DE1577658B2 - METHOD AND DEVICE FOR EVEN DISTRIBUTION OF NATURAL OR ARTIFICIAL FIBERS FOR ELECTROSTATIC FLOCKING - Google Patents

Description

The invention relates to a method for evenly distributing natural or artificial fibers for electrostatic flocking, in which the dosed quantities of fibers fed in by means of several successively Brushes spreading over a sieve at equal intervals on the sieve and through the sieve on pinp receiving area underneath (to be brushed and a device for this.

The device essentially consists of a metering device for distributing the fibers in portions a storage container of brush brushes for brushing through a sieve onto the receiving surface below with an electrostatic field between the sieve and the receiving surface and one of the brushes and that Sieve laterally enclosing housing, in the lower opening of which the sieve sits.

In the known method, the fibers metered in from the storage container are centered over The brush wheel running on the sieve is brushed directly onto the sieve. The ones sitting on the brush wheel Brushes must be long enough to cover the entire sieve. The brush pressure on the The sieve and the fibers therefore run approximately sinusoidally from a minimum when running onto the sieve a maximum in an approximately vertical position on the sieve to a minimum in the movement of each brush from the sieve. In addition, the angle of reach changes from an initially acute angle to one perpendicular to an obtuse angle. These conditions make it difficult to distribute the fibers on the Sieve. Most of the fibers fall through the sieve at the point of greatest brush pressure, the longer the sieve is the brushes of the brush wheel have to be longer, and the more they work Difficulties arise. The sometimes high brush

"Rock also deforms the screen what the Faservereilung also affected adversely ^k rug £ _r fmHung has the task of the metered quantities of fiber with constant pressure and stroke angle! to distribute dykes even over large sieve lengths and thus to ensure even loading even of a relatively large receiving area.

The method according to the invention solves this problem in that the small dosed amounts of fibers one with numerous storage shells and located in between, arranged at the same strike angle Brushed, endless, revolving transport chain fed and temporarily there in portions stored, then thrown onto the sieve and from which the flat sieve with constant pressure and Spreading brushes over the entire screen and brushed through the screen.

The method according to the invention brings the advantage that the metered from the storage container to the numerous brushes by means of the storage shells small amounts of fiber, regardless of the size of the sieve and thus the receiving surface, always evenly spread over the sieve and brushed onto the receiving surface underneath. Since there is neither pressure nor If the brush angle changes during the overflow over the sieve, the fibers are over the whole sieve equally stressed, treated gently and its even distribution over the receiving surface relieved. Each brush has only a small amount of fiber to process, which is a fiber backlog and prevents the associated plug formation on the sieve.

In a known manner, the device for carrying out the method initially consists of a metering device for portion-wise allocation of the fibers from a storage container to brush brushes for brushing through through a sieve onto the Δ intake area underneath, with an electrostatic field between the screen and the receiving surface and one the brushes and the screen laterally enclosing housing, in the lower opening of which the sieve sits. In this device there is the invention is that between the dispenser and the Sifib parallel to the sieve at a distance therefrom an im essential horizontally revolving, endless transport chain is provided, which extends over its entire circumference at equal intervals with brushes that are the same as one another and arranged at the same angle is occupied, with passage gaps for the fibers provided between the brush brushes and the storage shells are, and that the transport chain is laterally trough-like enclosed by the housing and the sieve in the The lower opening of the housing is replaceably seated on slide rails.

This device is simple and easy to clean and can be used for a wide variety of tasks by changing the Brush pressure or the running speed of the Dcsierer and Transportketle and of seven different Mesh size can be adjusted quickly. Through the use of storage trays and / or brush brushes different transport chains one can achieve the most diverse distribution areas without something about the basic structure of the device

changes. ...

As a streak angle for the Sireich brushes a Angle of about 15 to 20 ° to the vertical The direction of travel of the transport chain over the sieve be-The transport chain can be connected by joints consist of the same lamellas, with a brush holder with a brush replaceable on each lamella is clamped and between two brushes each one made of a tray bottom and elastic Side walls of the existing storage tray for the added small amounts of fibers so at the Transport chain is attached so that it is open to the top along the upper run of the transport chain the side walls to the bottom of the tray can be chosen differently depending on the tasks to be mastered will. It is recommended that the side wall immediately leading to the brush brush is approximately parallel to the To provide brush axis. The edges of the side walls should be a certain distance above the Sieve lying. The storage trays then support the fiber distribution by the brushes, because their side walls Take a certain amount of fiber with you and distribute it beforehand. The device according to the invention allows longer fibers with a low denier to be kept straight and torsion-free. on the other hand you can also change the length and / or the denier of the fibers quickly, because on the one hand the Brush configuration of the transport chain and its running speed changed quickly and on the other hand Sieves with different mesh sizes can be changed quickly. The running speed of the Brush brushes can run at 15 to 45 m / min, at excellent speeds Distribution uniformity in width regardless of the length and denier of the fibers and the distribution density. ) e square meter can distribute up to 40 g of fibers. The large brush surface brings a good one even with a lower walking speed in the range of! 0 to 30 m / min ; ö Distribution of the fibers without settling on the sieve Form fiber plugs. The brush angle of 15 to 20 ° also allows the distribution of rolled up flakes, which are frayed on the sieve by the brushes. The ones on the fibers acting mechanical forces are because of the

VCUCIiUiIg uta l »u <.m to numerous

small amount. The fibers therefore remain undeformed, straight and untwisted.

Further features and advantages of the method and the device according to the invention emerge from the following description with reference to the drawing, the embodiments for the device according to the invention brings. It shows

F i g. 1 shows a schematic section through the device according to the invention,

F i g. 2 shows an enlarged section of the transport chain with storage trays according to FIG. 3,

F i g. 3 to 7 excerpts from the transport chain with different designs of the storage shells and 55 Fig. 8 a schematic section through the front direction with their transport chain with storage trays according to Fig. 3, but with fiber passage gaps between see every storage bowl and brush.

According to Fig. 1 the fibers become fin in the direction of f \

ho a line 26 fed into a storage container 41

and from its exit in small measured

Quantities through a metering device D to the distributor V ge

promotes. In the exemplary embodiment, the dispenser D has it

lower exit sit a discharge wheel, which consists of a

65 shaft 27 with radial ar at equal angular intervals

set blades 28 consists. The one in between

between two blades 28 from the storage container

41 taken over fibers F are by the rotation

of the paddle wheel (arrow h) is transferred in free fall onto one of the storage trays 25 of the distributor V. From the distributor V , the fibers reach the sieve 15 and are brushed through onto the receiving surface A , which is guided in the direction of arrow (A).

The distributor V essentially includes a motor reduction gear 17, with a speed that can be selected according to the flocking requirements, which drives a wheel 13 via a clutch 18. The wheel 13 controls the pulling wheel 24 of an endless transport chain 20, which consists of slats 21 connected by joints 22 . Each lamella 21 returns to its starting position when the deflection stars 24, 24 'run over.

According to FIG. 1, each lamella 21 carries. 2 in the middle part a brush element 11, which consists of a brush holder 12 , the z. B. has two clamping blocks 33, between which brushes 35 made of nylon hair 36 are clamped, which have, for example, 70 to 90/100 cross-section and 100 mm in length.

The brush holders 12 are rigidly attached to angle irons 34 which are made in one piece with the slats 2t. All brush brushes 35 are inclined at the same angle α of preferably 15 to 20 ° with respect to the running direction A of the transport chain 20.

The brush brushes 35 are arranged between the edges 31 of the storage trays 25. A storage tray 25 across two lamellae 2t belongs to each brush 35. Each storage shell consists of such a material and is designed in such a way that it can elastically adapt to the positions of the lamellas while the chain is running in the direction of arrows A, A '. The edges 31 of the storage trays 25 are inclined towards the floors 32. The optimum sweeping angle of the sweeping brushes 35 during the overflow over the sieve 15 is according to FIG. 2 «= 15 to 20 °. The stroke angle λ is chosen so that the fibers Fin the stroke brush 35 are held in order to prevent their penetration into the transport chain 20 , but in particular to prevent the fibers F from compacting. On the other hand, the edges 31 of the storage trays 25 must not press on the non-abrasive brush brushes 35 during their migration along arrow A (FIG. 1) on the upper run of the transport chain 20.

This arrangement works as follows: The feeder 27, controlled by the motor reduction gear 17, transfers exactly the same, small amounts of fibers F to each storage tray 25. The stored amounts of fibers are conveyed by the transport chain 20 in the direction of arrow A in front of the wall of the housing 30 and finally dropped onto the sieve 15. In the case of electrostatic flocking, the housing 30 and the coupling 18 are made of an insulating material.

After being thrown, according to FIG. 1 a part of the fibers F from the storage tray 25 through the sieve 15. The part of the fibers F remaining on the sieve 15 is guided through the edge 31 of the storage tray 25 against the brushes 35. The edge 31 is always at a distance h from the sieve 15, which is chosen so that the facility works well

The small fiber bead B, which is uniformly formed along each brush 35 and formed over the entire width of the manifold, quickly detaches itself because it is rolled between the tufts of hair of the brush 35 and its fibers B are brushed through the sieve 15 in the process. The temporary storage of relatively small amounts of fibers F prevents clogging of the screen 15 before or after the brush overflow. The throughput time of the fibers F through the distributor V is short. The quality, especially the straightness, the moisture content and the possible sheathing, etc. of the fibers are therefore not reduced.

The articulated transport chain 20 allows each lamella 21 to pivot about joints 22 and, due to its own weight, always guides the brushes 35 correctly against the sieve 15, as the plane or the design of the sieve is designed.

During the run of a storage tray 25 and the associated brush element 11 along the screen 15 in the direction of arrow A ', the defibrillation described above continues evenly. Then the next storage tray 25 with its brush element 11 follows directly on the first, etc. The working length of the screen 15 is chosen so that all fibers F are evenly distributed under all working conditions. The fibers F now fall through the electrostatic grid 19, are charged there before they hit the carrier 40 leading to the receiving surface A and then stand upright on the receiving surface A , which runs in the direction of the arrow k depending on the load.

An arrangement of the sieve 15 on slide rails 16 allows sieves of different types to be changed quickly Mesh size and great adaptability to different fiber lengths and easy cleaning of the housing 30.

When used to manufacture a non-woven cloth, it is sufficient to use the electrostatic grid to neutralize to obtain a shallow deposit on a non-stick support, a binder solution to atomize and then condense the whole thing. This addition allows carriers to be loaded in the manner of a velor and a flat, intersecting deposit in the manner of a felt or the like.

Storage shells 25 which adapt to each position of the lamellae 21 are, however, proportionate complicated and expensive. Often it is also desirable that a part of the fibers F freely through the transport chain and can fall through the sieve 15, especially the fibers that are on and between the lamellae 21 and the joints 22 have collected during their course.

The F i g. 3 to 7 show exemplary embodiments of devices that allow this.

All figures show the part of the transport chain 20 that includes the brush brushes 35 and the storage trays 25

carries when the brush brushes overflow the sieve 15 according to arrow A '. In Fig. 3 the storage trays 25 are arranged so that each lamella 21 carries a storage tray 25, the bottom 32 of which extends from the brush 33 to a distance s from the joint 22 between two lamellae 21. Each storage tray has edges 31 and 31 '. The base 32 is attached to the associated slats 21 either directly or at a distance e in order to enable the fibers to be recovered / and / or for easy and effective maintenance

To enable the transport chain. The edge 31 forms an angle (β) of 100 to 120 ° with the bottom 32 in such a way that it runs essentially parallel to the axis of the brush U and ends at the height h above the sieve 15

an effective defibrillation on the sieve 15 is seen. The edge 31 'forms an angle with the bottom 32 (γ \ whose size is selected such that the edge 31 ends at the same height Λ in front of the sieve as the ranc

31 ', with a passage gap ρ for the fibers F through the sieve 15 remaining.

The F i g. 4 shows a modification of the device according to FIG. 1. The edge 3Γ is at right angles to the bottom 32. This creates a larger passage gap ρ for the fibers F.

In the modification according to FIG. 5 the edge 31 'is missing. This solution is particularly suitable for special productions.

In the execution according to FIG. 6 is a storage shell ι ο le 25 'assigned to a storage tray 25, which is the storage tray of FIG. 5 is the same. This storage shell 25 'is on the opposite side of the movement of the transport chain .20 in the direction of arrow A' Brush 35 provided and has a bottom 32 'and an edge 3Γ on the brush side, the one forms a right angle with the bottom 3Γ and the joint 22 is too open.

The two free ends of the bottom 32 and 32 'of the parts 25 and 25' of the storage shell are arranged at the same distance s from both sides of the joint 22 between two lamellas 21, with a passage gap ρ remaining.

In the execution according to FIG. 7, two parts 25 and 25 'belong to a storage shell. The edges 31 'and 31 "form a right angle with the bottoms 32 and 32', are arranged on both sides of the joint 22 between two lamellas 21 and leave a passage gap ρ free, the bottoms 31, 31 'on both sides of the brush 35 ending without an edge .

FIG. 8 shows an application example for an overall device with storage trays 25 corresponding to FIG. 3 on the transport chain 20. Simple storage shells 25 made of sheet steel are arranged on the lamellae 21 in such a way that a passage gap ρ for the fibers is distant.

The storage shells 25 allow the arrangement de; Dosing device D at any desired point above the Transport chain 20.

The present patent application is based on a state of the art, for example as indicated by di < DT-AS 10 70 132 has become known.

For this purpose 4 sheets of drawings

Claims (9)

Patent claims: 1. Method of evenly distributing natural or man-made fibers for electrostatic Flocking, in which the dosed amounts of fiber are fed into the evenly spaced brushes spread over a sieve on the sieve and through the sieve on a receiving surface to be brushed underneath, ι ο characterized in that the small-dosed Quantities of fibers of a with numerous storage shells (25) and located in between, Coating brushes (35) arranged at the same sweeping angle (α) are equipped with endless, revolving Transport chain (20) supplied and temporarily stored there in portions, then on the Sieve (15) thrown off and brushed over the flat sieve with constant pressure and sweeping angle Spreading brushes over the whole sieve and brushing through the sieve. 2. Apparatus for performing the method according to claim 1 with a doser for portion-wise allocation of the fibers from a storage container to brush brushes for brushing through a sieve onto the receiving surface below, with an electrostatic field between the sieve and receiving surface and a brush and the sieve laterally enclosing the Housing, in the lower opening of which the seat sits, characterized in that between the dosing device (D) and the sieve (15) parallel to the sieve at a distance therefrom an essentially horizontally circulating, endless transport chain (20) is provided, which over its whole Circumference is occupied at equal intervals with the same brushes (35) arranged at the same brushing angle (α), with passage gaps (W for the fibers (F)) being provided between the brushes and the storage shells (25) and that dip Tran ^ nnrtkptip vom Clphäii <; p ^ n (30) is enclosed in a trough at the side and the sieve in the lower The opening of the housing is exchangeable on the slide rails (16). 3. Apparatus according to claim 2, characterized in that the strike angle («) 15 to 20 ° to Vertical against the running direction (A ') of the transport chain (20) above the sieve (15) (Fig. 2). 4. Device according to claims 2 and 3, characterized in that the transport chain (20) consists of the same slats (21) connected by joints (22), a brush holder (34) with a brush (35) interchangeably clamped on each slat is and between two brushes each one of a tray bottom (32) and elastic side walls (31, 3Γ) existing storage tray (25) for the added small amounts of fibers (F) is attached to the transport chain (20) that it is along the Upper run of the transport chain is open at the top. 5. Device according to claims 1 to 4, characterized in that the brush (35) over the sieve (15) immediately leading side wall (31) of each storage tray (25) approximately parallel to the brush axis at an angle (ß) = about 120 ° to the bottom of the bowl (32) and the second side WanH i ^ i '\ in £> in «> m rtiimnfan \ 1 /; _η |, ^ ν1 ί.Λ », lor c.inl, .. ...... γ *, aj _lai «,,.," .., JiullipiVll tt IIIIW.I \ {f UVJ I. 1 J \ _ II t \ right to the bottom of the bowl and between the second side wall and The brush has a gap (p) for the fibers (F) to pass through (Fig. 3, 4). 6. Device according to claims 1 to 5, characterized in that each storage schah (25) from the brush (35) was up to a distance (s) z \ xm joint (22) between two neighboring slats (21) extends 7. Device according to claims 1 to 4, characterized in that each storage shell au: two shell parts (25, 25 '), of which there: a shell part (25) in front of the brush (35) unc the other shell part (25 ') behind the brush on successive lamellae (21) is ordered and both shell parts on the brush side or on the hinge side each have a sidewall (31,3Γ) have (Fig. 5,6). 8. Device according to claims 2 to 7, characterized in that the storage shells (25 with a certain distance (e) are attached in parallel to the lamellae (21). 9. Device according to claims 2 to 8, characterized in that the metering device (D) au; a paddle wheel (27) with fiber discharge chamber (k) between its radial paddles (28) that rotates in the outlet of the fiber storage container (*> 1) above the endless transport chain (20)! and the paddle wheel is controlled by the motor change gear (17) of the endless transport chain (20).