JPH08232113A - Spinning block for melt spinning apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a spinning block which comprises many parts including a filter, can uniformly heat the parts and the filter, and facilitates the exchange of the parts for the maintenance of the block. SOLUTION: This spinning block 3 is heated from its inside with a heating device which comprises one or more long and slender heating elements 11 that are equally disposed on the main flow direction axis of a melted material as a center. The heating elements are extended over the whole body of the spinning block 3, and can be detached for exchanging or maintaining a filter 9 or a spinning plate 10. In order to improve heat transfer between the heating elements 11 and the spinning block 3, the heating elements 11 are made from a substantially single material or covered with a material having a larger thermal expansion coefficient than that of a material surrounding the heating elements.

Description

Detailed Description of the Invention

[0001]

FIELD OF THE INVENTION The present invention relates to a spinning block for a melt spinning machine, which comprises one or more interconnected metal blocks containing a melt filter, a nozzle plate and a heating device.

[0002]

BACKGROUND OF THE INVENTION Spinning blocks or other spinnerets are usually arranged to be heated in a heating box in which a suitable heating medium (liquid, vapor) is flowing. Such an external heating type spinning block
For example, it is described in European Patent No. 0 271801. Such a configuration requires a supply line such as a pipe and an external heating device for the heating medium, and thus the design is very complicated.

EP 0 008 612 discloses an elongated subduction heating element for additionally heating the nozzle plate. These heating elements are arranged exclusively in the area of the nozzle plate and are not suitable for replacing the heating device described at the beginning with a multi-part spinneret.

[0004]

SUMMARY OF THE INVENTION The invention is based on the object of providing a heating device of simple construction for heating a multi-component spinning block with a filter, whereby the individual components and the filter are heated uniformly. It is an object of the present invention to provide a spinning block which can be easily replaced and can be easily replaced for maintenance (for example, replacement or cleaning of a filter or a nozzle plate). After removing the spinning block and subsequent re-installation, if it is not reheated quickly enough to the desired operating temperature,
Fall into production interruption. Therefore, the thermal inertia of the heating system should be as low as possible. This is because if the spinning block can already be heated separately before it is removed to bring it to the required operating temperature before installation,
Especially desirable.

[0005]

This object is achieved by a spinning block for a melt-spinning machine, which is defined below.

The spinning block consists of one or more interconnected metal blocks (6, 7) containing a filter (9) for the melt, a nozzle plate (10) and a heating device. The device internally heats the spinning block and consists of one or more elongated heating elements (11), which heating elements extend in the main flow direction of the melt so as to extend through the entire spinning block. It is arranged in an evenly distributed manner around the axis and can be removed for the purpose of replacing the filter or the nozzle plate or for maintenance purposes.

Although the spinning blocks according to the invention can be heated individually and thus in principle require no additional external heating, the spinning blocks according to the invention can be heated in a manner known per se and For the purpose of fixing and / or fixing, it is desirable to install it on a spinning bar known per se. If the known spinning bars have their own heating devices, it is advantageous for these heating devices to interact with the heating devices of the spinning block according to the invention. This interaction occurs during the actual spinning of fibers or the like, during the insertion or removal of the spinning block from the spin bar and / or during the replacement of the filter.

Spinning blocks are in principle suitable for the production of all types of melt-spun fibers known per se. The production of polyester fibers, in particular polyethylene terephthalate fibers, is preferred.

The shape of the spinning block should be roughly as desired, but it should conveniently be made as simple as possible. Such a suitable simple form of construction is a substantially cylindrical symmetrical form about the main flow direction of the melt, in particular a substantially cubic form as shown in FIG. If the spinning block according to the invention is to be installed on an existing spinning bar or a newly manufactured spinning bar, it is recommended that the installation be technically simple. Due to the heating device of the spinning block, the heat transfer is not as pronounced as when using an unheated spinning block, which is known per se, but can be optimized accordingly according to the usual technical measures. The spinning bar required is either heated by itself or only serves the supporting function of the spinning block.

The material forming the spinning block is
The thermal conductivity should be as high as possible.
All materials common in the manufacture of spinning blocks can be used. Suitable high-quality or improved metals are preferentially used, in particular VA steel. The linear thermal expansion coefficient of these materials is preferably 17 × 10-
⁶ (° C) ^-1 or less, specifically 12 x 10-
⁶ (℃) ^-1 or less. The spinning block must be constructed so that the heat exchange between regions of different temperature is as great as possible. Therefore, the spinning block is preferably manufactured from solid material to eliminate cavities with low thermal conductivity. If the spinning block is made up of multiple parts, the size of the contact surface between the parts should be as large as possible and there should be no gaps.

The heating element extending through the spinning block is designed to facilitate insertion into and removal from the spinning block in the cooled state. The shape of the hollow space and the shape of the heating element are preferably made cylindrical. What is important here is that the shape of the heating element and the shape of the hollow space are as closely matched as possible, taking into account the thermal expansion of the material. In particular, the end of the heating rod that abuts the end of the hollow space when fully inserted is shaped so that there is virtually no hollow space between the heating rod and the expansion block. Particularly preferred are heating elements that are mechanically pressed into, for example, a hollow space, so that a good heat transfer takes place between the heating element and the expansion block. This pressure need only be applied until the heating element expands to a predetermined degree after heating, such that it firmly holds itself in a particular position.

The heating element can be heated in a manner known per se, but electric heating, in particular electric resistance heating, is preferred.

The coefficient of thermal expansion of the material that substantially contains the heating element is greater than the coefficient of thermal expansion of the material from which the components of the spinning block are made. Thus, the heating element can be made to be covered by a material having a higher coefficient of thermal expansion than the heating element. In particular, a metal with a relatively low melting point, preferably an alloy, is used as the material for the heating element. Particularly preferred are linear thermal expansion coefficient 20.5 × 10 ^-6
(° C) ^-1 is an alloy such as cast Al-Si or cast Al-Si-Mg.

It is not important that the entire spinning block component be made of a material having a low coefficient of thermal expansion. Importantly, in order to improve the heat transfer between the heating element and the spinning block, the increase in the volume of the hollow space in which the heating element is located during heating is increased by the volume of the heating element located in this space. Is smaller than.

The coefficient of thermal expansion between the material surrounding the heating element and the material of the heating element having a high coefficient of thermal expansion is 1: 1.05.
Or more, preferably 1: 1.5 or more, and specifically 1: 1.7 or more. The gap or hollow space between the heating element and the spinning block should be as small as possible, but if the ratio of the coefficients of thermal expansion is large, the pressure caused by the difference in the expansion of the material is The mechanical load bearing strength should not be exceeded.
Such stress can be reduced by increasing the gap between the heating element and the spinning block. As a result, the pressure between the materials due to the difference in thermal expansion can be reduced to the desired level. This gap can preferably be as small as possible.

A spinning block consisting of a plurality of interconnected metal blocks is convenient, in which the heating elements can be separated from one another without the heating elements having to be removed beforehand. Their longitudinal axes are aligned. The separation of the individual metal blocks takes place in the cooled state.

The spinning block, which is made up of several parts, is preferably provided with a heating device. These heating devices extend straight through the spinning block and thus heat all parts of the spinning block simultaneously.

Providing a heating element is particularly desirable as long as the removal work for replacing the filter or nozzle plate is simple. A design in which the heating element can be pushed in and removed from above is particularly preferred.

The spinning block according to the invention can be heated separately when removed. The detached heating can be performed by a second set of heating elements. However, the power supply line to the heating element can also be pluggable in order to connect the heating element to an external power supply and control device.

The heating elements provide for even heating so that the heat output is practically the same throughout, but the individual heating element zones can be compensated for temperature differences in the spinning block, or It may also be divided into a plurality of independently heatable zones in order to heat to different extents so that a particular desired temperature difference may be created thereby.

The temperature of the spinning block can be controlled by signals from one or more thermocouples. The thermocouple can be arranged in the heating element, or it can be arranged outside the heating element, for example in the spinning block, in the vicinity of the filter, in the inlet area of the melt, on the nozzle plate or in the nozzle plate. It is preferably located inside the heating element.

[0022]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to FIGS. 1 to 3, but the present invention is not limited to the embodiments shown in these drawings.

According to FIG. 1, the melt has a flange (2).
Flows through the feed line (1) via a pump connected to and then feeds the actual spinning block (3). The spinning block is provided with a bore (4) for receiving a heating element. Spinning ·
The block consists of an upper block (6) and a lower block (7), which can be separated at the face (5).

The polymer melt enters the filter (9) via the feed line (8), first through the filter and then through the nozzle plate (10) which constitutes the lower end of the spinning block. Electrically heated heating rods (11) are inserted into the bore (4), these heating rods comprising a cable (13) and a plug (14).
Connected to a power source or a control device. The two parts of the spinning block are interconnected by screws (15).

According to FIG. 3, the heating element (11) and the screw (15) are arranged annularly around the filter (9).

Spinning blocks designed in accordance with the present invention provide significant advantages in fiber manufacturing. In particular, the heating element can be removed from the spinning block in a simple manner, which simplifies maintenance.
It is particularly advantageous to remove the heating element after cooling the spinning block. This is because the difference in coefficient of thermal expansion creates an intermediate space between the heating element and the spinning block. In the case of a multi-part spinning block, removal of the heating element can be very easy if the heating element extends through all of the parts to be heated of the block.

The spinning block according to the invention has the feature that it is surprisingly easy to remove for replacement or maintenance of filters or nozzle plates. Prior to removal, the heating element can first be removed. It is particularly convenient to carry out the removal of the spinning block with the heating element inserted. This is because the working steps required to do this are particularly low.

A heating element designed and arranged according to the invention is capable of heating the spinning block in a decisive and advantageous manner. Since the spinning block is internally heated, the heat can be radiated particularly directly. Multi-part spinning blocks can be heated very easily using elements that extend through all parts of the block to be heated.

If the form of the heating elements is elongated and arranged in the direction of the axis of the main flow direction of the melt, it is likewise advantageous for disassembly and uniform heating. The heating can be carried out in a particularly preferred manner if the heating elements are arranged evenly, preferably in a ring about this axis.

The heating element according to the invention can improve the heat transfer between the heating element and the spinning block. The close contact results in high heat flow, which allows the spinning block to heat up very quickly.

A particularly great advantage is a spinning block in which the heating element is divided into zones which can be heated independently. Thus, the effects of localized heating or cooling that may occur on the present spinning block can be compensated. It is also possible to create specific temperature distributions or gradients to create specific spinning process conditions.

[Brief description of drawings]

FIG. 1 is a perspective view showing a spinning block with a supply line.

FIG. 2 is a sectional view taken along line II-II of the spinning block.

FIG. 3 is a sectional view taken along line III-III of the spinning block.

[Explanation of symbols]

1 Supply line 2 Flange 3 Spinning block 4 Bore 5 Surface 6 Upper block 7 Lower block 8 Supply line 9 Filter 10 Nozzle plate 11 Electric heating type heating rod 13 Cable 14 Plug 15 Screw

Claims (11)

[Claims] 1. A melt filter, nozzle plate,
And a spinning device for a melt-spinning device consisting of one or more interconnected metal blocks including a heating device.
In a block, the heating device heats the spinning block (3) from the inside and comprises one or more heating elements (11) in the form of elongated strips, these elements covering the entire spinning block (3). Extends through and is evenly distributed about the axis of the main melt flow direction so that it can be removed for replacement of the filter (9) or nozzle plate (10) or for maintenance purposes Spinning block for anti-melting device. 2. Is the heating element (11) made of a substantially single material to improve heat transfer between the heating element (11) and the spinning block (3)? Alternatively, the spinning block of claim 1 coated with a material having a higher coefficient of thermal expansion than the material surrounding the heating element. 3. The spinning block according to claim 1, wherein the heating element (11) can be pushed in and removed from above. 4. The spinning block (3) comprises a plurality of interconnected metal blocks (6, 7), the longitudinal axis of the heating element (11) defining the heating element (11). Spinning block according to claim 1 or 2, wherein the individual metal blocks (6, 7) are aligned such that they can be separated from each other without prior removal. 5. Spinning block according to claim 1 or 2, wherein the spinning block (3) comprises a plurality of parts and the heating device heats all parts of the spinning block (3) evenly. block. 6. The heating element (11) according to claim 1 or 2, wherein the heating element (11) is configured to simplify the removal procedure for replacing the filter (9) or the nozzle plate (10). Spinning block. 7. The heating element (11) is divided into zones that can be individually heated, each heating element zone being heated to a different extent, so that the temperature of the spinning block (3) is increased. 3. The spinning block according to claim 1, wherein the difference can be compensated for or a particularly favorable temperature difference can be created thereby. 8. A spinning block according to claim 1 or 2, wherein the spinning blocks (3) can be individually preheated in the removed state. 9. The heating element (11) comprises one or more thermocouples, which are arranged inside the heating element and can be used to control the temperature, The spinning block according to claim 1 or 2. 10. The spinning block (3) comprises:
Including one or more thermocouples, these thermocouples being
Spinning block according to claim 1 or 2, which is arranged outside the heating element and which can be used to control the temperature. 11. Use of a spinning block according to claim 1 for melt spinning filaments from thermoplastic polymers.