Method and device for regulating the output humidity of tobacco

Information

  • Patent Grant
  • 6502581
  • Patent Number
    6,502,581
  • Date Filed
    Monday, December 4, 2000
    24 years ago
  • Date Issued
    Tuesday, January 7, 2003
    21 years ago
Abstract
The invention relates to a method and device for regulating the output moisture content of tobacco conditioned by a loosening/conditioning and optionally casing (saucing) drum comprising injecting a throughflow of water into the infeed region of the drum by a first nozzle regulated depending on the target value for the tobacco output moisture content and the actual values for the tobacco mass flow, the steam throughflow and the tobacco input moisture content; and injecting a throughflow of water in the outlet region of the drum through a second nozzle, the target value of which is computed depending on the target value and actual value for the tobacco output moisture content.
Description




BACKGROUND OF THE INVENTION




1. Field of the Invention




The invention relates to a method and device for regulating/controlling the output moisture content of tobacco conditioned by a loosening/conditioning and optionally casing (saucing) drum.




2. Description of the Related Art




It is in the tobacco industry, especially in the cigarette industry, that a loosening/conditioning and optionally loosening/conditioning/casing (saucing) drum has the function of loosening the raw tobacco furnished in bales, casing it (also called saucing so that hereinafter casing (saucing) is used) and conditioning it for further steps in the process of preparing the tobacco. Special embodiments of such drums are known, for example, from WO 90/13231, EP-B-0 424 501 and EP-A-0471 513.




In such a drum, water and/or steam is injected into the tobacco mass contained in the drum, which is supplied to the drum in the form of bales or bale pieces.




A typical embodiment is evident from

FIG. 5

of EP-A-0 471 513 wherein the water nozzles are located in the infeed region of the drum and are configured as duplex nozzles introducing a mixture of water and steam. The intention is that the tobacco leaving the drum has an output moisture content of approx. 12% to approx. 16.5%, the precise value depending on the subsequent steps in the method of preparing the tobacco.




Experience has shown that the optimum target value necessary in each case fails to be attained by these known methods, thus resulting in fluctuations in the output moisture content of the tobacco and corresponding problems in subsequent steps in the method of preparing the tobacco.




SUMMARY OF THE INVENTION




The invention is thus based on the object of providing a method and device in which the aforementioned disadvantages do not occur and in which, more particularly, the output moisture content of the tobacco may be regulated/controlled to an optimum value.




This object is achieved in accordance with the invention by a method for regulating the output moisture content of tobacco conditioned by a loosening/conditioning and optionally a casing (saucing) drum


28


, comprising injecting into the infeed region of the drum through a first nozzle a throughflow of water regulated depending on the target value for the output moisture content of the tobacco and the actual set values for the tobacco mass flow, the steam throughflow and the input moisture content of the tobacco; and injecting into the outlet region of the drum through a second nozzle a throughflow of water, the target value of which is computed depending on the target value and actual value for the output moisture content of the tobacco; and wherein the discharge hood of said drum is heated by a steam heat exchanger.




Expedient embodiments read from the corresponding sub-claims.




The advantages achieved by the invention are rooted in employing a two-stage infeed of water, namely, for one thing, in the infeed region of the drum and, for another, in the outlet region. The target value for the throughflow of water in the infeed region of the drum is calculated, i.e. dependent on the target value for the output moisture content of the tobacco which in turn depends on the subsequent steps in the method, and on the actual values of the tobacco mass flow, input moisture content of the tobacco and steam throughflow applied to the drum.




In the infeed region of the drum a throughflow of water is thus employed tailored to the method which, however, is yet to be rendered strictly conform with the target value for the output moisture content of the tobacco, this later being exactly set by means of a second water infeed into the outlet region of the drum by calculating the target value of this second water infeed from the target value and actual value for the output moisture content of the tobacco. It is not until the second stage that finalizing the regulation of the output moisture content of the tobacco is fine “tuned” so that a value is attained with high accuracy which is optimum for subsequent steps in the method of preparing the tobacco.




In one preferred embodiment the throughflow of water for water supply in the outlet region of the drum is fine tuned by comparing it to the actual value of the injected flow of water to assure minimum departures from the target value for the output moisture content of the tobacco.




Since the casing (sauce) likewise supplied to the drum contains water, i.e. up to 90% in extreme cases, the target value for the throughflow of the casing (sauce) applied to the drum is taken into account in a preferred embodiment when calculating the throughflow of water for the infeed region of the drum so as avoid heavy departures or fluctuations in this respect, too.




As it reads, calculating the throughflow of water for the infeed region of the drum is done by a formula which takes into account the salient influencing parameters, namely the target value for the output moisture content of the tobacco, the actual value for tobacco mass flow, the actual value for the input moisture content of the tobacco, the actual value for the steam throughflow and in conclusion, where needed, also the target value for the casing (sauce) throughflow.




It has been discovered to be important that the tobacco mass flow supplied to the drum should be maintained constant to assure in this respect consistent and homogenous conditions in the method. It is for this reason that the tobacco mass flow supplied to the drum is regulated by means of a weighing belt disposed between the drum and a slicer upstream of the drum, this slicer being used to apportion the tobacco in slices, whereby the cutting frequency of the slicer is dictated by the weighing belt so that a constant tobacco mass flow is supplied to the drum with high consistency.




In accordance with one advantageous aspect there is provided between the slicer and the weighing belt a first photoelectric barrier located at the start of the impact belt and activating the slicer when receiving a “no slice” alert. To ensure a continuous supply of tobacco bale portions to the weighing belt any gaps in supply are “seen” by a second photoelectric barrier at the end of the impact belt when a “no slice” alert is received, these gaps being closed by elevating the speed of the impact belt to thus also contribute towards a constant tobacco mass flow.




In accordance with one preferred embodiment the two nozzles are configured as duplex nozzles injecting a duplex mixture of water and steam. Both the steam A flow supplied and the water flow supplied are detected and tuned to the corresponding target values so that here too heavy fluctuations are practically eliminated.




The casing (sauce) infeed too is engineered by means of a duplex casing/steam nozzle arranged in the outlet region of the drum.




For regulating the temperature of the drum, steam is fed into a recirculating air passage of the drum, this steam flow too being regulated/controlled and taken into account in regulating/controlling the output moisture content of the tobacco.




It has been discovered to be expedient when the discharge hood of the drum is indirectly heated by steam heat exchangers so that in this respect no deposits and more particularly no condensation can materialize, thus ensuring consistent conditions in the method. The door of the discharge hood is electrically heated to avoid condensation and deposits.




In accordance with another preferred embodiment the drum is provided with an “pneumatic blade” which scrapes soilage from the surface of the drum which could otherwise result in random conditions in the method and more particularly in heavy fluctuations in heat transfer.











BRIEF DESCRIPTION OF THE DRAWINGS




The invention will now be detailed on the basis of an example embodiment with reference to the accompanying schematic drawings in which:





FIG. 1

is a schematic overview of the system;





FIG. 2

is a detailed view of the slicer for the tobacco bales and the subsequent weighing belt; and,





FIG. 3

is a schematic diagram for regulating/controlling the system.











DESCRIPTION OF THE PREFERRED EMBODIMENTS




Referring now to

FIGS. 1 and 2

the system is illustrated as identified in general by the reference numeral


10


, it serving to condition the raw tobacco furnished in the form of tobacco bales


12


for further steps in the process of preparing the tobacco and comprising, as viewed in the conveying direction of the tobacco bales


12


, firstly a conveyor belt


14


on which the individual tobacco bales


12


are located in sequence, already stripped of their packaging. The conveyor belt


14


transports the tobacco bales


12


to a cutting device


16


known as a slicer in the tobacco industry in which the tobacco bales


12


are apportioned into slices by a vertically moving cutting knife


18


. The cut-off front sliced or cubed portions


20


of each tobacco bale


12


drop onto an impact belt


22


which brings the tobacco slice


20


to a weighing belt


24


which establishes from the weight of the tobacco slice and the belt speed the tobacco mass flow in kg per hour so that the momentary tobacco mass flow value is obtained for each cut-off tobacco slice


20


.




From the weighing belt


24


the tobacco slice


20


gains access to an infeed trough


26


for a rotating loosening/conditioning—and optionally casing (saucing)—drum


28


comprising a duplex nozzle


30


located in the infeed region of the drum


28


, i.e. in the embodiment as shown in the input face wall


32


of the drum


28


, receiving water and steam, whereby the injected flow of water is set so that the tobacco is loosened and conditioned to be transportable.




A further duplex nozzle


34


is located in the discharge hood


36


of the drum


28


, it likewise spraying a mixture of water and vehicle steam onto the loosened tobacco particles discharged from the drum


28


.




The water flow injected at the output is intended to guarantee a consistent output moisture content of the tobacco as supplied to further processing.




Adjacent to the duplex nozzle


34


for water and vehicle steam a further nozzle


38


is included in the discharge hood


36


of the drum


28


for injecting casing (sauce) and steam, employed should the drum


28


also be intended to serve as a casing (saucing) drum. It is evident that the three nozzles


30


,


34


and


38


receive steam from a common conduit


40


connecting the nozzles.




In addition, the drum comprises a recirculating air passage


42


into which likewise steam is injected from the conduit


40


for setting the temperature of the drum.




Installed on the discharge hood


36


is a hood heating fixture configured as a steam heat exchanger to prevent condensation of casing (sauce) and water on the discharge hood


36


.




Provided in the discharge hood


36


is a door which is heated for the same reasons, this heating being done electrically.




A steam heat exchanger


44


, indicated schematically, is provided in the recirculating air passage


42


serving to preheat the drum.




Provided in the upper region of the drum is an “pneumatic blade”, namely a tube


52


provided with outlet nozzles fed with compressed air. The compressed air ejected from the nozzles cyclically, roughly every three minutes, release soilage from the inner wall of the drum


28


so that no sauce or tobacco deposits can materialize. Since the drum is rotated, the complete cylindrical inner surface area of the drum in the region of the discharge end is cleaned so that no soilage can materialize there.




Starting from its infeed region, the drum


28


is inclined obliquely downwards so that the loosened, conditioned and optionally cased (sauced) tobacco is able to fall onto a discharge chute


46


which supplies the tobacco to a conveyor belt


48


and thus to further steps in the process of preparing tobacco.




In the system


10


six process parameters are regulated/controlled, namely, for one, the tobacco mass flow, expressed in kg per hour, for another, the tobacco moisture content express in %, the circulating air temperature of the drum, expressed in


1


C, and in conclusion when casing (sauce) is injected, also the casing (sauce) throughflow, expressed in kg per hour, the steam expressed in


1


C and the casing (sauce) pressure, expressed in bar.




As evident from the schematic regulation diagram as shown in

FIG. 3

, a series of transducers or measuring value pickups is provided which continuously sense the actual values of the salient process parameters, namely a first transducer


54


for the actual value of the input moisture content, located above the weighing belt


24


, and sensing the moisture content of the tobacco slices


20


located on the weighing belt


24


by one of the techniques as usual in the tobacco industry.




The weighing belt


24


establishes the actual value of the tobacco mass flow.




Regulating the tobacco mass flow is done with the aid of the weighing belt


24


by it being caused to run faster or slower, depending on the size of the departure of the tobacco mass flow from the predetermined target value, i.e. a practically constant tobacco mass flow being supplied to the drum


28


.




The actual value of the tobacco mass flow supplied to the drum


28


as established by the weighing belt


24


serves in addition for calculating the throughflow of water at the drum input as injected by the nozzle


30


, i.e., this throughflow of water depending on the momentary tobacco mass flow. Provided at the transfer belt


22


between the slicer


16


and the weighing belt


24


is a first photoelectric barrier


50


which “sees” whether a tobacco slice


20


is on the belt


22


or not. If the photoelectric barrier


50


signals a “slice” alert, the next tobacco slice


20


cut by the slicer


16


is made available via a tipper


53


. Should the second photoelectric barrier


51


at the end of the impact belt


22


signal a “no slice” alert, the speed of the impact belt


22


is increased to close the gap between the tobacco slices


20


as a result of which a gapless feed on the weighing belt


24


is assured.




In conclusion, the cutting frequency of the slicer


18


is further dictated by the weighing belt


24


, i.e. should the tobacco mass flow drop below the target value, the slicer


18


is moved faster to produce more tobacco slices


20


per unit of time.




A third transducer


58


is connected to a central feeder


60


for the steam, it establishing the momentary actual value of the steam throughflow.




The actual value for the tobacco mass flow, the actual value for the input moisture content and the actual value for the steam throughflow are input into a computer


62


which computes from the momentary values of these actual values, on the one hand, and two process parameters on the other—namely the target value for casing (sauce) throughflow and the target value for output moisture content of the tobacco—the target value for the throughflow of water which is applied to a first controller


64


. The actual value for the throughflow of water received by the first controller


64


is the output signal of a fourth transducer


66


connected to a first water infeed


68


for the duplex nozzle


30


. The controller


64


processes the target value and actual value for the throughflow of water in the usual way and generates a positioning signal for a water flow valve


70


located in the water feed conduit


72


to the duplex nozzle


30


between the first water infeed


68


and the fourth transducer


66


.




From the above parameters the throughflow of water in the infeed region of the drum


28


injected by means of the duplex nozzle


30


is calculated by the following formula;







Q
W

=


(





M
2

-

M
1




100





%

-

M
2



·

Q
T


-


Q
D

·
A

-


Q
S

·
C


)

·
B











where




Q


W


=throughflow of water




Q


T


=tobacco mass flow




M


2


=output moisture content target value




Q


D


=steam throughflow actual value




M


1


=input moisture content actual value




Q


S


=casing (sauce) amount




The factor A contained in this formula is in the range of 0.4 to 1 and serves the purpose of adapting the influence of the steam flow on the water amount in the process and on the system


10


, thereby taken into account more particularly the differences in the condensation of steam at the tobacco, a feature dictated by the following influencing variables: drum temperature, tobacco temperature, steam flow and air flow profile in the drum. The factor A can be set on the bases of empirical data when taking into account these parameters.




The value for the factor B is in the range 0.6 to 0.8 and assumes that the computed water flow corresponds to roughly 60 to 80% of total water flow in the process. The remaining water flow, i.e. 20 to 40% of total water flow, serves as the working range for tuning the output moisture content in the tobacco discharge done via the duplex nozzle


34


in the discharge region.




Should a casing (saucing) means be present, as is already included in the formula, it must further be taken into account that the casing (sauce) likewise contains water. The water content of commercially available casing (sauces) is in the region 50% to almost 100% and is taken into account by the factor C, the numerical value on which is between 0.5 and almost 1.




The actual value of the output moisture content of the tobacco is established above the conveyor belt


48


by means of a fifth transducer


74


, the output signal of which is applied to a second controller


76


which also receives the target value for the output moisture content of the tobacco, as is evident from FIG.


3


.




The second controller


76


processes the two signals in the usual way in accordance with one of the known control mechanisms and generates a target value for the water flow in the discharge region which is applied to a third controller


78


which receives the actual value of the water supply to the duplex nozzle


34


from a sixth transducer


80


located in the water conduit


82


between a second water infeed


84


for the discharge region and the duplex nozzle


34


. The third controller


78


activates a flow control valve


86


arranged between the second water infeed


84


and the transducer


80


.




In the on-going process the actual values for the tobacco mass flow, steam throughflow and the input moisture content of the tobacco are continuously adapted to the target value for the throughflow of water so that in taking into account the target value for the output moisture content of the tobacco, depending among other things on the subsequent steps in the method and the nature of the tobacco being used, as well as optionally the target value for the casing (sauce) throughflow, the optimum throughflow of water may be computed, from which in turn in the first controller


64


an optimum target value for the water flow is tuned as injected at the inlet of the drum


28


by means of the duplex nozzle


30


onto the tobacco in the drum


28


, whereby the steam flow fed to the system is automatically taken into account.




The water amount for the duplex nozzle


34


is determined by a cascade control


76


,


78


, regulating the output moisture content of the tobacco being finalized by the master controller


78


.




The casing (sauce) throughflow is regulated by a separate control loop (not shown).




In a further (likewise not shown) control loop the steam flow injected into the recirculating air passage is set to maintain the temperature of the drum


28


at a predetermined target value.



Claims
  • 1. A device for regulating the output moisture content of tobacco conditioned by a conditioning drum, comprising:a computer for computing a target value for a throughflow of water injected through a first nozzle in an infeed of said drum from a set of actual values for tobacco mass flow, steam throughflow and input moisture content of said tobacco and a target value for said tobacco output moisture content; and a controller for controlling: the water amount injected through a second nozzle into an outlet of said drum depending on said target value and an actual value for said tobacco output moisture content; measuring said throughflow of water supplied to said first nozzle from said computed target value and said actual value for said throughflow of water; computing a target value for said throughflow of water supplied to said second nozzle from said target value and said actual value for said tobacco output moisture content.
  • 2. A device for regulating the output humidity of tobacco, comprising:a conditioning drum, said conditioning drum having an infeed and in outlet; a first nozzle positioned in said conditioning drum at said infeed; a second nozzle positioned in said conditioning drum at said outlet; a computer operably connected to said first nozzle and said second nozzle; said computer regulating the throughflow of water through said first nozzle depending on a target value for output moisture content of said tobacco, tobacco mass flow and an input moisture content of said tobacco; said computer regulating the throughflow of water through said second nozzle depending on said target value for output moisture content of said tobacco and an actual value of output moisture content of said tobacco.
  • 3. The device of claim 2 wherein said computer regulates said throughflow of water for said second nozzle such that said throughflow consists of between about 20% to about 40% of a total water throughflow into said device.
  • 4. The device of claim 3 further comprising a third nozzle, said third nozzle connected to a supply of casing material.
  • 5. The device of claim 4 wherein said third nozzle is further connected to a supply of water.
  • 6. The device of claim 4 wherein said first and said second nozzle are duplex nozzles, said duplex nozzles in flow communication with a supply of water and a supply of steam.
  • 7. The device of claim 5 wherein said third nozzle is a duplex nozzle.
  • 8. The device of claim 3 wherein said outlet of said drum deposits said tobacco into a discharge hood.
  • 9. The device of claim 8 wherein said discharge hood is heated by a heat exchanger.
  • 10. A device for controlling the output humidity of tobacco, comprising:a conditioning drum having an infeed region and an outlet region; a first nozzle located within said infeed region; a second nozzle located within said outlet region; said first nozzle and said second nozzle in flow communication with a water source and a steam source; wherein said first nozzle and said second nozzle are in operable communication with a controller, said controller regulating a total water throughflow into said conditioning drum such that said second nozzle supplies from about 20% to about 40% of said total water throughflow.
  • 11. The device of claim 10 wherein the throughflow of water through said first nozzle is dependent upon a target value for output moisture content of said tobacco, an actual set value for a tobacco mass flow through said device, a steam throughflow applied to said drum and an input moisture content of said tobacco.
  • 12. The device of claim 11 wherein said throughflow of water through said second nozzle is dependent upon a target value and an actual value for output moisture content of said tobacco.
  • 13. The device of claim 12 further comprising a third nozzle said outlet region of said drum, said third nozzle in flow communication with a casing source and said steam source.
  • 14. The device of claim 13 wherein said throughflow of water through said first nozzle is further dependent upon a target value of throughflow of said casing source through said third nozzle.
  • 15. The device of claim 14 further comprising a weighing belt and a slicer, said weighing belt and slicer sequentially positioned before said conditioning drum.
  • 16. The device of claim 14 further comprising a discharge hood at said outlet region of said conditioning drum, said discharge hood having a steam heat exchanger, said steam heat exchanger in flow communication with said steam source.
  • 17. A device for controlling the output humidity of tobacco, comprising:a conditioning drum having an drum infeed and a drum outlet; a first nozzle located at said drum infeed and a second nozzle located at said drum outlet, said first nozzle and said second nozzle in flow communication with a steam source and a water source; a third nozzle located at said drum outlet, said third nozzle in flow communication with a casing source; wherein a first controller is operably connected to said first nozzle and wherein a second and a third controller are operably connected to said second nozzle.
  • 18. The device of claim 17 wherein said third nozzle is further in flow communication with a steam source.
  • 19. The device of claim 17 wherein said third nozzle is further operably connected to said second and third controller.
  • 20. A device for controlling the output humidity of tobacco, comprising:a conditioning drum having an drum infeed and a drum outlet; a first nozzle located at said drum infeed and a second nozzle located at said drum outlet, said first nozzle and said second nozzle in flow communication with a steam source and a water source; a third nozzle located at said drum outlet, said third nozzle in flow communication with a casing source; said third nozzle is further in flow communication with a steam source; a first controller operably connected to said first nozzle, a second and a third controller operably connected to said second nozzle and said third nozzle; wherein said first, second and third controller operate to control a total throughflow of water through said device, said second and said third controller regulating a throughflow of water through said second nozzle of about 20% to about 40% of said total throughflow of water.
Priority Claims (1)
Number Date Country Kind
197 51 525 Nov 1997 DE
CROSS REFERENCE TO RELATED APPLICATION

This application is a divisional application of patent application filed Nov. 9, 1998, Ser. No. 09/188,854 now U.S. Pat. No. 6,155,269 which claims priority to a German Patent Application 197 51 525.8, filed Nov. 20, 1997.

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