or Water and Solvents; (2) Graik, et al., 2001, “The Effect of Ozone Gas-Liquid Contacting Conditions in a Static Mixer on Microorganism Reduction,”
Ozone Science
&
Engineering
, Vol. 23, pp. 91-103; (3) Min Cho et al., 2001, “Effect of pH and Importance of Ozone initiated Radical Reactions In Inactivating
Bacillus subtilis
Spore,”
Ozone Science
&
Engineering
, Vol. 24, pp. 145-150; (4) Mortimer, C. H., 1981, “The oxygen content of air-saturated fresh waters over ranges of temperature and atmospheric pressure of limnological interest,”
International Association Of Theoretical And Applied Limnology
, pp. 1-23, E. Schweizerbart'sche Verlagsbuchhandlung: Stuttgart; (5) Langlais, et al. (eds.), 1991,
Ozone In Water Treatment Application and Engineering
, pp. 90-132, 349-442, 474-485, and 543-551; (6) Masschelein, W. J. (ed.), 1982,
Ozonization Manual for Water and Wastewater Treatment
, pp. 47-56, 69-102, 129-139, and 151-153, John Wiley & Sons: New York; (7) Gerrard, w\W., 1976,
Solubility Of Gases And Liquids
, pp. 1-276, Elsevier Scientific Publishing Company: New York; (9) Lide, D. R. (ed.), 1995-1996, “Vapor Pressure Of Fluids At Temperatures Below 300K—Ozone (O
3
)”,
CRC Handbook of Chemistry and Physics
, p. 6-71, CRC Press: New York; and (10) Linke, W. F., 1965, “O
3
Ozone Solubility In Water,”
Solubilities Inorganic and Metal
-
Organic Compounds
, pp. 1239-1240, American Chemical Society: Washington, D.C.
The Faivre et al. '307 and '830 patent references would appear to be the closest potentially applicable prior art. The '307 reference is entitled: “Unit for the treatment of water by ozonation, and a corresponding installation for the production of ozonized water.” The '830 reference is entitled: “Water treatment installation for a tangential filtration loop.” These references teach a water treatment unit and installation designed expressly for the purpose of producing “ozonated white water,” or water characterized by a multi-phase, non-homogeneous mixed system containing gaseous “bubbles” of ozone within the water, giving the water the appearance of turbulent ‘white’ water, and disclosed to have bubbles the size of between 20 and 200 microns, or larger in magnitude by virtue of the visibility to the naked eye of bubbled white water as described in Faivre.
The bubbles and white water of the Faivre teachings are designed to create physical turbulence in the water at the membrane, and employ the ability of ozone, in such a gaseous state, as an oxidation agent to further restrict clogging of their tangential filtration membrane. Such installations or units require a reduction in initial pumping pressure to form gaseous ozone bubbles, and a phase separation to prevent cavitation of pumping units and other equipment on line by virtue of Faivre's feedstream being at a point of supersaturation with the presence of potentially damaging gaseous bubbles; therefore, exposing such a system to the loss of useful ozone content, even in the form of the gas bubbles earlier created, as well as further time and expense in reinstating gaseous ozone bubble concentrations with regard to any recycling operations. The pressure in the Faivre installation must be dropped some 50% to 75% before reaching any filter unit to form Faivre's ozone gas bubbles. The unit or installation system of Faivre cannot sustain useful pressure throughout its system loop, from beginning to end, during any given cycle of its application or operation. This loss in pressure will decrease potential flow rate across tangential membranes along with significant reduction in turbulence. Nor can it recycle, as indicated, without losing its gaseous ‘white water-bubbled ozone and starting from the beginning in re-generating its gaseous ozone bubbles or white water. These systems, therefore, lose their ability to effectively clean filter media because gaseous bubbled ozone, multi-phase fluid or suspension is submitted not to be an optimal form for effectively cleaning and saving wear on filter media. Nor is it effective and cost-saving in re-utilization through re-cycling because of the required reduction in pressure to form ozone bubbles and the phase separation required to protect against cavitation and other phase separation damage to pumps and other such equipment within Faivre's loop, or other equipment utilized on-line. This is born out by its relative or substantial obscurity of use in any environmental system employing filter media in the United States. Additionally, the teachings of Faivre would suggest, chemically, that its unit, installation or system, is sensitive to temperature and pH requirements because of the nature of its gaseous multi-phase mixture; thereby inherently involving greater potential for failure or demanding greater time and expense to maintain.
These and other disadvantages, structurally, functionally and by virtue of distinction in process and method approach, will become apparent in reviewing the remainder of the present specification, claims and drawings.
Accordingly, it is an object of the present invention to provide a substantially improved and cost-effective method in treating aqueous waste feedstream for improving the flux rates, cleaning and prolongation of useful life of filter media in many diverse environmental and process applications; with special adaptability and advantageous application to aqueous feedstreams from nuclear plant sites.
It is a further object of the present invention to provide a method which utilizes the solublizing (or the making soluble and uniform) of an ozone mixture (provided as having at least O
3
and O
2
) and an aqueous feedstream to create a substantially homogeneous single phase liquid mixture or a substantially homogeneous molecular single phase mixture, without ‘white water’ or ozone bubbles; so that the ozone mixture generated within the present

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