IT201900010047A1 - DISTRIBUTION DEVICE BY DIE - Google Patents

Description

DESCRIPTION

DISTRIBUTION DEVICE BY DIE

The present invention relates to a distribution device for spinnerets of the type specified in the preamble of the first claim.

In particular, the present invention relates to a distribution device adapted to collaborate with a spinneret for the production of filaments of extruded polymers which can also be intended to directly or indirectly produce fabric of the TNT type.

As is known, spinnerets are the terminals of plants suitable for allowing the production of polymeric filaments or fibers by means of the extrusion process.

Briefly, these plants are made up of at least three main groups: the power supply group, the distribution group and the extrusion group.

The feeding assembly includes at least one polymeric fluid feed channel adapted to convey the polymeric fluid towards the distribution assembly. The distribution assembly, on the other hand, substantially includes a network of small distribution channels preceded by filtering means suitable for filtering the polymeric fluid entering the distribution channels. Therefore, usually, the polymeric fluid, before reaching the extrusion group, is filtered and distributed through the distribution group.

The extrusion group substantially includes at least one die arranged downstream of the distribution group. This device may vary according to the types of use for which it is intended.

For example, if the plant is suitable for making non-woven fabric, the supply chain may have specific characteristics.

Non-woven fabric, or TNT, is an industrial product similar to a fabric but obtained with processes other than weaving and knitting. Therefore, within a non-woven, the fibers have a random pattern, without identifying any ordered structure while in a fabric the fibers have two prevailing and orthogonal directions to each other, usually called weft and warp.

Currently, a plurality of products containing TNT are made depending on the manufacturing technique used mainly connected to the use that is made of the product itself.

We distinguish, in particular, the high quality non-woven fabrics for hygienic-sanitary products and the low quality non-woven fabrics used above all for geotex.

From a technical point of view, non-woven fabrics, also known by the English-speaking term nonwoven fabric, can be substantially divided into spunlace, spunbond and melt-blown.

Naturally, each of the aforementioned techniques differs from the others especially as regards the extrusion group, that is, the supply chain.

In any case, all the distribution units include a small seat inside which is housed a filter substantially defined by a more or less dense metal grid arranged in adhesion with the distribution ducts and adapted to receive polymeric fluid from the supply duct. .

The known art described includes some important drawbacks.

In particular, as the spinneret is used to make polymeric filaments, the filter tends to become saturated with the consequence that the filter itself generates a cap effect on the spinneret which tends to significantly reduce the efficiency of the spinneret itself.

Furthermore, even when the filter is at full capacity, the current distribution units have a distribution efficiency that is limited above all by the fact that the filter removes part of the delivery space of the polymer fluid from the distribution ducts.

Therefore, such distribution groups are subject to significant drops in efficiency both at the start and as a result of processing cycles which involve a high level of maintenance to ensure the correct operation of the supply chain.

In fact, due to the inefficiency of the filters, the dies produce poor quality polymer filaments.

In this situation, the technical task underlying the present invention is to devise a distribution device for spinnerets capable of substantially obviating at least part of the aforementioned drawbacks.

Within the scope of said technical task, it is an important object of the invention to obtain a distribution device that allows to increase the delivery efficiency of the distribution ducts.

Another important purpose of the invention is to create a distribution device that allows to reduce or totally avoid the onset of the plug effect resulting from the saturation of the filter upstream of the distribution ducts.

In conclusion, a further purpose of the invention is to create a distribution device that allows, for any plant, for example spunbond or melt-blown plants but not only, to significantly increase the quality of extruded polymeric filament.

The technical task and the specified aims are achieved by a distribution device for spinnerets as claimed in the attached claim 1.

Preferred technical solutions are highlighted in the dependent claims.

The features and advantages of the invention are clarified below by the detailed description of preferred embodiments of the invention, with reference to the accompanying drawings, in which:

Fig. 1 shows a sectional view of a distribution device according to the invention in a first embodiment;

Fig. 2 illustrates a perspective view of the support of a distribution device according to the invention in a first embodiment;

Fig. 3 is a sectional view of a distribution device according to the invention in a second embodiment;

Fig. 4 represents a top perspective view of the support of a distribution device according to the invention in a second embodiment;

Fig. 5 shows a bottom perspective view, ie from the point of view of the die, of the support of a distribution device according to the invention in a second embodiment;

Fig. 6 illustrates an example of application of a distribution device according to the invention inside a spunbond system; And

Fig. 7 is an example of application of a distribution device according to the invention inside a melt-blown plant.

In this document, measurements, values, shapes and geometric references (such as perpendicularity and parallelism), when associated with words such as "about" or other similar terms such as "almost" or "substantially", are to be understood as less than measurement errors or inaccuracies due to production and / or manufacturing errors and, above all, unless there is a slight divergence from the value, measurement, shape or geometric reference to which it is associated. For example, these terms, if associated with a value, preferably indicate a divergence of no more than 10% of the value itself.

Furthermore, when used, terms such as "first", "second", "superior", "inferior", "main" and "secondary" do not necessarily identify an order, relationship priority or relative position, but can simply be used to more clearly distinguish different components from each other.

The measurements and data reported in this text are to be considered, unless otherwise indicated, as carried out in the ICAO International Standard Atmosphere (ISO 2533: 1975).

With reference to the Figures, the distribution device for spinnerets according to the invention is globally indicated with the number 1.

The device 1 is preferably adapted to distribute polymeric fluid inside plants for making polymeric filaments.

The systems can be of various types. For example, the device 1 can be part of a spunbond type TNT manufacturing plant, as shown in Fig. 6, or a melt-blown type TNT manufacturing plant, as shown in Fig. 7, or also of other types of systems, even simpler ones, generally suitable for making polymeric filaments.

The device 1 can therefore also coincide with a breaker plate of a TNT manufacturing plant.

The device 1 is, in general, substantially part of extrusion plants which can also include, as is known, feeding means and a die 4. In general, the feeding means can include a structure defining at least one duct inside the which the polymeric fluid flows at a temperature suitable for making the finished polymeric filaments.

The device 1 is therefore preferably adapted to be coupled with the power supply means by means of connections of a type known to those skilled in the art. In the same way, preferably, the device 1 is adapted to be coupled with a spinneret 4. The spinneret 4 is the terminal of any plant for making polymeric filaments and, in particular, can have structures that depend on the type of application to which the plant is in charge. For example, the spinneret 4 of a spunbond type plant, visible in Fig. 6, is different from the spinneret 4 of a melt-blown plant, visible in Fig.7. In any case, preferably, the device 1 is adapted to connect the feeding means and the spinneret 4 and is substantially interposed between them in such a way as to convey the polymeric fluid coming from the feed means to the spinneret in a controlled manner.

Moreover, in particular, the polymeric fluid preferably produces fibers chosen from nylon fibers, polyester fibers, acrylic fibers and carbon fibers. This means that preferably the polymeric fluid, introduced into systems which include the device 1, emerges from the spinneret 4 of the aforementioned systems preferably in the form of the aforementioned fibers.

It is specified that, as for the systems just described, the following description defines the device 1 considering the front section of the device 1 itself. Of course, even if not specified, each component also extends along the direction normal to the section plane considered for the description and visible, as evident for example in Figs.1-2.

The device 1, in particular, preferably comprises at least one filter 2 and a support 3.

The filter 2 is preferably adapted to filter the polymeric fluid in transit within the device 1. In particular, therefore, the filter 2 is able to withdraw polymeric fluid from the supply means, when the device 1 is in use, and to release the filtered polymeric fluid to the supply chain 4.

However, preferably, the filter 2 does not directly transfer the filtered polymeric fluid to the spinneret 4; in detail, preferably, the polymeric fluid is distributed from the filter 2 to the spinneret 4 by means of part of the support 3.

In this regard, preferably, the support 3 comprises broadly a seat 30 and a distribution portion 31.

The seat 30 preferably contains the filter 2. Furthermore, the seat 30 is configured so that the polymeric fluid can flow through it. In this regard, therefore, preferably the seat 30 is substantially a through hole made inside the support 3 which can have various shapes and sizes.

Preferably, the seat 30 defines a contour 300. The contour 300 substantially delimits the seat 30 and, therefore, preferably defines the housing space of the filter 2. Therefore, preferably, the contour 300 is the seat part inside which the filter 2.

The filter 2, therefore, is preferably counter-shaped to the contour 300 in such a way as to completely occupy the seat 30.

The distribution portion 31 is preferably arranged downstream of the seat 30 in such a way as to distribute the filtered polymeric fluid to the spinneret. Basically, preferably, the polymeric fluid passes inside the device 1 respectively in the seat 30 being filtered by the filter 2 and reaches, by gravity and / or under pressure, the distribution portion 31 where it is selectively distributed to the spinneret 4.

The distribution portion 31, in this regard, preferably includes a plurality of distribution ducts 310.

The distribution ducts 310 are substantially smaller ducts than the hole made by the seat 30, which can define a substantially cylindrical or even frusto-conical shape in some portions.

In any case, preferably, the distribution ducts 310 are adapted to convey the filtered polymeric fluid along a conveying direction 3a.

The conveying direction 3a is preferably defined by the distribution ducts 310 and substantially corresponds to the direction in which the filtered polymeric fluid is selectively conveyed to the spinneret 4.

Advantageously, the seat 30 and the distribution portion 31 are mutually separated by a separation space 32.

The separation space 32 is substantially an empty chamber which, when the device 1 is in use, can be filled exclusively with the filtered polymeric fluid.

Substantially, therefore, the separation space 32 is an interspace arranged between the filter 2 in the seat 30 and the distribution portion 31.

The separation space 32 preferably defines a thickness along the conveying direction 3a equal to at least 500 μm.

Even more in detail, preferably, the separation space 32 defines a thickness comprised between 500 μm and 3 cm.

In any case, preferably but not necessarily, the thickness of the separation space 32 is greater than or equal to the thickness of the filter 2. Therefore, the thickness of the filter 2 is preferably less than or equal to the thickness of the separation space 32.

The support 3, in addition to what has been said, comprises support means 33. The support means 33 can be part of the seat 30 and, indeed, define part of the seat 30. For example, in this sense, the support means 33 they can define a support frame extending at the contour 300 thus defining a support plane 3b.

The support plane 3b is preferably the plane on which the filter 2 rests. Furthermore, in particular, the support plane 3b is preferably perpendicular to the conveying direction 3a. In this way, preferably, when the filter 2 is inserted in the seat 30 resting on the support surface 3b, it remains homogeneously spaced from the distribution portion 31 so that the separation space 32 maintains a constant thickness.

In general, preferably, the support means 33 extend within the separation space 32 and are configured to support the filter 2 spaced from the distribution portion 31. The support means 33 can also be only protuberances extending along the conveyance direction. 3a starts from the distribution portion 31 towards the seat 30 and may not necessarily be arranged in correspondence with the contour 300.

The support means 33 could also be simple support spikes for the filter 2.

Filter 2 can be of any type. It can be a metallic grid defining meshes with a more or less dense density. Or, it can be of an unconventional type.

Preferably, the filter 2 includes at least one porous element 20.

The porous element 20 is substantially structurally similar to a sponge. In this sense it is not intended that the porous element is a soft and easily deformable element. On the contrary, the porous element is preferably defined, in terms of stiffness and hardness, by the materials and manufacturing processes that distinguish it.

However, also the porous element 20 includes, like the sponges, a plurality of pores which make the porous element 20 itself substantially inhomogeneous and anisotropic.

In particular, preferably, the porous element 20 is an element made with the sintering technique.

The latter, thanks to the manufacturing process, preferably includes a plurality of non-straight passage channels of variable or irregular dimensions. The term dimensions refers to all the dimensions that contribute to the volumetric determination of the cavities or pores characterizing the porous element 20.

More in detail, preferably, the filter 2 comprises a plurality of pores, or cavities, defining the passage channels when adjacent. In other words, the consequentiality of the pores creates the passage channels for the polymeric fluid.

Furthermore, preferably, each of the pores has a minimum porosity of 30 μm.

Even more in detail, the pores have a porosity preferably between 30 μm and 1 mm. Even more in detail, preferably the pores have a porosity preferably between 700 μm and 900 μm.

As already mentioned, the porous element 20 is preferably worked by sintering and, therefore, comprises a plurality of mutually sintered particles of the same material.

The particles can therefore be of any material, as long as it is resistant to the passage of the polymeric fluid. For example, the porous element 20 comprises metallic material.

Furthermore, the sintered particles can be of different nature.

For example, in a first embodiment, the particles can be components chosen from spheres or fragments.

In a second embodiment, the porous element 20 can comprise mutually intertwined and sintered filaments.

In a third embodiment, the porous element 20 can include a first layer and a second layer. Such layers are preferably mutually superimposed and include the components and filaments respectively as previously described. Alternatively, the third embodiment can also provide for the sintering in a single layer of both particles and filaments.

The porous element 20, therefore, also defines a thickness along the conveying direction 3a. Preferably, the porous element 20 has a minimum thickness of 500 μm. Even more preferably, the porous element has a thickness between 500 μm and 5 mm. Even more preferably, the porous element 20 has a thickness between 3 mm and 4 mm.

The operation of the supply chain distribution device 1 previously described in structural terms is as follows.

Substantially, the polymeric fluid passes through the device 1 inside the seat 30 and, therefore, through the filter 2. The filter 2 is able to continuously filter the polymeric fluid, crushing, during the passage, almost all the pigmented particles that they are trapped inside the filter 2 itself. The highly irregular conformation of the porous element 20, in fact, does not allow the polymeric particles to deposit and stratify as is the case with the mesh filters of the prior art.

In any case, even in the presence of conventional filters 2, the device passes the filtered polymeric fluid not directly from the filter 2 to the distribution portion 31, but provides for the transit of the filtered polymeric fluid inside the separation space 32.

The distribution device for dies 1 according to the invention achieves important advantages.

In fact, the device 1 allows, especially thanks to the interspace defined by the separation space 32, to reduce or even avoid the occurrence of plug effects of the filter 2 with respect to the device 1.

Furthermore, the conformation of the device 1 allows to increase the useful surface of the distribution portion 31 since the distribution ducts 310 are no longer partially obstructed by the filter 2 and the polymeric fluid can be distributed to the spinneret 4, considerably increasing the efficiency. of production. Therefore, as a consequence of what has been said, the distributor allows to increase the quality of the polymeric filaments made with systems which include the device 1.

Furthermore, also the porous element 20, if present, contributes to increasing the production efficiency of the polymeric filaments since it avoids the obstruction of the filter 2 by shattering, as mentioned, most of the polymeric particles that pass through the porous element. 20.

In general, therefore, a further advantage is given by the fact of significantly reducing the maintenance costs of the system, both in terms of money and time, increasing the efficiency and safety of the systems in which the devices 1 are installed.

The invention is susceptible of variants falling within the scope of the inventive concept defined by the claims.

In this context, all the details can be replaced by equivalent elements and the materials, shapes and dimensions can be any.

Claims (10)

CLAIMS 1. Distribution device (1) for spinnerets comprising - a filter (2) adapted to filter a polymeric fluid in transit within said device (1), - a support (3) configured to be arranged upstream of a spinneret (4) and including a seat (30) containing said filter ( 2) through which said polymeric fluid and a distribution portion (31) arranged downstream of said seat (30) can flow in such a way as to distribute said filtered polymeric fluid to said spinneret (4) and including a plurality of distribution ducts (310) adapted to convey said filtered polymeric fluid along a conveying direction (3a), and characterized in that - said seat (30) and said distribution portion (31) are mutually separated by a separation space (32) defining a thickness along said conveying direction (3a) at least equal to 500 μm. Device (1) according to claim 1, wherein said support (3) includes support means (33) extending within said separation space (32) and configured to support said filter (2) spaced from said distribution portion (31). Device (1) according to at least one preceding claim, in which said seat (30) defines a contour (300) defining the housing space of said filter (2) and said support means (33) define a support frame extending in correspondence with said contour (300) and defining a support plane (3b) for said filter (2) perpendicular to said conveying direction (3a). Device (1) according to at least one preceding claim, in which said polymeric fluid forms fibers chosen from nylon fibers, polyester fibers, acrylic fibers, carbon fibers, PLA and cellulose fibers. Device (1) according to at least one preceding claim, wherein said filter (2) defines a thickness along said conveying direction (3a) lower than or equal to the thickness of said separation space (32). Device (1) according to at least one preceding claim, wherein said filter (2) includes a porous element (20) defining a plurality of non-rectilinear and irregularly sized passage channels. Device (1) according to at least one preceding claim, wherein said porous element (20) comprises a plurality of pores defining said passage channels when adjacent and with a minimum porosity of 18 μm. Device (1) according to at least one preceding claim, wherein said porous element (20) comprises a plurality of mutually sintered particles of the same material. Device (1) according to at least one preceding claim, wherein said said porous element (20) comprises mutually intertwined, sintered, intertwined sintered filaments. Device (1) according to at least one preceding claim, wherein said porous element (20) comprises at least a first layer and a second layer mutually superimposed and respectively including said components and said filaments or a single layer comprising both said components and said mutually sintered filaments.