DE102005048939A1 - Centrifugal melt spinning, especially for producing nanofibers, uses an air stream to guide and treat fibers emerging from rotating melt container - Google Patents

Abstract

A heated (3), part cone-shaped container (1) is supplied (2) with molten polymer and rotates at high speed, e.g. 25000 revolutions per minute. Polymer emerges from an exit (4) at the edge, e.g. a number of holes of 500 mu m diameter, and is then treated and guided without further contact, e.g. by a gas stream (5). The gas stream can be air or nitrogen supplied by a fan or pump. An electrical potential difference can be applied between the container (1) and the surface on which the fibers are deposited. An independent claim is included for a process in which fluid material is converted into fibers by centrifugal force and then guided and stretched without contact. The fibers are in the region of 50 nm to 200 mu m in diameter and deposited into a matrix. The material can be heated (3) up to 450 [deg]C by infra-red radiation, hot air or a hot plate integrated into the container (1).

Description

technical area

The Invention relates to a device for producing fibers, comprising a container for receiving raw fiber material, wherein the container by at least one heat source is heated, the container is rotatable and wherein the container exit areas for the fiber raw material having. The invention further relates to an arrangement of several devices. The invention further relates to a method for producing fibers, wherein fiber raw material is placed in a container is, where the container is rotated and wherein the fluidized fiber raw material by centripetal forces from the container is discharged in the form of fibers. Finally, the invention relates an arrangement comprising a layer comprising fibers, wherein the fibers produced by said method or apparatus are.

such Devices and methods are already known in the art known. The generic devices and methods utilize the during rotation of the container occurring Zentripetal- or centrifugal forces. Cause these forces that parts of molten fiber raw material in the tangential direction be moved away from the exit areas.

The Geometry of the produced fibers can be achieved by a variety of influenced by chemical or physical parameters. Out the prior art, it is known, the speed of the container so to choose that the centripetal forces a certain strength to reach. Alone by adjusting the strength of the centripetal forces it possible the To influence fiber diameter.

The produced fibers are subject to a distribution curve, which covers a whole spectrum of fiber thicknesses, fiber lengths and fiber shapes. hereby When using the generic devices a significant Scrap generated.

presentation the invention

Of the The invention is therefore based on the object, fiber products defined Fiber structure to produce easily.

The present invention solves the aforementioned object by the features of the claim 1. Thereafter, an initially mentioned device is characterized in that that the exit areas means for directional, contactless guide from the container associated with exiting fiber raw material.

According to the invention is recognized been that the fiber geometry through a variety of parameters can be influenced. In a next Step has then been recognized that the fiber geometry in particular adjustable after leaving the container is. After all has been recognized that a contactless and defined leadership of the Fibers before they hit a collector, a Modification of the fibers allowed. It has been recognized that alone the duration of the tour or the direction of the leadership Influence on the fiber length, the Fiber diameter and the fiber structure decreases. Also according to the invention have been recognized that a directed contactless leadership produces a more homogeneous fiber spectrum than a production process without Guide. Concretely, the width of a distribution curve can be determined solely by the guidance all Fiber properties are set. This can reduce the amount on fibers with unwanted Fiber geometry can be significantly reduced.

consequently the task mentioned at the beginning is solved.

In a structurally particularly favorable embodiment could the means comprise a gas flow. It is conceivable that the fibers transported by a gas stream become. If the gas stream is formed laminar, the Fibers are stretched and formed between the laminar layers.

In front From this background it is also conceivable that the means a gas flow field include. A gas flow field could to be composed of the interplay of several currents. It is conceivable that the fibers stretched in a first flow, in the context of a second flow diverted and under a third flow through a chemical treatment functionalized and / or cooled become. It is conceivable that the individual flows different temperatures and / or speeds.

When Gas could Air act. Air is a cheap gas, which is characterized that distinguishes a manufacturing process at atmospheric pressure carried out could be.

It is also conceivable that instead of air further gases, in particular inert gases such as nitrogen are used. This ensures that Fiber raw material is processable, which includes reactive groups or prone to post-reaction after leaving the container.

The Could mean fan include. fan make cost-effective Apparatuses through which easily blown away fibers or can be sucked. Against this background, it is also conceivable that the means fans or pumps.

The container could as a truncated cone-like hollow body be educated. It is conceivable that the hollow body in such a way is arranged so that it tapers upwards. This concrete configuration provides sure that a melt of the fiber raw material during rotation of the container do not spill out of this.

The container could be filled from above. this makes possible the filling of the container during that Rotation. In that regard, a continuous manufacturing process is easy realizable.

the container could Be assigned tear-off edges, which cause gas flows or turbulence be deflected in an advantageous manner, distracted or interrupted. The demolition edges could peripherally on the container be arranged and configured as a radially projecting protrusions.

The Exit areas of the container could as passages be designed. It is conceivable that the passages circular, oval or rectangular are designed. In dependence from the shape of the passages can be influenced on the fiber geometry.

The crossings could have a diameter or width up to 500 microns. This dimensioning has proven to be particularly beneficial for the production of nanofibers and microfibers proved. The passageways could be at a distance of be positioned one centimeter apart. It is also conceivable that the passages in several rows one above the other are arranged. This is the throughput of fiber raw material in a particularly simple manner steigerbar. By reducing or enlarging the Diameter it is possible Nano or microfibers in the range of 50 nm to 200 microns to produce.

The container could be rotatable with up to 25,000 revolutions per minute. By this high Speed is it possible To produce nanofibers with a diameter of 50 nm. Usually Nanofibers using an electric spinning process using an electric field generated. By a suitable constructive Design of the container as well as very high rotational speeds, however, it is possible without electric field To produce nanofibers from a melt. By selecting the rotation speed and viscosity of the fiber raw material also fibers with a larger diameter be generated.

A heat source could be designed as a radiant heater. A radiant heater has the advantage that the heat radiation even at the highest Speeds of the container can easily act on the fiber raw material. In that regard, can to dispense with a heater, which on the container directly is appropriate and only under major equipment problems with Electricity is available.

In front In this background, it is conceivable that a heat source as an infrared radiator is designed. An infrared radiator allowed by a suitable optical Establishment of a focus of the heat energy directly on the container or in the interior of the container. It is conceivable that the optical device lenses and mirrors which directs the infrared light directly and selectively to heated Volume directs. This specific embodiment minimizes scattering losses and not wanted warming other parts of the device.

A particularly cost-effective heat source represents a hot air blower. In that regard could a heat source designed as a hot air blower be.

A heat source could in the container be integrated. This structural design realizes a particularly homogeneous heating of the entire container. It is conceivable that the container is metallic or comprises metallic body and by a Resistance heating can be heated is.

In front This background is also an inductive heating of the preferably metallic container conceivable. A warming by induction can be realized particularly fast, whereby the Processing chemically rapidly changeable Fabrics possible is. Due to low melting times, a reactive substance remains only very short time in the melt, so no unwanted Reactions can take place, before the fabric is made into fibers.

A heat source could also inside the container be arranged statically and the container around the heat source rotate. This embodiment allows lowest losses Thermal energy, because the heat radiation enclosed by the container and inside the container is reflected. In this embodiment, the heat source could be designed as a heating plate.

The container could be heated to 450 ° C be. This embodiment advantageously allows use of virtually all thermoplastic fiber-forming materials as fiber raw material. It is conceivable that polyesters, polyamides, polyurethanes, polylactides and polyhydroxybutyrate / polyhydroxyvalerate copolymers and also native sugars, for example sucrose, or mixtures of the substances mentioned are used. In addition, the fiber raw material could include polyolefins or reactive polymers. It is conceivable that polypropylene, polypropylene grafted with acrylic acid and / or modified polypropylene are used.

The Use of biodegradable substances such as gelatine as fiber raw material allows the Generation of fibers that are easy to dispose of. Furthermore can with these fibers medical products such as wound dressings or Cell growth drivers be made.

All mentioned substances used alone or mixed with other than fiber raw material Find.

Of the Device could be associated with a storage device for receiving fiber raw material. The storage device could be designed as a platform on which the fibers to form a fibrous pile can be stored. It is also conceivable that the storage device is a rotating device on which Fibers for coating a cylindrical body or for producing a Wickelvlieses be included.

Between the storage device and the container could be an electrical potential difference. This specific embodiment allows the production of electrostatic charged fibers. Such fibers are especially for use suitable as a particle filter, since their electrostatic charge suspended particles from the air.

Of Furthermore, it is conceivable that the electrical potential difference to support the production of nanofibers is used. Add this the effects of centripetal forces and the electric field, d. H. The fiber raw material is tangential on the one hand by the centripetal forces in thin threads from the rotating container thrown away and further by the electric field, if necessary further split up. In that regard, conceivable is a manufacturing process to realize, by which fibers can be produced in the subnanometer range.

The The object mentioned at the outset is further characterized by an arrangement solved with the features of claim 20. After that are several devices of the type mentioned arranged in a matrix. It is under one Matrix any areal or spatial Arrangement for the defined production of nonwovens or nonwovens to understand.

Around Avoiding repetitions becomes in relation to the inventive activity on the designs referred to the device as such.

Also The object mentioned above by the features of the claim 21 solved. After that is a generic method characterized in that directed the exiting fibers are guided contactless.

Around Be sure to avoid repetition in relation to the inventive step the designs referred to the device as such.

It could Fibers are produced, which have a diameter of 50 nm to 200 microns. In that regard, a production of nanofibers is possible without an electrostatic Field must be used.

The Fiber raw material could already introduced in fluidized form in the container. hereby Is it possible, to carry out a continuous process, namely the Fiber raw material outside of the container heated becomes. However, it is also conceivable to first fluidize the fiber raw material, after putting it in the container was introduced.

The Procedure could under defined setting of the viscosity of the melt, the surface tension the melt, the temperature of the melt and the rotational speed are performed. An optimization of these parameters could be used to set the desired Fiber diameter can be used. It is conceivable that the Melt be added to modify the surface tension surfactants. In particular, it is conceivable that partially or perfluorinated surfactants or tetraethyl benzyl ammonium chloride find use.

The execution of the process is using any of those described Devices conceivable.

The This task finally becomes solved by an arrangement according to claim 23. Such an arrangement comprises a fiber-comprising layer, wherein the fibers by a method or a device according to any one of the preceding claims are.

Around Be sure to avoid repetition in relation to the inventive step the designs referred to the device as such.

Nanofibers which according to the said method or by said device produced in air filters, liquid filters or acoustic damping elements Find use. Layers of such fibers have a very low porosity and high surface so that filters and damping elements formed therefrom have very good filtering and damping characteristics exhibit.

arrangements, which fibers comprise, by a previously described method or a device described above could be manufactured in medical use as they are with regard to their fabric structure and material composition are very well modifiable. For example, it is conceivable to set the tissue structure so that an arrangement can act as a wound dressing, namely, if the Fiber fabric structure can well grow together with the human tissue. Other medical applications such as use as a cell growth carrier are conceivable.

arrangements, which fibers comprise, by a previously described method or a device described above could be considered as Battery or battery separator be configured. Especially could Such a battery may be configured as a NiCd battery. The after the method or with the said device produced fibers feature due to its high specific surface area it has a very good fluid absorption capacity. Therefore, you can Nonwovens made from these fibers as separators in batteries use find where to get the electrolyte fluid be able to record.

It are now different ways to design the teaching of the present invention in an advantageous manner and continue to form. This is on the one hand to the downstream Claims, on the other hand, to the following explanation of a preferred embodiment the device according to the invention referring to the drawing. In conjunction with the explanation of the preferred embodiment With reference to the drawing are also generally preferred embodiments and further developments of the teaching explained.

Brief description of the drawing

In the drawing shows the only one

FIG. in a schematic view of an apparatus for generating fibers

Execution of the invention

The only Fig. Shows a container 1 for receiving fiber raw material 2 , where the container 1 through a heat source 3 is heated, the container 1 is rotatable and wherein the container exit areas 4 for the fiber raw material 2 having. The exit areas 4 are means 5 for directional, contactless guidance of the container 1 exiting fiber raw material 2 assigned.

The means 5 are designed as a fan, which generate an air flow, in which the fiber raw material is guided in a defined contactless. The blower acts as a suction device.

The container 1 is designed as a truncated cone-like hollow body. The container 1 is from the top with fiber raw material 2 fillable.

The exit areas 4 of the container 1 are designed as passages which have a diameter of 200 microns. The passages are 1 cm apart.

The container 1 is up to 25,000 revolutions / min. rotatable. The heat source 3 is designed as a heating plate to which the container 1 is rotatably arranged.

Regarding further advantageous embodiments and developments of the teaching of the invention on the one hand to the general part of the description and on the other hand to the attached claims. Finally be particularly emphasized that the previously purely arbitrarily selected embodiment for discussion only the teaching of the invention serves, but this does not limit this embodiment.

Claims (30)

Device for producing fibers, in particular nanofibers, comprising a container ( 1 ) for receiving fiber raw material ( 2 ), the container ( 1 ) by at least one heat source ( 3 ) is heated, the container ( 1 ) is rotatable and wherein the container ( 1 ) Exit areas ( 4 ) for the fiber raw material ( 2 ), characterized in that the exit areas ( 4 ) Medium ( 5 ) for directed, contactless guidance of the container ( 1 ) exiting fiber raw material ( 2 ) assigned. Device according to claim 1, characterized in that the means ( 5 ) comprise a gas flow. Device according to claim 1 or 2, characterized in that the means ( 5 ) comprise a gas flow field. Device according to Claim 2 or 3, characterized that acts as gas gas. Device according to one of claims 1 to 4, characterized in that the means ( 5 ) Blower. Device according to one of claims 1 to 5, characterized in that the means ( 5 ) Pumps. Device according to one of claims 1 to 6, characterized in that the container ( 1 ) is designed as a truncated cone-like hollow body. Apparatus according to claim 7, characterized in that the container ( 1 ) is fillable from above. Device according to one of claims 1 to 8, characterized in that the exit areas ( 4 ) of the container ( 1 ) are designed as passages. Device according to claim 9, characterized in that that the passages a diameter of up to 500 μm exhibit. Device according to one of claims 1 to 10, characterized in that the container ( 1 ) is rotatable at up to 25,000 revolutions per minute. Device according to one of claims 1 to 11, characterized in that a heat source ( 3 ) is designed as a radiant heater. Device according to one of claims 1 to 12, characterized in that a heat source ( 3 ) is designed as an infrared radiator. Device according to one of claims 1 to 13, characterized in that a heat source ( 3 ) is designed as a hot air blower. Device according to one of claims 1 to 14, characterized in that a heat source ( 3 ) in the container ( 1 ) is integrated. Device according to one of claims 1 to 15, characterized in that a heat source ( 3 ) is designed as a heating plate. Device according to one of claims 1 to 16, characterized in that the container ( 1 ) Can be heated to 450 ° C. Device according to one of claims 1 to 17, characterized by a storage device for receiving fiber raw material ( 2 ). Device according to one of claims 1 to 18, characterized in that between the storage device and the container ( 1 ) there is an electrical potential difference. Arrangement of several devices according to a of the preceding claims, wherein the devices are arranged in a matrix. Process for producing fibers, in particular using a device or an arrangement according to one of the preceding claims, wherein fiber raw material ( 2 ) in a container ( 1 ), the container ( 1 ) and wherein the fluidized fiber raw material ( 2 ) by centripetal forces from the container ( 1 ) is discharged in the form of fibers, characterized in that the exiting fibers are directed directed contactless. Method according to claim 21, characterized that fibers are produced, which have a diameter of 50 nm up to 200 μm exhibit. Arrangement with a fiber comprising layer, wherein the fibers by a method or apparatus according to a of the preceding claims are made. Arrangement according to claim 23, characterized by an embodiment as an air filter. Arrangement according to claim 23, characterized by an embodiment as a liquid filter. Arrangement according to claim 23, characterized by an embodiment as an acoustic damping element. Arrangement according to claim 23, characterized by an embodiment as a wound dressing. Arrangement according to claim 23, characterized by an embodiment as a cell growth carrier. Arrangement according to claim 23, characterized by an embodiment as a battery. Arrangement according to claim 23, characterized by an embodiment as a battery separator.