JP5736074B2 - Spinning reel spool connection structure - Google Patents

Description

  The present invention relates to a coupling structure, and more particularly, to a spinning reel spool coupling structure in which a spool is coupled to a spool shaft that passes through a spool of a spinning reel so as not to rotate.

  2. Description of the Related Art Conventionally, a spinning reel spool connecting structure is known in which a spool is prevented from rotating at the tip of a spool shaft, and the spool is connected to the spool shaft so as to be integrally rotatable or non-rotatable. For example, there are lever brake type spinning reels and rear drag type spinning reels in which the spool is connected to the end of the spool shaft so as not to rotate (see, for example, Patent Document 1).

  In the conventional spool coupling structure, a rotation prevention pin is detachably inserted into a through hole formed so as to penetrate the spool shaft in the radial direction to prevent rotation. Specifically, a rotation-preventing groove is formed along the diameter in the boss portion of the spool through which the spool shaft passes, and the rotation-preventing groove is engaged with the outer peripheral surface of the rotation-preventing pin to prevent rotation. The non-rotating pin is formed with a large-diameter collar for preventing it from coming off. Further, an anti-removal O-ring is mounted on the non-rotating pin on the side opposite to the flange portion with the spool shaft interposed therebetween. The O-ring is generally mounted at a position where it can contact the spool shaft. In order to prevent movement in the axial direction, the O-ring is mounted on an annular groove formed on the outer peripheral surface of the rotation stopper pin so as to be close to the outer peripheral surface of the spool shaft.

  In the spool connection structure having such a configuration, when a large tension is applied to the fishing line when a fish is caught and a large rotational force is applied to the spool, the spool shaft is difficult to rotate. A large shearing force acts on the part. For example, in the case of a lever brake type spinning reel capable of braking the rotor, a large tension acts on the fishing line, and a large shearing force acts on the detent pin when the rotor is braked. In the case of a rear drag type spinning reel, if a large tension is applied to the fishing line when the drag force is increased to make it difficult to rotate the spool shaft, a large shearing force is applied to the detent pin.

Utility Model Registration No. 2603123 (FIG. 10)

  In order to reduce the size of the spinning reel, it is desired to reduce the diameter of the spool shaft. When the diameter of the spool shaft is reduced, the ratio of the inner diameter of the through hole to the outer diameter of the spool shaft is increased unless the diameter of the locking pin is also reduced, the thickness around the through hole is reduced, and the strength of the spool shaft cannot be secured. . When a shearing force acts on the outer peripheral surface of the spool shaft of the non-rotating pin whose diameter has been reduced, stress concentration occurs at the annular groove forming portion, making it difficult to ensure the strength of the non-rotating pin.

  An object of the present invention is to ensure the strength of a rotation-preventing pin even if the diameter of the rotation-preventing pin is reduced by reducing the diameter of the spool shaft.

The spinning reel spool connection structure according to the first aspect of the present invention is a structure in which the spool is connected to a spool shaft that passes through the spool of the spinning reel by preventing the spool from rotating. The spool coupling structure includes a pin insertion portion, a rotation prevention pin, a retaining member, and a rotation prevention groove. The pin insertion portion has a through hole formed so as to penetrate the spool shaft in the radial direction. The anti-rotation pin has a first anti-rotation portion provided at the first end, a fitting portion, and a second anti-rotation portion. The fitting portion is disposed adjacent to the first detent portion and has a length that fits into the pin insertion portion. The second detent portion extends from the fitting portion toward the second end and has a larger diameter than the pin insertion portion. The retaining member prevents the rotation prevention pin from coming off from the spool shaft. The retaining member is disposed on the outer peripheral side of the first detent portion and has an axial length that can contact the spool shaft. The non-rotating groove is formed in the spool shaft penetrating portion of the spool along the diameter of the spool shaft, and has a groove width that engages with the second non-rotating portion. The first detent portion has the same outer diameter as the fitting portion. The retaining member is a coil spring that can be mounted on the outer peripheral side of the first detent portion.

  In this spool connection structure, the rotation prevention pin is inserted into the pin insertion portion of the spool shaft from the first end side where the first rotation prevention portion is located. Then, the step portion between the large-diameter second detent portion and the fitting portion contacts the outer peripheral surface of the spool shaft, and the detent pin is positioned. In this state, the first detent portion on the first end side protrudes from the pin insertion portion. A retaining member is attached to the projecting first detent portion, and the detent pin is retained. When the spool is mounted on the spool shaft in a state in which the anti-rotation pin is mounted on the spool shaft, the anti-rotation groove of the spool engages with the anti-rotation pin, and the spool is connected to the spool shaft while being prevented from rotating.

  Here, a retaining member is attached to the first detent portion of the detent pin to prevent the detent pin from coming off. For this reason, it is not necessary to form an annular groove for preventing slipping in the vicinity of the outer peripheral surface of the spool shaft where the shearing force is generated in the non-rotating pin. As a result, it is possible to ensure the strength of the detent pin even if the detent pin is reduced in diameter.

In addition, since the fitting portion and the first detent portion have the same outer diameter, the strength of the detent pin can be further ensured as compared with the case where the first detent portion is smaller in diameter than the fitting portion.

Further, the rotation prevention pin can be prevented from coming off by preventing one end of the coil spring from coming off and contacting the other end with a free length or compression to contact the spool shaft.

Spool coupling structure for a spinning reel according to a second aspect is the structure according to the invention 1, retaining member has an outer diameter that engages the detent groove. In this case, since the retaining member has an outer diameter that engages with the non-rotating groove, the spool is less likely to rattle.

The spinning reel spool coupling structure according to a third aspect of the present invention is the structure according to the first or second aspect , wherein the rotation prevention pin further includes an annular groove formed on the first end side of the first rotation prevention portion, The end portion on the first end side is formed with a small diameter so that it can be locked in the annular groove. In this case, since the annular groove is formed on the first end side where the shearing force does not act, even if the annular groove is formed, the strength of the small-diameter detent pin is secured and the retaining member is removed by the annular groove. I can stop it.

A spinning reel spool coupling structure according to a fourth aspect of the present invention is the structure according to any one of the first to third aspects, wherein the sleeve is fitted to the outer peripheral surface of the spool shaft and formed with a retaining hole communicating with the pin insertion portion. Further prepare. In this case, even if the diameter of the spool shaft is reduced, it becomes possible to connect a spool adapted to the large-diameter spool shaft, and compatibility with a spool for a large-diameter spool shaft can be ensured.

A spinning reel spool coupling structure according to a fifth aspect of the present invention is the structure according to any one of the first to fourth aspects, wherein the spool is a tubular body provided on the inner circumferential side of the bobbin trunk around which the fishing line is wound, and the bobbin trunk. And a boss portion. The anti-rotation groove is a groove formed along the diameter on one end face of the boss portion. In this case, the spool and the spool shaft can be connected together so that they can rotate together or not.

A spinning reel spool coupling structure according to a sixth aspect of the present invention is the structure according to any one of the first to fourth aspects, wherein the spool includes a spool body and a cylindrical member. The spool main body has a bobbin trunk around which a fishing line is wound, and a cylindrical boss provided on the inner peripheral side of the bobbin trunk. The cylindrical member is attached to the spool shaft so as to rotatably support the boss portion of the spool body. The anti-rotation groove is a groove formed along the diameter on one end surface of the cylindrical member. In this case, since the spool body and the cylindrical member can be rotated relative to each other, a front drag mechanism can be provided between the spool body and the cylindrical member.

  According to the present invention, the retaining pin is attached to the first detent portion of the detent pin to prevent the detent pin from coming off. For this reason, it is not necessary to form an annular groove for preventing slipping in the vicinity of the outer peripheral surface of the spool shaft where shearing force is generated. As a result, it is possible to ensure the strength of the detent pin even if the detent pin is reduced in diameter.

1 is a side cross-sectional view of a spinning reel that employs a first embodiment of the present invention. The cross-sectional enlarged view of the spool periphery. The exploded perspective view of the spool connection structure. The cross-sectional enlarged view of the spool connection structure. VV sectional drawing of FIG. The figure equivalent to FIG. 2 of 2nd Embodiment. The figure equivalent to the FIG.

<First Embodiment>
<Overall configuration>
As shown in FIG. 1, the spinning reel adopting the first embodiment of the present invention is a lever brake type reel that winds a fishing line around a first axis X along the longitudinal direction of the fishing rod. The spinning reel winds up a reel body 2 having a handle 1, a rotor 3 rotatably supported around the first axis X on the front portion of the reel body 2, and a fishing line disposed on the front portion of the rotor 3. And a spool 4.

  The reel body 2 is made of, for example, a magnesium alloy. As shown in FIG. 1, the reel body 2 includes a rod mounting portion 2c that is long before and after being mounted on a fishing rod, a reel body 2a that is spaced from the rod mounting portion 2c, a rod mounting portion 2c, and a reel body. 2a to connect 2a. The reel body 2a has a mechanism mounting space inside, is formed integrally with the leg portion 2b, and has an open side portion. The opening of the reel body 2a is closed by a lid member (not shown). A metal cylindrical mounting member 2e with a mounting flange is mounted on the front portion of the reel body 2a. In the first embodiment, the leg 2b is formed integrally with the reel body 2a, but may be formed integrally with the lid member.

  Inside the reel body 2a, a rotor drive mechanism 5, a lever brake mechanism 6, and an oscillating mechanism 20 are provided. The rotor drive mechanism 5 is a mechanism for rotating the rotor 3 in conjunction with the handle 1. The lever brake mechanism 6 is a mechanism for braking the rotation (reverse rotation) of the rotor 3 in the yarn drawing direction. The oscillating mechanism 20 is a mechanism for reciprocating the spool 4 back and forth via the spool shaft 8 in conjunction with the rotation of the handle 1.

  The rotor 3 is made of, for example, a magnesium alloy, and is rotatably supported by the reel body 2. The rotor 3 includes a cylindrical portion 3a and a first arm portion 3b and a second arm portion 3c provided on the side of the cylindrical portion 3a so as to face each other. A boss portion 3f through which a spool shaft 8 and a pinion gear 12 which will be described later penetrate is formed at the center portion of the front wall 3d of the cylindrical portion 3a. A bail arm 9 is swingably provided at the tip of the first arm portion 3b and the tip of the second arm portion 3c. The fishing line is guided to the spool 4 by the bail arm 9.

<Spool configuration>
The spool 4 is made of, for example, an aluminum alloy. The spool 4 is disposed between the first arm portion 3 b and the second arm portion 3 c of the rotor 3. The spool 4 can be attached to and detached from the spool shaft 8 penetrating the spool 4 by a one-touch attachment / detachment mechanism 48. Further, the spool 4 is coupled to the tip end portion of the spool shaft 8 by a spool coupling structure 65 while being prevented from rotating.

  The spool shaft 8 is, for example, a shaft having an outer diameter smaller than that of a conventional spinning reel having the same diameter. In the first embodiment, for example, the outer diameter of the spool shaft 8 is 4 mm, and the diameter of the conventional spool shaft is 4.5 mm, for example. As shown in FIG. 2, the spool shaft 8 has a tapered surface 8a formed at the tip and an annular retaining groove 8b formed at the rear of the tapered surface 8a. Further, a pin insertion portion 8d having a through hole 8c formed so as to penetrate along the diameter is provided behind the retaining groove 8b of the spool shaft 8. A detent pin 50 is detachably fitted in the through hole 8c of the pin insertion portion 8d.

  2 and 3, the spool 4 includes a spool main body 22, a front drag mechanism 23 attached to the spool main body 22, and a spool cylinder portion (a cylindrical member of the cylindrical member) on which the spool main body 22 is rotatably attached. One example) 24. The spool body 22 has a cylindrical bobbin trunk 22a, a cylindrical skirt 22b formed at the rear end of the bobbin trunk 22a with a larger diameter than the bobbin trunk 22a, and a front part of the bobbin trunk 22a. And a flange portion 22c formed to be inclined forward.

  The bobbin trunk 22a includes a mounting disc portion 22e extending inward in the radial direction and a mounting cylinder portion (an example of a boss portion) 22f integrally formed on the inner peripheral side of the mounting disc portion 22e. A claw member 82 of a drag sound generation mechanism 56, which will be described later, is generated on the rear surface of the mounting disc portion 22e so as to be swingable. On the front surface of the mounting disc portion 22e, a drag storage cylinder portion 22g for storing the front drag mechanism 23 is formed to protrude forward. One or a plurality (for example, two to four) of slits 22h for preventing rotation of a second drag washer 67 of a friction portion 58, which will be described later, is formed in the drag storage cylinder portion 22g. . The mounting cylinder portion 22f is rotatably mounted on the spool cylinder portion 24.

  On the outer peripheral surface of the flange portion 22c, a rectifying member 22d having a tapered surface that is widened is attached. The rectifying member 22d is provided so that the fishing line can be smoothly fed out without backlash during casting. The rectifying member 22d is fixed to the flange portion 22c by a flange fixing member 25. The flange fixing member 25 is formed to project radially inward from the tapered pressing portion 25a that presses the rectifying member 22d, the first cylindrical portion 25b that extends rearward from the pressing portion 25a, and the rear portion of the first cylindrical portion 25b. The disc portion 25c and the second cylinder portion 25d extending rearward from the disc portion 25c are provided. The second cylindrical portion 25d is screwed and fixed to the inner peripheral surface of the bobbin trunk 22a. In addition, a recess 25e is formed in the second cylindrical portion 25d to which a retaining spring 26 for retaining the front drag mechanism 23 is attached.

  The spool cylinder portion 24 has an inner diameter that can be attached to a conventional spool shaft having a diameter of 4.5 mm. As shown in FIGS. 3 and 5, the spool cylinder portion 24 has chamfered portions 24 a that are arranged on the outer peripheral surface of the intermediate portion so as to face each other in parallel. Further, as shown in FIGS. 3, 4 and 5, the rear end portion 24b of the spool cylinder portion 24 is formed with a large diameter, and there is an engagement groove (rotation) with which the rotation prevention pin 50 is engaged. An example of a stop groove) 24c is formed along the diameter. The engagement groove 24c has a groove width that can be engaged with the outer diameter of the conventional detent pin in order to maintain compatibility with the conventional detent pin. The spool cylinder portion 24 is attached to the spool shaft 8 by a non-rotating pin 50 so as not to rotate.

A male screw portion 24d for drag adjustment is provided on the outer peripheral surface of the front end portion of the spool cylinder portion 24. A mounting groove 24e for mounting a later-described leaf spring 77 and retaining plate 78 of the one-touch attaching / detaching mechanism 48 is formed behind the male screw portion 24d. The mounting groove 24e has a D-shaped cross section so as to cut out to the inner peripheral surface of the spool cylinder portion 24. A disc member 80 of the drag sound generating mechanism 56 is mounted on the outer peripheral surface of the rear portion of the spool cylinder portion 24 so as to be in contact with the rear end portion 24b so as not to rotate. The disc member 80 is restricted from moving backward by contacting the rotation stopper pin 50. Thereby, the backward movement of the spool body 22 is restricted. Between the disc member 80 and the mounting disc portion 22e, as shown in FIG. 4, a plurality of (for example, three) spool washers made of synthetic resin for adjusting the position of the spool body 22 in the spool axial direction. 81 is attached. The spool washer 81 has a sealing function for preventing liquid from entering from the rear. A one-touch attaching / detaching mechanism 48 is attached to the inner peripheral surface on the front end side of the spool cylinder portion 24.

As shown in FIG. 3, the one-touch attachment / detachment mechanism 48 is disposed between the push button 76, which is slidably mounted in the spool cylinder portion 24, the leaf spring 77, and the leaf spring 77 and the push button 76. And a retaining plate 78. The push button 76 is a substantially bottomed cylindrical member, and protrudes forward from an operation member 60 of the front drag mechanism 23 described later. The push button 76 is biased forward by a pressing spring 79 in the form of a coil spring and is prevented from coming off from the spool cylinder portion 24. The base end side of the push button 76 is tapered cam projection 76a to move the fastened securely stop plate 78 is formed. The retaining plate 78 is urged inward in the radial direction of the spool cylinder portion 24 by a plate spring 77. The leaf spring 77 is formed by bending a spring plate material in a generally D shape. The leaf spring 77 is a pair of first engaging portions 77a curved in an arc shape that engages with the mounting groove 24e of the spool cylinder portion 24, and a second engagement bent in a convex manner between the first engaging portions 77a. And a joint portion 77b. A retaining plate 78 is disposed between the second engaging portion 77 b and the cam projection 76 a of the push button 76, and is engaged with and disengaged from the annular retaining groove 8 b of the spool shaft 8. The retaining plate 78 includes a pair of first portions 78a disposed at both ends that engage with the mounting groove 24e, and a second portion 78b disposed between the first portions 78a and engaged with the retaining groove 8b. Are C-shaped plate-like members. When the push button 76 is pressed, the retaining plate 78 engages with the cam protrusion 76a and moves in the radial direction, and moves the second engagement portion 77b of the leaf spring 77 uniformly in the radial direction. Thereby, the leaf | plate spring 77 can be displaced stably. The spool 4 can be detached from the spool shaft 8 by detaching the second portion 78 b of the retaining plate 78 from the retaining groove 8 b by pressing the push button 76. Further, when the spool 4 is mounted on the spool shaft 8, the retaining plate 78 moves radially outward along the tapered surface 8 a at the tip of the spool shaft 8 against the urging force of the leaf spring 77, and the retaining groove When reaching 8b, the retaining plate 78 is locked to the retaining groove 8b by the urging force of the leaf spring 77.

  As shown in FIGS. 3, 4, and 5, the rotation prevention pin 50 includes a first rotation prevention portion 50 a provided at the first end, a fitting portion 50 b, and a second rotation prevention portion 50 c. doing. An annular groove 50d for locking the retaining member 51 is formed at the tip of the first detent portion 50a. The fitting portion 50b is disposed adjacent to the first detent portion 50a and has a length that fits into the pin insertion portion 8d. In the first embodiment, the fitting portion 50b has the same diameter as that of the first detent portion 50a. The second detent portion 50c extends from the fitting portion 50b toward the second end and has a larger diameter than the pin insertion portion 8d. The second detent portion 50c has an outer diameter that engages with the engagement groove 24c. The second anti-rotation portion 50c contacts the outer peripheral surface of the spool shaft 8 at a step portion with the fitting portion 50b when the anti-rotation pin 50 is attached to the pin insertion portion 8d. The outer diameter of the second detent portion 50c is the same as that of the conventional detent pin and is an outer diameter that can be engaged with the engagement groove of the conventional spool.

  On the outer peripheral side of the first detent portion 50a, a retaining member 51 disposed with the second detent portion 50c and the spool shaft 8 interposed therebetween is mounted. The retaining member 51 prevents the rotation prevention pin 50 from coming off from the spool shaft 8. The retaining member 51 has an outer diameter that engages with the engaging groove 24c and an inner diameter that fits to the outer peripheral surface of the first detent portion 50a. Accordingly, the outer diameter of the retaining member 51 is substantially equal to the second detent portion 50c. In the first embodiment, the retaining member 51 is, for example, a coil spring 51a in which a small-diameter mounting portion 51b is formed at one end. The mounting portion 51b is locked in the annular groove 50d. Thereby, the retaining member 51 is prevented from coming off from the rotation prevention pin 50. The retaining member 51 has an axial length that can contact the outer peripheral surface of the spool shaft 8. In the first embodiment, the other end of the retaining member 51 is in contact with the outer peripheral surface of the spool shaft 8 in a slightly compressed state.

  A sleeve 52 is mounted between the spool shaft 8 and the spool cylinder portion 24 in order to ensure compatibility with a conventional spool shaft having a diameter of 4.5 mm. The sleeve 52 has an outer peripheral surface that fits to the inner peripheral surface of the spool cylinder portion 24 by clearance fit, and an inner peripheral surface that fits to the outer peripheral surface of the spool shaft 8 by clearance fit. In the rear portion of the sleeve 52 that approaches the rotor 3, a passage hole 52 a through which the second detent portion 50 c of the detent pin 50 and the retaining member 51 can pass is formed along the diameter. Since the rotation prevention pin 50 and the retaining member 51 pass through the passage hole 52a, the sleeve 52 can be retained. With this sleeve 52, the spool mounted on the conventional spool shaft can be mounted on the spool shaft 8, and compatibility with the conventional spool can be achieved.

  The spool connection structure 65 includes the pin insertion portion 8d of the spool shaft 8 described above, the anti-rotation pin 50, the retaining member 51, and the engagement groove 24c.

  As shown in FIGS. 2 and 3, the front drag mechanism 23 includes a drag adjusting portion 57 and a friction portion 58 whose friction force is adjusted by the drag adjusting portion 57. The drag adjusting portion 57 includes an operation member 60 that is screwed into the spool cylinder portion 24, and a pressing member 61 that is pressed by the operation member 60 and presses the friction portion 58.

  As shown in FIGS. 2 and 3, the operation member 60, which is a generally cylindrical member with a flange, includes a knob handle 60b having a knob protrusion 60a protruding along the diameter, and a knob flange portion to which the knob handle 60b is fixed. 60c. At the center of the knob handle 60b, as shown in FIG. 2, a nut 62 that is screwed into the male thread portion 24d of the spool cylinder portion 24 is mounted so as to be rotatable integrally and axially movable. In FIG. 2, the nut 62 is depicted as being moved to the right side in FIG. 2 so that the lower side of the nut 62 with respect to the upper side of the first axis X has a stronger pressing force. Between the nut 62 and the pressing member 61, an adjustment spring 63 in the form of a coil spring for smoothly adjusting the drag force is mounted in a compressed state. The pressing member 61 is mounted on the spool cylinder portion 24 so as not to rotate but to move in the axial direction. The pressing member 61 is connected to the operation member 60 so as to be rotatable and cannot be removed. A first gap that seals a gap between the spool body 22 and the drag adjusting portion 57 between the pressing member 61 and the inner circumferential portion of the spool body 22 (for example, the inner circumferential surface of the second cylinder portion of the flange fixing member 25). A seal member 84 is attached. A second seal member 85 that seals the gap between the pressing member 61 and the spool cylinder portion 24 is integrally formed at the rear portion of the pressing member 61 by an integral molding technique such as insert molding or outsert molding. The first seal member 84, the second seal member 85, and the spool washer 81 can prevent liquid from entering the friction portion 58 regardless of whether the spool 4 is attached or detached. Between the operation member 60 and the pressing member 61, a drag knob sound generation mechanism 64 that emits sound when the operation member 60 is rotated to adjust the drag is mounted.

The friction part 58 is mounted between the pressing member 61 and the mounting disk part 22 e of the spool body 22. The friction portion 58 includes a first drag washer 66a and a third drag washer 66b that are non-rotatably attached to the chamfered portion 24a of the spool cylinder portion 24, and a first ear-attached ear that is integrally attached to the bobbin trunk 22a. 2 drag washers 67. A drag disk 68a is mounted between the first drag washer 66a and the second drag washer 67 and between the second drag washer 67 and the third drag washer 66b. Between the third drag washer 6 6 b and the mounting disk portion 22e, drag disk 68b is mounted. As shown in FIG. 3, the second drag washer 67 has one or a plurality of (for example, four) ears 67 a protruding in the radial direction. The ear portion 67a is locked to the slit 22h of the bobbin trunk described above. The flange fixing member 25 is screwed and bonded to the bobbin trunk 22a. Thereby, the flange fixing member 25 is not loosened by vibration. The friction portion 58 is prevented from coming off by a retaining spring 26 attached to the recess 25 e of the flange fixing member 25. Thereby, even if the operation member 60 is removed from the spool cylinder part 24, the friction part 58 does not fall off.

  As shown in FIG. 1, the rotor drive mechanism 5 includes a master gear 11 that rotates together with a master gear shaft 10 to which the handle 1 is fixed so as to be integrally rotatable, and a pinion gear 12 that meshes with the master gear 11. . The master gear shaft 10 is rotatably supported by the reel body 2. The pinion gear 12 is formed in a cylindrical shape, and the front portion 12 a of the pinion gear 12 extends through the boss portion 3 f of the rotor 3 to the spool 4 side. At the front portion 12 a of the pinion gear 12, the rotor 3 is fixed to the pinion gear 12 by a nut 13 so as to be integrally rotatable. The pinion gear 12 is rotatably supported on the reel body 2a by bearings 14a and 14b at the front part and the intermediate part. The nut 13 is prevented from loosening by a retainer 36. The nut 13 is in contact with the spool shaft 8 through a bearing 13a. As a result, a gap is formed between the inner peripheral surface of the pinion gear 12 and the outer peripheral surface of the spool shaft 8. The retainer 36 is provided with a third seal member 36b, which prevents liquid from entering from the gap between the spool shaft 8 and the pinion gear 12.

  As shown in FIG. 1, the oscillating mechanism 20 is of a traverse cam type, and is mounted on the reel body 2a so as to be rotatable about an axis parallel to the spool shaft 8 and meshed with the pinion gear 12. It has a screw shaft 20b and a slider 20c that moves back and forth by the rotation of the screw shaft 20b. The rear end portion of the spool shaft 8 is attached to the slider 20c so as not to rotate but to move in the axial direction.

  As shown in FIG. 2, the drag sound generation mechanism 56 is a mechanism that generates sound by the relative rotation of the spool 4 and the spool shaft 8 during drag operation. The drag sound generation mechanism 56 includes a disc member 80 fixed to the spool cylinder portion 24 that cannot rotate on the spool shaft 8 and a pawl member 82 that is swingably attached to the mounting disc portion 22e of the spool 4. And an urging member 83 for urging the claw member 82 to the neutral position.

  As shown in FIG. 1, the lever brake mechanism 6 includes a braking portion 16, a braking lever 17 for adjusting the braking force of the braking portion 16, and a biasing force of the braking lever 17 in a direction away from the saddle mounting portion 2 c. And a predetermined braking portion (not shown) that can be switched between a predetermined braking state and a braking release state by the braking lever 17. The brake lever 17 is swingably attached to the leg 2b of the reel body.

  The braking portion 16 includes a cylindrical braking portion main body 31 that is braked by pressing the tip of the braking lever 17 and a claw-type one-way clutch 32 that transmits the rotation of the rotor 3 in the yarn feeding direction to the braking portion main body 31. Have.

  When the brake lever 17 is operated in a direction approaching the heel mounting portion 2c, the brake portion main body 31 is braked by the brake lever 17, and the rotation of the rotor 3 in the yarn unwinding direction is braked according to the operating force. When the brake lever 17 is operated in a direction away from the saddle mounting portion 2c, the brake portion main body 31 is braked with a preset braking force by the action of the predetermined brake portion.

<Reel operation and operation>
At the time of casting, the fishing line is fed out from the outer periphery of the spool 4 by tilting the bail arm 9 toward the line releasing posture and casting. At the time of winding the yarn, if the handle 1 is rotated in the yarn winding direction, the bail arm 9 returns to the yarn winding posture by a return mechanism (not shown). The rotational force of the handle 1 is transmitted to the pinion gear 12 via the master gear shaft 10 and the master gear 11. The rotational force transmitted to the pinion gear 12 is transmitted to the rotor 3 via the front portion 12a of the pinion gear 12. At this time, since the rotor 3 rotates in the yarn winding direction, the one-way clutch 32 does not operate, and this rotational force is not transmitted to the braking unit main body 31. When the pinion gear 12 rotates, the spool shaft 8 reciprocates in the front-rear direction. As a result, the fishing line is wound on the spool 4.

  When a fish is caught and the brake lever 17 is operated to brake the rotor 3 and the operation member 60 is operated to increase the drag force, a strong torque is transmitted to the spool cylinder portion 24 via the front drag mechanism 23. As a result, a strong shearing force is generated in the vicinity of the outer peripheral surface of the spool shaft 8 of the rotation stopper pin 50. However, in this embodiment, the small-diameter annular groove is not formed in the portion where the shearing force of the rotation preventing pin 50 is generated. For this reason, as a result, the strength of the locking pin 50 can be secured even if the diameter of the locking pin 50 is reduced.

Second Embodiment
In the first embodiment, the present invention has been described by taking the spool 4 having the drag mechanism as an example, but in the second embodiment, the spool coupling structure according to the present invention is described by taking a spool having no drag mechanism as an example. Since the second embodiment shown in FIG. 6 has the same structure as that of the first embodiment except for the spool 104 and the spool connection structure 165, the description of the structure other than the spool and the spool connection structure is omitted.

  6 and 7, the spool 104 is connected to the spool shaft 8 so as not to rotate. The spool 104 includes a cylindrical bobbin trunk 122a, a cylindrical skirt 122b formed at the rear end of the bobbin trunk 122a and having a diameter larger than that of the bobbin trunk 122a, and a front part of the front of the bobbin trunk 122a. And a flange portion 122c formed to be inclined.

  The bobbin trunk 122a includes a mounting disc portion 122e extending inward in the radial direction, and a mounting cylinder portion (an example of a boss portion) 122f integrally formed on the inner peripheral side of the mounting disc portion 122e. The mounting disc 122e is integrally formed on the front inner peripheral surface of the bobbin trunk 122a. A fixed cylindrical portion 122g protruding forward is formed on the front surface of the mounting disc portion 122e.

  A rectifying member 122d having a tapered surface that is widened is attached to the outer peripheral surface of the flange portion 122c. The rectifying member 122d is fixed to the flange portion 122c by a flange fixing member 125. The flange fixing member 125 includes a tapered pressing portion 125a that presses the rectifying member 122d, and a first tube portion 125b that extends rearward from the pressing portion 125a. The first cylindrical portion 125b is screwed and fixed to the outer peripheral surface of the fixed cylindrical portion 122g. A disk-shaped front cover part 122i is screwed and fixed to the inner peripheral surface of the fixed cylinder part 122g. A push button 176 of a one-touch attachment / detachment mechanism 148 is attached to the front cover portion 122i so as to be movable back and forth. An engagement groove 124c with which the rotation stopper pin 50 engages is formed along the diameter at the rear end portion of the mounting cylinder portion 122f. The spool 104 is prevented from rotating with respect to the spool shaft 8 by a rotation stopper pin 50.

  As shown in FIG. 7, the one-touch attachment / detachment mechanism 148 includes a push button 176 that is attached to the front cover portion 122 i of the spool 104 so as to be movable back and forth, and a retaining spring 177. The push button 176 is a substantially bottomed cylindrical member, and protrudes forward from the front cover portion 122i. The push button 176 is biased forward by a retaining spring 177 and is prevented from being detached from the front cover portion 122i. A tapered cam projection 176 a for moving the retaining spring 177 is formed on the proximal end side of the push button 176. The retaining spring 177 is formed by bending a spring wire in a generally E shape. The retaining spring 177 is held by a plurality of washer members 182 attached to the inner peripheral surface of the front cover portion 122i. The spool 104 can be detached from the spool shaft 8 by releasing the retaining spring 177 from the retaining groove 8 b by pressing the push button 76. Further, when the spool 104 is mounted on the spool shaft 8, the retaining spring 177 spreads along the tapered surface 8a at the tip of the spool shaft 8, and when reaching the retaining groove 8b, the retaining spring 177 elastically acts on the retaining groove 8b. It is locked by.

  The anti-rotation pin 50 has the same configuration as that of the first embodiment. On the outer peripheral side of the first detent portion 50a, a retaining member 151 disposed with the second detent portion 50c and the spool shaft 8 interposed therebetween is mounted. The retaining member 151 is for retaining the rotation prevention pin 50 with respect to the spool shaft 8. The retaining member 151 has an outer diameter that engages with the engaging groove 124c and an inner diameter that fits with the outer peripheral surface of the first detent portion 50a. Therefore, the outer diameter of the retaining member 151 is substantially equal to the second detent portion 50c. In the second embodiment, the retaining member 151 includes a cylindrical body 151a made of synthetic resin such as synthetic rubber or polyacetal. The retaining member 151 has an axial length that can contact the outer peripheral surface of the spool shaft 8. The retaining member 151 has an annular engagement protrusion 151b that is engaged with the annular groove 50d at one end of the inner peripheral surface. The engagement protrusion 151b is elastically locked to the annular groove 50d, so that the retaining member 151 is retained by the non-rotating pin 50. In the second embodiment, the retaining member 151 is attached to the first detent portion 50 a so that the other end of the retaining member 151 contacts the outer peripheral surface of the spool shaft 8.

  A sleeve 52 is mounted between the spool shaft 8 and the mounting cylinder portion 122f in order to ensure compatibility with a conventional spool shaft having a diameter of 4.5 mm. The sleeve 52 has the same configuration as that of the first embodiment.

  The present invention can also be applied to a spool 104 that does not have such a drag mechanism.

<Features>
(A) The spool coupling structure 65 (or the spool coupling structure 165) has a structure in which the spool 4 (or the spool 104) is coupled to the spool shaft 8 that passes through the spool 4 (or the spool 104) of the spinning reel. is there. The spool coupling structure 65 (or the spool coupling structure 165) includes a pin insertion portion 8d, a detent pin 50, a retaining member 51 (or retaining member 151), and an engaging groove 24c (or engaging groove 124c). It is equipped with. The pin insertion portion 8d has a through hole 8c formed through the spool shaft 8 in the radial direction. The anti-rotation pin 50 includes a first anti-rotation portion 50a provided at the first end, a fitting portion 50b, and a second anti-rotation portion 50c. The fitting portion 50b is disposed adjacent to the first detent portion 50a and has a length that fits into the pin insertion portion 8d. The second detent portion 50c extends from the fitting portion 50b toward the second end and has a larger diameter than the pin insertion portion 8d. The retaining member 51 (or retaining member 151) prevents the rotation prevention pin 50 from coming off from the spool shaft 8. The retaining member 51 (or retaining member 151) is disposed on the outer peripheral side of the first detent portion 50a with the second detent portion 50c and the spool shaft 8 interposed therebetween, and has an axial length that can contact the spool shaft 8. have. The engaging groove 24c is formed along the diameter of the spool shaft 8 in the spool shaft 8 penetrating portion of the spool 4 (or the spool 104), and has a groove width that engages with the second detent portion 50c.

  In this spool coupling structure 65 (or spool coupling structure 165), the rotation prevention pin 50 is inserted into the pin insertion portion 8d of the spool shaft 8 from the first end side where the first rotation prevention portion 50a is present. Then, the stepped portion between the large-diameter second detent portion 50c and the pin insertion portion 8d comes into contact with the outer peripheral surface of the spool shaft 8, and the detent pin 50 is positioned. In this state, the first detent portion 50a on the first end side protrudes from the pin insertion portion 8d. A retaining member 51 (or retaining member 151) is attached to the projecting first detent portion 50a, and the detent pin 50 is retained. When the spool 4 (or spool 104) is mounted on the spool shaft 8 with the rotation stopper pin 50 mounted on the spool shaft 8, the engagement groove 24c (or engagement groove 124c) of the spool 4 (or spool 104) rotates. The spool 4 (or spool 104) engages with the stop pin 50 and is connected to the spool shaft 8 while being prevented from rotating.

  Here, the retaining member 51 (or retaining member 151) is attached to the first retaining portion 50a of the retaining pin 50 to prevent the retaining pin 50 from falling off. For this reason, in the rotation prevention pin 50, it is not necessary to form an annular groove for preventing the removal in the vicinity of the outer peripheral surface of the spool shaft 8 where a shearing force is generated. As a result, the strength of the rotation stopper pin 50 can be secured even if the diameter of the rotation prevention pin 50 is reduced.

  (B) In the spool coupling structure 65 (or the spool coupling structure 165), the first detent part 50a has the same outer diameter as the fitting part 50b. In this case, since the fitting portion 50b and the first detent portion 50a have the same outer diameter, the strength of the detent pin is further increased compared to the case where the first detent portion 50a has a smaller diameter than the fitting portion 50b. It can be secured.

  (C) In the spool coupling structure, the retaining member 51 (or retaining member 151) has an outer diameter that engages with the engaging groove 24c (or engaging groove 124c). In this case, since the retaining member 51 (or retaining member 151) has an outer diameter that engages with the engaging groove 24c (or engaging groove 124c), the spool 4 (or spool 104) is It becomes difficult to stick.

  (D) In the spool coupling structure 65, the retaining member 51 has a coil spring 51a that can be mounted on the outer peripheral side of the fitting portion 50b. In this case, the rotation prevention pin 50 can be prevented from coming off by preventing one end of the coil spring 51a from coming off and making the other end free length or compressed to contact the spool shaft 8.

  (E) In the spool coupling structure 65, the rotation prevention pin 50 further includes an annular groove 50d formed on the first end side of the first rotation prevention portion 50a, and the end portion on the first end side of the coil spring 51a is It is formed in a small diameter so that it can be locked in the annular groove 50d. In this case, since the annular groove 50d is formed on the first end side where the shearing force does not act, even if the annular groove 50d is formed, the strength of the small-diameter detent pin 50 is secured and the retaining member 51 is secured. The annular groove 50d can prevent it from coming off.

  (F) The spool connection structure 65 (or the spool connection structure 165) further includes a sleeve 52 that is fitted to the outer peripheral surface of the spool shaft 8 and has a passage hole 52a that communicates with the pin insertion portion 8d. In this case, even if the diameter of the spool shaft 8 is reduced, the spool 4 (or the spool 104) adapted to the large diameter spool shaft can be connected, and compatibility with the spool for the large diameter spool shaft can be ensured. .

  (G) In the spool coupling structure 165, the spool 104 has a bobbin trunk 122a around which a fishing line is wound, and a mounting cylinder 122f provided on the inner peripheral side of the bobbin trunk 122a. The engagement groove 124c is a groove formed in the mounting cylinder portion 122f along the diameter. In this case, the spool 104 and the spool shaft 8 can be coupled together so as to be rotatable or non-rotatable.

  (H) In the spool connection structure 65, the spool 4 has a spool body 22 and a spool cylinder portion 24. The spool body 22 includes a bobbin trunk 22a around which a fishing line is wound, and a mounting cylinder 22f provided on the inner peripheral side of the bobbin trunk 22a. The spool cylinder portion 24 is attached to the spool shaft 8 so as to rotatably support the spool body 22. The engagement groove 24 c is a groove formed along the diameter in the rear end portion 24 b of the spool cylinder portion 24. In this case, since the spool body 22 and the spool cylinder part 24 can be rotated relative to each other, the front drag mechanism 23 can be provided between the spool body 22 and the spool cylinder part 24.

<Other embodiments>
As mentioned above, although one Embodiment of this invention was described, this invention is not limited to the said embodiment, A various change is possible in the range which does not deviate from the summary of invention.

  (A) In the above-described two embodiments, the invention has been described by taking a lever brake type spinning reel as an example, but the spinning reel to which the present invention is applied is not limited thereto. For example, the present invention can be applied to a rear drag type spinning reel and a front drag type spinning reel. In these cases, it is preferable to apply to a spinning reel having a one-touch attachment / detachment mechanism.

  (B) Although the coil spring 51a or the synthetic resin cylindrical body 151a is disclosed as the retaining member 51 (or the retaining member 151) in the two embodiments described above, the retaining member is not limited thereto. For example, a plurality of disc springs, corrugated springs, or O-rings may be used, or a rod-shaped member having a circular hole formed in the center and a polygonal outer shape may be used.

  (C) In the two embodiments, the retaining member 51 (or retaining member 151) is retained by the annular groove 50d formed in the rotation preventing pin 50, but the present invention is not limited to this. For example, without providing the annular groove 50d, it may be prevented from coming off with respect to the first anti-rotation portion 50a of the anti-rotation pin 50 by the elasticity of the anti-detachment member itself. In this case, the inner diameter of the retaining member may be slightly smaller than the outer diameter of the first detent portion.

22 spool body 22a bobbin trunk 22f mounting cylinder (an example of a boss)
23 Front drag mechanism 24 Spool cylinder (an example of a cylindrical member)
24c Engaging groove (an example of a detent groove)
DESCRIPTION OF SYMBOLS 50 Anti-rotation pin 50a 1st anti-rotation part 50b Fitting part 50c 2nd anti-rotation part 50d Annular groove 51 Retaining member 51a Coil spring 51b Mounting part 52 Sleeve 52a Passing hole 65 Spool connection structure 104 Spool 122a Bobbin trunk part 122f Installation cylinder Part (example of boss part)
124c engagement groove (an example of a non-rotating groove)
151 Retaining member 151a Tubular body 151b Engaging protrusion 165 Spool coupling structure

Claims (6)

A spinning reel spool connection structure for connecting the spool to a spool shaft penetrating the spool of the spinning reel while preventing the spool from rotating,
A pin insertion portion having a through hole formed through the spool shaft along the diameter;
A first anti-rotation portion provided at the first end, a fitting portion disposed adjacent to the first anti-rotation portion and having a length for fitting into the pin insertion portion, and a second from the fitting portion A detent pin having a second detent portion extending toward the end and having a larger diameter than the pin insertion portion;
A retaining member disposed on the outer peripheral side of the first detent portion, having an axial length capable of contacting the spool shaft, and retaining the detent pin with respect to the spool shaft;
A detent groove formed along the diameter of the spool shaft in the spool shaft penetrating portion of the spool and having a groove width engaged with the second detent portion ;
The first detent portion has the same diameter as the fitting portion,
The spinning reel spool coupling structure , wherein the retaining member is a coil spring that can be mounted on an outer peripheral side of the first detent portion . The spinning reel spool connection structure according to claim 1, wherein the retaining member has an outer diameter that engages with the detent groove. The detent pin further includes an annular groove formed on the first end side of the first detent portion,
3. The spinning reel spool connection structure according to claim 1, wherein an end of the coil spring on the first end side is formed with a small diameter so as to be able to be locked in the annular groove. The spinning reel spool coupling structure according to any one of claims 1 to 3 , further comprising a sleeve fitted to an outer peripheral surface of the spool shaft and formed with a retaining hole communicating with the pin insertion portion. The spool has a bobbin trunk around which a fishing line is wound, and a cylindrical boss provided on the inner peripheral side of the bobbin trunk,
The detent groove, said a one end is formed along the diameter surface groove of the boss portion, the spool coupling structure of a spinning reel according to any one of claims 1 to 4. The spool has a spool body having a bobbin trunk around which a fishing line is wound, and a cylindrical boss provided on the inner peripheral side of the bobbin trunk,
A cylindrical member mounted on the spool shaft so as to rotatably support the boss portion of the spool body,
The detent groove is a groove formed along a diameter on one end surface of the tubular member, the spool coupling structure of a spinning reel according to any one of claims 1 to 4.

Images