BE515901A - - Google Patents

Description

       

   <EMI ID = 1.1>

  
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said, a solution or lacquer of the coagulable material is extruded or ejected through a number of small orifices of a die into a chamber

  
coagulation where the fiber is coagulated in a bath of liquid coagulant. With continuous filament yarn, there is little difficulty in coagulating

  
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filaments) which constitute the strand extruded by a single die because the coagulating agent penetrates into all the filaments of the small bundles. However? the problem is more complicated in the case of tow which is mainly used in the manufacture of wick fibers. An extremely high number of relatively thin fibers is desired for the tow. In addition, the greater the number of these filaments which can be obtained with the aid of a single spinneret, the higher the manufacturing efficiency, since a smaller number of spinnerets and consequently a smaller number of spinning positions are necessary.

  
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Using a single die to increase the die face area, other considerations limit the possible size of die faces

  
to a maximum of a few centimeters. Additional problems arise.

  
 <EMI ID = 5.1> coagulant maintained below 10 [deg.] And preferably a few degrees above or below 0 [deg.]. When we use the channels known for there

  
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temperature among the various orifices of a single spinneret, that unacceptable differences in filament denier values result. In addition, it has been found that the heating action of the spinning solution raises the temperature of the coagulating liquid in the immediate extrusion zone to a point.

  
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lique, which was visible from the milky, opaque appearance of the filaments

  
and by their reduced ability to stretch necessary to orient molecules and give them their maximum strength.

  
The object of the present invention is to provide an improved process using improved dies for the wet spinning of artificial fibers in general, and in particular for the wet spinning of tow of artificial fibers by extrusion of a relatively solution. hot in

  
a relatively cold coagulant bath by the process described in the aforementioned patent.

  
The invention therefore relates to a method of wet spinning of artificial filaments consisting in continuously ejecting in a liquid coagulant bath a coagulable polymeric material in the form of a hollow current interrupted on its periphery, and consisting of several separate jets, practically parallel , arranged in a discontinuous pattern in the vicinity of

  
the periphery of the stream, and interrupted by one or more peripheral zones practically free of jets located through the stream allowing free access between the main mass of the coagulant bath and the interior zone of the stream. If desired, one can have, at a certain distance and around this stream, one or more smaller streams similar-ment hollow and peripherally interrupted by one or more peripheral zones practically free of jets, placed through the stream.

  
The invention also relates to a die for the wet spinning of artificial filaments, in which the face comprises a strip

  
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practically unperforated surfaces arranged through the strip. If desired, one or more similar smaller discontinuous strips of spinning holes can be arranged at a distance and around this strip, each of them similarly interrupted by one or more

  
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bandaged.

  
The invention will be better understood by referring to the following description corresponding to the appended drawing in which:

  
Figures 1 and 2 are plan views of dies showing a discontinuous strip of spinning orifices;

  
and Figure 3 is a plan view of a die showing the outer and inner discontinuous bands of spinning orifices.

  
Referring first to Figure 1, it will be seen that the die shown is a hollow cup of platinum alloy or other suitable material having a rim 10 and a flat face 12. The central region

  
14 of the face is not perforated and all the holes or perforations in this relatively thin sheet of metal are arranged in two annular sections.

  
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sieurs non-perforated zones 18. As the spinning orifices are small and very close together, the perforated zones of the face have been shown diagrammatically by shaded zones.

  
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In another die of the same type and of the same diameter, each of the two perforated zones 16 contains 1165 orifices 90 microns in diameter, i.e. a total of 2330 holes arranged in ten concentric circles with spaces of

  
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on the circles. In this case, the width of the non-perforated zones is 64

  
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Figure 2 differs essentially from the sector represented <EMI ID = 14.1>

  
have been rounded to reduce the breakage of the extruded filaments in

  
critical coagulation conditions through the orifices in these exposed corners. This arrangement appears to be of the greatest utility. when we are in the most critical operating conditions.

  
If we now refer to Figure 3 we see that the die

  
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trimmed by the intact zones 124. Thus, all the spinning orifices are arranged in the vicinity of the bands 116 and 118. As these orifices are very small and very close, the perforated zones of this space have been schematically represented by shaded zones.

  
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outside diameter of 6.25 cm, constructed according to Figure 3, each of the outer perforated segments contains 1925 orifices of 65 microns in diameter practically equidistant from 0.52 mm between centers, on 14 concentric circles spaced 0.50 mm apart. The diameters of the inner circle and the outer circle

  
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interior 116 has the same spacing between 475 65 micron holes

  
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areas 122 is 0.60 cm.

  
The proportion between the surfaces of the perforated bands 16 and of the central unperforated zone 14 of Figures 1 and 2 is an imperative characteristic.

  
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unperforated or intact peripheral areas 18. The intact central surface 14 must represent at least 80% of the area of the perforated peripheral strips 16 or in other words, the perforated strips must not have a surface area greater than 25% on the surface of the non-perforated center of the die. In general, it is preferable that this intact central area is

  
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The same proportion between the non-perforated bands and the perforated bands is to be recommended with the dies presenting several bands added.

  
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it is always desirable that the total area of the perforated bandages 116 and
118 does not exceed the total area of perforated areas 114 and 120 more <EMI ID = 24.1>

  
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face of a relatively wide openwork strip and the total area of all non-perforated areas within this wide strip .......

  
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cited. In this operation, the solution is ejected at 90-100 [deg.] By a die such as that shown in Figures 1 and 2 in the form of a continuous hollow current interrupted on its periphery, or by a die such as that re -

  
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from the center of the single stream or the multiple stream into the coagulation zone. This free access of the coagulant bath through the channels formed by the peripheral zones free from current jet, makes it possible to maintain

  
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order than that of the main mass of the bath. As a result, the filaments

  
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the desired transparency despite the large number of filaments extruded by a single die. These excellent results contrast sharply with those obtained.

  
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of an uninterrupted peripheral annular current. The uninterrupted current consists of approximately 2,400 individual jets emitted from orifices 90 microns in diameter, arranged in a single ring of a size very close to those of the single stream of Figures 1 and 2 and of the outer stream of Figure 3. The tow obtained from the complete or uninterrupted annular stream is very insufficient for textile use due to large variations in diameter of the individual filaments in various parts of the stream and also due to the fact that many of the filaments are opaque instead. to be translucent. In addition, it has been found that the opaque filaments are not suitable for the subsequent drawing operation in a hot bath which orients the molecules of the fiber and develops all their resistance.

   These defects arise from excessive temperatures in the center of the hollow stream of the coagulating solution, as the temperature at this point has been found to be up to 20 [deg.] Above that of the coagulating bath in general. .

  
It is best to extrude the spinning solution as

  
of hollow cylindrical annular current having peripheral zones interrupted so as to constitute channels for the coagulant bath, but the invention is not limited to this particular form, since any form of hollow current interrupted peripherally may be suitable. Thus, the individual jets of spinning solution can be arranged in several hollow patterns of rectangular, hexagonal, oval or even irregular section,

  
with the proviso that at least one or more channels pass through the periphery of each stream so as to allow free circulation of the coagulant between the main portion of the coagulant bath and the hollow interior region of each stream. In addition, in the die of Figure 3, it is not necessary that the different hollow currents coming from the single source have the same shape because the external current could be hexagonal and the internal current annular, etc.

  
In the description of the present invention, the expressions "perforated zone", "perforated strip" and the like have been used to denote a

  
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regularly or not, bordered by tangential lines to the orifices arranged along the periphery of the zone considered.


    

Claims (1)

<EMI ID = 32.1> see a smaller size and fewer and smaller orifices if desired. For ease of construction, it is preferable to arrange all the holes on concentric arcs of a circle whatever the shape of the perforated bands, as this allows the use of a circular pantograph, which facilitates proper positioning and drilling. from small <EMI ID = 33.1> a number of factors, including the diameter of the orifice and the temperature difference between the coagulant bath and the spinning solution. <EMI ID = 34.1> Other factors such as ease of manufacture must also be considered. <EMI ID = 35.1> large spacing when a smaller number of holes per spinneret is sufficient, provided the fibers are not separated by such a gap <EMI ID = 36.1> the turbulence of the surrounding mass of liquid. If one wishes in a die a maximum number of orifices with diameters of the order indicated above, one must consider that each perforated strip contains 10 to 14 rows. <EMI ID = 37.1> very case a smaller number of rows may be suitable. Despite their surprising effect on the temperature of the coagulant bath inside the hollow stream (s) of solution, the channels in the streams produced by the non-perforated zones 18 of Figures 1 and 2 and 122 and 124 of Figure 3 can be very narrow as long as the passage of <EMI ID = 38.1> Following narrow areas can be satisfactory in many cases, with single or multiple trough currents. - Although the dies shown in the drawing denied that two non-perforated bands in each hollow stream, one can use a <EMI ID = 39.1> <EMI ID = 40.1> best results when the two non-perforated bands 122 and 124 are in <EMI ID = 41.1> in which the channels of several hollow streams are not aligned the ones with the others. CLAIMS. lo Method of wet spinning of artificial filaments, characterized in that one ejects continuously in a coagulating liquid bath a coagulable polymerized material in the form of a hollow stream interrupted peripherally, comprising several separate jets substantially parallel arranged in a discontinuous pattern near the periphery of the stream and interrupted by one or more peripheral zones substantially free of jets passing through the stream and allowing the free access of the main mass of the coagulant bath with the interior of the current. <EMI ID = 42.1> peripherally interrupted hollow current is spaced apart and surrounded by one or more smaller peripherally interrupted hollow currents, each current being <EMI ID = 43.1> one or more peripherally practically free zones of jets passing through the stream and allowing free access between the main mass of the coagulant bath and the interior zone of each stream. 3. Method according to claim 2, characterized in that the currents are practically concentric and the peripheral zones practically free of jet are arranged practically radially. 4. A method according to either of claims 1, 2 and <EMI ID = 44.1> an area representing at least about 80% of the section of the hollow stream (s). 5. Method according to either of the preceding claims, characterized in that the jets of each stream are arranged in an annular pattern. 6. A method according to either of the preceding claims, characterized in that the coagulable polymerized material is ejected at a temperature of 60-110 [deg.] Into a coagulating bath maintained at a temperature below 10 [deg. ]. 7. Die for the wet spinning of artificial filaments, characterized in that the face of the die has a discontinuous strip <EMI ID = 45.1> practically unperforated face connections crossing the web. 8. Die according to claim 7, characterized in that the discontinuous strip of spinning orifices surrounds at a certain distance one or more smaller discontinuous strips of spinning orifices, each strip being peripherally interrupted by one or more face portions. practically unperforated passing through the web. <EMI ID = 46.1> the bands are practically concentric and the portions of the unperforated faces are disposed practically radially. 10. A die according to either of claims 7 and 8, <EMI ID = 47.1> a section representing at least about 80% of the section of the strip or strips of spinning holes. <EMI ID = 48.1> characterized in that the orifices of each strip are arranged in an annular pattern.