Alcohol vapor deodorization system

Information

  • Patent Grant
  • 10898602
  • Patent Number
    10,898,602
  • Date Filed
    Tuesday, January 29, 2019
    5 years ago
  • Date Issued
    Tuesday, January 26, 2021
    3 years ago
  • Inventors
    • Kodak; James Allen (Odenton, MD, US)
  • Examiners
    • Bhat; Nina
Abstract
A system that deodorizes gear, padding, or other apparel by killing the bacteria that cause odor. Articles to be deodorized are placed within a re-sealable airtight bag along with highly pure anhydrous ethanol. As the ethanol vaporizes, the gaseous ethanol readily dissolves within the aqueous environment that envelops the bacteria. Ethanol levels within this moisture gradually increase and eventually become bactericidal.
Description
BACKGROUND OF INVENTION

Commercialized efforts at deodorizing padding and apparel without washing usually involve masking unpleasant odors with perfumes that quickly wear off. There is little point in employing bactericidal sprays for deodorization because the liquid can only affect the surface of any article while the vast majority of the bacterial population remains unaffected.


It is therefore necessary to use bactericidal gases in order to kill odors at the source. One very effective way to do this is through the use of ozone. There is a substantial selection of machines on the market today in which the user places the articles to be deodorized in an airtight vessel that produces ozone through electrical discharge. This method can kill odor-causing bacteria in less than 30 minutes. Unfortunately, due to their fundamental bulk and expense, this method is too cumbersome for most consumers. It is preferable to find a generally safe, bactericidal gas that can be deployed quickly and cheaply.


SUMMARY OF INVENTION

Enclosed is a deodorization system for padding and apparel that works by destroying the viability of odor-causing bacteria. This is accomplished by the release of ethanol vapor within the confines of a sealed bag. This vapor gradually dissolves into the aqueous surroundings of the bacteria and eventually reaches levels that stress and then kill the bacteria.





BRIEF DESCRIPTION OF THE DRAWINGS


FIG. 1: shows the alcohol vapor deodorization system.





DETAILED DESCRIPTION OF THE INVENTION

Articles to be deodorized are placed in a re-sealable airtight bag and an anhydrous alcohol mixture that is at least 85% ethanol and/or methanol is poured on top of the articles prior to sealing the bag.


The bag must be sealable to prevent ethanol vapors from escaping. Preferably, this would be accomplished through the use of a zippered bag or simply cinching a thick plastic bag using a releasable cable tie.


As an alternative to pouring the ethanol directly on the articles, the ethanol could be poured into a receptacle resistant to spillage but with sufficient openings to permit the vapor to escape the receptacle and into the bag. However, in the preferred embodiment, the ethanol should be poured directly over the articles. This simple step maximizes the surface area of the liquid ethanol and enables it to reach its equilibrium vapor pressure at a much faster rate than keeping it within a receptacle. This in turn speeds the deodorization process.


With the passage of time, more and more ethanol vapor dissolves into the aqueous environment that surrounds the bacteria living within the articles. As the ethanol levels rise, the bacteria become increasingly stressed and eventually die. The process of deodorization, affected by temperature, moisture levels, and the quantity of ethanol relative to the load, usually takes 12-24 hours.


The most important criteria for a practical, no wash, deodorization system include: (1) an active agent that is stored in a solid or liquid form, (2) possessing a high equilibrium vapor pressure, (3) that readily dissolves into an aqueous environment, (4) that is toxic to bacteria, and (5) can be applied safely by humans. 85% or better anhydrous ethanol maximizes this family of variables more than any other substance.


In general there are many alcohols that readily dissolve in water and can be readily stored in liquid form. However, methanol and ethanol are distinguished in that they both possess equilibrium vapor pressures several times greater than any of the higher molecular weight alcohols. While methanol and ethanol both exhibit considerable anti-microbial properties, ethanol is far less toxic and is thus the preferred active agent for this purpose.


To maximize the rate of evaporation and thereby increase the rate at which ethanol dissolves into the aqueous environment surrounding the odor-causing bacteria, the ethanol should come in an anhydrous form. Furthermore, since anhydrous mixtures of ethanol, such as completely denatured alcohol, contain volatile additives that are themselves hazardous, it is ideal to minimize the additive presence by using highly pure varieties, 85% ethanol or better.

Claims
  • 1. A process for deodorizing articles of apparel or padding that consists of placing the articles in an airtight bag or other airtight container, adding a disinfecting anhydrous composition that is at least 85% ethanol or at least 85% methanol by volume, or a mixture of the two alcohols in which their combined volumes is at least 85% of the total volume of the mixture, followed by sealing the airtight bag or container.
  • 2. A process for deodorizing articles of apparel or padding that consists of placing the articles in an airtight bag or other airtight container, adding a disinfecting anhydrous composition that is at least 85% ethanol by volume, followed by sealing the airtight bag or container.
  • 3. A process for deodorizing articles of apparel or padding that consists of placing the articles in an airtight bag or other airtight container, adding a disinfecting anhydrous composition that is at least 85% methanol by volume, followed by sealing the airtight bag or container.
US Referenced Citations (17)
Number Name Date Kind
5238587 Smith Aug 1993 A
5658651 Smith Aug 1997 A
5789368 You Aug 1998 A
6663830 Tindall Dec 2003 B1
6753306 Simpson Jun 2004 B2
6759006 Siklosi Jul 2004 B1
7008600 Katsigras Mar 2006 B2
7807118 Green Oct 2010 B2
7947086 Panandiker May 2011 B2
8008247 Falk Aug 2011 B2
8563017 Cunningham Oct 2013 B2
8642054 Green Feb 2014 B2
9481961 Parekh Nov 2016 B2
20010044399 Keppie Nov 2001 A1
20010053333 Messier Dec 2001 A1
20060228250 Brown Oct 2006 A1
20160136698 Kaufman May 2016 A1
Foreign Referenced Citations (2)
Number Date Country
2004-33729 May 2003 JP
2004-337219 May 2003 JP
Non-Patent Literature Citations (2)
Entry
English Translation JP 2004-337219 A (Year: 2003).
English Translation of JP 2004-337219 (Year: 2003).
Related Publications (1)
Number Date Country
20200237942 A1 Jul 2020 US