This disclosure relates to systems and methods for drying wet organic solids, for example biosolids, through the use of radiant and convective heat generated from at least one infrared heating element. Wet organic solids must be dried in many applications, for example, solids from wastewater treatment systems. In many instances, wet organic solids are dried by convection only. This process is both time consuming and energy intensive. The utilization of radiant heat, especially in combination with convective heat, provides for the possibility of lower operating costs and shortened processing times.
A process for drying wet organic solids is disclosed. One aspect of the process is providing an infrared drying system having a housing, a conveyor extending through the housing, at least one infrared heater located within the housing and being directed towards the conveyor; and a fan for moving an airflow stream through the at least one infrared heater and onto the conveyor. Another step in the process can be providing wet organic solids and feeding the wet organic solids onto the conveyor at a metering rate. In one embodiment, the wet organic solids have a moisture content of about 80 percent by weight or less. Another step in the process can be transporting the waste matter into the housing of the drying system. Moisture is removed from the wet organic solids by exposing the wet organic solids to at least one infrared heating element within the drying system and an airflow stream that has been heated by the at least one infrared heating element. The wet organic solids can remain in the infrared drying system until a moisture content of less than 10 percent by weight is achieved to result in dried solids. Subsequently, the solids can be transported out of the housing, such as by the conveyor.
A process for treating wet organic solids from a wastewater stream is also disclosed wherein an infrared drying system comprising at least one infrared heating element and a heated airflow stream is utilized. In one step, wet organic solids are provided having a moisture content of about 80 percent by weight and a fecal coliform density of between about 1,000 MPN/g TS and about 2×106 MPN/g TS. In other steps a metering rate for feeding the wet organic solids into the treatment system; an exposure intensity output for the waste matter treatment system; and an exposure period for simultaneously exposing the wet organic solids to the heating element and the airflow stream of the treatment system can be determined. The wet organic solids can be fed at the metering rate into the waste treatment system and exposed to the at least one infrared heating element and the heated airflow stream for the exposure period at the exposure intensity output. The metering rate, the exposure intensity output, and the exposure period can be selected to reduce the moisture content of the waste matter to less than 10 percent by weight, and to reduce the fecal coliform density of the waste matter to less than 1,000 MPN/g TS (most probable number per gram of total solids on a dry weight basis).
Reference will now be made in detail to the exemplary aspects of the present disclosure that are illustrated in the accompanying drawings. Wherever possible, the same reference numbers will be used throughout the drawings to refer to the same or like structure.
Referring to
Housing 110 also includes an air inlet 116 and an air outlet 118. Air inlet 116 is for allowing air to enter the housing 110 while housing air outlet 118 is for allowing air to exhaust from the housing. In the particular embodiment shown, air inlet 116 is located at a top portion of the housing 110 and is about 14 inches in diameter while air outlet 118 is also located at a top portion of the housing 110 and is about 8 inches in diameter. One will appreciate that other dimensions and locations may be selected depending on production requirements.
Extending through the housing 110 is a conveying system 120. Conveying system 120 is for transporting the solids through the housing interior 111 from the process inlet 112 to the process outlet 114. As shown, conveying system 120 includes a conveyor belt 122 extending between two rollers 124, 126. Depending on the characteristics of the wet organic solids, conveyor belt 122 may consist of flat belting, rollers, parallel chains, flatwire, flex wire, or TEFGLAS. In the particular embodiment shown, the conveyer 130 is a flat belt coated with TEFLON. Conveyor belt 122 is also driven by a motor 128. The speed of the motor 128 can be adjusted to vary the speed of the conveyor 120 such that the solids are within the housing interior 111 for a desired period or duration.
Within the housing interior is an upper infrared heating system 130 and a lower infrared heating system 140. Upper infrared heating system 130 is for directly heating the solids to be dried through a combination of radiation and convective heat. Radiant heating is provided by medium or long wave infrared heating elements within heating system 130. Convective heating is provided by the air delivered to the housing interior 111 via air inlet 116 and fan 150, discussed later, as it passes through the heating elements of the upper infrared heating system 130, and onto the solids. Upper infrared heating system 130 can include one infrared heating element or a plurality of infrared heating elements. Furthermore, the heating elements can have either the same or different heating outputs from each other. In the particular embodiment shown, upper infrared heating system 130 includes three heating elements 130a, 130b, 130c that span a majority of the width and length of the housing interior 111. One suitable heating element 130a,b,c suitable for use with the infrared drying system 100 is the Series FSA medium wave infrared radiant heater provided by Process Thermal Dynamics (also known as Pro-Therm) of Brandon, Minn. In the embodiment shown, each heating element 130a, 130b, and 130c has a heating output of about 16,000 watts for a total heating output of about 48,000 watts.
Lower infrared heating system 140 is for providing additional radiant heating to the conveyor belt 122 such that the solids to be dried can be additionally heated by coming into contact with the conveyor belt 122. In the embodiment shown, lower infrared heating system 140 is placed within conveyor belt 122 and directed upwards towards the solids to be dried. Lower infrared heating system 140 can include one infrared heating element or a plurality of infrared heating elements. In the particular embodiment shown, lower infrared heating system 140 includes three heating elements 140a, 140b, 140c that span a majority of the width and length of the housing interior 111. One suitable heating element 140a,b,c suitable for use with the infrared drying system 100 is the Series CB medium wave infrared heater provided by Process Thermal Dynamics of Brandon, Minn. In the embodiment shown, each heating element 130a, 130b, and 130c has a heating output of about 4,000 watts for a total heating output of about 12,000 watts. However, one will understand that different heating outputs can be chosen based on production requirements. Furthermore, the heating elements can have the same or different heating outputs from each other. Additionally, where conveyor belt 122 is not a solid belt, lower infrared heating system 140 can also provide radiant heating to the solids to be dried from below.
Mounted to the air inlet 116 is a fan 150 driven by a motor 152. Fan 150 is for causing air to circulate throughout the housing interior 111 and directly through the upper infrared heating system 130. As stated previously, the air passing through the heating system 130 is heated and provides convective based heating to the wet organic solids. This air circulation also prevents a vapor barrier from forming above the waste products that would otherwise reduce the moisture removal rate from the waste products. In the particular embodiment shown, fan 150 is mounted to the housing 110 at the location of the air inlet 116 such that fan 150 forces air directly into the housing interior 111. Although a small portion of the air will escape through the process inlet and outlet 112, 114, the majority of the air is removed from housing interior 111 via air outlet 118. To ensure that air is forced through the upper infrared heating system 130 and does not bypass directly to air outlet 118, a baffle 119 is provided within the housing interior 111. In one embodiment, fan 150 has a capacity of 2,000 cubic feet per minute. One will appreciate that multiple fans 150 can be utilized simultaneously for a more even distribution of airflow within the housing interior 111. One will also appreciate that fan 150 can be remotely located and connected to the inlet 116 via ductwork. To further facilitate removal of the air from the housing interior via air outlet 118, an exhaust fan 160 driven by a motor 162 can also be provided. In one embodiment, exhaust fan 160 has a capacity of about 2,000 cubic feet per minute.
Infrared drying system 100 is also shown as being supported by a stand 170. Stand 170 can be of any construction suitable to support the weight of housing 110, and the associated components. In the particular embodiment shown, stand 170 is constructed of welded tubular members and has a pair of adjustable legs 170a and a pair of fixed length legs 170b that allow for adjustment of the height and orientation of the housing 110.
To control operation of the infrared drying system 100, a control panel 180 can be provided. Control panel 180 can be configured to monitor and control all of the process variables relating to the drying system. One set of outputs control panel 180 can provide is an on/off/speed control of conveyor motor 128. For example, conveyor motor can be controlled to achieve a belt speed anywhere from 1 inch per minute to 60 inches per minute by control panel 180. Another set of outputs that can be provided is on/off/output level of the upper infrared heating system 130 and lower infrared heating system 140. In one embodiment, output control of the heaters can be provided by an SCR controller. Fans 150 and 160 can also be provided with on/off/speed control. The control panel 180 can also be utilized to measure the conditions of the drying system 100 to provide user or automated feedback for adjusting the process variables. For example, the temperature of the solids to be dried can be sensed and utilized to control the output from the upper infrared heating system 130 and/or the lower infrared heating system 140.
As can be seen most easily in
With reference to
As can be most easily seen in
Housing 110′ also has two air inlets 116′ to which fans 150′ are mounted. In the exemplary embodiment shown, air inlets 116′ are about 14 inches in diameter while fans 150′ have a capacity of about 2,000 cubic feet per minute per fan. Similar to the first embodiment, housing 111′ has a single air outlet 118′ connected to fan 160′ for extracting air from the interior 111′ of the housing. In the particular embodiment shown, air outlet 118′ is about 18.25 inches in diameter and exhaust fan 160′ has a capacity of about 4,000 cubic feet per minute. Due to the increased size of housing 110′, conveyor system 120′ has a longer conveyor belt 122′.
Drying system 100′ is also shown as having an upper infrared heating system 130′ including six individual heating elements 130a to 130f and having a lower infrared heating system 140′ having six individual heating elements 140a to 140f. Due to the increased size of the housing 110′ and the number of heating elements, drying system 100′ has an increased capacity, as compared to drying system 100. Further capacity can be achieved by arranging a plurality of drying systems 100′ end-to-end in a line layout, such as the configuration shown in
From the two embodiments presented in
With reference to
In the third embodiment, wet solids 10 are processed into dry solids by within a rotating drum drying system 200. As shown, drying system 200 has a housing 210 with a drum 212 extending between a first end 212a and a second end 212b, and defining an interior volume 212c. In one embodiment, the drum housing 210 has a length of about 10 feet and a diameter of about 7 feet.
As shown, the housing 210 is supported by a frame assembly 270. The support frame assembly can have a vertical front section 272a for supporting the first end 212a of the drum 212 and a vertical rear section for supporting the second end 212b of the drum 212. A base portion 272c is provided to support the front and rear sections 272a, 272b. The frame assembly 270 is also provided with a front extension 272d for supporting a conveyor feed system 230, discussed later. The frame assembly 270 also includes an additional frame structure 276 extending between the front and rear sections 272a, 272b and through the interior volume 212c of the drum for slidably supporting an infrared heating system 240, discussed later. As shown, frame structure 276 has a first arm 276a and a second arm 276b, each of which is provided with a channel for receiving the infrared heaters of the heating system 240.
On the exterior of the drum 212 are ribs for providing structural strength to the housing. As shown, two of the ribs 212d are configured to engage with roller assemblies 274 such that the housing 210 is both supported by the roller assemblies 274 and allowed to rotate. As shown, two pairs of roller assemblies 274 are provided to support the drum 212 for a total of four roller assemblies 274. Each of the roller assemblies 274 is shown as being provided with two casters that are pivotally mounted such that the assemblies 274 can easily conform to the outer surface of the drum 212. Other configurations are possible.
Housing 210 is also provided with another rib or channel 212e that is configured to receive a drive belt or chain 226c. As shown, the drive belt or chain 226c wraps around the drum 212 and engages with a gear reducer 226b that is in turn engaged with a drive motor 262a. The gear reducer 226b is selected to allow for the desired rotational rate of the drum 212. Alternatively, motor 262a could be driven by a variable frequency drive and connected directly to the belt or chain 226c without reliance on a gear reducer. When the motor is activated, the drive belt or chain 226b causes the drum to rotate.
The interior of the housing 210 is provided with a pair of parallel spiral flights 222 (222a, 222b) that move the solids to be dried from the first end 212a to the second end 212b when the drum 212 is rotated. Although two spiral flights 222a, 222b are shown, only one spiral flight 222 could be used, or more than two spiral flights 222 could be used. The spiral flights 222 are arranged on the interior side of the drum 212, and form a pair of continuous helical surfaces from the first end 212a to the second end 212b. As can be most easily seen at
With reference to
For example,
In the embodiment shown at
The interior of the drum 212, between the blades of the spiral flights 222a, 222b, is provided with a plurality of cleats 224 radially spaced about the interior surface. The cleats 224 act to lift the solids residing at the bottom of the interior volume of the drum housing 210 towards the top layer of solids. In one embodiment, the cleats 224 have a height that is less than or equal to the height of the spiral flights 222. In one embodiment, the cleats are about 3 inches tall. The churning action caused by the cleats 224 assures that the solids within the drum are exposed in a more even fashion to the infrared heating system 240, discussed later.
As shown, the housing 210 at the first end 212a is also provided with a front end plate 216 and a center plate 214 located within the front end plate 216. As configured, the front end plate 216 has a height of about 15 inches and is fixed to the drum 212 while the center plate 214 is fixed to the front section 272a of the support assembly 270. Accordingly, front end plate 216 rotates with drum 212 while center plate 214 does not. In the embodiment shown, a gap, for example about a ¼ inch gap, is provided between the plates 214, 216 such that no frictional resistance is caused by the drum rotation. Alternatively, a low friction bearing surface could be provided to eliminate the gap. As shown, the center plate 214 is provided with a first opening 214a for allowing the wet solids 10 to be introduced into the interior volume 212c of the drum 212. In the embodiment shown, opening 214a is configured to receive the discharge end of a belt type conveyor 234. The center plate 214 is also shown as having a second opening 214b which is configured to receive an exhaust outlet duct 266. Exhaust outlet duct 266 is for allowing relatively moist air travelling through the drum interior volume 212c to be exhausted to the outdoors.
The housing 210 at the second end 212b is provided with a back end plate 218. As shown, the back end plate 218 is provided with a large central opening 218b that allows for air to easily enter the interior volume 212c of the drum 212 such that it can absorb moisture within the drum 212 and be exhausted via outlet duct 266. The back end plate is also provided with two curved openings 218b for allowing the dried solids 20 to exit the drum 212. As shown, the number of openings 218b corresponds with the number of spiral flights 222 such that each opening 218b is aligned with one of the spiral flights 222.
As shown, the heating system 240 includes a plurality of electric infrared heaters 242 for drying the solids 10. Although the infrared heaters 242 are shown as being electric, the heaters 242 may also be configured as gas or liquid propane infrared heaters. Additionally, the heaters 242 may be configured to have different heating outputs from each other. In the embodiment shown, a first infrared heater 242a is provided near the first end 212a where the wet solids 10 are first introduced. As shown, first infrared heater 242a is configured as a short wave electric infrared heater and operates to preheat the drum 212 such that conductive heat can be transferred from the drum 212 to the wet solids 10 residing at the bottom of the drum 212. In the configuration presented, the first infrared heater 242a is slidably mounted to the frame structure 276 and is oriented horizontally to face directly downwards towards the bottom of the drum 212.
Also shown is a pair of second infrared heaters 242b that are configured as electric short wavelength heaters. The second heaters 242b operate to transfer infrared energy to the wet solids 10 after entrance at the front end 212a. Short wavelength heaters are capable of dissipating a high heat flux density and therefore are beneficial for use in drying the wet solids 10 at their most moisture laden stage. Adjacent to the second infrared heaters 242b is a set of three third infrared heaters 242c. The third infrared heaters 242c are configured as electric medium wavelength heaters and operate to further reduce the moisture content of the wet solids. As configured, the second and third heaters 242b, 242c are oriented at an angle with respect to the drum 212. In the embodiment shown, the heaters 242b, 242c are oriented at about a 55 degree angle with respect to the vertical plane extending through the longitudinal axis of the drum 212. It is also noted that the heaters 242b, 242c are oriented to face the side of the drum 212 at which the cleats 224 bring up the wet solids 10 from the bottom of the drum 212 such that infrared heat is applied to the solids as they are being continually deposited at the top surface. However, other orientations are possible, such as a completely horizontal configuration similar to that shown for the first heater 242a.
The heaters 242b, 242c are supported by a bracketing system 244 that attaches to the support structure 276 at the first arm 276a and 276b. As shown, bracketing system 244 has a first arm 244a that engages into the channel of the support structure first arm 276a and a second arm 244b that engages into the channel of the support structure second arm 276b. The heater 242a is provided with a similar configuration, but with a bracket that does not hold the heater at an angle. As configured, the first and second arms 244a, 244b are received by and slide within the channels of the first and second arms 276a, 276b. Accordingly, the bracket and channel configuration allows for each of the heaters 242 to be slidably removable from the interior volume 212c without requiring service personnel to enter into the drum. In one embodiment, the channels and/or arms are coated with an HDPE material to reduce friction. It is noted that this configuration allows for the heater configuration to be changed from one application to another more easily. In one embodiment, a chain drive system (not shown) can be provided to pull the heaters 242 into and out of the drum 212. It is noted that the bracket could be alternatively configured with the channel and that the support arms 276a, 276b could be configured to be received within the bracket channels. It is further noted that each of the heaters can be configured with gas or electric connectors that allow for the heaters to be connected and disconnected to each other as they are installed and removed, respectively.
As shown, drying system also includes a conveying system 230 for delivering wet solids 10 to the drum 212. As shown, conveying system 230 includes an inlet hopper 232 and a conveyor 234. As configured, inlet hopper 232 receives the wet solids 10 and deposits the wet solids 10 onto the conveyor 234 which in turn transports the solids into the interior volume 212c of the drum 212. As shown, the inlet hopper 232 is provided with a mesh screen (not shown) and a vibrator assembly 238, wherein the hopper 232 is mounted on vibration isolators 238b and wherein a motor assembly 238a with eccentric weights is mounted to the hopper. The motor assembly 238b may include a variable frequency drive. When the motor assembly 238b operates, the hopper 232 is vibrated and sifts the solids through the mesh screen without imparting vibration onto the conveyor 234. As shown, the conveyor 234 is a belt type conveyor with an electric motor drive system 236. However, other types of conveyors may be used, for example an auger type conveyor.
The drying system 200 can also provided with a supply air system 250. As shown, the supply air system includes a supply fan 252 having a motor 254 that is in airflow communication with an air knife 258 via ducting 256. As configured, the air knife 258 discharges high velocity air along its length directly at the surface of the wet solids 10 on the same side of the drum 212 as the heaters 242b, 242c where the cleats 242 are churning the solids 10 upwards. In one embodiment, the air knife discharges air at about 1,000 to 2,000 feet per minute. In one embodiment, the air knife discharges air through spaced openings along its length while in another embodiment the air knife discharges air through a continuous opening along its length. In operation, the air knife 258 disturbs the moisture laden air immediately adjacent to the wet solids 10 with relatively drier air and therefore operates to reduce the vapor pressure of the adjacent air which increases the capacity of the infrared heaters 242b, 242c to remove moisture from the wet solids 10. Although one air knife 258 is shown extending a majority of the length of the drum 212, more air knives 258 may be used without departing from the concepts presented herein. The supply air system may also be provided with a heater (not shown) to increase the temperature of the air entering the drum 212. The heater may be installed in the ducting 256.
The drying system 200 is also provided with an exhaust system 260 that connects to the drum outlet 266. As shown, the exhaust system 260 includes a fan 262 having a motor 264 and being in air flow communication with the drum outlet 266 via ducting 268. In one embodiment, the exhaust fan removes about 4,000 cubic feet per minute of air from the drum 212, and the ducting 268 and drum outlet 266 have a diameter of about 20 inches.
Multiple drying systems 200 may be arranged in series in order to obtain a desired moisture content for the dried solids 20. For example,
In the embodiment shown, drying system 200 has infrared heaters 242 configured to provide about 924,000 btu/hr, wherein the first heater 242a has an output of about 30 kw, the second heaters 242b have an output of about 13 kW each, and the third heaters 242c have an output of about 39 kW each. Also, the drum 212 is configured to be rotated at about 9 revolutions every 20 minutes, or at about 0.45 rpm. The flights 222 within the drum 212 are configured such that about 11 cubic feet of solids can be continually processed through one pass of the drum 212 which takes about 20 minutes at the aforementioned rotational rate. In one embodiment, drying system 200 can be configured to dry solids having about 80% water by weight to a moisture content of about 10% by weight in a single pass through the drum 212 for a total processing volumetric rate of 33 cubic feet of wet solids per hour. In order to meet EPA standards for drying wet solids, the flight pitch, the flight pitch length reduction, and/or the drum rotation rate can be adjusted such that the reside time is sufficiently long in relation to the required temperature of the solids being dried. For example, the flight pitch, the flight pitch length reduction, and/or the drum rotation rate can be adjusted to result in a reside time of 30 minutes or longer.
With reference to
Wastewater treatment system 300 is also shown as including a centrifuge system 320. Centrifuge system 320 may be used instead of or in addition to system 310. Centrifuge system 320 is for providing a separation of water from the solids and can be configured to increase the solids content of the waste stream to about 20% by weight to provide wet organic solids. One centrifuge system 320 suitable for use in system 300 is the CS-10 Centrifuge manufactured by Centrisys Centrifuge of Kenosha, Wis. Other systems known in the art may also be used for system 320, provided they perform the same separation function of centrifuge system 320.
Wastewater treatment system 200 also includes an infrared drying system 330, to which the wet organic solids provided by the centrifuge system are delivered. Either of infrared drying systems 100, 100′, or 200 and variations thereof, may be used as system 330. As such all previous descriptions of systems 100, 100′, and 200 are incorporated by reference in their entirety into the description of system 330. In the embodiment shown, system 330 is configured in an end-to-end arrangement similar to that shown in
A method 400, shown at
In one step of the process, an infrared drying system is provided. In one embodiment, the infrared drying system has convective and radiant heat capability. In one embodiment, the infrared drying system has a housing; a conveyor extending through the housing; at least one infrared heater located within the housing and being directed towards the conveyor; and a fan for moving an airflow stream through the at least one infrared heater and onto the conveyor. In one embodiment, the drying system includes the above described features for drying system 100 and/or 100′. In one embodiment, the drying system includes a plurality of units arranged end-to-end.
In another step of the process, a metering rate of the wet organic solids can be determined. The metering rate is the rate at which the wet organic solids will be provided to the infrared drying system. In one embodiment, the metering rate is dependent upon the output rate of process equipment upstream of the infrared drying system. In one embodiment, the metering rate is dependent upon the desired output rate of the infrared drying system.
The process may also include a step of determining an exposure period for the wet organic solids. The exposure period is the amount of time the wet organic solids will be exposed to the infrared heater located within the housing. The exposure period is dependent upon the length of the infrared drying system housing; the number, physical size, and orientation of the infrared heaters within the housing; and the speed of the conveyor belt extending through the housing. In one embodiment, the exposure period is dependent upon regulations for time and temperature that a wet solid must be exposed to heat, for example EPA time-temperature regime requirements for human waste treatment. As such, determining the exposure period may comprise or consist of the step of determining the conveyor belt speed. In one example, the dryer 100, 100′, 200 is configured to ensure that wet solids are maintained at 50 degrees Celsius for a period of 30 minutes. One skilled in the art, based on the concepts herein, will appreciate that dryers 100, 100′, and 200 can be configured to meet a wide variety of EPA time-temperature regimes and pathogen reduction protocols.
In another step of the process, an exposure intensity output for the infrared drying system can be determined. The exposure intensity output of the infrared drying system is the level of heat output that will be provided by the infrared heaters within the infrared drying system. Depending upon the type of solids and the moisture content of the product, various output levels of the heaters can be determined to achieve the desired moisture removal from the solids to be dried. Additionally, the exposure intensity output can be dependent upon preventing a condition in which the wet organic solids may be burned or scorched, such as for dried distillers grains.
The disclosed process can also include the steps of determining a supply fan output rate and an exhaust fan output rate necessary to prevent the build-up of a vapor barrier and to remove moisture extracted from the wet organic solids. Alternatively, the supply and exhaust fans can be configured for constant volume operation.
Once the process variables for the operation of the drying system have been determined, the drying of the wet organic solids can be commenced. It is noted that the process can fix certain process variables such that they do not need to be determined and alter remaining process variables to achieve the desired result. In this way, it is not necessary to make a determination of every single operational variable prior to feeding the wet organic solids into the drying system. Furthermore, the process variables may be calculated and/or empirically established to achieve a desired level of moisture removal and/or treatment (e.g. pathogen removal) from the wet organic solids. In this way, such determinations are inherently accomplished by operating the system to achieve a desired result. Where an automation system is used, the process variables can be automatically determined by the controller based on inputs to the controller, such as desired temperature of the solids to be dried, desired internal temperature within the housing, and/or the desired moisture content of the solids to be dried which may be either manually determined or determined by sensors providing feedback to the controller. As such, the steps of determining the exposure intensity and exposure period may be automatically performed by the infrared drying system control system based on various user and/or sensor inputs (e.g. solids type, desired temperature for a specified duration, starting and ending moisture content, solids metering rate, etc.).
Once the drying system is activated, the wet organic solids can be fed into the infrared drying system at the metering rate. The conveyor of the infrared drying system can then transport the wet organic solids into the housing where they will be exposed to both convective and radiant heat through the use of the infrared heaters and supply/exhaust fan(s) for the specified exposure period and intensity output to create dried solids. By use of the term “dried solids,” it is meant to include solids having a moisture content less than the moisture content of the wet organic solids provided to the infrared drying system.
In one example of utilizing the above described process and an infrared drying system in accordance with the concepts of this disclosure, biosolids containing about 78.28 percent by weight water and having a containing fecal coliform density of about 400,000 MPN/g TS were treated. The infrared drying system tested was most similar to that described and shown as infrared drying system 230. The metering rate into the infrared drying system was selected at 700 pounds per hour with a conveyor belt speed of about 663 inches/hour. The exposure output intensity was set to 40,000 watts for the upper infrared heating system and to 40,000 watts for the lower infrared heating system. The resulting exposure period was set to about seven. The supply fan was set to approximately 2,000 cubic feet per minute. The resulting dry solids after treatment by the infrared drying system were measured to have a moisture content of 0.3 percent by weight water and a fecal coliform density at less than 200 MPN/g TS. The dried solids produced, which qualify as Class A biosolids (fecal coliform density below 1,000 MPN/g TS) can be used as biomass fuel or as fertilizer. One will appreciate that the time required and power utilized for processing wet organic solids in accordance with the concepts presented herein are significantly less than that of systems relying solely on convective heating.
Various modifications and alterations of this disclosure will become apparent to those skilled in the art without departing from the scope and spirit of this disclosure, and it should be understood that the scope of this disclosure is not to be unduly limited to the illustrative embodiments set forth herein.
The present application claims priority to U.S. Provisional Patent Application Ser. No. 61/561,026, filed Nov. 17, 2011, which is incorporated herein by reference in its entirety.
Number | Date | Country | |
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61561026 | Nov 2011 | US |