JP6820980B2 - Double bearing reel - Google Patents

Description

The present invention is a double-bearing reel, particularly a double-bearing reel that feeds a fishing line forward.

Both bearing reels are provided with a casting control mechanism that constantly brakes the spool shaft. A double-bearing reel in which an adjusting member of a casting control mechanism is provided on the side opposite to the handle mounting side is known (see, for example, Patent Document 1).

In the conventional double bearing reel, a positioning member (lid member 9) for positioning the spool shaft is provided on the handle side. The positioning member is a bottomed tubular member having an outer peripheral surface and an inner peripheral surface. A boss portion that protrudes in a circle is formed on the handle side of the reel body. The positioning member is fixed by screwing the inner peripheral surface of the positioning member into the boss portion. The adjusting member is screwed into the reel body so that the second end surface opposite to the first end surface can be pressed. In the casting control mechanism, the spool shaft is braked by sandwiching the spool shaft between the adjusting member and the positioning member.

JP 2013-128439

In the conventional double bearing reel, if the positioning member is erroneously rotated, the axial position of the spool shaft shifts. When the axial position of the spool shaft shifts, the spool's bobbin shape changes. Further, when a spool braking mechanism for braking the rotation of the spool in the feeding direction during casting is provided, the braking force may change if the axial position of the spool shaft deviates.

An object of the present invention is to prevent erroneous operation by the user and prevent the axial position of the spool shaft from shifting.

The double-bearing reel according to the present invention is a reel that feeds a fishing line forward. Both bearing reels include a handle for bobbin winding, a reel body, a spool, a spool shaft, a casting control mechanism, and a cover member. The reel main body has a first side plate provided on the handle side and a second side plate arranged so as to face the first side plate at a distance from each other. The spool is arranged between the first side plate and the second side plate, and can be rotated in the thread winding direction by the rotation of the handle. The spool shaft is provided so as to be rotatable integrally with the spool. The casting control mechanism has a rotation operation member. The rotation operation member is rotatably provided on the handle side of the reel body, the spool shaft can be pressed from the handle side, and the cover member whose axial position changes according to the rotation is the rotation operation member. Cover the outer peripheral surface of.

In both bearing reels, in the casting control mechanism, the outer peripheral surface of the rotation operation member is covered with the cover member. Therefore, it becomes difficult for the user to erroneously rotate the rotation operation member, the erroneous operation of the user is prevented, and the axial position of the spool shaft is not displaced.

The reel body may further have a first side cover that covers the outer surface of the first side plate. The first side cover may have a tubular first boss portion that protrudes outward in the axial direction and opens in the axial direction. The rotation operation member is a cap member that is screwed into the outer peripheral surface of the first boss portion to close the axially outer side of the opening, and the cover member may cover the outer peripheral surface of the cap member. According to this configuration, since the screw portion can be formed on the outer peripheral surface of the first boss portion, the rotation operation can be easily attached. Further, since the rotation operation member has a cap shape, the cover member can easily cover the outer peripheral surface of the rotation operation member.

Both bearing reels may further include a drive shaft that can rotate integrally with the handle. The first side cover may have a tubular second boss portion through which the drive shaft penetrates and projects outward in the axial direction. The cover member may be fitted and mounted on the second boss portion. According to this configuration, the cover member can be prevented from rotating at the first boss portion and the second boss portion, and the cover member can be positioned.

The casting control mechanism may further have a plate whose axial position changes according to the rotation of the rotation operating member. The rotation operating member may press the spool shaft from the handle side via the plate.

According to the present invention, it becomes difficult to erroneously rotate the positioning member, erroneous operation by the user is prevented, and the axial position of the spool shaft is prevented from shifting.

A side view of both bearing reels according to an embodiment of the present invention. The cross-sectional view cut by the cutting line II-II of FIG. A side view of the first side cover and the cover member. The perspective view of the 1st side cover and the cover member. An exploded perspective view of the first side cover and the positioning member. The figure corresponding to FIG. 3 of the 1st modification. The figure corresponding to FIG. 2 of the 2nd modification. The figure corresponding to FIG. 2 of the 3rd modification.

<Overall configuration of both bearing reels>
In FIGS. 1 and 2, the double bearing reel 10 according to the embodiment of the present invention is a low profile type reel that feeds a fishing line forward. The double bearing reel 10 includes a handle 12 for winding a thread, a reel body 14, a spool 16, a spool shaft 18, a casting control mechanism 20, a cover member 22, a drive shaft 24, and a spool braking mechanism 26. Be prepared. The spool shaft 18 has a first end surface 18a on the handle 12 side and a second end surface 18b on the opposite side of the handle 12.

<Handle>
As shown in FIG. 1, the handle 12 is integrally rotatably connected to the tip of the drive shaft 24. The handle 12 has a handle arm 12a rotatably connected to the drive shaft 24, and a handle operating portion 12b rotatably connected to one end or both ends of the handle arm 12a.

<Reel body>
As shown in FIG. 2, the reel body 14 includes a frame 30, a first side cover 32 that covers the handle 12 side of the frame 30, and a second side cover 34 that covers the side opposite to the handle 12 of the frame 30. Have. The frame 30 has a second side plate 30b on which the spool 16 can be arranged between the first side plate 30a and the first side plate 30a provided on the handle 12 side. The first side plate 30a is provided with a through hole 30c through which the spool shaft 18 penetrates and a drive shaft support portion 30d that supports the drive shaft 24. The second side plate 30b has a side plate main body 35 having a stepped opening 35a through which the spool 16 can pass, and a shaft support portion 36 detachably provided in the opening 35a. The first side plate 30a and the side plate main body 35 are connected by a plurality of integrally formed connecting members 30e.

The shaft support portion 36 is rotatably supported by the second side cover 34 while sandwiching the second side cover 34. The shaft support portion 36 is prevented from coming off from the second side cover 34. Further, the shaft support portion 36 is detachably attached to the side plate main body 35 by a known bayonet mechanism (not shown).

The shaft support portion 36 sandwiches the second side cover 34 relative to each other between the bearing mounting portion 36a on which the second bearing 42b supporting the second end portion 18d of the spool shaft 18 is mounted and the bearing mounting portion 36a. It has a detachable operation unit 36b and a detachable operation unit 36b. The bearing mounting portion 36a is a dish-shaped member, and the outer peripheral portion 36c fits into the opening 35a of the second side plate 30b. A bayonet mechanism is provided between the outer peripheral portion of the bearing mounting portion 36a and the opening 35a. At the center of the bearing mounting portion 36a, a tubular bearing accommodating portion 36d for accommodating the second bearing 42b is formed so as to project in a tubular shape toward the spool 16. Inside the bearing housing portion 36d, a disc-shaped second plate 54b constituting the casting control mechanism 20 is mounted. A screw hole 36e into which an adjusting member 52 described later of the casting control mechanism 20 is screwed is formed at the bottom of the bearing housing portion 36d. The attachment / detachment operation portion 36b can rotate integrally with the bearing mounting portion 36a with respect to the second side cover 34 in a state of being positioned on the bearing mounting portion 36a.

The first side cover 32 covers the outer surface of the first side plate 30a. As shown in FIG. 5, the first side cover 32 is arranged at a distance in front of and below the first boss portion 32a and the tubular first boss portion 32a projecting outward in the axial direction. It has a tubular second boss portion 32b that protrudes toward the surface. The inner circumference of the first boss portion 32a opens toward the first end surface 18a of the spool shaft 18. A first bearing 42a that rotatably supports the first end portion 18c on the first end surface 18a side of the spool shaft 18 is mounted on the inner peripheral surface of the first boss portion 32a. On the outer peripheral surface of the first boss portion 32a, a male screw portion 32c and an annular seal groove 32d for mounting an O-ring 72 for sealing are formed. The second boss portion 32b has a larger diameter than the first boss portion 32a, and is configured so that the drive shaft 24 penetrates therethrough. A one-way roller clutch 44 that rotates the drive shaft 24 only in the thread winding direction is provided on the inner peripheral surface of the second boss portion 32b.

The second side cover 34 covers the outer surface of the second side plate 30b. The second side cover 34 has a circular recess 34a and an opening 34b in the center. The shaft support portion 36 is rotatably mounted on the second side cover 34. The second side cover 34, together with the shaft support portion 36, is removable from the frame 30.

<Spool>
The spool 16 is a member made of a conductor such as an aluminum alloy. The spool 16 is arranged between the first side plate 30a and the second side plate 30b, and can be rotated in the thread winding direction by the rotation of the handle 12. The spool 16 has a spool body portion 16a around which a fishing line is wound, and a pair of flange portions 16b formed with a large diameter at both ends of the spool body portion 16a. One flange portion 16b is arranged in the opening 35a.

<Spool shaft>
The spool shaft 18 is provided so as to be rotatable integrally with the spool 16. As described above, in the spool shaft 18, the first end portion 18c on the first end surface 18a side is supported by the first boss portion 32a via the first bearing 42a, and the second end portion 18d on the second end surface 18b side is supported. It is supported by the bearing housing portion 36d via the second bearing 42b. The first end surface 18a and the second end surface 18b are each formed on a spherical surface.

<Casting control mechanism>
As shown in FIG. 2, the casting control mechanism 20 includes a positioning member 50, an adjusting member 52, a first plate 54a, and a second plate 54b. The positioning member 50 is detachably provided on the first boss portion 32a of the first side cover 32. As shown in FIGS. 2 and 5, the positioning member 50 can be screwed into the male screw portion 32c formed on the outer peripheral surface of the first boss portion 32a to position the first end surface 18a of the spool shaft 18. The positioning member 50 is tightened to the first boss portion 32a so that the bottom portion contacts the tip surface of the first boss portion 32a. The positioning member 50 is a bottomed tubular cap member that closes the opening of the first boss portion 32a. The positioning member 50 has a large-diameter flange portion 50a on the outer peripheral portion of the opening. The flange portion 50a is configured to face the outer surface of the first side cover 32 on which the first boss portion 32a protrudes with a gap in the state where the positioning member 50 is tightened. A plate-shaped first plate 54a in contact with the first end surface 18a is mounted inside the positioning member 50. As described above, the second plate 54b is provided inside the bearing accommodating portion 36d of the shaft support portion 36.

The adjusting member 52 is screwed into either the second side plate 30b or the second side cover 34. In the present embodiment, the adjusting member 52 is screwed into the second side plate 30b. Specifically, the adjusting member 52 has a screw shaft 52a screwed into a screw hole 36e provided at the bottom of the bearing housing portion 36d of the shaft support portion 36 constituting the second side plate 30b. Further, the adjusting member 52 has a circular operation knob 52b for turning the screw shaft 52a. The adjusting member 52 can press the second end surface 18b on the side opposite to the first end surface 18a of the spool shaft 18. The casting control mechanism 20 sandwiches the spool shaft 18 between the adjusting member 52 and the positioning member 50, and constantly brakes the spool shaft 18. The adjusting member 52 can adjust the braking force acting on the spool shaft 18 by rotating the spool shaft 18. The operation knob 52b of the adjusting member 52 is arranged in the recess 34a of the second side cover 34 and does not protrude from the second side cover 34. As a result, the adjusting member 52 also becomes difficult to rotate unexpectedly, and the spool shaft 18 becomes more difficult to move in the axial direction.

<Cover member>
The cover member 22 is, for example, a member made of synthetic resin. The cover member 22 is arranged on the outer surface of the first side cover 32 as shown in FIGS. 2, 3, 4, and 5. The cover member 22 is provided so that the positioning member 50 cannot be easily operated by the user. This is because when the positioning member 50 is rotated and the axial position of the spool shaft 18 changes, the bobbin shape of the spool 16 changes and the braking force at each adjustment position of the spool braking mechanism 26 changes. .. The cover member 22 has a cover portion 22a that covers the outer peripheral surface of the cap member as the positioning member 50, and a mounting portion 22b that is fitted and mounted on the second boss portion 32b. As shown in FIG. 2, the cover portion 22a comes into contact with the flange portion 50a of the positioning member 50 to prevent the positioning member 50 from coming off. By covering the positioning member 50 with the cover portion 22a of the cover member 22 in this way, the user cannot easily operate the positioning member 50. As shown in FIG. 5, the mounting portion 22b has a larger diameter than the cover portion 22a. The mounting portions 22b include a fitting hole 22c that is fitted to the outer peripheral surface of the second boss portion 32b and fitted to the second boss portion 32b, and a plurality (for example, two) for fixing to the first side cover 32. ) With a fixed boss 22d. The screw member 74 is screwed into the fixed boss 22d through the first side cover 32. As a result, the cover member 22 is detachably attached to the outer surface of the first side cover 32. The cover member 22 may be used, for example, as a name plate on which the model number, company name, logo, etc. of both bearing reels 10 are printed.

<Drive shaft>
As shown in FIG. 2, the drive shaft 24 is provided to transmit the rotation of the handle 12 to the spool 16. The drive shaft 24 transmits the rotation of the handle 12 to the spool 16 via a known drag mechanism 54, drive gear 56, pinion gear 58, and clutch mechanism 60.

<Spool braking mechanism>
As shown in FIG. 2, the spool braking mechanism 26 is configured to brake the rotation of the spool 16 in the thread feeding direction opposite to the thread winding direction during casting. The spool braking mechanism 26 of the present embodiment mechanically brakes the spool 16 by centrifugal force. The spool braking mechanism 26 includes a first braking member 62, a second braking member 64, and an adjusting mechanism 66. The first braking member 62 can rotate integrally with the spool 16. The second braking member 64 is provided on the second side plate 30b and brakes the first braking member 62. The adjusting mechanism 66 is configured to adjust the braking force of the second braking member 64. The first braking member 62 has a support member 68 that is integrally rotatably connected to the spool shaft 18, and a braking shoe 70 that is swingably supported by the support member 68 around an axis that is inconsistent with the spool shaft 18. The braking shoe 70 swings due to centrifugal force. The second braking member 64 constitutes a brake drum 64a that can come into contact with the braking shoe 70. The brake drum 64a is screw-engaged or cam-engaged with the bearing housing portion 36d and moves in the axial direction by rotation. The adjusting mechanism 66 can adjust the braking force in a plurality of stages by moving the brake drum 64a in the spool axial direction by a screw or a cam mechanism. The adjustment mechanism 66 is rotated by a rotation operation of an adjustment knob (not shown) connected by a gear, and adjusts the axial position of the brake drum 64a in a plurality of stages. The adjustment knob is rotatably attached to the shaft support portion 36, is exposed from the second side cover 34, and is provided so as to be operable from the outside.

In the double bearing reel 10 configured in this way, the positioning member 50 is covered by the cover member 22 so that the user cannot operate it. Therefore, it becomes difficult to rotate the positioning member 50 by mistake, and the axial position of the spool shaft 18 does not shift. As a result, the change in the bobbin shape of the spool 16 and the change in the braking force of the spool braking mechanism 26 at each stage, which are caused by the displacement of the spool shaft 18 in the axial direction, are less likely to occur.

<First modification>
In the following description of the modified example, the same reference numerals as those in the above-described embodiment are attached to the members having the same configuration as the above-described embodiment, and the description thereof will be omitted. The corresponding members, which have different configurations, are marked with a three-digit code having the same last two digits.

In the above embodiment, the cover member 22 has the cover portion 22a and the mounting portion 22b, but in the first modification shown in FIG. 6, the cover member 122 has only the cover portion 122a. There is no mounting part. Similar to the above embodiment, the cover portion 122a is detachably attached to the outer surface of the first side cover 32 by an appropriate fixing means such as elastic engagement or screwing. Even with the double bearing reel 110 having such a configuration, the same operation and effect as those of the above-described embodiment can be obtained.

<Second modification>
In the double bearing reel 210 of the second modification shown in FIG. 7, the spool braking mechanism 226 mechanically brakes the spool 16 by a magnetic force. The spool braking mechanism 226 includes a first braking member 262 made of a conductor, a second braking member 264, and an adjusting mechanism 266. The first braking member 262 is a part of the spool 16 in the second modification, and specifically, is the inner peripheral surface of the bobbin body 16a of the spool 16. The second braking member 264 is at least one magnet 264a provided on the second side plate 30b so that the positional relationship with a part of the spool 16 in the spool axial direction can be changed. The magnet 264a is fixed to the outer peripheral surface of the tubular moving member 270 that is cam-engaged with the adjusting mechanism 266. The moving member 270 moves in the spool axial direction by the rotation of the adjusting mechanism 266. The adjustment mechanism 266 is connected by a gear to an adjustment knob (not shown) rotatably supported by the shaft support portion 36. The adjusting mechanism 266 rotates according to the rotation of the adjusting knob, and the braking force can be adjusted in a plurality of stages. Even with the double-bearing reel 210 having such a configuration, the spool shaft 18 is unlikely to shift in the axial direction. Therefore, even if the magnet 264a is moved in the axial direction by the adjusting mechanism 266, the braking force adjusted at the moving position fluctuates. It becomes difficult to do.

<Third modification example>
In the double bearing reel 310 of the third modification shown in FIG. 8, the spool braking mechanism 326 is an electrically controllable mechanism. The spool braking mechanism 326 includes a first braking member 362, a second braking member 364, and an adjusting mechanism 366. The first braking member 362 is a magnet 362a that has a plurality of magnetic poles and can rotate integrally with the spool 16. The magnet 362a is a tubular bond magnet, which is integrally rotatably connected to the spool shaft 18. The second braking member 364 is a plurality of coils 364a provided so as to face the magnet 362a and immovably with respect to the second side plate 30b. The adjusting mechanism 366 adjusts the braking force by electrically controlling the current flowing through the coil 364a, for example, by a switching element. The adjusting mechanism 366 includes a circuit board 366a including a control unit including a microcomputer. Even in the double bearing reel 310 having such a configuration, the spool shaft 18 is less likely to be displaced in the axial direction, so that the axial positions of the magnet 362a and the coil 364a are less likely to be displaced. Therefore, even if the current flowing through the coil 364a is controlled by the adjusting mechanism 366, the current can be controlled with high accuracy, and the adjusted braking force is less likely to fluctuate.

<Other embodiments>
Although one embodiment of the present invention has been described above, the present invention is not limited to the above embodiment, and various modifications can be made without departing from the gist of the invention. In particular, the plurality of embodiments and modifications described in the present specification can be arbitrarily combined as required.

(A) In the above embodiment and the modified example, the adjusting member 52 is screwed into the second side plate 30b, but the adjusting member may be screwed into the second side cover 34. In this case as well, the operation knob of the adjusting member may be configured so as not to protrude from the second side cover 34.

(B) In the above-described embodiment and modification, the cover member 22 does not cover the bottom surface of the positioning member 50, but the cover member may cover the bottom surface of the positioning member 50.

(C) In the above embodiment and the modified example, the adjusting member 52 is configured so as not to protrude from the second side cover 34, but the adjusting member may be arranged so as to protrude from the second side cover.

(D) In the above embodiment and the modified example, the cover member 22 is detachably attached to the first side cover 32 by the screw member 74, but the attachment means is not limited to screwing, and for example, elasticity such as snap fit. It may be attached by engagement.

(E) In the above-described embodiment and modification, both bearing reels 10 (or 110, 210) having a spool braking mechanism 26 (or 226,326) whose braking force changes when the spool shaft 18 moves in the axial direction are disclosed. However, the double bearing reel according to the present invention is not limited to this. The present invention can also be applied to both bearing reels in which the braking force does not change even if the spool shaft moves in the axial direction. In this case, fluctuations in the spool shape can be suppressed.

<Features>
The above embodiment can be expressed as follows.

(A) Both bearing reels 10 (or 110, 210) are reels for feeding fishing line forward. Both bearing reels 10 (or 110, 210) include a handle 12 for winding a thread, a reel body 14, a spool 16, a spool shaft 18, a casting control mechanism 20, and a cover member 22. The reel body 14 has a frame 30 and a first side cover 32, and the spool 16 is rotatably mounted. The frame 30 has a first side plate 30a provided on the handle 12 side and a second side plate 30b arranged so as to face the first side plate 30a at a distance from each other. The first side cover 32 covers the outer surface of the first side plate 30a. The spool 16 is arranged between the first side plate 30a and the second side plate 30b, and can be rotated in the thread winding direction by the rotation of the handle 12. The spool shaft 18 is provided so as to be rotatable integrally with the spool 16. The casting control mechanism 20 includes a positioning member 50 and an adjusting member 52. The positioning member 50 is screwed into the first side cover 32 and can position the first end surface 18a of the spool shaft 18. The adjusting member 52 is screwed into either the second side plate 30b or the second side cover 34, and can press the second end surface 18b on the side opposite to the first end surface 18a of the spool shaft 18. The adjusting member 52 brakes the spool shaft 18 together with the positioning member 50, and the braking force acting on the spool shaft 18 can be adjusted. The cover member 22 is arranged on the outer surface of the first side cover 32 and covers the outer peripheral surface of the positioning member 50.

In both bearing reels 10 (or 110, 210), in the casting control mechanism 20, the spool shaft 18 is sandwiched between the adjusting member 52 and the positioning member 50, and the spool shaft 18 is braked. The outer peripheral surface of the positioning member 50 is covered by the cover member 22 arranged on the outer surface of the first side cover 32. Therefore, it becomes difficult for the user to erroneously rotate the positioning member 50, the erroneous operation of the user is prevented, and the axial position of the spool shaft 18 is prevented from shifting.

(B) The first side cover 32 may have a tubular first boss portion 32a whose inner circumference opens toward the first end surface 18a and projects outward in the axial direction. The positioning member 50 is a cap member that closes the opening, and the cover member 22 may cover the outer peripheral surface of the cap member. According to this configuration, the male screw portion 32c can be formed on the outer peripheral surface of the first boss portion 32a, so that the positioning member 50 can be easily attached. Further, since the positioning member 50 has a cap shape, the cover member 22 can easily cover the outer peripheral surface of the positioning member 50.

(C) The first boss portion 32a may be provided with a first bearing 42a that rotatably supports the spool shaft 18 on the inner peripheral surface. According to this configuration, the positioning member 50 can be positioned and the spool shaft 18 can be supported by the first boss portion 32a.

(D) Both bearing reels 10 (or 110, 210) may further include a drive shaft 24 that can rotate integrally with the handle 12. The first side cover 32 may have a tubular second boss portion 32b through which the drive shaft 24 penetrates and projects outward in the axial direction. The cover member 22 may be fitted and mounted on the second boss portion 32b. According to this configuration, the cover member 22 can be prevented from rotating by the first boss portion 32a and the second boss portion 32b, and the cover member 22 can be positioned.

(E) The second side plate 30b may have a screw hole 36e penetrating toward the second end surface 18b of the spool shaft 18, and the adjusting member 52 may have a screw shaft 52a screwed into the screw hole 36e. .. According to this configuration, since the adjusting member 52 is screwed into the screw hole 36e, the adjusting member 52 can be compactly configured and the protrusion from the reel main body 14 can be suppressed.

(F) The reel body 14 may further have a second side cover 34 that covers the outer surface of the second side plate 30b. The adjusting member 52 may not protrude from the second side cover 34. According to this configuration, a feeling of strangeness during palming is less likely to occur, and the rotation position of the adjusting member 52 is less likely to change unexpectedly.

(G) The double-bearing reel 10 (or 110, 210) may further include a spool braking mechanism 26 that brakes the rotation of the spool 16 in the thread feeding direction opposite to the thread winding direction. The spool braking mechanism 26 is controlled by a first braking member 62 that can rotate integrally with the spool 16, a second braking member 64 that is provided on the second side plate 30b and brakes the first braking member 62, and a second braking member 64. It has an adjusting mechanism 66 configured to adjust the power. According to this configuration, the spool shaft 18 is less likely to shift in the axial direction, so that the braking force can be stabilized.

(H) The first braking member 62 may be a braking shoe 70 that moves by centrifugal force. The second braking member 64 may be a brake drum 64a that can come into contact with the braking shoe 70. The adjusting mechanism 66 may adjust the braking force by moving the brake drum 64a in the direction of the spool axis. According to this configuration, since the spool shaft 18 is less likely to shift in the axial direction, the adjusted braking force is less likely to fluctuate even if the brake drum 64a is moved in the axial direction by the adjusting mechanism 66.

(I) The spool 16 may have a spool body portion 16a and a pair of flange portions 16b formed on both ends of the spool body portion 16a with a large diameter. The first braking member 262 may be a part of the spool 16 made of a conductor. The second braking member 264 may be at least one magnet 264a provided on the second side plate 30b so that the positional relationship with a part of the spool 16 in the spool axial direction can be changed. The adjusting mechanism 266 may adjust the braking force by moving the magnet 264a in the direction of the spool axis. According to this configuration, since the spool shaft 18 is less likely to shift in the axial direction, even if the magnet 264a is moved in the axial direction by the adjusting mechanism 266, the braking force adjusted at the moving position is less likely to fluctuate.

(J) The first braking member 362 may be a magnet 362a that has a plurality of magnetic poles and can rotate integrally with the spool 16. The second braking member 364 may be a plurality of coils 364a provided so as to face the magnet 362a and immovably with respect to the second side plate 30b. The adjusting mechanism 366 may adjust the braking force by electrically controlling the current flowing through the coil 364a. According to this configuration, the spool shaft 18 is less likely to be displaced in the axial direction, so that the axial positions of the magnet 362a and the coil 364a are less likely to be displaced. Therefore, even if the current flowing through the coil 364a is controlled by the adjusting mechanism 366, the current can be controlled with high accuracy, and the adjusted braking force is less likely to fluctuate.

10, 110, 210 Double bearing reel 12 Handle 14 Reel body 16 Spool 16a Thread winding body 18 Spool shaft 18a First end surface 18b Second end surface 20 Casting control mechanism 22 Cover member 24 Drive shaft 26, 226, 326 Spool braking mechanism 30 frame 30a 1st side plate 30b 2nd side plate 32 1st side cover 32a 1st boss part 32b 2nd boss part 32c Male screw part 34 2nd side cover 36e Thread hole 42a 1st bearing 50 Positioning member 52 Adjusting member 52a Screw shaft 62,262 , 362 1st braking member 64,264,364 2nd braking member 64a Brake drum 264a Magnet 66,266,366 Adjustment mechanism 70 Braking shoe 366a Coil

Claims (4)

A double-bearing reel that feeds fishing line forward.
Handle for thread winding and
A reel body having a first side plate provided on the handle side and a second side plate arranged so as to face the first side plate at a distance from each other.
A spool arranged between the first side plate and the second side plate and rotatable in the thread winding direction by the rotation of the handle.
A spool shaft that is integrally rotatable on the spool and
A casting control mechanism having a rotation operating member rotatably provided on the handle side of the reel body, capable of pressing the spool shaft from the handle side, and changing its axial position according to rotation. ,
A cover member mounted and fixed to the reel body so as to cover the outer peripheral surface of the rotation operation member,
Both bearing reels. The reel body further has a first side cover that covers the outer surface of the first side plate.
The first side cover has a tubular first boss portion that protrudes outward in the axial direction and opens in the axial direction.
The rotation operation member is a cap member that is screwed onto the outer peripheral surface of the first boss portion to close the axially outer side of the opening.
The cover member covers the outer peripheral surface of the cap member.
The double bearing reel according to claim 1. Further equipped with a drive shaft that can rotate integrally with the handle,
The first side cover has a tubular second boss portion through which the drive shaft penetrates and projects outward in the axial direction.
The cover member is fitted and mounted on the second boss portion.
The double bearing reel according to claim 2. The casting control mechanism further includes a plate whose axial position changes according to the rotation of the rotation operating member.
The rotation operating member presses the spool shaft from the handle side via the plate.
The double bearing reel according to any one of claims 1 to 3.