Images

Classifications

• • C—CHEMISTRY; METALLURGY
  • C12—BIOCHEMISTRY; BEER; SPIRITS; WINE; VINEGAR; MICROBIOLOGY; ENZYMOLOGY; MUTATION OR GENETIC ENGINEERING
  • C12F—RECOVERY OF BY-PRODUCTS OF FERMENTED SOLUTIONS; DENATURED ALCOHOL; PREPARATION THEREOF
  • C12F3/00—Recovery of by-products
  • C12F3/10—Recovery of by-products from distillery slops
• • C—CHEMISTRY; METALLURGY
  • C12—BIOCHEMISTRY; BEER; SPIRITS; WINE; VINEGAR; MICROBIOLOGY; ENZYMOLOGY; MUTATION OR GENETIC ENGINEERING
  • C12C—BEER; PREPARATION OF BEER BY FERMENTATION; PREPARATION OF MALT FOR MAKING BEER; PREPARATION OF HOPS FOR MAKING BEER
  • C12C1/00—Preparation of malt
  • C12C1/15—Grain or malt turning, charging or discharging apparatus
• • A—HUMAN NECESSITIES
  • A23—FOODS OR FOODSTUFFS; TREATMENT THEREOF, NOT COVERED BY OTHER CLASSES
  • A23C—DAIRY PRODUCTS, e.g. MILK, BUTTER OR CHEESE; MILK OR CHEESE SUBSTITUTES; MAKING OR TREATMENT THEREOF
  • A23C21/00—Whey; Whey preparations
• • A—HUMAN NECESSITIES
  • A23—FOODS OR FOODSTUFFS; TREATMENT THEREOF, NOT COVERED BY OTHER CLASSES
  • A23C—DAIRY PRODUCTS, e.g. MILK, BUTTER OR CHEESE; MILK OR CHEESE SUBSTITUTES; MAKING OR TREATMENT THEREOF
  • A23C1/00—Concentration, evaporation or drying
  • A23C1/04—Concentration, evaporation or drying by spraying into a gas stream
• • A—HUMAN NECESSITIES
  • A23—FOODS OR FOODSTUFFS; TREATMENT THEREOF, NOT COVERED BY OTHER CLASSES
  • A23C—DAIRY PRODUCTS, e.g. MILK, BUTTER OR CHEESE; MILK OR CHEESE SUBSTITUTES; MAKING OR TREATMENT THEREOF
  • A23C1/00—Concentration, evaporation or drying
  • A23C1/12—Concentration by evaporation
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
  • B01D—SEPARATION
  • B01D9/00—Crystallisation
  • B01D9/0004—Crystallisation cooling by heat exchange
  • B01D9/0013—Crystallisation cooling by heat exchange by indirect heat exchange
• • F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
  • F26—DRYING
  • F26B—DRYING SOLID MATERIALS OR OBJECTS BY REMOVING LIQUID THEREFROM
  • F26B11/00—Machines or apparatus for drying solid materials or objects with movement which is non-progressive
  • F26B11/02—Machines or apparatus for drying solid materials or objects with movement which is non-progressive in moving drums or other mainly-closed receptacles
  • F26B11/04—Machines or apparatus for drying solid materials or objects with movement which is non-progressive in moving drums or other mainly-closed receptacles rotating about a horizontal or slightly-inclined axis
• • F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
  • F26—DRYING
  • F26B—DRYING SOLID MATERIALS OR OBJECTS BY REMOVING LIQUID THEREFROM
  • F26B17/00—Machines or apparatus for drying materials in loose, plastic, or fluidised form, e.g. granules, staple fibres, with progressive movement
  • F26B17/10—Machines or apparatus for drying materials in loose, plastic, or fluidised form, e.g. granules, staple fibres, with progressive movement with movement performed by fluid currents, e.g. issuing from a nozzle, e.g. pneumatic, flash, vortex or entrainment dryers
• • F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
  • F26—DRYING
  • F26B—DRYING SOLID MATERIALS OR OBJECTS BY REMOVING LIQUID THEREFROM
  • F26B3/00—Drying solid materials or objects by processes involving the application of heat
  • F26B3/02—Drying solid materials or objects by processes involving the application of heat by convection, i.e. heat being conveyed from a heat source to the materials or objects to be dried by a gas or vapour, e.g. air
  • F26B3/04—Drying solid materials or objects by processes involving the application of heat by convection, i.e. heat being conveyed from a heat source to the materials or objects to be dried by a gas or vapour, e.g. air the gas or vapour circulating over or surrounding the materials or objects to be dried
• • Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
  • Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
  • Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
  • Y02E50/00—Technologies for the production of fuel of non-fossil origin
  • Y02E50/10—Biofuels, e.g. bio-diesel

Definitions

• Biorefineries can produce one or more biochemicals from micoorganisms such as yeast, bacteria, and the like.
• a biorefinery can produce fuel-grade ethanol using a fermentation-based process. Much of the ethanol used for transportation fuel in the United States is produced from the fermentation of corn.
• a vegetable such as corn is delivered to a biorefinery, and its particle size can be reduced by grinding the corn in a dry milling step.
• the resulting corn flour can then be combined with water, nutrients, enzymes, yeast, and/or other ingredients in a fermenter.
• Enzymes convert starch into fermentable sugars and microorganism such as yeast can convert fermentable sugars into ethanol.
• Fermentation results in a beer stream that includes, e.g., ethanol, water, suspended solids, dissolved solids, and corn oil.
• the beer stream is processed by a distillation unit where ethanol is removed.
• the stream from the distillation unit after ethanol has been recovered is referred to as whole stillage.
• This whole stillage stream includes, e.g., suspended solids, dissolved solids, water, and corn oil, which can be recovered as one or more co-products.
• the whole stillage stream is separated, typically by decanting centrifuges, into a thin stillage stream and a wet cake stream.
• the wet cake stream has a higher concentration of solids than whole stillage and is typically of a relatively high viscosity sludge-like consistency.
• the thin stillage has a lower concentration of suspended solids than whole stillage and is typically of a relatively low viscosity liquid stream.
• the solids concentration of the thin stillage stream can be increased in an evaporation step where water is evaporated from the thin stillage.
• Concentrated thin stillage is referred to as syrup in the art.
• the syrup stream contains an increased concentration of corn oil, which can be separated and sold as distiller's corn oil (DCO).
• DCO distiller's corn oil
• thin stillage includes protein (corn protein and protein material from spent yeast cells) which can be recovered and sold as grain distillers' dried yeast (GDDY).
• the present disclosure includes embodiments of a method of evaporating moisture from one or more process streams derived from a beer in a biorefinery, wherein the method includes:
• the present disclosure also includes embodiments of a biorefinery system configured to evaporate moisture from one or more process streams derived from a beer, wherein the system includes:
• At least one evaporation system in direct or indirect fluid communication with the recovered solids stream, wherein the evaporation system is configured to directly or indirectly receive and expose the at least one recovered solids stream to at least one evaporation process to remove moisture from the at least one recovered solids stream and form a concentrated, recovered solids stream having a higher suspended solids content on an as-is basis than the at least one recovered solids stream;
• At least one dryer system configured to receive and dry the concentrated, recovered solids stream to form a dried product.
• FIG. 1 is a process flow diagram illustrating an embodiment according to the present disclosure that forms a recovered solids stream and then exposes at least a portion of the recovered solids stream to an evaporator system;
• FIG. 2 is a process flow diagram illustrating an embodiment according to the present disclosure of a dry mill ethanol distillation process that includes exposing a recovered solids stream such as yeast paste to an evaporator system to form a concentrated yeast paste stream and drying the concentrated yeast paste stream in a dryer system to form grain distillers' dried yeast (GDDY);
• a recovered solids stream such as yeast paste
• GDDY grain distillers' dried yeast
• FIG. 3 A shows a non-limiting embodiment of a process flow schematic illustrating an evaporator system according to an aspect of the present disclosure
• FIG. 3 B shows another non-limiting embodiment of a process flow schematic similar to FIG. 3 A and further including an example of using evaporated water vapor for process water in a biorefinery;
• FIG. 4 shows another non-limiting embodiment of a more detailed process flow schematic illustrating an evaporator system according to an aspect of the present disclosure
• FIG. 5 shows another non-limiting embodiment of a more detailed process flow schematic illustrating an evaporator system according to an aspect of the present disclosure
• FIG. 6 shows another non-limiting embodiment of a more detailed process flow schematic illustrating an evaporator system according to an aspect of the present disclosure.
• FIG. 7 is a flow chart showing one or more additional processes or treatments that a recovered solids stream and/or a concentrated solids stream can be exposed to.
• the present disclosure relates to methods and systems for concentrating a solids stream (e.g., yeast paste) recovered from a process stream (e.g., thin stillage) in a biorefinery that converts monosaccharides derived from grain-based feedstocks into one or more biochemicals.
• a solids stream e.g., yeast paste
• process stream e.g., thin stillage
• Biorefineries can produce a wide variety of biochemicals from micoorganisms such as yeast, bacteria, and the like.
• a biorefinery can produce one or more alcohols such as ethanol, methanol, butanol, combinations of these, and the like.
• a biorefinery can make fuel-grade ethanol using a fermentation-based process.
• Ethanol can be produced from grain-based feedstocks (e.g., corn, sorghum/milo, barley, wheat, soybeans, etc.), or from sugar (e.g., sugar cane, sugar beets, etc.).
• ethanol is produced from starch contained within the corn, or other plant feedstock. The majority of U.S.
• ethanol production is from dry mill ethanol facilities that predominately produce ethanol and distillers dried grains with solubles (DDGS).
• Initial treatment of the feedstock varies by feedstock type. Generally, however, the starch and sugar contained in the plant material is extracted using a combination of mechanical and chemical means. In the case of a corn facility, corn kernels are cleaned and milled to prepare starch-containing material for processing.
• the starch-containing material is slurried with water and liquefied to facilitate saccharification, where the starch is converted into sugar (e.g., glucose), and fermentation, where the sugar is converted by an ethanologen (e.g., yeast) into ethanol.
• the fermentation product is beer, which includes a liquid component having one or more constituents such as ethanol, oil, water, and soluble solid components (dissolved solids such as proteins, vitamins, minerals, and the like), and suspended solids component having one or more constituents such as fiber and protein (corn protein and protein material from spent yeast cells).
• the fermentation product can be sent to a distillation system where the fermentation product is distilled, and the overhead distillate dehydrated into ethanol.
• the residual matter (e.g., whole stillage) includes liquid and solid components of the beer with substantially all ethanol removed, which can be dried into dried distillers' grains (DDG) and sold, for example, as an animal feed product.
• DDG dried distillers' grains
• Other co-products e.g., oil and protein
• whole stillage or portions thereof, can be viewed as a cost for an ethanol plant, it is possible to generate one or more high value co-products from the whole stillage.
• oil and protein feeds are all able to be recovered from whole stillage and sold as higher value co-products.
• whole stillage is often initially separated into two streams referred to as wet cake and thin stillage. Separation may be performed using centrifugation, and/or filter and press.
• the thin stillage may have water removed to concentrate the thin stillage and form syrup.
• At least a portion of the syrup can be added to the wet cake to increase the fat content of DDG to make DDGS (Distillers Dried Grains with Solubles). This process requires removing a large amount of water from the thin stillage. Thin stillage may also be recycled into the plant, such as for replacement of some portion of the water used during fermentation (fermentation backset).
• the present disclosure involves evaporating at least a portion of water from one or more recovered solids streams using an evaporator system in a biorefinery prior to drying the recovered solids stream into a dried product via a dryer system.
• a “recovered solids stream”, “solids stream recovered from”, and similar phrases involving “recovered” and “solids” refer to a stream that has been recovered from a process stream (or multiple process streams combined together) in a biorefinery, where the process stream is derived from a beer that includes one or more biochemicals such as ethanol, butanol, and the like that are made in the biorefinery. Referring to FIG.
• biorefinery 100 includes a beer stream 105 that is exposed to one or more unit operations 110 that form at least one process stream 115 .
• the process stream 115 can be separated in separation system 120 to form at least a recovered solids stream 125 , which can then be exposed to an evaporator system 130 .
• an example of a process stream is thin stillage in a dry grind corn ethanol plant and the recovered solids stream is yeast paste used to make dried yeast paste product. Removing water via evaporation from a yeast paste stream prior to drying can advantageously reduce the load on a dryer to produce the final dried product.
• the yeast paste stream and/or a concentrated, yeast paste stream can be relatively higher in viscosity and/or more challenging to transfer through downstream process equipment as compared to the stream it was derived from.
• the evaporative cooling effect that results from the phase change of liquid water to water vapor may reduce the heat exposure of the protein in a yeast paste stream that may otherwise occur, while at the same time drying the yeast paste as desired.
• a subsequent drying process to form a dried product e.g., GDDY
• a relatively high temperature as compared to a temperature protein may be exposed to during evaporation in an evaporator system.
• a subsequent drying process may be accomplished in a relatively shorter time period and/or at a relatively lower temperature, thereby improving the quality of at least some of the protein content.
• a variety of separation techniques can be used to recover a solids stream (e.g., yeast paste stream) from a process stream in a biorefinery according to the present disclosure so as to form a stream that is relatively less concentrated in liquid (e.g., moisture) and relatively more concentrated in solids before exposing the recovered solids stream to an evaporator system to further concentrate the recovered solids stream and form a concentrated, recovered solids stream.
• a solids stream can be recovered from a process stream using mechanical separation systems that separate process streams based on differences in sizes of stream components, differences in densities of stream components, combinations of these, and the like.
• a separation system can be selected and operated to provide a desired moisture content and solids content in the recovered solids stream as described herein.
• the separated system can be configured to form a concentrated, recovered solids stream having one or more properties that permit it to be transferred through an evaporator system and any downstream process equipment without undue fouling, clogging, and the like.
• properties include one or more of viscosity, suspended solids content, soluble solids content, and the like.
• Non-limiting examples of separation systems that can be used to separate a process stream into one or more recovered solids streams according to the present disclosure include systems having one or more centrifuges (e.g., two-phase vertical disk stack centrifuge, three-phase vertical disk stack centrifuges), one or more decanters (e.g., filtration decanters), one or more filters, combinations of these and the like.
• centrifuges e.g., two-phase vertical disk stack centrifuge, three-phase vertical disk stack centrifuges
• decanters e.g., filtration decanters
• filters e.g., filters, combinations of these and the like.
• Multiple separation systems can be used together and arranged in a parallel and/or series configuration.
• one or more process input streams can be separated into
• One or more process streams in a biorefinery can be selected for recovering a solids stream according to the present disclosure.
• recovering a solids stream for producing a dried protein product that includes corn protein and/or protein material from spent yeast can occur at one or more locations in a biorefinery that are downstream from fermentation.
• one or more solids streams can be recovered from one or more process streams in a biorefinery for producing a dried protein product that includes corn protein and/or protein material from spent yeast can occur before and/or after distillation.
• FIG. 2 shows recovering a yeast paste stream 235 from thin stillage 217 , which is downstream from distillation 208 .
• At least a portion of the beer 206 could be separated from the process flow in in FIG. 2 before distillation 208 to recover a yeast paste stream.
• a non-limiting example of a process stream that can used as an input stream for recovering a solids stream prior to distillation is fermentation product stream 32 in U.S. Pat. No. 8,449,728 (Redford), wherein the entirety of said patent is incorporated herein by reference.
• Another non-limiting example of a process stream that can used as an input stream for recovering a solids stream prior to distillation is fine solids and liquid stream 30 in U.S. Patent Publication 2015/0181911 (Redford), wherein the entirety of said patent publication is incorporated herein by reference.
• corn is first ground 201 into a flour with one or more hammermills.
• the corn flour can be mixed with various sources of water and enzymes in the slurry or liquefaction step 204 .
• the corn slurry is mixed at relatively low temperatures, approximately 90° F. to 100° F., and sent directly to the fermentation 205 without any additional processing.
• This process is commonly referred to as raw starch hydrolysis.
• the corn slurry is mixed at elevated temperatures, approximately 150° F.-200° F., and then maintained at that temperature for an extended period of time to allow the enzymes to reduce the viscosity (or liquefy) the corn slurry.
• Some processes may also employ a short time, high temperature cooking process up to approximately 250° F. to improve the liquefaction of the corn slurry.
• enzymes are added before and after the high temperature cooking process due to enzyme denaturation that may occur.
• the corn slurry, or liquefied corn slurry can then be fermented with an ethanologen such as Saccharomyces cerevisiae yeast in a simultaneous saccharification and fermentation (or SSF) mode.
• an ethanologen such as Saccharomyces cerevisiae yeast
• enzymes added to the slurry convert the corn starch into soluble glucose at the same time as the yeast converts the soluble glucose into ethanol and carbon dioxide.
• the resulting fermentation broth, or beer 206 is collected in a beer well 207 .
• saccharification and fermentation can occur sequentially in the same vessel or different vessels.
• one or more solids streams can be recovered from the beer 206 before distillation 208 so that at least a portion of water from the one or more recovered solids streams can be exposed to an evaporator system according to the present disclosure, e.g., prior to drying the recovered solids stream into a dried product (e.g., dried yeast paste).
• a dried product e.g., dried yeast paste
• beer 206 is distilled in order to separate the ethanol 209 from the water and remaining solids.
• the whole stillage 212 from the distillation 208 is processed in a separation system 215 into thin stillage 217 and wet cake 219 .
• separation system 215 can include one or more decanters (e.g., from 2-6 horizontal decanters in parallel).
• the wet cake 219 includes a large portion of corn fiber suspended solids from the whole stillage 212 .
• the wet cake 219 is sometimes sold as an animal feed as-is (distiller's wet grains). But, as shown in FIG.
• the wet cake 219 from separation system 215 can be provided to a dryer system 220 that includes a single (First Stage Dryer) dryer in dryer system 220 to form distiller's dried grains (DDG).
• a dryer system 220 that includes a single (First Stage Dryer) dryer in dryer system 220 to form distiller's dried grains (DDG).
• DDG distiller's dried grains
• the thin stillage 217 from the separation system 215 is primarily a liquid that includes dissolved solids and suspended solids.
• the liquid can include water and oil, but a large portion of the liquid is water.
• the dissolved solids can include one or more of saccharides and protein (e.g., soluble corn gluten protein).
• Thin stillage 217 can also include fine suspended solids.
• the fine suspended solids include protein such as grain protein (e.g., corn protein) and yeast protein from spent yeast cells.
• the thin stillage 217 from the separation system 215 can be transferred to a single tank (not shown).
• a recovered solids stream such as a “yeast paste” stream 235 can be recovered from thin stillage 217 using a separation system 230 as described above.
• a “yeast paste” stream 235 can include at least moisture and protein material from spent yeast cells.
• Yeast paste 235 can also include one or more of oil, dissolved minerals, sugar and/or starch, dissolved protein, and suspended protein and/or corn fiber.
• dissolved and suspended protein can also include grain protein such as corn protein.
• thin stillage 217 can be separated into a yeast paste stream 235 and one or more other process streams.
• a yeast paste stream can be separated from one or more process streams downstream from and derived from thin stillage. As shown in FIG. 2 , the thin stillage 217 can be separated into a clarified thin stillage stream 233 and a yeast paste stream 235 .
• the clarified thin stillage stream 233 can be transferred directly or indirectly to the slurry or liquefaction step 204 as backset 236 and the remaining clarified thin stillage 237 can be fed to an evaporator train 250 , made up of 4-8 evaporators in series (depending on plant size) to remove water and form syrup 255 .
• a semi-concentrated syrup 251 Prior to reaching the end of the evaporator train 250 , a semi-concentrated syrup 251 is sent to an oil recovery system 260 (e.g., POET's Voila® oil recovery system), which removes corn oil 261 .
• the residual stream 252 containing little to no corn oil is sent back to the evaporator train 250 to produce syrup 255 .
• oil recovery system 260 e.g., POET's Voila® oil recovery system
• residual stream 252 may include protein.
• residual stream 252 is another example of a process stream from which a recovered solids stream can be separated from according to the present disclosure, followed by being exposed to, directly or indirectly, an evaporator system.
• the syrup 255 can be combined with the First Stage Dryer Discharge in a single Second Stage Dryer of the dryer system 220 and dried down to approximately 10% moisture and sold as distiller's dried grains with solubles (DDGS) 221 .
• DDGS distiller's dried grains with solubles
• a recovered solids stream (e.g., yeast paste stream) according to present disclosure is used to ultimately form a dried solids product, therefore, it tends to be relatively more concentrated in suspended solids as compared to the process stream it was recovered from.
• a recovered solids stream has a suspended solids content of at least 8% on an as-is basis, at least 10% on an as-is basis, at least 15% on an as-is basis, at least 20% on an as-is basis, or even at least 25% on an as-is basis.
• a recovered solids stream has a suspended solids content from 8 to 35% on an as-is basis, from 10 to 30% on an as-is basis, from 15 to 25% on an as-is basis, or even from 15 to 20% on an as-is basis.
• the suspended solids can include one or more of protein (from yeast and/or grain such as corn), fat, ash, and carbohydrates (e.g., fiber and/or starch).
• a recovered solids stream has protein suspended solids content from 40-75%, from 40-65%, from 40 to 60%, or even from 45-60% by total weight of the suspended solids.
• a recovered solids stream according to present disclosure can have relatively less moisture (water) as compared to the process stream it was recovered from.
• a recovered solids stream has a moisture content of 90% or less on an as-is basis, 88% or less on an as-is basis, 80% or less on an as-is basis, 75% or less on an as-is basis, 70% or less on an as-is basis, or even 60% or less on an as-is basis.
• a recovered solids stream has a moisture content from 60 to 90% on an as-is basis, from 60 to 75% on an as-is basis, or even from 75 to 88% on an as-is basis.
• the balance of a recovered solids stream can include soluble solids, which in some embodiments include one or more of soluble protein, soluble mineral, soluble vitamins, and the like.
• a recovered solids stream can have a total solids content (dissolved and suspended solids) from 10 to 40%, from 12 to 30%, from 18-25%, from 25-35%, or even from 26-35% on an as-is basis.
• referring to the amount of a component on an “as-is basis” means that moisture is included to describe the degree of concentration of dissolved and/or suspended solids. Unless noted otherwise, the amounts are on a weight basis.
• At least a portion of water can be evaporated from a recovered solids stream via an evaporator system to form a concentrated, recovered solids stream having a lower moisture content and a higher concentration of suspended solids on an as-is basis as compared to the recovered solids stream from which water is evaporated from.
• the concentrated, solids stream is exposed, directly or indirectly, to a dryer system to form a dried solids product (e.g., dried yeast paste).
• a recovered solids stream can be considered at least partially concentrated in suspended solids as compared to the process stream that it was recovered from.
• the yeast paste stream 235 recovered from thin stillage 217 has less water than the thin stillage 217 and is more concentrated in protein (corn protein and/or protein material from spent yeast cells). As shown, the yeast paste stream 235 is exposed to an evaporator system 240 to remove water and form a condensed yeast paste stream 243 prior to being dried in a dryer system 245 to form grain distillers dried yeast (GDDY) 246 .
• GDDY grain distillers dried yeast
• a recovered solids stream can be exposed to temperature, pressure and humidity conditions to cause water to evaporate and be removed from the recovered solids stream and form a concentrated recovered solids stream.
• a variety of evaporator systems can be used to remove moisture from a recovered solids stream and form a concentrated recovered solids stream having a higher suspended solids content on an as-is basis as compared to the recovered solids stream. Because a recovered solids stream is relatively more concentrated in solids than the stream it was recovered from, it can be higher in viscosity and/or more challenging to transfer through downstream process equipment, which is a consideration when selecting an evaporator system (equipment, flowrates, etc.) for a recovered solids stream according to the present disclosure.
• an evaporator system includes one or more heat exchangers arranged in series and/or parallel configurations that can transfer heat from a heat source to the recovered solids stream to heat the water in the recovered solids stream and cause at least a portion of the water in the recovered solids stream to evaporate.
• heat sources include heat sources on the jacket side of a heat exchanger that indirectly heat the recovered solids stream and include steam or hot liquid mediums such as hot water, hot oil, or molten salt.
• An evaporator system can be operated at one or more operating temperatures and pressures, which can be selected depending on one or more factors such as type of evaporator system and evaporator system configuration.
• Non-limiting examples of evaporator systems can be described by the type of heat transfer, which include a once through falling film evaporator system, a recirculated falling film evaporator system, a natural circulation evaporator system, a forced circulation evaporator system, and the like.
• a falling film evaporator system includes a shell and tube heat exchanger in a vertical position, where the recovered solids stream is fed at the top of the heat exchanger to rely on gravity for the recovered solids stream to flow down the tube walls and through the heat exchanger to be heated and cause evaporation.
• a falling film evaporator system can facilitate processing relatively more viscous materials.
• distributers and/or spray nozzles can be used to help distribute the recovered solids stream among the tubes in the heat exchanger in a uniform manner. Also, the diameter of the tubes can be selected to accommodate higher solids streams to prevent undue fouling.
• Flow of vapor and liquid may be either co-current, in which case vapor-liquid separation takes place at the bottom, or countercurrent (the liquid is withdrawn from the bottom and the vapor from the top).
• co-current flow the liquid is withdrawn from the bottom and the vapor from the top.
• the vapor shear-force can thin the film, and produce relatively higher heat-transfer coefficients. Also, since the vapor is in contact with the hottest liquid at the point of withdrawal, stripping tends to be more efficient.
• a recovered solids stream (e.g., yeast paste stream) can be heated in a falling film evaporator system to at least the temperature that water boils at for a given pressure.
• a recovered solids stream can be heated to a temperature of at least 212° F. while exposed to atmospheric pressure (e.g., 14.7 psia) or less.
• a suppressed boiling evaporator system For illustration purposes, another non-limiting example of an evaporator system is described herein below with respect to what is referred to as a suppressed boiling evaporator system.
• Suppressed boiling occurs when the recovered solids stream has sufficient heat input into the liquid phase in a heat exchanger, as sensible heat under pressure, such that after exiting the exchanger it can be flashed.
• An example of a heat exchanger that can be used in a suppressed boiling evaporator is a plate and frame heat exchanger or a shell and tube heat exchanger. Relatively large heat transfer areas can be packed into a smaller volume and heat-transfer coefficients tend to be higher for plate and frame heat exchangers as compared to tubular evaporators. Also, fouling tends to be less since the action of fluid flow can cause a scouring action on the plate surface. Plate and frame heat exchangers can preserve product quality since exposure to high temperature tends to occur for a relatively short time period.
• a recovered solids stream (e.g., yeast paste stream) can be heated in a suppressed boiling evaporator system to at least the temperature at least 250° F. while exposed to a pressure above 30 psia. Water can flash from liquid to vapor when the pressure is reduced (e.g., to atmospheric pressure, 14.7 psia).
• a wiped film evaporator includes large-diameter jacketed tubes, in which the recovered solids stream can be wiped over the heat exchange surface (tube wall) by rollers or wipers. Blades can be pitched blades for high viscosity applications.
• the recovered solids stream can be continuously spread as a film on the tube wall by mechanical wipers. This can permit processing relatively viscous and heat-sensitive materials.
• a wiped film evaporator may be horizontal, vertical, or inclined.
• the heat-transfer tubes can be from 3 to 48 inches in diameter and from 2 to 75 ft. in length.
• a system for evaporating a recovered solids stream according to the present disclosure can include one or more evaporator systems as described herein.
• Two or more evaporator systems of the same or different type may be coupled to each other in a series and/or parallel configuration.
• a recovered solids stream can be exposed to up to eight evaporator systems in series (also referred to as an “evaporator train”).
• auxiliary equipment can be included in an evaporation system such as piping, pumps, and the like.
• Non-limiting illustrations of process flow schematics of evaporator systems such as 240 are illustrated with respect to FIGS. 3 A and 3 B .
• FIG. 3 A shows a non-limiting embodiment of exposing a yeast paste stream 335 to an evaporator system 340 to form a condensed (concentrated) yeast paste stream 343 , which can be dried in a dryer system 345 to form GDDY 346 .
• the yeast paste stream 335 is passed through a heat exchanger 341 so that it can be heated by indirect contact with a heat source such as steam or hot water 342 .
• the yeast paste stream 335 is heated to a temperature and at a pressure so that at least a portion of the liquid water in the yeast paste evaporates to water vapor 344 , thereby reducing the moisture content of the yeast paste to form a condensed yeast paste stream 343 .
• the yeast paste stream 335 can be heated in a first vessel (heat exchanger 341 ) to a temperature of at least 165° F. (or even at least 170° F., at least 175° F., or even at least 176° F.) while at atmospheric pressure (e.g., 14.7 psia) followed by flashing in a separate vessel 339 that is under vacuum (e.g., at a pressure of 7 psia or less).
• at least a portion of the water vapor 344 can be used as process steam at one or more locations within a biorefinery (e.g., as illustrated in FIG. 3 B , which is discussed below).
• FIG. 3 A schematically shows heating in heat exchanger 341 and evaporating separately in flash tank 339 , heating and evaporating could occur in the same vessel.
• FIG. 3 B shows another non-limiting embodiment of exposing a yeast paste stream 335 to an evaporator system 340 to form a condensed (concentrated) yeast paste stream 343 , which can be dried in a dryer system 345 to form GDDY 346 .
• the yeast paste stream 335 in FIG. 3 B is passed through an evaporator system 340 that includes a heat exchanger 341 so that the yeast paste stream 335 can be heated by indirect contact with a heat source 342 such a steam or hot water.
• the yeast paste stream 335 is heated to a temperature and at a pressure so that at least a portion of the liquid water in the yeast paste stream 335 evaporates to water vapor 344 , thereby reducing the moisture content of the yeast paste stream 335 to form a condensed yeast paste stream 343 .
• FIG. 3 B schematically shows heating and evaporating separately, where the yeast paste stream 335 is superheated and then exposed to a reduced pressure in flash tank 339 to cause liquid water to flash to water vapor 344 at the reduced pressure (e.g., atmosphere or vacuum).
• a reduced pressure e.g., atmosphere or vacuum
• At least a portion of the water vapor 344 can be used as process steam at one or more locations within a biorefinery by passing the water vapor through a heat exchanger 360 and condensing it using a cooling source 361 into a condensate 371 that can be used as process water at one or more locations in a biorefinery.
• a vacuum 370 may be applied to facilitate evaporating moisture from the yeast paste stream 335 at a relatively lower temperature.
• FIGS. 4 , 5 , and 6 show more detailed process flow schematics of non-limiting embodiments of exposing a yeast paste stream to an evaporator system according to the present disclosure.
• FIG. 4 shows an embodiment of an evaporator system 440 that includes a forced circulation heat exchanger and suppressed boiling configuration to concentrate a yeast paste stream according to the present disclosure.
• a yeast paste stream 435 from a separation system goes into a yeast paste tank 436 .
• the “pre-heated”yeast paste 437 is fed to a forced circulation, shell and tube evaporator, which includes a shell and tube heat exchanger 441 and an evaporation flash tank 439 .
• evaporator system 440 can concentrate yeast paste stream 435 by at least 0.1% solids content, at least 0.5% solids content, at least 1% solids content, at least 2% solids content, at least 5% solids content, or even at least 10% solids content.
• evaporator system 440 can save in gas costs with respect to a downstream dryer system and/or provide a lower carbon intensity (“CI”) due to less natural gas being used at a dryer.
• CI carbon intensity
• FIG. 5 shows another embodiment of an evaporator system 540 that includes a forced circulation heat exchanger configuration to concentrate a yeast paste stream according to the present disclosure.
• the evaporator system 540 has similarities to evaporator system 440 , but one difference is that heating and evaporating occur in the same vessel 541 and yeast paste stream is not “pre-heated” in a yeast paste tank.
• a yeast paste stream 535 from an upstream separation system is fed to heat exchanger 541 , which is a forced circulation, shell and tube heat exchanger.
• the yeast paste stream 535 is heated in heat exchanger 541 to remove water vapor 544 via evaporation and form concentrated yeast paste stream 546 , which can be transferred downstream to a dryer.
• evaporator system 540 can concentrate yeast paste stream 535 by at least 0.1% solids content, at least 0.5% solids content, at least 1% solids content, at least 2% solids content, at least 5% solids content, or even at least 10% solids content.
• evaporator system 540 can save in gas costs with respect to a downstream dryer system and/or provide a lower carbon intensity (“CI”) due to less natural gas being used at a dryer.
• the yeast paste stream 635 is obtained by separating thin stillage 617 in, e.g., a two-phase disk stack centrifuge 630 into a clarified thin stillage stream 633 and the yeast paste stream 635 .
• the thin stillage 617 could be separated using another separation device or system as described herein above.
• the yeast paste stream 635 from the centrifuge 630 is heated in a single yeast paste evaporation tank 639 with re-circulated, condensed yeast paste 638 , which was heated in a heat exchanger 641 by indirect contact with a heating medium such as steam 642 .
• a heating medium such as steam 642 .
• the incoming yeast paste stream 635 is heated to a temperature and at a pressure so that at least a portion of the liquid water in the yeast paste stream 635 evaporates to water vapor, thereby reducing the moisture content of the yeast paste stream 635 to form a condensed yeast paste stream 645 , which can be pumped by pump 651 .
• the flashed water vapor 644 can be used as process stream at one or more locations within a biorefinery.
• a concentrated, recovered solids stream formed by evaporation according to present disclosure is ultimately used to form a dried solids product. Therefore, it can be desirable for a concentrated, recovered solids stream to be relatively more concentrated in at least suspended solids (and have less moisture) as compared to the recovered solids stream it was concentrated from.
• a concentrated, recovered solids stream has a suspended solids content of at least 12% on an as-is basis, at least 13% on an as-is basis, at least 15% on an as-is basis, or even at least 20% on an as-is basis.
• a concentrated, recovered solids stream has a suspended solids content from 13 to 40% on an as-is basis, from 15 to 25% on an as-is basis, or even from 20 to 25% on an as-is basis.
• a concentrated, recovered solids stream according to present disclosure can have relatively less moisture (water) as compared to the recovered stream it was concentrated from.
• a concentrated, recovered solids stream has a moisture content of 85% or less on an as-is basis, 80% or less on an as-is basis, 75% or less on an as-is basis, or even 40% or less on an as-is basis.
• a concentrated, recovered solids stream has a moisture content from 20 to 80% on an as-is basis, from 20 to 70% on an as-is basis, from 20 to 60% on an as-is basis, from 50 to 80% on an as-is basis, or even from 60 to 80% on an as-is basis.
• a concentrated, recovered solids stream can have a total solids (dissolved and suspended solids) from 15 to 85% on an as-is basis, or even from 15 to 85% on an as-is basis.
• a recovered solids stream can be transferred directly or indirectly to an evaporator system.
• the yeast paste stream 235 is transferred directly to the evaporator system 240 to form the concentrated yeast paste stream 243 .
• the recovered solids stream could first be exposed to one or more processes such as one or more of those described in FIG. 7 below before being exposed to an evaporator system to form a concentrated, recovered solids stream.
• a concentrated, recovered solids stream can optionally be exposed to one or more additional processes or treatments after being exposed to an evaporator system, but before being dried in a dryer system.
• one or more of the evaporator systems described herein can also be used to produce a concentrated liquid product such as a syrup 255 from thin stillage.
• a concentrated liquid product such as a syrup 255 from thin stillage.
• evaporator systems can also be used to concentrate a recovered solids stream such as a yeast paste stream, which can be recovered from a thin stillage stream as shown in FIG. 2 , thereby reducing the load on a subsequent dryer system that produces a final dried product via a dryer system.
• a recovered solids stream can be exposed to one or more additional processes or treatments before or while being exposed to an evaporator system, but before being dried in a dryer system.
• a concentrated, recovered solids stream can optionally be exposed to one or more additional processes or treatments after being exposed to an evaporator system, but before being dried in a dryer system.
• the recovered solids stream and/or the concentrated, recovered solids stream may be processed physically, chemically, or enzymatically to provide one or more of moisture removal, viscosity reduction (e.g., to help fluid transport), and the like.
• Such optional treatments can facilitate processing relatively high solids content streams through process systems such as evaporator systems and/or dryer systems. Non-limiting examples of such processes/treatments are shown in FIG. 7 .
• a recovered solids stream and/or the concentrated, recovered solids stream can be exposed to one or more mechanical shearing processes. Because a recovered solids stream and/or the concentrated, recovered solids stream may relatively more concentrated in solids than the process stream it was formed from it can be suitable to mechanical shearing processes as is. If needed, water can be added or removed prior to mechanical shearing processes to make it more suitable to mechanical shearing. In some embodiments, mechanical shearing can reduce the viscosity of the recovered solids stream and/or concentrated, recovered solids stream, thereby making the recovered solids stream and/or the concentrated, recovered solids stream easier to pump, especially through an evaporator system and/or a dryer system, respectively.
• yeast paste exhibits shear-thinning behavior when exposed to mechanical shearing.
• mechanical shearing may also liberate water trapped in suspended solids (e.g., in individual yeast cells) and/or agglomerated suspended solids, thereby making the free water easier to drive off and less energy intensive in the evaporator system and/or a dryer system.
• mechanical shearing devices include shear mixers (e.g., shear rotor stator mixers), shear pumps, homogenizers, disk refiners, and the like.
• a single mechanical shearing device can be used, or two or more mechanical shearing devices can be used in parallel and/or series configurations. Further, a single type of mechanical shearing device can be used or in any combination with different types of mechanical shearing devices.
• a mechanical shearing device can be selected and operated to achieve one or more of desired results as just described herein.
• a recovered solids stream and/or the concentrated, recovered solids stream can be exposed to one or more mechanical particle size reduction processes. Because a recovered solids stream and/or a concentrated, recovered solids stream may relatively more concentrated than the process stream it was formed from it can be suitable to mechanical particle size reduction processes as is. If needed, water can be added or removed prior to mechanical particle size reduction processes to make it more suitable to mechanical particle size reduction. In some embodiments, mechanical particle size reduction device can reduce the viscosity of the recovered solids stream and/or the concentrated, recovered solids stream, thereby making the recovered solids stream and/or the concentrated, recovered solids stream easier to pump, especially through an evaporator system and/or a dryer system, respectively.
• mechanical particle size reduction may also liberate water trapped in suspended solids (e.g., in individual yeast cells) and/or agglomerated suspended solids, thereby making the free water easier to drive off and less energy intensive in the evaporator system and/or dryer system.
• mechanical particle size reduction devices include mechanical milling such as with one or more disc mills, roller mills, a colloid mills, rotary impact mills (beater mills), jet mills, tumbling mills (e.g., ball mills, tube mills, pebble mills, rod mills, and the like), impact mills, cone mills, centrifugal mills, screw presses, French presses, and combinations thereof.
• a single mechanical particle size reduction device can be used, or two or more mechanical particle size reduction devices can be used in series and/or parallel configurations. Further, a single type of mechanical particle size reduction device can be used or any combination of different types can be used. A mechanical particle size reduction device can be selected and operated to achieve one or more of desired results as just described herein.
• a recovered solids stream and/or a concentrated, recovered solids stream can be exposed to one or more enzyme treatments to digest cell walls of plant material (e.g., corn grain) and/or microorganisms such as ethanologens (bacteria or yeast).
• enzymes may break down solids which can reduce the viscosity of the recovered solids stream and/or the concentrated, recovered solids stream, thereby making the recovered solids stream and/or the concentrated, recovered solids stream easier to pump, especially through an evaporator system and/or a dryer system, respectively.
• enzyme treatment may break down solids and liberate water trapped in suspended solids (e.g., in individual yeast cells) and/or agglomerated suspended solids, thereby making the free water easier to drive off and less energy intensive in the evaporator system and/or the dryer system.
• Cell walls differ in their composition between types of cells, so an enzyme can be selected to have the correct specificity and activity for a given cell wall substrate.
• Other considerations in selecting an enzyme include the need for other reagents and/or additional procedures related to the use of that particular enzyme.
• Enzymes for yeast cellular lysis can include one or more enzymes such as protease, ⁇ -1,3 glucanase (lytic and nonlytic), ⁇ -1,6 glucanase, mannanase, and chitinase.
• Non-limiting examples of enzyme systems for yeast cellular lysis include zymolyase (also referred to as lyticase), which is an enzyme mixture used to degrade the cell wall of yeast and form spheroplasts. Activities of zymolyase include ⁇ -1,3-glucan laminaripentao-hydrolase activity and ⁇ -1,3-glucanase activity.
• Non-limiting examples of enzymes for bacteria cell wall lysis include lysozyme, lysostaphin, achromopeptidase, labiase, and mutanolysin.
• Non-limiting examples of enzymes for plant cell wall lysis include pectinases and cellulases.
• moisture may be mechanically removed from the recovered solids stream before exposing the recovered solids stream to an evaporator system, e.g., to reduce the energy input into the evaporator system and/or mechanically removed from the concentrated, recovered solids stream before exposing the concentrated, recovered solids stream to a dryer system, e.g., to reduce the energy input into the dryer system.
• Mechanical dewatering can include centrifugal separation, sedimentation, filtration, and/or sieving.
• Non-limiting examples of mechanical dewatering include decanters, disk stack centrifuges, screens (e.g., a “DSM” screen, which refers to a Dutch State Mines screen or sieve bend screen, and is a curved concave wedge bar type of stationary screen), filters, hydrocyclones, presses, combinations of these and the like.
• moisture to the recovered solids stream prior to and/or during mechanically removing moisture and before exposing the recovered solids stream to an evaporator system and/or before exposing the concentrated, recovered solids stream to a dryer system, e.g., by adding fresh water and/or one or more aqueous process streams from a biorefinery.
• Adding moisture to the recovered solids stream can reduce the concentration of dissolved solids with added moisture through mixing and entropy, and facilitates removal of a larger proportion of dissolved solids in the step of mechanically removing moisture (referred to as “dilution washing”).
• Adding moisture to the recovered solids stream can be performed in a manner that physically replaces a portion of moisture containing dissolved solids with a portion of added moisture containing less or no dissolved solids, and minimizes localized mixing (referred to as “displacement washing”). Adding moisture may enhance the efficiency of separation of suspended solids in some methods of mechanical moisture removal (e.g. centrifugation and/or filtration). Also, adding moisture to condition the recovered solids stream and/or concentrated, recovered solids stream may facilitate mechanical shearing and mechanical particle size reduction as discussed above. Finally, moisture may be added to the recovered solids stream to facilitate heat transfer in the evaporator system while maintaining the relatively high level of suspended solids on an as-is basis as discussed above.
• particle size separation include screens, filters, membranes, combinations of these and the like.
• certain sonic methods, rotary pulsation, and pulse wave technology may improve the flow of the recovered solids stream prior to and/or during evaporation, and/or improve the flow of the concentrated, recovered solids stream after evaporation in an evaporator system.
• Sonic methods create low pressure and induce cavitation of solid particles or agglomerates thereof.
• the cavitated or disrupted particle may improve the flow of the recovered solids stream through an evaporator system and/or the flow of the concentrated, recovered solids through, e.g., a dryer system.
• a sonic method can include sonicating the recovered solids stream and/or the concentrated, recovered solids stream at a frequency (e.g., measured in kHz), power (e.g., measured in watts), and for a time effective to reduce (or to assist in reducing) the particle size of the suspended particles, or agglomerates thereof.
• a sonic method can include sonicating the recovered solids stream and/or the concentrated, recovered solids stream at 20,000 Hz and up to about 3000 W for a sufficient time and at a suitable temperature.
• Such sonicating can be carried out with a commercially available apparatus, such as high powered ultrasonics available from ETREMA (Ames, Iowa).
• Rotary pulsation may include rotary pulsating the solid component of a process stream at a frequency (e.g., measured in Hz), power (e.g., measured in watts), and for a time effective to reduce (or to assist in reducing) the particle size of the solid component.
• a frequency e.g., measured in Hz
• power e.g., measured in watts
• Such rotary pulsating can be carried out with known apparatus, such as apparatus described in U.S. Pat. No. 6,648,500, the disclosure of which is incorporated herein by reference.
• a concentrated, recovered solids stream can be dried in a dryer system to form a dried product.
• a concentrated, recovered solids stream can be transferred directly or indirectly to a dryer system to be dried by removing enough moisture to form a dried product.
• a dried product tends to be a solid particulate in nature such as a powder, a granule, a flake, and the like.
• the concentrated, recovered solids stream can optionally be exposed to one or more processes such as one or more of those described in FIG. 7 above before being exposed to a dryer system as described herein. Referring to FIGS. 1 and 2 A- 2 B for illustration purposes, the condensed yeast paste stream can be transferred directly to the dryer system if desired.
• Non-limiting examples of dryer systems that can be used to dry a concentrated, recovered solids stream into a dried product include hot gas dryer systems such as a flash dryer system, a ring dryer system, a p-type ring dryer system, a rotary dryer system, a spray dryer system, a dispersion dryer system, a fluidized bed dryer system, combinations thereof and the like.
• hot gas dryer systems such as a flash dryer system, a ring dryer system, a p-type ring dryer system, a rotary dryer system, a spray dryer system, a dispersion dryer system, a fluidized bed dryer system, combinations thereof and the like.
• a hot gas such as hot air, combustion air, or a blend thereof.
• Two or more dryers may be used in a dryer system in series and/or parallel configurations and may be of the same type or different type.
• a ring dryer system is a type of a pneumatic conveyed flash dryer system that can receive a suspended solids stream such as a concentrated, recovered solids stream as described herein, which can be mixed with a portion of dry product that is recycled from the dryer discharge to form a friable, non-sticky feed material that can be fed into the dryer.
• a disperser injects the feed material into a hot drying gas stream at a venturi valve of the dryer. At this point, moisture in the feed material is flashed off due to the high velocity of the drying gas stream, which can generate high heat and mass transfer.
• the drying gas conveys the material to a manifold, or internal classifier.
• a manifold a single (p-type ring dryer system) or multiple classifiers (e.g., blades).
• the wetter, heavier particles are separated in the manifold and recycled back to the feed point to dry further, while the drier lighter particles (dry product) are transported downstream and separated from the drying gas in one or more cyclone separators.
• the presence of a manifold is essentially what distinguishes a ring dryer system from a flash dryer system.
• a portion of the dry product from the one or more cyclones is recycled to the dryer mixing system to condition the incoming suspended solids stream such as a concentrated, recovered solids stream.
• the rest of the dry product can pass to a product cooling system.
• Material such as a concentrated, recovered solids stream that is to be dried in a ring dryer system has relatively short residence time period.
• a rotary dryer system includes at least one drying drum that has an internal space where drying gas and wet feed material such as a concentrated, recovered solids stream are brought into contact.
• the wet feed material is showered through the drying gas by rotating the drum.
• lifters mounted on the inside of the dryer drum wall transport wet feed materials up to the top, where it falls off the lifter and through the drying gas.
• the residence time through a rotary dryer system can be relatively longer as compared to a ring dryer.
• material e.g., protein
• material can be exposed to a drying temperature for a longer time in the rotary dryer as compared to a ring dryer. If desired, at least a portion of dried product can be recycled to condition the wet feed material in a rotary dryer system.
• a dryer system can be operated at one or more operating temperatures and pressures, which can be selected depending on one or more factors such as heat sensitivity of one or more components (e.g., protein) of the dried product, type of dryer system and dryer system configuration.
• relatively high inlet gas temperatures can be used without damaging sensitive material such as protein because the surface moisture on the wet feed rapidly evaporates at the dryer inlet. This rapid evaporation lowers the gas temperature as it travels from the dryer inlet to the dryer outlet, thereby avoiding undue heat damage to the sensitive material.
• a dryer inlet gas temperature can be 400° F. or greater, 500° F. or greater, 600° F. or greater, 700° F. or greater, 750° F. or greater, 800° F.
• a dryer inlet gas temperature can be from 400° F. to 700° F., or even from 420° F. to 650° F.
• a dryer outlet gas temperature can be 250° F. or less, or even 220° F. or less.
• a dryer outlet gas temperature can be from 150° F. to 250° F., or even from 180° F. to 210° F.
• the drying gas in a dryer system can be at a variety of pressures while it contacts a material to be dried.
• the drying gas can be at pressure from atmospheric pressure (e.g., 14.7 psia) to less than atmospheric pressure (under vacuum conditions).
• a dryer system can include a drying gas at a pressure greater than atmospheric pressure.
• exposing a recovered solids stream to an evaporator system according to the present disclosure can permit adjustment of one or more of a downstream dryer parameters as compared to if the evaporator system was not used. For example, a dryer inlet temperature may be reduced. In some embodiments, using an evaporator system according to the present disclosure may allow the inlet temperature of a dryer to be reduced from 900° F. to 600° F.
• the flow rate of a concentrated, recovered solids stream through a dryer may be increased.
• using an evaporator system according to the present disclosure may allow the production capacity of a dryer system to be increased by permitting the flow rate to a dryer to increase by 50% or more.
• the average residence time a suspended solid particle spends in a dryer system may be reduced by 50% or greater, or even 33% or greater.
• a dryer system can be selected and operated to provide a desired moisture content in a dried product.
• a dried product has a suspended solids content of at least 65% on an as-is basis, or even at least 70% on an as-is basis.
• a dried product according to present disclosure can have relatively less moisture (water) as compared to the stream that was dried to form the dried product.
• a dried product has a moisture content of 10% or less on an as-is basis, 8% or less on an as-is basis, 6% or less on an as-is basis, or even 5% or less on an as-is basis.
• a dried product has a moisture content from 0.5 to 10% on an as-is basis, from 1 to 8% on an as-is basis, from 2 to 6% on an as-is basis, or even from 3 to 5% on an as-is basis.
• a dried product can have a total solids (dissolved and suspended solids) from 90 to 99.5% on an as-is basis, or even from 90 to 95% on an as-is basis.
• the dried product is GDDY, which can be sold as a high protein animal feed.
• a GDDY can have greater than 40%, or even greater than 45% protein on a dry wt. basis.
• a GDDY can have from 40 to 75%, from 40 to 52%, from 40 to 48%, from 46 to 52%, or even from 48 to 60% protein on a dry wt. basis.
• the GDDY may be particularly suited for mono-gastric (non-ruminant) and young animal feed.
• the high protein DDG may have high metabolizable energy and a lysine content of between about 2% and about 5%, which can be important in feed ration formulations.
• At least a portion of the yeast paste stream 235 and/or at least a portion of the concentrated yeast paste stream 243 may be combined with the wet cake 219 in order to alter the nutritional makeup of the WDG, DDG, and/or DDGS. Also, combining concentrated yeast paste according to the present disclosure with wet cake can help reduce the dryer load when forming DDG and/or DDGS.
• a method of evaporating moisture from one or more process streams derived from a beer in a biorefinery comprising:
• the dried product is grain distiller's dried yeast comprising a moisture content of less than 10% on an as-is basis, and a protein content of at least 40% on a dry weight basis, wherein the protein content comprises corn protein and yeast protein.
• evaporator system is chosen from a falling film evaporator system, a suppressed boiling evaporator system, a wiped film evaporator system and combinations thereof.
• the dryer system is chosen from a flash dryer system, a ring dryer system, a p-type ring dryer system, a rotary dryer system, a spray dryer system, a dispersion dryer system, and combinations thereof.
• any preceding embodiment further comprising exposing the at least a portion of the at least one recovered solids stream to one or more additional processes prior to and/or during exposing the at least a portion of the at least one recovered solids stream to an evaporator system, wherein the additional processes are chosen from one or more mechanical shearing processes; one or more mechanical particle size reduction processes; one or more enzyme treatments; one or more chemical treatments; one or more particle size separation processes; and combinations thereof.
• any preceding embodiment further comprising exposing the at least a portion of the concentrated, recovered solids stream to one or more additional processes prior to and/or during drying the at least a portion of the concentrated, recovered solids stream, wherein the additional processes are chosen from one or more mechanical shearing processes; one or more mechanical particle size reduction processes; one or more enzyme treatments; one or more chemical treatments; one or more particle size separation processes; and combinations thereof.
• the one or more process streams derived from a beer comprise at least a portion of the first aqueous fraction stream and/or at least a portion of the second aqueous fraction stream.

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