This invention relates to an apparatus and method for drying sludge to produce a substantially dry benign end product e.g. for use as a fertilizer or an innocuous and biologically benign material which can be readily disposed of.
Sludge as used herein shall be construed as including semi-solids, sludges and slurries, e.g. sewage, fecal material, containing evaporable liquids, particularly, though not exclusively, water.
There are many methods of reducing the moisture content of sludges and slurries containing organic material including filtering using filter presses, heating or chemical treatment or applying partial vacuums. A major concern when using heat and a partial vacuum to dehydrate materials is the high temperature to which the material is heated while exposing the material to an optimum vacuum level. In addition the high temperatures involved tend to reduce or destroy the fertile quality of the end product. In addition, prior art proposals are often suited only to dehydration of batches of sludge as opposed to a continuous process suitable for the mass production of a benign particulate end product.
It is an object of the invention to provide apparatus for continuously drying sludges to provide an end product having fertile qualities.
It is an object of the invention to provide a continuous process to produce an environmentally benign particulate dry final product from sludge, e.g. sewage or fecal material.
It is yet a further object of the present invention to use a cyclonic action to produce substantially dry material which is substantially odorless.
According to the invention there is provided a material drying apparatus for continuous operation to substantially evaporate the liquid content of a sludge, the apparatus comprising:
a first stage operating at ambient pressure for heating the sludge;
a second stage operating with partial vacuum for receiving heated sludge from the first stage for further heating and for drying the sludge by evaporation of substantially all liquid therefrom to leave a dry particulate material; and
a cyclonic stage operating with a partial vacuum for applying sufficient centrifugal force to the dry particulate material to render this material substantially odorless.
Preferably the first stage comprises a cylindrical housing defining a longitudinal axis, a hollow shaft coaxial with the housing and extending entirely through the housing, and conveyor paddles mounted on the hollow shaft and helically inclined relative to the axis to convey, upon rotation of the hollow shaft, sludge from an input end of the cylindrical housing to an outlet end thereof while being heated, wherein the paddles terminate at their radially outer ends sufficiently proximate the cylindrical housing to scrape sludge from the housing during rotation of the paddles about the axis by the hollow shaft and are mounted on the hollow shaft by tubes the interiors of which are open to the interior of the hollow shaft whereby steam introduced into the hollow shaft will enter the tubes to provide a heat source for the sludge.
A rotary transfer lock may be disposed between an outlet for the heated sludge from the first stage and the inlet for the heated sludge into the second stage, the transfer lock comprising a cylindrical chamber closed at its ends and housing a finned rotor having a plurality of fins cooperating with the cylindrical chamber to substantially prevent loss of the partial vacuum from the second stage while, upon rotation of the finned rotor, the heated sludge from the first stage is metered through the transfer lock for onward transmission to the second stage; and the finned rotor may be hollow and is provided with openings to allow air introduced into the rotor to pass into the heated sludge being metered through the transfer lock in order to prevent clogging of the finned rotor. The air maybe hot to one of further heat and maintain heat of the sludge.
A shredder disposed between the rotary transfer lock and the inlet for the heated sludge into the second stage is desirable, the shredder serving to break the heated sludge into small pieces and particles.
Also preferably the second stage comprises a cylindrical housing defining a longitudinal axis, a hollow shaft coaxial with said housing and a plurality of tined projections mounted on the shaft for rotation with the shaft to agitate particles and break up small pieces of the sludge entering the second stage, the tined projections terminating closely adjacent the housing with each projection having a plurality of tines and with the housing supporting blocks which cooperate with the tines upon rotation thereof to remove material from between the tines, and the tined projections may be mounted on the hollow shaft by tubes the interiors of which are open to the interior of the hollow shaft to receive steam passed through the hollow shaft to provide additional heating of the sludge.
Again preferably dried particulate material from the second stage is drawn into a cyclone by a vacuum pump connected to the cyclone to provide the partial vacuum in the cyclone and second stage, the material being drawn into the cyclone by way of a venturi to accelerate the particles for entry tangentially into the cyclone whereby centrifugal force generated by passage of the dried particles in the cyclone renders the dried particles substantially odorless, a rotary transfer lock being located to provide an outlet for particles from the cyclone and to substantially prevent loss of the partial vacuum from the second stage and the cyclone.
The invention also provides a method of drying sludge to produce a benign particulate material comprising the steps of:
The invention will now be described, by way of example, with reference to the accompanying drawings, in which:
Referring to
The design of the hopper 2 and its rotary shredder 4 will be well known to those of skill in the appropriate art.
The first stage comprises a tubular housing 20, about 2 feet in diameter and about 30 feet long, concentrically surrounding a hollow shaft 22, about 6 inches in diameter, extending through the length of the tubular housing 20 and beyond the ends thereof by way of seals and bearings 24 for connection to a motor 26 capable of rotating the shaft 22 within the housing 20 at from about 10 to about 50 r.p.m. The hollow shaft 22 is connected at one end to receive high pressure non-turbulent steam at about 300° F. or more. The steam is exhausted at the other end of the shaft 22 after passage therethrough. The housing 20 is surrounded by two serially disposed insulated heat jackets 28 to insulate and heat the housing substantially throughout its length. To provide a source of heat to the heat jackets 28, steam inlets and outlets 30 are provided. As with the shaft 22 the steam for the jackets 28 is supplied as a high pressure non-turbulent steam at about 300° F.
The shaft 22 supports a plurality of helically inclined, relative to the axis 31 of the shaft 22 and housing 20, paddles 32 (two only being shown in FIG. 1). Sixteen or more such paddles 32 may be evenly spaced along the shaft 22 and these may be dispersed in a straight line parallel to the axis 31 of the shaft 22 or in a helical array as shown in FIG. 6.
Each paddle 32 (see
As seen in
The temperature of the sludge is at least 200° F. at the outlet end 34 as determined by its rate of conveyance through the first stage 8 and the heating provided by the steam heated jackets 28 and shaft 22 during this conveyance.
The entire housing 20 and heat jackets 28 are insulated to prevent loss of heat from the housing 20. It should be noted that the heating of the sludge, in the first stage 8, takes place substantially at ambient pressure.
If required the housing 20 and shaft 22 may be constructed of serially interconnected parts and also, if required, two or more first stages 8 may be serially arranged before the heated sludge exits to the transfer lock 12.
The transfer lock 12 is a rotary device somewhat akin to a revolving door. The transfer lock 12 comprises a housing 48 defining an inlet 50, connected to the outlet end 34 of the first stage, and an outlet 52, to supply the heated sludge to the second stage 10 by way of the shredder 14, with a cylindrical portion 54 therebetween. The cylindrical portion 54 is closed at its ends. Housed in the portion 54 is a finned rotor 56 coaxial with cylindrical portion 54 comprising at least three, preferably six or eight, fins 58 mounted on a hollow shaft 60 with their radially outer ends contacting or in very close proximity to the cylindrical portion 54 and their axial ends contacting or in very close proximity to the closed ends of the cylindrical portion so that the path from the inlet 50 to the outlet 52 is always closed by at least two of the fins 58 to prevent loss of the partial vacuum from the second stage 10 while passing the heated sludge to the outlet 32. The hollow shaft is sealed and supported in the ends of the cylindrical housing. The finned rotor 56 (shown in greater detail in
Air is supplied through the hollow shaft 60 to openings 62 for onward passage into the heated sludge to prevent clogging. If the air is hot it will further heat the sludge, or at least maintain its temperature, so that heated sludge enters the second stage 10 at about 200° F. or more.
The heated sludge passes from the outlet 52 to a small shredder 14 driven by a shredder motor 66. The shredder 14 is sealed to prevent loss of vacuum from the second stage 20 and has a multi-bladed rotor driven at between about 200 and about 2000 r.p.m. to break the heated sludge into small pieces and particles. The small pieces and particulate material so formed is fed into the input end of the second stage 10 as shown by arrow 68.
The second stage 10 comprises a cylindrical housing 70 coaxial with a hollow rotatable shaft 72 supported in bearings 74 and sealed by seals 76, at the ends of the housing 70, for rotation at about 10 to about 50 r.p.m. by a motor 78. The housing has a diameter of about two feet, a length of about 15 feet and is surrounded by an insulated heat jacket 80. The hollow shaft 72 has an outside diameter of from about six inches to about one foot. Mounted on the shaft 72 are a plurality of tined projections 82 (see
Each tined projection 82 has three equi-spaced tines 86 terminating at or closely proximate the interior cylindrical surface of the housing 70. Affixed to the housing are blocks 88 sized to closely pass between the tines 86 as the tined projections 82 are rotated by the shaft 72 thereby to remove any particulate material held between the tines.
The heat jacket 80 has connections 90 for the admission and exhaust of high pressure non-turbulent steam at about 300° F. whereby the steam passes through the heat jacket 80 to heat the housing 70 and the particulate material therein.
The housing 70 is evacuated to about 20 inches Hg. below ambient pressure by a vacuum pump 106 attached to a cyclone 18 which receives particulate material dried in the second stage 10 by way of a duct 94 and a venturi 16. The pressure in the housing may be adjusted by controlling (bleeding) air into air inlet 98 at the inlet end of the housing 70.
The venturi 16 may have an air inlet 100 for pressurized air to increase acceleration of the dried particulate material into the cyclone 18 substantially tangentially along the cyclone's inner surface.
The cyclone 18 has a cylindrical upper body connected to an inverted cone which decreases in diameter to an outlet controlled by a rotary particle lock 102 which functions in similar manner to the transfer lock 12 to remove the particulate material from the cyclone 18. This lock 102 is driven by motor 104.
The accelerated particulate material entering the cyclone is subjected to centrifugal force due to its motion around the interior of the cyclone and to the force of gravity. As a result the particulate material follows a helical path to the particle lock 102.
The second stage 10 and cyclone are evacuated by the vacuum pump 106 connected to an outlet 108 at the top of the cyclone 18. A baffle 110 ensures that the particulate material is not drawn into the vacuum pump 106.
The forces applied to the particulate material in the cyclone serve to substantially destroy odors and to destroy any pathogens remaining in the particulate material.
Although preferably horizontal the first and second stages may be inclined downwardly from their inlets to their outlets in order to assist in conveyance of the sludge/particulate material therethrough.
It will be appreciated that while the use of steam for heating has been described above, other sources of heat, e.g. hot air, electrical elements, solar energy, geothermal energy, could be used. The source for heating the various components of the invention may also be combined into a single source with an appropriate distribution system and/or different types of heat source could be used in different components or combinations of components.
Similarly, some or all of the motors could be replaced by a single motor with appropriate transmission arrangements to drive associated components.
It will also be appreciated that the vacuum pump 106 may have an outlet connected to a condenser to condense water vapor or steam removed from the sludge and removed through the vacuum pump 106.
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Number | Date | Country | |
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20050000108 A1 | Jan 2005 | US |