CN210394618U - High-strength polyester yarn production is with preventing disconnected silk device - Google Patents

Abstract

The utility model discloses a production of high-strength polyester yarn is with preventing disconnected silk device, including frame, insulation box, spinning nozzle and corridor, the copper pipe of the vertical setting of spinning nozzle bottom fixedly connected with, copper pipe surface welded fastening has a plurality of heat conduction ring pieces, copper pipe surface cover is equipped with the spiral pipe, spiral pipe and heat conduction ring piece welded fastening, spiral pipe one side welded fastening has a plurality of fins that are used for the radiating, spiral pipe one side is provided with the heat collecting box, the fin inlays to be established inside the heat collecting box. The utility model discloses a be provided with the copper pipe, the fibre thick liquid of high temperature forms the fibre strand silk through the spinning jet, and the fibre strand silk is at the in-process through the copper pipe, and on the heat transmission of fibre strand silk arrived the copper pipe, the heat transmitted spiral pipe and fin through the heat conduction ring piece, is favorable to cooling down the processing to the fibre strand silk, makes its structure more stable, is difficult for disconnected silk.

Description

High-strength polyester yarn production is with preventing disconnected silk device

Technical Field

The utility model relates to the technical field of weaving, in particular to production of high-strength polyester yarn is with preventing disconnected silk device.

Background

The fiber tows are processed in a spinning machine which comprises a metering pump, a filter, a spinning nozzle and a channel. The fiber slurry enters a metering pump from a slurry pipe in the insulation box body, the metering pump presses the precisely metered fiber slurry into a filter for filtration, and then the fiber slurry is conveyed to a spinning nozzle and is sprayed into fiber strands with required diameters through tiny holes on the spinning nozzle. The fiber strand silk enters the channel and is dried by hot air. The upper end of the channel is provided with an air supply pipe, the air supply pipe is positioned on one side of the upper end of the channel, and the lower part of the channel is provided with an air return channel. Hot air directly enters the channel through the blast pipe, sprayed fiber strands are dried by the hot air after entering the channel, the hot air in the channel is pumped out through the air return channel at the lower part of the channel, and due to the fact that the temperature of the fiber strands sprayed out from the interior of the heat preservation box body is high, the structure is not stable enough, the fiber strands are easy to break under the action of wind power, and meanwhile, the heat of the fiber strands is wasted.

Therefore, it is necessary to invent a yarn breakage preventing device for producing high-strength polyester yarns to solve the above problems.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a production of high strength polyester yarn is with preventing disconnected silk device to solve the problem that proposes in the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: a yarn breakage preventing device for producing high-strength polyester yarns comprises a frame, a heat preservation box body, a spinning nozzle and a channel, wherein a vertically arranged copper pipe is fixedly connected to the bottom end of the spinning nozzle, a plurality of heat conducting ring blocks are fixedly welded on the surface of the copper pipe, a spiral pipe is sleeved on the surface of the copper pipe and fixedly welded with the heat conducting ring blocks, a plurality of fins for heat dissipation are fixedly welded on one side of the spiral pipe, a heat collecting box is arranged on one side of the spiral pipe, the fins are embedded in the heat collecting box, a water storage box filled with cooling water is fixedly arranged at the bottom end of the frame, a water outlet is formed in the bottom of the water storage box, a water inlet is formed in the top of the water storage box, the bottom end of the spiral pipe is communicated with the water outlet through a water pipe, the top end of the spiral pipe, a first flow equalizing ring and a second flow equalizing ring are fixedly arranged inside the channel, and a plurality of through holes are formed in the surfaces of the first flow equalizing ring and the second flow equalizing ring.

Preferably, the first flow equalizing ring and the second flow equalizing ring are arranged in a mirror image mode.

Preferably, the water storage tank is externally connected with a low-temperature cooling liquid circulating pump.

Preferably, the bottom of the heat collecting box is communicated with an air outlet pipe, and the top end of the heat collecting box is provided with a grid.

Preferably, the first flow equalizing ring is externally connected with a blower through a pipeline, one end of the air outlet pipe of the heat collecting box is communicated with the pipeline on one side of the first flow equalizing ring, and the second flow equalizing ring is externally connected with an exhaust fan through a pipeline.

Preferably, a single chip microcomputer is arranged on one side of the rack.

The utility model discloses a technological effect and advantage:

the utility model is provided with the copper pipe, the high-temperature fiber slurry forms fiber strand wires through the spinning nozzle, the heat of the fiber strand wires is transferred to the copper pipe in the process that the fiber strand wires pass through the copper pipe, and the heat is transferred to the spiral pipe and the fins through the heat conducting ring block, thereby being beneficial to cooling the fiber strand wires, ensuring that the structure of the fiber strand wires is more stable and the fiber strand wires are not easy to break; when the fiber strand silk after the cooling treatment is inside the corridor, the forced draught blower works, the heat dissipated from the fins in the heat collecting box is converted into hot air through the air outlet pipe at the bottom of the heat collecting box by utilizing the negative pressure principle, and the hot air is blown into the first flow equalizing ring, and is sprayed out through the through holes on the surface of the first flow equalizing ring to dry the fiber strand silk, so that the resource saving is facilitated.

Drawings

Fig. 1 is a schematic view of the overall front view section of the present invention.

Fig. 2 is a cross-sectional view of the first flow equalizing ring of the present invention.

Fig. 3 is an enlarged view of a portion a in fig. 1 according to the present invention.

In the figure: the device comprises a frame 1, a heat preservation box 2, a spinning nozzle 3, a channel 4, a copper pipe 5, a heat conduction ring block 6, a spiral pipe 7, a fin 8, a heat collecting box 9, a water storage box 10, a water outlet 11, a water inlet 12, a temperature sensor 13, a first flow equalizing ring 14, a second flow equalizing ring 15 and a through hole 16.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

The utility model provides a yarn breakage preventing device for producing high-strength polyester yarns, as shown in figures 1-3, which comprises a frame 1, a heat preservation box body 2, a spinning nozzle 3 and a corridor 4, wherein the bottom end of the spinning nozzle 3 is fixedly connected with a vertically arranged copper pipe 5, the copper material has good heat conductivity, the surface of the copper pipe 5 is fixedly welded with a plurality of heat conducting ring blocks 6, the surface of the copper pipe 5 is sleeved with a spiral pipe 7, the spiral pipe 7 is fixedly welded with the heat conducting ring blocks 6, one side of the spiral pipe 7 is fixedly welded with a plurality of fins 8 for heat dissipation, the spiral pipe 7, the heat conducting ring blocks 6 and the fins 8 are all made of the copper material, one side of the spiral pipe 7 is provided with a heat collecting box 9, the fins 8 are embedded inside the heat collecting box 9, the bottom end of the frame 1 is fixedly provided with a water storage box 10 filled with cooling water, the water inlet 12 has been seted up at the water storage box 10 top, 7 bottoms of spiral pipe are put through with delivery port 11 through the water pipe, are located 11 one sides of delivery port inside the water storage box 10 and are equipped with the circulating pump that is used for hydrologic cycle, 7 tops of spiral pipe are put through water pipe and water inlet 12, water storage box 10 internally mounted has temperature sensor 13, corridor 4 sets up in 5 bottoms of copper pipe, corridor 4 inside fixed has placed first ring 14 and the second ring 15 that flow equalizes, a plurality of through-holes 16 have all been seted up on first ring 14 and the second ring 15 surface that flow equalizes, and the diameter of through-hole 16 scales up from the inner circle of first ring 14 and the second ring 15 that flow equalizes toward the outer lane in proper order to evenly arrange, can both guarantee the air output, compromise the wind speed simultaneously, provide better evaporation to dryness environment for the fibre silk.

Further, in the above technical solution, the first flow equalizing ring 14 and the second flow equalizing ring 15 are mirror images;

further, in the above technical scheme, the water storage tank 10 is externally connected with a low-temperature cooling liquid circulating pump, when the temperature sensor 13 detects that the water temperature is too high, the temperature sensor 13 sends a signal to the single chip microcomputer, and the single chip microcomputer controls the low-temperature cooling liquid circulating pump to work, so that the water in the water storage tank 10 can be cooled, and the copper pipe 5 is prevented from being too high in temperature;

further, in the above technical scheme, the bottom of the heat collecting box 9 is communicated with an air outlet pipe, and the top end of the heat collecting box 9 is provided with a grid;

further, in the above technical solution, the first flow equalizing ring 14 is externally connected with a blower through a pipeline, one end of the outlet pipe of the heat collecting box 9 is communicated with the pipeline on one side of the first flow equalizing ring 14, and the second flow equalizing ring 15 is externally connected with an exhaust fan through a pipeline;

further, in the above technical solution, a single chip microcomputer is disposed on one side of the frame 1.

Further, in the above technical scheme, the type of the single chip microcomputer is set to 80C51, the type of the temperature sensor 13 is set to WRM-101, the temperature sensor 13 is electrically connected with the input end of the single chip microcomputer, and the output end of the single chip microcomputer is electrically connected with the low-temperature coolant circulating pump.

This practical theory of operation:

referring to the attached drawing 1 of the specification, the fiber slurry of high temperature forms the fiber strand silk through spinning jet 3, the fiber strand silk passes through copper pipe 5 and corridor 4, at the in-process through copper pipe 5, the heat transmission of fiber strand silk is to copper pipe 5, the heat transmits spiral pipe 7 and fin 8 for through heat conduction ring 6, be favorable to cooling down the processing to the fiber strand silk, make its structure more stable, be difficult for disconnected silk, when corridor 4 is inside, the forced draught blower work, utilize the negative pressure principle to give off fin 8 through the play tuber pipe of heat collecting box 9 bottom and turn into inside the hot-blast ring 14 that blows into in the heat of heat collecting box 9, spout through 14 surperficial through-hole 16 of the ring of first flow equalizing and dry the fiber strand silk, be favorable to resources are saved.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications and variations can be made in the embodiments or in part of the technical features of the embodiments without departing from the spirit and the scope of the invention.

Claims (6)

1. The utility model provides a production of high strength polyester yarn is with preventing disconnected silk device, includes frame (1), insulation box (2), spinning jet (3) and corridor (4), its characterized in that: the bottom end of the spinning nozzle (3) is fixedly connected with a vertically arranged copper pipe (5), the surface of the copper pipe (5) is fixedly welded with a plurality of heat-conducting ring blocks (6), the surface of the copper pipe (5) is sleeved with a spiral pipe (7), the spiral pipe (7) is fixedly welded with the heat-conducting ring blocks (6), one side of the spiral pipe (7) is fixedly welded with a plurality of fins (8) for heat dissipation, one side of the spiral pipe (7) is provided with a heat collecting box (9), the fins (8) are embedded in the heat collecting box (9), the bottom end of the frame (1) is fixedly provided with a water storage box (10) filled with cooling water, the bottom of the water storage box (10) is provided with a water outlet (11), the top of the water storage box (10) is provided with a water inlet (12), the bottom end of the spiral pipe (7) is communicated with the water outlet (11) through a, the water storage tank (10) is internally provided with a temperature sensor (13), the channel (4) is arranged at the bottom end of the copper pipe (5), a first flow-equalizing ring (14) and a second flow-equalizing ring (15) are fixedly arranged inside the channel (4), and a plurality of through holes (16) are formed in the surfaces of the first flow-equalizing ring (14) and the second flow-equalizing ring (15).

2. The yarn breakage preventing device for producing the high-strength polyester yarn according to claim 1, wherein: the first flow equalizing ring (14) and the second flow equalizing ring (15) are arranged in a mirror image mode.

3. The yarn breakage preventing device for producing the high-strength polyester yarn according to claim 1, wherein: the water storage tank (10) is externally connected with a low-temperature cooling liquid circulating pump.

4. The yarn breakage preventing device for producing the high-strength polyester yarn according to claim 1, wherein: the bottom of the heat collecting box (9) is communicated with an air outlet pipe, and the top end of the heat collecting box (9) is provided with a grid.

5. The yarn breakage preventing device for producing the high-strength polyester yarn according to claim 1, wherein: the first flow equalizing ring (14) is externally connected with a blower through a pipeline, one end of an air outlet pipe of the heat collecting box (9) is communicated with the pipeline on one side of the first flow equalizing ring (14), and the second flow equalizing ring (15) is externally connected with an exhaust fan through a pipeline.

6. The yarn breakage preventing device for producing the high-strength polyester yarn according to claim 1, wherein: and a singlechip is arranged on one side of the rack (1).

Images