KR101207746B1 - Device for heating spinning nozzle block - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heating apparatus for a spinning nozzle block. Arranging the radiation nozzles 3, and having a plurality of electric heaters (H), a cooling tube (C), and a temperature sensor (S) around the branch pipe (2a) and each of the radiation nozzles (3). will be.
According to the present invention, the nozzle block 1 is heated and maintained at the radiation temperature by a plurality of electric heaters (H) (Ha), and the temperature deviation is detected by sensing the radiation temperature of each radiation nozzle (3) by the temperature sensor (C). If generated, it can be controlled to a constant temperature by the electric heater (Ha) and the cooling tube (C) adjacent to the spinning nozzle to spin a high quality synthetic fiber at a constant spinning temperature.

Description

Heating device for spinning nozzle block {DEVICE FOR HEATING SPINNING NOZZLE BLOCK}

The present invention relates to a heating apparatus of a spinning nozzle block for heating and maintaining a spinning nozzle block of a synthetic resin fiber at a constant spinning temperature.

3 and 4 are exemplary views of an apparatus for heating and maintaining a nozzle at a predetermined spinning temperature during spinning of a synthetic resin fiber, such as polypropylene resin (PP), as an example of the prior art. In the heating chamber (a) filled with the provided oil (o), the supply passage (d) of the synthetic resin solution and the branch pipe (da) and the plurality of spinning nozzles (n) associated with the branch pipe (da) The block (b) is placed and the supply passage (d) of the synthetic resin solution, the branch pipe (da), and the spinning nozzle (n) by the oil (o) of the heating chamber (a) heated by the electric heater (h). (b) is heated and maintained at the set spinning temperature.

The oil (o), which is heated by the electric heater (h) disposed in the heating chamber (a), maintains the block (b) of the spinning nozzle (n) at a set spinning temperature. ) Is convection in the heating chamber (a) as it heats, but the temperature distribution of the oil in the heating chamber is not constant depending on the type of convection, and variations occur depending on the position. The supply passage (d) and the branch pipe (da) of the synthetic resin solution have no problem in the supply operation because there is fluidity of the synthetic resin while the synthetic resin solution is maintained in the melting temperature range even if there is a slight temperature deviation in heating.

However, in the case of the spinning nozzle (n), even though there is a slight temperature deviation, the spinning fiber structure is not uniform, so that spinning of a certain quality is difficult. In addition, since all spinning nozzles are heated by oil, each nozzle There is a problem that can not control the minute temperature, and because the oil is a fluid, the heat transfer rate is slow and the temperature change is insensitive, there was a problem that rapid temperature control is difficult.

SUMMARY OF THE INVENTION An object of the present invention is to provide a heating device for a spinning nozzle block which can be controlled at a rapid and precisely set spinning temperature when a change in the simultaneous spinning temperature is maintained at a constant spinning temperature.

Another object of the present invention is a metal nozzle block is provided with a supply passage and a branch pipe of the synthetic resin solution and a plurality of spinning nozzles associated with the branch pipe and a plurality of electric heaters and cooling tubes around the branch pipe and the spinning nozzle and A temperature sensor is provided to maintain the nozzle block at a basic radiation temperature by a plurality of heat transfer heaters, and according to the sensing signal of the temperature sensor, a minute temperature of the radiation temperature is reduced for each radiation nozzle by an electric heater and a cooling tube provided around the radiation nozzle. It is to provide a heating device of the spinneret block configured to be able to more quickly and accurately control the fluctuation.

Still another object of the present invention is to provide a heating device for a spinning nozzle block capable of controlling the spinning temperature of each spinning nozzle to be able to spin higher quality fibers.

According to the present invention, in the synthetic resin spinneret, a supply passage and a branch pipe of the synthetic resin solution and a plurality of spinning nozzles associated with the branch pipe are arranged in a metal nozzle block, and a plurality of electric heaters are disposed around the branch pipe and the spinning nozzle. A plurality of cooling tubes and a temperature sensor are provided around the spinning nozzle.

According to the present invention configured as described above, the nozzle block is heated to a basic spinning temperature by a plurality of electric heaters provided around the branch pipe and the spinning nozzle. Since the metal nozzle block has good thermal conductivity, heat is quickly transferred to the entire block so that the supply passage of the synthetic resin solution, the branch pipe, and the spinning nozzle are heated and maintained at the basic spinning temperature. Therefore, the synthetic resin solution is supplied to the supply passage and the branch pipe at a constant pressure by an external supply means, and the synthetic fiber is spun from the spinning nozzle.

At this time, the radiation temperature of each radiation nozzle is sensed by a temperature sensor provided for each radiation nozzle. When the radiation nozzle rises above the set radiation temperature by the heat storage of the nozzle block as the spinning process proceeds, the refrigerant is circulated to the cooling tube by the external controller according to the detection signal of the temperature sensor to suppress the increase in temperature. do. When it is adjusted to the set radiation temperature, the supply of the refrigerant to the cooling pipe is stopped by the controller according to the detection signal of the temperature sensor.

In addition, when the temperature drops below the radiation temperature of the radiation nozzle for some reason, a plurality of electric heaters provided around the radiation nozzle are controlled to a higher temperature according to an external controller's instruction according to the detection signal of the temperature sensor. Controlled by temperature. At this time, since the nozzle block is made of metal, the thermal conductivity is good, so it is sensitive to temperature change and can be quickly controlled. As such, it is possible to spin the synthetic resin fiber at a constant spinning temperature by being quickly adjusted to a constant temperature with respect to a slight change in the spinning temperature of each spinning nozzle.

 In the present invention, the supply passage, the branch pipe and the plurality of spinning nozzles of the synthetic resin solution disposed on the metal nozzle block are arranged, and the plurality of electric heaters and cooling tubes are provided around the branch pipe and the spinning nozzle to control the spinning temperature for each spinning nozzle. Because it is configured to control, it is possible to control the constant radiation temperature for each spinning nozzle.

 In addition, because the temperature control is set for each spinning nozzle, it is possible to spin higher quality synthetic fiber by controlling the spinning temperature of various synthetic resins.

The present invention is configured by arranging a supply passage and a branch pipe of a synthetic resin solution in a metal nozzle block and a plurality of spinning nozzles associated with the branch pipe, and a plurality of electric heaters and cooling tubes around the branch pipe and the spinning nozzle. Because of its simple structure, handling is easy.

In addition, the electric heater provided around the branch pipe maintains the nozzle block at the basic radiation temperature, and the radiation temperature is controlled more accurately for each radiation nozzle according to the detection signal of the temperature sensor by the electric heater provided around each radiation nozzle. Thus, there are various effects that can spin a higher quality synthetic resin fiber at a constant spinning temperature.

1 is a front sectional view of a spinning nozzle of the present invention;
Figure 2 is a side cross-sectional view of the spinning nozzle of the present invention.
Figure 3 is a low cross-sectional view of a conventional spinning nozzle heating apparatus
Figure 4 is a front sectional view of the radiant nozzle heating device of Figure 3

An embodiment of the present invention will be described in detail with reference to the drawings.

As shown in Figs. 1 and 2, in the synthetic resin spinning machine, a plurality of spinning yarns connected to the supply passage 2 of the synthetic resin solution, the branch pipe 2a, and the branch pipe 2a to the nozzle block 1 made of metal material. The nozzle 3 is disposed, and a plurality of electric heaters H and a cooling tube C are provided around the branch pipe 2a and the spinning nozzle 3, and the side of each spinning nozzle 3 is provided. It is provided with a temperature sensor (S) to be configured to control the radiation temperature of the radiation nozzle (3) by the electric heater (Ha) and the cooling tube (C) according to the detection signal of the temperature sensor.

According to the present invention configured as described above, the nozzle block 1 is turned on by supplying power from a controller not shown in the electric heater (H) Ha provided in the nozzle block 1 (the radiation of polyflophylene resin). If at 250 ° C.). Therefore, the synthetic resin solution is supplied to the supply passage 2 and the branch pipe 2a by a supply means not shown from the outside to spin the synthetic resin fibers at the pressure specified in the spinning nozzle 3.

  The temperature of each spinning nozzle 3 is continuously sensed by the temperature sensor S while spinning the synthetic resin fibers. If the radiation time fluctuates higher than the set radiation temperature of the radiation nozzle 3 by the heat storage of the nozzle block 1 as the elapse of the spinning time, the cooling tube is instructed by the controller (not shown) according to the detection signal of the temperature sensor S. The refrigerant is supplied to the circulation to (C) to suppress the temperature rise of the spinning nozzle 3. When it is adjusted to the set radiation temperature, the supply circulation operation of the coolant to the cooling pipe C is stopped by the controller according to the detection signal of the temperature sensor S.

If, for some reason, the temperature is lower than the set radiation temperature of the radiation nozzle 3, the electric heater (Ha) provided around the radiation nozzle 3 by the instruction of a controller (not shown) according to the detection signal of the temperature sensor S (Ha). ) Is controlled to a higher temperature. At this time, since the nozzle block 1 is maintained at the basic spinning temperature by the heater H, the temperature control of the spinning nozzle 3 corrects the changed minute temperature difference. In addition, since the metal nozzle block 1 has good thermal conductivity and is sensitive to temperature change, the result of temperature control appears quickly. When the radiation temperature of the radiation nozzle 3 is adjusted, the electric heater ha is controlled to the original temperature by the instruction of the controller according to the detection signal of the temperature sensor S.

Therefore, each spinning nozzle (3) by the individual temperature control always maintains a constant spinning temperature constant temperature, it is possible to spin the synthetic resin fibers of higher quality than all the spinning nozzle.

1: nozzle block, 2: supply passage, 2a: branch pipe, 3: spinning nozzle,
H, Ha: electric heater, C: cooling tube, S: temperature sensor.

Claims (2)

In a synthetic resin spinning machine in which a supply passage (2) of a synthetic resin solution, a branch pipe (2a), and a plurality of spinning nozzles (3) are arranged in the branch pipe (2a) in a metal nozzle block (1),
A plurality of electric heaters (H) (Ha) are arranged around the supply passage (2) and the branch pipe (2a) of the synthetic resin solution, and the cooling tube (C) and the temperature sensor (S) around each of the spinning nozzles (3). Heating device for a radiation nozzle block characterized in that it is provided with a) to control the temperature of the radiation nozzle (3) in accordance with the signal of the temperature sensor (S). The method of claim 1,
The plurality of radiating nozzles 3 arranged in the nozzle block 1 can control the temperature of each of the radiating nozzles 3 by the plurality of electric heaters H and the cooling tubes C disposed around the plurality of radiating nozzles 3. Heating device of the radial nozzle block, characterized in that configured to.

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