JPH10119138A - Production of filament wounding pressure vessel - Google Patents

Abstract

PROBLEM TO BE SOLVED: To realize a producing method of a pressure vessel with a minimum volume of fibers. SOLUTION: A pressure vessel is prepared by first implementing a circumferential winding around a cylindrical portion 3 as a central portion of the pressure vessel, next implementing a combination winding comprising a helical winding 5 at a fiber angle of αdeg. around a first dome portion 1a as an end portion, an in-plane winding around the cylindrical portion 3, and a helical winding 7 at a fiber angle of β deg. around a second dome portion 1b as the other end portion, next implementing a helical winding 8 at the fiber angle of α deg. around the first dome portion 1a, the cylindrical portion 3 and a part of the second dome portion 1b, and lastly implementing a circumferential winding around the cylindrical portion 3.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for manufacturing a pressure vessel made of filament winding which is applied to a product such as a rocket motor case where weight reduction is important.

[0002]

2. Description of the Related Art Filament winding (hereinafter referred to as F)
W) is applied to the production of hollow containers, pipes, and the like. A continuous fiber impregnated with a resin is wound around a mandrel (mold material), and after the resin is cured, the mandrel is removed and the hollow container or pipe is removed. This is a method for manufacturing pipes and the like, and a lightweight and high-strength product can be obtained by this method.

According to this method, a container having an arbitrary convex shape can be manufactured, and the winding angle of the fiber (hereinafter, referred to as the fiber winding angle) can be obtained.
By changing the fiber angle, there is an advantage that the strength of the obtained product can be adjusted. As shown in FIG. 3, there are three general winding methods of the fiber in the FW: helical (spiral) winding, in-plane (planar) winding, and circumferential winding.

The helical winding is a normal winding method used for manufacturing a pipe, and winds a fiber coming out of a yarn reciprocating in parallel with a central axis of a rotating mandrel 10 as shown in FIG. It is. The fiber shows a spiral trajectory in the cylindrical portion 3, and is wound in contact with the base portions 2a, 2b by the domes 1a, 1b at both ends.

[0005] The in-plane winding is a winding method suitable for manufacturing a container having a relatively short length such as a sphere, and the center axis of the mandrel 10 is rotated at a very low speed, and FIG.
As shown in the figure, the base portions 2a of the dome portions 1a, 1b at both ends,
The fiber is wound around the mandrel 10 in a plane inclined with respect to the central axis of the container so as to contact the container 2b.

[0006] Circumferential winding is the same as helical winding as shown in Fig. 1 (c), but can be realized by extremely reducing the reciprocating speed of the yarn end in the mandrel axis direction.

In the conventional production of a cylindrical pressure vessel with a dome having openings of different diameters (joining portions of ferrules) at both ends, helical winding and in-plane winding have been used. In the helical winding, the fiber tension becomes constant if the dome shape is formed as an equal tension curved surface, and the dome portion can theoretically be manufactured with a minimum number of fibers for a predetermined internal pressure.

However, this is limited to the case where the diameters of the openings of the dome portions at both ends are the same, and the fiber angle of the cylindrical portion is not generally the ideal fiber angle with respect to the internal pressure. In many cases, reinforcement was applied.

On the other hand, in-plane winding can be applied to the case where the diameters of the openings at both ends are different, and are generally used. However, the fiber tension of the dome cannot be made uniform.
In addition, since the strength of the cylindrical portion in the circumferential direction is generally insufficient, it is necessary to add a circumferential winding.

[0010]

In the manufacture of a conventional pressure vessel made of filament winding, since the diameter of the openings at both ends of the pressure vessel is different, the pressure vessel is generally manufactured by in-plane winding as described above. For example, there is a problem that the total weight of the pressure vessel increases.

(1) Since the fiber tension at the dome portion is not constant, the fiber amount becomes excessive as compared with the ideal state.

(2) Since the intersection angle of the fibers in the vicinity of the cylindrical portion of the dome portion is small, in order to be able to counter the circumferential stress due to the internal pressure, the fibers against the axial stress become excessive.

(3) The cylindrical portion also needs a circumferential reinforcing winding with a large amount of fibers for the same reason. The present invention seeks to solve the above problems.

[0014]

Means for Solving the Problems A method of manufacturing a filament winding made pressure container according to the first aspect of the present invention, the cylindrical portion of diameter a is in the center, the first having a large diameter base part of the diameter d ₁ In a pressure vessel formed by providing a dome portion at one end and a second dome portion having a small-diameter ferrule portion with a diameter d _{2 at} the other end, first, a cylindrical portion is circumferentially wound. Fiber angle α for 1 dome
⁰ (α ⁰ = sin ⁻¹ d ₁ / a), helical winding of the cylindrical portion, in-plane winding, and helical winding of the second dome portion at a fiber angle β ⁰ (β ⁰ = sin ⁻¹ d ₂ / a). After performing the combination winding, the fiber angle α ⁰ from the equatorial plane of the first dome portion, the cylindrical portion, and the second dome portion to the position having the same diameter as the diameter of the opening of the first dome portion.
Helical winding, and finally, the cylindrical portion is circumferentially wound to produce a pressure vessel.

In the above, first, the circumferential winding is performed on the cylindrical portion. Therefore, it is possible to prevent the slippage of the fibers in the in-plane winding performed on the cylindrical portion in the subsequent combination winding.

In the combination winding performed on the circumferential winding, the optimum fiber angles α ⁰ and β ⁰ are obtained for each dome portion.
Helical winding can be performed, so that an equal tension curved surface with a constant fiber tension can be formed, and the in-plane winding is performed on the cylindrical portion, so that the fiber angle is changed from α ⁰ to β ^0.
Can be changed gradually.

[0017] In these combinations winding, since the first dome portion than the second dome portion is insufficient amount of fibers, the fibers angle on the combined helical winding of alpha ⁰ is applied, the The shortage of the fiber amount in the first dome portion can be compensated.

On the helical winding having the fiber angle α ^0, a circumferential winding is performed on the cylindrical portion. Therefore, it is possible to prevent the fiber from slipping in the transition region from the in-plane winding to the helical winding. Insufficient strength in the circumferential direction can be compensated.

As described above, since the respective dome portions and cylindrical portions can be formed with the minimum amount of fiber used, the winding time can be reduced, the weight can be reduced, the economy can be improved, and the construction period can be shortened. A possible pressure vessel manufacturing method is realized.

[0020]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A method for manufacturing a filament wound pressure vessel according to one embodiment of the present invention will be described with reference to FIGS.

In the method of manufacturing the pressure vessel according to the present embodiment shown in FIGS. 1 and 2, first, the cylindrical portion 3 is subjected to cylindrical winding so that no slip occurs when winding the upper layer fiber.

Next, as shown in FIG. 2 (a), the helical winding 5 having a fiber angle α ⁰ from the opening, which is the joint with the base 2a, to the equatorial plane 4a is formed on the large-diameter side dome 1a. The fiber angle of the large diameter side of the cylindrical portion 3 is α.
^The in-plane winding 6 is performed so that the fiber diameter becomes β ⁰ on the small diameter side, and the helical angle β ⁰ is formed from the opening, which is the junction with the base 2 b, to the equatorial plane 4 b for the small diameter side dome part 1 b. A combination winding for winding 7 is performed.

Next, as shown in FIG. 2B, the small-diameter dome portion 1b having the same diameter as the diameter of the large-diameter side dome portion 1a passes through the cylindrical portion 3 from the opening of the large-diameter side dome portion 1a.
The helical winding of the fiber angle α ⁰ is performed up to the position 11 of the diameter of, and finally, the cylindrical portion 3 is circumferentially wound.

In the above description, the fiber angles α ⁰ and β ⁰ of the helical windings 5 and 7 in the combination winding are obtained by setting the diameter of the joint between the dome portions 1a and 1b and the base portions 2a and 2b to d.
₁ , d ₂ and the diameter of the cylindrical portion 3 is a.

Α ⁰ = sin ⁻¹ (d ₁ / a) β ⁰ = sin ⁻¹ (d ₂ / a) α ⁰ and β ⁰ obtained from the above equation are optimal fiber angles.
A constant tension curved surface with a constant fiber tension can be formed for each of the domes 1a and 1b forming the pressure vessel.

Since the cylindrical portion 3 provided between the dome portions 1a and 1b is formed by the in-plane winding 6, the fiber angle can be gradually changed from α ⁰ to β ⁰ .

In the case of the above-mentioned combination winding, since α ⁰ is larger than β ^{0 in} the large-diameter dome portion 1a, the fiber amount is insufficient compared with the small-diameter dome portion 1b. Therefore, a helical winding 8 having a fiber angle α ⁰ is further added on the combination winding.
To compensate for the shortage of fiber.

The cylindrical portion 3 on which the helical winding 8 having the fiber angle α ⁰ is applied is provided with a cylindrical winding, whereby the fiber in the transition region from the in-plane winding 6 to the helical winding 8 is formed. It prevents slippage and compensates for insufficient strength in the circumferential direction.

As described above, it is possible to form the respective dome portions and the cylindrical portions with the minimum amount of fiber used, to reduce the amount of expensive fiber used, shorten the winding time, reduce the weight and reduce the economical efficiency. A pressure vessel manufacturing method that can be improved has been realized.

[0030]

According to the method for manufacturing a pressure container made of filament winding of the present invention, first, a cylindrical portion which is a central portion of the pressure container is circumferentially wound, and then a first dome portion which is one end portion is formed. The helical winding of the fiber angle α ^0, the in-plane winding of the cylindrical portion, and the combination winding of the second dome portion at the other end portion performing the helical winding of the fiber angle β ⁰ , and then the first dome portion and the cylindrical portion Helical winding with a fiber angle α ⁰ for the part and a part of the second dome part, and finally, for the cylindrical part, the dome part and the second dome part are circumferentially wound to produce a pressure vessel. The pressure vessel can be formed with the minimum amount of fiber, which reduces the winding time, and reduces the weight, improves economy and shortens the construction period. To achieve.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram of a filament winding procedure in a manufacturing method according to an embodiment of the present invention.

FIG. 2 is an explanatory diagram of a manufacturing method according to the embodiment,
(A) is an explanatory diagram of a combination winding, and (b) is an explanatory diagram of a helical winding (α ⁰ ).

FIG. 3 is an explanatory view of filament winding;
(A) is a helical winding, (b) is an in-plane winding,
(C) is an explanatory view of a circumferential winding.

[Description of Signs] 1a, 1b Dome 2a, 2b Cap 3 Cylindrical 4a, 4b Equatorial plane 5 Helical winding (α ⁰ ) 6 In-plane winding 7 Helical winding (β ⁰ ) 8 Helical winding (α ⁰ )

 ────────────────────────────────────────────────── ─── Continuing from the front page (72) Inventor Shigehiro Takeda 1-1-1 Wadazakicho, Hyogo-ku, Kobe-shi, Kobe Shipyard

Claims (1)

[Claims] 1. A cylindrical portion having a diameter a at the center, a first dome portion having a large-diameter ferrule portion having a diameter d ₁ at one end, and a diameter d _{2 at} one end.
In the pressure vessel formed by providing the second dome portion having the small-diameter base portion at the other end, first, the cylindrical portion is circumferentially wound, and then, the fiber angle α ⁰ is provided for the first dome portion. (Α ⁰ = sin ⁻¹ d ₁ / a) helical winding,
The cylindrical portion is subjected to in-plane winding, and the second dome portion is subjected to combination winding in which helical winding is performed at a fiber angle β ⁰ (β ⁰ = sin ⁻¹ d ₂ / a), and then the first dome portion and the cylindrical portion And helical winding at a fiber angle α ⁰ from the equatorial plane of the second dome portion to a position having the same diameter as the diameter of the opening of the first dome portion, and finally, circumferentially winding the cylindrical portion to obtain pressure. A method for producing a pressure container made of filament winding, which comprises producing a container.