EP1241283A1 - Device for producing fibrous synthetic materials - Google Patents

Abstract

With a device for the production of synthetic fiber materials with a feed for a polymer melt to a rotating hollow reactor (1), the wall of which can be heated, conically widened for guiding a melt film to an open side which can be closed with a lid (13) and with ribs (4) for dividing the melt film into fibers which solidify after exiting after the hollow reactor (1), an improved quality of the fibers produced with reduced energy input can be achieved in that the hollow reactor (1) is oriented vertically and a continuously curved inner wall and has an opening (3) on the curved upper side for the supply of the polymer melt and that a rotating distributor plate (12) is arranged at a short distance from the inner wall of the hollow reactor (1) opposite the opening (3). <IMAGE>

Description

The invention relates to a device for producing synthetic fiber materials with a feed for a polymer melt to a rotating hollow reactor, the wall of which is heatable and for guiding a melt film to one open side, which can be closed with a lid, expanded conically and with ribs to divide the melt film into those that solidify after exiting the hollow reactor Fibers is provided.

Such synthetic fibers can be used in particular as absorbents be made from water petroleum and petroleum products as well as a number of Can filter out heavy metal ions.

The process for the production of thermoplastic fibers takes place regularly in two stages, namely extraction of the melt and formation of the fiber.

In known plants, the thermoplastic material is first melted and then the melt is extruded through spinnerets to form the fibers. A System known from SU 1 236 020 A has a loading bunker, a power supply and a melting grid with a distributor for heated Inert gas. The distributors are triangular and even over the Distributed melting grid surface. The thermoplastic to be processed Material is in the space above the grid up to the melting temperature evenly heated and can flow freely between the triangular distributors undergo treatment with nitrogen. In the housing of the Melting grids are connection points for the assembly of heating elements. As a result, the heated material is melted and continues to reach one Worm drive, is pushed through the nozzles and into a strand or one Thread formed. With systems of this type, fibers can only be made from high quality Raw materials are produced, it must be ensured that the raw material in steady speed on the melting grid and then on the melt the screw arrives for removal.

From GB 1 265 215 and SU 669 041 A plants are known in which the fiber extraction is made from a band of melt so that the uniformity the flow of the melt is not critical. The tape is made from the The melt is divided into individual strands at the edge of the rotating reactor. The Reactor is a horizontally arranged rotating two-part basin with a Cavity and a work surface. There are gaps in the cavity Openings. An energy source penetrates from the outer cavity of the reactor the gap-like openings and separates the melting band into individual strands, processes them from two sides, makes them thinner and pulls them into fibers. To with To get a high-quality fiber in this system, the energy source a higher temperature than the destruction temperature of the polymer and a have sufficient speed to make the melt strands thinner and longer and thus can be formed into a fiber. The open pool of the reactor causes a loss of energy and leads to a reduced effectiveness of the Manufacturing process.

A plant for the production of fibrous materials is also known from RU 2 061 129, which form an extruder, a fiber-forming ring head with radially arranged and in the center converging channels, an air flow generator that the At the same time, the melt strands are drawn out and cooled until they become fibers and has an element for separating the finished fiber that has an extension converging in the direction of the incoming thread. The The fibers are deposited under the action of a stream of air flowing in Direction of the extruded melt strands is directed. The radially arranged and Channels converging in the center also require the use of high quality Raw materials. Otherwise, these channels will not be completely melted Block the mass, causing it to pass through the fuse lines is difficult. The manufacture of high quality fibers less high quality raw materials is therefore not possible.

A device of the type mentioned at the outset is known from RU 2 117 719, at which heats a horizontally mounted rotating cylindrical hollow reactor from the outside becomes. The open part of the reactor has the shape of an expanding cone, which is closed with an immovable cone cover. The cone cover forms a gap opening with the lateral surfaces of the expanding cone from 15 to 20 mm. In addition, on the inner surface of the reactor flat ribs attached, which have a triangular shape along their length, the along the fiber formation and with the tip towards the melt flow exit is aligned. The device is with an annular high pressure air supply equipped. With this known device it is possible to process thermoplastic material from industrial and domestic waste with simultaneous increase of high-quality fiber material. In practice However, the problem occurred that with the usual heating elements in a Cylindrical shape of the reactor even heating of the reactor wall and - floor cannot be reached. Hence the temperature of the reactor floor and the end pieces always lower than that of the reactor wall. The melt collects in the corners between the wall and the floor and thus forms a kind Standstill zone, where the melt cools down and tends to on the ground and on to adhere to the transitions of the floor to the walls. The formation of such standstill zones reduces the productivity of the system and has a negative effect on the Fiber quality. Solid parts of the polymer can be carried away from this standstill zone and under the influence of the centrifugal forces together with the melt transported to the end of the reactor and discharged together with the fiber become solid, making the fiber more uneven with thickening or inclusions unmelted pieces of various shapes are formed, the quality of the fiber is reduced. The system must be cleaned regularly to clean the standstill zone stopped to mechanically remove the adherent polymer. If the reactor walls were heated more, this would lead to an essential one Overheating of the melt film. Another disadvantage of the known device is that just over 30% of the thermal energy supplied is immediate is used for heating the tape. The rest, given by the heater Energy is used to heat the inside of the reactor and the ambient air consumed by transmission of radiation energy. Furthermore occurs because of Retroreflection between the heater and the reactor in the central part of the reactor overheating of the heating elements and the melting tape. On the one hand, it can to burn the heaters and on the other hand not to be neglected or even completely burn out the polymer. With an even Distribution of the capacity of the heater in the radial and axial direction collects the main amount of heat in the upper part of the heater. In this case overheating and burning of the heating elements is also possible.

The present invention has for its object a device for manufacturing to improve synthetic fiber materials of the type mentioned at the beginning, that achieves an increased fiber quality with a reduced energy consumption becomes.

This object is achieved according to the invention in a device of the type mentioned at the outset solved in that the hollow reactor is aligned vertically and a steady curved inner wall and an opening for the curved top Has supply of the polymer melt and that a rotating opposite the opening Distribution plate arranged at a short distance from the inner wall is.

The device according to the invention is for producing a uniform thin Melting film formed, which extends to the open side of the reactor due to the steady Curvature of the inner wall can move without standstill zones. Training of the uniform thin melt film is achieved by the polymer melt axially on the curved top of the hollow reactor through an opening is fed and arrives there on a rotating distributor plate, which in one short distance from the inner wall of the hollow reactor is arranged. This will the molten polymer fed is collected and by centrifugal force hurled evenly onto the inner wall of the hollow reactor. The distributor plate thus forms a closure of the feed opening to form an annular gap with the inner wall of the hollow reactor, from which the on the distributor plate collected material emerges evenly distributed and on the inner wall of the Hollow reactor arrives. The flow rate of the melt film on the inner wall of the hollow reactor due to the rotation of the hollow reactor resulting centrifugal force and additionally by the weight of the melt film determined because the hollow reactor is oriented vertically and open downwards.

The distribution effect of the distributor plate is further improved in that the Surface of the distributor plate rises towards the edge, preferably one towards the opening pointing concave curved top forms. In a preferred embodiment a truncated cone is arranged on the distributor plate, its diameter is smaller than the diameter of the distributor plate. The diameter the top of the distributor plate in the order of the diameter correspond to the opening of the feeder.

The continuously curved inner wall of the hollow reactor is preferably parabolic formed, corresponds to the surface created by the rotation of a parabola the own axis arises. At the same height and with the same diameter Outlet opening arises from the constant curvature compared to the previously known Device a significantly reduced internal volume, so that the required Amount of heat energy reduced for heating the interior. The invention Construction also minimizes heat loss and specific Heat consumption.

In a particularly preferred embodiment of the invention, the inner wall forms with a surrounding container of the hollow reactor a curved Gap to which a steam supply and a steam discharge is connected. Due to the constant circulation of heated water vapor through the formed Cavity, a uniform heating of the reactor walls is achieved. Consequently it is possible to make the melting tape or the melting film with a uniform Produce temperature and thickness, which unites the fiber over the entire length has a uniform diameter and contains no unmelted parts. For this purpose it is useful if the steam supply and the steam discharge are arranged at the top and bottom of the inner wall. The steam can both in cocurrent and in countercurrent to the direction of transport Polymer melt are performed. The arrangement in direct current is preferred.

Figur 1

einen Vertikalschnitt durch ein Ausführungsbeispiel einer erfindungsgemäßen Vorrichtung

Figur 2

eine Teilansicht auf einen zwischen Innenwand und Deckel ausgebildeten Ringspalt.

The invention will be explained in more detail below with reference to an embodiment shown in the drawing. Show it:

Figure 1

a vertical section through an embodiment of a device according to the invention

Figure 2

a partial view of an annular gap formed between the inner wall and cover.

The device shown in the drawing is used to produce fibers a thermoplastic melt and includes a vertically installed rotating one Hollow reactor 1 in the form of a paraboloid, which by rotating a parabola around the own axis is formed. At the open edge of the paraboloid there is an as expanding cone provided edge 2 provided. Centric is in the curved Part of the paraboloid formed an opening 3 for feeding a polymer melt. The inner wall of the hollow reactor 1 is provided with flat ribs 4 which run perpendicular to the edge 2 in the lower region of the hollow reactor 1.

The hollow reactor 1 is located in a surrounding container 5, in the surface thereof is adapted to the shape of the hollow reactor 1, so that a curved Gap 6 results. The gap 6 is in its upper part with the exit and in its lower part connected to the input of a steam generator 7, so with the gap 6 forms a closed steam cycle. The direction of movement of the water vapor is illustrated by arrows in FIG. 1, with a direct current movement of water vapor is formed. By reversing the Steam generator 7 can be used in the same way and for some applications also sensibly implement a countercurrent direction of the water vapor.

Opposite the opening 3 is located inside the hollow reactor 1 a distribution arrangement 8, which is guided centrally through the feed opening 3 Rod 9 is attached. The rod 9 is axially adjustable so that the distance the distribution device 8 is adjustable from the inner wall of the hollow reactor 1. In the exemplary embodiment shown, the distribution device consists of a Truncated cone 11 and an attached distributor plate 12, the Diameter is larger than the base of the truncated cone 11. Truncated cone 11 and Distribution plates 12 are firmly connected to one another, preferably in one piece. The ring of the distributor plate projecting radially beyond the truncated cone 11 12 is provided with a surface that rises towards the radial edge and forms such a concave curved top.

The hollow reactor 1 is at the lower open end by a disc-shaped cover 13 closed. The flat ribs 4 are connected to the edge of the cover 13, so that there are outlet openings between the ribs.

The hollow reactor is attached to the end of a hollow shaft 14 which rotates on bearings 15 is stored. The bearings 15 are located in a housing 16 to be cooled. At the end of the shaft 14 remote from the hollow reactor 1 there is a drive pulley 17 for transmitting the rotation, for example, from an asynchronous (not shown) Engine arranged.

For the production of fibrous materials, the reactor is supplied before being put into operation brought from circulating steam in the gap 6 to working temperature. Because the water vapor flow has a constant temperature and speed has, the heating of the inner wall of the hollow reactor 1 takes place over its entire Even surface. The heat flow is from the heated surface of the Hollow reactor 1 released to the inside and thus generates the required temperature throughout the interior and keeps it constant. This creates a homogeneous temperature field on the entire surface of the hollow reactor 1.

After this preparation of the plant, the hollow reactor with a given Angular speed made to rotate. Then through the hollow shaft 14 and the annular distributor gap 10 introduced the polymer melt. The The melt first reaches the truncated cone 11 and then flows onto the distributor plate 12. Due to the taper of the truncated cone 11, the speed of the Melt flow too. This speed increases with the running of the Melt to the edge of the distributor plate 12. The distributor plate 12 thus provides one Kind of collecting device on which the melt evenly over the entire Plate is distributed. By increasing the surface of the distributor plate 12 to An additional compaction force is created at the edge, so that the melt coexists increasing speed and force as a homogeneous band to the periphery of the Distribution plate moves. After reaching the edge of the distributor plate 12, the tears Melting tape and reaches the inner wall of the hollow reactor 1. Moved there the melt film down, with the downward movement through the Gravity due to the vertical arrangement of the hollow reactor 1 supported becomes. After reaching the part of the hollow reactor in which the flat ribs are 4 are located, the melt film divides into different strands, which over the Edge 2 run and when torn from the edge of the conical edge 2 form thin fibers.

A ring-shaped air supply directs the resulting and cooling thread a collecting device.

Claims (12)

Device for the production of synthetic fiber materials with a feed for a polymer melt to a rotating hollow reactor (1), the wall of which can be heated, is conically widened for guiding a melt film to an open side which can be closed with a cover (13) and with ribs (4 ) for dividing the melt film into fibers which solidify after exiting after the hollow reactor (1), characterized in that the hollow reactor (1) is oriented vertically and has a continuously curved inner wall and an opening (3) on the curved upper side for the feed the polymer melt has and that a rotating distributor plate (12) is arranged at a short distance from the inner wall of the hollow reactor (1) opposite the opening (3). Apparatus according to claim 1, characterized in that the distance between the distributor plate (12) and the inner wall of the hollow reactor (1) is adjustable. Device according to claim 1 or 2, characterized in that the distributor plate (12) has a surface pointing towards the opening (3) and rising towards the edge. Device according to claim 3, characterized in that the distributor plate (12) has a concavely curved upper side pointing towards the opening (3). Device according to one of claims 1 to 4, characterized in that a truncated cone (11) is arranged on the distributor plate (12), the diameter of which is smaller than the diameter of the distributor plate (12). Apparatus according to claim 5, characterized in that the diameter of the truncated cone (11) corresponds in the order of magnitude to the diameter of the opening (3) of the feed. Device according to one of claims 1 to 6, characterized in that the inner wall of the hollow reactor (1) is parabolically shaped. Device according to one of claims 1 to 7, characterized in that the ribs (4) on the inner wall of the hollow reactor (1) in the lower region run perpendicular to the edge (2). Device according to one of claims 1 to 8, characterized in that the hollow reactor (1) with a surrounding container (5) forms a curved gap (6) to which a steam supply and a steam discharge is connected. Apparatus according to claim 9, characterized in that the steam supply and the steam discharge are arranged on the upper and lower edge of the hollow reactor (1). Apparatus according to claim 9 or 10, characterized in that the steam is passed in a circuit through the curved gap (6). Apparatus according to claim 11, characterized in that the steam is passed in cocurrent to the melt flowing in the form of a film on the inner wall of the hollow reactor (1) through the curved gap (6).

Images