KR101137062B1 - Device for heating spinning nozzle - Google Patents

Abstract

The present invention relates to a heating device for a spinning nozzle, and in a synthetic resin spinning machine, an oil-filled heating chamber (1) and a metal nozzle block (3) are integrally combined, and the heating chamber (1) includes a plurality of electric heaters ( H) and the supply passage (2) and the branch pipe (2a) of the synthetic resin solution is arranged and a plurality of spinning nozzles (4) associated with the branch pipe (2a) are arranged in the nozzle block (3) and each spinning nozzle (4) ), A plurality of electric heaters (Ha), a cooling tube (C), and a temperature sensor (S) are provided at the periphery.
The electric heater H of the heating chamber 1 maintains the nozzle block 3 at a basic radiation temperature, and a plurality of electric heaters Ha and cooling tubes C provided around the plurality of spinning nozzles 4. And by the temperature sensor (S) to maintain the precise spinning temperature for each spinning nozzle it is possible to spin higher quality synthetic fiber.

Description

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

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

3 and 4 are illustrations of an apparatus for heating and maintaining a nozzle at a predetermined spinning temperature when spinning synthetic resin fibers, such as polypropylene (PP) resin, as an example of the prior art. 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) in the heating chamber (a) filled with the provided oil (o). Block (b) is arranged, 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). Block (b) is heated and maintained at the set radiation 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 the synthetic resin solution is fluid while it is maintained in the melting temperature range of the synthetic resin which is a spinning material even though there is a slight temperature deviation in heating.

However, in the case of the spinning nozzle (n), even though a slight temperature deviation occurs, spinning of the spun synthetic resin is not uniform, which makes it difficult to emit a certain quality and also blocks (b) of all the spinning nozzles (n) Since the heating chamber (a) is heated by the oil (o), there is a problem that the individual minute temperature control of the spinning nozzle (n) cannot be controlled. In addition, the oil is a fluid, and the heat transfer rate is slow and sensitive to temperature changes. There was a problem that it is difficult to control the temperature quickly and accurately.

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

Another object of the present invention is to integrally combine the oil filled heating chamber and the nozzle block, the heating chamber is provided with a plurality of electric heaters, the supply passage of the synthetic resin solution, the nozzle block and the branch pipe associated with the supply passage of the synthetic resin solution; A plurality of radiation nozzles associated with the branch pipes are arranged, and a plurality of electric heaters, cooling tubes, and temperature sensors are provided around each of the plurality of radiation nozzles, and are heated and maintained at a basic radiation temperature by an electric heater provided in the heating chamber. SUMMARY OF THE INVENTION An object of the present invention is to provide a heating device for a spinning nozzle configured to quickly and accurately correct a change in the spinning temperature of each spinning nozzle by a plurality of electric heaters and cooling tubes arranged in the nozzle block.

It is still another object of the present invention to provide a heating device for spinning nozzles capable of controlling the spinning temperature of each spinning nozzle to be able to spin higher quality synthetic fiber.

According to the present invention, in the synthetic resin spinneret, the oil-filled heating chamber and the nozzle block are integrally combined, and the heating chamber is provided with a plurality of electric heaters and a supply passage of the synthetic resin solution. The nozzle block made of a metal material includes a branch pipe associated with the supply passage of the synthetic resin solution, a plurality of spinning nozzles associated with the branch pipe, and a plurality of electric heaters, cooling tubes, and temperature sensors around the spinning nozzle. By heating the basic radiation temperature by the electric heater provided in the oil heating chamber, and by changing the radiation temperature of the spinning nozzle by the electric heater and the cooling tube provided in the nozzle block it is configured to be able to immediately control the exact spinning temperature.

According to the present invention configured as described above, the oil is heated by an electric heater provided in the heating chamber to maintain the supply passage of the synthetic resin solution, the branch pipe and the spinning block by the heated oil to the basic spinning temperature. Each spinning nozzle is supplied with a synthetic resin solution to the supply passage and the branch pipe of the synthetic resin solution by the raw material supply means from the outside while maintaining accurate heating at the spinning temperature of each spinning nozzle by an electric heater provided around each spinning nozzle. Spin the synthetic fibers at a predetermined pressure at.

Since the heated oil in the heating chamber is convection as a fluid even during the spinning operation, the temperature distribution varies depending on the position of the inside of the heating chamber depending on the type of convection. However, the supply passage and the branch pipe of the synthetic resin solution are not impeded to supply the synthetic resin solution as long as the temperature of the synthetic resin is maintained even though there is a slight temperature deviation.

In the case of each spinning nozzle of the nozzle block, the temperature difference of the heating chamber is affected by the temperature sensor to detect the spinning temperature of each spinning nozzle.

When the synthetic fiber is spun from each spinning nozzle, if the spinning nozzle rises above the set spinning temperature due to the heat accumulation of the nozzle block of the metal, it is provided around the spinning nozzle by the instruction of an external controller according to the detection signal of the temperature sensor. The refrigerant is supplied to the cooling tube to suppress the increase in temperature. When the radiation nozzle returns to the set radiation temperature, the supply operation of the coolant supplied to the cooling tube is stopped by the controller according to the detection signal of the temperature sensor.

In addition, when the radiation nozzle is lowered to the temperature lower than the radiation temperature according to the room temperature or the temperature deviation of the heating chamber, a plurality of electric heaters provided around each nozzle by the external controller in response to the detection signal of the temperature sensor become hotter. It is controlled with the desired constant spinning temperature. At this time, since the nozzle block is heated and maintained at the basic spinning temperature by the heated oil, each nozzle adjusts for a small change in the spinning temperature, and a plurality of spinning nozzles arranged in the nozzle block are controlled at a predetermined spinning temperature. It keeps spinning the synthetic fiber continuously.

As described above, in the present invention, by combining the oil-filled heating chamber and the nozzle block in which the plurality of spinning nozzles are arranged, the basic spinning temperature is maintained by the plurality of electric heaters provided in the heating chamber, and around the spinning nozzle. Because it is configured to be able to control the minute change of the spinning temperature set by a plurality of electric heaters and cooling tubes more quickly and accurately, it is possible to spin high quality synthetic fiber by precisely and simply controlling the spinning temperature for each nozzle. have.

The present invention combines a nozzle chamber having a plurality of spinning nozzles with an oil-filled heating chamber, and maintains a basic spinning temperature by a plurality of electrical heaters provided in the heating chamber, and a plurality of electrical heaters provided around the spinning nozzle. Since it is configured to adjust at a slight change in the spinning temperature set by the heater and the cooling tube, the nozzle block can be heated and maintained at the basic spinning temperature by the oil heated in the heating chamber.

In addition, the spinning nozzle disposed on the metal nozzle block can control the change of the spinning temperature more quickly and accurately by the plurality of electric heaters and cooling tubes arranged around the nozzle.

Therefore, it is possible to maintain a constant spinning temperature, there is a variety of effects that the spinning of a variety of high-quality synthetic resin fibers than the conventional one.

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 Fig. 1 and Fig. 2, in the synthetic resin spinning machine, the heating chamber 1 filled with oil o and the nozzle block 3 made of metal are integrally combined, and the heating chamber 1 is provided with a plurality of electricity. A heater H, a supply passage 2 of the synthetic resin solution, and a branch pipe 2a associated with the supply passage 2, and the nozzle block 3 has a plurality of spinning nozzles associated with the branch pipe 2a. (4) and a plurality of electric heaters (Ha), cooling tubes (C) and temperature sensors (S) around each of the radiation nozzles (4) to radiate according to the detection signal of the temperature sensor (S) It is configured to be able to accurately control the spinning temperature of the nozzle (4) by the electric heater (Ha) and the cooling tube (C).

The present invention configured as described above is to supply power to the electric heater (H) provided in the heating chamber 1 to operate the oil (o) filled in the heating chamber (1) in the case of spinning temperature (polypropylene resin spinning 250 ° C.). The heated oil o is convection and heat-holds the supply pipe 2, the branch pipe 2a, and the nozzle block 3 of the synthetic resin solution disposed in the heating chamber 1. On the other hand, power is supplied to the electric heater (Ha) provided around the spinning nozzle (4) to keep all the spinning nozzle (4) heated to the spinning temperature.

Therefore, the synthetic resin solution supplied by the supply means from the outside is supplied to the supply passage 2 and the branch pipe 2a to spin the synthetic resin fibers at the pressure specified by the spinning nozzle 4.

  While spinning the synthetic fiber, the temperature is varied depending on the position of the heating chamber 1 depending on the convection of the heated oil o of the heating chamber 1, while the synthetic resin solution is in the melting temperature range of the synthetic resin solution. Since the solution is fluid, the supply passage (2) and the branch pipe (2a) flows to each of the spinning nozzles (3), and there is no problem, so there is no temperature control operation for the temperature deviation of the heating chamber.

Each spinning nozzle 4 disposed in the nozzle block 3 continues to sense the spinning temperature by the temperature sensor S even during spinning. If the nozzle block 3 of the metal material is accumulated during the spinning operation and the spinning nozzle 4 is higher than the set spinning temperature, the cooling tube is instructed by an external controller (not shown) according to the detection signal of the temperature sensor S. In (C), the refrigerant is supplied circulated to suppress the temperature rise of the spinning nozzle. When it is adjusted to the set radiation temperature, the supply circulation operation of the refrigerant to the cooling tube C is stopped by an instruction of a controller not shown in response to the detection signal of the temperature sensor S.

In addition, when the radiation temperature of the radiation nozzle 4 is lowered due to a cause such as room temperature or a temperature deviation of the heating chamber, the radiation nozzle 4 is instructed by a controller (not shown) according to the detection signal of the temperature sensor S. Electric heater (Ha) provided around the () is adjusted to a higher temperature. At this time, since the nozzle block 3 is already maintained at the basic spinning temperature by the heated oil o of the heating chamber 1, the temperature control of the spinning nozzle is adjusted by correcting the changed minute temperature difference. Because the adjustable temperature range for the radiation temperature change is narrow, quick adjustment is possible, and because the nozzle block is a metal material, the thermal conductivity is fast, so it is sensitive to the temperature change and thus the rapid control of the radiation temperature is possible.

Therefore, it is possible to spin a variety of synthetic resin fibers of higher quality than ever since the spinning nozzle 4 is constantly maintained at a constant spinning temperature by individual temperature control.

1: heating chamber, 2: supply passage, 2a: branch pipe, 3: nozzle block, 4: spinning nozzle,
H, Ha: electric heater, C: cooling tube, S: temperature sensor.

Claims (3)

In the synthetic resin spinning machine, a heating chamber (1) filled with oil and a nozzle block (3) made of metal are integrally combined, and the heating chamber (1) includes a plurality of electric heaters (H) for heating oil, and a synthetic resin solution. A supply passage 2 and a branch pipe 2a are arranged in the nozzle block 3, and a plurality of spinning nozzles 4 associated with the branch pipe 2a are disposed, and a plurality of spin nozzles are disposed around each of the spinning nozzles 4, respectively. The electric heater (Ha), the cooling tube (C) and the temperature sensor (S) of the heating nozzle characterized in that it comprises a. The radiation nozzle (4) according to claim 1, wherein the plurality of radiation nozzles (4) disposed in the nozzle block (3) are formed by radiation nozzles by a plurality of electric heaters (Ha) and cooling tubes (C) arranged around each of the radiation nozzles (4). Heating device of the radiation nozzle, characterized in that the temperature control by each. The heating nozzle heating device according to claim 1, wherein the nozzle block (3) is heated and maintained at a basic radiation temperature by a plurality of electric heaters (H) provided in the heating chamber (1).

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