1. Field of the Invention
The present invention generally relates to dryers, and more particularly to a method and system for drying solid material
2. Discussion of the Background
Existing dryers and roasters either transfer heat directly (when the heat transfer medium is in contact with and mixes with the process materials and products), or indirectly (when the heat exchange medium remains separated from the process materials and process products).
The direct heating approach benefits from low thermal resistance and high surface area contact, often with high driving temperatures. If the heat transfer medium is hot air, the risk of fire or partial combustion exists, placing limits on the driving temperature. These limits may be overcome by either using an inert gas or oxygen depleted combustion gas as the heat transfer medium; however this leads to a more complicated system.
In any case, the gases produced, which includes steam and combustible gases, are mixed with the heat exchange medium. A combustion system to use the chemical energy in the gases (to create process heat) becomes problematic because of the low Btu value of the mixed gas.
The indirect heating approach benefits from the high Btu value of the produced gases, having not been diluted into the heat transfer medium. This allows the gases to be combusted at high temperatures, ultimately providing a superior heating source. The process materials are more easily kept in an oxygen depleted or oxygen free environment.
Thus there is a need in the art for a method and apparatus that permits the more efficient use of material and energy in the drying of solid materials. Such a method and apparatus should be compact, easy to control, and be relatively maintenance-free.
The present invention overcomes the disadvantages of prior art by using a furnace that utilizes a phase-change heat transfer fluid to heat a material.
It is one aspect of the present invention to provide a furnace having an input adapted to accept a material to be processed, an output adapted to provide processed material. The furnace includes a first volume and a second volume. The first volume contains a fluid, where the fluid is a phase-change heat-transfer fluid, and where the fluid includes a vapor of the fluid and a liquid of the fluid. The second volume contains the material to be processed. The first volume and the second volume have a separating wall that is a fluid barrier between the first volume and the second volume and which provides for heat transfer between condensing vapor of the fluid and material contained within the second volume. The second volume includes at least two trays, where said at least two trays are substantially horizontal and disposed at different vertical heights, and at least one passageway between two of said at least two trays.
It is another aspect of the present invention to provide a method of torrefying a material using a fluid, where the fluid is a phase-change heat-transfer fluid and includes a liquid phase of the fluid and a vapor phase of the fluid. The method includes providing the material sequentially to at least two trays, where said at least two trays are substantially horizontal and disposed at different vertical heights; condensing the vapor phase at a temperature; and providing heat from said condensing the vapor phase to the material. The temperature is sufficient to torrefy the material.
These features together with the various ancillary provisions and features which will become apparent to those skilled in the art from the following detailed description, are attained by the furnace of the present invention, preferred embodiments thereof being shown with reference to the accompanying drawings, by way of example only, wherein:
Reference symbols are used in the Figures to indicate certain components, aspects or features shown therein, with reference symbols common to more than one Figure indicating like components, aspects or features shown therein.
Furnace 100 is particularly well suited to the heating of material M at a controlled temperature and environment. The material is shown as an input and output to heater 110 as an input Mi and an output Mo, respectively. Examples of material M include, but are not limited to, forest product residuals, agricultural residuals, and foodstuffs (ie. raw, coffee beans, cocoa, grains, etc.). The processed (heated) material may be used in a variety of uses including, but not limited to biofuels, filler for plastics, or food products. In certain embodiments, material M is processed to drive off volatile compounds that have a heating value that may be used to drive the processing of the material.
Thus, for example and without limitation: dryer 20 of the present application could be dryer reactor 320 of the '157 application, biomass dryer 310 of the '356 or '497 applications; cooler 30 or 40 of the present application could be cooling reactor 340 of the '157 application, biomass cooler 330 of the '356 or '497 applications; press 150 of the present application could be pelletizer 350 of the '157 application, biomass cooler 330 biomass compression portion 340 of the '356 or '497 applications. Furnace 100 may also include additional processing equipment, such as a load-lock to maintain material within volume 112 at a pressure that is higher or lower than atmospheric pressure and as discussed in the '157, '356, and '497 applications, a biomass preparation portion 301 and/or a biomass metering portion 303 of the '356 or '497 applications.
Material M is indicated at different states or conditions as M1, M2, M3, and M4. When dryer 20 is present, M1 is the input material and Mi is the dried input material. Mo is the heated (torrefied) material, when cooler 30 or 40 are present, M2 or M4 are cooled torrefied material, respectively, and if press 150 is present M3 is densified material. When load locks 62 and/or 64 are present, the pressure P in volume 112 may be greater than or less than atmospheric pressure
Heater 110 has an outer shell 118 that includes two internal volumes: a volume 112 for conducting a material M, and a volume 114 for containing a heat exchange fluid F. A common wall 116 between volumes 112 and 114 separates the volumes. In general, a material M may be provided to a material input 111, which passes through volume 112 to a material output 113, from which heated material M exits furnace 100. Heat transfer fluid F contained within volume 114 conducts heat through wall 116 to heat, react, or torrefy a material M passing through volume 112.
Heater 110 also includes a port 115 for the transfer, both into and from volume 114, of heat exchange fluid F, and a port 117 in fluid communication with volume 112 (and not volume 114) for the exiting of combustible gases from the heated material. Optional port 119 is also in fluid communication with volume 112 (and not volume 114) to transport gases that are primarily humid air from heated material M.
As shown in
Heat exchange fluid F is preferably a phase-change fluid that may be in either a vapor phase V or a liquid phase L. In one embodiment, heat exchange fluid F is DOWTHERM™ A (Dow Chemical Company, Midland, Mich.), an organic heat transfer fluid that is a eutectic mixture of biphenyl (C12H10) and diphenyl oxide (C12H10O). The saturated DOWTHERM™ A vapor has a temperature that ranges from 205° C. at 0.28 atmosphere, 260° C. at one atmosphere, and 305° C. at 2.6 atmospheres of pressure. In a second embodiment, heat exchange fluid F is a parafin fluid, ie. XCELTHERM® XT (Radco Industries, Batavia, Ill.). XCELTHERM® XT can be used for higher temperatures, as it has a higher temperature than DOWTHERM™ A at the same vapor pressure.
In one embodiment, the pressure PV within volumes 114 and 122 is maintained so that the temperature TV can achieve the proper temperature for material M within volume 112. Heater 100 may include diagnostics 155 that may be used to monitor the pressure and temperature of fluid F within volume 114. As shown schematically in
Heat source 140 has inputs that supply various gases that are reacted with the heat source and outputs that provide hot, reacted gases. In one embodiment heat source 140 provides gases to a thermal oxidizer 143 via an air intake port 149 and a combustible gas intake port 148. The oxidized gases exit the thermal oxidizer at an output 147. In another embodiment heat source 140 provides gases to a burner 141 via an auxiliary air input port 142a that accepts air from blower 103 and an auxiliary fuel input 142b that accepts fuel from an auxiliary fuel source 102. The combusted gases exit burner 131 at an output 145. Gases from outputs 145 and 147 are combined and exit heat source 140 at output port 146. The combined outputs 145 and 147 also exit heat source 140 at a second output port 144. The flow through second output port 144 is controlled by valve 109 and exits furnace 100 via stack 107. The gas provided by output port 146 and 144 may thus include reaction products of the thermally oxidized combustible gases and the combusted auxiliary fuel.
The heat source 140 may, for example and without limitation, be the combined thermal oxidizer/burner fabricated by Clark Griffith Consulting, of Lansdale, Pa. This device includes both burner 141 and thermal oxidizer 143 in one package, allowing for start-up or extra operating temperature with an alternative fuel source 102 (i.e. propane),
Vaporizer 120 accepts hot gas at a temperature T1 from output port 146 into an input port 121 and through tubing 125 before exiting the vaporizer at exit port 123 at a lower temperature, T2. Vaporizer 120 also includes a volume 122 separate from tubing 125, which contains a heat exchange fluid F. Volume 122 is in fluid communication with volume 114 of the heater, through ports 115 and 127, to allow liquid L and vapor V to flow between heater 110 and vaporizer 120.
A lower portion of volume 122 includes liquid phase L, and an upper portion of volume 122 includes a combination of liquid phase L and vapor phase V. The gases within tubing 125 provide heat Q to heat liquid L, causing a portion of the liquid to vaporize into vapor V. Heat provided by conduction from the hot gas provided at input port 121 heats the liquid L, which vaporizes at a temperature Tv determined by the pressure of within volume 122 and 114 according to the thermal properties of fluid F. Vapor V in volume 114 condenses on wall 116, providing heat by conduction at approximately the vaporization temperature Tv of fluid F.
Preheater 130 has an input port 131 for accepting gas from exit port 123 of vaporizer 120, an input port 133 for accepting air from a blower 101, an exit port 137 that provides gas to a stack 105 that exits furnace 100, and an exit port 135. Preheater 130 is a heat exchanger that recovers heat not used by vaporizer 120 to preheat air that is provided to thermal oxidizer 143.
Preheater 130 may be, for example and without limitation, a flat plate heat exchanger, which is well known in the field, and are manufactured, for example, by Southwest Thermal Technology, Inc, Camarillo, Calif.
In alternative embodiments, energy may be removed from furnace 100 for other processing or energy production uses. Thus, for example, stack 107 may be replaced with a device for recovering thermal energy and/or optional cooling loop 50 through vapor V may remove heat from fluid F at a temperature TV. Such heat may be used as process heat, as through a heat exchanger, or may be used for generating electricity or mechanical work, as in the power generator 230 of the '356 application, which may include a Rankine cycle (OCR) engine model UTC 2800, manufactured by UTC Power (United Technologies Corporation, South Windsor, Conn.), or a turbine.
The heat exchange fluid is contained within a closed, constant volume within heater 110 and vaporizer 120 and does not mix with either the material that passes though heater 110 or gases from heat source 140. Furnace 100 thus provides for the indirect heating of material, where the temperature is controlled though the uses of a phase-change heat exchange fluid.
Furnace 100 may, in certain embodiments, provide material M to a press 150 to compact the heated material. Press 150 may, for example and without limitation, be an extrusion press. As an example, the heated material from output 113 may be first ground, if necessary, to pieces on the order of, for example and without limitation, 5 mm, and subsequently be fed into a screw press, where the material is extruded to the desired format, which may be, for example and without limitation, between 25 mm and 100 mm in diameter. The heated material may then be cooling and stored. By properly coordinating the speed of the extrusion screw with the process material flow, the extrusion screw remains full and the process output is sealed from the environment.
In certain other embodiments, diagnostics 160 may be utilized to monitor the material before, during or after pressing. Diagnostics 160 may, for example and without limitation, utilize spectroscopy to monitor the densified material M3. Examples of such a diagnostic technique are described, for example and without limitation, in the “'497 application, which describes a method of measuring the fuel value and other physical properties of the process products(s) using IR spectroscopy. Thus, for example, an Attenuated Total Reflectance (ATR) crystal may be positioned in the extrusion barrel. The process material is forced against the crystal, and an IR spectrometer continuously records the spectrum. This information may be used to control the process and to provide continuous process history.
Furnace 100 may also include a computer or other electronic control system 10. System 10 includes inputs from diagnostics 155 and 160 to acquire data concerning heat transfer fluid F (that is, the pressure Pv and temperature Tv of fluid F within volume 114), and processed material M, such as the density, temperature of processed material M, including data from diagnostics 160 Other process information can be made available to the system 10, including but not limited to, data from an emission analyzer system, (ie. ENERAC of Holbrook, N.Y.) which may include excess Oxygen, CO2 and total combustible gases as measured in stack 107 and/or 105. Thermocouples and pressure sensors, well known in the art, can be located at various process positions and made accessible to system 10. System 10 may then provide control signals to blowers 101 and 103, value 109, auxiliary fuel source 102, and paddle drive 211.
Details of heater 110 and vaporizer 120 are now described in greater detail, where
Heater 120 is shown in greater detail in
Trays 510 and 520 are shown in greater detail in
The interior of trays 510 and 520 are shown in
Paddles 603, 803 move in the same direction, but are oriented relative to shaft 301 to move material toward the differently located holes. The orientation of paddle 603 is shown in
The space between trays 510, 520, through which fluid F flows in volume 114, is shown in
In one embodiment, furnace 100 is sized to process 1000 kg/hr of wood chips. Trays 510 and 520 have a height H of 100 mm, and a radius RT of 1.8 m, and are spaced apart by a distance S of 50 mm. The heater has a radius of RH of 1.9 m, providing a gap RH-RT of 0.1 m for fluid F. Paddle drive 211 is operated to urge the material from one tray to another. In one embodiment, the angle θ is 30 degrees, oriented to move the material towards the open holes at the bottom of trays 510 and 520, and is rotated at 60 rpm.
The operation of furnace 100 is illustrated with reference
Eventually, the temperature of gas entering port 121 is hot enough to vaporize heat exchanger fluid F, and vapor rises from volume 122 of vaporizer 120 into volume 114 of heater 110. When the temperature Tv, as measured by diagnostics 155, reaches a set point, furnace 100 is ready to process material M. Blower 101 and paddle drive 211 are turned on by system 10 and material M is provided to input 110. As material M flows through volume 112, it is heated and gives off gases that may be recovered. Material M preferably will generate volatile gases which are recovered at port 117 and provided for mixing with preheated air from blower 101 in thermal oxidizer 143, and the products of oxidization are mixed with those of burner 141 and provided back to vaporizer 120.
In certain embodiments, furnace 100 is controlled by system 10. Thus, for example, if a sufficient amount of combustible gases are provided to thermal oxidizer 143, then system 10 may reduce the flow of auxiliary fuel 102, or shut off the auxiliary fuel and blower 103. If too much heat is generated in heat source 140, then valve 109 may be partially or fully opened to release heat from furnace 100. Process parameters determined by diagnostic 160 may be used to increase or decrease heat and/or material flow to maintain desired conditions.
In certain operating conditions, for instance torrefying a material M that is dry wood, at between 250° C. and 300° C. with a residence time of between 5 and 30 minutes, the product gas has more chemical energy than required by the heating process. If heat is not removed from the system, then the process throughput will be limited, as will the allowable process set points. For oily feedstocks, with rapid processing rates, chemical energy is in significant excess, and recovering this energy is attractive.
A critical aspect of the indirect heated roaster of heater 110 is the handling of the process off gases, which may contain condensable hydrocarbons (CxHyOz), steam, non-condensable gases, and particulates. A second critical aspect are the methods to provide an oxygen free process, while preventing all off gas leakage to atmosphere. In the present invention, volume 112 of heater 110 can be operated at either ambient pressure, or slightly above ambient pressure (i.e. 4 inches H2O), or slightly below ambient pressure. In a preferred embodiment, volume 112 is operated at slightly above the pressure of thermal oxidizer, promoting flow from the volume into heat source 140.
Examples of the conditions required for torrefaction of materials is described in the related '497, '356, and '157 applications. More specifically, the following is a table of operating conditions for different feedstock materials M.
Reference throughout this specification to “one embodiment” or “an embodiment” means that a particular feature, structure or characteristic described in connection with the embodiment is included in at least one embodiment of the present invention. Thus, appearances of the phrases “in one embodiment” or “in an embodiment” in various places throughout this specification are not necessarily all referring to the same embodiment. Furthermore, the particular features, structures or characteristics may be combined in any suitable manner, as would be apparent to one of ordinary skill in the art from this disclosure, in one or more embodiments.
Thus, while there has been described what is believed to be the preferred embodiments of the invention, those skilled in the art will recognize that other and further modifications may be made thereto without departing from the spirit of the invention, and it is intended to claim all such changes and modifications as fall within the scope of the invention. Similarly, it should be appreciated that in the above description of exemplary embodiments of the invention, various features of the invention are sometimes grouped together in a single embodiment, figure, or description thereof for the purpose of streamlining the disclosure and aiding in the understanding of one or more of the various inventive aspects. This method of disclosure, however, is not to be interpreted as reflecting an intention that the claimed invention requires more features than are expressly recited in each claim. Rather, as the following claims reflect, inventive aspects lie in less than all features of a single foregoing disclosed embodiment. Thus, the following claims are hereby expressly incorporated into this description, with each claim standing on its own as a separate embodiment of this invention.
This application claims the benefit of U.S. Provisional Application No. 61/654,014, filed May 31, 2012, hereby incorporated by reference in its entirety.
Number | Date | Country | |
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61654014 | May 2012 | US |