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| United States Patent |
4,608,247 |
| Heinig, Jr. |
August 26, 1986 |
Composition for bactericidal treatment of water
Abstract
A composition and method for the bactericidal treatment of water with
oligodynamic metal ions. The composition comprises a particulate silver yielding
material and a particulate filler material which is intermixed with the silver
yielding material. The silver yielding material comprises a highly porous
carrier having a hardness which is greater than that of elemental silver and a
layer of elemental silver on the surfaces of the carrier, and the filler
material comprises a material, such as charcoal, having a hardness which is less
than that of elemental silver. The composition is utilized in accordance with
the method of the invention by passing a stream of water through a quantity of
the composition to cause the particles of silver yielding material to
mechanically interact with each other to release silver into the water. The
particles of filler material, intermixed with the silver yielding material,
buffer this mechanical interaction to provide a relatively slow release of
silver from the composition which can be effectively controlled so that the
composition and method can be effectively used in substantially closed systems,
such as swimming pool systems.
| Inventors: |
Heinig, Jr.; Charles F. (Warwick, RI)
|
| Assignee: |
LeMire; George J. (Cranston, RI) |
| Appl. No.: |
664205 |
| Filed: |
October 24, 1984 |
| Current U.S. Class: |
424/421; 210/501; 424/618;
424/691 |
| Intern'l Class: |
A01N 025/26 |
| Field of Search: |
210/668,679,764,169,501
424/16,21,132 427/217 428/403,404 |
References Cited [Referenced
By]
U.S. Patent Documents
| 2017456 |
Oct., 1935 |
Gudmundsen |
210/501. |
| 2521713 |
Sep., 1950 |
Goetz |
210/764. |
| 3268444 |
Aug., 1966 |
Renn |
210/501. |
| 3788982 |
Jan., 1974 |
Zsoldos et al. |
210/679. |
| 4092245 |
May., 1978 |
Franks et al. |
210/764. |
| 4238334 |
Dec., 1980 |
Halbfoster |
210/679. |
| 4353741 |
Oct., 1982 |
Capuano et al. |
427/217. |
| 4396512 |
Aug., 1983 |
Beauman et al. |
210/668. |
| 4407865 |
Oct., 1983 |
Nice |
210/501. |
| Foreign Patent Documents |
| 2364504 |
Aug., 1974 |
DE |
210/501. |
| 50-6718 |
Jan., 1975 |
JP |
210/764. |
Primary
Examiner: Hruskoci; Peter
Attorney, Agent or Firm: Salter &
Michaelson
Claims
What is claimed is:
1. A composition for the bactericidal
treatment of a stream of water comprising:
a. a particulate silver
yielding material comprising:
i. a carrier which has a particle size of
between approximately 4 and 20 mesh, a surface area of greater than
approximately 150 square inches per gram, and a Mohs scale hardness of greater
than 2.5 and which is substantially insoluble in water having a pH of between 5
and 9;
ii. a layer of elemental silver on the surfaces of said carrier,
said silver being between approximately 1% and 10% by weight of said silver
yielding material; and
iii. the mechanical interaction between adjacent
particles of said silver yielding material causing a release of elemental silver
into said stream when it is passed therethrough;
b. a particulate filler
material intermixed with said silver yielding material, said filler material
being substantially insoluble in water having a pH of between 5 and 9, said
filler material having a particle size of between approximately 4 and 20 mesh
and a Mohs scale hardness of less than 2.5, the volumetric ratio of said filler
material to said silver yielding material being between approximately 1:1 and
5:1; and
c. said filler material reducing the rate at which elemental
silver is released from said composition to produce a controlled release of said
elemental silver when said stream is passed therethrough.
2. In the
composition of claim 1, said carrier further characterized as being activated.
3. In the composition of claim 2, said carrier comprising alumina.
4. In the composition of claim 1, said carrier comprising alumina.
5. In the composition of claim 4, said filler material comprising
charcoal.
6. In the composition of claim 1, said silver yielding
material and said filler material being of substantially the same particle size.
7. The composition of claim 1 further characterized as being
substantially free from silver salts.
Description
BACKGROUND AND SUMMARY OF THE INVENTION
The instant invention
relates to water treatment processes, and more particularly, to a novel
composition for the bactericidal treatment of water.
It is widely known
that chlorine can be effectively used to kill bacteria contained in water.
Chlorine is commonly used for treating drinking water, and also for treating
water used in swimming pool systems, and it is even used to treat waste water
during sewage treatment processes. However, while the addition of chlorine to
water has been found to be an effective method of killing bacteria contained in
the water, it has a number of disadvantages. First, chlorine, which is a
relatively volatile gas in its natural state, is rapidly dissipated from water
which is left to stand open to the atmosphere, particularly when the water has a
temperature of greater than approximately 70 degrees fahrenheit. Therefore, it
is generally necessary to make frequent additions of chlorine to water under
these conditions in order to maintain the bacteria levels in the water within
safe ranges, and obviously this has disadvantages from both practical and
economic standpoints. Further, while the necessity for frequently replenishing
chlorine levels in water represents a major drawback to the use of chlorine for
the germicidal treatment of water, there are several other disadvantages which
specifically apply to the use of chlorine for the treatment of water used in
open pools, such as swimming pools, hot tubs, soaking tubs and the like. In
particular, chlorine produces a distinct odor as it is dissipated from an open
pool of water, and this has been found to be objectionable to many swimmers and
bathers. In addition, water containing high concentrations of chlorine can be
harmful to the eyes of swimmers and bathers after prolonged periods of exposure
and, to a lesser extent, water containing high levels of chlorine can be harmful
to the skin and hair. Further, because the dissipation of chlorine from a pool
of water is substantially accelerated when the water is heated to an elevated
temperature level, chlorine is often dissipated so rapidly from hot tubs and
soaking tubs that it is difficult or impossible to reliably maintain chlorine
levels in these tubs within the desired ranges. This, combined with the fact
that the growth of bacteria is substantially accelerated by elevated temperature
levels, makes the use of chlorine frequently unsatisfactory for hot tub and
soaking tub applications.
The use of heavy metals, in particular, heavy
metals of the type commonly referred to as oligodynamic metals for the
bactericidal treatment of water is also widely known. More specifically, it is
known that ions of oligodynamic metals, especially silver ions, have a
bactericidal effect when they are present in water, even at relatively low
concentration levels, such as below 50 parts per billion. As a result, it is
generally accepted that oligodynamic metal ions can be effectively utilized to
maintain bacteria levels in water within tolerable ranges which permit the safe
use of the water for swimming or drinking purposes. On the other hand, however,
it is also recognized that excessive concentration levels of oligodynamic metal
ions in water can be toxic or harmful to humans. Generally, it has also been
found that silver ions are the most effective oligodynamic metal ions for the
bactericidal treatment of water, and it has been found that silver ion
concentration levels of up to 50 parts per billion can be safely tolerated by
humans without adverse effects. Further, it has been found that silver ion
concentration levels in the range of between 10 and 50 parts per billion can be
generally effective for maintaining the bacteria concentrations in water within
tolerable ranges. In any event, in order to utilize silver ions to effectively
kill bacteria in a water treatment system, some mechanism must be provided for
releasing silver ions at rates which can be effectively controlled so that the
overall silver ion concentrations in the water can be maintained within a safe
range of between approximately 10 and 50 parts per billion. Further, for
practical reasons, it is important for a system of this type to be able to
maintain the silver ion concentration level in the quantity of water within a
desired range over a prolonged period of time without requiring significant
amounts of attention.
While a variety of systems have been heretofore
available which have utilized oligodynamic metals for the bactericidal treatment
of water, generally, the heretofore known technology has failed to provide an
effective means for releasing silver ions into a contained system, such as a
swimming pool, at a controlled rate over a prolonged period of time. In this
regard, most of the known systems have comprised apparatus which is operative
for releasing silver ions at relatively high rates, but not at slow rates which
can be effectively controlled over prolonged periods of time. Hence, while the
known systems can be utilized for adding large quantities of silver ions to
previously untreated water to kill the bacteria contained therein, they
generally release silver ions at rates which are far too high for use in
maintaining silver ion levels in contained or closed systems, such as swimming
pool systems, after the desired ion levels have initially been reached. In many
cases, this is because systems have utilized silver salts, which are highly
soluble in water, as the sources of silver ions and these salts have typically
released silver ions at rates which are far too high to be effectively
controlled over prolonged periods in contained systems such as swimming pool,
soaking tub, and hot tub systems. While water treatment systems have also been
available which have utilized elemental silver which is dissolved very, very
slowly in water to produce silver ions, these systems have generally not
released ions at rates which are sufficient to permit their use for maintaining
ion concentrations in contained systems, and generally the known systems of this
type have also been ineffective for prolonged use.
The instant invention
provides an effective composition and method for releasing silver ions into
water at controlled practical rates over prolonged periods of time so that the
composition and method can be effectively utilized in essentially closed
systems. In this regard, the composition of the instant invention from which
silver ions are released comprises a silver yielding material comprising a
carrier having a particle size of between 4 and 20 mesh and a layer of elemental
silver on the surfaces of the carrier, and a filler material also having a
particle size of between 4 and 20 mesh which is intermixed with the silver
yielding material. The carrier has a relatively high porocity which provides a
surface area of greater than 150 square inches per gram and it has a Mohs scale
hardness which is greater than that of silver, i.e. greater than 2.5. The
carrier is also substantially insoluble in water having a pH of between 5 and 9.
The carrier preferably consists of alumina which has a hardness of greater than
9 on the Mohs scale, a porocity which provides a surface area of approximately
210 square inches per gram, and a particle size of between 8 and 14 mesh, and
preferably the alumina is activated to provide a greater bond strength between
the carrier and the silver on the surfaces thereof. The silver is preferably
distributed over both the interior and exterior surfaces of the porous carrier
and it preferably comprises between 1% and 10% by weight of the total silver
yielding material. The filler material which is intermixed with the silver
yielding material has a hardness which is less than that of silver, i.e. less
than 2.5 on the Mohs scale, and it is intermixed with the silver yielding
material so that the ratio of filler material to silver yielding material is
between approximately 1:1 and 5:1. Preferably, the filler material has a
particle size which is substantially the same as that of the silver yielding
material, and it is intermixed therewith in a ratio of approximately 2:1 and,
preferably, the filler material consists essentially of activated charcoal.
For practicing the method of the instant invention, to treat a pool of
water, a stream of water is drawn from the pool and passed through the
composition of the instant invention and then returned to the pool and the flow
rate of the stream is controlled to maintain the concentration of silver ions in
the pool at a level of between 10 and 50 parts per billion. It has been found
that because of the make-up of the composition of the instant invention, it can
be effectively utilized for providing controlled additions of silver ions to a
body of water at rates which are practical for most pool systems, and it has
also been found that the composition can be utilized over a prolonged period of
time to maintain the silver ion concentration level in a pool within a desired
range. Further, because of the make-up of the composition of the instant
invention and the effectiveness with which it can provide controlled releases of
silver ions into a stream of water, the method and composition of the instant
invention can be readily adapted for use in most conventional swimming pool and
soaking tub systems. More specifically, when a quantity of the composition of
the instant invention is contained in a relatively small canister, the canister
can be readily utilized in a conventional swimming pool or soaking tub system
simply by connecting the canister to the otherwise conventional filtration
system of the swimming pool or soaking tub system. This is because the
composition of the instant invention is effective for releasing silver ions to
maintain the desired silver ion levels in swimming pool or soaking tub systems
when relatively small quantities of the composition are exposed to water flow
rates which are normally within the ranges of flow rates provided by
conventional filtration system equipment. Hence, the composition and method of
the instant invention can be utilized in most conventional swimming pool and
soaking tub systems simply by connecting a canister containing a quantity of the
composition to existing or conventional equipment of the system. This provides
substantial practical advantages for the method and composition of the instant
invention.
The closest prior art to the instant invention of which the
applicant is aware is disclosed in the U.S. patents to Conconi (U.S. Pat. No.
2,283,883), Renn (U.S. Pat. No. 3,268,444), Nishino et al (U.S. Pat. No.
3,872,013), and Beauman et al (U.S. Pat. No. 4,396,512); the United Kingdom
patents to Krause (Nos. 279,085 and 353,686), the German patent to Mitsumori et
al (No. 2,505,597), and the Japanese KoKai publication No. 74 97,730 by Tsukada
et al. However, none of these references suggest the combination of a relatively
hard silver yielding material with a relatively soft filler material to provide
a composition having the silver release properties of the composition of the
instant invention. Hence, these references are felt to be of nothing more than
general interest.
Accordingly, it is a primary object of the instant
invention to provide an effective composition which can be utilized to release
silver ions into water at a slow controlled rate in a closed system, such as a
swimming pool, soaking tub, or hot tub system.
Another object of the
instant invention is to provide an effective method of releasing silver ions
into a pool of water which permits the overall silver ion concentration in the
pool to be effectively controlled.
Another object of the instant
invention is to provide an effective method of releasing silver ions into a
swimming pool which permits the overall silver ion concentration in the swimming
pool to be maintained at between 10 and 50 parts per billion.
An even
further object of the instant invention is to provide a method of releasing
silver ions into water at a slow controlled rate utilizing a silver yielding
material, wherein the silver yielding material is operative over a prolonged
period of time.
Other objects, features and advantages of the invention
shall become apparent as the description thereof proceeds.
DESCRIPTION
OF THE INVENTION
The instant invention provides an effective composition
for the bactericidal treatment of water, particularly water which is contained
in a closed system, such as a system comprising a swimming pool, a hot tub, a
soaking tub, or the like. More specifically, the instant invention provides a
composition which can be utilized in accordance with the inventive method for
releasing silver ions into water at relatively slow controllable rates so that
the composition and the method can be effectively utilized for maintaining the
silver ion concentration level in a substantially closed system within a range
of between 10 and 50 parts per billion.
The composition of the instant
invention comprises a silver yielding material comprising a carrier and a layer
of elemental silver on the surfaces of the carrier, and a filler material which
is intermixed with the silver yielding material. The carrier has a particle size
of between approximately 4 and 20 mesh, a porocity which provides a surface area
of greater than 150 square inches per gram, and a Mohs scale hardness which is
greater than the hardness of silver, i.e. greater than 2.5, and the carrier is
substantially insoluble in water having a pH within the range of between 5 and
9. The elemental silver is deposited on the surfaces of the carrier and it is
between 1% and 10% by weight of the silver yielding material. Preferably, the
carrier is activated to provide an improved bond between the carrier and the
silver on the surfaces thereof. The filler material also has a particle size
which is between 4 and 20 mesh, and preferably, the filler material has a
particle size which is substantially the same as that of the carrier. The filler
material has a hardness which is less than the hardness of silver, and the
filler material is also substantially insoluble in water having a pH of between
5 and 9. The volumetric ratio of filler material to carrier material is between
approximately 5:1 and 1:1 and the carrier material preferably consists
essentially of activated alumina, whereas the filler material preferably
consists essentially of activated charcoal.
It has been found that a
composition of the above type can be effectively utilized for maintaining the
silver ion concentration in an essentially closed pool system within a
predetermined range over a prolonged period of time. More specifically, after
the silver ion concentration in a pool of water has been initially adjusted to a
predetermined level by conventional means, for example, by the addition of a
silver salt such as silver sulfate to the water, the composition of the instant
invention can be effectively utilized to maintain the silver ion concentration
level in the pool of water within the same predetermined range over a prolonged
period of time. In this regard, silver ions are normally only dissipated from a
pool of water when a portion of the water is removed from the pool and
thereafter replaced with fresh water or when materials in which the silver ions
have concentrated, such as waste materials of the type which are normally
trapped in a filtration system of the pool, are removed from the pool system.
Accordingly, silver ions are normally only removed or dissipated from a pool
system at very slow rates and hence, in order to maintain the ion concentration
level in a pool system within a predetermined ranges it is only necessary to add
silver ions to the system at very slow rates. The composition and method of the
instant invention are particularly adapted for use in applications of this type
and they rely on the interactions of several physical and chemical
characteristics of the components of the composition to provide effective
controllable releases of silver ions.
It is widely known that elemental
silver is only soluble in water to a very, very small degree and, in fact, it is
because of this property that elemental silver is utilized in the composition of
the instant invention instead of other forms of silver, such as silver salts,
etc. However, while the solubility of elemental silver is of some significance
in the instant invention, the physical interactions between the particles in the
composition also play a significant role in providing an effective ion release
from the composition of the instant invention. Specifically, when water passes
through the particles of the composition of the instant invention, silver is
released chemically as it is slowly dissolved in the water, but silver is also
released mechanically in the form of tiny elemental silver particles which are
so small that they are rapidly also dissolved in the water and become ionized.
This mechanical release of silver results from the combined effects of abrasion
and erosion as water is passed through the composition. In this regard, since
the carrier has a hardness which is greater than the hardness of silver, and
also greater than the hardness of the filler material, the carrier remains
substantially intact throughout this abrasion and erosion process, whereas the
silver is eroded and abraded from the surfaces of the carrier as the water
passes over the particles and adjacent silver yielding particles contact one
another. On the other hand, since the filler material which is intermixed with
the silver yielding material has a hardness which is less than that of silver,
i.e. it is less than 2.5 on the Mohs scale, the filler material provides a
cushioning effect which retards the release of silver by preventing many of the
particles of silver yielding material from physically interacting with each
other. Hence, by providing a silver yielding material comprising a carrier
having a hardness which is greater than that of silver, and by intermixing the
silver yielding material with a filler material having a hardness which is less
than that of silver, a controlled abrasion and erosion reaction can be achieved
when water is passed through the composition to effectively control the
mechanical release of silver. The high porocity of the carrier not only provides
a high surface area for the silver, but it also retards the release of silver
because a substantial portion of the silver on the carrier is on the interior
surfaces thereof, and this portion of the silver is more protected from release
by erosion and abrasion than the silver on the exterior surfaces. To achieve the
optimum result, the particle sizes of the silver yielding material and the
filler material are preferably substantially the same so that the desired
interaction between the particles is achieved and the ratio of filler material
to silver yielding material is between approximately 1:1 to 5:1 to achieve the
desired interaction. In addition, the particle sizes of both the filler material
and the silver yielding material must be within the range of between 4 and 20
mesh to both achieve the desired particle interaction and also to provide a
material through which water can easily flow.
Preferably, the carrier
comprises activated alumina which, because of its high degree of hardness
(greater than 9 on the Mohs scale) and because of its high porocity which
provides a surface area of approximately 210 square inches per gram, provides a
highly effective transport medium for the silver. Preferably, the alumina is
activated by heating it to a temperature of greater than approximately 400
degrees fahrenheit to provide an improved bond between the alumina and the
silver and preferably the filler material comprises charcoal, in particular,
activated charcoal, since activated charcoal is substantially softer than silver
and it also has a number of well-known absorption properties which make it
particularly desirable for use in a water treatment system.
EXAMPLE
An outdoor swimming pool system comprising a private swimming pool
containing approximately 19,000 gallons of water was treated over a period of
approximately three and a half (31/2) months utilizing the composition and
method of the instant invention. The system included a conventional diatomaceous
earth filter and a canister containing the composition of the instant invention
which were both fed by a single filtration pump. The canister, which was
approximately four inches in diameter and twenty inches in length and which had
a central open tubular passage therethrough of approximately one inch in
diameter, was filled with the composition of the instant invention in the area
of the canister between the outer wall thereof and the open tubular passage.
Water was introduced into the canister so that it could either flow through the
central tubular passage or through the composition and the overall flow rate of
water through the canister was maintained at approximately 15 gallons per minute
over the three and a half month period. The composition utilized consisted
essentially of a silver yielding material having a carrier of alumina with a
particle size of between 5 and 14 mesh, and a layer of elemental silver on the
surfaces of the carrier, the silver comprising approximately 1.25 weight percent
of the silver yielding material. The silver yielding material had been prepared
by a conventional silver refining process to provide a layer of elemental silver
on the surfaces of the alumina medium and thereafter the alumina with silver on
the surfaces thereof had been heated to a temperature of approximately 400
degrees fahrenheit to activate the alumina. Approximately 1,000 grams of silver
yielding material was intermixed with approximately 660 grams of activated
charcoal having a particle size of between 5 and 14 mesh to provide an
approximate volumetric ratio of two parts charcoal to one part silver yielding
material in the composition which was utilized in the canister. Initially,
before the canister was operated, the water in the pool was adjusted to provide
a silver ion concentration level of approximately 20 parts per billion utilizing
a silver sulfate composition. Thereafter, the silver ion concentration level in
the pool was maintained exclusively through the release of silver ions from the
composition of the instant invention in the canister. Over the three and a half
month period, the water temperature in the pool was generally between 70 and 85
degrees fahrenheit, and the bather load was considered to be moderate. The pool
was operated out of doors and the amount of rainwater which entered the pool was
considered to be moderate. The diatomaceous earth filter was backflushed
approximately monthly. It was found that throughout the entire period, the
silver ion concentration in the pool system was maintained within the range of
between 10 and 25 parts per billion. In this regard, it was found that after a
period of approximately one week, the ion concentration level had dropped from
its initial value of approximately 20 parts per billion to a level of
approximately 10 parts per billion, and thereafter a level of approximately 10
parts per billion was consistently maintained throughout the period. Water
samples were removed from the surface portion of the pool on a weekly basis and
tested for coliform bacteria levels. It was found that throughout the period the
coliform level was less than one organism per hundred milliliters of pool water.
This level of coliform bacteria was considered to be extremely satisfactory, and
hence the quality of water in the pool was considered to be extremely safe for
swimming purposes. It was found, however, that at the end of the three and
one-half month period the silver had been substantially depleted from the
surfaces of the silver yielding material. When the system was operated beyond
the period without changing the canister, the silver ion concentration level in
the pool dropped effectively to nil, and upon testing after operating for
approximately two weeks under these conditions, it was found that the coliform
level had climbed to 16 organisms per 100 milliliters of water. Hence, it was
concluded that the composition and method of the instant invention had
effectively operated throughout the three and one-half month period, and that
they had effectively released silver ions to provide a germicidal effect in the
pool which maintained the bacteria level therein within safe and tolerable
levels. However, once the silver had been depleted from the canister, the silver
ion concentration level in the pool decreased rapidly and the water in the pool
could no longer be considered safe for swimming.
As this invention may
be embodied in several forms without departing from the spirit or essential
characteristics thereof, the present embodiment is therefore illustrative and
not restrictive, since the scope of the invention is defined by the appended
claims rather than by the description preceding them, and all changes that fall
within the metes and bounds of the claims or that form their functional as well
as conjointly cooperative equivalents, are therefore intended to be embraced by
these claims.
* * * * *
