WO1998039237A1

WO1998039237A1 - Stacking of layered cellulose products

Info

Publication number: WO1998039237A1
Application number: PCT/US1998/004552
Authority: WO
Inventors: Christof Karl Stary
Original assignee: The Procter & Gamble Company
Priority date: 1997-03-07
Filing date: 1998-03-09
Publication date: 1998-09-11
Also published as: EP0863100B1; CA2282425A1; JP2001514608A; BR9812286A; DE69705018D1; AU6546298A; CN1252037A; EP0863100A1; DE69705018T2; ES2157495T3; ATE201652T1

Abstract

An apparatus for the manufacture and stacking of layered cellulose products, in particular of cotton pads (1), by cellulose products being cut from a continuous web (6) and by the cellulose products (1) being transferred to a stacking and storing means (39), is provided with a rotary cutter unit (7, 8) for the continuous, serial cutting of cellulose products (1) from a continuous web (6), with a conveyor belt arrangement (3), which conveys the cellulose products (1) deposited by the rotary cutting unit (7, 8), and with a transfer station (4, 4'), in which the cellulose products (1) can be lifted off the continuously running conveyor belt arrangement (3) by means of a lifting tappet (41) and can be inserted successively into the stacking and storing means (39).

Description

STACKING OF LAYERED CELLULOSE PRODUCTS

The invention relates to a device for the manufacture and stacking of layered cellulose products and in particular cotton pads as used for cosmetic purposes.

An apparatus for punching rounds or other shaped parts out of a fibrous material is known

from DE 30 22 369 Al, in which a punch cooperates with a die. A web of cotton or cotton wool is guided stepwise over the die. With each stepwise advance of the web, the punch

performs a punching motion. The punched rounds are transported downwards through the punching die into a pipe passage, through which they are pushed successively. In a subsequent charging station as disclosed in DE 43 16 363 Al, partial stacks are separated

from the continuous stream of products to be stacked, the number of rounds in a partial

stack corresponding to the desired number in a packing unit - for instance a flexible tubular

bag.

The punching apparatus known from DE 30 22 369 A 1 has the drawback that the raw

material web of cellulose or cotton must be stopped for each punching operation.

Furthermore, punching is a comparatively rough way of material treatment, which is

accompanied with some noise. Moreover, it is inherent in the system that the cutting edges

of a punch are highly susceptible to wear. As becomes obvious from the separating device according to DE

43 16 363 Al, the requirements in terms of equipment are comparatively high in order for a

corresponding number of pads to be separated from the continuous flow of punched rounds,

then forming a partial stack which is the packing and selling unit. As seen from the prior

art, a second web of semirigid plastic material was also guided in the punching machine,

from which separating sheets were punched after a number of rounds corresponding to a

selling unit had been punched, and were integrated into the stream of products to be stacked.

In this regard, the handling arrangement for layered cellulose products, in particular cotton pads, according to DE 195 08 248 Al means a certain improvement. This handling

arrangement is provided with a temporary storage device which moves the successive cotton pads between a punching machine and a packing station. The temporary storage

device has at least one pair of separate chambers for the serial take-up of the cellulose products discharged from the punching machine in a number corresponding to the packing unit

and for transferring the cotton pads taken up as a package into a conveying cartridge. The

pairs of chambers are to be coupled alternately with the outlet of the punching machine and,

respectively, in a transfer station with the respective conveying cartridge.

With this handling arrangement, there is no continuous stream of products to be stacked,

from which partial stacks have to be separated in complicated operation. Rather, a number

of cotton pads precisely corresponding to the packing unit is supplied to the take-up chamber and transferred as a package to a packing station by means of the conveying

cartridges.

A drawback of the known handling arrangement again resides in that the actual punching .

operation only takes place with a web moved stepwise. The drawbacks mentioned above

apply here, too.

It is the object of the invention to specify an apparatus for the manufacture and stacking of

layered cellulose products, in particular of cotton pads, by means of which to attain improved production capacity, low suceptibility to wear and the possibility of suitably

handling the cellulose products for subsequent packing.

According to the invention, this object is attained by an apparatus for the manufacture and

stacking of layered cellulose products, in particular cotton pads, by the cellulose products being cut from a continuous web and by the cellulose products being transferred to a

stacking and storing means, comprising: a rotary cutter unit for the continuous, serial cutting of the

cellulose products from the continuous web,

a conveyor belt arrangement, which continuously conveys the

cellulose products deposited by the rotary cutter unit, and

a transfer station, in which the cellulose products can be lifted

off the continuously running conveyor belt arrangement by means of a lifting tappet and can be inserted successively into the stacking and storing means.

The objects provided according to the invention are attained by the combination of the

aforementioned subassemblies of the apparatus. For instance, when a rotary cutter unit is

used, there is no longer the stepwise advance of the prior art punching machines which

limits the capacity. Furthermore, owing to their structure and operation, rotary cutter units

are less susceptible to wear than the prior art punching machines, there being no blunt

punching impact between punch and die in the case of cutting rolls. At most, rolling cutting contact takes place between the rotary cutting roll and the opposite roll.

In coordination with the cellulose products continuously produced, the conveyor belt arrangement then conveys the cellulose products likewise continuously. Contrary to the

prior art, the invention adds an intermediate step of conveying. Unproblematic access to the

cellulose products conveyed is ensured by the use of a conveyor belt arrangement.

This access takes place in the transfer station mentioned, where the cellulose products can

be lifted continuously off the conveyor belt arrangement by means of a lifting tappet. By its

lifting motion, the lifting tappet removes the cellulose products from the conveyor belt,

pushing them simultaneously into the stacking and storing means. This way of handling

ensures that the cellulose products are fed into the stacking and storing means precisely in

the number the packing unit is to have. Preferred embodiments as well as further features, details and advantages of the invention will become apparent from the subclaims and the ensuing description in which an

exemplary embodiment of the invention is explained, taken in conjunction with the

drawings, in which

Fig. 1 is a lateral view, partially diagrammatic, of an apparatus

for the manufacture, transport and stacking of cotton pads,

Fig. 2 is a highly diagrammatic plan view of the apparatus

according to Fig. 1,

Fig. 3 is a sectional plan view of the conveyor belt arrangement

of the apparatus according to Fig. 1 in the vicinity of the

transfer station,

Fig. 4 is a vertical section, parallel to the cotton pads conveying

direction, through the transfer station of the apparatus

according to Fig. 1 with a lifting tappet and storage pipe,

and Figs. 5 and 6 are detailed side views of the lifting tappet in the transfer station in the former's lowered and lifted position.

Reference is made to Figs. 1 and 2 for the explanation of the rough structure of an

apparatus according to the invention for the manufacture and stacking of cotton pads 1. The

apparatus is split up into a rotary cutter unit 2, a conveyor belt arrangement 3 and two

transfer stations 4, 4'. The mentioned components are mounted on a frame-type machine table designated in its entirety by 5 and not needing further explanation.

The rotary cutter unit 2 serves for the continuous, serial cutting of cotton pads 1 from a

continuous web 6 of appropriate cellucotton. The continous web is fed from a storage roll (not shown) via corresponding guiding and compensating rolls, as is usual prior art. The rotary cutter unit 2 substantially consists of a lower rotary cutting roll 7 and an opposite roll

8 cooperating with the latter. Round cutting edges 9 are formed on the rotary cutting roll distributed over the length of the roll sleeve and its circumference, having the interlocked

and staggered configuration shown on the left of Fig. 2. The rotary cutting roll and the

opposite roll 7, 8 are set to each other in such a way that clear cutting of cottom pads 1 from

the continuous web 6 takes place, with, however, the wear of the cutting edges being

minimal. Cutting edge angles of approximately 15° are usual, the distance between the

cutting edge 9 and the opposite roll 8 being 0.015 mm. This is conventional technology

known from the manufacture of sanitary towels, diapers and the like. In a manner likewise known, the rotary cutting roll 7 is provided with a vacuum fixing

device which retains the cut cotton pads 1 on the rotary cutting roll 7 during the transfer between the place of cutting - i.e. the roll slit 1 1 - and the place of deposition on the

conveyor belt arrangement 3. Customarily, openings are provided in the sleeve of the rotary

cutting roll 7 within the closed cutting edges 9; the openings are in connection with a

vacuum source. In this way the cotton pads 1 are sucked up and held in place.

As opposed to this, the web of waste 10, which remains between the rotary cutting roll and

the opposite roll 8 after the place of cutting has been passed, is led away from the roll slit 11 in a straight conveying direction.

The conveyor belt arrangement extends in the conveying direction F tangentially to the

lowest point of the rotary cutting roll 7 and comprises two conveyor belts 12, 13 which pass into each other and follow each other in this direction. The overlapped portion between

these two conveyor belts is designated by 14. As seen in the diagrammatic illustration

according to Fig. 2, the in each case first conveyor belt 12 for each row 15 of cotton pads 1

is formed by three partial belts 16.1, 16.2, 16.3 running side by side at a distance. Each of

the successively produced cotton pads 1 is deposited by the rotary cutting roll 7 on these

partial belts 16.1, 16.2, 16.3 by the mentioned vacuum openings, when passing the

conveyor belt arrangement 3, being shortly actuated by overpressure within the closed

cutting edges 9 so that the cotton pads 1 are virtually "blown off. The conveyor belts 12,

13 are provided with a vacuum fixing device, which will be described in detail below, so that the cotton pads 1 are reliably held thereon and conveyed in a smooth, troublefree condition.

As seen in Fig. 1, all the partial belts 16.1, 16.2, 16.3 are guided via deflection pulleys 17,

18 at the front and rear end of the conveyor belts 12, in the vicinity of their lower strand 19

meandering via a compensating pulley 20 and a drive pulley 21. The latter is in connection

with a drive motor 22 (roughly outlined) which drives the conveyor belts at a defined speed.

By means of a piston-cylinder drive 24, the support structure for the conveyor belts 12 and

their deflection pulleys 17, 18 can be pivoted downward, i.e. away from the rotary cutting roll 7.

As seen in Fig. 2, the conveyor belts 13 which follow the conveyor belts 12 consist of two

partial belts 25.1, 25.2, these partial belts 25.1, 25.2, in the overlapped portion 14, running in the spaced gap 26.1, 26.2 between the associated partial belts 16.1 and 16.2 and 16.2 and

16.3, respectively, of the conveyor belts 12. This ensures an absolutely continuous transfer

of the cotton pads 1 from the first conveyor belts 12 to the second conveyor belts 13. The width b of the two partial belts 25.1, 25.2 is less than the width B of the central partial belt

16.2 of the three partial belts 16.1, 16.2, 16.3 of the first conveyor belts 13. The distance a

of the two outer edges 27 turned away from each other is selected to be clearly smaller than

the diameter of the cotton pads 1. If, for instance, this distance a amounts to 70 to 75 % of

the diameter D of the cotton pads, edge portions remain, which clearly stand out beyond the

outer edges 27 and which are of importance for the handling of the cotton pads 1 in their

course through the apparatus according to the invention. As seen in Figs. 5 and 6, the partial belts 25.1, 25.2 - as well as the partial belts 16.1, 16.2, 16.3, which is however not shown in the drawing - are provided with openings 28

extending centrally and following each other in the conveying direction F and run on guide

rails 29 into which the vacuum passages 30 are integrated. The latter communicate with the

openings 28 on the one hand and are joined to a vacuum source on the other so that the

cotton pads 1 are reliably and smoothly held on the partial belts 25, 16 by means of this

vacuum holding device.

At their ends, the conveyor belts consisting of the partial belts 25 are likewise guided via deflection pulleys 31, 33, and in the vicinity of their lower strand 33 they are guided via a

compensating pulley 34 and a drive pulley 35, as seen in Fig. 1. The deflection pulley 31 located in the overlapped portion 14 consists of individual disks, between which the respective lower strand 19 of the first conveyor belts 12 is guided. Further, connectors 36

disposed on the guide rails 29 are roughly outlined in Fig. 1, which are connected to a

vacuum source (not shown in detail) via pressure hoses.

The specification now turns to the two transfer stations 4, 4', of which only the first transfer

station 4 will be explained in detail. The second transfer station 4' is identical with the first.

As diagrammatically outlined in Fig. 2, in the transfer station 4, storage cartridges 27 are

moved by a transporting equipment 38 at an acute angle W relative to the conveying

direction F over the rows 15 of cotton pads 1 approaching on the conveyor belt arrangement 3 in such a way that in each case a storage pipe 39 aligns in the vertical direction with the

cotton pad 1 approaching in a row 15. The angle W corresponds to the angle taken by a continuous oblique row 40 by reason of the staggering V within the row 15. One of the storage pipes is shown in Figs. 1, 5 and 6.

In a position of vertical alignment with the storage pipes 39, lifting tappets 41 are located

under the conveyor belts 13, of which only one is shown in Figs. 1, 4, 5 and 6 for reason of clarity. By way of bearing rods 42, the lifting tappets 41 are lodged in a corresponding

guide 43 on the machine table 5 displaceably in the vertical direction. Drive takes place by

way of a connecting rod 44, which is connected via eccentric levers 45 with a crank drive 46. The crank drive 46 is mechanically connected with the drive motor 48 of the rotary cutting roll 7 by way of an appropriate linkage 47. The coupling ensures a defined

adjustable clock frequency of the lifting tappet 41 so that a lifting motion of the lifting tappet 41 is attained that is synchronous with the arriving cotton pads.

As seen in Figs. 3, 5 and 6, each lifting tappet 41 has three lifting props 49.1, 49.2 and 49.3

lying side by side at right angles to the conveying direction. In a horizontal section, the

central lifting prop 49.1 is in the form of a flat cuboid, moving upward between the two partial belts 25.1, 25.2 of the conveyor belts 13, whereas the two lateral lifting props 49.2

and 49.3, which, in a horizontal section, are in the form of a flat segment of a circle, move

upward laterally beyond these partial belts. The entire surface outlined by these lifting props

49 is slightly smaller than the surface of the cotton pads 1 so that the respective cotton pad

is clearly lifted off the conveyor belts 13 by the lifting motion of the lifting tappet 41 and, as seen in Figs. 4 and 6, is pushed from below into the storage pipe 39 located above. During this lifting off the conveyor belts 13, the cotton pads 1 keep on moving continuously. The oscillatory motion of the lifting tappet 14 runs synchronous with the

arriving cotton pads, it being returned into its lower position when the next cotton pad 1

arrives under the opening of the storage pipe 39. The lifting operation then starts again.

For the cotton pads 1 inserted from below into the respective storage pipe 39 not to fall out

downward when the lifting tappet 41 is withdrawn, the lower edge 50 of each storage pipe

39 has a collar 51 directed inward and leaving an opening that is slightly smaller as compared to the surface of the cotton pads 1. The lightweight cotton pads rest on this collar.

For clearly adjusted stacking of the individual cotton pads 1 to take place, a stop 52 is provided directly behind each lifting tappet 41 in the conveying direction; it corresponds to

the contour of the cotton pads 1 and is formed by three bent ribs 53.1, 53.2 and 53.3. Related to the conveying direction F, these ribs 53 are contiguous to the respective props 49

of the lifting tappet 41, but in the active position shown in Fig. 4, they project upward over the conveyor belts 13. The ribs 53 form in common a contour in the shape of the arc of a

circle, the interior radius of which corresponds to the exterior radius of the cotton pads 1.

Consequently, the approaching cotton pads 1 are at least slightly decelerated when

contacting the stop 52 and the lifting tappet 41 lifts the cotton pads 1 upward in a clearly

defined position. This provides for impeccable stacking of the cotton pads 1 within the

storage pipe 29. As seen in Figs. 1 and 4, three ribs 53 of the stop 52 reside in a multipart foot 54 which is mounted on a vertically displaceable actuating rod 55. The latter is displaceable upward or downward by way of a drive lever 56 so that the stop 52 can be moved from the elevated

position seen in Fig. 4 downward below the upper strand 57 of the conveyor belts 13.

As further outlined in Fig. 1, the fulcrum of the eccentric lever 45 can be lowered

downward by means of an adjusting mechanism 58 so that the connecting rod 44 together

with the lifting tappet 41 is displaced downward. As a result, the oscillatory motion of the lifting tappet 41 takes place in a portion where the lifting props 49 no longer project over the conveyor belts 13 and no longer reach into the corresponding storage pipe 39. As a

result, arriving cotton pads may approach the second transfer station 4', uninfluenced by the first transfer station 4, which is the case when the storage pipes 39 of the storage cartridges 37 in the first transfer station 4 are filled with a desired number of cotton pads 1 for a

packing unit. Then this storage cartridge 37 is discharged via the transporting equipment 38 and another storage cartridge 37 is positioned in the transfer station 4. During this time, a

storage cartridge 37 is filled in the second transfer station 4.

By reference to Fig. 4, attention is drawn to some special measures regarding the storage

39. For instance, the transporting equipment 38 for the storage cartridges 37 comprises

upper and lower guiding and holding devices 59, 60. A guiding plate 61 is mounted on the

lower guiding and holding device 60, preventing the cotton pads 1 from turning up in the

vicinity of the transfer stations 4, 4'. Furthermore, each storage pipe 39 in the transfer stations 4, 4' is closable to be comparatively pressure-sealed by means of a cover 62 that can be slipped on from above.

Placing the cover 62 takes place by an independent piston-cylinder drive 63 on the upper

guiding and holding device 59. Each cover 62 has a cover plate 64 which is connected with

the piston rod 65 of the piston-cylinder drive 63. By means of an annular seal 66, the cover

plate 64 rests on the upper edge of the storage pipe 39. Centrally on the cover plate 64,

provision is made for a cylindrical displacer 68 which, in the closed position seen in Fig. 4, projects into the storage pipe 39 by a length which corresponds about to one third of the

entire length of the storage pipe 39. It is the purpose of the cover 62, the seal 66 and the displacer 68 that, in particular in the case of an empty or hardly filled storage pipe 39, back

pressure will build up rapidly as soon as a cotton pad 1 is "shot" from below into the storage pipe 39 by means of the lifting tappet 41. If the storage pipe 39 were simply open, then the cotton pad 1 would whirl around uncontrolled within the volume of the storage

pipe 39, as a result of which clean stacking would be impossible.

Summing up, attention must still be drawn to some general advantages of the apparatus

according to the invention for the manufacture and stacking of layered cellulose products.

For instance, owing to the utilization of a rotary cutting unit instead of a punching machine,

the continuous cellulose web can be exploited to a higher degree, because the cutting edges

of the rotary cutting roll are by far more filigree as compared with the edges of a punch and

can be set more closely. As a result, the surface proportion of the leaving web of waste 10

can be reduced from 36 % in the case of prior art cotton-pad punching to 27 % in the case of an apparatus according to the invention. Further, output capacity can almost be doubled

from 250 pads per minute to 440 pads per minute. Finally, rotary cutting is accompanied with substantially less noise than punching with a chamfered punch hitting on a 90° die

edge. In this regard, the lifetime of a rotary cutting tool exceeds by far that of a punching

tool, there being - as mentioned at the outset - no blunt impact of the cutting edges on the

opposite roll in the case of rotary cutting.

Claims

WHAT IS CLAIMED IS:

1. Apparatus for the manufacture and stacking of layered cellulose products, in particular of cotton pads (1), by cellulose products (1) being cut out of a continuous web and by the cellulose products (1) being transferred to a stacking and storing means (39), comprising:

a rotary cutter unit (2) for the continuous, serial cutting of

cellulose products (1) from the continuous web (6),

a conveyor belt arrangement (3), which continuously conveys

the cellulose products (1) deposited by the rotary cutter unit (2),

and

a transfer station (4, 4'), in which the cellulose products (1) can be lifted off the continuously running conveyor belt

arrangement (3) by means of a lifting tappet (41) and can be inserted successively into the stacking and storing means (39).

2. An apparatus according to claim 1, characterized in that for each row (15) of cellulose

products (1), the conveyor belt arrangement (3) has two conveyor belts (12, 13) following

each other and passing into each other, of which

the first is contiguous to a rotary cutter unit (2) and comprises

three partial belts (16) running side by side at a distance, and

the second comprises two partial belts (25) running side by side

at a distance and which, in an overlapped portion (14) in the spaced gap (26) of the partial belts (16) of the first conveyor belt (12), run from the first (12) to the second conveyor belt (13) for the transfer of the cellulose products (1).

3. Apparatus according to claim 2, characterized in that the width (b) of the two partial belts

(25) of the second conveyor belt (13) is less than the width (B) of the central partial belt (16.2) of the three partial belts (16) of the first conveyor belt (12).

4. Apparatus according to one of claims 1 to 3, characterized in that the at least one lifting tappet (41) is coupled with the drive (48) of the rotary cutter unit (2) by way of a linkage (47).

5. Apparatus according to one of claims 2 to 4, characterized in that each lifting tappet (41) has three lifting props (49), which are disposed side by side at right angles to the conveying

direction (F) of the cellulose products (1) and which reach through between, and laterally

beyond, the two partial belts (25) of the second conveyor belt (13) and lift the respective

cellulose product (1) upward off the conveyor belt (13) and insert it from below into the

stacking and storing means (39).

6. Apparatus according to one of claims 1 to 5, characterized in that a stop corresponding to

the contour of the cellulose product (1) is provided directly behind each lifting tappet (41)

related to the conveying direction (F) of the cellulose products.

7. Apparatus according to claim 6, characterized in that the stop (52) can be moved out of the conveying path of the cellulose products (1).

8. Apparatus according to one of claims 1 to 7, characterized in that the stacking and

storing means comprises at least one storage pipe (39), which is to be charged successively

from below by the lifting tappet (41), and the upper end of which is closable by a

removable cover (62).

9. Apparatus according to claim 8, characterized in that a displacer (68) is mounted on the cover (62) and reaches into the storage volume of the stacking and storing means (39).

10. An apparatus according to one of claims 1 to 9, characterized in that a multiplicity of cellulose products (1) is handled in rows (15) running side by side parallel to the conveying

direction (F) and in that the stacking and storing means comprises storage pipes (39)

corresponding to the number of rows.

11. Apparatus according to claim 10, characterized in that the stacking and storing means is

a transportable unit (37) comprising the corresponding number of storage pipes (39).

12. Apparatus according to one of claims 1 to 11, characterized in that two transfer stations

(4, 4') to be actuated alternately are provided on the conveyor belt arrangement (3),

disposed one after the other in the conveying direction (F).

13. Apparatus according to one of claims 1 to 12, characterized in that a vacuum-actuated fixing device (30) for the cellulose products (1) is allocated to the partial belts (16, 25) of the conveyor belt arrangement (3).