EP1351030A1 - Apparatus and process for consolidating a fibre composite - Google Patents

Abstract

Device for compacting a continuous fiber composite (V) transported along a transport path (F) by heating or cooling comprises at least one nozzle arrangement (2a) on at least one side (3a) of the transport path for blowing an especially heated treatment medium (L) in the direction of the transport path. The nozzle arrangement has a number of blast nozzles (4) arranged next to each other a separation distance (a) apart with an intermediate space (5) in between. The intermediate space between the blast nozzles is/can be closed off from the transport path. An Independent claim is also included for a process for compacting a fiber composite. Preferred Features: The intermediate space between the blast nozzles is closed so that between the nozzle arrangement and the fiber composite a pressure chamber (6) is formed in which an excess pressure (P) is produced with the blast nozzles.

Description

The invention relates to a device and method for solidifying a fiber composite with the features of the generic term of the independent claims.

Such a fiber composite is often referred to as a nonwoven. The fiber composite consists of a mixture of basic fibers, for example cotton fibers or flax fibers and from Binding fibers, for example meltable plastic fibers. binder fibers can be melted by heating. Thereby the loose fiber composite can be consolidated. To solidify It is known from such fiber composites that the fiber composite is continuous along a conveyor path in a dryer device to promote and thereby apply heat. Subsequently the fiber composite is cooled. The one made in this way Non-woven mat can be used, for example, as upholstery, insulating material, Mattresses or used as a cosmetic product (cotton wool) become.

For strengthening such a fiber composite or for loading the fiber composite with heat are different devices known.

In so-called suction dryers, air is in one Drying device in a direction transverse to the conveying direction sucked through the fiber composite. In such dryers satisfactory heat exposure to the fiber composite can be achieved across its entire thickness. Such devices but have certain disadvantages. To perform this procedure must be on one side of the fiber composite being conveyed a negative pressure can be generated. Heated air is on the suctioned opposite side from a chamber. Is to this chamber is provided with openings, for example slits, which run transversely to the conveying direction of the fiber composite. In order to it is ensured that the air through the fiber composite is sucked through, it is necessary to adjust the width of this Adjust openings to the width of the respective fiber composite. For this purpose, covers are provided, by means of which the active Width of the chamber openings can be adjusted. Subsequently a cooling zone follows the heating zone, which is constructive is constructed essentially the same. Operation of such devices is expensive because the device in each case adapted to the width of the fiber composite to be treated must become. Such a suction dryer is, for example, in DE 299 00 646 U1 shown.

Another type of such device is the device trained as a blow dryer. Such a device is e.g. known from DE 30 23 229. In the process, heated air is removed Blowing nozzles blown against the fiber composite. It turned out that such blow dryers are combined with relatively thin fibers can be used satisfactorily. For the production thicker mats, for example, in the range of over 5 cm but problems arise because the air does not get through can blow through the entire thickness of the fiber composite. It has It was shown that the fiber composite is from one side blown hot air enters the fiber composite, but is reflected to some extent by this and again on the same side emerges from the fiber composite. Especially with the Treatment of thicker fiber composites therefore results in one middle area a zone which is not sufficient with Heat is applied and in which the binding fibers are not be melted sufficiently. The fiber composite is therefore not solidified evenly over its entire thickness.

It is therefore an object of the present invention that To avoid disadvantages of the known, in particular a method and a device for strengthening a fiber composite to create an even solidification of the fiber composite over its entire thickness even with relatively thick Fiber-composite enables. The device or the method but should also be used to treat thin fiber composites let insert.

According to the invention, these tasks are carried out with a device and with a process according to the characteristics of the characterizing part of the independent patent claims.

In the device for strengthening the fiber composite Fiber composite continuously conveyed along a conveyor path. The consolidation takes place by loading the fiber composite with warmth. The device has at least one nozzle arrangement on. The at least one nozzle arrangement is on at least one Arranged side of the conveyor path. The nozzle arrangement is used for Blowing a heated treatment medium in the direction of the conveying path against the fiber composite. As a treatment medium typically uses air. But it would also be other treatment media conceivable. The at least one nozzle arrangement has a plurality of adjacent blowing nozzles, i.e. the device is designed as a blow dryer. The blow nozzles are spaced apart in a known manner, so that there is a space between each two adjacent blowing nozzles is formed. To prevent the treatment medium is reflected by the fiber composite and on the width flows out of the nozzle arrangement between the blowing nozzles, is proposed according to the invention, the space between the blowing nozzles essentially closed towards the conveying path or lockable training. This ensures that the treatment medium is forced by the to pass through the entire thickness of the fiber composite. In this way uniform consolidation of the fiber composite guaranteed its entire thickness.

According to a preferred embodiment, it is not necessary close the gap completely airtight. It is sufficient to close the gap in such a way that between a pressure chamber is formed of the nozzle arrangement and the fiber composite is created in which an excess pressure is generated by means of the blowing nozzles can be. The overpressure should be sufficiently large so that the treatment medium is forced through the entire fiber composite to pass through. In other words, the invention exists So in it, a device for solidifying a continuously conveyed fiber composite so that a treatment medium even with a relatively thick fiber composite, typically more than 5 to 10 cm thick, through the entire thickness of the fiber composite can be blown through. If the device is used to make relatively thin fiber composites it is also conceivable to solidify the spaces between to open the blow nozzles.

According to a preferred embodiment, the gap is therefore locked or closable in such a way that with a given fiber composite (especially given material, given density and given thickness) and with given Exit velocity and exit quantity of the treatment medium the treatment medium from the blow nozzles entire thickness of the fiber composite is blowable.

In this context, the blowing nozzles advantageously have a blowing opening which ends adjacent to the surface of the fiber composite. By arranging the blowing opening as close as possible to the surface of the fiber composite, the treatment medium can be blown directly into the fiber composite.
Usually, a rotating upper or lower belt between which the fiber composite is conveyed is used to convey the fiber composite in such a device. The upper band or lower band is permeable to the treatment medium. According to this preferred exemplary embodiment, the aim is to arrange the blowing opening as close as possible to the upper belt or lower belt. In order to ensure the smallest possible distance between the blowing opening and the surface of the fiber composite, even in the case of fiber composites of different thicknesses, the distance between the surface of the fiber composite and the blowing opening of the blowing nozzles can be set according to a further preferred embodiment.

It is to close the space between the blow nozzles conceivable to use sealing elements, which in the space can be used between the blow nozzles. In particular, as Sealing elements sheets are used, which are between the blowing nozzles can be inserted.

The blowing nozzles are preferably designed as wide slot nozzles. The slot die extends essentially over the full width of the conveyor path in the device. The blow nozzles are advantageously provided with a nozzle box that has a cross section has that of a connection opening from which the treatment medium can be blown into the nozzle box into one closed end of the nozzle box decreases. With this in Area of dryer known measure is ensured that the exit velocity or the exit quantity of the treatment medium over the entire width of the conveying path or the fiber composite transverse to the conveying direction essentially remains constant. The blowing speed or the blowing quantity the treatment medium is independent of the width of the fiber composite to be treated. Because the flow resistance generated by the slot die has the width of the fiber composite no influence on the exit behavior of the treatment medium from the blow nozzle.

According to a further preferred exemplary embodiment, Nozzle arrangements are arranged on both sides of the conveying path. In order to the device can operate according to the invention as a blow dryer, with which treatment medium through the entire width of the fiber composite can be blown, it makes sense to blow the nozzles alternating on one side and on the other side of the funding path to arrange. Alternatively, it is also conceivable to use blowing nozzles to be arranged simultaneously on both sides of the conveyor path, in each case but only the blow nozzles on one or the other Activate page.

According to a further preferred embodiment several blow nozzles grouped together. The groups of Blow nozzles can be activated or deactivated individually.

The gap between deactivated blowing nozzles is in this Context openable or open. This ensures that treatment medium emerging from the fiber composite can flow and that not on the opposite of the blow nozzles Side can build up a counter pressure.

The device according to the invention is provided with at least one fan and with at least one heating device for heating the treatment medium. According to a preferred exemplary embodiment, the fan and the heating device are designed such that 500 to 2000 m ^{3 of} air per hour and per meter of working width at a temperature of 0 to 300 ° C. and at a speed of 0.5 to 70 m / s are preferred per blowing nozzle 20 to 40m / s is blowable against the fiber composite.

The method according to the invention serves to solidify a fiber composite by applying heat. The fiber composite is continuously funded along a funding path. there becomes a heated treatment medium in the direction of the fiber composite blown. In an adjacent to the fiber composite Overpressure is thus generated in the pressure chamber. The treatment medium is blown through the entire thickness of the fiber composite.

According to a preferred embodiment, the treatment medium directly from a blow opening of the blow nozzles, which the fiber composite lies adjacent to the surface of the fiber composite blown.

According to a further preferred exemplary embodiment, the Distance between the blow opening of the blow nozzle and the surface of the fiber composite before the start of the fastening process a predeterminable value is set.

According to a further preferred exemplary embodiment, the treatment medium, viewed in the conveying direction, is blown alternately from one side and from the other side towards the fiber composite. For this purpose, it is preferred that groups of blowing nozzles are alternately activated and deactivated on one side of the fiber composite, and that the space between deactivated blowing nozzles is opened to enable the treatment medium to flow away. The treatment medium is typically blown out of the blow nozzles at a temperature of 0 to 300 ° C. and at an exit speed of 0.5 to 70 m per second. Typically, 500 to 2000 m ^{3 of} air are blown out per hour per blowing nozzle and per meter of working width.

Both the speed and the amount of blown out Treatment medium is significantly above the speed or over the discharge amount of the treatment medium, which at Suction dryers are sucked through the fiber composite.

Die Erfindung wird im Folgenden in Ausführungsbeispielen und anhand der'Zeichnungen näher erläutert. Es zeigen:

Figur 1 Seitenansicht einer erfindungsgemässen Vorrichtung zur Vliesverfestigung,

Figur 2 schematische Darstellung eines Ausschnitts aus der erfindungsgemässen Vorrichtung mit oberhalb und unterhalb des Faserverbundes angeordneten Blasdüsen,

Figur 3 schematische Darstellung von auf beiden Seiten des Faserverbundes angeordneten, alternierend aktivierten und deaktivierten Blasdüsen,

Figur 4 Draufsicht auf Düsenanordnungen einer erfindungsgemässen Vorrichtung,

Figur 5 Darstellung einer erfindungsgemässen Vorrichtung im Querschnitt in einer Ebene senkrecht zur Förderrichtung,

Figur 6 vergrösserte Darstellung von Blasdüsen einer erfindungsgemässen Vorrichtung, und

Figur 7 Seitenansicht von mehreren Düsenkasten.

The invention is explained in more detail below in exemplary embodiments and with reference to the drawings. He show:

The invention is explained in more detail below in exemplary embodiments and with reference to the drawings. Show it:

FIG. 1 side view of a device for nonwoven bonding according to the invention,

FIG. 2 shows a schematic representation of a section of the device according to the invention with blowing nozzles arranged above and below the fiber composite,

FIG. 3 shows a schematic representation of blowing nozzles that are alternately activated and deactivated on both sides of the fiber composite,

FIG. 4 top view of nozzle arrangements of a device according to the invention,

FIG. 5 representation of a device according to the invention in cross section in a plane perpendicular to the conveying direction,

FIG. 6 shows an enlarged representation of blowing nozzles of a device according to the invention, and

Figure 7 side view of several nozzle boxes.

Figure 1 shows a side view of a device according to the invention 1. The device 1 according to the invention is used for conveying of a fiber composite V along a conveying path F. For conveying of the fiber composite V through the device 1 is an upper band 17 and a lower band 18 are provided. The upper and lower band 17, 18 are designed as all-round, open-mesh bands, which are guided around pulleys in the device 1. The fiber composite V is between the upper belt 17 and the Lower band 18 promoted. The fiber composite V is typically a mixture of natural fibers, for example cotton or Flax fibers and from a binding fiber, for example one fusible plastic fiber used. For strengthening the fiber composite V becomes the fiber composite in the device 1 in one Heating section 15 is subjected to heat, so that the binding fibers melt and the fiber composite V is solidified. Subsequently becomes the consolidated fiber composite V in a cooling section 16 cooled. The device 1 is designed as a dryer, the well-known way with fans, heating device and air vents. For solidification is used as a treatment medium Air used at a temperature of 0 is heated to 300 ° C. This allows the inside of the fiber composite V can reach temperatures of up to 250 ° C.

The device 1 is designed as a blow dryer. To this Purpose are on both sides 3a, 3b (see Figures 2 and 3) nozzle arrangements 2a, 2b to apply the fiber composite V. Heat W provided.

Figure 2 shows a section of the device 1 in cross section in a side view. The fiber composite V is along of the conveying path F is conveyed in the conveying direction R by the device 1. The upper belt 17 serves to convey the fiber composite V. or the lower belt 18, wherein only the upper part of the Device 1 and correspondingly shown only the upper band 17 is.

The nozzle arrangement 2a on the top of the fiber composite V has blowing nozzles 4. The blowing nozzles 4 blow heated air L in the direction of the fiber composite V via a blowing opening 7. The air L heated to 300 ° C. is blown out of the blowing openings 7 at a speed v of approximately 40 m / s. Up to 2000 m ^{3 of} heated air L is blown out per hour per blowing nozzle 4.

The blowing nozzles 4 are arranged at a distance a from one another, so that an intermediate space 5 is formed between adjacent blowing nozzles 4 becomes. According to the invention, the intermediate space 5 is between active ones Blow nozzles 4 closed by a sealing element 8. In the embodiment 2, the sealing element 8 is a sheet formed, which bridges the gap 5. In this way is between the nozzle arrangement 2a and 2b and the surface O of the fiber composite V, a pressure chamber 6 is formed, in which can generate an excess pressure P with the blowing nozzles 4. According to the According to the arrangement of the heated air L by the blown through the entire thickness d of the fiber composite V. An outflow the heated air L through spaces 5 between adjacent Blow nozzles are not possible due to the sheets 8.

The blow opening 7 of the blow nozzles 4 is relatively close to the surface O of the fiber composite V arranged. It is also conceivable to design the distance b adjustable.

FIG. 3 shows a larger section from the one according to the invention Device shown in side view. Figure 3 shows a first side 3a arranged above the fiber composite V. Nozzle arrangements 2a and on a second side 3b below the Fiber composite V arranged second nozzle arrangements 2b. The Blow nozzles 4 are each grouped together. there are alternately on the top 3a and on the bottom 3b of the fiber composite V groups 12 activated by blowing nozzles 4. At the same time are alternately on the bottom 3b of the fiber composite V and on the top 2a of the fiber composite V groups 12 'of blowing nozzles 4' inactive. Based on the fiber composite V are therefore each inactive compared to active blow nozzles 4 Blow nozzles 4 '. During the gap 5 between active blow nozzles 4 as explained in connection with FIG. 2 by sheets 8 is closed, the gap 5 is between inactive Blow nozzles 4 'open so that the active blow nozzles 4 through the fiber composite blown air L between the inactive blowing nozzles 4 'can flow.

According to FIG. 3, the treatment medium is alternated from the top to the top led below and from bottom to top through the fiber composite V.

Of course, it is also conceivable to use the inactive blow nozzles 4 'omitted. The provision of blow nozzles on both sides of the fiber composite V, which can be activated or deactivated as required are, allows flexible use of the inventive Contraption.

FIG. 4 shows a top view of the device 1 promoted fiber composite V. The blowing nozzles 4 are as wide slot nozzles formed and each have a blow opening 7, which are essentially over the entire width B of the conveyor path F extends. The conveyor path F is defined by two lateral boundaries 19 indicated. In Figure 4 is on the left a first group 12 of active blowing nozzles 4 is shown. it is followed by a group 12 'of inactive blow nozzles 4'. In on the right side of FIG. 4 are active blowing nozzles 4 of a further one Group 12 of active air jets shown. The between active Blow nozzles 4 formed space 5 is through the cover plate 8 closed, while the gap 5 between inactive blow nozzles 4 'remains open, so that from opposite Air blown between the inactive air nozzles 4 'can flow.

Figure 5 shows schematically a cross section of the inventive Device seen in the conveying direction R. The fiber composite V is by means of the upper band 17 and the upper band 18 through the device 1 led. The nozzle arrangements 2a, 2b on both sides 3a, 3b of the fiber composite V consist of blowing nozzles 4, the are provided with a nozzle box. Typically there are two Blow nozzles 4 are provided with one blow opening 7 per nozzle box 9 (see Figure 5a).

The nozzle box 9 has a connection opening 10 into which heated air L can be blown in by means of a fan 13 can. The cross section Q of the nozzle box 9 takes against a closed End 11 of the nozzle box 9 continuously. On in this way a uniform escape of the air L in the total width of the nozzle box 9 achieved. The heater 14 between fan 13 and connection opening 10 of the nozzle box 9 is used to heat the air L. The fan 13 is in known as a radial fan. The heater 14 and a fan 13 can be used to for example a group 12 (see FIGS. 3 and 4) of blowing nozzles 4 together with heated air L.

To either on the upper side 3a or on the lower side 3b of the fiber composite V arranged to activate bubble nozzles 4 or to deactivate, a pivotable flap 20 is provided. In the position shown in Figure 5, the flap closes 20 the connection opening 10 'of the lower nozzle box 9 during the connection opening 10 of the upper nozzle box is open. In the position shown in broken lines in FIG. 5 closes the position Flap 20, the connection opening 10 of the upper nozzle box 9 and thus activates the on the lower side 3b of the fiber composite V arranged nozzle boxes 9, so that blown from below to the top becomes.

FIG. 6 shows the blow openings 7 in an enlarged representation of two adjacent blowing nozzles 4. The blowing openings 7 have a width c of 3mm to approx. 30 (with a working width dependent Length of the wide slot nozzles from 0.5 to several Meters). The blowing openings 7 are bent sheets trained, which the air against the surface O (see Figures 2 and 3) of the fiber composite V. Between the adjacent blowing openings 7, the space 5 is through an insertion plate 8 closed. The insertion plate 8 is as folded sheet formed. The sheet 8 has one on both sides H-shaped cross-section, by means of which the sheet over a U-shaped bend 21 can be pushed on at the end of the blowing opening 7 is. To activate or deactivate the individual blowing nozzles the flap 20 shown in FIG Positioned. On the other hand, to activate of the blowing nozzles the sheets 8 are inserted between activated blowing nozzles 4 or for deactivating the blow nozzles, the metal sheets 8 are removed.

Figure 7 shows a side view of several nozzle boxes 9 each two blowing openings 7. The nozzle boxes 9 are only on the upper Side 3a of the fiber composite V arranged. Corresponding blow nozzles can also be provided on the lower side 3b.

Claims (17)

Device (1) for solidifying a fiber composite (V) continuously conveyed along a conveying path (F) by application of heat (W) or for cooling,
with at least one nozzle arrangement (2a, 2b) on at least one side (3a, 3b) of the conveyor path for blowing a particularly heated treatment medium (L) in the direction of the conveyor path (F),
wherein the at least one nozzle arrangement (2a, 2b) has a plurality of blowing nozzles (4) arranged next to one another and spaced apart (a), and an intermediate space (5) is formed between two adjacent blowing nozzles (4),
characterized in that the intermediate space (5) between the blowing nozzles (4) is essentially closed or closable towards the conveying path (F). Device according to claim 1, characterized in that the intermediate space (5) between the blowing nozzles (4) is closed in such a way that a pressure space (6) is formed between the at least one nozzle arrangement (2a, 2b) and the fiber composite (2) an overpressure (P) can be generated with the blowing nozzles (4). Device according to one of claims 1 or 2, characterized in that the intermediate space (5) is closed or lockable in such a way that with a given fiber composite (4) and with a given outlet speed (v) and outlet quantity (M) of the treatment medium (L) the treatment medium (L) can be blown through the entire thickness (d) of the fiber composite (V) into the blowing nozzles (4). Device according to one of claims 1 to 3, characterized in that the blowing nozzles (4) have a blowing opening (7) which ends adjacent to the surface (O) of the fiber composite (V). A method according to claim 4, characterized in that the distance (b) between the surface (O) of the fiber composite (V) and the blowing opening (7) is adjustable. Device according to one of claims 1 to 5, characterized in that the spaces (5) between the blowing nozzles (4) are closed or closable by sealing elements (8) which can be inserted, in particular pushed in, between the blowing nozzles (4). Device according to one of claims 1 to 6, characterized in that the blowing nozzles (4) are designed as slot dies which extend substantially over the entire width (B) of the conveying path (F) and that the blowing nozzles (4) with a nozzle box (9) is provided, which has a cross section (Q) which decreases from a connection opening (10) at which treatment medium (L) can be blown into the nozzle box (9) towards a closed end (11) of the nozzle box (9) , Device according to one of claims 1 to 7, characterized in that nozzle arrangements (2a, 2b) are arranged on both sides (3a, 3b) of the conveying path (F). Apparatus according to claim 8, characterized in that a plurality of blowing nozzles (4, 4 ') are combined into groups (12, 12') and that the groups (12, 12 ') of blowing nozzles (4, 4') can be activated and deactivated individually , Device according to claim 9, characterized in that the intermediate space (5) between deactivated blowing nozzles (4 ', 2b) can be opened or opened. Device according to one of claims 1 to 10, characterized in that the device (1) is provided with at least one fan (13) and with at least one heating device (14), which are designed such that per blowing nozzle (4) and meter working width 500 to 2000m ^{3 of} air per hour at a temperature of 0 to 300 ° C at a speed (v) of 0.5 to 70m per second can be blown against the fiber composite (V). Method for solidifying a fiber composite (V) by applying heat (W) to the fiber composite (V), characterized by the steps Conveying the fiber composite (V) along a conveying path (F), Blowing a particularly heated treatment medium (L) in the direction of the fiber composite (V) by means of blowing nozzles (4) arranged next to one another, each of which delimits an intermediate space (5), the space (5) being closed,
whereby an overpressure (P) is generated in a pressure chamber (6) adjoining the fiber composite (V), and wherein the treatment medium (L) is blown through the entire thickness (d) of the fiber composite (V). Method according to claim 12, characterized in that the treatment medium (L) is blown directly into the fiber composite (V) from a blowing opening (7) of the blowing nozzles (4) which is arranged adjacent to the surface (O) of the fiber composite (V) becomes. A method according to claim 13, characterized in that the distance (a) between the blowing opening (7) of the blowing nozzle (4) and the surface (O) of the fiber composite (V) is set to a predetermined value. Method according to one of claims 12 to 14, characterized in that the treatment medium (L), viewed in the conveying direction (R), is blown alternately from one side (3a) and from the other side (3b) against the fiber composite (V). Method according to claim 15, characterized in that groups (12, 12 ') of blowing nozzles (4, 4') on one side (2a, 2b) of the fiber composite (V) are alternately activated or deactivated,
and that the space (5) between deactivated blowing nozzles (4) is opened to allow the outflow of the treatment medium (L). Method according to one of Claims 12 to 16, characterized in that the treatment medium (L) is blown out of the blowing nozzles (4) at an exit speed (1) of 0.5 to 70 m per second and that 500 to 2000 m per blowing nozzle and meter of working width ³ per hour of the treatment medium (L) is blown out.

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