734 Fermentation and Biochemical Engineering Handbook SECTION 11: DIRECT DRYING (by Barry Fox) 1.0 INTRODUCTION The purpose ofthis chapter is to review various forms of solids dryers and auxiliary components. It is intended to be a practical guide to dryer selection (as opposed to the theory of drying, which is addressed in various technical manuals referenced in the bibliography). From a microscopic viewpoint, the process is simple: water or solvent basically evaporates leaving the solid behind. When viewed macroscopically, it is apparent that the drying process is extremely complicated with many interdependent forces that combine in various dryers to achieve the end result. The information in this article can also help the reader become more familiar with the drying process from beginning to end. Drying is the process of removing a liquid from a solid. The liquid to be dried can be water or a hydrocarbon based solvent. The solids are usually classified as organic or inorganic, either of which can be completely or partially soluble in the liquid medium. The inorganic materials are generally called salts because they are usually soluble in water. Organic materials are more difficult to dry due to temperature sensitivity. When drying, organic materials can stick to walls and cling to themselves resulting in a tacky consistency. Direct drying is the process of removing this liquid via the mechanism of convective heat transfer. The heat input usually takes the form of preheating a carrier medium (such as air, evaporated solvent or an inert gas) that transfers the sensible heat and acts as an absorbent to take away the liquid in the vapor form. The carrier medium can hold a fixed amount of liquid (saturation) at its defined temperature. The solids release the liquid to the carrier medium as a function of saturation and equilibrium. In essence, the heated gas has a higher saturation affinity for the liquid in the vapor form than does the solid at the gas temperature. Typical examples of conventional direct dryers are spray, fluid bed, flash, rotary, belt and continuous tray type. In the former three types, the wet solids are suspended in the carrier medium. In the latter three types, the carrier medium passes slowly across the bed of solids. Additionally, there exists some minor tumbling of the solids through the gas stream (carrier medium). There is a nonconventional form of direct drying that is often over- looked or possibly unknown to the designers of the process. It is applicable to almost any of the forms of dryers mentioned in this chapter. The method is to use the solvent or liquid that is being dried as the carrier medium for the Drying 735 heat transfer, In essence, the moisture that is evaporated from the product is recycled and reheated. It replaces air or inert gas and this hot vapor is used to strip off additional liquid from the wet product. The excess vapors are removed via a vent condenser outside of the closed vapor loop. This procedure can be applied in any of the drying processes mentioned here. One advantage to this method ofdrying is that the product sees onlythe vapor with which it is already in contact in the liquid state. A possible reason for using this method is product oxidation when air drying. This method may reduce oxidation ifthe solvent is used. This method is also more energy efficient when solvents are present since the inert gas that is recycled in the former method needs to be reheated after it has been cooled down to condense the solvents. 2.0 DEFINITIONS Absolute Humid@-the ratio of mass of vapor (moisture) to mass present in the carriergas stream. Example: 0.02 pounds ofwater per pound of air. This number can be used to find the relative humidity on the psychrometric charts. It is also usehl for cumulative quantities in a stream due to such items as products of combustion (when a gas fired heater is used), and evaporation and ambient quantities. This is necessary for calculating condenser or venting amounts. BoundMoisture-liquid which is bound to a solid by chemical bonds or physical adsorption in the molecular interstices of the solids. Capillaryflow-the flow of liquid through the pores of a solid. Critical moisture content-the average moisture in the solids when the constant rate drying period ends. Dijfision-the process of mass transfer ofthe liquid from the interstices of the solid to the surface of the solid. Dry basis-means of measuring moisture content in terms of moisture content per quantity of dry product, for example, pounds of water per pound of dry product. (Also see Wet Basis.) Equilibrium moisture content-the limiting moisture content to which a product can be dried under fixed conditions such as temperature, humidity and pressure. Evaporative cooling-when drying a solid with free or bound moisture, the effect of a phase change from the liquid state to the vapor state removes energy from the liquid-solid mass. This results in a reduction of temperature in a nonadiabatic operation, whereas in an 736 Fermentation and Biochemical Engineering Handbook adiabatic operation ofconstant heat input, the temperature may drop or more likely it will maintain a level (pseudo-wet bulb) temperature. Falling rateperiod-this is the period of drying where the instantaneous drying rate is constantly decreasing. Feed material-this is the description ofthe material being dried before it enters the dryer. Final moisture content-the desired product moisture level required after completion of the drying process. Freeflowing-refers to the feed and product characteristics, as in a free flowing powder. This is the state in which the material being dried would not cling to itself, forming large chunks or possibly bridging in a hopper. Free moisture-liquid which is promptly removable due to its availabil- ity at the interface between the surface of the particles (solids) and the gas stream. Hygroscopic material-solids having an affinity for liquids due to a chemical or physical attraction between the solids and the liquid. Initial moisture content-the average moisture contained in the wet material before the start of the drying process. If given in percent, specification of wet or dry basis is necessary. Plugflow-a term used to describe the breakup of a continuous process into small batch segments. The term may originate from a reactor tube being filled or plugged with small quantities of material using a piston pump. The reactor would process the volume of material in each piston cavity like a small batch, yet when the material is viewed as a large quantity, it appears homogeneous. The term is used in conjunction with semi-continuous operations. Product-this is the description of the solid material after it has been dried. Relative humidi-the percentage of water vapor in a gas stream relative to it’s saturation level. Example: 100% relative humidity is the complete saturation of a camer gas stream, whereby any further vapor cannot be absorbed by the gas and will condense or precipitate out in the liquid phase. There is an equilibrium between the liquid- solid mass and the gas stream (carrier medium). This equilibrium is a result of a combination of saturation capability of the medium at agiven temperature. At higher temperatures, the camer medium has Drying 737 a higher saturation limit and, therefore, a lower relative humidity, given the same absolute humidity. Wet basis-means of measuring moisture content in terms of quantity of moisture per quantity of wet material. For example, if we have 1000 Ibs. of wet cake with 200 Ibs. of water, our moisture content is 20% on a wet basis and 25% on a dry basis. (See Dry basis.) Wet bulb temperature-the dynamic equilibrium temperature attained by a water surface when the rate ofheat transfer by convection equals the rate of mass transfer away from the surface. 3.0 PSYCHROMETRIC CHARTS There are many forms of psychrometric charts available from various technical sources as well as many manufacturers of process equipment who have tailored the chart for use with their equipment. These charts are usehl for determining moisture content in the air at a given temperature and relative humidity or wet bulb temperature. The type of information obtainable from these charts depends upon which chart one uses, because each is designed differently. Usually, accompanying the chart is a set of instructions for use. Please see the references for examples of these charts and the various forms in which they exist. 4.0 DRYING THEORY The process of drying solids is usually quantified into three phases: 1. Initial adjustment period-this is the stage at which the wet feed material heats up or cools down to the starting drying temperature which is basically referred to as the wet cake temperature. For example, the wet feed is introduced to the heated dryer at ambient temperature. During this period the material temperature will start to rise to the wet bulb temperature which may be different fromthe initial feed temperature. The reason the tempera- ture of the wet cake remains low relative to the gas temperature is a phenomenon known as evaporative cooling. 2. Constant rate period-this is the stage at which the free moisture is evaporating from the solids at a constant rate. 738 Fermentation and Biochemical Engineering Handbook If one were to measure the temperature of the bed or individual particles ofwet solids at this point, the tempera- ture would be the wet cake temperature. After the free moisture has evaporated, the cake temperature rises, an indication of the end of the constant rate period. Several stages of this period can occur due to the existence of bound moisture. If bound moisture exists, the energy required to break the bonds is absorbed from the gas stream as heat input. As the bonds break, the bound moisture is released and is removed as surface moisture described above. The quantity of molecules of hydration and the temperature which the product must reach in order to break these bonds affect the overall constant drying rate period. One can generally observe a rise in the wet cake temperature, after the free moisture has evaporated, to the temperature which is required to break the bonds. This temperature then becomes the next wet bulb level or isotherm. Several levels of bound moisture may exist during the drying process. (Note: In general, this bound moisture phenomenon occurs mostly with inorganic salts and therefore may not be a major concern of the pharma- ceutical or biochemical industry.) 3. Diffusion, or falling rate period-this is the stage where the rate at which the liquid leaves the solid decreases. The liquid which is trapped inside the particles diffuses to the outside surface of the particle through capillary action. The random path which the liquid must take slows down the drying process at this stage. (See Fig. 9 for typical graph.) 5.0 FUNDAMENTAL ASPECTS OF DRYER SELECTION The starting point in determining how to dry certain products is first to ascertain whether the process will be a batch or continuous operation. If the product is manufactured in relatively small quantities and identification ofparticular size lots is required, than batch mode is usually the routetaken. Full accountability may be achieved when batch processing with the proper controls and procedures in place. The full batch of material to be dried must be enclosed in the dryer. A necessity for the equipment should be that the product dries uniformly. Drying 739 Figure 9. Typical rate-of-dqing curve, constant drying conditions. When manufacturing large quantities of a product which does not require tight batch controls, a more efficient operation (usually less expen- sive) results by drymg the product in a continuous or semi-continuous fashion. The product, in one case, can be batch-stored in large vessels and fed at a continuous rate to the dryer. The product is usually dried in small quantities thus requiring a long time to process the entire amount in a smaller, more efficient piece of equipment. In another situation, ideal for continuous operation, the product would be manufactured upstream ofthe dryer in a true plug flow manner and transferred to the dryer at a constant rate. In other words, the dryer’s capacity matches that of the upstream equipment. This is the most efficient manner. 5.1 Batch Direct Dryers Most direct batch dryers are fluid bed types such as those which retain the batch on a screen while pneumatically fluidizing the product. Mechani- cally agitated or tumble rotary dryers also exist. Ifthe product is temperature 740 Fermentation and Biochemical Engineering Handbook sensitive, the user should consider a vacuum dryer as an alternative. Vacuum or lower pressure can be utilized to assist in drying the product. However, since most of the mass transfer occurs as a result of the heat input transferred via conduction through the walls of the dryer’s jacket, that is considered to be an indirect dryer. For more information on indirect dryers please refer to the first section of this chapter. 5.2 Batch Fluid Bed Dryers In the category of fluid bed dryers, there are two types of processes commonly used to suspend the material-pneumatic and mechanical fluidi- zation. 1. Pneumatic Fluid Bed Dryers. In the pneumatic fluidiza- tion process, the wet cake is placed in the dryer and dry heated gas is introduced at a very high velocity (under the bed of product) through a fine screen or a porous plate in order to fluidize the product. There is a visible layer of material which is sustained as the gas passes through the bed. The wet gas leaves the chamber through a sock or bag type dust collector which removes the fines and returns them tothe batch. [More recently, stainless steel cartridge filters are becoming very popular because they can be cleaned-in-place (CIP). This has been developed by the Aeromatic-Fielder Division of Niro.] If the carrier me- dium is air containing only clean water vapor, the gas can then be exhausted to the atmosphere if it contains clean water vapor. If the medium is an inert gas, it can be recycled back to the dryer while removing contaminants or solvents via a condenser and filter. However, this inert gas must then be reheated to the proper inlet temperature. 2. Mechanically Agitated Fluid Bed Dryers, In the fluidi- zation process, the wet cake is gently lifted by rotating paddle type agitators thus blending the product into the gas stream creating an intimate mixing of the wet solids with the dry gas stream. This results in a very efficient exposure of the wet product’s surface area. The advantage of such a dryer is a faster drying time and a lower total energy input due to lower overall energy requirements (see Fig. 10). Drying 741 Exhaust air Exhwt duct R Filk h I oT tort,& filters - Material / contoiner Air preporation Material , unit Figure 10. Typical batch fluid bed dryer. 5.3 Batch Rotary Dryers ha batch rotary dryer, a horizontal cylinder is used to contain the batch while heated air is passed across the length of the cylinder. A jacket can be placed on the outside of the cylinder where steam or hot water is introduced to aid in heat transfer via conduction through the walls. Sometimes an agitator shaft with paddle arms, either heated or unheated, are included in the design to assist in heat transfer and product discharge. 5.4 Ribbon Dryers This type consists of a long, jacketed, horizontal cylinder, or a “U” shaped trough, which contains an agitator shaft positioned down the length of the bowl. The purpose of the cylindrical-shaped vessel may be for operation under pressure or vacuum. The agitator spokes are intermittently 742 Fermentation and Biochemical Engineering Handbook mounted on the shaft which support inner and outer rows of ribbon flights pitched so as to move the product. The outer ribbon flights usually move the product towards one side of the vessel and the inner ribbons move the product towards the other side. This design would have the discharge port at one end ofthe dryer. An alternative to this design is to have a center discharge, where the ribbons on one half of the dryer are pitched at 90" to the ribbons on the opposite end. The drying here is achieved by means of exposing the product to the surface area of the jacketed vessel. The jacket is a shell of metal (usually carbon steel) welded onto a stainless steel vessel body. This design can include a heated shaft for increased surface area exposure. The heat transfer medium used here is generally steam, hot oil, or hot water. Ports must be provided so as to vent the evaporated vapors being removed fromthe product. 5.5 Paddle Dryers Whereas a gaseous medium can be used to transfer heat to the product, in most cases the paddle type is considered to be an indirect dryer. It is similar in design to the ribbon dryer. The differences exist when heated (hollow) paddles are used as opposed to flat blades. (See the previous section on indirect drying.) Also, shoe-like paddles or plows can be used which tend to disperse or smear the product against a heated, horizontal, cylindrical wall. The advantage of a heated paddle design is that the surface area exposure to the product being dried has been expanded thus increasing the overall heat transfer rate. Most paddle dryers are designed for use under vacuum which can supplement the indirect drying process. 5.6 Agitated Pan Dryers An agitated open pan dryer is somewhat more complicated mechani- cally. This is a short cylinder whose axis and agitator are vertical. The agitator can enter from either the top or the bottom. As with the paddle dryers, these are mostly considered to be indirect dryers since heat transfer is from the jacket. If the product is a sticky, pasty material one may wish to use this design. The advantage of the pan dryer is the availability of several heated agitator designs which improve the overall heat transfer rate appreciably over a simple heated jacket; the reason is the same as mentioned in the previous section on paddle dryers. As mentioned earlier, venting of the dryer is necessary to remove the evaporated vapors. Drying 743 5.7 Continuous Dryers Continuous types of direct dryers are spray, flash or rotary designs, where the product enters in a form suitable to be handled properly by that dryer. Spray dryers can accommodate a feed stream in a slurry or solution form, whereas a flash dryer is intended to take a feed cake which can be broken up into individual pieces without coalescing. The feed characteristics required for flash dryers are that the product must break up if introduced as a cake. If introduced as a paste, it is necessary for the feed to be backmixed with previously dried material so as to firm up the cakes's consistency. Rotary dryers are more flexible in that they can handle a wide variety of feed consistencies. 5.8 Spray Dryers Spray dryers are large cylindrical chambers with a cone or flat bottom. They also appear in the form of a large cube or box referred to as a box dryer. Small nozzles are located in the chamber walls through which the feed material, in the form of a slurry or solution, is atomized to a fine droplet. The droplet comes into contact with a hot gas stream and dries to a powder in the time that it takes for it to fall to the bottom ofthe chamber. Typical residence times in a chamber are 12 to 30 seconds. Due to the evaporative cooling effect, the inlet temperature on this type of dryer is normally quite high relative to the dry products' temperature limitations. Typical inlet tempera- tures for spray dryers range from 400'F to lOOOOF depending on the application. The higher temperatures are normally for inorganic salt drying and the lower temperatures are normally for organic temperature sensitive products. The resultant individual product is always spherical in shape due to the initial droplet and it will tend to be extremely porous and fracture easily. Further processing of spray dried product has been done to achieve instuntizing by creating agglomerates of these spheres which retain a relatively high surface area compared to the individual particles. The action of adding this powder to water results in a release of energy from the agglomerated bonding forces and the capillary effect of the water traveling into the porous spheres. The net effect is one of quick dissolution of the agglomerated powder. This is highly desirable when searching for a means of instuntizing a product. In order to consider spray drying, certain criteria about the material must be met. The feed slurry viscosity must be low enough whereby it can be pumped through either a rotary atomizer, a two fluid nozzle or a high 744 Fermentation and Biochemical Engineering Handbook pressure nozzle which have narrow paths. The product must also be able to withstand high inlet temperatures for very short times. Usually the product will reach the outlet temperature. 5.9 Flash Dryers Flash dryers have many variations in design. The most basic is a long pipe with a fan, using a high velocity air stream to fluidize and move the wet product in the pipe while concurrently drying the product. Wet feed consistency is extremely important here because if the feed is too sticky or tacky, it will tend to lump together in the feed inlet. The use of paddle type backmixers is common to combine dry material with wet cake to provide a consistent friable feed tothe dryer. Backmixing 50% ofthe dry material with the wet cake is not uncommon. The inlet of the flash dryer is sometimes referred to as the throat-it is ofthe venturi design so that product is whisked into the chamber and exposed to a high velocity and high temperature as quickly as possible. Most products being flash dried are inorganic salts because the process lends itself to materials which are not temperature sensitive and their final particle shape is not critical. The larger chunks of material will abrade quickly in the long pipe as the material traverses the entire distance of the dryer. 5.10 Ring Dryers A second flash dryer design is a ring dryer. The product may be introduced into this type of dryer in a similar fashion as the standard flash dryer. However, instead ofthe long pipe as the drying chamber, the product is brought into a ring of pipe where the high velocity air stream and centrifugal forces keep the larger particles in the loop, while smaller particles leave via a contoured inner discharge port. The inlet and outlet port are tangential to the ring and two fans are utilized; one as an exhaust fan for providing the motive air and the second for providing the closed loop recirculation and introducing the product into the ring. 5.11 Mechanically Agitated Flash Dryers A third design is a flash dryer design (combined fluid bed and flash) with a small drying chamber using high speed agitators and complicated swirling arrangements. In this design the cake can be in the pasty or even runny form. Material enters a feed vat where pitched turbine-type blades Drying 745 rotate at a slow speed forcing the cake or paste down towards the bottom of the vat. At the bottom of the vat is a port which opens to a screw conveyor that sends the material into the flash chamber. The flash chamber has a relatively narrow diameter, is a vertical vessel with an agitator on the bottom which breaks up the cake. This occurs while hot air (or inert gas) is introduced into the chamber bottom to dry the cake in a co-current fashion. The larger pieces ofthe wet cake tend to ride on top ofthe agitator, thus thefluidbedpart of the design. The fine particles swirl around the drying chamber and leave via a cone shaped weir at the top of the vessel. The weir acts as a barrier to the oversizedmaterials and retains them in the chamber until they break down in particle size and essentially are dry. 5.12 Rotary Tray or Plate Dryers In a continuous rotary dryer, rotating tray or plate type dryer design, the feed enters and is turned over many times exposing fresh wet surfaces of material to the hot gas stream. In the former, lifters or an agitator may be used to assist the product in moving through the unit and towards the discharge port. In the latter (the Wyssmont Turbo-Dryer), wiper arms are used to displace the product as it falls through slots to successive trays below. This style is ideal for delicate, crystalline pharmaceuticals where particle breakage is a major concern for the producer. In the plate type design (Krauss Maffei’s Plate Dryer), a cylindrical housing with a vertical axis holds a stack ofheated plates or discs on a central support. There are rotating wiper arms which plow through and push material towards the center or outside of the heated plates. The plates are sized so that the plate below is under the above plate at the point where the material falls. The plates are designed as a closed conductive surface to transmit the heat up from the bottom of the plate into the bed of material. There are also some radiation effects from the upper plate to the material below. This design can be operated under pressure or vacuum conditions since the heat transfer is by conduction. The limitation of this design is that it can only handle relatively free flowing materials. 5.13 Fluid Bed Dryers Continuous fluid bed dryers can be used for drying materials which have aconsistency whereby the initial material is friable. This is an important consideration, especially in continuous processing, since the cake must continue to move along the path ofthe bed at a fairly constant rate. Otherwise 746 Fermentation and Biochemical Engineering Handbook the result will be a blockage of the unit and shutdown of the processing line until the blockage can be cleared. The “constant rate” part of the drying process in a fluid bed occurs at the porous plate or screen where the heaviest (and usually the wettest) material rests. This part of the process is the most critical as the material needs to become fluidized here to continue through the bed in stages, over weirs or simply down the deck of the bed. The air flow here needs to be at the highest velocity to compensate for the denser (wetter) material. The lighter material fluidizes rather easily and is generally dry by the time it “floats” to the top. One manufacturer’s design uses weirs to retain the heavy (wet) material in the first zone. In the second zone, the bulk of the moisture has been removed and the lighter material can be dried through the diffusion or falling rate period. In most cases there is a desire to cool the product and this can be achieved in a third zone. Such a design is similar in shape to a submarine, with the weirs having a very short height on top of the porous plate which is located horizontally at the lower middle section of the cylinder. Since the weirs are low relative to the height of the chamber, cool air will mix with the drying air in the open chamber and therefore, it is more efficient to perform the cooling operation in a separate unit. Fines removal is achieved by placing a recycle fdduct loop at a peak above the fiont-center of the top of the chamber. By lifting the fines up into this area they can be sent off to a bag house or cyclone where they can be collected for removal from the batch or for recycling. When agglomeration is desired, a spray bar can be incorporated to introduce a mist to a point near the inlet throat of the fluid bed unit where the wet material can be mixed with fines which are recycled as described above. This process is used mainly after a product has been spray dried or if the initial material to the fluid bed is not too wet. 6.0 DATA REQUIREMENTS In order to assist the purchaser of the dryer, the equipment manufac- turer will require certain data about the product to be dried and the operation around the dryer. One needs to have the answers to questions relating to the physical properties, characteristics and end use of the material to be dried as well as the liquid being removed. The following example is used to illustrate why such data is needed as a guide to select a dryer; notice the terms which are italicized: Drying 747 Example l-Dry 100 Ibs. of wet cake with an initial volatiles content of 25% (wet basis) down to ajnal volatiles content of less than 1 %. This will be achieved in a batch operation for lot identification, GMP and high quality standards. The loose bulk density of the wet cake is 45 Ibs../fL3 and the loose bulk density of the dry powder is 12 Ibs./ft3 The temperature limit of the product is 145°F and the feed material is wet with ethanol. The product is apharmaceu- tical which will be ajnishedproduct. The solvent is to be recovered for reuse, and its physical properties can be found in a handbook of hydrocarbons. The product is freeJowing in the dry state, but very tacky andpasty in the wet state. We can see in the above example that there is a significant amount of information about the product to be dried. With more information available about the product, we can select the dryer such that it performs the necessary functions with a better and more efficient operation. Also, a possible benefit may be improved product quality. Using the above example, let’s select a dryer for the operation specified-first, we can calculate the amount of solvent to be dried by taking the total weight of the wet cake and multiplying it by the initial volatiles content. This is the total amount of ethanol in the product as it will be introduced to the dryer. In this case the result is 25 Ibs. Now we must calculate the amount of volatiles left in the final dry product. One way of calculating this amount is to first calculate the total solids in the batch. Since we have 100 lbs. ofwet cake with 25 Ibs. of ethanol, we must have 75 Ibs. of dry solids or total solids. Using the total solids in the batch as a basis, we add back the non-dried moisture by the following formula: Final Volatiles in dried product = (Total solids) x (1/[ 1 - FUC wet basis]) - 1) Or, if we carry the unit analysis through: Pounds = (pounds) x (l/[l - (%/100)] - 1) Substituting the above numbers we see: 75 lbs. x (l/[l - (l%/lOO)]) or 75 x ([1/.99]-1) 748 Fermentation and Biochemical Engineering Handbook or: 75 x (1.0101 - 1) = ,7575 pounds of ethanol. Therefore, the final product weight is 75.76 pounds. this formula reduces to: When the final volatiles content is less than 5% a simplified version of Total Final Volatiles = Total solids x FMC/I00 or, in this case: 75 Ibs. x 1Yd100 = .75 Ibs. of ethanol Depending upon the application, one can choose whichever method is more practical. In any case, the final weight of the product will be about 76 Ibs. The next calculation is for the volume that the cake will occupy in the batch. By dividing the wet cake weight by the wet loose bulk density we attain the wet volume of the cake as it will be introduced into the dryer. This is important for several reasons. It is important to know the volume that will be occupied by the cake as it relates to the geometry of the proposed dryer. Some dryers may not be suitable beyond a given working volume due to dryer design characteristics. A more important reason is to actually choose the correct size ofthe dryer. A comparison must be made between the dry volume and the wet volume. The dryer should be chosen on the basis of the larger of the two operating volumes. Note that there is a difference between operating volume and a manufacturer’s stated “Total”vo1ume. The total volume given may include vapor space but it is not meant to contain just product. For instance, if we use the above case, the dry volume is about 75/12 ft3 or 6.25 ft3. The wet volume is 100/45 ft3 or 2.22 ft3. Due to the tacky nature of the product, one should begin the dryer selection process with a mechanically agitated style and proceed to test various types from there. If the material were free-flowing, a batch fluid bed dryer with an operating volume of 6.25 ft3 would be ideal. 7.0 SIZING DRYERS In order to practically evaluate a design, you need to conduct test work on either a specific manufacturer’s laboratory/pilot plant unit or design and build a test unit of your own, The former case is recommended because of the obvious advantages involved in making use of the manufacturer’s Drying 749 experience and the relatively low cost. Typically, these costs are only charged by the manufacturers in order to cover their expenses for the laboratory and to avoid becoming a substitute for a company’s research facility. The option of building your own pilot unit may be desirable if there is much test work to be performed in research and development, but the drawback is that it may be difficult to obtain a full-scale model of your own lab design without manufBcturing it through a metal fiibrication shop. Usually, the best option is to select a reputable manufacturer through references and rent or purchase one oftheir pilot or laboratory models to conduct serious test work, which can be used to scale up to a production size model. After conducting test work, most manufacturers are willing to explain the internal features of the design of their unit. This may require sufficient mechanical design details to remove some of the mystique surrounding the manufacturer’s design, 7.1 Spray Dryers Sizing a continuous spray dryer begins with defining the hourly quantity which is broken down into solids and liquids. The quantity of the liquid present is used to calculate the energy input necessary to evaporate that amount of liquid. For example: Example 2-Dry 1000 1bs.hour of a slurryholution contain- ing 90% water and 10% solids. The temperature limit ofthe product is 170°F. The feed temperature is 65°F and the viscosity is less than 100 centipoise. The above information is all that is required to perform a preliminary sizing on a spray dryer. The temperature limit of the product is given at 170°F. Using 160’F as the outlet temperature of the dryer should allow us the safety necessary so as not to exceed the temperature limit of the dry powder (product). The fact that we get evaporative cooling while drying the spherically shaped droplets to a similarly shaped powder allows us to use an inlet temperature of about 320°F. Thus the temperature difference (AT) is 160°F. This is the primary driving force in motivating the water to leave the product due to the enormous difference in saturation equilibrium between the wet droplevdry powder and the very hot dry air. To illustrate further, the relative humidity of air at 320°F is about 1% and the absolute humidity of the air is about 0.027 Ibs. of water per pound of dry air. This already includes moisture from the products of combustion of the natural gas used for heating in an open system. This is a long way from 750 Fermentation and Biochemical Engineering Nan dbook saturation. Our objective is to calculate how much air will be required to “carry” the water out of the spray drying chamber. In order to avoid condensation in a bag house, where the temperature may drop to 110°F depending upon indoor vs. outdoor installation factors, we will use 100” as our saturation limit. This means that at 100°F our relative humidity may equal 100% and our absolute humidity is equal to 0.042 Ibs. water per pound of dry air. Working backwards on the air-water saturation charts,[5] at 1 60°F we will have a relative humidity of 20% in the air. The difference between the absolute humidities is our factor for calculating the volume of air required to carrythe water out ofthechamber: 0.042-0.027 = .015 lbs ofwaterAb. of dry air. We have 900 Ibs/hr ofwater to evaporate, therefore, we need at least 60,000 Ibsh of air. At a density of 0.075 lbshubic foot at 70°F, we need an inlet volume of 13,333 cubic feet per minute (cfjn). In spray drying, typical residence times are based on certain manufac- turers configurations for the material to dry as it free falls and is swept through the chamber. These range from 12 to 25 seconds. Choosing a residence time here of 20 seconds yields a chamber volume of about 4,444 cubic feet. Using a cone bottom configuration and a 1 : 1 diameter to straight side ratio, the dimensions required are for the chamber to be about 16 feet in diameter and a height for the cone bottom and cylinder of about 32 feet. Next we will calculate the energy consumption. We have 900 lbshr of water to evaporate. Practically, we use 1000 BTUAb. of water as the energy consumption for evaporation. This means we need 900,000 BTUhr. As a coincidence, the amount of heat generated from burning natural gas is also about 1000 BTU/cubic foot. Therefore, if we now divide the 900,000 by 1000 we have 900 cubic feet of natural gas per hour as our energy consumption for evaporation. As a general rule, we must add some amount of energy consumption due to radiation heat transfer losses through the shell of the dryer. We will add 10% here since the temperature is not very high. For higher inledoutlet temperatures such as 1000°F-4000F, a number such as 20% would be acceptable as an estimate. 7.2 Flash Dryers These generally follow the same rule as used in the example above, however, one major difference is that one needs to know the fluidizing velocity of the wet cake or back mixed material to dry. The factors involved in determining the fluidizing velocity are particle size, particle density, particle shape, bulk density, and medium for fluidization. Since there are too many factors to place into a reliable equation, the most expedient method of Drying 751 determining this quantity is for tests to be conducted. Once this velocity is known, the volume of air required to dry (which can be calculated as in the previous example) is divided by the velocity, thus resulting in the diameter of the flash dryer pipe. The residence times are generally the same as those in spray dryers. 7.3 Tray Dryers The basis for sizing convection type tray dryers usually requires the testing of three parameters on a fixed tray area-residence time, air velocity across the bed, and bed depth. Basically, this form of dryer requires a very long time to dry material relative to spray, flash and fluidized bed types. Much of the performance of this dryer has to do with the turning over of the cakehed so that new surfaces are exposed to the air stream which is at a constant temperature. The time requirement can range from 10 minutes for some products to upwards of 24 hours or longer. The length of the residence time is so important that a difference of 30 minutes may require the selection of a larger or smaller size dryer with a significant impact on the price. Example 3-Dry 100 lbs./hr (wet cake) of a pharmaceutical cake with 35%moisture coming from aplateand frame filter press in 1" thick pieces. The temperature limit of the dry material is about 190°F. The final moisture content is desired at 2% or less. It is known that on a continuous tray dryer with a bed depth of 2", it takes 3 hours to dry the material on a tray area of 1 ft2. The loose bulk density of the wet cake is 60 lbs./ft3. Calculating the initial amount on the tray as 1/6 of a ft3 (2"/12"), or 5 lbs. and dividing by the 3 hour drying time, we have a drying factor of 1.67 lbshour- ft2. Dividing this factor into the 100 lbs/hr required we see that the area required is about 60 A*. This is effective area and not total area, thus any places where material is not present in a 2" layer must not be accounted for as area. This refers to slots in between trays, as in a Wyssmont type Turbo-Dryer, or, if the material is very free flowing, it may be 2" high in the middle of the bed, but it's angle of repose gives it a 1" layer depth on the edges of the tray. Manually loaded shelf dryers are not continuous so we would have to calculate a batch-surge arrangement to accommodate the continuous operation. 752 Fermentation and Biochemical Engineering Handbook 7.4 Fluid Bed Dryers For the continuous vibrating deck type units, we would perform the sizing on a similar basis to that for flash drying, although we would probably not need to backmix here since the fluid bed can handle a denser, pastier material. Simply stated, the units are sized based on the amount of area required to dry the quantity desired in a finite time period. Unfortunately, each manufacturer uses different designs for their bed screen or porous plate. The way to size the dryer would be based on an effective drying yield defrned in units of pounds of solvent per hour-ft2. Knowing the amount of solvent or moisture to be removed per hour, one can easily calculate the area ofthe fluid bed. Getting the manufacturer to divulge the yield may prove difficult since they may not have the data for your particular solvent or may not want to divulge it due to the competitive nature of the business. 7.5 Belt or Band Dryers These dryers are very similar to continuous tray dryers, from a process viewpoint, yet different in layout and conveying design. The volumetric throughput ofthese units can be calculated with the usable surface area ofthe belt, the layer depth of the material and the speed of the belt. Process considerations also include the temperature of the air above the material and the temperature of the material bed itself. The product is generally dry when the bed temperature rises or approaches the air temperature. This is an indication that the moisture which had been evaporating and cooling down the bed of product no longer exists, thus indicating that the product is dry. Process designs vary among manufacturers, however, there is gener- ally an air flow from the top or sides blowing down or across the bed of material in a zoned area. This zone may have its own batch dryer with a fan, a heater, instrumentation and duct work, or it may be manifolded such that the air flow is regulated to maintain a certain temperature in that section using the evaporative cooling effect to control the outlet temperature from that zone. In the case of the downward air flow pattern, the belt is porous, whereas in the case of the cross flow pattern, the belt may be solid. The selection of air flowhelt design would depend on the particle size and shape of the product being dried. One would choose a porous belt when drying a large granular material which would not fall through the pores of the belt (which can be a wide metal or nylon wire mesh or, with a smaller particle size, could be a tight braided type screen). For very small particles, or those which Drying 753 can become dusty, one should choose the solid belt design with the cross flow air pattern. This will probably result in a longer drying time, but the alternative of dry powder falling through the cracks ofa porous belt will result in a loss in productivity or yield. Another factor for choosing the solid belt may be if the product being dried is time-temperature sensitive in which case material which falls through the cracks may decompose and may also pose a contamination problem for the good product passing through the dryer. 8.0 SAFETY ISSUES Most drying applications require a review of the safety issues by responsible personnel within the user’s company. Some of the matters to be discussed may affect the decision as to which type of dryer to use. Relevant questions to ask (and the concerns they raise) may include the following: 1. Is the product solvent wet? Inclusion of a solvent recov- ery system should be required for emissions and personnel protection. The emissions requirements are mandated by federal, state and/or local regulations and pertain to both atmospheric (air) and sewer (liquid) pollution by the hydrocarbon based or other solvents. For personnel protection, appropriate OSHA regulations should be fol- lowed pertaining to the proper breathing respirators, eye and skin protection. 2. Is the product dusty or hazardous? Even if the product is water wet, consideration should be given to the fact that the product may be toxic, flammable or hazardous in other ways. This would entail a hazardanalysis review of what if situations. For example, What if the product escapes from the confinement of the dryer, or what if air gets into the dryer from the surrounding environment? Some drying processes may require the addition of a fire or explosion suppression system. One such system uses an infra-red detector to sense a cinder combined with a sonic detection device to sense the shock wave of a deflagration. Halongas is immediately released into the drying chamber to suppress and smother the deflagration before it ruptures the chamber. For more information the reader should contact the suggested manufacturers in the reference list 754 Fermentation and Biochemical Engineering Handbook 3. at the end of the chapter. Other safety devices to investi- gate are rupture discs, relief valves, emergency vents and conservation breather vents. Also explosion containment is a valid path to follow with a manufacturer. Is the dryer in a safe area? The dryer’s environment may be mother consideration to look at from the standpoint of personnel access to emergency stop buttons on the equip- ment. The location should be where an employee can reach the button when in a panic state. Proper dust collection equipment should be specified for a situation where the system is exhausting gases. This can be in the possible form of a bag house, a cyclone, or a scrubber. It is also possible to have a situation where two or three of the above are required. 4. Is the dryer built to safe standards? During the course of drying the material, the vessel may be subjected to positive or negative pressure. As such, it may need to be regulated by standards such as the ASME (American Society for Testing and Materials) Code, which defines mechanical specifications, such as wall thicknesses, for various ma- terials of construction. This must be defined by the manufacturer, but the purchaser should be aware of the process needs so as to inform the manufacturer to insure the proper design. 8.1 Specific Features If there is a part of the design which can result in someone getting hurt due to temperature of a hot metal surface, OSHA regulations apply. An electrical panel being washed down with water would be regulated by NEMA classifications. The steam pressure required to heat a vessel may need to be 100 psig for the drying operation. As such, the jacketed heat transfer surface area on the vessel will need to be built according to the ASME Code. If there is a moving part in the dryer which operators may be exposed to, or where possible injury may result, this requires serious consideration of limit switches on access doors, etc. These are used quite often to protect the operator from opening a unit with moving parts. Attention should be paid to any possible moving parts which can coast after the door is opened and the limit switch has shut off the electrical circuit. The above-mentioned Drying 755 regulations are only examples of possible situations which may be encoun- tered. It is the responsibility of the user of the equipment to provide the manufacturer with enough information as tothe intended use ofthe equipment so as to allow the manufacturer input for safety. 9.0 DECISIONS When choosing a particular dryer design one should consider the following factors: 1. Has this design been used for this productlprocess before? 2. Is the equipment design produced by several manufactur- ers? This allows the purchaser to choose several potential vendors. Each may have similar designs, but the pur- chaser should consider individual features that offer ad- vantages to the process, production or maintenance de- partments. 3. What are the cost factors involved between continuous and batch designs? Has continuous processing been considered more valuable than the quality which can be defined by batch integrity? 4. Is the design capable of meeting your stringent quality standards with regards to the overall cleanability of the design? This may have to do with the internal quality of the welds and polishing of the machine. Another factor may be the outside support structure itself which may need to be redesigned by the manufacturer in order to make the unit easier to clean or inspect. What are the implications of cleanup between batches? How clean does the equip- ment have to be when changing products? 5. Will the unit selected fit into an existing area? Does the area need to be enlarged? Will permits be required? In selecting a spray dryer, generally, a good rule of thumb is to select the largest dryer which can fit into a given space based on the height available. 6. Have the auxiliary systems (materials handling, heating, solvent recovery, dust collection, etc.) been given enough consideration with safety factors for product changes? 756 Fermentation and Biochemical Engineering Handbook For example, the dryer may be large enough to handle the intended capacity, but the heating system may be too small. 10.0 TROUBLE SHOOTING GUIDE Some of the problems encountered in drying are a result of the following actions by the user: 1. Changing the product formulation that the dryer was originally intended to process. 2. Changing upstream process equipment. Example-The dryer was designed to process material from a vacuum belt filter at 30% W.B. which is now coming from a filter press with a moisture content of 40% W.B. This will probably lengthen the drying time and may affect the product quality due to possible changes in feed character- istics. If a flash dryer is being used, the finer material may overheat because it is not wet enough and the processing time is fixed by the length of the tube. 3. Changing the solvent used to process the material to be dried. This will affect the performance of the solvent recovery system. It may also affect the materials of construction if a particularly nasty solvent is used such as methylene chloride. For resistance to chloride attack, a dryer of stainless steel construction may now need to be made of a higher nickel alloy such as Hastelloy or Monel. 4. Changing the process parameters. Temperature, pressure and work (agitators, mechanical action) all affect the end product in some way. Temperature is the most visible parameter. Agitation can be critical in both breaking up a product in a lump form or it may cause the undesirable effect of churning the product into a very difficult paste. Products which are thixotropic or dilatant are most af- fected by agitation. Drying 757 Additional suggestions: 1. Product melting or liquifjmg in dryer. Check if there is bound water present and reduce product temperature exposure. 2. Case Hardening. Break up feed material and increase air flow or agitation to speed up drymg process. 3. Occasional discoloration or charring. Check for exposed hot surfaces or residual product holdober. 11.0 RECOMMENDED VENDORS LIST AeromaticRielder Div. Niro, Inc. 9165 Rumsey Road Columbia, MD 2 1045 Aljet Equipment Co. 10 15 York Road Willow Grove, PA 19090 Barr & Murphy Ltd. Victoria Ave. Westmount, Quebec H3Z 2M8 Fenwall Safety Systems 700 Nickerson Road Marlborough, MA 0 1752 Fike Metal Products 704 S 10 Street Blue Springs, MO 64 105 Komline-Sanderson Corp. 100 Holland Ave. Peapack, NJ 07977 Batch and Continuous PneumaticFluid Bed and Spray Dryers Continuous Flash Ring Dryers Continuous Flash Ring and Spray Dryers Fire and Explosion Sup- pression Systems Fire and Explosion Sup- pression Systems, Rupture Discs Continuous Paddle Dryers 758 Fermentation and Biochemical Engineering Handbook Krauss Maffei Corp. Process Technology Div. PO Box 6270 Florence, KY 41042 Continuous Plate Dryers Paul 0. Abbe, Inc. 139 Center Ave. Little Falls, NJ 07424 Dryers Batch Dryers, Mechanical Fluid Bed Protectoseal Company 225 W Foster Ave. Bensenville, IL 60 106 Wyssmont Co. 1470 Bergen Blvd. Ft. Lee, NJ 07024 Emergency, Conservation and Breather Vents (Safety and Explosion Venting) Continuous Rotary Tray Dryers REFERENCES AND BIBLIOGRAPHY (for Section 1I:Direct Drying) 1. 2. 3, 4. 5. Perry, R. H. and Chilton, C. H., Chemical Engineer’s Handbook, 5th. Edition, McGraw-Hill (1973) Babcock and Wilcox, Steam/Its Generation and Use, 38th. Edition, The Babcock and Wilcox Company (1972) Smith, J. M. and Van Ness, H . C., Introduction to Chemical Engineering Thermodynamics, 3rd. Edition, McGraw-Hill (1975) Robinson, Randall N., Chemical Engineering Reference Manual, 4th. Edition, Professional Publications (1 987) Treybal, R. E., Mass Transfer Operations, Second Edition, p. 187, Fig. 7.5, p. 582, Fig. 12.10, McGraw-Hill (1968)