Method for reducing the noise level of tobacco-processing machines with sound-damping line segments

Information

  • Patent Grant
  • 6431310
  • Patent Number
    6,431,310
  • Date Filed
    Wednesday, August 30, 2000
    24 years ago
  • Date Issued
    Tuesday, August 13, 2002
    22 years ago
Abstract
A method for reducing noise level in a tobacco-processing production machine that is acted upon by flowing process air includes supplying process air to the production machine predominantly conveyed by sound-damping line segments.
Description




CROSS-REFERENCE TO RELATED APPLICATIONS




Priority is claimed with respect to application No. EP 19943319.4 filed in the European Patent Office on Sep. 10, 1999, the disclosure of which is incorporated herein by reference.




BACKGROUND OF THE INVENTION




The invention relates to an arrangement for reducing the noise level of tobacco-processing production machines acted upon by flowing process air, particularly in the operator region of a production line comprising at least two production machines disposed at an angle to one another.




Production machines of the tobacco-processing industry primarily encompass cigarette-production machines and filter-attachment machines, which are preferably joined diagonally at a 90° angle to form a production line. The machines may further include packaging machines and other standard tobacco-industry components, such as filter-production machines and article-transport devices, the latter representing a secondary source of noise. Particularly in the aforementioned production line, an operator, who is preferably positioned in the corner zone between two machines, is exposed to a great deal of machine noise. Previous efforts to reduce the noise have been unsuccessful in preventing operating noises created by mechanical components, and flow noises produced by process air, especially suction noises, from being emitted from the machines and entering the operator region, because it is not possible to hermetically seal the machine.




SUMMARY OF THE INVENTION




It is the object of the invention to implement further, more effective anti-noise measures in tobacco-processing production machine.




According to the invention, this object is accomplished in that the process air supplied to the production machines is predominantly conveyed via sound-damping line segments.




In accordance with a preferred modification, such sound-damping line segments are concentrated in a floor region of the production machines.




In accordance with an advantageous modification, the damping measures in the floor region can be particularly effectively supported by the integration of a sound-absorbing floor covering, which is under the production machines, into the sound-damping line segments.




To optimize the anti-noise measures, it is further proposed to provide secondary air-flow gaps as noise dampers between moving or stationary machine or wall sections.




In accordance with advantageous modifications, the flow noises are additionally suppressed by damping mats that form a cladding of the production machines for sound-damping the air-flow gaps.




As a further noise-reduction measure, it is proposed to provide sound-damped air-exit openings on the top of the production machines, so the emitted noise is directed away from the nearby operator region.




The advantage attained with the invention is that, in machines whose noise level is distinguished by a relatively large process-air throughput, such as strand machines and filter-attachment machines having conveying air, including retaining air and control blast air, the flow noises are absorbed, and thus rendered harmless to operating personnel at the locations where the noise is the most intense and has the greatest impact on the operator region, namely in the boundary zone between the surroundings and the machine interior.











BRIEF DESCRIPTION OF THE DRAWINGS




The invention is described in detail below in conjunction with embodiments illustrated in the drawing.




Shown are in:





FIG. 1

is a sectional representation through the distributor of a cigarette-strand machine;





FIG. 2

is a sectional representation through a filter-attachment machine;





FIG. 3

is a plan view of an angular production line formed by a cigarette machine and a filter-attachment machine;





FIG. 4

a floor plan for sound-damping material for setting up the production line according to

FIG. 3

;





FIG. 5

a cross section through a tile element of the sound-damping material according to

FIG. 4

;





FIG. 6

a plan view of the tile element according to

FIG. 5

;





FIG. 7

a cross section through a sound-damping element of the machine cladding;





FIG. 8

a plan view of the sound-damping element according to

FIG. 7

;





FIG. 9

an alternative damping cladding on a machine wall embodied as a removable carriage according to

FIGS. 1 and 2

;





FIG. 10

a cross section through a corner profile strip of the carriage according to

FIG. 9

;





FIG. 11

a cross section through an alternative damping profile on a machine cladding embodied as a door;





FIG. 12

a front view of the door according to

FIG. 11

;





FIG. 13

a cross section through a detail of the door damping profile;





FIG. 14

a cross section through a damping profile of a machine cladding embodied as a see-through flap;





FIG. 15

a cross section through an alternative damping tile for covering the floor;





FIG. 16

a plan view of the damping tile according to

FIG. 15

; and





FIG. 17

a partial cross section through a further embodiment of the damping tile.











DETAILED DESCRIPTION OF THE INVENTION




The distributor


1


illustrated in

FIG. 1

is an aggregate of the cigarette-strand machine


2


according to

FIG. 3

, with a high throughput of flowing process air for the purpose of feeding and sorting tobacco and forming a tobacco strand from a stream of tobacco. The tobacco is fed in portions, via a pneumatic lock system


3


, into a reservoir container


4


of distributor


1


, transferred via a screen roller


6


into an intermediate storage element


7


, then transported upward by a removal conveyor


8


equipped with carriers, and placed in a storage shaft


9


, whose fullness level is kept essentially constant.




A removal roller


11


continuously removes tobacco from storage shaft


9


and, in cooperation with a beater roller


12


, transfers it into a drop shaft


13


.




At the lower exit of the drop shaft


13


, a transverse sorting air current generated by high-pressure air nozzles


14


separates the tobacco into heavier and lighter tobacco fibers, of which the latter are transported to a concave guiding surface


16


, while the former travel downward via a star-feeder lock


17


into a sorting shaft


18


, from which heavy strands are removed at the bottom after a further sorting, and lighter tobacco fibers are transported upward due to the injector effect of a compressed-air jet generated by a further nozzle arrangement


19


, then join the other tobacco fibers on the guide surface


16


to form a tobacco stream that extends over the width of the distributor


1


(perpendicular to the drawing plane), which is supported and accelerated by additional compressed air exiting a further nozzle arrangement


21


at the guide surface


16


.




In this way, the tobacco stream is transferred upward to a suction strand conveyor


25


that is moved perpendicular to the drawing plane, and at which a tobacco strand is formed with the use of flowing suction air; this strand is encased and processed into individual cigarettes as it continues through the cigarette-strand machine


2


.




The high air throughput effected by the numerous pneumatic conveyor elements creates an increased noise level in addition to the mechanical drive noises of the machine. This noise reaches the outside by way of unavoidable machine cladding gaps.




In accordance with the invention, the outside machine walls, flaps, doors, hoods or carriages facing the operating space or the floor region, and acting as reflection surfaces, are provided to the greatest possible extent with noise-damping material in the form of damping mats


22


, which are embodied with a neutral shape, such as frustoconical damping elements


23


, in the region of the outside machine walls according to

FIG. 7

, and are connected by a central screw connection


24


to the machine cladding sheets of varying sizes so as to be easily exchanged.




According to

FIG. 7

, the damping elements


23


facing the operating space with their sound-damping structure are covered on all absorption surfaces with sound-permeable cladding sheets


26


, which are provided with holes in the manner of a sieve.




The damping mats


22


on the machine floor are embodied to limit an air-intake opening


27


of sufficiently-large dimensions, and act as sound dampers


28


on the air


29


flowing in. In this way, the supply of process air is predominantly concentrated over the machine floor, instead of being conveyed via gaps in the front or rear machine cladding.




In the filter-attachment machine


30


shown in

FIG. 2

, which is likewise operated with a high air throughput for retaining rod-shaped tobacco articles in the cavities of conveyor drums


31


, and for checking and separating out articles, damping mats


22


embodied in the same manner are mounted to the front and rear machine cladding, and on the machine floor, in the form of a sound damper


28


for a central air-intake opening


27


.




In addition, a damping mat


22


is laid on the floor, at least from the standing region in front of the machine to beneath the machine floor.




In the cigarette-strand machine


2


and filter-attachment machine


30


having a switch cabinet


32


, and with the machines being set up at a closed right angle to form a production line


35


according to

FIG. 3

, the damping mat


22


is designed to cover the entire base surface of the production line


35


corresponding to FIG.


4


. As the floor mat, the damping mat


22


comprises individual damping tiles


33


, which, according to

FIG. 5

, are embodied as tile boxes


34


having supports


36


that are disposed in the manner of a grid, and are equipped with damping material in the form of damping mats


22


inserted with a precise fit. The tile boxes


34


as the standing surface are provided with a gridiron support


37


that is screwed to the supports


36


.




Corresponding to the setup plan of the production line


35


, stress-specific supports are inserted into the gridiron supports


37


according to

FIG. 4

, for example, at the locations with greater particle accumulation, in the form of easy-to-clean, closed plates


38


, or under the machine bases in the form of reinforced support plates


39


.




As a further anti-noise measure, according to

FIG. 2

, the remaining gaps


41


at the machines


2


and


30


are embodied to have the greatest possible sound-damping effect.




The air sucked in through a fan


42


is conveyed through sound-damped flow conduits


43


,


44


,


46


inside the machine, and carried off via an air exit


47


at the top of the machine, which further reinforces the sound damping.




In alternative embodiments of the damping elements illustrated in

FIGS. 9 through 16

, parts that correspond to those in the above-described arrangements are provided with reference numerals that are increased by one hundred.




In the carriages


148


illustrated on the outside of the machine in

FIGS. 9 and 10

, damping mats


122


are inserted laterally and underneath between inside reflection surfaces


120


and outside, sound-permeable cladding sheets


126


, and into corner-profile strips


149


, with the plate-shaped reflection surfaces


120


and cladding sheets


126


being inserted into the correspondingly-spaced receiving grooves of corner-profile strips


149


.




In the machine cladding embodied as a door


151


in

FIGS. 11 through 13

, inside and outside sound-permeable cladding sheets


126


with interposed reflection surfaces


120


are inserted into receiving grooves of four profile strips


154


joined by corner connectors


152


to form a profile frame


153


. The hollow spaces formed in the process are filled with damping mats


122


.




Sealing elements


157


are inserted into the profile frame


153


, which can pivot about an axis


156


. The cladding sheets


126


and the reflection surface


120


are stabilized against shifting by spacing sleeves


158


that are screwed together.




In the window flap


159


illustrated in

FIG. 14

, two viewing panes


162


and


163


, and a cladding sheet


126


, are inserted as a double glazing into a profile strip


161


of a window frame. The cladding sheet limits a hollow space that is filled with damping mats


122


.




In the alternative tile box


134


of a damping tile


133


covering the floor, as shown in

FIGS. 15 and 16

, the gridiron support


137


is provided with elevations


164


in a specific lattice or grid arrangement of the supports


136


; these elevations prevent tobacco fibers that are lying on the gridiron support


137


from entering the damping mats


122


, and allows them to be swept away more easily.




Furthermore, buffers


166


, which prevent a solid-borne sound transmission between the damping tiles, and into the floor, are inserted, on the side and bottom, between the damping tiles


133


.




As the last embodiment, in a floor-damping tile


233


, a gridiron support


237


is provided with rounded edges


267


and a sound-permeable film


269


, which is inserted between a narrow-mesh sieve


268


that lies on the damping mat


222


and the gridiron support


237


, the film preventing the passage of fine particles into the damping material.




The invention has been described in detail with respect to preferred embodiments, and it will now be apparent from the foregoing to those skilled in the art, that changes and modifications may be made without departing from the invention in its broader aspects, and the invention, therefore, as defined in the appended claims, is intended to cover all such changes and modifications that fall within the true spirit of the invention.



Claims
  • 1. A method for reducing noise level in at least one tobacco-processing production machine that is acted upon by flowing process air, comprising:conveying flowing process air through sound-damping line segments disposed in a floor region outside of an exterior enclosure of the production machine to reduce noise in the flowing process air; and supplying said flowing process air to the production machine through an opening in said exterior enclosure.
  • 2. The method according to claim 1, wherein the at least one tobacco-processing production machine comprises two production machines, and the method further comprises:disposing said two production machines at an angle to one another to form a production line and defining an operator region; whereby noise level in the operator region is reduced.
  • 3. The method according to claim 2, further comprising integrating a sound-absorbing covering on the floor beneath the exterior enclosure of the production machines into the sound-damping line segments.
  • 4. The method according to claim 2, wherein the production line includes movable and stationary machine or wall sections, and wherein the method further comprises:defining at least one secondary air-flow gap between the movable and stationary machine or wall sections; and employing the at least one secondary air-flow gap as a sound damper.
  • 5. The method according to claim 4, further comprising providing the production machines with cladding of damping mats for sound-damping the at least one secondary air-flow gaps.
  • 6. The method according to claim 1, wherein the at least one production machine has a top with at least one air-exit opening, and the method further comprises sound-damping the at least one air-exit opening.
Priority Claims (1)
Number Date Country Kind
199 43 319 Sep 1999 DE
US Referenced Citations (1)
Number Name Date Kind
3866708 Rudszinat et al. Feb 1975 A
Foreign Referenced Citations (3)
Number Date Country
29 10 371 Oct 1980 DE
39 31 228 Mar 1990 DE
1 442 751 Jul 1976 GB