The present invention relates generally to spray dryers, and more particularly to an apparatus and methods for spray drying liquids into dry powder form.
Spray drying is a well known and extensively used process in which liquid slurries are sprayed into a drying chamber into which heated air is introduced for drying the liquid into powder. The slurry commonly includes a liquid, such as water, an ingredient, such as a food, flavor, or pharmaceutical, and a carrier. During the drying process, the liquid is driven off leaving the ingredient in powder form encapsulated within the carrier. Spray drying also is used in producing powders that do not require encapsulation, such as various food products, additives, and chemicals.
Spray drying systems commonly are relatively massive in construction, having drying towers that can reach several stories in height. Not only is the equipment itself a substantial capital investment, the facility in which it is used must be of sufficient size and design to house such equipment. Heating requirements for the drying medium also can be expensive.
While it is desirable to use electrostatic spray nozzles for generating electrically charged particles that facilitate quicker drying, due to the largely steel construction of such sprayer dryer systems, the electrostatically charged liquid can charge components of the system in a manner, particularly if unintentionally grounded, that can impede operation of electrical controls and interrupt operation, resulting in the discharge of uncharged liquid that is not dried according to specification.
While it is known to form the drying chamber of electrostatic spray dryers of a non metallic material to better insulate the system from the electrically charged liquid, particles can adhere to and build up on the walls of the drying chamber, requiring time consuming cleanup which interrupts the use of the system. Moreover, very fine dried powder within the atmosphere of heating air in the drying chamber can create a dangerous explosive condition from an inadvertent spark or malfunction of the electrostatic spray nozzle or other components of the system.
Such spray dryer systems also must be operable for spray drying different forms of liquid slurries. In the flavoring industry, for example, it may be necessary to operate the system with a citrus flavoring ingredient in one run, while a coffee flavoring ingredient is used in the next operation. Residual flavor material adhering to the walls of the drying chamber can contaminate the taste of subsequently processed products. In the pharmaceutical area, of course, it is imperative that successive runs of pharmaceuticals are not cross-contaminated.
Existing spray dryer systems further have lacked easy versatility. It sometimes is desirable to run smaller lots of a product for drying that does not require utilization of the entire large drying system. It further may be desirable to alter the manner in which material is sprayed and dried into the system for particular applications. Still in other processing, it may be desirable that the fine particles agglomerate during drying to better facilitate ultimate usage, such as where more rapid dissolution into liquids with which it is used. Existing sprayers, however, have not lent themselves to easy alteration to accommodate such changes in processing requirements.
Spray dryers further tend to generate very fine particles which can remain airborne in drying gas exiting the dryer system and which must be filtered from gas exiting the system. Such fine particulate matter can quickly clog filters, impeding efficient operation of the dryer and requiring frequent cleaning of the filters. Existing spray dryers also have commonly utilized complex cyclone separation and filter arraignments for removing airborne particulate matter. Such equipment is expensive and necessitates costly maintenance and cleaning.
It is an object of the present invention to provide a spray dryer system adapted for more efficient and versatile operation.
Another object is to provide a spray dryer system as characterized above which has a filter system for more effectively and efficiently removing airborne particulate matter from drying gas exiting the dryer and with lesser maintenance requirements. A related object is to provide such a spray dryer in which the filter system is effective for enabling recirculation and reuse of the filtered gases, and particularly inert heating gases.
Another object is to provide a spray dryer system of such type in which the drying gas filter system includes means for automatically and more effectively removing the buildup of particulate matter on the filters.
A further object is to provide an electrostatic spray dryer system that is relatively small in size and more reliable in operation.
Still another object is to provide an electrostatic spray dryer system that is relatively short in height and can be installed and operated in locations without special building or ceiling requirements.
A further object is to provide an electrostatic spray dryer system of the foregoing type that is effective for spray drying different product lots without cross-contamination.
Yet another object is to provide an electrostatic spray dryer system of the above kind that is easily modifiable, both in size and processing techniques, for particular drying applications.
A further object is to provide an electrostatic spray dryer system that is operable for drying powders in a manner that enables fine particles to agglomerate into a form that better facilitates subsequent usage.
Still another object is to provide an electrostatic spray dryer system that can be effectively operated with lesser heating requirements, and hence, more economically. A related object is to provide a spray dryer system of such type that is operable for effectively drying temperature sensitive compounds.
Another object is to provide a modular electrostatic spray dryer system in which modules can be selectively utilized for different capacity drying requirements and which lends itself to repair, maintenance, and module replacement without shutting down operation of the spray dryer system.
Yet another object is to provide an electrostatic spray dryer system of the above type that is less susceptible to electrical malfunctions and dangerous explosions from fine powder and the heating atmosphere within the drying chamber of the system. A related object is to provide a control for such spray dryer system that is effective for monitoring and controlling possible electrical malfunctions of the system.
Still a further object is to provide such an electrostatic spray dryer system that is relatively simple in construction and lends itself to economical manufacture.
Other objects and advantages of the invention will become apparent upon reading the following detailed description and upon reference to the drawings.
While the invention is susceptible of various modifications and alternative constructions, certain illustrative embodiments thereof have been shown in the drawings and will be described below in detail. It should be understood, however, that there is no intention to limit the invention to the specific forms disclosed, but on the contrary, the intention is to cover all modifications, alternative constructions, and equivalents falling within the spirit and scope of the invention.
Referring now more particularly to the drawings, there is shown an illustrative spray drying system 10 in accordance with the invention which includes a processing tower 11 comprising a drying chamber 12 in the form of an upstanding cylindrical structure, a top closure arrangement in the form of a cover or lid 14 for the drying chamber 12 having a heating air inlet 15 and a liquid spray nozzle assembly 16, and a bottom closure arrangement including a powder directing plenum in the form of a powder collection cone 18 supported at the bottom of the drying chamber 12, a filter element housing 19 through which the powder collection cone 18 extends having a heating air exhaust outlet 20, and a bottom powder collection chamber 21. The drying chamber 12, collection cone 18, filter element housing 19, and powder collection chamber 21 all preferably are made of stainless steel. The top cover 14 preferably is made of plastic or other nonconductive material and in this case centrally supports the spray nozzle assembly 16. The illustrated heating air inlet 15 is oriented for directing heated air into the drying chamber 12 in a tangential swirling direction. A frame 24 supports the processing tower 11 in upright condition.
Pursuant to an important aspect of this embodiment, the spray nozzle assembly 16, as best depicted in
The nozzle supporting head 31 in this case further is formed with a radial pressurized air atomizing inlet passage 39 downstream of said liquid inlet passage 36 that receives and communicates with an air inlet fitting 40 coupled to a suitable pressurized gas supply. The head 31 also has a radial passage 41 upstream of the liquid inlet passage 36 that receives a fitting 42 for securing a high voltage cable 44 connected to a high voltage source and having an end 44a extending into the passage 41 in abutting electrically contacting relation to an electrode 48 axially supported within the head 31 and extending downstream of the liquid inlet passage 36.
For enabling liquid passage through the head 31, the electrode 48 is formed with an internal axial passage 49 communicating with the liquid inlet passage 36 and extending downstream though the electrode 48. The electrode 48 is formed with a plurality of radial passages 50 communicating between the liquid inlet passage 36 and the internal axial passage 49. The illustrated electrode 48 has a downstream outwardly extending radial hub 51 fit within a counter bore of the head 31 with a sealing o-ring 52 interposed there between.
The elongated body 32 is in the form of an outer cylindrical body member 55 made of plastic or other suitable nonconductive material, having an upstream end 55a threadably engaged within a threaded bore of the head 31 with a sealing o-ring 56 interposed between the cylindrical body member 55 and the head 31. A liquid feed tube 58, made of stainless steel or other electrically conductive metal, extends axially through the outer cylindrical body member 55 for defining a liquid flow passage 59 for communicating liquid between the axial electrode liquid passage 49 and the discharge spray tip assembly 34 and for defining an annular atomizing air passage 60 between the liquid feed tube 58 and the outer cylindrical body member 55. An upstream end of the liquid feed tube 58 which protrudes above the threaded inlet end 55a of the outer cylindrical nozzle body 55 fits within a downwardly opening cylindrical bore 65 in the electrode hub 51 in electrical conducting relation. With the electrode 48 charged by the high voltage cable 44, it will be seen that liquid feed to the inlet passage 36 will be electrically charged during its travel through the electrode passage 49 and liquid feed tube 58 along the entire length of the elongated nozzle body 32. Pressurized gas in this case communicates through the radial air inlet passage 39 about the upstream end of the liquid feed tube 58 and then into the annular air passage 60 between the liquid feed tube 58 and the outer cylindrical body member 55.
The liquid feed tube 58 is disposed in electrical contacting relation with the electrode 48 for efficiently electrically charging liquid throughout its passage from the head 31 and through elongated nozzle body member 32 to the discharge spray tip assembly 34. To that end, the discharge spray tip assembly 34 includes a spray tip 70 having an upstream cylindrical section 71 in surrounding relation to a downstream end of the liquid feed tube 58 with a sealing o-ring 72 interposed therebetween. The spray tip 70 includes an inwardly tapered or conical intermediate section 74 and a downstream cylindrical nose section 76 that defines a cylindrical flow passage 75 and a liquid discharge orifice 78 of the spray tip 70. The spray tip 70 in this case has a segmented radial retention flange 78 extending outwardly of the upstream cylindrical section 71 which defines a plurality of air passages 77, as will become apparent.
For channeling liquid from feed tube 58 into and though the spray tip 70 while continuing to electrostatically charge the liquid as it is directed through the spray tip 70, an electrically conductive pin unit 80 is supported within the spray tip 70 in abutting electrically conductive relation to the downstream end of the feed tube 58. The pin unit 80 in this case comprises an upstream cylindrical hub section 81 formed with a downstream conical wall section 82 supported within the intermediate conical section 74 of the spray tip 70. The cylindrical hub section 81 is formed with a plurality of circumferentially spaced radial liquid flow passageways 83 (
For concentrating the electrical charge on liquid discharging from the spray tip, the pin unit 80 has a downwardly extending central electrode pin 84 supported in concentric relation to the spray tip passage 75 such that the liquid discharge orifice 78 is annularly disposed about the electrode pin 84. The electrode pin 84 has a gradually tapered pointed end which extends a distance, such as between about ¼ and ½ inch, beyond the annular spray tip discharge orifice 78. The increased contact of the liquid about the protruding electrode pin 84 as it exits the spray tip 70 further enhances concentration of the charge on the discharging liquid for enhanced liquid particle breakdown and distribution.
Alternatively, as depicted in
The discharge spray tip assembly 34 further includes an air or gas cap 90 disposed about the spray tip 70 which defines an annular atomizing air passage 91 about the spray tip 70 and which retains the spray tip 70, pin unit 80, and liquid feed tube 58 in assembled conductive relation to each other. The air cap 90 in this instance defines a conical pressurized air flow passage section 91a about the downstream end of the spray tip 70 which communicates via the circumferentially spaced air passages 77 in the spray tip retention flange 78 with the annular air passage 60 between the liquid feed tube 58 and the outer cylindrical body member 55 for directing a pressurized air or gas discharge stream through an annular discharge orifice 93 about the spray tip nose 76 and liquid discharging from the spray tip liquid discharge orifice 78. For retaining the internal components of the spray nozzle in assembled relation, the air cap 90 has an upstream cylindrical end 95 in threaded engagement about a downstream outer threaded end of the outer cylindrical member 55. The air cap 90 has a counter bore 96 which receives and supports the segmented radial flange 78 of the spray tip 70 for supporting the spray tip 70, and hence, the pin unit 80 and liquid feed tube 58 in electrical conducting relation with the upstream electrode 48.
The spray nozzle assembly 16 is operable for discharging a spray of electrostatically charged liquid particles into the drying chamber 12. In practice, it has been found that the illustrated electrostatic spray nozzle assembly 16 may be operated to produce extremely fine liquid particle droplets, such as on the order of 70 micron in diameter. As will become apparent, due to the breakdown and repelling nature of such fine liquid spray particles and heated drying gas introduced into the drying chamber, both from the heating air inlet 15 and the air assisted spray nozzle assembly 16, the liquid particles are susceptible to quick and efficient drying into fine particle form. It will be understood that while the illustrated electrostatic spray nozzle assembly 16 has been found to have particular utility in connection with the subject invention, other electrostatic spray nozzles and systems could be used, including electrostatic hydraulic rotary spray nozzles and high volume low pressure electrostatic spray nozzles of known types.
Pursuant to a further important feature of the present embodiment, the drying chamber 12 has an internal non-metallic insulating liner 100 disposed in concentric spaced relation to the inside wall surface 12a of the drying chamber 12 into which electrostatically charged liquid spray particles from the spray nozzle assembly 16 are discharged. As depicted in
According to another aspect of the present embodiment, the processing tower 11 has a quick disconnect assembled construction that facilitates assembly and the mounting of the annular liner 100 in electrically insulated relation to the outer wall of the drying chamber 12. To this end, the annular insulating liner 100 is supported at opposite ends by respective upper and lower standoff ring assemblies 104 (
For securing each standoff ring assembly 104 within the drying chamber 12, a respective mounting ring 110 is affixed, such as by welding, to an outer side of the drying chamber 12. Stainless steel mounting screws 111 extend through aligned apertures in the mounting ring 110 and outer wall of the drying chamber 12 for threadably engaging the insulating standoff studs 106. A rubber o-ring 112 in this instance is provided about the end of each standoff stud 106 for sealing the inside wall of the drying chamber 12, and a neoprene bonded sealing washer 114 is disposed about the head of each retaining screw 111.
For securing the drying chamber top cover 14 in place on the drying chamber 12 in sealed relation to the upper standoff ring assembly 104, an annular array 120 (
During operation of the electrostatic spray nozzle assembly 16, liquid supplied to the electrostatic spray nozzle assembly 16 from a liquid supply, which in this case is a liquid holding tank 130 as depicted in
An electronic controller 133 is operably connected to the various actuators and electric or electronic devices of the electrostatic spray dryer system such as an electric motor 134, the pump 132, the liquid spray nozzle assembly 16, a high voltage generator providing electrical voltage to the high voltage cable 44, and others, and operates to control their operation. While a single controller is shown, it should be appreciated that a distributed controller arrangement including more than one controller can be used. As shown, the controller 133 is capable of operating in response to a program such as a programmable logic controller. The various operable connections between the controller 133 and the various other components of the system are omitted from
Pursuant to a further aspect of the present embodiment, the pump 132 is operated by the electric motor 134 (
An electrostatic voltage generator 222 is electrically connected to the nozzle assembly 16 via an electrical line 224 for providing a voltage that electrostatically charges the sprayed liquid droplets. In the illustrated embodiment, the electrical line 224 includes a variable resistor element 226, which is optional and which can be manually or automatically adjusted to control the voltage and current provided to the spray nozzle assembly 16. An optional grounding wire 228 is also electrically connected between the liquid supply line 131 and a ground 232. The grounding wire 228 includes a variable resistor 230 that can be manually or automatically adjusted to control a voltage that is present in the fluid. In the illustrated embodiment, the grounding wire is placed before the pump 132 to control the electrical charge state of the fluid provided to the system. The system may further include sensors communicating the charged state of the fluid to the controller 133 such that the system may automatically monitor and selectively control the charge state of the liquid by controlling the resistance of the variable grounding resistor 230 to bleed charge off from the liquid line in the system.
The drive motor 134, which also is appropriately grounded, in this instance is supported within a nonconductive plastic motor mounting housing 144. The illustrated liquid holding tank 130 is supported on a liquid scale 145 for enabling monitoring the amount of liquid in the tank 130, and an electrical isolation barrier 146 is provided between the underside of the liquid holding tank 130 and the scale 145. It will be understood that in lieu of the peristaltic pump 132, plastic pressure pots and other types of pumps and liquid delivery systems could be used that can be electrically insulated from their electrical operating system.
Pressurized gas directed to the atomizing air inlet fitting 18 of the spray nozzle assembly 16 in this case originates from a bulk nitrogen supply 150 which communicates with the atomizing air inlet fitting 18 of the spray nozzle assembly 16 via a gas supply line 151 (
Pursuant to a further important aspect of the present embodiment, heated nitrogen atomizing gas supplied to the spray nozzle assembly 16 and directed into the drying chamber 12 as an incident to atomization of liquid being sprayed into the drying chamber 12 is continuously recirculated through the drying chamber 12 as the drying medium. As will be understood with further reference to
The illustrated powder collection cone 18, as best depicted in
Alternatively, as depicted in
The illustrated the reverse pulse air filter cleaning devices 21, as depicted in
For interrupting the flow of process gas from the filter element housing 19a to the exhaust plenum 164 during operation of the reverse pulse nozzle 240, an annular exhaust port cut off plunger 249 is disposed above the reverse pulse nozzle 160a for axial movement within the exhaust plenum 164 between exhaust port opening and closing positions. For controlling movement of the plunger 249, a bottom opening plunger cylinder 250 is mounted in sealed depending relation from the upper wall of the exhaust plenum 164. The illustrated plunger 249 includes an upper relatively small diameter annular sealing and guide flange 252 having an outer perimeter adapted for sliding sealing engagement with the interior of the cylinder 250 and a lower larger diameter valve head 254 disposed below the lower terminal end of the cylinder 250 for sealing engagement with an exhaust port 253 in the panel 163. The plunger 249 preferably is made of a resilient material, and the upper sealing and guide flange 252 and lower valve head 254 have downwardly tapered or cup shaped configurations.
The plunger 249 is disposed for limited axial movement along the reverse pulse nozzle 240 and is biased to a normally open or retracted position, as shown in
During a reverse pulse gas cleaning cycle, a pulse of compressed gas is directed through the reverse pulse nozzle 240 from the inlet line 167a. As the compressed gas travels through the nozzle 160a, it first is directed through the larger diameter or plunger actuation holes 246 into the plunger cylinder 250 above the plunger sealing and guide flange 252 and then though the smaller reverse pulse nozzle holes 248. Since the larger holes 249 provide the path of less resistance, gas first flows into the plunger cylinder 250 and as pressure in the plunger cylinder 250 increases, it forces the plunger 249 downwardly against the biasing force of the spring 256. Eventually, the pressure builds to a point where it overcomes the force of the spring 256 and forces the plunger 249 downwardly toward the exhaust port 253 temporarily sealing it off. After the plunger 249 seals the exhaust port 253 the compressed gas in the outer plunger cylinder 250 can no longer displace the plunger 249 and gas pressure in the plunger cylinder 250 increases to a point that the compressed gas is then forced through the smaller nozzle holes 248 and against the filter 160a for dislodging build up particulate matter about its outside surface.
Following the reverse compressed air pulse and the dislodgement of the accumulated particulate on the filter 160a, pressure will dissipate within the plunger cylinder 250 to the extent that it will no longer counteract the spring 256. The plunger 249 then will move upwardly under the force of the spring 256 to its retracted or rest position, unsealing the exhaust port 253 for continued operation of the dryer.
Still another alternative embodiment of an exhaust gas filter element housing 270 and powder collection chamber 271 mountable on a lower end of the drying chamber 12 is depicted
The illustrated powder direction plenum 272 comprises an outer cylindrical housing wall 289 mountable in sealed relation to an underside of the drying chamber 12 and having an open upper end for receiving drying gas and powder from the drying chamber 12 and drying zone 127. Housed within the powder direction plenum 272 is a downwardly opening conically configured exhaust plenum 281 which defines on its underside an exhaust chamber 282 (
The filter element housing 270 comprises an outer cylindrical housing wall 284 mounted in sealed relation by means of an annular seal 285 to a bottom peripheral edge of the powder direction plenum 272 and an inner cylindrical filter shroud 286 mounted in sealed relation by means of an annular seal 288 to the bottom peripheral edge of the conical exhaust plenum 281. The conical exhaust plenum 281 and the inner cylindrical filter shroud 286 are supported within an outer cylindrical housing wall 289 of the gas directing plenum 272 and filter element housing 270 by the plurality of radial supports 290 (
The cylindrical filters 274 in this case are supported in depending relation to a circular support plate 295 fixedly disposed below the underside of the downwardly opening conical exhaust plenum 281. The circular filter support plate 295 in this case is mounted in slightly recessed relation to an upper perimeter of the cylindrical shroud 286 and defines a bottom wall of the exhaust chamber 282. The illustrated cylindrical filters 274 each are in cartridge form comprising a cylindrical filter element 296, an upper cylindrical cartridge holding plate 298, a bottom end cap and sealing plate 299 with interposed annular sealing elements 300, 301, 302. For securing the filter cartridges in assembled relation, the upper cartridge holding plate 298 has a depending U-shaped support member 304 with a threaded lower end stud 305 positionable through a central aperture in the bottom end cap 299 which is secured by a nut 306 with a o-ring sealing ring 308 interposed therebetween. The upper holding plate 298 of each filter cartridge is fixed in sealed relation about a respective circular opening 310 in the central support plate 295 with the filter element 296 disposed in depending relation to an underside of the support plate 295 and with a central opening 311 in the holder plate 298 communicating between the exhaust chamber 282 and the inside of the cylindrical filter element 296. The filter element cartridges in this case are disposed in circumferentially spaced relation about a center of the inner shroud 274.
The filter element housing 270 in this instance is secured to the powder direction plenum 272 by releasable clamps 315 or like fasteners to permit easy access to the filter cartridges. The inner filter shroud 286 also is releasably mounted in surrounding relation to the cylindrical filters 274, such as by a pin and slot connection, for enabling access to the filters for replacement.
During operation of the dryer system, it will be seen that drying gas and powder directed into the powder direction plenum 272 will be channeled about the conical exhaust plenum 281 into the annular passageways 291, 292 about the inner filter element shroud 274 downwardly into the powder direction cone 275 and collection chamber 271 for collection in the chamber 271. While most of the dried powder remaining in the gas flow will migrate into the powder collection chamber 271, as indicated previously, fine gas borne particulate matter will be separated and retained by the annular filters 274 as the drying gas passes through the filters into the drying gas exhaust plenum 282 for exit through a drying gas exhaust port 320 and recirculation to the drying chamber 12, as will be become apparent.
For cleaning the cylindrical filters 274 of buildup of powder during the course of usage of the dryer system, the cylindrical filters 274 each have a respective reverse gas pulse cleaning device 322. To this end, the gas direction plenum 272 in this case has an outer annular pressurized gas manifold channel 321 coupled to a suitable pressurized air supply. Each reverse air pulse cleaning device 322 has a respective pressurized gas supply line 325 coupled between the annular pressurized gas manifold channel 321 and a respective control valve 326, which in this case mounted on an outer side of the air direction plenum 272. A gas pulse direction line or tube 328 extends from the control valve 326 radially through the air direction plenum 272 and the conical wall of the exhaust plenum 329 and then with a right angle turn downwardly with a terminal discharge end 329 of the gas pulse directing line 328 disposed above and in aligned relation to the the central opening 311 of the filter cartridge holding plate 298 and underlying cylindrical filter element 296.
By appropriate selective or automated control of the control valve 326, the control valve 26 can be cyclically operated to discharge pulses of the compressed gas from the line 328 axially into the cyclical filter 274 for dislodging accumulated powder on the exterior wall of the cylindrical filter element 296. The discharge end 329 of the pulse gas directing line 328 preferably is disposed in spaced relation to an upper end of the cyclical filter 274 to facilitate the direction of compressed gas impulses into the filter element 296 while simultaneously drawing in gas from the exhaust chamber 282 which facilitates reverse flow impulses that dislodge accumulated powder from the filter element 296. Preferably the discharge end 329 of the air tube 328 is spaced a distance away from the upper end of the cylindrical filter element such that the expanding air flow, depicted as 330 in
The powder collection chamber 271 in this case has a circular butterfly valve 340 (shown in
For enabling recirculation and reuse of the exiting drying gas from the filter element housing 19a, the exhaust outlet 20 of the filter housing 19 is coupled to a recirculation line 165 which in turn is connected to the heating gas inlet port 15 of the top cover 14 of the heating chamber 12 through a condenser 166, a blower 168, and a drying gas heater 169 (
It will be appreciated that the drying gas introduced into the effective drying zone 127 defined by the flexible liner 100 both from the electrostatic spray nozzle assembly 16 and the drying gas inlet port 15, is a dry inert gas, i.e. nitrogen in the illustrated embodiment, that facilitates drying of the liquid particles sprayed into the drying chamber 12 by the electrostatic spray nozzle assembly 16. The recirculation of the inert drying gas, as described above, also purges oxygen from the drying gas so as to prevent the chance of a dangerous explosion of powder within the drying chamber in the event of an unintended spark from the electrostatic spray nozzle assembly 16 or other components of the system.
Recirculation of the inert drying gas through the spray drying system 10, furthermore, has been found to enable highly energy efficient operation of the spray drying system 10 at significantly lower operating temperatures, and correspondingly, with significant cost savings. As indicated previously, emulsions to be sprayed typically are made of three components, for example, water (solvent), starch (carrier) and a flavor oil (core). In that case, the object of spray drying is to form the starch around the oil and dry off all of the water with the drying gas. The starch remains as a protective layer around the oil, keeping it from oxidizing. This desired result has been found to be more easily achieved when a negative electrostatic charge is applied to the emulsion before and during atomization.
While the theory of operation is not fully understood, each of the three components of the sprayed emulsion has differing electrical properties. Water being the most conductive of the group, will easily attract the most electrons, next being the starch, and finally oil being the most resistive barely attracts electrons. Knowing that opposite charges attract and like charges repel, the water molecules, all having the greatest like charge, have the most repulsive force with respect to each other. This force directs the water molecules to the outer surface of the droplet where they have the greatest surface area to the drying gas which enhances the drying process. The oil molecules having a smaller charge would remain at the center of the droplet. It is this process that is believed to contribute to more rapid drying, or drying with a lower heat source, as well as to more uniform coating. Testing of the spray dried powder produced by the present spray drying system operated with an inlet drying gas temperature of 90 degrees C. found the powder comparable to that dried in conventional spray drying processes operable at 190 degrees C. Moreover, in some instances, the subject spray drying system can be effectively operated without heating of the drying gas.
Encapsulation efficiency, namely the uniformity of the coating of the dried powder, also was equal to that achieved in higher temperature spray drying. It further was found that lower temperature drying significantly reduced aromas, odors and volatile components discharged into the environment as compared to conventional spray drying, further indicating that the outer surface of the dried particle was more uniformly and completely formed of starch. The reduction of discharging aromas and odors further enhances the working environment and eliminates the need for purging such odors that can be irritating and/or harmful to operating personnel. Lower temperature processing also enables spray drying of temperature sensitive components (organic or inorganic) without damage or adversely affecting the compounds.
If during a drying process any particles may stick or otherwise accumulate on the surface of the liner 100, a liner shaking device is provided for periodically imparting shaking movement to the liner 100 sufficient to remove any accumulated powder. In the illustrated embodiment, the drying chamber 12 has a side pneumatic liner shake valve port 180 which is coupled to a pneumatic tank 181 that can be periodically actuated to direct pressurized air through the pneumatic liner shake valve port 180 and into the annular air space between the liner 100 and the outer wall of the drying chamber 12 that shakes the flexible liner 100 back and forth with sufficient force to dislodge any accumulated powder. Pressurized air preferably is directed to the pneumatic liner shake valve port 180 in a pulsating manner in order to accentuate such shaking motion. Alternatively, it will be understood that mechanical means could be used for shaking the liner 100.
In order to ensure against cross contamination between successive different selective usage of the spray dryer system, such as between runs of different powders in the drying chamber 12, the annular arrays 120, 120a of quick disconnect fasteners 121 enable disassembly of the cover 14 and collection cone 18 from the drying chamber 12 for easy replacement of the liner 100. Since the liner 100 is made of relatively inexpensive material preferably it is disposable between runs of different powders, with replacement of a new fresh replacement liner being affected without undue expense.
In keeping with another important feature of this embodiment, the drying chamber 12 is easily modifiable for different spray drying requirements. For example, for smaller drying requirements, a smaller diameter liner 100a may be used to reduce the size of the effective drying zone. To that end, standoff ring assemblies 104a (
In further enabling more efficient drying of smaller lot runs, the drying chamber 12 has a modular construction that permits reducing the length of the drying chamber 12. In the illustrated embodiment, the drying chamber 12 comprises a plurality, in this case two, vertical stacked cylindrical drying chamber modules or sections 185, 186. The lower chamber section 186 is shorter in length than the upper chamber section 185. The two cylindrical drying chamber sections 185, 186 again are releasably secured together by an array 102b of circumferentially spaced quick disconnect fasteners 121 similar to those described above. The mounting ring 110 for this array 102b of fasteners 121 is welded to the upper cylindrical drying chamber section 185 adjacent the lower end thereof and the fasteners 121 of that array 102b are oriented with the draw hooks 122 downwardly positioned for engaging and retaining an underside of a top outer radial flange 188 (
It will be appreciated that additional cylindrical drying chamber modules or sections 186 could be added to further increase the effective length of the drying chamber 12. For increasing the quantity sprayed liquid into the drying chamber 12, whether or not increased in size, a plurality of electrostatic spray nozzle assemblies 16 can be provided in the top cover 14, as depicted in
According to still another feature of this embodiment, the modular quick disconnect components of the drying tower 11 further enables relocation of the electrostatic spray nozzle assembly 16 from a position on top of the drying chamber 12 for downward spraying to a position adjacent a bottom of the drying chamber 12 for the upward direction of an electrostatically charged liquid spray into the drying chamber 12. To this end, the spray nozzle assembly 16 may be removed from the top cover 14 and secured in a bottom spray nozzle mounting support 195 (
With the electrostatic spray nozzle assembly 16 mounted adjacent the underside of the drying chamber 12, a central spray nozzle mounting aperture 192 in the cover 14 may be appropriately capped, as well as the gas inlet port 15. The powder collection cone 18 further has a tangentially oriented drying gas inlet 215, which may be uncapped and connected to the drying gas recirculation line 165, and the cover 14 in this case has a pair of exhaust ports 216 which also may be uncapped for connection to the heating gas return line.
With the spray nozzle assembly 16 mounted on the underside of the drying chamber 12, electrostatically charged liquid spray particles directed upwardly into the drying chamber 12 are dried by drying gasses, which in this case are tangentially directed through the bottom heating gas inlet 215 and by heating atomizing gas from the spray nozzle assembly 16, which again both are dry inert gas, i.e. nitrogen.
Pursuant to this embodiment, the annular liner 100 in the drying chamber 12 preferably is made of a filter media 100b (
From the foregoing, it can be seen that the processing tower can be easily configured and operated in a variety of processing modes for particular spray applications, as depicted in the table 220 in
While in the foregoing embodiments, nitrogen or other inert drying gas, is introduced into the system as atomizing gas to the electrostatic spray nozzle assembly 16, alternatively, the nitrogen gas could be introduced into the recirculating gas. In the spray dry system as depicted in
With reference to
Referring now to
While the non-permeable liner 100 of the foregoing embodiments, preferably is made of flexible non-conductive material, such as plastic, alternatively it could be made of a rigid plastic material, as depicted in
As a further alternative embodiment, the illustrated spray dryer system can be easily modified, as depicted in
During spray chilling, the atomizing gas heater 152 is turned off so that cool atomizing gas is delivered to the atomizing nozzle 16. During the spray chilling, the drying gas heater 169 also is turned off delivering drying gas that has been cooled by the dehumidification coil 170a to the drying chamber 12 through the drying gas line 165. As the atomized droplets enter the drying gas zone 127 they solidify to form particles that fall into the collection cone 18 and are collected in the collection chamber 19 as the gas stream exits for recirculation. The removable liner 100 again aids in the cleaning of the dryer chamber since it can be removed and discarded. The insulating air gap 101 prevents the drying chamber 12 from becoming cold enough for condensation to form on the outside surface.
In carrying out still a further feature of this embodiment, the spraying system 10 may operate using an automated fault recovery system that allows for continued operation of the system in the event of a momentary charge field breakdown in the drying chamber, while providing an alarm signal in the event of continued electrical breakdown. A flowchart for a method of operating a voltage generator fault recovery method for use in the spraying system 10 is shown in
At times when the voltage supply is determined at 302 to be active, a delay of a predefined time, for example, 5 seconds, is used before the liquid pump is started at 308, and the liquid pump is run at 310 after the delay has expired. A check is performed at 312 for a short or an arc at 312 while the pump continues to run at 310. When a short or arc is detected at 312, an event counter and also a timer are maintained to determine whether more than a predefined number of shorts or arcs, for example, five, have been detected within a predefined period, for example, 30 seconds. These checks are determined at 314 each time a short or arc is detected at 312. When fewer than the predefined shorts or arcs occur within the predefined period, or even if a single short or arc is detected, the liquid pump is stopped at 316, the voltage generator producing the voltage is reset by, for example, shutting down and restarting, at 318, and the liquid pump is restarted at 310 after the delay at 308, such that the system can remediate the fault that caused the spark or arc and the system can continue operating. However, in the event more than the predefined number of sparks or arc occur within the predefined period at 314, an error message is generated at a machine interface at 320 and the system is placed into a standby mode by deactivating the voltage generator and the liquid pump at 306.
In one aspect, therefore, the method of remediating a fault in an electrostatic spray drying system includes starting a pump startup sequence, which entails first determining a state of the voltage generator and not allowing the liquid pump to turn on while the voltage generator has not yet activated. To accomplish this, in one embodiment, a time delay is used before the liquid pump is turned on, to permit sufficient time for the voltage generator to activate. The liquid pump is then started, and the system continuously monitors for the presence of a spark or an arc, for example, by monitoring the current drawn from the voltage generator, while the pump is operating. When a fault is detected, the voltage generator turns off, as does the liquid pump, and depending on the extent of the fault, the system automatically restarts or enters into a standby mode that requires the operator's attention and action to restart the system.
Finally, in carrying out a further aspect of the present embodiment, the spray drying system 10 has a control which enables the charge to the liquid sprayed by the electrostatic spray nozzle assembly to be periodically varied in a fashion that can induce a controlled and selective agglomeration of the sprayed particles for particular spray applications and ultimate usage of the dried product. In one embodiment, the selective or controlled agglomeration of the sprayed particles is accomplished by varying the time and frequency of sprayer activation, for example, by use of a pulse width modulated (PWM) injector command signal, between high and low activation frequencies to produce sprayed particles of different sizes that can result in a varying extent of agglomeration. In another embodiment, the selective or controlled agglomeration of the sprayed particles may be accomplished by modulating the level of the voltage that is applied to electrostatically charge the sprayed fluid. For example, the voltage may be varied selectively in a range such as 0-30 kV. It is contemplated that for such voltage variations, higher voltage applied to charge the fluid will act to generally decrease the size of the droplets, thus decreasing drying time, and may further induce the carrier to migrate towards the outer surfaces of the droplets, thus improving encapsulation. Similarly, a decrease in the voltage applied may tend to increase the size of the droplets, which may aid in agglomeration, especially in the presence of smaller droplets or particles.
Other embodiments contemplated that can selectively affect the agglomeration of the sprayed particles include selectively changing over time, or pulsing between high and low predetermined values, various other operating parameters of the system. In one embodiment, the atomizing gas pressure, the fluid delivery pressure, and the atomizing gas temperature may be varied to control or generally affect particle size and also the drying time of the droplets. Additional embodiments may further include varying other parameters of the atomizing gas and/or the drying air such as their respective absolute or relative moisture content, water activity, droplet or particle size and others. In one particular contemplated embodiment, the dew point temperature of the atomizing gas and the drying air are actively controlled, and in another embodiment, the volume or mass airflow of the atomizing gas and/or the drying air are also actively controlled.
A flowchart for a method of modulating a pulse width in an electrostatic spray nozzle to selectively control the agglomeration of sprayed particles is shown in
In one aspect, therefore, the agglomeration of sprayed particles is controlled by varying the injection time of the sprayer. At high frequencies, i.e., at a high PWM, the sprayer will open and close more rapidly producing smaller particles. At low frequencies, i.e., at the low PWM, the sprayer will open and close more slowly producing larger particles. As the larger and smaller particles make their way through the dryer in alternating layers, some will physically interact and bind together regardless of their repulsing electrical charges to produce agglomerates by collusion. The specific size of the larger and smaller particles, and also the respective number of each particle size per unit time that are produced, can be controlled by the system by setting the respective high and low PWM setpoints, and also the duration for each, to suit each specific application.
In accordance with still a further feature, a plurality of powder processing towers 10 having drying chambers 11 and electrostatic spray nozzle assemblies 16 as described above, may be provided in a modular design, as depicted in
Such a modular processing system has been found to have a number of important advantages. At the outset, it is a scalable processing system that can be tailored to a users requirements, using common components, namely substantially identical processing powder processing towers 10. The system also can easily be expanded with additional modules, as depicted in
From the foregoing, it can be seen that a spray dryer system is provided that is more efficient and versatile in operation. Due to enhanced drying efficiency, the spray dryer system can be both smaller in size and more economical usage. The electrostatic spray system further is effective for drying different product lots without cross-contamination and is easily modifiable, both in size and processing techniques, for particular spray applications. The spray drying system further is less susceptible to electrical malfunction and dangerous explosions from fine powder within the atmosphere of the drying chamber. The system further can be selectively operated to form particles that agglomerate into a form that better facilitates their subsequent usage. The system further has an exhaust gas filtration system for more effectively and efficiently removing airborne particulate matter from drying gas exiting the dryer and which includes automatic means for removing the buildup of dried particulate matter on the filters which can impede operation and require costly maintenance. Yet, the system is relatively simple in construction and lends itself to economical manufacture.
This patent application claims the benefit of U.S. Patent Application No. 62/250,318, filed Nov. 3, 2015, which is incorporated by reference.
Number | Name | Date | Kind |
---|---|---|---|
3011543 | McCormick, Jr. | Jul 1957 | A |
3201924 | Fulford | Aug 1965 | A |
3620776 | Mishkin | Nov 1971 | A |
3675393 | Meade | Jul 1972 | A |
4170074 | Heckman et al. | Oct 1979 | A |
5044093 | Itoh | Sep 1991 | A |
5139612 | Andersen | Aug 1992 | A |
5358552 | Seibert | Oct 1994 | A |
5624530 | Sadykhov | Apr 1997 | A |
5632102 | Luy | May 1997 | A |
6463675 | Hansen | Oct 2002 | B1 |
6695989 | Tsujimoto | Feb 2004 | B1 |
6711831 | Hansen | Mar 2004 | B1 |
8524279 | Snyder | Sep 2013 | B2 |
8533971 | Hubbard, Jr. | Sep 2013 | B2 |
8939388 | Beetz | Jan 2015 | B1 |
8966783 | Kitamura | Mar 2015 | B2 |
20050197487 | Kurashima | Sep 2005 | A1 |
20080155853 | Wang et al. | Jul 2008 | A1 |
20100101737 | Kiekens | Apr 2010 | A1 |
20130312609 | van Vorselen | Nov 2013 | A1 |
20140318087 | Hjelmberg | Oct 2014 | A1 |
Number | Date | Country |
---|---|---|
1350098 | Apr 1974 | GB |
Entry |
---|
International Search Report dated Mar. 16, 2017, in International Patent Application No. PCT/US2016/060376. |
Number | Date | Country | |
---|---|---|---|
20170151576 A1 | Jun 2017 | US |
Number | Date | Country | |
---|---|---|---|
62250318 | Nov 2015 | US |