The present invention relates generally to the art of collection and disposal of waste products. It has particular application to the collection, treatment, and recycling of encapsulated waste, such as municipal solid waste (MSW) including medical waste and agricultural waste.
For the purpose of this specification, waste products refer to household waste ‘garbage’, which is encapsulated in garbage bags, usually plastic bags, and medical waste encapsulated in bags and rigid containers, MSW.
It is common in certain fields to enclose waste in sealed containers such as plastic bags, to facilitate removal for disposal. One particular instance of such packaging is in the case of medical waste wherein the waste is packaged, not only for convenience of handling but also to ensure that pathogens are not spread inadvertently.
Alternative means of treatment of MSW have previously been disclosed by the present applicant in a series of patents, amongst which are issued in the U.S. Pat. No. 4,342,830 dated 3 Aug. 1982. U.S. Pat. No. 4,540,495 dated 10 Jun. 1985. U.S. Pat. No. 4,844,351 dated 4 Jul. 1989. U.S. Pat. No. 4,190,226 dated 2 Mar. 1993. U.S. Pat. No. 5,361,994, dated 8 Nov. 1994. U.S. Pat. No. 5,427,650 dated 27 Jun. 1995. Each of these have been primarily concerned with providing apparatus and method to improve the amount of waste that may be recycled. However each patent discloses a treatment of the waste by steam and pressure in a manner which sterilizes the waste. In addition the methods include a means of thorough agitation and mixing which ensures that all of the waste is effected by the steam, heat and pressure. While the process defined in the applicant's patents mentioned above have been found to effectively sterilize the waste, even medical waste, they have nonetheless been found to be inefficient in treating waste encapsulated in multiple bags and rigid containers. The treatment process requires substantial processing time and energy to break down the bags and other containers sufficiently to ensure thorough agitation and sterilization of the contents. This requires a considerable energy input beyond what would normally be required to treat the waste, therefore the process is inefficient. The waste included in the bag is small compared to the volume of the sealed bag, because of the volume of air in the bag. If a pressure vessel, as disclosed in the applicants patents mentioned above is filled with bagged waste, the quantity of waste held is quite small compared with the volume of the pressure vessel. The treatment process requires a substantial processing time to break down the plastic of the waste bags to sufficiently ensure thorough agitation and sterilization of the contents. This requires a considerable energy input just to remove the waste from its encapsulation so that it may be exposed to treatment.
The proceeding discussion of the background to the invention is intended only to facilitate an understanding of the present invention. It should be appreciated that the discussion is not an acknowledgment or admission that any of the material referred to was common knowledge in Australia at the priority date of this application.
Accordingly, the invention resides in a waste collection and processing unit adapted to process encapsulated waste. The process unit comprising an autoclave ratable about an axis, drive means adapted to cause rotation the autoclave, defining a chamber with an inlet, a first closure adapted to sealing close the inlet, guide means within the chamber adapted to coax the waste away from the inlet during the rotation of the autoclave, piercing means adapted to pierce the capsules on contact and a port adapted to be connected to a source of sterilizing medium.
According to a preferred feature of the invention, the chamber is further provided with an outlet and and a second closure adapted to sealingly close the outlet, the guide means being adapted to coax the waste to move from the inlet to the outlet during the rotation of the pressure vessel.
According to a preferred embodiment, the sterilizing medium is steam.
According to a preferred feature of the invention, the piercing means is provided in a portion of the autoclave proximate to the inlet.
According to a preferred embodiment, the autoclave is substantially cylindrical, the chamber thereby defined having an inner surface, and the guide means comprises a helical rigid strip extending substantially perpendicularly inwardly from the inner surface into the chamber. (flighting)
According to a preferred embodiment, the axis about which the autoclave rotates is inclined to the horizontal, the inlet being positioned at a level above the outlet.
According to a preferred embodiment the guide means is configured helical to extend substantially along the length of the inner surface of the cylindrical pressure vessel.
According to a preferred embodiment the guide means may be of variable dept. into the cylinder in order to control the flow of the material.
According to a preferred embodiment, the pitch of the helical guide means reduces proximate to the outlet.
According to a preferred feature of the invention, the piercing means is associated with the guide.
According to a preferred embodiment, the piercing means comprises knife members releasably supported by the guide means.
According to a preferred embodiment, the knife members extend from the inner edge of the guide means inwardly into the chamber.
According to a preferred embodiment, the piercing means comprises serrations formed on the guide means.
According to a preferred feature of the invention, the process unit further comprises loading means associated with the inlet.
According to a preferred feature of the invention, an air inlet is provided proximate to the inlet, the air inlet being adapted to be connected to a source of pressurized air, which may be heated.
According to a preferred feature of the invention the autoclave is provided with a vacuum inlet, the vacuum inlet being adapted to be connected to an evacuating means.
According to a preferred feature of the invention, a water inlet is provided proximent to the inlet, the water inlet adapted to be connected to a source of pressurized water or other fluids.
According to a preferred feature of the invention, the pressure vessel is associated with a barrier which extends around the around the exterior of the pressure vessel and isolates the inlet from the outlet.
According to a preferred feature of the invention, the inlet is located in an enclosure accommodating the loading means, the enclosure isolating the inlet from the ambient surroundings.
According to a preferred embodiment, the barrier comprises a wall of the enclosure.
According to a preferred feature of the invention, the process unit further comprises a collecting zone associated with the outlet which is isolated from the ambient surroundings.
According to a preferred feature of the invention, the process unit further comprises a sensing means adapted to sense the viscosity of the fluidised waste, the sensing means being adapted to provide a signal when a predetermined level of viscosity of the fluidised waste has been attained.
According to a preferred feature of the invention, the process unit is microprocessor controlled.
According to a preferred feature of the invention, the process unit may be mounted on a truck or other mobile means.
According to a preferred feature of the invention, the mobile process unit may be used as a collection compactor (garbage compactor truck}.
The invention will be more fully understood in light of the following description of several specific embodiments.
The description is made with reference to the accompanying drawings of which:
The first embodiment of the invention as shown at
The cylindrical vessel 12 defines an internal chamber 50 having an inlet 23 at one end 21 of the cylindrical vessel 12 and an outlet 28 at the other end 26. The process unit 10 is further provided with a first closure adapted to close the inlet 23 and a second closure 29 adapted to close the outlet 28. Each of the closures are supported from above the cylindrical vessel 12 by support means adapted to move the closure from a position wherein it is engaged with the respective end to a position upwardly clear of the respective end when disengaged from the respective end.
The inlet closure is provided with a first aperture (not shown) which is connected to a source of steam through a steam line 36. The inlet closure is further provided with a second aperture (not shown) which is connected to a source of compressed air through an air line 37. The inlet closure is further provided with a third aperture (not shown) which is connected to a vacuum pump through a vacuum line 44.
A first enclosure 42 is associated with the inlet to substantially contain the inlet and to collect any air expelled from the chamber when waste is delivered to it. Air from within the first enclosure 42 is exhausted through an air treatment means adapted to destroying any pathogens which may be present in the air prior to the air being exhausted into the atmosphere.
The process unit 10 further comprises an inlet conveyor 38 and a sub-conveyor 39 (see
As shown in
In addition, the collection and sorting means is provided with a filtration means to collect airborne waste expelled from the cylindrical vessel by compressed air. The filtration means comprises a mesh filter exhausting to the environment at the end of a duct directing the airborne waste away from the path of the more dense waste.
As shown in
The pitch of the helix of the flighting is reduced in the outlet portion 27, producing compression on the waste. For ease of maintenance, the flighting 52 may be constructed from a series of segments configured end to end arrangement and reasonably secured to the inner surface 51.
In the region of the chamber adjacent to inlet 23 and as shown in more detail in
In use, bagged waste 41 is loaded into the cylindrical vessel 12 through inlet 23 by the conveyor 38 while the cylindrical vessel 12 is rotating, outlet 28 being closed by second closure 29. After entry into chamber 50, the container (bag) 41 is moved about within the chamber 50 because of the rotation of the cylindrical vessel 12. When a bag 41 contacts the pointed end of a knife member 61 in the inlet portion of chamber 50, the bag 41 is pierced. The rotational movement of the cylindrical vessel 12 ensured that the bag (container) 41 is torn open after it is pierced and injected by steam, thereby releasing and spreading the contents within chamber 50. Further as a result of the rotational motion the flighting urges the waste away from the inlet, toward the outlet portion. As a result the waste is pre-compacted during the loading process, increasing the vessel capacity by 50% or more. Loading continues until sufficient waste has been inserted. Thereafter the inlet is closed by the first closure 24 and steam under pressure is introduced into chamber 50. The cylindrical vessel 12 is rotated and pressurized steam is directed into the chamber 50 through the steam line 54, expelling air through a relief valve (not shown) and filling the cylindrical vessel 12 with steam under pressure. The helical configuration of the flighting 52 transports the waste materials to the closed end of the vessel. Since the exit closure member 16 is closed and there is no exit, the waste material is squeezed back (extruded) through that portion of the chamber between the flighting in a manner previously described in the applicant's patent no. U.S. Pat. No. 5,190,446. This process causes any paper (cellulose) to be torn apart by the compression and sheer action of this indirect extrusion.
After a predetermined viscosity or period of time which depends on the nature of the waste being being processed, the pressure within the vessel is released. The steam remaining in the autoclave is evacuated through the vacuum line 44. A predetermined vacuum depending on the nature of the waste being treated, causes the the moisture content of the waste to be reduced. As a result of the heat and vacuum the cellulose material present takes on a finely shredded, fluffy appearance as a result of being exposed to the vacuum and this material is easily able to be displaced by a blast of air. Upon completion of the evacuation phase, air is admitted into the autoclave to bring the priddure to atmospheric pressure. The second closure member 29 is opened. The cellulose material is expelled by directing a draft of pressurized air from the air line 37 into the chamber 50. This airborne waste is collected by the filtration means to collect airborne waste within the waste collection and sorting means 45. The remainder of the processed waste which is solid or paste like is forced out of the chamber 50 by the rotary of the flighting 52.
In a preferred adaptation of the first embodiment, the inlet closure is provided with a third aperture (not shown) which is connected to a source of water by a water line. a spray nozzle is mounted to the inner side of the third aperture. In use, after the cylindrical vessel is emptied of the waste, water from the water line is sprayed into the chamber to clean the chamber of remaining refuse.
In a second embodiment, as shown in
In a third embodiment as shown in
In a fourth embodiment, not shown, the piercing means comprises saw tooth-like serration's, not shown, associated with the inner edge 52 of the flighting. The internal edge of flighting has saw-tooth like edging to the flighting.
In a fifth embodiment, the serrations are provided by a metal strip with the serrations preformed on one edge, the strip being adapted to be secured to the flighting proximate the edge of the edge of the flighting.
In a sixth embodiment, the pressure unit comprises a pressure vessel rotatable about an axis and having a motor adapted to cause rotation of the pressure vessel in a manner similar tooth described with respect to the first embodiment. The pressure vessel defines a chamber with an inlet and a first closure adapted to sealingly close the inlet. Guide means and piercing means are provided within the chamber, in a manner similar to that of the first or subsequent embodiments. However, in this embodiment, no separate outlet is provided.
In a further adaptation of any of the previous embodiments, a second enclosed space in the form of a room encloses the inlet end of the cylindrical vessel, the cylindrical vessel penetrating an opening in a wall of the room intermediate the ends of the cylindrical vessel. The conveyor, 38, the sub-conveyor 39 and first enclosure are contained within the second enclosure, A sealing means is associated with the opening of the wall, the sealing means being adapted to sealingly engage the cylindrical vessel without impeding rotation. In this manner, the outlet of the cylindrical vessel is isolated from the inlet. The room containing the inlet may then be treated as a hazardous area where in it is recognized that there is a risk of contact with pathogens and in which appropriate safety precautions should be taken. By operation of the process unit as described above, the outlet of the cylindrical vessel need never be opened while the inlet is open, other than for maintenance of the process unit. When the second closure is opened, the inlet is closed by the first closure and processing of the waste has been completed rendering the chamber of the cylindrical vessel and its contents are completely sterilized. In this way, the area adjacent to the outlet may be treated as a safe area with regards to the spread of pathogens wherein no special precautions are required.
In this embodiment the loading means and the waste collection and sorting means are adapted so that they may be alternately positioned adjacent to the opening and otherwise moved clear of the opening, in other respect the ampetures for steam etc. are best located in the closed end. This embodiment may be adapted for mobile operation for waste collection, (waste compactor truck). See
In use, when processing is complete, the fluffy cellulose waste is removed by directing a stream of air from the airline into the chamber. the cellulose waste is expelled through the opening as a result and the waste filtered in the manner of the first embodiment. The remaining waste is removed from the chamber by reversing the rotation of the pressure vessel, whereby it is coaxed by the flighting. In other respects, this embodiment may be be adapted as previously described in respect of the other embodiments.
In a further adaptation of any of the previous embodiments, the process unit further comprises a sensor adapted to detect the viscosity of the processing waste. The sensor is adapted to signal when when the processed waste has reached a predetermined level of fluidisation. This level of fluidisation more accurately identifies when the waste has been processed sufficiently. The signaling by the sensor may then be used as a means to identify when the processing should cease, rather than operating the process unit for specific time period.
In an adaptation of the previous embodiments, the pitch spacing of the flighting (see
In another adaptation of any of the previous embodiments, the process unit is microprocessor controlled. A microprocessor is connected to actuate the motor, 33, the closures 24 and 29, the vent fan the conveyor 38 and sub-conveyor 39, steam air and water valves and waste collection and sorting means 45. Automatic operation of the process unit is established in a pre-determined manner, with appropriate safety interlocks in place to ensure that the operation occurs only after appropriate precautions have been taken.
The process unit according to the above embodiments provides a means for processing of bagged waste in which a substantial quantity of bagged waste may be processed in an efficient and economic manner in a way in which the environmental impact is considerably reduced from previous methods, by use of this process unit, a process for processing bagged waste may be implemented which incorporate procedures for safe handling of bagged waste containing pathogens. The process is further adapted to the use of techniques previously identified for for the processing municipal solid waste, which substantially enhances the proportion of waste recovered for recycling. In addition, when used to process medical waste, the process is effective in separating a needle or other “sharps” from their plastic hypodermic syringe. Such needles are then able to be separated for re-cycling. As a result of this separation of the sharps, the need for hammer-mill is removed. This reduces operating costs considerably.
It should appreciated that the scope of the present invention need not be limited to the particular scope of the embodiments described above.
Number | Date | Country | Kind |
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2004904499 | Aug 2004 | AU | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/AU05/01185 | 8/9/2005 | WO | 00 | 2/12/2007 |