JPH0364509A - Method and apparatus for sealing spinneret capillary tubes - Google Patents

Abstract

PURPOSE: To seal the capillary of a spinneret at a low cost without the breakage of the surface of the capillary by inserting a plug seal consisting of a plug not being inserted from the top of the spinneret into the capillary deeply and a cap having a larger diameter than that of the capillary into the capillary and then by applying pressure to tops of both the seal and the spinneret. CONSTITUTION: Capillary seals for spinnerets 1 are carried out as follows: (1) making a plug seal 5 composed of a plug part 6 not being inserted deeply so as to reach the tip part 2 of a capillary 3 in the spinneret 1 and a cap part 7 having a larger diameter than that of the capillary 3 so as for its underside to correspond to the top 10 of the spinneret 1 surrounding the capillary; (2) the close fit of the plug seal 5 inserted into the capillary 3; (3) applying pressure 9 by extruding force for forming fiber to both the top 10 of the spinneret 1 and the plug seal cap 7 to plug the capillary 3 of the spinneret 1.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application This invention relates to capillary tubes in spinnerets.
) and its apparatus.

PRIOR ART AND THE PROBLEM TO BE SOLVED BY THE INVENTION Considerable progress has been made since attempts to replicate silk produced by silkworms began in the early part of this century. clothing, first by cellulose fibers, and later by thermoplastic resin fibers,
The living world has changed considerably in terms of carpets, as well as other exterior coverings.

However, basically the same equipment used for silkworms is still used today. Continuous fibers are forced through capillaries. That is, approximately human hair formed in a solid plate by the compressive force on the fiber resin is forced through a small opening of any size. This solid material is the silk thread spinning channel of the silkworm.
spinningpassage).

Spinnerets used in the production of "artificial" fibers such as rayon, nylon, polyester, acrylic, acetate, and others can contain anywhere from one to several thousand capillary tubes, depending on the specific application conditions imposed on the textile product. The fiber size is determined by the spinning material and spinning conditions as well as the "size" of the capillary. Many capillaries are round in cross section. However, it is becoming increasingly fashionable to provide capillaries of various shapes in order to impart different properties to textile products.

Due to their small size, spinneret capillaries can become "clogged" by foreign matter contained in the spinning resin.

If clogging occurs, the fibers produced will become thinner in size or, in the worst case, break. When a capillary blockage occurs, the spinneret is removed and the capillary is cleaned.

Cleaning the capillaries is very difficult due to the resin used. It is also very advantageous to provide an additional capillary tube in which the spinneret capillary tubes may be damaged by cleaning beyond what would occur in use. Also, having additional capillaries available in the spinneret allows flexibility in the overall size, weight, or other properties of the fibers produced. This weight is often referred to as "F denier," and its name (nominally, 9000
weight in grams of a fiber of length m) or by its other customary name - decitex (d
ecitex: 10/9 denier). Furthermore, it is advantageous to be able to "mark" textile products by providing capillaries that are different from the others. This "marking" is -11,! For this purpose, the different capillaries are sealed except when marking is being performed. Like this-
There are various situations in which it may be beneficial to plug or seal the capillary from time to time, but it is also possible to use the capillary entirely.

Capillaries for resin materials vary in shape, but are usually constructed with two or more recesses arranged concentrically in series. The lower portion of the spinneret capillary (ie, the last portion through which the polymer flows), the shaping portion, is configured to give the fiber the final desired shape. This lower portion is usually narrowed to reduce the cost of producing unusually shaped fiber structures. The upper part, ie the "surface 1 part", which follows this lower part is larger and is usually cylindrical or tapered relative to the surface part.

The structure of a typical capillary tube is described in U.S. Letter Patent No. 3,0.
Seen in No. 06,026. This reference patent shows one means of constructing a removable insert in the lower portion, such that the insert is configured to be press-fit within the body of the hollow spinneret.

Additionally, it is known to use a similar technique of plugging a capillary tube by forcing a soft aluminum rod inside the upper portion of the capillary tube. The difficulty in inserting such a rod is that it must bottom out against the surface portion in order to press outward to seal the upper portion, which may damage the surface portion. That's what happens.

It would be of great advantage to positively seal the capillary tube without creating the possibility of damaging surface parts. Attempts have been made to use threaded bolts or screws to seal capillary openings. But these attempts failed. The reason for this is that the spinning environmental conditions prematurely corrode the threaded portion of the screw L bolt. Furthermore, the opening of the capillary tube could be damaged by the removal of the screw l bolt, which would affect the flow characteristics and therefore the spinning uniformity of the capillary tube.

Means for Accomplishing the Problems The present invention actively seals capillaries, but
To provide a method for sealing a capillary tube without damaging the surface portion of the capillary tube, which determines the final shape of the fiber. The present invention provides a plug member that provides a positive seal, is inexpensive, and is reusable if desired.

That is, the sealing method according to the present invention includes a plug portion that is tightly fitted into the capillary tube and is not inserted deeper than the surface portion of the spinneret, and a cap portion that has a diameter larger than that of the capillary tube. A plug seal configured with a cap portion adapted to coincide with the top surface of the spinneret surrounding the capillary tube is inserted into the capillary tube, and pressure due to the extrusion force is applied to the top surface of the spinneret as well as the plug seal cap. It is characterized by including steps for imparting.

The plug seal according to the invention is also a plug seal for a spinneret having a plug portion and a cap portion, the plug portion being shorter than the depth of the capillary tube to the capillary surface portion and forming an interference fit with the capillary tube. The cap part has the shape of a sufficiently thick cylindrical rod as shown in FIG. The upper surface of the spinneret surrounding the capillary tube as well as a part of the cap part having a larger diameter than the capillary tube are characterized in that they form a sealing part.

DESCRIPTION OF THE EMBODIMENTS FIG.
A cross-section of a typical spinneret plate 1 is shown, most of which are described in the US Pat. The spinneret capillary is shown configured with a surface portion 2, an upper portion 3 and an inlet portion 4.

According to the invention, a capillary seal 5 is shown inserted into the inlet section 4 and the upper section 3. The total depth of the plug section 6 of this seal is less than the mating depth over the inlet section 4 and the upper section 3. This depth limit is to prevent damage to the surface portion.

A slight interference fit provided between the plug section 6 and the upper section wall 8 holds the seal in place. This hold is maintained until pressure transmitted from the polymer extrusion source (indicated by arrow 9) is applied to the seal. The seal is typically constructed of a material that is also flexible and capable of withstanding the extrusion conditions above the spinneret plate. Aluminum alloys such as 6061T6 are acceptable for mechanical workability and relative hardness. Although more permanent plugs can be constructed of 316 stainless steel, copper-based materials exhibit a tendency to corrode under spinning environmental conditions.

The sealing element or cap portion 7 formed at the upper end of this plug has a diameter larger than the diameter of the inlet portion in order to form a flat sealing surface on the top surface 10 of the spinneret. Although the interference fit of the plug 6 initially holds this seal in place and contributes to maintaining the seal in that position, during the spinning operation the downward force 9 acting on the cap portion 7 forces the cap This forms an operative capillary tight seal at the interface between section 7 and spinneret plate 1. When the spinning operation is terminated and the spinneret is cleaned, the seal 5 can be easily removed and the previously sealed capillary can be used again.

[Brief explanation of drawings]

FIG. 1 is a schematic side cross-sectional view showing a spinneret capillary and a seal of the present invention. FIG. 2 is an exploded perspective view of a typical spinneret and seal used in the present invention. 2 1... Spinneret plate, 2... Surface portion, 3...
・Upper part, 4... Inlet part, 5... Capillary seal, 6... Plug part, 7... Cap part, 8...
- Wall surface, 9...Arrow indicating pressure, 10...Top surface of spinneret plate.

Claims (7)

[Claims] (1) a plug portion (6) which is an interference fit within the capillary of the spinneret and which is not inserted deeper than the surface portion of said spinneret, together with a cap portion (7) of a larger diameter than said capillary; inserting into the capillary tube a plug seal configured with a cap portion adapted to coincide with a top surface of the spinneret surrounding the capillary tube; A method of sealing a spinneret capillary comprising the steps of applying extrusion force pressure to a sealing cap. (2) A plug seal for a spinneret having a plug portion and a cap portion, the plug portion being shorter than the depth of the capillary to the capillary surface portion and having a thickness sufficient to form an interference fit with the capillary. in the form of a cylindrical rod, the cap part being formed subsequent to the plug part and having a larger diameter than the inlet of the capillary tube, by applying an extrusion force to the spinneret. . A plug seal for a spinneret, characterized in that an upper surface of the spinneret surrounding the capillary tube and a portion of a cap portion having a larger diameter than the capillary tube form a sealing portion. (3) A method for temporarily sealing at least one capillary of a spinneret, the plug seal comprising a plug portion and a cap portion, the plug portion being longer than the length of the upper portion of the capillary. a cylindrical rod of short length and sufficient thickness to form an interference fit with the wall of the capillary tube, the cap portion being formed subsequent to the plug portion and having a larger diameter than the entrance of the capillary tube; a spinneret comprising the steps of: inserting a plug seal into the capillary tube and applying an extrusion force to the upper surface of the spinneret as well as to the cap portion for forming fibers; How to seal a capillary tube. (4) A method for changing the properties of a textile product produced using a spinneret having a plurality of capillaries of different configurations and shapes, the method comprising: temporarily sealing selected capillaries;
and melt-spinning fibers from the remaining capillaries exhibiting desired fiber-forming properties. (5) A method for temporarily verifying a textile product produced by a spinning assembly comprising at least one verification spinneret hole having a temporary plug seal, the method comprising: removing said plug seal; , and spinning a fiber through an opening of a spinneret comprising a hole in said verification spinneret. (6) a spinneret plate having a plurality of spinneret openings of one selected type and at least one spinneret opening of a second type; and means for temporarily plugging the spinneret opening, said means comprising a plug seal having a plug portion and a cap portion, said plug portion at said spinneret opening. A textile spinning assembly, characterized in that it is in the form of a cylindrical rod that is shorter than the depth of the capillary tube, and that the cap portion has a larger diameter than the opening of the spinneret. (7) In a spinneret for simultaneously forming a predetermined number of textile products, at least one additional spinneret opening is formed in the spinneret, and the additional opening is temporarily plugged. A method of extending the service life of the spinneret by.