EP1239063A1 - Method for producing meltblown non-wovens, non-wovens produced thereby and use of such non-wovens - Google Patents

Abstract

Melt leaving the nozzle outlets (3.1) is blown by air streams (V1,V2) from air channels (L1,L2) on both sides to form fibers. The fiber flow (9) leaves the nozzle at an outlet angle ( alpha ) of 5-70 degrees , whose shanks (51,61) are formed by the long axis (5) through the polymer channel (2) in the nozzle and the central axis (6) of the diverted fiber flow.

Description

The present invention is generally concerned with a method of making meltblown nonwovens. The present deals in particular with Invention with the exit angle with which the fiber stream enters the nozzle opening leaves.

Meltblowing devices for the production of meltblown nonwovens are has long been known in the art. This is how the US patent is concerned 3,825,379 with a melt blowing device which, for example, for Implementation of the method according to the invention is suitable. The one in this writing Melting blow head consists of a series of polymer channels through which a stream of liquid plastic is fed to a meltblowing nozzle.

Air channels are assigned to this meltblowing nozzle from both sides, which inflate heated air at high speed onto the stream of liquid plastic leaving the meltblowing nozzle and defibrate and / or stretch it.
Opposite the meltblower head is a storage medium in the form of a drum, which collects the fiber stream formed and transports it away as a nonwoven fabric.
However, it is not apparent from US Pat. No. 3,825,379 that the fiber stream can run the melt blow head differently than in the same direction as the longitudinal axis of the polymer channel running through the nozzle opening.

US Pat. No. 5,676,388 is concerned with the production of a liquid distribution fleece from meltblown microfibers, which are deposited on the storage medium at an acute angle after leaving the meltblowing head. This creates a fiber density gradient.
However, it is also not apparent from the cited US patent that the fiber stream can leave the melt blow head differently than in the same direction as the longitudinal axis of the polymer channel running through the nozzle axis.
In order to generate a fiber density gradient across the cross section of the liquid distribution fleece, the cited document teaches that two or more layers of fibers of different strength are placed on a storage medium. Such a method is very complex in terms of machine technology, since several meltblowing units in a row are required for this.

German Offenlegungsschrift 41 23 122 deals with a device for producing a plastic nonwoven web. Here, a stream of liquid plastic is pressed through a sieve and stretched and cooled by laterally entering stretching air. This creates a fleece that has almost endless fibers.
Since the stretching air is guided to the point of impact of the fiber stream on the storage medium within an air channel, an exit angle of the fiber stream which, unlike in the same direction as the longitudinal axis of the polymer channel running through the nozzle opening, cannot be realized. The formation of a fiber density gradient is not provided in DE 4123122.

The US patent 4,714,647 is concerned with a filter medium which over the cross section has a fiber diameter gradient. The filter medium is manufactured by a process in which a large number of successive switched meltblowing heads microfibers of different fiber diameters are produced, these fiber layers together on a storage medium to be collected. This process is extremely complex in terms of machine technology because it is the series connection of many meltblowing heads in a line requires. Also in this document it is not mentioned that the fibers Melt blow heads other than the same direction as the longitudinal axis of the polymer channel leave.

The German design specification 27 35 063 deals with the production of thermal insulation for clothing. This is a fiber web made from a mixture of microfibers and staple fibers, the task of the staple fibers being to increase the bulk of the microfiber fiber mat, that is to say to lower the density of the fiber mat.
The addition of staple fibers to increase the bulk is necessary because, in contrast to staple fibers, melt-blown microfibers are mostly uncrimped and therefore make no contribution to bulkiness. The method disclosed in the cited document for the production of bulky meltblown nonwovens has the disadvantage that two nonwoven formation units, namely a device for meltblowing nonwovens, and a device for dissolving and metering in staple fibers are required for production. Again, this document does not mention that the fibers leave the meltblowing heads other than in the same direction as the longitudinal axis of the polymer channel.

The object of the present invention is to provide a method through which with a single blow head a meltblown nonwoven can be produced with a very wide range of individual fiber diameters has a gradient in the average fiber diameter has a high proportion of crimped fibers owns and can cover a wide range of densities, namely from Low density nonwovens with high bulk, up to thin nonwovens with high density.

A meltblown nonwoven fabric made by the method of the present invention can be used in the construction of a variety of objects, such as: B. as heat and / or cold insulation in clothing or technical objects, as sound insulation in the sound insulation of technical objects, as an absorbent for hydrophobic liquids, or as a particle filter.
In the particle filtration area, the fiber mat according to the invention serves as a filter medium, for example for the production of filter bags, flat filter inserts or pleated filter inserts in filter cartridges and cassettes. Filters of this type are used, for example, in the HVAC sector, for engine air filters, for passenger cabin air filters in motor vehicles or for the supply air filtration of electrical machines.

Especially with the pleated filter media mentioned, it is possible to use a correspondingly rigid design of the meltblown nonwoven supportive backing materials that stabilize the pleats. The degrees of separation of the air filters used according to the invention Process manufactured meltblown nonwovens (classified according to DIN EN 779) Separation classes from G 4, over F 5 to F 9, beyond that they can cover the HEPA and ULPA area.

Further possible uses of the process according to the invention Manufactured nonwovens are in hygiene articles, where they are particularly used as a means of Absorption and distribution of liquids, and as a means of storing Liquids can be used.

The listed areas of application of the method according to the invention Nonwovens manufactured are exemplary and are not intended to be restrictive in any way for applications not mentioned or which will still be considered in the future.

The invention results from the features of claim 1, advantageous Configurations, nonwoven fabrics produced by the method according to the invention, and applications for this result from the subclaims.

Explanation of the drawing:

Figur 1 bis Figur 3 zeigen den Schnitt durch einen Schmelzblaskopf und erläutern jeweils unterschiedliche Methoden zur Erreichung des Austrittswinkels α.

Die Figuren 4 bis 10 zeigen beispielhaft schematisch unterschiedliche Varianten des Auftreffens des Faserstromes auf ein Ablagemedium und des Abtransportes des Faservlieses.

The method according to the invention is explained as follows with reference to the accompanying drawings:

Figure 1 to Figure 3 show the section through a melt blow head and each explain different methods for achieving the exit angle α.

FIGS. 4 to 10 schematically show examples of different variants of the impact of the fiber stream on a storage medium and the removal of the fiber fleece.

In the inventive method of manufacturing a meltblown fibrous web 11 (Figure 4), a fiber stream 9 is produced by means of a Schmelzblaskopfes 1 that with an exit angle α of 5 to 70 degrees, which from the plane passing through the nozzle opening 3.1 longitudinal axis 5 of the polymer passage 2 as the first leg 51 of the exit angle α and of the central axis 6 of the fiber stream 9 is formed as the second leg 61 of the exit angle α, leaves the nozzle opening 3.1 and is deposited on a storage medium A to the nonwoven fabric 11 and is pulled off.

For this purpose, the liquid plastic, which can be temporarily stored in a chamber 10 , enters the polymer channel 2 and leaves the polymer channel 2 at the nozzle opening 3.1 .

At the same time , blowing air heated via the air channels L 1, L 2 , which is formed from the volume flows V1 and V2 and leaves the air channels L 1, L 2 through a respective air gap S1, S2, acts on the flow of liquid plastic.
Depending on the intensity of the blown air, fibers can arise, which are referred to as endless in the textile industry.
The stream of liquid plastic can also be torn apart in such a way that a large number of short to very short fibers are formed.

The fibers produced by this process are commonly called microfibers designated and generally have individual diameters of 1 - 100 microns. Very are frequently used in nonwoven fabric produced by the method according to the invention Fiber diameters from 1 µm to 50 µm were found. In addition, these can Firmly assemble fibers to form agglomerates with diameters from 30 to 150 µm were found.

FIG. 1 shows a first preferred embodiment of the method according to the invention. Here, the stream of liquid plastic, which leaves the polymer channel 2 at the nozzle opening 3.1 , by heated blown air by means of a first volume flow V1 and a second volume flow V2, which the first air channel L1 and the second air channel L2 at the air gaps S1 and S 2 leaves frayed and / or stretched. The air gaps S1 and S2 can have the same size.
In the first preferred embodiment shown in FIG. 1, the volume flow V1 has a lower value than the volume flow V2. Accordingly, the fiber stream 9 is deflected after the nozzle opening 3.1 at an exit angle α, which extends through the nozzle opening 3 , the longitudinal axis 5 of the polymer channel 2 as the first leg 51 of the exit angle α and through the central axis 6 of the fiber stream 9 as the second leg 61 of the exit angle α ,
Accordingly, for the preferred method shown in FIG. 1, it follows that the quotient of the first volume flow V1 and the second volume flow V2 is less than 1, that is to say the first volume flow V1 is less than the second volume flow V2.

In a particularly preferred embodiment of the method according to the invention, the quotient of V1 and V2 is less than 0.97.

For the preferred embodiment shown in FIG. 1, as well as for all the other embodiments shown in the figures, it goes without saying that they can also be mirror images of the embodiments shown in the figures. It is thus also possible, for example, for V1 to make up the larger and V2 the smaller of the volume flow, the fiber flow 9 then being deflected in the opposite direction.

FIG. 2 shows a further preferred embodiment of the method according to the invention, the transport of the liquid plastic being essentially identical to the method described in FIG. 1. In contrast, the volume flows V1 and V2 can, however, be the same in this preferred embodiment. In this second preferred embodiment of the method, however, the air gaps S1 and S2 are of different widths. Since, as shown in FIG. 2, the air gap S1 is larger than the air gap S2, the blown air leaves the larger air gap S1 at a lower speed than the leaving the smaller air gap S2 at the same volume flows V1 and V2 .
In turn the exiting at a higher speed blowing air of the air gap S2 deflects the fiber stream 9 in an exit angle α of 5 ° - from 70 °, which in turn by the running through the nozzle opening longitudinal axis 5 of the polymer passage 2 as the first leg 51 and through the central axis 6 of the fiber stream 9 is formed as a second leg 61 .

FIG. 3 shows a further preferred embodiment for carrying out the method according to the invention. In this case, the transport of the liquid plastic through the polymer channel 2 to the nozzle opening 3 is essentially identical to the embodiment in FIG. 1. In this preferred embodiment, the volume flows V1 and V2 have essentially the same value. The air gaps S1 and S2 also have the same size.

However, in this further preferred embodiment is located on the opposite side to the deflection a Luftleitbleich 12, in which the air deflector deflects the emerging from the air gaps S1 and S2 heated blast air for defibering and / or stretching of the stream of liquid plastic 12 opposite direction.
In particular, the scattered air surrounding the fiber stream 9 is reflected by the air bleach 12 in such a way that it is deflected after the nozzle opening 3.1 at an exit angle α, which corresponds to the features mentioned, to the side opposite the air baffle.
Since the fiber stream 9 is a mixture of fibers and air, the entire fiber stream 9 is of course deflected after the nozzle opening 3.1 at an exit angle α, which corresponds to the features mentioned.

It goes without saying that the three preferred embodiments for Reaching the exit angle α both on its own and in combination used with each other to carry out the method according to the invention can be and this does not contradict the meaning of the present invention.

It has been shown that with an exit angle α of at least 5 degrees and at most 70 degrees, the best effects result in the nonwoven fabric 11 with respect to a very wide range of individual fiber diameters and on the fiber thickness gradients.
The minimum value of 5 ° should therefore be adhered to because, with a smaller value, the effect mentioned in the aim of this invention can no longer be sufficiently achieved.
An angle of more than 70 ° is difficult to implement from a mechanical engineering point of view, since there are fears that the machine parts delimiting the air gap S1 could lead to fiber deposits and therefore to malfunctions. The exit angle α is limited on the one hand by the longitudinal axis 5 of the polymer channel 2 running through the nozzle opening 3.1 as its first leg 51.
The second leg 61 of the exit angle α is formed by the central axis 6 of the fiber stream 9 .

It should be shown as a model that the fiber stream 9 usually has the cross-section of a three-legged triangle, the tip of which lies at the nozzle opening 3.1 and the imaginary base 7 forms the side of the cross-section of the fiber stream 9 facing the storage medium A. The central axis 6 of the fiber stream 9 can accordingly be regarded as the height of the triangle mentioned.

After leaving the nozzle opening 3.1 of the melt blow head 1 , the fiber stream 9 is deposited on a rotating storage medium A (A 1, A 2) to the nonwoven fabric 11 and drawn off. The storage medium A can have the shape of a collector drum A1 or the shape of a collector belt A2 .

FIGS. 4 to 10 show preferred embodiments of depositing the fiber stream 9, which leaves the nozzle opening 3.1 at an exit angle α of 5-70 °.

It should be noted that this series of examples does not Restrictions on other ways to do this should mean method according to the invention, as long as these embodiments are covered by the appended claims.

For further explanation it should be mentioned that in the present examples a vertical production direction, i.e. from top to bottom. Naturally but a horizontal direction of production is also possible, such as in U.S. Patent No. 3,825,379, Figure 1.

The removal of the nonwoven fabric 11 can be done in various ways.

In a first preferred embodiment, the nonwoven fabric 11 is drawn off in the opening direction of the exit angle α, the opening of the exit angle α starting from its first leg 51 and the first leg 51 of the exit angle α, which is the longitudinal axis 5 of the polymer channel 2 extending through the nozzle opening 3.1 . Such a pull-off is preferably chosen when the nonwoven fabric 11 produced by the method according to the invention is to have a high uniformity with low cloudiness and high density.

In a preferred embodiment thereof, the nozzle opening 3.1 of the melt blow head 1 is located directly above the zenith of the collector drum A1. This embodiment is particularly suitable when the exit angle α has a small or medium amount, and the fiber stream 9 can still be safely deposited on the collector drum A1 and not next to it by this embodiment.

4 shows the shelf on the collector drum A1, with the zenith of the collector drum A1 below the nozzle opening 3.1 is exactly the Schmelzblaskopfes. 1 The nonwoven fabric 11 is drawn off in the opening direction of the exit angle α, the opening of the exit angle α in this, as in all the following examples, starting from its first leg 51, namely the longitudinal axis 5 of the polymer channel 2 running through the nozzle opening 3.1 .

In a further preferred embodiment, the nonwoven fabric 11 is pulled off against the opening direction of the exit angle α, the exit angle α opening again from its first leg 51 . This further preferred embodiment is preferably chosen when value is placed on low density, ie high bulk of the nonwoven fabric 11 produced by the method according to the invention. This preferred embodiment results in a crushing and kinking process in the area of impact of the nonwoven fabric 9 on the collector drum A1 , which gives the still soft fibers of the nonwoven fabric 11 a crimp, so that at least 50% of the fibers of the nonwoven fabric 11 are present in a crimped state.

The crimp of the fibers of the nonwoven fabric 11 has the advantage for the nonwoven fabric 11, that the ball of the nonwoven fabric 11 is increased, so the density of the nonwoven fabric 11 is lowered. The densities that can be achieved here are, for example, 60 kg / m ³ or less.
This can be explained in such a way that, due to the crimped arches, the otherwise plane-oriented fibers, viewed across the cross-section of the nonwoven fabric 11 , can maintain a distance from one another, the nonwoven fabric 11 experiencing good porosity, that is to say good permeability to fluids such as gases or liquids.

This crimping of the fiber of the nonwoven fabric 11 is, in contrast to, for example, crimped, textile staple fibers of the prior art, essentially irregular, whereby the crimping intensity, the crimping bow height and the crimping bow frequency can fluctuate very strongly within a very short fiber path. The crimped sheets can be arranged in two or three dimensions. The crimp can be a primary crimp. Primary crimp in the sense of this invention is understood to mean a zigzag crimp or sinusoidal crimp of the fiber body itself, the fiber provided with primary crimp usually forming a straight or serrated straight line again.

A secondary crimp can be superordinate to the primary crimp. This Secondary crimp generally has larger amplitudes as well as larger ones Wavelengths as the primary crimp, with that of the secondary crimp underlying fiber body can again have the primary crimp.

The primary crimping of the fibers of the nonwoven fabric 11 has a very low amplitude of, for example, 0.1 to 1 mm, with a quantity of, for example, 2 to 100 crimping sheets per centimeter.

The secondary crimp can have a higher amplitude and has in generally less than two crimps per centimeter.

FIG. 5 shows this preferred embodiment of the method according to the invention, the zenith of the collector drum A1 again being exactly below the nozzle opening 3.1 of the melt blow head 1 . In this preferred embodiment, the nonwoven fabric 11 is drawn off in the direction opposite to the opening direction of the exit angle α, the opening of the exit angle α starting again from its first leg 51 .

In a further embodiment, the nozzle opening 3.1 of the blow head 1 is outside the zenith of the collector drum A1. Such an embodiment of the method according to the invention is preferred if either the exit angle α should be so large that it is no longer possible to deposit the fiber stream 9 on the collector drum A1 and there is a risk that the fiber stream 9 next to the collector drum A1 and not on this will hit.
Such an embodiment of the invention is additionally preferred if the fiber stream 9 is to hit the edge region of the collector drum A1 , for example in order to achieve different flight paths of the fibers of the fiber stream 9, which are located on the outer edge and on the inner edge of the fiber stream 9 .

FIG. 6 shows a further preferred embodiment of the method according to the invention, the nozzle opening 3.1 of the melt blow head 1 being outside the zenith of the collector drum A1 . This results in a steep angle of incidence of the fiber stream 9 on the collector drum A1 . The nonwoven 11 is drawn off in the opening direction of the exit angle α.

FIG. 7 shows a further preferred embodiment of the method according to the invention, the nozzle opening 3.1 of the melt blow head 1 again being outside the zenith of the collector drum A1 . In this further preferred embodiment, however, the melt blow head 1 is located, for example, on the opposite side of the zenith of the collector drum A1 as shown in FIG.
The removal of the nonwoven fabric 11 takes place again against the opening direction of the exit angle α, which can result in a particularly bulky nonwoven fabric 11 .

In a further preferred embodiment, the storage medium A is a collector belt A2. A collector belt A2 is also suitable as storage medium A for the fiber stream 9 produced by the method according to the invention.

FIG. 8 shows such a preferred embodiment of the method according to the invention, the fiber stream 9 being collected on a collector belt A2 and the fiber fleece 11 being drawn off in the opening direction of the exit angle α.

FIG. 9 shows a further preferred embodiment of the method according to the invention, which essentially corresponds to that of FIG. 8, with the difference that the nonwoven fabric 11 is drawn off against the opening direction of the exit angle α.

FIG. 10 shows a further preferred embodiment of the method according to the invention, which essentially corresponds to the embodiment described in FIG. 8, with the exception that the collector belt A2 is inclined, e.g. B. to achieve different trajectories of the fibers, which are located in the outer edge of the fiber stream 9 and the inner edge of the fiber stream 9 .

The fibers of the nonwoven fabric 11 produced by the method according to the invention have a very large scatter in the diameters. For example, 11 fibers with a diameter of 1 µm to fibers with a diameter of 100 µm were measured in one and the same nonwoven. Very often, fiber diameters from 1 μm to 50 μm are found in nonwovens produced by the process according to the invention. Surprisingly, there are coarse fibers, preferably on one side of the nonwoven fabric 11 , the fine fibers accumulating on the opposite side of the nonwoven fabric 11 .
This phenomenon is explained by the fact that a different amount of air is applied to the underside of the fiber stream 9 than the top of the fiber stream 9.

This results in different drawing forces, which in turn result generate different fiber diameters.

This effect is reinforced by the fact that the fiber stream 9 leaves the nozzle opening 3.1 at an exit angle α of 5 to 70 ° and the fibers on the upper side of the fiber stream 9 have a further flight path than the fibers which are located on the underside of the fiber stream 9 ,

A fiber diameter gradient can thus form within the cross section of the nonwoven fabric 11 , that is to say that the mean fiber diameter changes continuously in the course of the cross section of the nonwoven fabric 11 .

Examples I to IV

Example I: Name of the pattern M1 Flow rate V1 [ft ³ / min] 280 Volume flow V2 [ft ³ / min] 350 Quotient V1 / V2 0.8 Exit angle α approx. 47 ° storage medium collector drum Position of the storage medium Zenith under the nozzle opening withdrawal direction in the opening direction of the trigger angle α Fiber curl Yes Fiber diameter of the nonwoven from-to 2 to approx. 47 µm Fiber diameter gradient present Yes Basis weight of the nonwoven 100 g / m ² Density of the nonwoven approx. 80 kg / m ³ Example II: Name of the pattern M2 Flow rate V1 [ft ³ / min] 280 Volume flow V2 [ft ³ / min] 350 Quotient V1 / V2 0.8 Exit angle α approx. 47 ° storage medium collector drum Position of the storage medium Zenith under the nozzle opening withdrawal direction against the opening direction of the trigger angle α Fiber curl yes, strong Fiber diameter of the nonwoven from-to approx. 2.5 to 63 µm Fiber diameter gradient present yes, clearly Basis weight of the nonwoven 120 g / m ² Density of the nonwoven 35 kg / m ³ Example III Name of the pattern M3 Flow rate V1 [ft ³ / min] 300 Volume flow V2 [ft ³ / min] 300 Quotient V1 / V2 1.0 1. Air gap opening: 1.3 mm 2. Air gap opening: 1.6 mm Exit angle α approx. 28 ° storage medium collector drum Position of the storage medium Zenith under the nozzle opening withdrawal direction in the opening direction of the trigger angle α Fiber curl Yes Fiber diameter of the nonwoven from-to 2 to approx. 34 µm Fiber diameter gradient present Yes Basis weight of the nonwoven 110 g / m ² Density of the nonwoven approx. 95 kg / m ³ Example IV (counterexample) Name of the pattern MG4 Flow rate V1 [ft ³ / min] 300 Volume flow V2 [ft ³ / min] 300 Quotient V1 / V2 1 Exit angle α approx. 0 ° storage medium collector drum Position of the storage medium Zenith under the nozzle opening withdrawal direction in the opening direction of the trigger angle α Fiber curl No Fiber diameter of the nonwoven from-to 2 to approx. 10 µm Fiber diameter gradient present No Basis weight of the nonwoven approx. 100 g / m ² Density of the nonwoven approx. 120 kg / m ³

Discussion of the results :

Examples I to III were based on features according to the invention Process manufactured. Example IV is a comparative example as it is according to a State of the art method was manufactured.

Example I and Example II differ essentially only in the direction in which the nonwoven is drawn off from the storage medium. From the comparison of the result tables it is clear that both fiber fleeces have a large scatter in the diameter of the individual fibers, which is advantageous for use in air filters with a low pressure difference and high separation efficiency.
The nonwoven fabrics of both examples show a fiber diameter gradient across their cross-section, the fiber diameter gradient being more evident in the pattern M2 of example II.
However, the main difference between pattern M1 and pattern M2 is their density, which is much higher with pattern M1 than with pattern M2. The pattern M2 is therefore particularly suitable, for example, as heat insulation in clothing, or, if necessary, in the state laminated with spunbonded nonwoven as a filter medium for pocket filters of separation classes F 5 to F9 (classification according to DIN EN 779.
The pattern M1, however, is suitable because of its small thickness and because of its fiber thickness gradient as a pleatable filter medium, for. B for pleated filter cassettes, and due to its good rigidity, it does not require a support medium such as a grid or spunbond.

In the production of the sample M3 of Example III, the withdrawal angle was α generated by means of different air gaps, the volume flows being the same Had values. The nonwoven fabric obtained in this way also corresponds to that in the target of Features defined invention.

The sample MG4 of Example IV was produced using a method which corresponds to the prior art. The fiber diameters are in a narrow range, the fibers are largely uncrimped, the density is very high at 120 kg / m ³ . Such a nonwoven fabric is not suitable for the purposes mentioned.

Claims (13)

Process for producing a melt-blown nonwoven fabric made of thermoplastic, in which a stream of liquid plastic is conveyed through polymer channels into a row of nozzles arranged along a straight line and, after leaving the nozzle, through streams of blowing air acting from both sides, which via Air channels that open into an air gap, the stream of liquid plastic are fed, defibrated and / or stretched, with a first air stream from the first side, with a first volume flow through a first air channel with a first air gap, and from the second Side a second air flow with a second volume flow through a second air channel with a second air gap strikes the flow of liquid plastic, wherein a fiber stream is formed, which is deposited and drawn off on a rotating storage medium to the nonwoven fabric
characterized in that the fiber stream (9) leaves the nozzle (3) at an exit angle α of 5 ° to 70 °, the legs (51, 61) of which extend on the one hand from the longitudinal axis (5) running through the central center of the nozzle opening (3.1) of the polymer channel (2) and, on the other hand, from the central axis (6) of the fiber stream (9) deflected from the nozzle opening (3.1). The method of claim 1
characterized in that the quotient of the first volume flow V1 and the second volume flow V2 is less than 1 and the fiber flow (9) is deflected in the direction of the air duct (L1) with the first volume flow V1. The method of claim 2
characterized in that the quotient of the first volume flow V1 and the second volume flow V2 is less than 0.97. The method of claim 1
characterized in that the first air gap (S1) is larger than the second air gap (S2) and the fiber stream (9) is deflected in the direction of the first air gap (S1). The method of claim 1
characterized in that an air baffle (12) is arranged after the nozzle (3) outside the fiber stream (9). The method of claim 1
characterized in that the nonwoven fabric (11) is drawn off in the opening direction of the exit angle α, the opening of the exit angle α starting from the first leg (51) thereof. The method of claim 1
characterized in that the removal of the nonwoven fabric (11) takes place counter to the opening direction of the exit angle α, the opening of the exit angle α starting from the first leg (51) thereof. Nonwoven fabric produced by the method of claim 1,
characterized in that it contains fibers in a single fiber thickness range of 3 µm and 50 µm. Nonwoven fabric produced according to the features of claim 1,
characterized in that it contains fibers in a single fiber thickness range of 1 µm and 100 µm. Nonwoven fabric produced according to the features of claim 1,
characterized in that the fiber thickness forms a gradient across the cross-section of the non-woven fabric (11). Nonwoven fabric produced according to the features of claim 1,
characterized in that at least 50% of the fibers have crimp. Use of the nonwoven fabric according to claims 8-11 as a strapless pleated filter medium for the filtration of fluids such as gases or liquids. Use of the nonwoven fabric according to claims 8-11 as a filter medium for the area of deep filtration, in pocket form or in flat form.

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