[0001] This invention relates to a process for the destruction of biological waste products.
[0002] Human and veterinary hospitals, surgical clinics, pathology laboratories and associated
health care facilities throughout the world are routinely removing and disposing of
tissues and body fluids from sick, injured and frequently infected humans and animals.
In addition, large volumes of contaminated syringes, tubes, surgical bandages and
blood products enter the waste streams of these institutions. In many cases, these
materials are harmless and pose no threat of infection to persons who handle or who
are otherwise exposed to them. In some cases, however, these materials can contain
infective viruses, pathogenic bacteria, toxins and/or bacterial spores which constitute
a threat of patients, health care professionals and the general public. In many cases,
hospital and clinical waste carries with it a noxious odor and may be considered unsightly.
[0003] In addition to the above-mentioned facilities, there are numerous university and
medical school facilities in which research into the etiology of disease, experimental
therapeutics and basic rease- arch is conducted. Fermentation broths and tissue cultures,
as well as experimental animals, may frequently contain higher concentrations of rare
and pathogenic organisms and toxic and carcinogenic chemical agents than would be
found in hospital and clinical wastes. Agricultural research facilities frequently
produce mosses, ferns and fungi which reproduce through sporulation and which may
be either pathogenic or allergenic.
[0004] Recent advances in genetic engineering enable the production of potent pharmaceuticals,
toxins, and other biochemicals in large fermentation cultures. Once the desired chemical
products have been isolated from the broth, the broth must be properly treated to
control both odor and the possibility that potentially infectious agents and toxins
may be released into the environment.
[0005] The disposal of small amounts of infectious laboratory wastes, bandages and similar
contaminated materials has, since the invention of the Chamber- land autoclave in
1884, been performed using wet steam. Wet steam is effective against most bacteria
and mycotoxins, but is frequently ineffective against spores, toxins and the so-called
"slow" viruses. Steam sterilization is extremely energy intensive; must be monitored
regularly for effectiveness, usually produces an odiferous product, and results in
no dimunution in the size of the waste. The autoclaving of whole research animals
and large volumes of tissue is rarely practiced, except in extreme emergencies.
[0006] Chemical treatment of pathological waste has never achieved routine use. Chemical
treatment of tissues requires the handling of comparatively large volumes of corrosive
and toxic chemicals, such as chloride of lime and formaldehyde. The end result is
an increased volume of a sterile, albeit chemically hazardous, waste.
[0007] The incineration of whole bodies, parts thereof and tissues has been a routine procedure
at medical facilities, morgues, mortuaries and veterinary hospitals. Incineration
involves minimum transportation within and especially outside of the institution,
produces a small volume of essentially sterile waste, and is comparatively energy
efficient. The use of small, pathological incinerators for the disposal of laboratory
wastes and patient contact items is limited by the design of a pathological incinerator,
which is typically a small solid hearth, single chamber unit. The incineration of
significant volumes of plastic laboratory items such as petri dishes and syringes
results in the emmission of large quantities of black smoke, and the BTU content of
these items frequently causes dramatic changes in combustion chamber temperatures.
The incorporation of tissue and infectious waste into the general waste stream of
an institution has been attempted at several large medical institutions, but entails
the installation of new and complex incinerators and the hiring of additional, qualified
operators, and is frequently beyond the financial capabilities of small and medium
sized hospitals.
[0008] The US Patent Specification 4 552 667 cites mere immersing of organic hazardous wastes
as understood to be hydrocarbon compound materials produced artificially contrary
to biological waste materials, which latter, although being hydrocarbon compounds
likewise, are understood to be materials produced by biological living, into molten
aluminum and allowing such material to react with the latter. For such organic hazardous
waste materials artificially produced as results from incomplete reaction or isomeric
or side-reaction product in chemical manufacturing plants or being manufactured articles
to be disposed of after being discovered to present a real or potential hazard to
workers in the plant manufacturing them, to their users or to people exposed to them,
this known process of mere introducing such materials below the surface of a bath
comprising molten aluminum and reacting the covalently bound oxygen, nitrogen, sulfur
and pho- phorus contained with said molten aluminum proved satisfactory in decomposing
such materials to less noxious or hazardous, respectively, compounds, but such treatment
of biological waste as concerned with this invention would be insufficient for the
purposes intended according to the objective concerned.
[0009] US Patent Specification 4 469 661 teaches the disposal of a special kind of organic
wastes, namely polychlorinated biphenyls (PCBs) and other hazardous halogenated hydrocarbons
by isolating the hazardous PCBs from the solids contaminated therewith by liquid extraction
to produce a liquid containing said hazardous halogenated hydrocarbons and thereafter
vaporizing said liquid and only after this contacting the vapor yielded with molten
metal comprising aluminum to remove halogen from said hazardous halogenated hydrocarbon
and leave a slag.
[0010] Either of these known processes proved unuseful for the disposal of biological waste
in the sense described above particularly when comprising or containing, respectively,
physiologically active material. It has been found that mere immersing such material
to a bath of molten aluminum and allowing a chemical reaction with the latter does
neither destroy the carrier material, if any, like contaminated syringes, tubes, surgical
bandages, sufficiently nor is able to guarantee satisfactory mortification of said
physiologically active material as e. g. blood product, infective viruses, pathogenic
bacteria, toxins and/or bacterial spores which constitute a threat of patients, health
care professionals and the general public.
[0011] Keeping this in account it is the problem of the invention to provide a process capable
of destroying pathogenic organisms, spores and viruses, as well as the tissues and
laboratory equipment in which they are contained, which process and device are capable
of significantly reducing the volume of waste while producing gaseous and particulate
emissions of low toxicity or which are easily trapped or otherwise contained. The
device should be amenable to production in sizes suitable for installation in facilities
zoned for light industry and require minimum operator training and service. Finally,
the cost of construction and operation must be competitive, with other, less efficient,
methods of disposal.
[0012] For solving the problem the process for the destruction of biological waste products
even if containing physiologically active materials comprises the steps of:
a) heating said waste products in a sealed chamber to a range from 600 °C to 850 °C
to vaporize volatiles and to pyrolize non-volatiles and producing an output stream
comprising gas with residual biological matter including said physiologically active
materials entrained therein, followed by
b) treating said output stream after removal from said sealed chamber by passage into
contact with molten aluminum thereby effecting chemical reduction by reaction with
aluminum and producing innocuous effluent.
[0013] The device for carrying out the process indicated above contains a closed and heated
chamber preferably in the form of a vessel in a gas-tight encasement, a second vessel
containing an aluminum bath and communicating with the chamber by a delivery tube
which runs from the top of the chamber to a point near the bottom of the aluminum
bath.
[0014] With the features according the present invention it is possible pyrolytically and
chemically detoxifying and destroying all toxic and infectious biological waste products
e.g. human or animal tissues, biological fluids such as blood, and bandages, cultures
and combustible laboratory apparatus containing infectious bacteria, bacterial spores,
toxins and viruses, as well as pharmaceuticals and other
[0015] trace chemicals which may be included therein.
[0016] The aluminum metal bath provides a long residence time for a secondary thermal treatment
of the pyrolysis gases, as well as a chemically reactive medium which reduces residual
physiologiclly active waste as well as organic compounds of physiological origin,
typical pharmaceuticals, and metal-based tissue strains to hydrogen, hydrocarbons,
carbon, nitrogen, etc.. The gaseous byproducts from the molten aluminum treatment
do not require filtration or scrubbing such as that which would normally be required
for the effluents from single and multiple chamber incinerators and can, when containing
economic amounts of combustible gases, e. g. hydrogen and hydrocarbons, be used for
combustion, e. g. to provide heat energy.
[0017] As indicated above, heating of the waste products herein in closed chamber means
is carried out to vaporize volatile materials and to pyrolyze residual organic non-volatiles.
[0018] The gas produced in the initial vaporization carries with it some solid and/or liquid
biological material and is routed under pressure generated by the vaporization of
the volatile materials into the bath of molten aluminum where the entrained solid
and/or liquid biological material is reduced by the molten aluminum and is thus destroyed,
along with the volatile components of the stream.
[0019] As heating in the closed chamber means continues, non-volatiles are pyrolyzed. The
resulting. off- gases, which can have biological wastes entrained therein are routed
to the molten aluminum bath where said biological wastes are reduced by the mot- ten
aluminum and destroyed. When further heating results in no further vaporization the
vapors remaining in the pyrolysis chamber may be swept into the molten aluminum by
means of a stream of nitrogen or other inert gas.
[0020] Turning now in more detail to the heating step, the most volatile components in the
waste being treated, e. g. chemicals used in treating pathological specimens such
as ethyl alcohol and toluene, are flashed off. As heating continues and the temperature
in the waste which is being treated increases, proteins coagulate and water vapor
is formed from ruptured cells, saline solution and the fluids attendant to tissue
specimens. Fats, oils and other organic compounds which are not watersoluble are steam
distilled during this initial heating. On further heating, collagen proteins and any
included higher molecular weight compounds and other non-volatile materials begin
to decompose until the decomposition products become volatile. At the conclusion of
the heating step, the residue remaining in the pyrolysis chamber consists primarily
of carbon and metal salts, from tissues and from the decomposition of bone. When they
are present with the tissue, cellulosic materials and as bandages and plastics decompose
and volatilize at the appropriate temperatures. Water-soluble organic compounds such
as pharmaceuticals, stains, and compounds being screened in such processes as the
Ames test of toxicological feeding tests are either volatilized at low temperatures
or degraded at higher temperatures, thereby becoming volatile. Viruses and enzymes,
which are proteinaceous in character, are normally denatured as the temperature in
the pyrolysis chamber increases. Proteinaceous materials within tissues, however,
can be protected by the char of the tissue surrounding the protein and can remain
viable as they pass out of the pyrolysis chamber in small particles entrained in the
gases. Bacterial spores, which are particularly heat resistant, are likewise able
under some circumstances, to exit the chamber in this way.
[0021] It has been discovered herein that physiologically active materials and organic compounds
in gases from the heating, i. e. pyrolysis, chamber can be effectively treated by
passage into molten aluminum. The invention described herein provides a method for
treating pyrolysis gases at high temperatures under reducing conditions as well as
modifications necessary to a pyrolysis chamber to make secondary treatment efficient
and controllable.
[0022] Contrary to the prior art this invention contemplates the pyrolysis products of human
and animal tissue, fermantation broths, bacterial cells, viruses, spores and toxins
to be further decomposed when bubbled through the bath of molten aluminum. The decomposed
products react with the hot aluminum metal and are reduced to low molecular weight
hydrocarbons, hydrogen, nitrogen, etc. Since all biological materials which can be
volatilized in a pyrolysis chamber are composed, almost exclusively, of oxygen, carbon,
hydrogen nitrogen, sulfur, phosphorus and, on occasion, halogens, the resultant byproducts
of the reaction with the aluminum are limited in number and character, regardless
of the biological nature of the feed. For example, in addition to the gaseous reaction
products set forth above, other products can inlcude aluminum oxide and sulfide and
on occasion carbides, nitrides, phosphides or phosphorus. Because the reactions are
carried out unter reducing conditions no water or carbon dioxide is formed or exhausted.
[0023] Effluent from the aluminum treatment can be vented to the atmosphere. In such case
it is preferred to flare the combustible materials. In some cases, the effluent is
preferably treated being vented to the atmosphere. It is preferred to recover the
heating values from the combustible gases and in such case the combustible gases are
routed to a burner for this purpose.
[0024] The following is a description of a preferred working and operation example with
respect to the drawing.
[0025] Herein fig. 1 schematically illustrates a system for carrying out the process herein.
[0026] The system includes a normally closed chamber means in the form of a heating pyrolysis
retort or chamber 1 which is a refractory-lined vessel enclosed in a gas-tight, preferably
steel, encasement 2. Waste material to be treated is fed into the chamber 1 bathwise
through a door or chute (not depicted) which is preferably fitted with gasketed doors
or other means to prevent or minimize the entry of air. A second gasketed door (not
depicted) is preferably fitted just above the level of the hearth for removal of ashes.
The chamber 1 can be heated by any conventional underfiring technique or, in the preferred
embodiment, electrically. The chamber 1 is equipped with a valved line 5. The chamber
1 communicates with a refractorylined vessel 8 containing an aluminum bath 3 having
an upper surface 7 via a delivery tube 4 which receives exhaust from the top of the
chamber 1 and vents to a point near the bottom of the aluminum bath 3. The tube 4
is readily made from a refractory material, although high temperature metal alloys
are also satisfactory. An exhaust stack 9 emanates from the head space 10 above the
molten aluminum, and may discharge directly to the out-of-doors, through a treatment
system as require to meet local emissions regulations. In the preferred embodiment,
the exhaust includes a flash arrester, The valved inlet 5 is provided to admit air
or nitrogen and may be fitted with a vacuum release device to prevent backsyphoning.
[0027] In operation, the waste material is introduced into chamber 1 and the molten aluminum
bath 3 is brought up to operating temperature. Temperatues for the molten aluminum
can range from its melting point to its boiling point, i.e. from 660
°C to 2450
°C, and are selected not only to provide reduction, but also to provide decomposition
of thermally resistant and low reactivity materials. Since the maximum operating temperature
in the secondary chamber or commercially available incinerators is approximately 1400
°C, it can be seen that the molten aluminum bath is capable of providing as much or
more heat than is available in the traditional processes.
[0028] When the aluminum in vessel 8 has reached its operating temperature, heat is applied
to chamber 1 to raise the temperature in it to range from 600
°C to 850
°C, preferably from 800
°C to 825
°C. As the temperature in chamber 1 rises, vaporization and pyrolysis occur and the
expansion and volatilization force vapor and materials entrained in it to leave chamber
1 by the tube 4 and ultimately pass into the molten aluminum bath 3, wherein reduction
and secondary thermal treatment occurs and the treated materials are converted to
innocuous compounds. Transfer of gases, vapors and solids from chamber 1 to bath 3
is preferably assisted by the introduction of nitrogen or other inert gas at line
5.
[0029] When the pyrolysis process is completed, the entry port can be reopened and the chamber
1 recharged. Alternatively, when all of the waste material has been destroyed, the
heat may be turned off and the valve in line 5 opened to prevent back-sy- phoning
as the chamber cools. It is advantageous to introduce nitrogen instead of room air
into the chamber during cool-down to prevent flaring of any unburned material on the
hearth and to provide an oxygen deficient atmosphere when the chamber is recharged.
[0030] The operation of this process in different mechanical configurations is apparent
to those skilled in the art.
[0031] The following examples illustrate the practice of the invention without limitation
thereof.
Example I
[0032] A young rat weighing 205 grams is humanely sacrificed and placed in a cast iron pot
of 9,092 liters (8 quarts) recipient volume. The pot is sealed with a cast iron lid
fitted with a copper wire gasket and secured by clamps. A transfer tube constructed
of stainless steel tubing of 0,635 cm inside diameter containing 18 % chromium, 11
% nickel, 25 % molybdenum and a maximum of 0,10 % carbon with the balance being iron
(1/4 inch ID SS 316 tubing) connects the pot to a silicon carbide bonded graphite
crucible of a capacity of 6 liters (Dixon graphite crucible size 16), approximately
one-half filled with molten aluminum. A stainless steel exhaust tube fitted through
a cover directs the gases from the head space above the aluminum to a glass cold finger
trap immersed in a dry ice/acetone bath. The cast iron pyrolysis chamber is heated
by two Meker burners. The crucible is heated by a gas flame in a melting furnace.
The pyrolysis chamber is raised to a temperature of 600
°C - 650
°C as measured by a thermister and the molten aluminum is maintained in the liquid
state throughout. After 30 minutes, the heat is turned off and the lid removed from
the pot. After an additional 15 minutes, the cold finger trap is removed and the condensate
is quantitatively removed to a tared glass vessel and weighed. The liquid is then
analyzed for total organic carbon (TOO); less than 2 parts per million TOO is found.
Example it
[0033] Using the apparatus as described in Example I, three plastic petri dishes containing
cultures of Bacillus stearothermophilis are introduced into the pyrolysis chamber
and the temperature raised to a surface temperature reading of 800
°C. The cold finger trap is replaced by a Matsson-Garvin slit to agar sampler timed
to complete one revolution in 60 minutes. At the completion of the cycle, the agar
plate from the slit to agar sample is covered and removed to an incubator. After 72
hours at 37
°C, no growth is seen on the plate.
Example III
[0034] Five grams of a-naphthylamine (a suspected carcinogen) is placed on 3 agar filled
petri dishes containing a Salmonella culture to simulate an Ames test and introduced
into the pyrolysis chamber, as described in Example II. The slit to agar sampler is
replaced by a glass T-tube with a serum cap on one end. During the treatment, 100
micro liter aliquots are removed via a gas-tight syringe at 15 minute intervals. The
aliquots are injected into a gas chromatograph fitted with a flame ionization detector.
Substantially no bacteria or a-naphthylamine is detected; acetylene is present at
less than 50 parts per million. The ash in the pyrolysis chamber is collected, slurried
in a minimal amount of carbon disulfide, filtered, concentrated by bubbling nitrogen
gas through the carbon disulfide in a test tube and analyzed by gas chromatography.
Substantially no bacteria or a-naphthylamine is detectable in the extract.
Example IV
[0035] A plastic 3 mil. thick bag with a volume of 1.1365 litres (1 quart) is half-filled
with cotton bandages and a cotton hand towel.
[0036] Ten 1 cc plastic Tuberculin syringes are filled from a fermentation broth containing
approximately 5x104 spores (B. subtilis) per litre, their contents injected into the
bandages, and the syringe dropped into the bag. An additional 10 cc of broth is carefully
poured onto the bandages and towel and the bag is tied with a wire utilizing apparatus
as described in Example II. The bag is introduced into the iron pot and the destruction
process is performed with sampling as described in Example 11. After three experiments
the plates from the slit to agar samples average fewer than 1 colony per plate. The
contents of the pot, after cooling, are washed out with 100 ml of sterile water, filtered
through coarse cloth, streaked on Tripticase Soy agar plates and incubated at 37
°C for 72 hours. The plates from the extraction of the ash contain 5-10 colonies per
plate.
[0037] While the foregoing describes perferred embodiments, modifications within the scope
of the claims will be evident to those skilled in the art. Thus, the scope of the
invention is intended to be defined by the claims.