JP6581739B1 - Mandrel - Google Patents

Abstract

An object of the present invention is to provide a mandrel capable of manufacturing a tube used for a power transmission shaft having a central portion swelled radially outward from both ends. The present invention is a mandrel 1 made of a fiber reinforced plastic and used for manufacturing a tubular body 102 used for a power transmission shaft 101, comprising a body portion around which continuous fibers impregnated with a resin are wound, The body portion 2 is formed of a material that expands by heating, and the body portion 2 has a larger expansion amount at the time of heating at the center than at both end portions 4a, 5 and 6. [Selection] Figure 3

Description

  The present invention relates to a mandrel used for manufacturing a tubular body used for a power transmission shaft.

A power transmission shaft (propeller shaft) mounted on a vehicle includes a tubular body extending in the front-rear direction of the vehicle. The tubular body transmits power generated by a prime mover and decelerated by a transmission to a final reduction device. Yes.
As a tube used for such a power transmission shaft, there is one formed of fiber reinforced plastic. As a method for manufacturing a tubular body made of fiber reinforced plastic and used for a power transmission shaft, for example, continuous fibers impregnated with a thermosetting resin are wound around a mandrel several times to form a tubular molded body. Thereafter, the molded body is heated to cure the resin, thereby forming a tubular tube. Thereafter, the mandrel is pulled out from the opening at the end of the cured tube, and the manufacturing process is completed (see Patent Document 1 below).

Japanese Patent Laid-Open No. 3-265738

By the way, regarding the shape of the tubular body, in recent years, it has been studied to form a so-called barrel shape (barrel shape) in which the central portion swells radially outward than both ends.
However, when trying to form a tubular body having the above shape using a barrel-shaped mandrel, the central portion of the mandrel swells outward, cannot pass through the opening of the tubular body, and the mandrel cannot be pulled out from the tubular body.

  The present invention was created in order to solve such a problem, and provides a mandrel capable of manufacturing a tubular body used for a power transmission shaft having a central portion swelled radially outward from both end portions. Objective.

  In order to solve the above-mentioned problems, a mandrel according to the present invention is a mandrel made of fiber-reinforced plastic and used for manufacturing a tubular body used for a power transmission shaft, and a body around which continuous fibers impregnated with a resin are wound. The body is formed of a material that expands by heating, and the body has a larger expansion amount at the time of heating at the center than at both ends.

  According to the present invention, since the barrel portion is formed into a so-called barrel shape (barrel shape) by heating, it is possible to manufacture a tubular body in which the central portion swells radially outward from both end portions. Moreover, since the center part of a trunk | drum is diameter-reduced by cooling, a mandrel can be extracted from a pipe body.

It is the side view which looked at the power transmission shaft side. It is sectional drawing which cut the main-body part of the tubular body in the axial direction. It is a side view of the mandrel of 1st embodiment, and is a side view of the state with which the rotation apparatus was specifically mounted | worn by the winding process. It is a flowchart which shows the manufacturing process of the tubular body used for the power transmission shaft which concerns on 1st embodiment. It is a manufacturing method using the mandrel of 1st embodiment, Comprising: It is a side view which shows the state at the time of completion | finish of a winding process. It is a manufacturing method using the mandrel of 1st embodiment, Comprising: It is a side view which shows the state at the time of a heating process. It is a manufacturing method using the mandrel of 1st embodiment, Comprising: It is a side view which shows the state at the time of a cooling process. It is a manufacturing method using the mandrel of 1st embodiment, Comprising: It is a side view which shows the state at the time of a decentering process. It is a side view of the mandrel of 2nd embodiment. It is a side view of the mandrel of 3rd embodiment. It is a manufacturing method using the mandrel of 3rd embodiment, Comprising: It is a side view which shows the state at the time of a heating process.

  Next, the mandrel of each embodiment will be described with reference to the drawings. Technical elements common to the embodiments are denoted by common reference numerals, and description thereof is omitted. First, a power transmission shaft manufactured by a mandrel will be described.

[Power transmission shaft]
As shown in FIG. 1, a power transmission shaft 101 is a propeller shaft mounted on a four-wheel drive vehicle based on FF (Front-engine Front-drive).
The power transmission shaft 101 includes a substantially cylindrical tubular body 102 extending in the longitudinal direction of the vehicle, a stub yoke 103 of a cardan joint joined to the front end of the tubular body 102, and a constant velocity joint joined to the rear end of the tubular body 102. The stub shaft 104 is provided.
The stub yoke 103 is a connecting member that connects the transmission mounted on the front portion of the vehicle body and the tube body 102. The stub shaft 104 is a connecting member that connects the final reduction gear mounted on the rear portion of the vehicle body and the tube body 102.
When power (torque) is transmitted from the transmission, the power transmission shaft 101 rotates around the axis O1 and transmits the power to the final reduction gear.

The tube 102 is made of carbon fiber reinforced plastic (CFRP). In addition, the fiber used for fiber reinforced plastics in this invention is not restricted to carbon fiber, A glass fiber and an aramid fiber may be sufficient.
The tube body 102 includes a main body portion 110 that occupies most of the tube body 102, a first connection portion 120 disposed on the front side of the main body portion 110, and a second connection portion 130 disposed on the rear side of the main body portion 110. And an inclined portion 140 positioned between the main body portion 110 and the second connection portion 130.

In FIG. 2 and subsequent drawings, the shape of the tube body 102 is exaggerated for easy understanding of the shape of the tube body 102.
As shown in FIG. 2, the first connection part 120 is continuous with the front end part (other end part) 111 of the main body part 110, and the inclined part 140 is provided at the rear end part (one end part) 112 of the main body part 110. It is continuous.

  When the main body 110 is cut along a plane whose normal is the axis O1, the cross-sectional shape of the outer peripheral surface 114 and the cross-sectional shape of the inner peripheral surface 115 of the main body 110 are circular. The outer diameter of the main body 110 is reduced from the central portion 113 toward both end portions (the front end portion 111 and the rear end portion 112). The outer diameter R1 of the central portion 113 is equal to both end portions (the front end portion 111). And the rear end 112) is larger than the outer diameter R2. The inner diameter of the main body 110 is also reduced from the central portion 113 of the main body 110 toward both ends (the front end 111 and the rear end 112).

  When the main body part 110 is cut along the axis O1, the cross-sectional shape of the outer peripheral surface 114 and the cross-sectional shape of the inner peripheral surface 115 of the main body part 110 draw a gentle curve, and the central part 113 protrudes outward. It is arcuate. Therefore, the outer shape of the main body 110 has a barrel shape (barrel shape) in which the central portion 113 swells radially outward. Further, in the cross-sectional shape, the plate thickness of the main body portion 110 becomes thinner from both end portions (the front end portion 111 and the rear end portion 112) toward the center portion 113, and the plate thickness T1 of the center portion 113 is It is thinner than the plate thickness T2 of both end portions (front end portion 111 and rear end portion 112).

As shown in FIG. 1, the shaft portion 103 a of the stub yoke 103 is fitted in the first connection portion 120. The outer peripheral surface of the shaft portion 103a is formed in a polygonal shape. The inner peripheral surface of the first connection portion 120 is formed in a polygonal shape that follows the outer peripheral surface of the shaft portion 103a. Therefore, the stub yoke 103 and the tube body 102 are configured not to rotate relative to each other.
In the second connection portion 130, the shaft portion 104a of the stub shaft 104 is fitted. The outer peripheral surface of the shaft portion 104a is formed in a polygonal shape. The inner peripheral surface of the second connection portion 130 is formed in a polygonal shape following the outer peripheral surface of the shaft portion 104a. Therefore, the stub shaft 104 and the tube body 102 are configured not to rotate relative to each other.

The outer diameter of the inclined portion 140 is gradually reduced from the main body portion 110 toward the first connection portion 120 and has a truncated cone shape. The thickness of the inclined portion 140 gradually decreases from the end on the second connection portion 130 side (rear side) toward the end on the main body 110 side (front side). For this reason, the plate | board thickness of the front-end part is the thinnest among the inclination parts 140, and comprises the weak part.
From the above, when the vehicle is collided from the front and a collision load is input to the power transmission shaft 101, a shearing force acts on the inclined portion 140 inclined with respect to the axis O1. And when the shear force which acts on the inclination part 140 exceeds a predetermined value, the front-end part (fragile part) of the inclination part 140 will be damaged. For this reason, at the time of a vehicle collision, the engine and transmission mounted on the front part of the vehicle body are quickly retracted, and the collision energy is absorbed by the front part of the vehicle body.

  According to the tube body 102 described above, the central portion 113 of the main body portion 110 where bending stress tends to concentrate is formed with a large outer diameter R1 and has a predetermined bending strength. On the other hand, both ends (the front end 111 and the rear end 112) of the main body 110 where the bending stress is difficult to concentrate are formed with a small outer diameter R2 and are lightened. Further, the central portion 113 of the main body 110 has a thin plate thickness T1 and is lightweight. Therefore, the tubular body 102 is lightened in the main body 110 while ensuring the predetermined bending rigidity of the central portion 113, and the primary bending resonance point of the main body 110 is improved.

[First embodiment]
As shown in FIG. 3, the mandrel 1 of the first embodiment includes a substantially cylindrical body portion 2 and a pair of shaft portions 3 that protrude from both ends of the body portion 2.
In addition, a pair of axial part 3 is the structure for hooking on another apparatus and making the trunk | drum 2 float. Therefore, the present invention may be configured only from the body portion 2.
The trunk | drum 2 is a core material for winding the continuous carbon fiber which impregnated resin, or the prepreg (sheet which impregnated resin to carbon fiber).
The body 2 is a columnar column 4, a diameter-reduced portion 5 that gradually decreases in diameter as it is separated from the one end 4 c of the column 4, and is located on one end side of the diameter-reduced portion 5. And a small-diameter portion 6 having a small diameter.

The other end 4 a of the cylindrical part 4 is a part that forms the first connection part 120. A region from the central part 4 b to the one end part 4 c in the cylindrical part 4 is a part that forms the main body part 110. The outer diameter of the cylindrical portion 4 is r1, and is the same diameter from one end side to the other end side. The outer diameter r1 of the cylindrical portion 4 is the maximum outer diameter of the body portion 2.
Further, the reduced diameter portion 5 is a portion where the inclined portion 140 is formed, and the small diameter portion 6 is a portion where the second connection portion 130 is formed.

The trunk | drum 2 is formed with a metal material, and expand | swells by heating (refer the dashed-two dotted line M of FIG. 3). Therefore, the outer diameter of the trunk portion 2 is formed smaller than the inner diameter of the tube body 102.
The trunk | drum 2 is provided with the site | part formed with the 1st metal material 7, and the site | part formed with the 2nd metal material 8 with a larger thermal expansion coefficient than the 1st metal material 7. FIG.
Each of the other end portion 4 a, the reduced diameter portion 5, and the small diameter portion 6 of the cylindrical portion 4 is formed of a first metal material 7. On the other hand, the outer peripheral part of the area | region from the center part 4b in the cylindrical part 4 to the one end part 4c is formed with the 2nd metal material 8. FIG. Hereinafter, the part formed with the second metal material 8 is referred to as an inflating part 9.
Therefore, as for the trunk | drum 2, the center part (expansion part 9) expand | swells at the time of a heating rather than one end part (the reduced diameter part 5 and the small diameter part 6) and the other end part (the other end part 4a of the cylindrical part 4). The amount is large (see the two-dot chain line M in FIG. 3).

The inner peripheral surface 9a of the inflating part 9 protrudes radially inward toward the central part in the direction of the axis O2. Further, the cross-sectional shape when the inner peripheral surface 9a of the inflating portion 9 is cut along the axis O2 is a gentle curve, and the central portion is an arc shape protruding inward. That is, the cross-sectional shape of the inflating part 9 is an arcuate shape.
For this reason, when the expansion part 9 is heated, the outer peripheral surface 9b of the expansion part 9 protrudes outward in the radial direction at the center part rather than both end parts in the direction of the axis O2. Moreover, the cross-sectional shape of the outer peripheral surface 9b at the time of expansion becomes a circular arc shape in which a gentle curve is drawn and the central portion protrudes outward (see a two-dot chain line M in FIG. 3).

Next, the manufacturing method of the tubular body 102 using the mandrel 1 of the first embodiment will be described. In the present embodiment, a case where a thermosetting resin is used as the resin forming the tubular body 102 will be described as an example.
As shown in FIG. 4, the manufacturing method of the tubular body 102 includes a winding step (step S <b> 1) for winding the material around the mandrel 1, a heating step (step S <b> 2) for heating the material and the mandrel 1, and cooling for cooling the mandrel 1. A step (step S3), and a decentering step (step S4) for pulling out the mandrel 1 from the tubular body 102.

  As shown in FIG. 3, in the winding step (step S <b> 1), the mandrel 1 is mounted on the rotating device 10 and a release agent is applied to the outer peripheral surface of the mandrel 1. Then, the rotating device 10 is driven to rotate the mandrel 1, and the intermediate product 11 (see FIG. 5) is formed by winding the material forming the tubular body 102 around the outer periphery of the mandrel 1.

The rotating device 10 is a device that includes a drive source (not shown) that detachably supports the pair of shaft portions 3 and transmits power to the shaft portions 3 to rotate the mandrel 1 about the axis O2.
Examples of the material forming the tube 102 include continuous carbon fibers or prepregs impregnated with a resin (sheets obtained by impregnating carbon fibers with a resin). That is, the mandrel 1 can be used for the filament winding method or the sheet winding method.

In the winding method of this embodiment, the continuous carbon fiber impregnated with resin is rotated around the mandrel 1 by rotating the mandrel 1 to form a first molded body. Next, the mandrel 1 is continuously rotated to wind the prepreg around the outer periphery of the first molded body. Therefore, the tubular body 102 is manufactured by incorporating two methods, a filament winding method and a sheet winding method.
Here, the first molded body produced by the filament winding method has high mechanical strength (particularly torsional strength) because the continuity of the fibers (carbon fibers) is maintained.
On the other hand, according to the sheet winding method, the carbon fibers can be disposed so as to extend in the axial direction of the mandrel, and a second molded body having high elasticity in the axial O1 direction can be manufactured.
That is, according to the above-described manufacturing method, the fiber layer made of fibers wound around the axis O1 and the fiber layer made of fibers extending in the direction of the axis O1 are laminated inside the tube body 102. Therefore, the tubular body 2 having high mechanical strength and high elasticity in the direction of the axis O1 can be manufactured.
In addition, a PAN (Polyacrylonitrile) fiber is preferable as the fiber oriented in the circumferential direction, and a pitch fiber is preferable as the fiber oriented in the axis O1 direction.

At the end of the winding step (step S1), as shown in FIG. 5, a cylindrical intermediate product 11 along the outer peripheral shape of the mandrel 1 is formed on the outer peripheral side of the mandrel 1.
The intermediate product 11 includes an intermediate first connecting portion 12 formed at the other end 4 a of the cylindrical portion 4, an intermediate main body portion 13 formed at the expanding portion 9, and an intermediate inclined portion formed at the reduced diameter portion 5. 14 and an intermediate second connecting portion 15 formed in the small diameter portion 6.
In the winding step (step S1), the radial thickness W1 of the intermediate product 11 is formed so as to be uniform in each part of the cylindrical portion 4, the reduced diameter portion 5, and the small diameter portion 6. Further, when the prepreg is wound around the mandrel 1, the prepreg may be wound while being pressed against the mandrel 1 with a roller.

As shown in FIG. 6, in the heating step (step S <b> 2), the mandrel 1 and the intermediate product 11 are heated at a predetermined temperature by a heating device to cure the resin, thereby molding the resin.
The predetermined temperature varies depending on the thermosetting resin to be used, and is approximately 130 ° to 180 °.
In the present embodiment, an oven 20 is used as a heating device. The mandrel 1 and the intermediate product 11 are carried into the oven 20 and baked at a predetermined temperature.

  According to the said process, the mandrel 1 is heated in the process in which resin of the intermediate product 11 hardens | cures. For this reason, the other end 4a of the cylindrical portion 4 formed of the first metal material 7 swells slightly outward in the radial direction, and the outer diameter becomes r2. Similarly, the reduced diameter portion 5 and the small diameter portion 6 also swell slightly outward in the radial direction. Therefore, in the process, the intermediate first connecting portion 12, the intermediate inclined portion 14, and the intermediate second connecting portion 15 of the intermediate product 11 are slightly expanded in diameter while the resin is cured, and the power transmission shaft 101 One connecting portion 120, an inclined portion 140, and a second connecting portion 130 are formed.

  Moreover, as for the expansion | swelling part 9 formed with the 2nd metal material 8, the center part of the axis line O2 direction expand | swells largely radially outside. Moreover, the cross-sectional shape of the outer peripheral surface 9b of the expansion part 9 becomes a circular arc shape that protrudes outward as it goes toward the central part in the direction of the axis O2. Therefore, in the process, the intermediate main body 13 has the resin hardened while greatly expanding the diameter, and the cross-sectional shape in the direction of the axis O2 becomes an arc shape to form the main body 110.

Further, in this process, since the body portion 2 swells radially outward, the thickness of the power transmission shaft 101 is thinner than the thickness W1 of the intermediate product 11 (see FIG. 5).
In particular, the center of the inflatable portion 9 swells radially outward from the end in the direction of the axis O2 so that the thickness W2 of the main body 110 extends from the end of the main body 110 to the central portion of the main body 110. It gradually gets thinner.

A cooling process (step S3) cools the mandrel 1 and returns the mandrel 1 to the initial shape. In the embodiment, as shown in FIG. 7, the pair of shaft portions 3 are placed on the suspension base 21, and the mandrel 1 is exposed to the atmosphere to radiate heat.
According to this process, the mandrel 1 is reduced, and a gap C <b> 1 is formed between the outer peripheral surface of the mandrel 1 and the inner peripheral surface of the tubular body 102. Further, the outer diameter r1 of the cylindrical portion 4 of the mandrel 1 is smaller than the inner diameter r2 (see FIG. 6) of the first connection portion 120.

In the decentering step (step S4), as shown in FIG. 8, the mandrel 1 is pulled out from the opening on the first connecting portion 120 side of the power transmission shaft 101, and the power transmission shaft 101 and the mandrel 1 are separated.
Here, the maximum outer diameter of the mandrel 1 is the outer diameter r1 of the cylindrical portion 4 (see FIGS. 3 and 7) and is smaller than the inner diameter r2 of the first connection portion 120. Therefore, the mandrel 1 can be pulled out smoothly without being caught on the inner peripheral surface of the tubular body 102.

From the above, according to the mandrel 1 of the first embodiment, the tubular body 102 in which the central portion (main body portion 110) swells radially outward from both end portions (the first connection portion 120 and the second connection portion 130) is manufactured. can do.
Further, according to the present embodiment, since the mandrel 1 can be decentered without breaking the mandrel 1, the cost is reduced as compared with a core material such as a sand mold or a melting member that is broken each time the tube 102 is manufactured. be able to.

[Second Embodiment]
Next, the mandrel 31 of the second embodiment will be described.
As shown in FIG. 8, the mandrel 31 of the second embodiment includes a barrel portion 32 having a circular outer peripheral shape, and a pair of shaft portions 3 protruding from both ends of the barrel portion 2.
The body portion 32 includes a cylindrical portion 34, a diameter-reducing portion 35 that gradually decreases in diameter as it moves away from the one end portion 34 c of the cylindrical portion 34, and one end side of the diameter-reducing portion 35. And a small-diameter portion 36 having a small diameter.

  The other end 34a of the cylindrical part 34 is a part that forms the first connection part 120 (see FIG. 1). A region from the central portion 34b to the one end portion 34c of the cylindrical portion 34 is a portion that forms the main body portion 110 (see FIG. 1). The outer diameter r3 of the cylindrical portion 34 is the same from one end side to the other end side. The reduced diameter portion 35 is a portion that forms the inclined portion 140 (see FIG. 1), and the small diameter portion 36 is a portion that forms the second connecting portion 130 (see FIG. 1).

Each structure of the trunk | drum 32 is formed with the same metal material, and expand | swells by heating (refer the dashed-two dotted line L of FIG. 8). Therefore, the outer diameter of the body portion 2 is formed smaller than the inner diameter of the power transmission shaft 101.
Each of the cylindrical portion 34, the reduced diameter portion 35, and the small diameter portion 36 has a space C2 formed therein and is hollow.
In addition, the radial thickness of the other end 34a of the cylindrical portion 34 is W3, which is relatively thin. Similarly, the radial thickness of the reduced diameter portion 35 and the small diameter portion 36 is also W3.
On the other hand, the region from the central portion 34b to the one end portion 34c in the cylindrical portion 34 has a thickness W4, and constitutes a thick portion 39 that is thicker than other portions.

  The inner peripheral surface 39 a of the thick portion 39 protrudes radially inward toward the central portion of the thick portion 39. In addition, the cross-sectional shape when the inner peripheral surface 39a is cut along the axis O2 is a gentle curve, and has a circular arc shape with the center portion protruding inward. That is, the cross-sectional shape of the thick part 39 is an arcuate shape.

  As described above, according to the mandrel 31 of the second embodiment, the portions of the cylindrical portion 34, the reduced diameter portion 35, and the small diameter portion 36 swell radially outward in the heating step (step S2). In particular, since the thick portion 39 has a large thickness W4, the amount of expansion that expands radially outward is large. Therefore, the tubular body 102 in which the central portion (main body portion 110) swells radially outward than both end portions (the first connection portion 120 and the second connection portion 130) can be manufactured.

Moreover, according to the said structure, the outer peripheral surface 39b of the thick part 39 at the time of expansion becomes circular arc shape. Therefore, it is possible to form the main body 110 having a circular cross-section in the direction of the axis O2.
Moreover, according to the said structure, the expansion | swelling amount in the thick part 39 is larger in the center part than the edge part of the axis line O1 direction. For this reason, the main-body part 110 which becomes thin toward the center part from the edge part of the axis line O1 can be formed.
Further, according to the present embodiment, since the core 102 can be decentered without breaking the mandrel 31, the cost is reduced as compared with a core material such as a sand mold or a melting member that is broken every time the tube 102 is manufactured. be able to.

[Third embodiment]
Next, the mandrel 41 of the third embodiment will be described.
As shown in FIG. 10, the mandrel 41 of the third embodiment includes a substantially cylindrical body portion 2, a pair of shaft portions 3 protruding from both ends of the body portion 2, and a heating device disposed in the body portion 2. 42. Since the trunk | drum 2 and the axial part 3 were demonstrated in 1st embodiment, it concentrates on the heating apparatus 42 and demonstrates.

  The heating device 42 is an apparatus for heating the continuous carbon fiber and the prepreg impregnated with the resin wound around the outer peripheral side of the trunk portion 2 by being arranged inside the trunk portion 2 and heating the trunk portion 2. . The heating device 42 of the present embodiment is a heating wire, and extends to the entire body portion 2 along the axis O2 to heat the entire body portion 2.

Next, the manufacturing method of the tubular body 102 using the mandrel 41 of the third embodiment will be described.
The manufacturing method of the tubular body 102 includes a winding process (step S1), a heating process (step S2), a cooling process (step S3), and a decentering process (step S4) (see FIG. 4). The only difference from the first embodiment is the heating process (step S2). Hereafter, the heating process (step S2) of a change point is demonstrated.

As shown in FIG. 11, in the heating step (step S <b> 2), the mandrel 41 and the intermediate product 11 are arranged in the outer mold 50, and the heating device 42 is driven to heat the mandrel 41 and the intermediate product 11. It should be noted that the cavity surface 51 of the outer mold 50 has the same shape as the outer shape of the tubular body 102.
According to the said process, the trunk | drum 2 heated by the heating apparatus 42 expand | swells, and the intermediate product 11 swells to radial direction outer side.
Further, when the expansion amount of the body portion 2 reaches a predetermined amount, the intermediate product 11 comes into contact with the cavity surface 51 of the outer mold 50, and the expansion of the intermediate product 11 is stopped.

As described above, also in the third embodiment, it is possible to manufacture the tubular body 102 in which the central portion (main body portion 110) swells radially outward from both end portions (the first connection portion 120 and the second connection portion 130). Further, according to the mandrel 41 of the third embodiment, it is not necessary to use the oven 20 or the like in the heating step (step S2) of the method for manufacturing the power transmission shaft 101.
Further, since the outer mold 50 is used, the expansion of the intermediate product 11 is limited by the outer mold 50. For this reason, the shape of the tubular body 102 can be made more desirable.

  As mentioned above, although each embodiment was described, you may make the outer peripheral shape of the other end part 4a of the cylindrical part 4 and the small diameter part 6 into a polygonal shape. According to this, the inner peripheral shape of the 1st connection part 120 and the 2nd connection part 130 is formed in polygonal shape. Therefore, the trouble of separately forming the first connection part 120 and the second connection part 130 into a polygonal shape can be saved.

  Moreover, regarding the power transmission shaft manufactured by the mandrel of the present invention, the cross-sectional shape of the main body 110 cut along the direction of the axis O1 is not limited to an arc shape. For example, the cross-sectional shape of the main body 110 cut along the axis O1 may be stepped. That is, in the mandrel of the present invention, the cross-sectional shape of the inflatable part 9 and the thick part 39 when inflated along the axis O2 may be stepped.

  Moreover, in the mandrel 41 of the third embodiment, the outer mold 50 is used. However, when the tubular body 102 is manufactured using the mandrel 1 of the first embodiment or the mandrel 31 of the second embodiment, the outer mold 50 is used. Also good.

  Moreover, the tubular body manufactured by the mandrel is not limited to the above. For example, regarding the inclined portion, the plate thickness may gradually decrease from the end on the main body 110 side (front side) toward the end on the second connection portion 130 side (rear side). According to this, the plate | board thickness of a rear-end part becomes the thinnest among inclination parts, and the rear-end part of an inclination part comprises a weak part. Or the inclined part of this invention may provide a recessed part in an outer peripheral surface or an internal peripheral surface, and may form a weak part by changing the plate | board thickness of a partial area.

1,31,41 Mandrel 2 Body 4 Column 4a, 34a The other end (both ends)
5,35 Reduced diameter part (both ends)
6,36 Small diameter part (both ends)
7 First metal material (first material)
8 Second metal material (second material)
9 Expansion part (central part)
32 body part 34 cylindrical part 39 thick part (central part)
50 External mold 101 Power transmission shaft 102 Tubing body 110 Main body portion 120 First connection portion 130 Second connection portion 140 Inclined portion

Claims (4)

A mandrel made of fiber reinforced plastic and used to manufacture a tube used for a power transmission shaft,
It has a trunk around which continuous fibers impregnated with resin are wound,
The trunk is formed of a material that expands when heated,
The barrel is much larger the amount of expansion upon heating towards the middle than at both ends,
An inflatable part is provided in the central part of the trunk part,
The expansion part is formed of a second material having a higher coefficient of thermal expansion than the first material forming the end of the body part,
The thickness of the expanding portion is formed thicker toward the central portion in the axial direction,
The mandrel characterized by the cross-sectional shape which cut | disconnected the said expansion | swelling part to the axial direction becomes a bow shape so that the center part may protrude in a radial direction inner side . A mandrel made of fiber reinforced plastic and used to manufacture a tube used for a power transmission shaft,
It has a trunk around which continuous fibers impregnated with resin are wound,
The trunk is formed of a material that expands when heated,
The barrel is much larger the amount of expansion upon heating towards the middle than at both ends,
The trunk is cylindrical and formed entirely of the same material,
A mandrel having a thick part thicker than a thickness of an end part of the trunk part is provided at a central part of the trunk part . The thickness of the thick portion is formed thicker toward the central portion in the axial direction,
3. The mandrel according to claim 2 , wherein a cross-sectional shape obtained by cutting an inner peripheral surface of the thick portion in an axial direction is a curved shape so that a central portion protrudes radially inward. The mandrel according to any one of claims 1 to 3 , wherein an outer peripheral shape of an end portion of the body portion is a polygonal shape.

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