CN115230129B - Steel belt mold cooling system for continuously winding glass fiber tube - Google Patents

Abstract

The invention discloses a steel belt mould cooling system for continuously winding a glass fiber pipe, which comprises a fixed seat, a steel belt guide plate arranged on the fixed seat and an air pipe arranged on the steel belt guide plate; a plurality of guide wheels are arranged on the steel belt guide plate; the device is characterized in that a water cooling mechanism and an air cooling mechanism are arranged on the fixed seat; the water cooling mechanism comprises cooling water tanks respectively arranged on two sides of the steel belt die, a lifting cylinder connected with the cooling water tanks and arranged on the fixing seat, and a fan arranged on the fixing seat; the air cooling mechanism comprises a fixing frame, an air jet box arranged on the fixing frame and a plurality of air jet ports arranged on the air jet box. According to the invention, the steel belt die is water-cooled through the water cooling mechanism, so that the temperature of the steel belt die is reduced, the steel belt die is conveniently demoulded, and the quality of a pipe body is improved; the steel belt die is cooled by water twice by utilizing the water cooling mechanism and the air cooling mechanism, so that the cooling effect of the steel belt die is improved.

Description

Steel belt mold cooling system for continuously winding glass fiber tube

Technical Field

The invention relates to the technical field of steel belt module cooling, in particular to a steel belt mold cooling system for continuously winding glass fiber tubes.

Background

The production of the glass fiber reinforced plastic pipe in China comprises three processes, namely a continuous winding process, a fixed-length winding process and a centrifugal casting process, wherein the continuous winding process is realized by a steel belt die which is usually continuously output, and the steel belt is excessively high in temperature due to factors such as pipeline demoulding and friction and the like during continuous production, and the steel belt is excessively high in temperature, so that the adhesion phenomenon between the steel belt and the resin or the pipeline body of a production pipeline is caused, the production quality of the pipe is influenced, and therefore the steel belt needs to be cooled to ensure normal production; the steel belt die is in a moving state in use in high-temperature summer, and the temperature of the steel belt die in a workshop in summer in the south is very high, so that blown gas is higher than the temperature in other seasons, the steel belt die cannot be cooled rapidly, the steel belt die is too high in temperature, and raw materials or pipe bodies such as resin and the like possibly exist in reproduction, so that demolding is inconvenient. Therefore, the invention provides a cooling system for cooling a steel belt die, which can select the on-off of a cooling device according to different workshop temperatures so as to prevent the steel belt die from being excessively high in temperature.

Disclosure of Invention

The invention aims to solve the problems and provides a steel belt mould cooling system for continuously winding glass fiber pipes.

In order to achieve the above purpose, the present invention provides the following technical solutions: a cooling system of a steel belt mould for continuously winding a glass fiber pipe comprises a fixed seat, a steel belt guide plate arranged on the fixed seat and an air pipe arranged on the steel belt guide plate; a plurality of guide wheels are arranged on the steel belt guide plate; the device is characterized in that a water cooling mechanism and an air cooling mechanism are arranged on the fixed seat; the water cooling mechanism comprises cooling water tanks respectively arranged on two sides of the steel belt die, a lifting cylinder connected with the cooling water tanks and arranged on the fixing seat, and a fan arranged on the cooling water tanks; the air cooling mechanism comprises a fixing frame, an air jet box arranged on the fixing frame and a plurality of air jet ports arranged on the air jet box.

Preferably, a plurality of bearing seats are arranged on the cooling water tank; the bearing seat (on which a plurality of guide rollers are arranged).

Preferably, a cooling water pipe is arranged between the guide roller and the cooling water tank.

Preferably, silica gel scrapers attached to the two sides of the steel belt die are respectively arranged on the cooling water tanks on the two sides of the steel belt die; the guide roller is provided with a mounting pipe; the guide roller is installed on the bearing seat through an installation pipe.

Preferably, the cooling water pipe comprises a cooling water inlet pipe connected with the installation pipe at one end of the guide roller and a cooling water outlet pipe connected with the installation pipe at the other end of the guide roller.

Preferably, rotary joints are arranged between the cooling water inlet pipe and the cooling water outlet pipe and the mounting pipe; and a cooling inner cavity communicated with the mounting pipe is arranged in the guide roller.

Preferably, a gas cooling water pipe and a gas inlet are arranged in the gas injection box; the air injection box is also provided with a condensed water outlet; the air cooling water pipe is connected with the cooling water tank.

Preferably, one end of the air nozzle is higher than the inner wall surface of the air jet box.

Preferably, a water pump is also arranged between the air cooling water pipe and the cooling water tank.

Preferably, a condensate pipe connected with the cooling water tank is arranged on the condensate outlet.

The invention has the beneficial effects that: the steel belt die is water-cooled through the water cooling mechanism, so that the temperature of the steel belt die is reduced, the steel belt die is convenient to demould, and the quality of the pipe body is improved;

the water cooling mechanism and the air cooling mechanism are utilized to cool the steel belt die in a water-cooling and air-cooling dual mode, so that the cooling effect of the steel belt die is improved, and the demoulding effect is further improved.

Drawings

Fig. 1 is a schematic structural view of the present invention.

Fig. 2 is an enlarged view of a portion of fig. 1 a of the present invention.

Fig. 3 is a schematic view of the water cooling mechanism of the present invention.

FIG. 4 is a cross-sectional view of the water cooling mechanism of the present invention.

Fig. 5 is a cross-sectional view of the air cooling mechanism of the present invention.

Legend description: 1, fixing a seat; 101 a steel belt guide plate; 102, an air pipe; 103 guide wheels; 2, a water cooling mechanism; 201 cooling a water tank; 202 lifting air cylinders; 203 fans; 204 bearing blocks; 205 guide rollers; 206 cooling water pipes; 207 a silica gel scraper; 208 mounting a tube; 209 cooling the inlet pipe; 210 cooling the water outlet pipe; 211 a rotary joint; 212 cooling the inner cavity; 3, an air cooling mechanism; 301 fixing frame; 302 jet box; 303 gas nozzles; 304 air cooling water pipe; 305 air inlets; 306 a condensate outlet; 307 water pump; 308 condensate line.

Detailed Description

The following describes a cooling system for a steel belt mold for continuously winding glass fiber tubes according to the present invention with reference to the accompanying drawings.

Example 1

Referring to fig. 1-2, a cooling system for a steel belt mold for continuously winding glass fiber tubes in this embodiment includes a fixing base 1, a steel belt guide plate 101 mounted on the fixing base 1, and an air pipe 102 mounted on the steel belt guide plate 101; a plurality of guide wheels 103 are arranged on the steel belt guide plate 101; the device is characterized in that a water cooling mechanism 2 and an air cooling mechanism 3 are arranged on the fixed seat 1; the water cooling mechanism 2 comprises cooling water tanks 201 respectively arranged on two sides of the steel belt die, a lifting cylinder 202 connected with the cooling water tanks 201 and arranged on the fixed seat 1, and a fan 203 arranged on the cooling water tanks 201; the air cooling mechanism 3 comprises a fixing frame 301, an air jet box 302 arranged on the fixing frame 301, and a plurality of air jet ports 303 arranged on the air jet box 302; the steel belt die is subjected to water cooling through the water cooling mechanism 2, so that the temperature of the steel belt die is reduced, the steel belt die is conveniently demoulded, and the quality of a pipe body is improved; the steel belt die is cooled by water cooling and air cooling by the water cooling mechanism 2 and the air cooling mechanism 3, so that the cooling effect of the steel belt die is improved, and the demoulding effect is further improved.

Referring to fig. 1-4, the cooling water tank 201 is provided with a plurality of bearing seats 204; a plurality of guide rollers 205 are mounted on the bearing seat 204; a cooling water pipe 206 is arranged between the guide roller 205 and the cooling water tank 201; the cooling water tanks 201 on the two sides of the steel belt mold are respectively provided with a silica gel scraper 207 attached to the two sides of the steel belt mold; the guide roller 205 is provided with a mounting pipe 208; the guide roller 205 is mounted on the bearing seat 204 through a mounting tube 208; the cooling water pipe 206 comprises a cooling water inlet pipe 209 connected with a mounting pipe 208 at one end of the guide roller 205 and a cooling water outlet pipe 210 connected with a mounting pipe 208 at the other end of the guide roller 205; a rotary joint 211 is arranged between the cooling water inlet pipe 209, the cooling water outlet pipe 210 and the mounting pipe 208; a cooling inner cavity 212 communicated with the mounting tube 208 is arranged in the guide roller 205; cooling water in the cooling water tank 201 enters the cooling inner cavity 210 of the guide roller 205 through the cooling water inlet pipe 209, and then flows back into the cooling water tank 201 from the cooling water outlet pipe 210 to circularly cool the guide roller 205, so as to cool the steel belt die contacted with the guide roller 205, thereby being convenient for cooling the steel belt die; the silica gel scraper 207 is used for scraping off the water vapor generated by cooling on the steel belt die, so that the rust caused by water drop residue of the steel belt die is prevented.

Referring to fig. 1-5, a gas cooling water pipe 304 and a gas inlet 305 are installed in the gas box 302; one end of the air jet port 303 is higher than the inner wall surface of the air jet box 302; the air injection tank 302 is also provided with a condensed water outlet 306; the air cooling water pipe 304 is connected with the cooling water tank 201; a water pump 307 is also arranged between the air cooling water pipe 304 and the cooling water tank 201; a condensate water pipe 308 connected with the cooling water tank 201 is arranged on the condensate water outlet 306; the cooling water in the cooling water tank 201 is conveyed into the air cooling water pipe 304 by the water pump 307 to cool the air entering the air jet box 302, and then the cooled air is jetted into the steel belt mold of the box by the air jet ports 303, so that rapid cooling of the steel belt mold is facilitated, and the cooling effect of the steel belt mold is improved; through the one end of jet 303 is higher than the inner wall surface of jet box 302, prevents that the comdenstion water that gas produced from encountering cold from spouting to the steel band mould from jet 303 to guarantee the normal production of steel band mould.

When the invention is applied in high-temperature seasons such as summer, the control system of the system controls the water pump 307 to convey cooling water in the cooling water tank 201 into the air cooling water pipe 304 by the water pump 307 during the continuous production of other glass fiber products such as glass fiber pipelines and the like, and the inside of the air injection box 302 is cooled; then, the gas in the factory enters a cooled gas injection box 302 or is conveyed into the cooled gas injection box 302 through a gas pump, the gas entering the gas injection box 302 and the gas in the cooled box are mutually replaced to form low-temperature gas, condensed water generated by replacement flows into a condensed water pipe 308 through a condensed water outlet 306 and flows back into a cooling water tank 201 from the condensed water pipe 308, and the low-temperature gas is sprayed to a steel belt die of a slave machine head through a gas injection port 303 to cool the surface of the steel belt die for the first time; then the air pipe 102 is utilized to cool the steel belt mould at normal temperature when the steel belt mould passes through the steel belt guide plate 101, the second cooling is realized, when the steel belt mould moves to the water cooling mechanism 2, the steel belt mould passes through the guide roller 205, the guide roller 205 is driven to roll, meanwhile, cooling water in the cooling water tank 201 enters the cooling inner cavity 210 of the guide roller 205 by the cooling water inlet pipe 209, then flows back into the cooling water tank 201 from the cooling water outlet pipe 210, the guide roller 205 is cooled circularly, the steel belt mould contacted with the guide roller 205 is cooled for three times, then the silica gel scraper 207 is utilized to scrape off water vapor and water drops generated when the steel belt mould is cooled, and the remaining water vapor of the steel belt mould is dried by the fan 203, and four times of cooling is realized at the same time, so that the cooling of the steel belt mould is ensured, and the normal production of the steel belt mould is realized.

Example 2

Compared with the embodiment 1, when the steel belt mold is produced in winter or under the condition of lower external temperature, one of the water cooling mechanism 2 or the air pipe 102 normal-temperature air cooling mechanism or the low-temperature air cooling mechanism 3 and the fan 203 can be selected to cool the steel belt mold, so that the normal use of the steel belt mold is ensured; the lifting cylinder is arranged without adopting the water cooling mechanism 2, so that the lifting cylinder 202 is used for controlling the cooling water tank 201 to reset, friction between the steel belt guide rollers 205 is reduced, and meanwhile, friction heat generation is avoided.

The above embodiments are illustrative of the present invention, and not limiting, and any simple modifications of the present invention fall within the scope of the present invention.

Claims (7)

1. A steel belt mould cooling system for continuously winding glass fiber pipes comprises a fixed seat (1), a steel belt guide plate (101) arranged on the fixed seat (1) and an air pipe (102) arranged on the steel belt guide plate (101); a plurality of guide wheels (103) are arranged on the steel belt guide plate (101); the device is characterized in that a water cooling mechanism (2) and an air cooling mechanism (3) are arranged on the fixed seat (1); the water cooling mechanism (2) comprises cooling water tanks (201) which are respectively arranged on two sides of the steel belt die, a lifting cylinder (202) which is connected with the cooling water tanks (201) and is arranged on the fixed seat (1), and a fan (203) which is arranged on the cooling water tanks (201); the air cooling mechanism (3) comprises a fixing frame (301), an air jet box (302) arranged on the fixing frame (301) and a plurality of air jet ports (303) arranged on the air jet box (302); a plurality of bearing seats (204) are arranged on the cooling water tank (201); a plurality of guide rollers (205) are arranged on the bearing seat (204); a cooling water pipe (206) is arranged between the guide roller (205) and the cooling water tank (201); the guide roller (205) is provided with a mounting pipe (208); the guide roller (205) is arranged on the bearing seat (204) through a mounting tube (208); an air cooling water pipe (304) and an air inlet (305) are arranged in the air jet box (302).

2. A steel strip die cooling system for continuously wrapping glass fiber tubes as claimed in claim 1 wherein: the cooling water pipe (206) comprises a cooling water inlet pipe (209) connected with a mounting pipe (208) at one end of the guide roller (205) and a cooling water outlet pipe (210) connected with the mounting pipe (208) at the other end of the guide roller (205).

3. A steel strip die cooling system for continuously wrapping glass fiber tubes as claimed in claim 2 wherein: a rotary joint (211) is arranged between the cooling water inlet pipe (209) and the cooling water outlet pipe (210) and the mounting pipe (208); the guide roller (205) is internally provided with a cooling inner cavity (212) communicated with the mounting tube (208).

4. A steel strip die cooling system for continuously wrapping glass fiber tubes as claimed in claim 1 wherein: the cooling water tanks (201) on the two sides of the steel belt die are respectively provided with a silica gel scraper (207) attached to the two sides of the steel belt die; the air cooling water pipe (304) is connected with the cooling water tank (201); the air injection tank (302) is also provided with a condensed water outlet (306).

5. A steel strip die cooling system for continuously wrapping glass fiber tubes as claimed in claim 1 wherein: one end of the air jet opening (303) is higher than the inner wall surface of the air jet box (302).

6. A steel strip die cooling system for continuously wrapping glass fiber tubes as claimed in claim 4 wherein: a water pump (307) is also arranged between the air cooling water pipe (304) and the cooling water tank (201).

7. A steel strip die cooling system for continuously wrapping glass fiber tubes as claimed in claim 4 wherein: and a condensed water pipe (308) connected with the cooling water tank (201) is arranged on the condensed water outlet (306).

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