Drying apparatus and methods

Information

  • Patent Grant
  • 6539645
  • Patent Number
    6,539,645
  • Date Filed
    Tuesday, January 9, 2001
    23 years ago
  • Date Issued
    Tuesday, April 1, 2003
    21 years ago
  • Inventors
  • Examiners
    • Lazarus; Ira S.
    • Rinehart; K. B.
    Agents
    • Reid; John S.
    • Reidlaw, L.L.C.
    • Olson; Thomas A.
Abstract
Apparatus and method for drying a product comprising placing the product on a first side of a support surface, and directing dry radiant heat toward the second side of the surface to heat the product. A sensor can be included to measure at least one characteristic of the product, such as the temperature or moisture content thereof. The temperature of the heat source can be regulated as a function of the measured characteristic. The support surface can also be made so as to be movable relative to the heat source. In an alternative embodiment, a plurality of control zones are defined and through which the product is successively passed. Each of the control zones has at least one associated heat source and an associated sensor so as to regulate the temperature of the heat sources associated with each control zone independently of those associated with another zone.
Description




FIELD OF THE INVENTION




The present invention relates to methods and apparatus for drying a product, and more specifically, to methods and apparatus for drying a product which is in the form of a liquid or paste by removing moisture there from.




BACKGROUND OF THE INVENTION




Prior art drying apparatus and methods have been utilized for drying organic products which are in the form of liquids or semi-liquids such as solutions and colloidal suspensions and the like. These prior art drying apparatus have been used primarily to produce various dried or concentrated foodstuffs and food-related products, as well as nutritional supplements and pharmaceuticals. The liquid products are usually first processed in a concentrator apparatus which employs a high-capacity heat source, such as steain or the like, to initially remove a portion of the moisture from the suspension. Then, the concentrated products are often processed in a prior art drying apparatus in order to remove a further portion of the remaining moisture.




Various types of prior art drying apparatus have been employed, including spray dryers and freeze dryers. While spray dryers are known to provide high processing capacity at a relatively low production cost, the resulting product quality is known to be relatively low. On the other hand, freeze dryers are known to produce products of high quality, but at a relatively high production cost.




In addition to spray dryers and freeze dryers, various forms of belt dryers have been used. Such prior art drying apparatus generally include an elongated, substantially flat, horizontal belt onto which a thin layer of product is spread. The product is usually either in the form of a concentrated liquid or a semi-liquid paste. As the belt slowly revolves, heat is applied to the product from a heat source. The heat is absorbed by the product to cause moisture to evaporate there from. The dried product is then removed from the belt and collected for further processing, or for packaging, or the like.




A typical prior art apparatus and method is disclosed in U.S. Pat. No. 4,631,837 to Magoon. Referring to FIGS. 1 and 2 of the '837 patent which are reproduced in the drawings which accompany the instant application as Prior Art FIGS. 1 and 2, an elongated frame or structure is provided on which an elongated water-tight trough 10 is supported. The trough 10 is preferably made of ceramic tile. An insulation layer 12 is provided on the outer surface of the trough 10. The interior surface of the trough 10 is lined with a thin polyethylene sheet 16. Parallel rollers 24, 26 are provided, with one roller being located at each end of the trough 10. One of the rollers 26 is driven by a motor.




A water heater 15 and circulation system, including a pump and related piping, is also provided with the prior art apparatus of the '837 patent. The water heater 15 is configured to heat a supply of water 14 to just below its boiling point, or slightly less than 100 degrees C. The pump and related piping system is configured to circulate the water 14 through the trough 10 so that a minimum given water depth is maintained throughout the trough. In addition, the water heater 15 and related circulation system is configured to maintain the water supply within the trough at a temperature which is slightly less than 100 degrees C.




A flexible sheet of polyester, infra-red transparent material 18 in the form of an endless belt is supported about the rollers 24, 26 at each end, and is also supported on top of the water supply 14 within the trough 10. That is, the polyester belt 18 is driven by the roller 26 and revolves there about and the roller 24, while floating on the water 14 within the trough 10. A thin layer of liquid product 20 is dispensed onto the revolving belt 18 by way of a product discharge means 28 which is located at an intake end of the apparatus.




As the layer of product 20 travels along the trough 10 on the belt 18 which floats on the water 14, the product is heated by the water 14 which is maintained near 100 degrees C., and on which the belt 18 floats. The heat from the water 14 drives moisture from the product 20 until the product reaches the desired dryness, whereupon the product is removed from the belt 18. The rate at which the belt 18 moves through the trough 10 can be regulated so that the product 20 will reach its desired dryness at the discharge end of the apparatus where it is removed there from.




Several characteristics of the drying apparatus and method disclosed by the '837 patent lead to inconvenient and troublesome use of the apparatus. For example, the trough 10 of a typical prior art apparatus as disclosed by the '837 patent has a length within the range of 12 to 24 meters or more. As a result, the apparatus occupies a relatively large amount of production space. Also, several potential problems regarding the operation of the prior art apparatus can be attributed to the use of water as a heat source.




For example, the prior art apparatus requires a relatively massive water heating and circulation system 15 for its operation. The water heating and circulation system 15 can prove troublesome in several ways. First, the water heating and circulation system 15 adds complexity to the configuration and construction of the apparatus as well as to its operation. The system 15 incorporates a water heater, a pump, and various pipes and valves which must all be maintained in a relatively leak-proof manner. The required water heating and circulation system 15 can also deter the ease of mobility of the prior art dryer because of the bulky nature of the system and because of the need for a water supply.




Secondly, the water 14, which is maintained below the boiling point can serve as a harbor for potentially dangerous microbial organisms which can cause contamination of the product 20. Thirdly, the presence of a large amount of water 14 can serve to counter the objective of the prior art apparatus which is to remove moisture from the product 20. That is, the water 14, by way of inevitable leaks and evaporation from the trough 10, can enter the product 20 thereby increasing the drying time of the product.




Moreover, because the water 14 is the sole source of heat for drying of the product 20, and because the water temperature is maintained below 100 degrees C., the process of drying of the product 20 is relatively slow. As a universally accepted rule, the quantity of heat transferred between two bodies is proportional to the difference in the temperature of each of the bodies. Also, as a general rule, the moisture contained in the product to be dried must absorb a relatively great amount of energy in order to vaporize. The product 20 initially contains a relatively high amount of moisture when it is initially spread onto the support surface 18. Thus, a relatively high amount of heat energy is required to vaporize the moisture and remove it from the product 18.




However, because the temperature of the water heat source of the prior art apparatus never exceeds 100 degrees C., the difference in the temperatures of the heat source and the product 20 is limited which, in turn limits the transfer of heat to the product. As the product 20 absorbs heat from the heat source, the temperature of the product will rise. This rise in temperature of the product as it travels through the apparatus results in an even lower difference in temperature between the product 20 and heat source which, in turn, further reduces the amount of heat transfer from the heat source to the product. For this reason, the prior art apparatus often requires extended processing times in order to satisfactorily remove moisture from the product 20.




Also, the prior art apparatus and method of the '837 patent does not provide for any flexibility in processing temperatures because the temperature of the heat source cannot be easily changed, if at all. For example, the production of some products can benefit from specific temperature profiles during the drying process. The “temperature profile” of a product refers to the temperature of the product as a function of the elapsed time of the drying process. However, because the temperature of the heat source of the prior art apparatus is not only limited to 100 degrees Centigrade, but also slow to change, the temperature profile of the product cannot be easily controlled, or changed.




Because the prior art apparatus disclosed by the '837 patent employs water as a heat source, and requires a large water heating system for its operation, the resulting prior art apparatus is large, heavy, immobile, complex, difficult to maintain, and can be a source of microbial contamination of the product. Additionally, because the temperature of the water heat source utilized by the prior art method and apparatus is limited to less than 100 degrees Centigrade, the prior art method of drying can be slow and inefficient, and does not provide for modification or close control of the product temperature profile.




Therefore it has long been known that it would be desirable to provide a method and apparatus which achieve the benefits to be derived from similar prior art devices, but which avoid the shortcomings and detriments individually associated therewith.




SUMMARY OF THE INVENTION




In accordance with a first embodiment of the invention, an apparatus generally includes a support surface which substantially allows radiant heat to pass there through. The support surface is configured to support a product on a first side thereof, while a dry radiant heat source is exposed to the second side of the support surface. A gap separates the radiant heat source from the support surface. The radiant heat source can direct radiant heat toward the second side which heat passes through the support surface so as to be absorbed by the product for drying thereof. A sensor can be located in a position which is exposed to the first side of the support surface. The sensor is configured to detect and measure at least one characteristic of the product, such as its temperature, moisture content, chemical composition or the like. The measured characteristic can be employed to regulate the temperature, and thus the heat output, of the heat source. Various other embodiments of drying apparatus in accordance with the instant invention which are similar to the first embodiment are discussed as well.




In accordance with a fifth embodiment of the invention, an apparatus includes an elongated chassis, and a support surface movably supported on the chassis. The support surface can preferably be configured as an endless belt which is configured to be moved, or driven, by an actuator. A heater bank, which comprises at least a first dry radiant heat source and a second dry radiant heat source, is supported on the chassis so as to be exposed to the second side of the support surface and to direct radiant heat thereto. A gap separates the heater bank from the support surface. An opposite first side of the support surface is configured to support a product and move the product through a plurality of control zones in succession. At least a first control zone and a second control zone are included in the apparatus. The temperature of each heat source within a given control zone can be regulated independently of the temperature of any other heat source which is outside the given control zone. A plurality of sensors which are configured to detect and measure at least one characteristic of the product can also be included. The sensors can be employed to provide feedback for the regulation of the temperatures of each of the heat sources.




In accordance with a sixth embodiment of the invention, a method of drying a product is provided. The method includes providing a support surface having a first side and an opposite second side. The product is placed on the first side of the surface and radiant heat is directed across a gap to the second side of the surface to dry the product thereon.











DESCRIPTION OF THE DRAWINGS




Preferred embodiments of the invention are described below with reference to the following accompanying drawings.





FIG. 1

is a side elevation diagram of a prior art apparatus.





FIG. 2

is a partial perspective of the prior art apparatus depicted in FIG.


1


.





FIG. 3

is a side elevation diagram of an apparatus in accordance with a first embodiment of the present invention.





FIG. 3A

is a side elevation diagram of an apparatus in accordance with a second embodiment of the present invention.





FIG. 3B

is a side elevation diagram of an apparatus in accordance with a third embodiment of the present invention.





FIG. 3C

is a top plan view of an apparatus in accordance with a fourth embodiment of the present invention.





FIG. 3D

is a side elevation diagram showing an alternative operational control scheme for the apparatus depicted in FIG.


3


.





FIG. 4

is a side elevation diagram of an apparatus in accordance with a fifth embodiment of the present invention.





FIG. 5

is a schematic diagram showing one possible configuration of communication links between the various components of the apparatus depicted in FIG.


4


.











DETAILED DESCRIPTION OF THE INVENTION




The present invention provides for methods and apparatus for drying a product containing moisture. The apparatus generally includes a support surface which is substantially transparent to radiant heat. The product is supported on a first side of the support surface while radiant heat is directed toward a second side of the support surface to heat the product for drying. The apparatus can also generally include a sensor which is configured to detect and measure at least one characteristic of the product, such as temperature or moisture content. The measurement of the product characteristic can be used to regulate the temperature of the heat source so as to radiate a desired quantity of heat to the product.




Referring to

FIG. 3

, a side elevation view of a basic drying apparatus


100


in accordance with a first embodiment of the present invention is depicted. The drying apparatus


100


is generally configured to remove a given amount of moisture from a product “P” to dry or concentrate the product. The product “P” can be in any of a number of types, including aqueous colloidal suspensions, or the like, which can be in the form of a liquid or paste, and from which is moisture is to be removed there from by heating. The product “P” is generally spread, or otherwise placed, onto the apparatus


100


for drying. Once the product “P” has reached the desired dryness, it is then removed from the apparatus


100


.




The apparatus comprises a support surface


110


onto which the product “P” is placed for drying. The support surface


110


has a first side


111


which is configured to support a layer of the product “P” thereon as shown. The support surface also has second side


112


which is opposite the first side


111


. Preferably, the first side


111


is substantially flat and supported in a substantially horizontal manner so that, in the case of a liquid product “P,” a substantially even layer thereof is formed on the first side. In addition, lips


115


can be formed on the edges of the support surface


110


for the purpose of preventing the product “P” from running off the first side


111


of the support surface.




The support surface


110


can be configured as a substantially rigid tray or the like as shown. However, in an alternative embodiment of the present invention which is not shown, the support surface


110


can be a relatively thin, flexible sheet which is supported by a suitable support system or the like. The support surface


110


is configured to allow radiant heat to pass there through from the second side


112


to the first side


111


. The term “radiant heat” means heat energy which is transmitted from one body to another by the process generally known as radiation, as differentiated from the transmission of heat from one body to another by the processes generally known as conduction and convection.




The support surface


110


is fabricated from a material which is substantially transparent to radiant heat and also able to withstand temperatures of up to 300 degrees Fahrenheit. Preferably, the support surface


110


is fabricated from a material comprising plastic. The term “plastic” means any of various nonmetallic compounds synthetically produced, usually from organic compounds by polymerization, which can be molded into various forms and hardened, or formed into pliable sheets or films.




More preferably, the support surface


110


is fabricated from a material selected from the group consisting of acrylic and polyester. Such materials, when utilized in the fabrication of a support surface


110


, are known to have the desired thermal radiation transmission properties for use in the present invention. Further, plastic resins can be formed into a uniform, flexible sheet, or into a seamless, endless belt, which can provide additional benefits.




Also, such materials are known to provide a smooth surface for even product distribution, a low coefficient of static friction between the support surface


110


and the product “P” supported thereon, flexibility, and resistance to relatively high temperatures. In addition, such materials are substantially transparent to radiant heat, have relatively high tensile strengths, and are relatively inexpensive and easily obtained.




The apparatus


100


can also comprise a chassis


120


. The chassis is preferably rigidly constructed and can include a set of legs


122


which are configured to rest on a floor


101


or other suitable foundation, although the legs can also be configured to rest on bare ground or the like. The chassis


120


can also include a bracket


124


, or the like, which is configured to support thereon a dry radiant heat source


130


which is exposed to the second side


112


of the support surface


110


.




The term “exposed to” means positioned such that a path, either direct or indirect, can be established for the transmission of radiant heat energy, wave energy, or electromagnetic energy between two or more bodies. The heat source


130


is configured to direct radiant heat “H” across a gap “G” and toward the second side


112


of the support surface


110


.




The term “dry radiant heat source” means a device which is configured to produce and emit radiant heat, as well as direct the radiant heat across a gap to another body, without the incorporation or utilization of any liquid heating medium or substance of any kind, including water. The term “gap” means a space which separates two bodies between which heat is transferred substantially by radiation and wherein the two bodies do not contact one another.




Since the apparatus


100


does not employ water, or other liquid, as a heating source or heating medium, the apparatus


100


is greatly simplified over prior art apparatus which do employ liquid heating media. In addition, the absence of a liquid heat medium in the apparatus


100


provides additional benefits.




For example, the absence of a water heating medium decreases likelihood of microbial contamination of the product “P” as well as the likelihood of re-wetting the product. Moreover, the absence of liquid heating medium and associated heating/pumping system enables the apparatus


100


to be moved and set up relatively easily and quickly which can provide benefits in such applications as on-site field harvest/processing.




The dry radiant heat source


130


is preferably configured to direct radiant heat “H” toward the second side


112


of the support surface


110


. Preferably, the dry radiant heat source


130


is positioned relative to the support surface


110


such that the second side


112


thereof is directly exposed to the radiant heat source. However, in an alternative embodiment of the present invention which is not shown, reflectors or the like can be employed to direct the radiant heat “H” from the radiant heat source


130


to the second side


112


of the support surface


110


. Also, although it is preferable for the heat source


130


to be positioned so as to direct heat “H” toward the second side


112


, it is understood that the heat source can be positioned so as to direct heat toward the first side


111


, and thus directly at the product “P” in accordance with other alternative embodiments of the present invention which are not shown.




Preferably, the radiant heat source


130


is configured to operate using either electrical power or gas. The term “gas” means any form of combustible fuel which can include organic or petroleum based products or by-products which are either in a gaseous or liquid form. More preferably, the radiant heat source


130


is selected from the group consisting of gas radiant heaters and electric heaters. The term “gas radiant heaters” means devices which produce substantially radiant heat by combusting gas. The term “electric radiant heaters” means devices which produce substantially radiant heat by drawing electrical current. Various forms of such heaters are known in the art. The use of such heaters as the heat source


130


can be advantageous because of the several benefits associated therewith.




For example, such heaters can attain high temperatures and can produce large quantities of radiant heat energy. Such heaters can attain temperatures of at least 100 degrees Centigrade and can attain temperatures significantly greater than 100 degrees Centigrade. The high temperatures attainable by these heaters can be beneficial in producing large amounts of heat energy. In addition, the temperature of the heater, and thus the amount of radiant heat energy produced, can be relatively quickly changed and can be easily regulated by proportional modulation thereof. Also, such heaters generally tend to be relatively light in weight compared to other heat sources, and are generally resistant to shock and vibration.




Since electric radiant heaters such as quartz heaters and ceramic heaters draw electrical power for operation, such heaters can be operated either from a portable generator, or from a permanent electrical power grid. Similarly, radiant gas heaters can be operated either from a portable gas supply, such as a liquified natural gas tank, or from a gas distribution system such as an underground pipeline system. Furthermore, heaters such as those discussed above are generally known to provide long, reliable operating life and can be serviced easily.




The radiant heat source


130


is preferably configured to reach a temperature greater than 100 degrees, Centigrade, and more preferably, the heat source is configured to reach a temperature significantly greater than 100 degrees, Centigrade, such as 150 degrees, Centigrade. The radiant heat source


130


can be configured to vary the amount of radiant heat that is directed toward the support surface


110


. That is, the radiant heat source


130


can be configured to modulate the amount of heat that it directs toward the support surface


110


.




Preferably, the radiant heat source


130


can be configured modulate so that the temperature thereof can be increased or decreased in a rapid manner. The heat source


130


can be configured to modulate by employing an “on/off” control scheme. Preferably, however, the heat source can be configured to modulate by employing a true proportional control scheme.




To facilitate the operational control of the heat source


130


, the apparatus


100


can include a control device


131


which is connected to the heat source. The control device


131


can be an electrical relay as in the case of an electrically powered heat source


130


. Alternatively, the control device


131


can be a servo valve as in the case of a gas powered heat source


130


.




The support surface


110


can be configured to be movable with respect to the radiant heat source


130


. For example, the support surface


110


can be configured as a movable tray which can be placed onto, and removed from, the chassis


120


as shown in FIG.


3


. In an alternative configuration of the first embodiment of the invention, the chassis


120


can include rollers or the like on which the support surface


110


can be supported and moved.




For example, referring to

FIG. 3A

, a side elevation diagram is shown of an apparatus


100


A in accordance with a second embodiment of the present invention. As is evident, the support surface


110


A of the apparatus


100


A is configured as an endless belt comprising a flexible sheet supported by rollers


123


. The support surface


110


A can be configured to move, or circulate, in the direction “D.”




The rollers


123


are, in turn, supported by the chassis


120


A which also supports at least one heat source


130


. The heat source


130


is configured to direct radiant heat “H” toward the second side


112


of the support surface


110


A. Opposite the second side


112


, is the first side


111


of the support surface


110


A which is configured to movably support the product “P” thereon. As is seen, the configuration of the apparatus


100


A can provide for continuous processing of the product “P.”




Turning now to

FIG. 3B

, a side elevation diagram is shown which depicts an apparatus


100


B in accordance with a third embodiment of the present invention which is similar to the apparatus


100


A discussed above for FIG.


3


A. However, the support surface


110


B of the apparatus


100


B is not only configured as an endless belt, but also comprises a plurality of rigid inks


113


which are pivotally connected to one another in a chain-like manner.




As shown, the apparatus


100


B comprises a chassis


120


which rotatably supports rollers


123


thereon. The rollers


123


in turn movably support the support surface


110


B thereon, which can be configured to move, or circulate, in the direction “D.” The chassis


120


also supports a heat source


130


thereon which is configured to direct radiant heat “H” toward the second side


112


of the support surface


110


B. The support surface


110


B is configured to support the product “P” on the first side


111


which is opposite the second side


112


.




Moving to

FIG. 3C

, a top plan view is shown of an apparatus


100


C in accordance with a fourth embodiment of the present invention. In accordance with the apparatus


100


C, the support surface


110


C is substantially configured as a flat, horizontal ring which is configured to rotate in the direction “R.” The support surface


110


C can be configured to rotate in the direction “R” about a center portion


114


which can comprise a bearing (not shown) or the like. The upper, or first, side


111


of the support surface


110


A is configured to support the product “P” thereon.




The product “P” can be placed onto the first side


111


of the support surface


110


A at an application station


140


, and can be removed from the support surface at a removal station


142


. At least one heat source (not shown) can be positioned beneath the support surface


110


A such that radiant heat (not shown) is directed from the heat source to a lower, or second, side (not shown) which is opposite the first side


111


.




Returning now to

FIG. 3

, the apparatus


100


can comprise a controller


150


such as a digital processor or the like for executing operational commands. The controller can be in communication with the radiant heat source


130


by way of the control device


131


as well as at least one communication link


151


. The communication link


151


can include either wire communication, or wireless communication means. The term “in communication with” means capable of sending or receiving data or commands in the form of signals which are passed via the communication link


151


.




The apparatus


100


can also comprise a sensor


160


which can be supported by a ceiling


102


or other suitable support, and which can be in communication with the controller


150


by way of a communication link


151


. The sensor


160


is configured to detect and measure at least one characteristic of at least a portion of the product “P.” The characteristic can include, for example, the temperature of the product “P,” the moisture content of the product, or the chemical composition of the product. The sensor


160


can be any of a number of sensor types which are known in the art. Preferably, the sensor


160


is either an infrared detector, or a bimetallic sensor.




The apparatus


100


can further include an operator interface


170


which is in communication with the controller


150


and which is configured to allow an operator to input commands or data into the controller


150


by way of a keypad or the like


172


which can be included in the operator interface. The operator interface


170


can also be configured to communicate information regarding the operation of the apparatus


100


to the operator by way of a display screen or the like


171


which can also be included in the operator interface. The controller can include an algorithm


153


which can be configured to automatically carry out various steps in the operation of the apparatus


100


. The controller


150


can farther include a readable memory


155


such as a digital memory or the like for storing data.




During operation of the apparatus


100


, the product “P” can be placed upon the first side


111


of the support surface


110


. Various means of placing the product “P” upon the first side


111


can be employed, including spraying, dripping, pouring, and the like. The operator of the apparatus


100


can input various data and commands to the controller


150


by way of the operator interface


170


. These data and commands input by the operator can include the type of product “P” to be processed, the temperature profile to be maintained in the product, as well as “start” and “stop” commands.




The algorithm


153


can include at least one predetermined heat curve which is associated with at least one particular product “P.” The term “heat curve” means a locus of values associated with the amount of heat produced by the heat source


130


and which locus of values is a function of elapsed time. After the operator identifies the particular product “P” and inputs this into the controller


150


, the drying process, in accordance with temperature parameters dictated by the predetermined heat profile, can be carried out automatically. In addition, the drying process can be adjusted “on the fly” based on inputs from the sensor


160


received by the controller during the process, as described below.




Once the drying operation begins, the sensor


160


can detect and measure at least one characteristic of at least a portion of the product “P” such as the temperature, moisture content, or chemical composition thereof. The sensor


160


can be instructed by the controller


150


, or otherwise configured, to repeatedly perform the detection and measurement of a characteristic of the product “P” at given intervals during the operation of the apparatus


100


. Alternatively, the sensor


160


can be configured to continuously detect and measure the characteristic during the operation of the apparatus


100


.




The measured characteristic which is detected and measured by the sensor


160


can be converted into a signal, such as a digital signal, and can then transmitted to the controller


150


by way of one of the communication links


151


. The controller


150


can then receive the signal sent by the sensor


160


, and can then store the signal as readable data in the readable memory


155


. The controller


150


can then cause the algorithm


153


to be activated, wherein the algorithm can access the data in the readable memory


155


and then use the data to initiate an automatic operational command.




For example, the controller


150


can use the signal data sent by the sensor


160


to control the radiant heat source


130


. That is, the controller


150


can use the signal data from the sensor


160


to control the amount of radiant energy “H” directed toward the support surface


110


. This can be accomplished in various manners such as by turning the heat source on or off for specific time intervals, or by proportionally modulating the heat output produced by the energy source


130


.




In a typical drying operation, for example, a product “P” can be placed onto the first side


111


of the support surface


110


as shown so as to be supported thereon. The operator can, by way of the interface


170


, communicate to the controller


150


the type of product “P” which is to be dried. Alternatively, the operator can enter other data such as the estimated moisture content, or the like, of the product “P.” The operator can also cause the apparatus


100


to commence a drying operation by entering a “start” command into the interface


170


.




When the drying operation commences, the sensor


160


can detect and measure a characteristic of the product “P” such as the temperature, moisture content, or chemical composition thereof. The sensor


160


can then convert the measurement of the characteristic to a signal and then send the signal to the controller


150


. For example, if the measured characteristic is the temperature of the product, then the sensor can send to the controller


150


a signal which contains data regarding the temperature of the product.




The controller


150


can use the data sent by the sensor


160


to regulate various functions of the apparatus


100


. That is, the controller


150


can regulate the amount of radiant heat “H” produced by the radiant heat source


130


and directed to the product “P” as a function of the characteristic detected and measured by the sensor


160


.




The controller


150


can also regulate the amount of radiant heat “H” produced by the radiant heater


130


as a function of elapsed time, as well as the particular type of product “P” which is to be dried. In alternative embodiments such as those described above for

FIGS. 3A

,


3


B, and


3


C, wherein the support surface


110


is configured to move the product “P” past the heat source


130


, the controller


150


can regulate the speed at which the support surface


110


, and thus the product, moves past the heat source.




The particular type of product “P” to be dried can have an optimum profile associated therewith, which, when adhered to, can optimize a given production result such as minimum drying time, or maximum quality of the product “P.” The term “profile” means a locus of values of one or more measured product characteristics as a function of elapsed time. For example, a given product “P” can have associated therewith a given optimum temperature profile, an optimum moisture content profile, or an optimum chemical composition profile. The readable memory


155


can store optimum profiles for several types of products “P.” Each of the stored optimum profiles can then be accessed by the algorithm


153


in accordance with instructions or commands entered into the controller


150


by the operator.




For example, the particular product “P” to be dried, for example, can have an optimum temperature profile that dictates an increase in the temperature of the product at a maximum rate possible and to a temperature of 100 degrees Centigrade. The optimum temperature profile can further dictate that, once the product “P” attains a temperature of 100 degrees Centigrade, the product temperature is to be maintained at 100 degrees Centigrade for an elapsed time of five minutes, after which the temperature of the product “P” is to decrease at a substantially constant rate to ambient temperature over an elapsed time of ten minutes.




The algorithm


153


can attempt to maintain the actual temperature of the product “P” so as to substantially match the optimum temperature profile stored in the a given temperature profile of the product “P” by regulating the amount of heat energy “H” produced by the heat source


130


. For example, in order to cause the temperature of the product “P” to increase rapidly so as to substantially match the optimum temperature profile, the algorithm


153


can cause the radiant heat source


130


to initially produce maximum output of radiant heat “H.” This can be accomplished by causing the temperature of the heat source to increase rapidly to a relatively high level.




The heat energy “H” is directed from the heat source


130


to the second side


112


of the support surface


110


. Because the support surface


110


in configured to allow the radiant heat “H” to pass there through, the product “P” will absorb at least a portion of the radiant heat. The absorption of the heat energy “H” by the product “P” results in an increased temperature of the product which, in turn, promotes moisture evaporation from the product. When the sensor


160


detects that the product “P” has reached a given temperature, such as 100 degrees Centigrade, the algorithm


153


can then begin a first elapsed time countdown having a given duration, such as five minutes.




During the first countdown, the algorithm


153


, in conjunction with temperature measurements received from the sensor


160


, can regulate the amount of heat output “H” produced by the radiant heat source


130


in order to maintain the temperature of the product “P” at a given temperature, such as 100 degrees Centigrade. For example, as moisture evaporates from the product “P,” the product can require less heat energy “H” to maintain a given temperature. At the end of the first countdown, the algorithm


153


can then begin a second elapsed time countdown having a given duration, such as ten minutes.




During the second countdown, the algorithm


153


can control the heat output “H” of the radiant heat source


130


in accordance with the temperature measurements received from the sensor


160


in order to maintain an even decrease in the product temperature from, for example, 100 degrees Centigrade to ambient temperature, whereupon the drying operation is complete. Once the product “P,” attains ambient temperature, or another given temperature, controller


150


can send a signal to the operator interface


170


which, in turn, can generate an audible or visual signal detectable by the operator. This audible or visual signal can alert the operator that the drying operation is complete. The operator can then remove the finished, dried product “P” from the apparatus


100


.




Moving now to

FIG. 3D

, a side elevation diagram is shown of an apparatus


100


D which is is an alternate configuration in accordance with the first embodiment. The apparatus


100


D depicts an alternative control scheme which can be used in place ofthat depicted in

FIG. 3

for the apparatus


100


. In accordance with the alternative control scheme which is depicted in

FIG. 3D

, the apparatus


100


D can comprise a display


177


and a manual heat source control


178


. The display


177


is connected to the sensor


160


by way of a communication link


151


. The display is configured to display data relating to at least on characteristic of the product “P” which is detected and measured by the sensor


160


.




The manual heat source control


178


is connected to the relay


131


by way of another communication link


151


. The manual heat source control


178


is configured to receive operator input commands relating to the amount of heat “H” produced by the heat source


130


. That is, the manual heat source control


178


can be set by the operator to cause the heat source


130


to produce a given amount of heat “H.”




In operation, the operator can initially set the manual heat source control


178


to cause the heat source


130


to produce a given amount of heat “H.” The manual heat source control


178


then sends a signal to the relay


131


by way of a communication link


151


. The relay


131


then receives the signal and causes the heat source


130


to produce the given amount of heat “H.” The operator then monitors the display


177


.




The sensor


160


can continually detect and measure a given characteristic of the product “P.” The sensor can send a signal to the display


177


which relates to the measured characteristic. The display receives the signal and converts the signal to a value which it displays and which is readable by the operator. The operator can then adjust the heat “H” produced by the heat source


130


in response to the information relating to the measured characteristic which is read from the display


177


.




As is seen, the apparatus


100


, as well as the various other configurations thereof and related embodiments, can allow for much greater control of the amount of heat that is transferred to the product than can the various apparatus of the prior art. Because of this, the apparatus


100


of the present invention can produce products “P” having higher quality, and can produce the products in a more efficient manner, than the drying apparatus of the prior art.




As is further seen, the apparatus


100


can be suited for “batch” type of drying processes in which case the support surface


110


is not moved during the drying operation. In alternative embodiments such as those depicted in

FIGS. 3A

,


3


B, and


3


C, the support surface


110


can be configured to move the product “P” past the radiant heat source


130


and sensor


160


, in which case a continuous drying process can be attained. In yet another embodiment of the present invention, which is described below, an apparatus


200


can be particularly suitable for producing a high-quality product in a high-output, continuous drying process.




Referring to

FIG. 4

, a side elevation view of a drying apparatus


200


in accordance with a fifth embodiment of the present invention is depicted. The apparatus


200


comprises a chassis


210


which can be a rigid structure comprising various structural members including legs


212


and longitudinal frame rails


214


connected thereto. The legs


212


are configured to support the apparatus


200


on a floor


201


or other suitable base.




The chassis


210


can also comprise various other structural members, such as cross-braces (not shown) and the like. The chassis


210


can be generally constructed in accordance with known construction methods, including welding, fastening, forming and the like, and can be constructed from known materials such as aluminum, steel and the like. The apparatus


200


is generally elongated and has a first, intake end


216


, and an opposite, distal, second, out feed end


218


.




The apparatus


200


can further comprise a plurality of substantially parallel, transverse idler rollers


220


which are mounted on the chassis


210


and configured to rotate freely with respect thereto. At least one drive roller


222


can also be included in the apparatus


200


and can be supported on the chassis


210


in a substantially transverse manner as shown.




An actuator


240


, such as an electric motor, can be included in the apparatus


200


as well, and can be supported on the chassis


210


proximate the drive roller


222


. A drive linkage


240


can be employed to transfer power from the actuator


240


to the drive roller


222


. A speed controller


244


, such as an alternating current (“A/C”) variable speed control device or the like, can be included to control the output speed of the actuator


240


.




The apparatus


200


comprises a support surface


230


, which has a first side


231


and an opposite second side


232


. The support surface


230


is movably supported on the chassis


210


. The support surface


230


is configured to allow radiant heat energy to pass there through from the second side


212


to the first side


211


.




Preferably, the support surface


230


is fabricated from a material comprising plastic. More preferably, the support surface


230


is fabricated from a material selected from the group consisting of acrylic and polyester. Also, preferably, the support surface


230


is configured to withstand temperatures of up to at least


300


degrees Fahrenheit. The support surface


230


is configured as an endless flexible belt as shown, at least a portion of which can preferably be substantially flat and level.




As an endless belt form, the support surface


230


is preferably supported on the idler rollers


220


and drive roller


222


. The support surface


230


can be configured to be driven by the drive roller


222


so as to move, or circulate, in the direction “D” relative to the chassis


210


. As is seen, the support surface


230


can be configured so as to extend substantially from the intake end


216


to the out feed end


218


. A take up device


224


can be supported on the chassis


210


and employed to maintain a given tension on the support surface


230


.




The first side


231


of the support surface


230


is configured to support a layer of product “P” thereon as shown. The first side


231


is further configured to move the product “P” substantially from the intake end


216


to the out feed end


218


. The product “P” can be in one of many possible forms, including liquid colloidal suspensions, solutions, syrups, and pastes. Is the case of a liquid product “P” having a relatively low viscosity, an alternative embodiment of the apparatus which is not shown can include a longitudinal, substantially upwardly-extending lip (similar to the lip


115


shown in

FIG. 3

) which can be formed on each edge of the support surface


230


to prevent the product from running off.




The product “P” can be applied to the first side


231


of the support surface


230


by an application device


252


which can be included in the apparatus


200


and which can be located proximate the intake end


216


of the apparatus


200


. In the case of a liquid product “P,” the product can be applied to the support surface


230


by spraying, as shown. Although

FIG. 4

depicts a spraying method of applying the product “P” to the support surface


230


, it is understood that other methods are equally practicable, such as dripping, brushing, and the like.




A removal device


254


can also be included in the apparatus


200


. The removal device


254


is located proximate the out feed end


218


, and is configured to remove the product “P” from the support surface


230


. The product “P” can be in a dry or semi-dry state when removed from the support surface


230


by the removal device


254


.




The removal device


254


can comprise a sharp bend in the support surface


230


as shown. That is, as depicted, the removal device


254


can be configured to cause the support surface


230


to turn sharply around a corner having a radius which is not more than about twenty times the thickness of the support surface


230


. Also, preferably, the support surface


230


forms a turn at the removal device


254


which turn is greater than 90 degrees. More preferably, the turn is about between 90 degrees and 175 degrees.




The type of removal device


254


which is depicted can be particularly effective in removing certain types of product “P” which are substantially dry and which exhibit substantially self-adherence properties. It is understood, however, that other configurations of removal devices


254


, which are not shown, can be equally effective in removing various forms of product “P” from the support surface, including scraper blades, low frequency vibrators, and the like. As the product “P” is removed from the support surface


230


at the out feed end


218


, a collection hopper


256


can be employed to collect the dried product.




The apparatus


200


comprises a heater bank


260


which is supported on the chassis


210


. The heater bank


260


comprises one or more first heat sources


261


and one or more second heat sources


262


. The heater bank


260


can also comprise one or more third heat sources


263


and at least one pre-heater heat source


269


. The heat sources


261


,


262


,


263


,


269


are supported on the chassis


210


and are configured to direct radiant heat “H” across a gap “G” and toward the second side


232


of the support surface


230


.




Each of the heat sources


261


,


262


,


263


,


269


are dry radiant heat sources as defined above for FIG.


3


. The heat sources


261


,


262


,


263


,


269


are preferably selected from the group consisting of gas radiant heaters and electric radiant heaters. Furthermore, each of the heat sources


261


,


262


,


263


,


269


is preferably configured to modulate, or incrementally vary, the amount of radiant heat produced thereby in a proportional manner. The operation of the heat sources


261


,


262


,


263


,


269


is more fully described below.




The apparatus


200


can comprise an enclosure


246


, such as a hood or the like, which is employed to cover the apparatus. The enclosure


246


can be configured to contain conditioned air “A” which can be introduced into the enclosure through an inlet duct


226


. Before entering the enclosure, the conditioned air “A” can be processed in air conditioning unit (not shown) so as to have a temperature and humidity which is beneficial to drying of the product “P.” The conditioned air “A” can circulate through the enclosure


246


before exiting the enclosure by way of an outlet duct


228


. Upon exiting the enclosure


246


, the conditioned air “A” can be returned to the air conditioning unit, or can be vented to exhaust.




The apparatus


200


can further comprise a first sensor


281


, a second sensor


282


, and a third sensor


283


. It is understood that, although three sensors


281


,


282


,


283


are depicted, any number of sensors can be included in the apparatus


200


. Each of the sensors


281


,


282


,


283


can be supported on the enclosure


246


, or other suitable structure, in a substantially evenly spaced manner as shown. Each of the sensors


281


,


282


,


283


can be any of a number of sensor types which are known in the art. Preferably, in the case of detecting temperature of the product “P,” each of the sensors


281


,


282


,


283


is either an infrared detector or a bimetallic sensor.




Preferably, the sensors


281


,


282


,


283


are positioned so as to be substantially exposed to the first side


231


of the support surface


230


. The sensors


281


,


282


,


283


are configured to detect and measure at least one characteristic of the product “P” while the product is movably supported on the first side


231


of the support surface


230


. Characteristics of the product “P” which are detectable and measurable by the sensors


281


,


282


,


283


can include the temperature, moisture content, and chemical composition of the product. Operational aspects of the sensors


281


,


282


,


283


are more fully described below.




The apparatus


200


can comprise a controller


250


for controlling various functions of the apparatus during operation thereof. The controller


250


can include any of a number of devices such as a processor (not shown), a readable memory (not shown), and an algorithm (not shown). The controller


250


will be discussed in further detail below. In addition to the controller


250


, the apparatus


200


can include an operator interface


235


which can be in communication with the controller.




The operator interface


235


can be configured to relay information regarding the operation of the apparatus


200


to the operator by way of a display screen


237


such as a CRT or the like. Conversely, the operator interface


235


can also be configured to relay data or operational commands from the operator to the controller


250


. This can be accomplished by way of a keypad


239


or the like which can also be in communication with the controller


250


.




As is seen, a plurality of control zones Z


1


, Z


2


, Z


3


are defined on the apparatus


200


. That is, the apparatus


200


includes at least a first control zone Z


1


, which is defined on the apparatus between the intake end


216


and the out feed end


218


. A second control zone Z


2


is defined on the apparatus


200


between the first control zone Z


1


and the out feed end


218


. The apparatus


200


can include additional control zones as well, such as a third control zone Z


3


which is defined on the apparatus between the second control zone Z


2


and the out feed end. Each control zone Z


1


, Z


2


, Z


3


is defined to be stationary relative to the chassis


210


.




A study of

FIG. 4

will reveal that each first heat source


261


, as well as the first sensor


281


are located within the first control zone Z


1


. Likewise, each second heat source


262


, and the second sensor


282


, are located within the second control zone Z


2


. Each third heat source


263


, and the third sensor


283


, are located within the third control zone Z


3


. It is further evident that the support surface


230


moves the product “P” through each of the control zones Z


1


, Z


2


, Z


3


. That is, as the actuator


240


moves the support surface


230


in the direction “D,” a given portion of the product “P” which is supported on the support surface, is moved successively through the first control zone Z


1


and then through the second control zone Z


2


.




After being moved through the second control zone Z


2


, the given portion of the product “P” can then be moved through the third control zone Z


3


and on to the removal device


254


. As is seen, at least a portion of the heater bank


260


, such as the pre-heater heat source


269


, can lie outside any of the control zones Z


1


, Z


2


, Z


3


. Furthermore, a cooling zone


248


can be defined relative to the chassis


210


and proximate the out feed end


218


of the apparatus


200


. The cooling zone


248


can be configured to employ any of a number of known means of cooling the product “P” as the product passes through the cooling zone.




For example, the cooling zone


248


can be configured to employ a refrigerated heat sink (not shown) such as a cold black body, or the like, which is exposed to the second side


232


of the support surface


230


and which positioned within the cooling zone. Such a heat sink can be configured to cool the product “P” by radiant heat transfer from the product and through the support surface


230


to the heat sink. One type of heat sink which can be so employed can be configured to comprise an evaporator coil which is a portion of a refrigeration system utilizing a fluid refrigerant such as Freon or the like.




It is understood that the cooling zone


248


can have a relative length which is different than depicted. It is further understood that other means of cooling can be employed. For example, the cooling zone


248


can be configured to incorporate a convection cooling system (not shown) in which cooled air is directed at the second side


232


of the support surface


230


. Furthermore, the cooling zone


248


can be configured to incorporate a conductive cooling system (not shown) in which refrigerated rollers or the like contact the second side


232


of the support surface


230


.




The operation of the apparatus


200


can be similar to that of the apparatus


100


in accordance with the first embodiment of the present invention which is described above for

FIG. 3

, except that the product “P” is moved continuously past the heat sources


261


,


262


,


263


,


269


and sensors


281


,


282


,


283


. As depicted in

FIG. 4

, the product “P” can be applied to the first side


231


of the moving support surface


230


proximate the intake end


216


.




The support surface


230


is driven by the actuator


240


by way of the drive link


242


and is drive roller


222


so as to revolve in the direction “D” about the idler rollers


220


. The product “P” can be in a substantially liquid state when applied to the support surface


230


by the application device


252


. The product “P,” which is to be dried by the apparatus


200


, is fed there through in the feed direction “F” toward the out feed end


218


.




The product “P,” while supported on the support surface


230


and moved through the apparatus


200


in the direction “F,” passes the heater bank


260


which can be positioned in substantially juxtaposed relation to the second side


232


of the support surface so as to be exposed thereto as shown. The heater bank


260


comprises one or more first heat sources


261


and one or more second heat sources


262


which are configured to direct radiant heat “H” toward the second side


232


and through the support surface


230


to heat the product “P” which is moved in the direction “F.”




The heater bank


260


can also comprise one or more third heat sources


263


and one or more pre-heater heat sources


269


which are also configured to direct radiant heat “H” toward the second side


232


to heat the product “P.” The product “P,” while moving on the support surface


230


in the feed direction “F,” is dried by the radiant heat “H” to a desired moisture content, and then removed from the support surface at the out feed end


218


by the removal device


254


.




The product “P,” once removed from the support surface


230


, can be collected in a collection hopper


256


or the like for storage, packaging, or further processing. The support surface


230


, once the product “P” is removed there from, returns to the intake end


216


whereupon additional product can be applied by the application device


252


.




In order to promote efficient product drying as well as high product quality, conditioned air “A” can be provided by an air conditioning unit (HVAC)


245


, and can be circulated about the product “P” by way of the enclosure


246


, intake duct


226


, and outlet duct


228


as the product is moved through the apparatus


200


in the feed direction “F” concurrent with the direction of the movement of the product.




As a further enhancement to production rate and product quality, a plurality of control zones can be employed. The term “control zone” means a stationary region defined on the apparatus


200


through which the product “P” is moved and in which region radiant heat is substantially exclusively directed at the product by one or more dedicated heat sources which are regulated independently of heat sources outside of the region. That is, a given control zone includes a dedicated servomechanism for controlling the amount of heat directed at the product “P” which is within the given control zone, wherein the amount of heat is a function of a measured characteristic of the product.




As is seen, the support surface


230


is configured to move the product “P” in succession through a first control zone Z


1


, and then through a second control zone Z


2


. This can be followed by a third control zone Z


3


. Within the first control zone Z


1


, one or more first heat sources


261


direct radiant heat “H” across the gap “G” toward the product “P” as the product moves through the first control zone. Likewise, within the second control zone Z


2


and within the third control zone Z


3


, one or more second heat sources


262


and one or more third heat sources


263


, respectively, direct radiant heat “H” across the gap “G” toward the product “P” as the product moves through the second and third control zones, respectively.




The temperature of, and thus the amount of heat “H” produced by, the first radiant heat sources


261


is regulated independently of the temperature of, and amount of heat produced by, the second heat sources


262


. Similarly, the third heat sources


263


are regulated independently of the first and second heat sources


261


,


262


. The use of the control zones Z


1


, Z


2


, Z


3


can provide for greater control of production parameters as compared to prior art devices.




That is, specific product profiles and heat curves can be attained with the use of the apparatus


200


because the product “P” can be exposed to different amounts of heat “H” in each control zone Z


1


, Z


2


, Z


3


. Specifically, for example, the first heat sources


261


can be configured to produce heat “H” at a first temperature. The second heat sources


262


can be configured to produce heat “H” at a second temperature which is different from the first temperature. Likewise, the third heat sources


263


can be configured to produce heat “H” at a third temperature.




Thus, as the product “P” proceeds through the apparatus in the feed direction “F,” the product can be exposed to a different amount of heat “H” in each of the control zones Z


1


, Z


2


, Z


3


. This can be particularly useful, for example, in decreasing the drying time of the product “P” as compared to drying times in prior art apparatus. This can be accomplished by rapidly attaining a given temperature of the product “P” and then maintaining the given temperature as the product proceeds in succession through the control zones Z


1


, Z


2


, Z


3


. The use of the control zones Z


1


, Z


2


, Z


3


can also be useful in providing tight control of the amount of heat “H” which is transmitted to the product “P” so as to provide greater product quality. That is, product quality can be enhanced by utilizing the control zones Z


1


, Z


2


, Z


3


to minimize over-exposure and under-exposure of the product “P” to heat energy “H.”




Assuming a given product “P” is relatively moist and at ambient temperature when placed onto the support surface


230


by the application device


252


, arelatively large amount of heat “H” is required to raise the temperature of the product to a given temperature such as 100 degrees Centigrade. Thus, a pre-heater heat source


269


can be employed to pre-heat the product “P” before the product enters the first control zone Z


1


. The pre-heater heat source


269


can be configured to continually produce radiant heat “H” at a maximum temperature and to direct a maximum amount of heat “H” to the product “P.”




As the product “P” enters the first control zone Z


1


, the first heat sources


261


within the first control zone Z


1


can be configured to produce an amount of heat “H” which sufficient to attain the given desired product temperature. The first sensor


281


, in conjunction with the controller


250


, can be employed to regulate the temperature of the first heat sources


261


in order to transfer the desired amount of heat “H” to the product “P.” The first sensor


281


is configured to detect and measure at least one given characteristic of the product “P” while the product is within the first control zone Z


1


. For example, the first sensor


281


can be configured to detect and measure the temperature of the product “P” while the product is within the first control zone Z


1


.




The first sensor


281


can detect and measure a characteristic of the product “P” while the product is in the first control zone Z


1


and then relay that measured characteristic to the controller


250


. The controller


250


can then use the measurement from the first sensor


281


to modulate the temperature, or heat output, of the first heat sources


261


. That is, the heat “H” produced by the first heat sources


261


can be regulated as a function of a measured product characteristic of the product “P” within the first control zone Z


1


as detected and measured by the first sensor


281


. This measured product characteristic can include, for example, the temperature of the product.




The second sensor


282


is similarly employed to detect and measure at least one characteristic of the product “P” while the product is within the second control zone Z


2


. Likewise, the third sensor


283


can be employed to detect and measure at least one characteristic of the product “P” while the product is within the third control zone Z


3


.




The product characteristics detected and measured by the second and third sensors


282


,


283


within the second and third control zones Z


2


, Z


3


, respectively, can be likewise utilized to modulate the amount of heat “H” produced by the second and the third heat sources


262


,


263


to maintain a specific temperature profile of the product “P” as the product progresses through each of the control zones.




In the case wherein the product “P” is heated rapidly to a given temperature and then maintained at the given temperature, the first heat sources


261


will likely produce heat “H” at a relatively high temperature in order to rapidly increase the product temperature to the given temperature by the time the product “P” leaves the first zone Z


1


. Assuming that the product “P” is at the given temperature when entering the second control zone Z


2


, the second and third heat sources


262


,


263


will produce heat “H” at a successively lower temperatures because less heat “H” is required to maintain the temperature of the product as the moisture content thereof decreases.




As mentioned above, the sensors


281


,


282


,


283


can be configured to detect and measure any of a number of product characteristics, such as moisture content. This can be particularly beneficial to the production of a high-quality product “P.” For example, in the above case wherein the product temperature has reached the given temperature as the product “P” enters the second control zone Z


2


, the second and third sensors


282


,


283


can detect and measure product moisture content as the product progresses through the respective second and third control zones Z


2


, Z


3


.




If the second sensor


282


detects and measures a relatively high product moisture content of the product “P” within the second control zone Z


2


, then the controller


250


can modulate the second heat sources


262


so as to continue to maintain the product temperature at the given temperature in order to continue drying of the product. However, if the second sensor


282


detects a relatively low product moisture content, then the controller


250


can modulate the second heat sources


262


so as to reduce the product temperature in order to prevent over-drying the product “P.”




Likewise, the third sensor


283


can detect and measure product moisture content within the third control zone Z


3


, whereupon the controller can determine the proper amount of heat “H” to be produced by the third heat sources


263


. Although three control zones Z


1


, Z


2


, Z


3


are depicted, it is understood that any number of control zones can be incorporated in accordance with the present invention.




In furtherance of the description of the interaction between the controller


250


, the sensors


281


,


282


,


283


, and the heat sources


261


,


262


,


263


provided by the above example, a given control zone Z


1


, Z


2


, Z


3


can be described as a separate, independent, and exclusive control loop which comprises each associated sensor and each associated heat source located within the given control zone, and which is, along with the controller, configured to independently regulate the amount of heat “H” produced by the associated heat sources as a function of at least one characteristic of the product “P” measured by the associated sensor.




That is, each sensor


281


,


282


,


283


associated with a given control zone Z


1


, Z


2


, Z


3


, can be considered as configured to provide control feedback to the controller


250


exclusively with regard to characteristics of a portion of the product “P” which is in the given control zone. The controller


250


can use the feedback to adjust the output of the heat sources


261


,


262


,


263


in accordance with a temperature profile or other such parameters defined by the operator or otherwise stored within the controller.




In addition to decreasing the drying time of the product “P” as compared to prior art drying apparatus, the plurality of control zones Z


1


, Z


2


, Z


3


of the apparatus


200


can also be employed to attain specific product profiles which can be beneficial to the quality of the product as described above for the apparatus


100


.




For example, it can be assumed that the quality of a given product “P” can be maximized by following a given product temperature profile during drying. The given product temperature profile can dictate that, as the product “P” passes successively through the first, second, and third control zones Z


1


, Z


2


, Z


3


, the temperature of the product initially increases rapidly to a maximum given temperature, whereupon the temperature of the product “P” gradually decreases until it is removed from the support surface


230


.




In that case, the first sensor


281


, first heat sources


261


and controller


250


can operate in a manner similar to that described above in order to rapidly increase the product “P” temperature to a first temperature which can be reached as the product “P” passes through the first control zone Z


1


. The first temperature can correspond to a relatively large amount of heat “H” which is transferred to the product “P” which initially contains a high percentage of moisture.




As the product “P” passes through the second control zone Z


2


, the second sensor


282


, second heat sources


262


and controller


250


can operate to decrease the product temperature to a relatively medium second temperature which is lower than the first temperature. The second temperature can correspond to a lesser amount of heat “H” which is required as the moisture content of the product “P” drops.




Likewise, as the product “P” passes through the third control zone Z


3


, the third sensor


283


, third heat sources


263


and controller


250


can operate to decrease the product temperature further to a relatively low third temperature which is lower than the second temperature. The third temperature can correspond to a relatively low amount of heat “H” which is required as the product “P” approaches the desired dryness.




In addition to regulating the temperature of the heat sources


261


,


262


,


263


, the controller


250


can also be configured to regulate the speed of the support surface


230


relative to the chassis


210


. This can be accomplished by configuring the controller


250


so as to modulate the speed of the actuator


240


. For example, as in the case where the actuator


240


is an A/C electric motor, the controller can be configured so as to modulate the variable speed control unit


244


by way of a servo or the like.




The speed, or rate of movement, of the support surface


230


can affect the process of drying the product “P” which is performed by the apparatus


200


. For example, a relatively slow speed of the support surface


230


can increase the amount of heat “H” which is absorbed by the product “P” because the slower speed will cause the product to be exposed to the heat “H” for a longer period of time. Conversely, a relatively fast speed of the support surface


230


can decrease the amount of heat “H” which is absorbed by the product “P” because the faster speed will result in less exposure time during which the product is exposed to the heat.




Moreover, the controller


250


can also be configured to regulate various qualities of the conditioned air “A” which can be made to circulate through the enclosure


246


. For example, the controller


250


can be made to regulate the flow rate, relative humidity, and temperature of the conditioned air “A.” These qualities of the conditioned air “A” can have an affect on both the drying time and quality of the product “P.”




In another alternative embodiment of the apparatus


200


which is not shown, the enclosure


246


can be configured so as to be substantially sealed against outside atmospheric air. In that case, the chemical composition of the conditioned air “A” can be controlled so as to affect the drying process in specific manners, or to affect or preserve the chemical properties of the product “P.” For example, the conditioned air “A” can substantially be inert gas which can act to prevent oxidation of the product “P.”




Moving to

FIG. 5

, a schematic diagram is shown which depicts one possible configuration of the apparatus


200


which comprises a plurality of communication links


257


. The communication links


257


are configured to provide for the transmission of data signals between the various components of the apparatus


200


. The communication links


257


can be configured as any of a number of possible communication means, including those of hard wire and fiber optic. In addition, the communication links


257


can comprise wireless communication means including infrared wave, micro wave, sound wave, radio wave and the like.




A readable memory storage device


255


, such as a digital memory, can be included within the controller


250


. The readable memory device


255


can be employed to store data regarding the operational aspects of the apparatus


200


which are received by the controller by way of the communication links


257


, as well as set points and other stored values and data which can be used by the controller


250


to control the drying process. The controller


250


can also include at least one algorithm


253


which can be employed to carry out various decision-making processes required during operation of the apparatus


200


.




The decision-making processes taken into account by the algorithm


253


can include maintaining integrated coordination of the several variable control aspects of the apparatus


200


. These variable control aspects comprise the speed of the support surface


230


, the amount of heat “H” produced by each of the heat sources


261


,


262


,


263


,


269


, and the product characteristic measurements received from the sensors


281


,


282


,


283


. Additionally, the algorithm


253


can be required to carry out the operational decision-making processes in accordance with various set production parameters such as a product temperature profile and production rate.




The communication links


257


can provide data transmission between the controller


250


and the operator interface


235


which can comprise a display screen


237


and a keypad


239


. That is, the communication links


257


between the controller


250


and operator interface


235


can provide for the communication of data from the controller to the operator by way of the display screen. Such data can include various aspects of the apparatus


200


including the temperature and moisture content of the product “P” with regard to the position of the product within each of the control zones Z


1


, Z


2


, Z


3


.




Additionally, such data can include the speed of the support surface with respect to the chassis


210


and the temperature of each of the heat sources


261


,


262


,


263


,


269


. The communication links


257


can also provide for data to be communicated from the operator to the controller


250


by way of the keypad


239


or the like. Such data can include operational commands including the specification by the operator of a given product temperature profile.




A communication link


257


can be provided between the controller


250


and the HVAC unit


245


so as to communicate data there between. Such data can include commands from the controller


250


to the HVAC unit


245


which specify a given temperature, humidity, or the like, of the conditioned air “A.” A communication link


257


can also be provided between the controller


250


and the actuator


240


so as to communicate data there between. This data can include commands from the controller


250


to the actuator which specify a given speed of the support surface


230


.




Additional communication links


257


can be provided between the controller


250


and each of the sensors


281


,


282


,


283


so as to communicate data between each of the sensors and the controller. Such data can include measurements of various characteristics of the product “P” as described above for FIG.


4


. Other communication links


257


can be provided between the controller


250


and each of the heat sources


261


,


262


,


263


,


269


so as to provide transmission of data there between.




This data can include commands from the controller


250


to each of the heat sources


261


,


262


,


263


,


269


which instruct each of the heat sources as to the amount of heat “H” to produce. As can be seen, the apparatus


200


can include a plurality of control devices


231


, wherein one each of the control devices is connected by way of respective communication links


257


to the controller


250


. Each of the control devices can be configured in the manner of the control device


131


which is described above for FIG.


3


.




In accordance with a sixth embodiment of the present invention, a method of drying a product includes providing a support surface which has a first side, and an opposite second side, and supporting the product on the first side while directing radiant heat toward product. Preferably, the support surface can allow radiant heat to pass there through so as to heat the product. The support surface can be a substantially flexible sheet. Alternatively, the support surface can be substantially rigid.




The method can further include the step of measuring a characteristic of the product, along with regulating the amount of radiant heat directed toward the second side as a function of the measured characteristic. The measured characteristic can include the temperature of the product, the moisture content of the product, and the chemical composition of the product. The characteristic can be detected and measured intermittently at given intervals, or it can be measured continually over a given time interval.




The method can also include moving the support surface so as to move the product past the heat source. Alternatively, the method can include moving the support surface so as to move the product through a plurality of control zones in succession, and providing a plurality of heat sources, wherein each control zone has at least one associated heat source dedicated exclusively to directing radiant heat within the associated control zone.




In other words, the method can include regulating the temperature of the heat sources within any given control zone independently of the temperature of any other heat sources outside the given control zone. This can allow producing and maintaining a given temperature profile of the product as the product is moved through the control zones.




The method can further include providing a plurality of sensors, wherein any given control zone has at least one sensor dedicated exclusively to detecting and measuring at least one characteristic of the product within the given control zone. This can allow regulating the temperature of each heat source in any given control zone as a function of at least one characteristic of the product within the given control zone. As noted above, the characteristics can include the temperature, moisture content, and chemical composition of the product, among others.




The rate of movement of the support surface relative to the control zones can also be regulated in accordance with the method. Additionally, an enclosure can be provided to aid in circulating conditioned air about the product as the product is processed by the apparatus. The quality of the conditioned air can be controlled, wherein such qualities can include the temperature, humidity, and chemical makeup of the conditioned air. The method can include annealing the product which the product is supported on the support surface.




While the above invention has been described in language more or less specific as to structural and methodical features, it is to be understood, however, that the invention is not limited to the specific features shown and described, since the means herein disclosed comprise preferred forms of putting the invention into effect. The invention is, therefore, claimed in any of its forms or modifications within the proper scope of the appended claims appropriately interpreted in accordance with the doctrine of equivalents.



Claims
  • 1. A drying method, comprising:providing a liquid product; providing a support surface which has a first side and an opposite second side; supporting the liquid product on the first side; directing dry radiant heat across a gap toward the second side to substantially heat the liquid product until dry; and, annealing the dried liquid product while the product is supported on the support surface.
  • 2. A drying apparatus, comprising:a support surface which allows radiant heat to substantially pass therethrough; a dry radiant heat source which is exposed to the support surface and configured to direct radiant heat thereto to heat the product, wherein the radiant heat source is configured to be proportionally modulated with respect to the quantity of heat directed thereby toward the support surface; a gap defined between the heat source and the support surface; a controller which is in communication with the heat source and which is configured to proportionally modulate the heat source to regulate the amount of radiant heat directed thereby toward the support surface; a sensor which is in communication with the controller and which is configured to measure the chemical composition of at least a portion of the product while the product is supported on the support surface, wherein the controller is configured to regulate the amount of radiant heat directed toward the support surface in direct proportion to the measurements made by the sensor.
US Referenced Citations (10)
Number Name Date Kind
2301589 Shepard Nov 1942 A
2668364 Colton Feb 1954 A
4631837 Magoon Dec 1986 A
5167079 Bowen Dec 1992 A
5323546 Glover et al. Jun 1994 A
5373647 Bernes et al. Dec 1994 A
5465504 Joiner Nov 1995 A
5636318 Polaert et al. Jun 1997 A
5678323 Domingue et al. Oct 1997 A
5937535 Hoffman et al. Aug 1999 A