WO2022264606A1 - Bushing, glass fiber manufacturing device, and glass fiber manufacturing method - Google Patents

Abstract

A bushing comprising: a base plate equipped with a plurality of cooling regions which extend in one prescribed direction, and on which a cooling member for cooling molten glass can be placed; a plurality of first nozzles provided in a first region, which is a region alongside the cooling region, of the base plate; and a plurality of second nozzles provided in a second region, which is a region alongside the cooling region, of the base plate, said bushing being characterized in that the average distance between the cooling region and the first region is shorter than the average distance between the cooling region and the second region, and the average length of the first nozzles is shorter than the average length of the second nozzles.

Description

BUSHING, GLASS FIBER MANUFACTURING DEVICE, AND GLASS FIBER MANUFACTURING METHOD

The present invention relates to improvements in glass fiber manufacturing technology.

Circular cross-section glass fibers whose cross-sections are perfect circles and modified cross-section glass fibers whose cross-sections are non-circular such as flattened oval or elliptical cross-sections have a high reinforcing effect when mixed with resin and combined. It is used in various fields because it can achieve

This type of glass fiber is generally produced by cooling molten glass while drawing it from a nozzle of a bushing. At this time, the cross-sectional shape of the manufactured glass fiber depends on the cooling state of the molten glass in addition to the shape of the nozzle hole at the tip of the nozzle.

For example, even if a nozzle having a flat nozzle hole is used to produce modified cross-section glass fibers, if the viscosity of the molten glass drawn out from the nozzle is too low, the surface tension of the molten glass directly below the tip of the nozzle will cause the molten glass to expand. The cross section of the glass fiber is likely to be rounded, making it impossible to produce the desired modified cross-section glass fiber. Moreover, even in the case of producing circular-cross-section glass fibers, it is possible to suppress breakage of the glass fibers by appropriately cooling the molten glass.

Therefore, for example, in the glass fiber manufacturing apparatus of Patent Document 1, as a cooling member for molten glass, the inner layer material is made of a material with a thermal conductivity of 100 W·m ⁻¹ ·k ⁻¹ or more, and the outermost layer material is nickel and/or It has a hollow elongated body and/or a solid elongated body made of a chromium-containing material. Such a cooling member can efficiently cool the molten glass.

Japanese Patent Application Laid-Open No. 2010-184858

In recent years, studies have been made on improving productivity and manufacturing large strands by increasing the amount of glass fiber pulled out from one bushing. Therefore, it is being considered to reduce the number of cooling members provided in the bushing and provide a nozzle in that area.

By using the cooling member described in Patent Document 1, the cooling efficiency of the molten glass drawn out from the nozzle is improved. In some cases, the molten glass drawn out from was not properly cooled.

In view of the above circumstances, an object of the present invention is to stably produce a large number of glass fibers having a desired shape.

A bushing according to the present invention includes a base plate extending in a predetermined direction and having a plurality of cooling regions in which a cooling member for cooling molten glass can be arranged; and a plurality of second nozzles provided in a second region of the base plate along the cooling region, The average distance between the cooling zone and the first zone is less than the average distance between the cooling zone and the second zone, and the average length of the first nozzles is the average length of the second nozzles. It is characterized by being shorter than it is long.

According to such a configuration, since a plurality of nozzle regions are arranged between the cooling members, more nozzles can be arranged than in the conventional art. Therefore, the productivity of the glass fiber can be improved, and a large number of glass fibers can be obtained at once, so that a large count strand can be produced.
In addition, since the second nozzle located away from the cooling region is longer than the first nozzle, it is possible to reduce variations in molten glass cooling efficiency caused by different distances from the cooling member. . Therefore, it is possible to appropriately adjust the viscosity of the molten glass during molding, and to stably mold the glass fiber.

In the present invention, the base plate further comprises a plurality of third nozzles provided in a third region along the cooling region, wherein the average distance between the cooling region and the second region is , preferably the mean distance between the cooling zone and the third zone is less than the mean length of the second nozzles is less than the mean length of the third nozzles.

According to such a configuration, variations in cooling efficiency of molten glass can be reduced even when more nozzles are arranged.

In the present invention, it is preferable that the first nozzle and the second nozzle have a flat-shaped nozzle hole at the tip from which the molten glass flows.

According to such a configuration, it is possible to easily produce irregular cross-section glass fibers with a large count.

A glass fiber manufacturing apparatus according to the present invention is characterized by comprising the bushing described above and a cooling member provided in the cooling area.

According to such a configuration, it is possible to obtain the same effect as the configuration already described.

In the present invention, the length of the cooling member from the base plate is preferably longer than that of the first nozzle and the second nozzle.

This makes it possible to efficiently cool the molten glass drawn out from the second nozzle.

A glass fiber manufacturing method according to the present invention is characterized by manufacturing glass fibers using the glass fiber manufacturing apparatus described above. According to such a configuration, it is possible to obtain the same effect as the configuration already described.

In the present invention, the molten glass is preferably E glass.

Since E-glass is a glass that is difficult to devitrify, the productivity of glass fibers is improved.

In the present invention, the molten glass preferably has a viscosity of 10 ^2.0 to 10 ^3.5 dPa·s at the molding temperature.

When the viscosity is 10 ^3.5 dPa·s or less, the viscosity of the molten glass does not become too high, so that the moldability of the glass fibers can be maintained well. Further, when the viscosity is 10 ^2.0 dPa·s or more, the viscosity of the molten glass does not become too low, so that the force of the molten glass to return to a circular cross section due to the surface surface force is reduced when producing the modified cross-section glass fiber. It is weakened, and the flatness ratio (major dimension/minor dimension) of the glass fiber can be increased.

According to the present invention, a large number of glass fibers having a desired shape can be stably produced.

FIG. 1 is a cross-sectional view showing a glass fiber manufacturing apparatus according to a first embodiment of the present invention. FIG. 2 is an enlarged cross-sectional view showing the periphery of the nozzle of the bushing of FIG. FIG. 3 is an enlarged bottom view showing the vicinity of the nozzle of the bushing of FIG. FIG. 4 is an enlarged bottom view showing the vicinity of the nozzle of the bushing of the glass fiber manufacturing apparatus according to the second embodiment of the present invention. FIG. 5 is an enlarged cross-sectional view showing the vicinity of a nozzle of a bushing of a glass fiber manufacturing apparatus according to a third embodiment of the present invention. FIG. 6 is an enlarged bottom view showing the vicinity of the nozzle of the bushing of the glass fiber manufacturing apparatus according to the third embodiment of the present invention. FIG. 7 is an enlarged cross-sectional view showing the periphery of a nozzle of a bushing of a glass fiber manufacturing apparatus according to a fourth embodiment of the present invention. FIG. 8 is an enlarged bottom view showing the vicinity of the nozzle of the bushing of the glass fiber manufacturing apparatus according to the fourth embodiment of the present invention.

A preferred embodiment will be described below. However, the following embodiments are merely examples, and the present invention is not limited to the following embodiments. Also, in each drawing, members having substantially the same function may be referred to by the same reference numerals.

(First Embodiment of Glass Fiber Manufacturing Apparatus and Manufacturing Method)
As shown in FIG. 1, a glass fiber manufacturing apparatus 10 according to the present embodiment is a manufacturing apparatus for circular cross-section glass fibers, and includes a glass melting furnace 1, a forehearth 2 connected to the glass melting furnace 1, and the forehearth 2 It has a feeder 3 connected to it. Here, in the XYZ orthogonal coordinate system shown in FIG. 1, the X direction and the Y direction are horizontal directions, and the Z direction is the vertical direction (the same applies hereinafter).

The molten glass G is supplied from the glass melting furnace 1 through the forehearth 2 to the feeder 3 and stored in the feeder 3 . Although FIG. 1 shows an example in which one glass melting furnace 1 is connected to one feeder 3 , a plurality of feeders 3 may be connected to the glass melting furnace 1 . A clarification furnace may be provided between the glass melting furnace 1 and the forehearth 2 .

In this embodiment, the molten glass G is made of E glass, but it may be made of other glass materials such as D glass, S glass, AR glass, and C glass.

A bushing 4 is arranged at the bottom of the feeder 3 . The bushing 4 is attached to the feeder 3 via a bushing block or the like. The bottom of the bushing 4 is composed of a base plate 41 as shown in FIG. 2, and the base plate 41 is provided with a plurality of nozzles 5 . Further, the base plate 41 is provided with a plurality of cooling regions S extending in the Y direction, which is one predetermined direction, in which the cooling pipes 6 can be arranged. A cooling pipe 6 is provided in the cooling area S as a cooling member.

Molten glass G stored in the feeder 3 is drawn downward from a plurality of nozzles 5 provided on the base plate 41 of the bushing 4 to produce glass fibers (monofilaments) Gm. At this time, the viscosity of the molten glass G at the molding temperature is set within the range of 10 ^2.0 to 10 ^3.5 dPa·s (preferably 10 ^2.5 to 10 ^3.3 dPa·s). The viscosity of the molten glass G at the molding temperature is the viscosity of the molten glass G at the position where it flows into the nozzle 5 . A sizing agent is applied to the surface of the glass fibers Gm by an applicator (not shown), and 100 to 10,000 fibers are spun into one strand Gs. The count of the strand Gs depends on the number of spun glass fibers Gm, and the greater the number of the glass fibers Gm, the larger the count of the strand Gs. The spun strand Gs is wound around a collet 7 of a winding device as a fiber bundle Gr. The strand Gs is cut into a predetermined length of about 1 to 20 mm, for example, and used as chopped strands.

At least part of the glass melting furnace 1, the forehearth 2, the feeder 3, the bushing 4, the nozzle 5, and the cooling pipe 6 is made of expensive material platinum or platinum alloy (for example, platinum rhodium alloy).

In order to adjust the viscosity of the molten glass G, one or more elements selected from the forehearth 2, feeder 3 and bushing 4 may be heated by electric heating or the like.

As shown in FIGS. 2 and 3, the nozzle 5 includes a nozzle wall 51 and a perfectly circular nozzle hole 52 defined by the nozzle wall. The thickness of the nozzle wall 51 is 0.1-10 mm, and the diameter of the nozzle hole 52 is in the range of 0.5-15 mm. The nozzles 5 are evenly spaced along the X and Y directions. The interval between the nozzles 5 is, for example, about 1 to 20 mm.

It is preferable that 200 to 10,000 nozzles 5 are arranged on the base plate 41 . By arranging the above number of nozzles 5, a strand Gs with a large count can be obtained. In addition, it is preferable that 1500 or more nozzles 5 are arranged on the base plate 41 .

The cooling pipe 6 exerts a cooling action by circulating cooling water F as a fluid inside it. The cooling pipe 6 is a plate-like body, and a plurality of cooling pipes 6 are arranged so that the plate surface extends along a certain direction (Y direction). Although the cooling pipe 6 is provided separately from the cooling area S of the base plate 41 in this embodiment, it may be provided integrally with the bottom of the bushing 4 . Moreover, the cooling pipe 6 may be a circular tubular body. The height position of the cooling pipe 6 can be appropriately adjusted according to the cooling conditions of the molten glass G. For example, the cooling pipe 6 may be arranged above the tip of the nozzle 5 so as not to directly face the molten glass G drawn from the nozzle 5, or may be arranged above the nozzle 5 and the molten glass G drawn from the nozzle 5. may be arranged so as to straddle both sides. The cooling member is not limited to the cooling pipe 6, and may be a cooling fin or the like that induces an air flow and exerts a cooling effect.

The base plate 41 has a plurality of cooling areas S extending in the Y direction in which the cooling pipes 6 are arranged. A plurality of cooling regions S are arranged at predetermined intervals in the X direction. The cooling area S is in a flat state so that the cooling pipes 6 can be arranged. A plurality of nozzles 5 are arranged between the cooling regions S.

Between the cooling areas S, there are a first area L1 and a second area L2 from the side closer to the cooling area S. The first area L1 and the second area L2 are provided with the same number of nozzles 5 (first nozzles 5a in the first area L1 and second nozzles 5b in the second area L2). . The first nozzle 5a is composed of a nozzle wall 51a, and the second nozzle 5b is composed of a nozzle wall 51b. The length H1 of the first nozzle 5a is shorter than the length H2 of the second nozzle 5b.

The molten glass G drawn from the first nozzle 5a near the cooling pipe 6 is easily cooled by the cooling pipe 6. On the other hand, the molten glass G pulled out from the second nozzle 5 b located far from the cooling pipe 6 is difficult to be cooled by the cooling pipe 6 . As a result of extensive studies, the inventors of the present invention have found that cooling variations can be suppressed by previously lowering the temperature of the molten glass G drawn out from the second nozzle 5b. As a result of further studies, the inventors of the present invention found that the longer the time for the molten glass G to flow through the nozzle 5, the lower the temperature of the molten glass G. Therefore, by setting the relationship of the lengths of the nozzles 5 as described above, the variation in cooling efficiency can be reduced.

Therefore, it becomes unnecessary to arrange the cooling pipes 6 next to all the nozzles 5 , and as a result, it becomes possible to arrange more nozzles 5 on the base plate 41 .

By setting the ratio (H2/H1) of the length H1 of the first nozzle 5a to the length H2 of the second nozzle 5b to 1.1 to 2.0, the nozzle 5 can be cooled while reducing variations in cooling. manufacturing cost (amount of platinum used) can be reduced.

Also, the length H3 of the cooling pipe 6 from the base plate 41 is longer than the length H1 of the first nozzle 5a and the length H2 of the second nozzle 5b. By doing so, the molten glass G drawn out from the first nozzle 5 a and the second nozzle 5 b can be efficiently cooled by the cooling pipe 6 .

(Second Embodiment of Glass Fiber Manufacturing Apparatus and Manufacturing Method)
Regarding the glass fiber manufacturing apparatus according to the second embodiment, only differences from the glass fiber manufacturing apparatus 10 according to the first embodiment will be described.

As shown in FIG. 4, the nozzles 5 are arranged on the base plate 42 of the bushing 14 in an arrangement different from that of the base plate 41 of the first embodiment. The nozzles 5 are arranged in a zigzag pattern. By arranging in this way, the second nozzles 5b arranged in the second region L2 are cooled more efficiently by the cooling pipes 6. As shown in FIG. In the case of the first embodiment, the cooling efficiency of the second nozzle 5b may slightly decrease due to the blockage by the first nozzle 5a. In contrast, in the case of the present embodiment, the second nozzle 5b is not blocked by the first nozzle 5a, so it is cooled more efficiently.

(Third Embodiment of Glass Fiber Manufacturing Apparatus and Manufacturing Method)
Only differences of the glass fiber manufacturing apparatus according to the third embodiment from the glass fiber manufacturing apparatus 10 according to the first embodiment will be described.

As shown in FIG. 6, the nozzles 5 are arranged on the base plate 43 of the bushing 24 in an arrangement different from that of the base plate 41 of the first embodiment. Between the cooling regions S, there are a first region L1, a second region L2 and a third region L3 from the side closer to the cooling region S. As shown in FIG. The first area L1, the second area L2 and the third area L3 have the same number of nozzles 5 (the first area L1 has the first nozzles 5a and the second area L2 has the second nozzles 5b). , the third region L3 is provided with a third nozzle 5c). The first nozzle 5a is composed of a nozzle wall 51a, the second nozzle 5b is composed of a nozzle wall 51b, and the third nozzle 5c is composed of a nozzle wall 51c. As shown in FIG. 5, the length H1 of the first nozzle 5a is shorter than the length H2 of the second nozzle 5b, and the length H2 of the second nozzle 5b is greater than the length H4 of the third nozzle 5c. shorter than

In this way, by increasing the length of the nozzle 5 as the distance from the cooling region S increases, the variation in cooling of the molten glass G drawn from the nozzle 5 can be reduced.

The length H3 of the cooling pipe 6 from the base plate 43 is longer than the length H1 of the first nozzle 5a, the length H2 of the second nozzle 5b, and the length H4 of the third nozzle 5c. . By doing so, the molten glass G drawn out from the first nozzle 5a, the second nozzle 5b and the third nozzle 5c can be efficiently cooled by the cooling pipes 6. FIG.

(Fourth Embodiment of Glass Fiber Manufacturing Apparatus and Manufacturing Method)
Regarding the glass fiber manufacturing apparatus according to the fourth embodiment, only points different from the glass fiber manufacturing apparatus 10 according to the first embodiment will be described.

As shown in FIGS. 7 and 8, in the base plate 44 of the bushing 34, a plurality of nozzle regions L4 and L5 are arranged in parallel and spaced apart in the X direction between the adjacent cooling regions S. The nozzle 5 has a flat-shaped (oval in this embodiment) nozzle hole 53 at the tip from which the molten glass flows. In this embodiment, the major axis direction of the nozzle hole 53 coincides with the Y direction, and the minor axis direction of the nozzle hole 53 coincides with the X direction. Moreover, the cross-sectional shape of the nozzle hole 53 may be an elliptical shape other than an oval shape.

Between the cooling areas S, there are a first area L4 and a second area L5 from the side closer to the cooling area S. The first area L4 and the second area L5 are provided with the same number of nozzles 5 (first nozzles 5d in the first area L4 and second nozzles 5e in the second area L5). . The first nozzle 5d is composed of a nozzle wall 51d, and the second nozzle 5e is composed of a nozzle wall 51e. The length H5 of the first nozzle 5d is shorter than the length H6 of the second nozzle 5e.

A bushing 34 having a flat-shaped (elliptical in this embodiment) nozzle hole 53 is used for manufacturing modified cross-section glass fibers. Even when the molten glass G is pulled out from the nozzle hole 53 having such a shape, the cross section of the glass fiber tends to become a perfect circle due to the surface tension. Therefore, conventionally, it was necessary to increase the number of cooling members 6 . Therefore, by setting the length relationship of the nozzles 5 as described above, the second nozzles 5e in the second region L5 can also be efficiently cooled, so the number of cooling members 6 can be reduced.

By setting the ratio (H6/H5) of the length H5 of the first nozzle 5d to the length H6 of the second nozzle 5e to 1.1 to 2.0, the nozzle 5 can be cooled while reducing variations in cooling. manufacturing cost (amount of platinum used) can be reduced.

Also, the length H7 of the cooling pipe 6 from the base plate 44 is longer than the length H5 of the first nozzle 5d and the length H6 of the second nozzle 5e. By doing so, the molten glass G drawn out from the first nozzle 5 d and the second nozzle 5 e can be efficiently cooled by the cooling pipe 6 .

The number of nozzles 5 included in the first area L4 and the second area L5 is preferably 10 to 100 or less. Also, the total number of nozzles 5 arranged on the base plate 44 is preferably 400 to 4000 or less.

According to the present embodiment for producing glass fibers as described above, the following effects can be obtained.

In this embodiment, the base plate extends in a predetermined direction and has a plurality of cooling regions in which cooling members for cooling molten glass can be arranged, and the base plate is provided in a first region along the cooling regions. and a plurality of second nozzles provided in a second region that is a region along the cooling region in the base plate, the average distance between the cooling region and the first region is less than the average distance between the cooling zone and the second zone, and the average length of the first nozzles is smaller than the average length of the second nozzles. By setting the length relationship between the first nozzle and the second nozzle as described above, a large number of glass fibers having a desired shape can be stably produced.

Although the glass fiber manufacturing method according to the embodiment of the present invention has been described above, the present invention is not limited to this, and various variations are possible without departing from the spirit of the present invention.

1: glass melting furnace,
4, 14, 24, 34: Bushing 41, 42, 43, 44: Base plate 5: Nozzle 51: Nozzle wall 52, 53: Nozzle hole 6: Cooling pipe 10: Glass fiber manufacturing device S: Cooling area,
L1, L4: first area L2, L5: second area L3: third area

Claims (8)

1. a base plate extending in a predetermined direction and having a plurality of cooling regions in which cooling members for cooling molten glass can be arranged;
   a plurality of first nozzles provided in a first region along the cooling region in the base plate;
   a plurality of second nozzles provided in a second region along the cooling region of the base plate,
   the average distance between the cooling zone and the first zone is less than the average distance between the cooling zone and the second zone;
   A bushing in which the average length of the first nozzles is less than the average length of the second nozzles.
2. further comprising a plurality of third nozzles provided in a third region along the cooling region of the base plate;
   the average distance between the cooling zone and the second zone is shorter than the average distance between the cooling zone and the third zone;
   2. The bushing of claim 1, wherein the average length of said second nozzles is less than the average length of said third nozzles.
3. The bushing according to claim 1 or 2, wherein the first nozzle and the second nozzle each have a flat nozzle hole at the tip from which the molten glass flows.
4. A bushing according to any one of claims 1 to 3;
   and a cooling member provided in the cooling area.
5. The glass fiber manufacturing apparatus according to claim 4, wherein the length of the cooling member from the base plate is longer than the length of the first nozzle and the second nozzle.
6. A glass fiber manufacturing method for manufacturing glass fibers using the glass fiber manufacturing apparatus according to claim 4 or 5.
7. The method for producing glass fiber according to claim 6, wherein the molten glass is E glass.
8. 8. The method for producing glass fiber according to claim 6, wherein the molten glass has a viscosity of 10 ^2.0 to 10 ^3.5 dPa·s at the molding temperature.

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