JP2006246794A - Drag control member attachment structure - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a drag control member attachment structure reducing the dispersion of a contacting part between a guide part and a reel body. <P>SOLUTION: The portions of total four portions of the first and second contact portions 37c1 and 37c2, and two portions 37a31 and 37a61 of the third and sixth inner periphery portions 37a3 and 37a6 contact with the outer periphery face of a guide member 17 when a drag control member 2 is operated to the direction in which the drag force is strengthened. On the other hand, when turned and operated in the reverse direction, only two portions 37a32 and 37a62 of the fourth and first inner periphery sides of the third and sixth inner periphery portions 37a3 and 37a6 contact with the outer periphery face of the guide member 17. As a result, the number of the contact parts is stabilized, and the dispersion of the contact parts of the guide member 17 of a hexagonal part with the hexagonal recessed part 37 of a guide fixing part 39 can be reduced. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an attachment structure, and more particularly to an attachment structure of a drag operation member of a lever drag reel that is swingably attached to a side portion of a reel body of a lever drag reel and adjusts a drag force of a drag mechanism.

As a lever drag reel, there is known a reel capable of adjusting a drag force by moving a spool shaft in an axial direction by a drag operation member mounted so as to be swingable around the spool shaft (for example, see Patent Document 1). The base end of this type of drag operation member is swingably supported by a swing support portion formed on the cover member of the reel body so as to protrude concentrically with the spool shaft. In addition, a cam mechanism that moves in the axial direction in response to swinging is provided at the base end of the drag operation member. The cam mechanism includes a first cam portion provided on the drag operation member, and a second cam portion that engages with the first cam portion and moves in the swing shaft (spool shaft) direction in conjunction with the swing of the drag operation member. And have. On the inner peripheral side of the swing support portion of the reel body, there is provided a guide portion for mounting the second cam portion so that it cannot rotate but can move in the axial direction. The guide portion is integrally formed with the swing support portion in a hexagonal appearance on the inner peripheral side of the swing support portion in order to receive and disperse the force in the rotational direction on many surfaces.
Japanese Patent Laid-Open No. 11-9157

  When the cover member of the reel body is molded, a hexagonal guide portion can be formed at the same time as the cover member is formed. However, when the reel body such as the cover member is formed of a machined metal member, if the hexagonal guide member is integrally formed by cutting, the processing cost increases. Therefore, it is conceivable that the guide portion is formed separately and fixed to the reel body by, for example, caulking. In this case, since the guide portion has to guide the second cam portion so as not to rotate, the guide portion must be fixed to the reel body so as not to rotate. Therefore, it is conceivable to fix the guide portion to the reel body so as not to rotate using a hexagonal appearance. In this case, a hexagonal concave portion may be formed in the reel body, and a guide portion may be engaged therewith. When a hexagonal recess is formed by machining using a tool, it is difficult to form an accurate hexagon because the tool (end mill) for forming the recess is a cylindrical tool. For this reason, the number of contact portions between the inner peripheral surface of the concave portion and the outer peripheral surface of the guide portion varies and is not stable. When the number of the contact portions is reduced, the load is concentrated in the vicinity of the hexagonal corner portion, the portion is deformed, and the fixed portion may be rattled.

  An object of the present invention is to reduce variations in contact portions between a hexagonal guide portion and a reel body in a drag operation member mounting structure.

  The attachment structure of the drag operation member according to the first aspect of the present invention is an attachment structure of the drag operation member that is swingably attached to the side of the reel body of the lever drag reel and adjusts the drag force of the drag mechanism. Part, a guide part, a guide fixing part, and a rocking | fluctuation support part. The second cam portion is engaged with the first cam portion provided on the drag operation member and moves in the swing axis direction in conjunction with the swing of the drag operation member. The guide portion is arranged adjacent to the hexagonal portion having a hexagonal portion having first to sixth outer peripheral surfaces for guiding the second cam portion so that the second cam portion cannot rotate with respect to the reel body and is movable in the swing axis direction. And a cylindrical portion having a smaller diameter than the inscribed circle. The guide fixing portion is provided on a side portion of the reel body, and has a hexagonal concave portion into which the hexagonal portion of the guide portion is fitted and a through hole into which the cylindrical portion is fitted, and the guide portion is fixed. The hexagonal recess includes a first outer peripheral surface and a fourth outer peripheral surface facing the first outer peripheral surface with a gap between each of the first and fourth inner peripheral surfaces and a second outer peripheral surface adjacent to the first outer peripheral surface. A first contact portion disposed so as to be in contact with the first portion on the first outer peripheral surface side of the surface and a second portion on the third outer peripheral surface side adjacent to the second outer peripheral surface with a gap from the second outer peripheral surface. A second inner peripheral surface having a first separating portion disposed, a third outer peripheral surface and a third outer peripheral surface disposed to be in contact with the sixth outer peripheral surface facing the third outer peripheral surface; 5th outer periphery in 4th part of the 6th outer peripheral surface side which contacted the 2nd contact part which can contact the 3rd part of the 4th outer peripheral surface side of the 5th outer peripheral surface adjacent to 4 outer peripheral surface, and 5th outer peripheral surface And a fifth inner peripheral surface having a second separating portion disposed with a gap from the surface, and the first to sixth inner peripheral surfaces are dragged by a drag operation member. Are arranged side by side along the swinging direction becomes strong. The swing support portion is provided on the reel body on the outer peripheral side of the guide fixing portion, and supports the drag operation member in a swingable manner.

  In this mounting structure, the guide portion is fixed to a guide fixing portion formed on the side portion of the reel body. Then, the second cam portion is mounted on the fixed guide portion so as not to rotate and is movable in the axial direction, and the drag operation member is swingably mounted on the swing support portion disposed on the outer peripheral side of the guide portion. When the drag operation member swings, the first cam portion swings and the second cam portion moves in the axial direction. The drag length can be adjusted by transmitting the movement of the second cam portion to the spool shaft or the spool. When the drag operating member is operated in a direction to increase the drag force by moving the spool shaft or the spool, a large force acts in the swing direction between the first cam portion and the second cam portion. Also, when operating in the reverse direction, a very large force does not act in the swinging direction. Further, when trying to form a hexagonal recess with a tool, it is difficult to accurately form a hexagonal recess since the tool is usually formed in a cylindrical shape. Therefore, in the present invention, the first and fourth inner peripheral portions of the hexagonal recess are separated from the outer peripheral surface of the hexagonal guide portion so that the portions are not prevented from rotating. Further, the second and fifth inner peripheral portions adjacent to the first and fourth inner peripheral portions are in contact with the first and third portions of the second and fifth outer peripheral portions on the first and fourth inner peripheral portion sides. First and second contact portions are formed, and first and second separation portions that are separated from the second and fourth portions of the second and fifth outer peripheral portions are formed on the third and sixth inner peripheral portion sides. . The third and sixth inner peripheral portions adjacent to the second and fifth inner peripheral portions are in contact with the third and sixth inner peripheral portions. Here, the first inner periphery and the fourth inner periphery are separated from the first and second outer periphery, and the first and second separation portions are provided on the second inner periphery and the fifth inner periphery. Thus, even if a cylindrical tool is used, the tool can be released at that portion, and the first and second contact portions and the third and sixth inner peripheral portions are connected to the hexagonal second and fifth outer peripheral portions. Machining can be accurately performed along the first and third portions and the third and sixth outer peripheral portions. Further, since the first and second contact portions are arranged on the upstream side of the swing direction in which a stronger force in the swing direction acts on the guide portion, the drag operation member is swung in the swing direction. In addition, the number of contact portions in contact with each other is larger than the number of contact portions in the reverse direction. Specifically, when the drag operation member is operated in the direction in which the drag force is increased, the first and second contact portions and the second and fifth inner peripheral portions of the third and sixth inner peripheral portions are two. A total of four portions of the portions are in contact with the outer peripheral surface of the guide portion. On the other hand, when the swinging operation is performed in the reverse direction, the outer peripheral surface of the guide portion is brought into contact with only the two portions of the third and sixth inner peripheral portions on the fourth and first inner peripheral portion sides. For this reason, the number of contact portions is stabilized, and variations in contact portions between the hexagonal guide portion and the reel body can be reduced.

  According to a second aspect of the present invention, there is provided the drag operation member mounting structure according to the first aspect, wherein the first cam member has a plurality of cam pins arranged along the radial direction of the swing shaft, and the second cam member is And an inclined cam having an inclined surface inclined along the circumferential direction so as to be engaged with the cam pin, and a hexagonal hole which is disposed on the inner peripheral portion and engages the guide portion so as to be axially movable and non-rotatable. In this case, the first cam member is constituted by a cam pin provided on the peripheral portion without the drag operation member, and the second cam member is constituted by an inclined surface formed along the circumferential direction so as to be engaged therewith. Therefore, the cam structure can be simplified as compared with the case where both are constituted by inclined surfaces.

  According to a third aspect of the present invention, there is provided the drag operation member mounting structure according to the second aspect, wherein the hexagonal portion connects the adjacent outer peripheral surfaces of the first to sixth outer peripheral surfaces with an arc centered on the pivot axis. The second cam member further includes a circular hole that is formed adjacent to the hexagonal hole in the inner peripheral portion and into which the arc portion can be fitted. In this case, even if the hexagonal hole is formed with a short length by, for example, press molding, the six arc portions can be fitted into the circular hole, so that rattling of the second cam member can be suppressed. it can.

  The attachment structure of the drag operation member according to a fourth aspect of the present invention is the structure according to any one of the first to third aspects, wherein the first separation portion of the second inner peripheral surface and the second separation portion of the fifth inner peripheral surface are respectively It is formed in an arc shape. In this case, when forming a hexagonal recess using a cylindrical tool, a stand. And it is easy to form the 2nd separation part.

  According to a fifth aspect of the present invention, there is provided the drag operating member mounting structure according to any one of the first to fourth aspects, wherein the cylindrical portion of the guide portion projects through the through hole and protrudes into the reel body, and the inner peripheral surface is first. The guide portion has a caulking portion formed by an expanded tapered surface, and the guide portion is caulked and fixed to the reel body by caulking the caulking portion protruding from the through hole toward the inner wall of the reel body. In this case, since the guide portion is fixed to the reel body by caulking, the fixing structure of the guide portion is simplified compared to a fastening structure using screws.

  According to the present invention, the first inner periphery and the fourth inner periphery are separated from the first and second outer periphery, and the first and second separation are performed on the second inner periphery and the fifth inner periphery. By providing the part, even if a cylindrical tool is used, the tool can be released at that part. Therefore, the first and second contact portions and the third and sixth inner peripheral portions are arranged along the first and second portions of the hexagonal first and fourth outer peripheral portions and along the third and sixth outer peripheral portions. Can be machined more accurately. In addition, since the first and second contact portions are arranged on the upstream side in the swing direction of the second and fifth inner peripheral portions where a stronger force in the swing direction acts on the guide portion, When the operating member is swung, the number of contact portions that come into contact is greater than the number of contact portions in the reverse direction. Specifically, when the drag operation member is operated in the direction in which the drag force is increased, the first and second contact portions and the two portions on the second and fifth inner peripheral sides of the third and sixth inner peripheral portions A total of four portions are in contact with the outer peripheral surface of the guide portion. On the other hand, when the rocking operation is performed in the reverse direction, the outer peripheral surface of the guide portion comes into contact only with the two portions on the fourth and first inner peripheral sides of the third and sixth inner peripheral portions. For this reason, the number of contact portions is stabilized, and variations in contact portions between the hexagonal guide portion and the reel body can be reduced.

  As shown in FIGS. 1 and 2, the dual-bearing reel according to the embodiment of the present invention is a medium lever drag type, and is disposed so as to be swingable on the reel body 1 and the side of the reel body 1. A drag operation member 2, a handle 3 rotatably supported by the reel body 1 below the drag operation member 2, and a spool 4 disposed inside the reel body 1.

<Structure of reel body>
The reel body 1 includes a frame 10 and first and second side covers 13a and 13b that cover the frame 10 on both sides. The frame 10 includes a pair of left and right first and second side plates 11a and 11b and a plurality of connecting portions 12 that connect the first and second side plates 11a and 11b. The first and second side plates 11a and 11b are members having a substantially circular shape when viewed from the side, and the diameter of the second side plate 11b is formed to be larger than the diameter of the first side plate 11a. For example, the diameter of the second side plate 11b ranges from 110% to 140% of the diameter of the first side plate 11a. In this embodiment, the diameter is 110% to 120% of the diameter of the first side plate 11a. The plurality of connecting portions 12 are integrally formed with the first and second side plates 11a and 11b, and the lower connecting portion 12 is used for mounting the reel to the fishing rod RD as shown in FIGS. Long metal heel mounting legs 7 are fixed to the front and rear. A rod clamp 8 that sandwiches the fishing rod RD is disposed opposite to the rod mounting leg portion 7.

  As shown in FIGS. 1 and 2, the first side cover 13a is a substantially circular member that is attached to the side of the first side plate 11a in a side view. As shown in FIGS. 1 to 3, the second side cover 13 b includes a cylindrical portion 14 that is attached to the side of the second side plate 11 b, and a bulge that protrudes axially outward (right side in FIG. 2). And an exit portion 15. The first side cover 13a and the cylindrical portion 14 are substantially circular members in side view having substantially the same diameter as the first and second side plates 11a and 11b, respectively. The diameter of the second side cover 13b is the diameter of the first side cover 13a. It is formed to have a larger diameter. For example, the diameter of the cylindrical portion 14 is in the range of 110% to 140% of the diameter of the first side cover 13a. In the present embodiment, the diameter is 110% to 120% of the diameter of the first side cover 13a.

  As shown in FIGS. 1 to 3, the cylindrical portion 14 is a cylindrical member that is mounted on the side of the second side plate 11 b and is substantially circular in a side view. The bulging portion 15 is integrally formed with the cylindrical portion 14 and is formed so as to protrude outward in the axial direction (right side in FIG. 2) so as to have a space communicating with the cylindrical portion 14 therein. The bulging portion 15 is a substantially raindrop-shaped member having a small arc portion and a large arc portion in a side view, and is formed such that the lower large arc portion projects downward from the cylindrical portion 14. A drag operation member 2 and a handle 3 are attached to the bulging portion 15 so as to be exposed to the outside.

  A swing support portion 34 for swingably supporting the drag operation member 2 is formed on the mounting portion of the bulging portion 15 on the drag operation member 2 so as to protrude outwardly from the other portions in a stepped manner. . The swing support portion 34 is a portion having a large-diameter protruding portion 34a and a small-diameter protruding portion 34b protruding from the large-diameter protruding portion. Inside the large-diameter protruding portion 34a is a bearing 20d described later (see FIG. 5). Is stored. A guide member (guide portion) that guides the second cam member 22 (see FIG. 5), which will be described later, in a non-rotatable and axially movable manner, on the inner peripheral side of the swing support portion 34, specifically, on the small-diameter protruding portion 34b. An example) 17 is arranged. The guide member 17 is caulked and fixed through the second side cover 13b to a guide fixing portion 39 provided on the inner peripheral side of the swing support portion 34 through which the spool shaft 5 of the second side cover 13b passes. As shown in FIGS. 5 and 6, the guide fixing portion 39 has a hexagonal concave portion 37 that is arranged concentrically with the spool shaft core and engages the guide member 17 so as not to rotate, and a circular through hole 38. Yes.

  As shown in FIGS. 5 and 6, the guide member 17 has a substantially hexagonal cross-sectional outer shape and a smaller diameter than the hexagonal portion 35 fitted into the hexagonal concave portion 37 and a circle inscribed in the hexagonal portion 35, A cylindrical portion 36 that fits into the through hole 38 is provided. The hexagonal portion 35 includes a first to sixth outer peripheral surface surfaces 35a1 to 35a6 that are, for example, regular hexagonal sides on the outer peripheral portion, and an adjacent first to sixth outer peripheral surface 35a1 to 35a6. First to sixth arc portions 35b1 to 35b6 connected by an arc of a circle 17c centering on the core. The cylindrical portion 36 is provided to fit the through hole 38 and center the guide member 17 with respect to the spool shaft 5. The cylindrical portion 36 has a caulking portion 36b that is formed by a tapered surface 36a that penetrates the through hole 38 and protrudes into the second side cover 13b and whose inner peripheral surface is widened. The guide member 17 is fixed to the second side cover 13b by caulking the caulking portion 36b protruding from the through hole 38 toward the inner wall of the second side cover 13b.

  As shown in FIG. 6, the hexagonal recess 37 has first to sixth inner peripheral surfaces 37 a 1 to 37 a 6. The first and fourth inner peripheral surfaces 37a1 and 37a4 are arranged with a gap from the first outer peripheral surface 35a1 and the fourth outer peripheral surface 35a4 facing the first outer peripheral surface 35a1, respectively. The second inner peripheral surface 37a2 includes a first contact portion 37c1 disposed so as to be in contact with the first portion 35a21 on the first outer peripheral surface 35a1 side of the second outer peripheral surface 35a2 adjacent to the first outer peripheral surface 35a1, and a second outer peripheral surface. The second portion 35a22 on the third outer peripheral surface 35a3 side adjacent to the surface 35a2 has a first separation portion 37d1 disposed with a gap from the second outer peripheral surface 35a2. The third and sixth inner peripheral surfaces 37a3 and 37a6 are disposed so as to be in contact with the third outer peripheral surface 35a3 and the sixth outer peripheral surface 35a6 facing the third outer peripheral surface 35a3. The fifth inner peripheral surface 37a5 includes a second contact portion 37c1 disposed so as to be in contact with the third portion 35a53 on the fourth outer peripheral surface 35a4 side of the fifth outer peripheral surface 35a5 adjacent to the fourth outer peripheral surface 35a4, and a fifth outer peripheral surface. The fourth portion 35a54 on the sixth outer peripheral surface 35a6 side adjacent to the surface 35a5 has a second separating portion 37d2 disposed with a gap from the fifth outer peripheral surface 35a5. These first to sixth inner peripheral surfaces 37a1 to 37a6 are arranged side by side along the swinging direction indicated by an arrow R in which the drag force of the drag mechanism 6 is increased by the drag operation member 2. The first and second separation portions 37c1 and 37c2 are formed in an arc shape and are continuous with the third and sixth inner peripheral portions 37a3 and 37a6.

  Below the drag operation member 2 of the bulging portion 15, a protruding cylinder 16 for mounting the handle 3 is formed to protrude outward. As shown in FIG. 2, a cylindrical handle shaft 31 is disposed inside the protruding cylinder 16 in parallel with the spool shaft 5 that is the rotation shaft of the spool 4. As shown in FIG. 2, the handle shaft 31 is cantilevered and supported by the projecting cylinder 16 by two bearings 32 and 33 disposed at both ends of the projecting cylinder 16, and one shaft end is supported by the bearing 32. It is arranged to protrude inward. A main gear 60 is rotatably mounted on the protrusion of the handle shaft 31 on the bearing 32 side.

  A roller-type first one-way clutch 62 is disposed between the bearings 32 and 33. The first one-way clutch 62 allows only forward rotation of the handle shaft 31 in the yarn winding direction and prohibits reverse rotation in the yarn unwinding direction. A claw-type second one-way clutch 63 is disposed at one shaft end of the handle shaft 31. The second one-way clutch 63 also prohibits reverse rotation of the handle shaft 31. These first and second one-way clutches 62 and 63 are mainly used for operating a drag mechanism 6 (described later) that brakes the rotation of the spool 4 in the yarn unwinding direction.

  As shown in FIG. 2, the handle 3 is fixed to the other end of the handle shaft 31. The handle 3 includes a handle arm 40 fixed to the distal end of the handle shaft 31 and a handle grip 41 supported rotatably at the distal end of the handle arm 40. The handle arm 40 is fixed to the tip end of the handle shaft 31 by a screw member 42 so that the handle shaft 31 cannot rotate relative to the handle arm 40. The handle grip 41 is formed to have a substantially T-shaped rounded outer shape in order to make it easier to grip with force.

<Spool configuration>
As shown in FIG. 2, the spool 4 includes a cylindrical bobbin trunk 4a and first and second flange portions 4b and 4c formed on both sides of the bobbin trunk 4a and having a larger diameter than the bobbin trunk 4a. Have. The spool 4 is rotatably supported on the spool shaft 5 by bearings 20a and 20b. A drag mechanism 6 is provided on the handle 3 side of the spool 4 to brake the rotation of the spool 4 in the yarn unwinding direction. A centrifugal braking mechanism 18 that brakes the spool 4 is provided on the first side cover 13 a side of the spool 4. A spool sound generating mechanism 19 is provided between the spool 4 and the first side cover 13a. The spool sound generation mechanism 19 can be switched between a sound generation state and a silent state in which sound is not generated according to the rotation of the spool 4.

  As shown in FIG. 2, the second flange portion 4c is formed to have a larger diameter than the first flange portion 4b. As shown in an enlarged view in FIG. 5, the second flange portion 4 c is a cylindrical small-diameter portion 4 d formed such that the bobbin trunk portion 4 a side has a smaller diameter than a first braking member 25 described later that constitutes the drag mechanism 6. And a cylindrical large-diameter portion 4e formed so that the outermost peripheral side has a larger diameter than the first braking member 25. The small diameter portion 4d is integrally formed with the large diameter portion 4e so as to have a smaller diameter than the large diameter portion 4e, and is provided so as to generate a step between the large diameter portion 4e and the end of the bobbin trunk 4a. . Here, the fishing line is wound around the outer periphery of the bobbin trunk 4a, but the fishing line can be wound up to the outermost diameter of the small diameter part 4d by the step of the small diameter part 4d. The second side plate 11b is disposed so as to cover the space between the large diameter portion 4e and the small diameter portion 4d, and the tip end portion extends radially inward so as to be close to the small diameter portion 4d. For this reason, it is possible to prevent the fishing line from being wound around the outer periphery of the small diameter portion 4d and to restrict the fishing line from moving outward in the axial direction.

  As shown in FIG. 2, the diameter of the small diameter portion 4d is formed to be substantially the same as the diameter of the first flange portion 4b. The diameter of the large diameter portion 4e is in the range of 110% to 140% of the diameter of the small diameter portion 4d. In the present embodiment, the diameter is 120% to 130% of the diameter of the small diameter portion 4d. Moreover, the diameter of the large diameter part 4e is formed so that it may become substantially the same diameter as the diameter of the 1st side plate 11a and the 1st side cover 13a. Further, the diameter of the first braking member 25 is in the range of 90% or more of the diameter of the small diameter portion 4d, and in this embodiment, is 130% to 140% of the diameter of the small diameter portion 4d. The outer diameter of the bobbin trunk 4a is 30% to 40% of the diameter of the small diameter portion 4d.

<Configuration of drag mechanism>
As shown in FIG. 2, the drag mechanism 6 is for changing and adjusting the braking force applied to the rotation of the spool 4 mounted on the spool shaft 5 in the yarn feeding direction. As shown in FIG. 4, the drag mechanism 6 includes a drag operation member 2, a first cam member (an example of a first cam portion) 21 provided on the inner peripheral portion of the drag operation member 2, and a first cam member 21. A second cam member (an example of a second cam portion) 22 disposed in contact with the second cam member, and a drag adjusting member that is rotatably mounted on the second cam member 22 and pulls the spool shaft 5 outward (right side in FIG. 7). 27, a retaining member 23 for retaining the drag adjusting member 27 in the axial direction with respect to the second cam member 22, and a first attachment comprising, for example, four disc springs for biasing the spool 4 in the axial direction. A second urging member 24b made of a biasing member 24a (see FIG. 2) and a coil spring; a third urging member 24c made of a coil spring that urges the drag adjusting member 27 outward in the axial direction (right side in FIG. 2); , Fixed to the outside of the spool 4 in the axial direction (right side in FIG. 4). And the braking member 25, and a second braking member 26 first braking member 25 is disposed to be contacted. In FIG. 2, the upper half of the spool shaft 5 indicates the axial position when the maximum drag operation is performed, and the lower half indicates the drag force reduction position.

  As shown in FIG. 4, the drag operation member 2 has a boss portion 2a formed at the center thereof rotatably supported by the second side cover 13b, and a lever portion 2b extending radially outward therefrom from the second side cover 13b. The cover 13b is configured to be locked at a plurality of locations in the circumferential direction. Further, as shown in FIG. 5, the mounting member 2c for mounting the first cam member 21 on the inner peripheral portion of the boss portion 2a cannot be relatively rotated by appropriate fixing means such as press-fitting or caulking fixing. It is fixed. The mounting member 2c is rotatably supported by the small-diameter protruding portion 34b of the swing support portion 34 of the second side cover 13b. The drag operation member 2 swings about 150 degrees.

  As shown in FIG. 5, the first cam member 21 is a rod-like cam pin fixed to a plurality of locations (for example, two locations) of the attachment member 2 c of the drag operation member 2. The second cam member 22 is disposed in contact with the first cam member 21, is movable in the axial direction in accordance with the swing of the first cam member 21, that is, the swing of the drag operation member 2, and is relative to the spool shaft 5. It is a cylindrical member that cannot rotate. A shim 46 is mounted between the mounting member 2 c and the wall surface of the swing support portion 34.

  As shown in FIGS. 7 and 8, the second cam member 22 includes an inclined cam 22 a having an inclined surface 22 e that is inclined along a circumferential direction in contact with the first cam member 21. In FIG. 8, two sets of inclined cams 22a are provided at an interval of 180 degrees, and each inclined cam 22a is provided with an arcuate recess 22g in which the first cam member 21 is disposed when the drag is released. The first flat surface portion 22d that is recessed, the inclined surface 22e that gradually protrudes along the circumferential direction (swing direction) from the first flat surface portion 22d, and the flat surface at the highest height position of the inclined surface 22e. And a second flat surface portion 22f that generates the maximum drag force. The second flat surface portion 22f is slightly closer to the swing start position than a position away from the swing start position (the position where the recess 22g is formed) that is the maximum swing position of the drag operation member 2 by an angle α (for example, 150 degrees). It is formed from the position.

  Further, the inner peripheral portion of the second cam member 22 is mounted on the guide member 17 so as not to rotate but to move in the axial direction. As shown in FIGS. 7 and 8, the second cam member 22 engages with the first to sixth outer peripheral portions 35a1 to 35a6 and the first to sixth arc portions 35b1 to 35b6 of the guide member 17 on the inner peripheral portion. It has a hexagonal hole 22b and a circular hole 22c that is formed adjacent to the hexagonal hole 22b and fits into a circle 17c that connects the first to sixth arc portions 35b1 to 35b6. Since the hexagonal hole 22c is formed by, for example, press molding, it cannot be formed with a very hot thickness (length in the axial direction) in consideration of accuracy. When the hexagonal hole 22b having such a small thickness is attached to the guide member 17 so as not to rotate and to be movable in the axial direction, the second cam member 22 may be rattled because the axial length is short. Therefore, the first to sixth arc portions 17b1 to 17b6 are formed in the guide member 17 and the circular hole 22c is formed adjacent to the hexagonal hole 22b, and the first to sixth arc portions 17b1 of the circular hole 22c and the guide member 17 are formed. The looseness of the second cam member 22 is suppressed by fitting with ˜17b6.

  The second cam member 22 moves counterclockwise in FIG. 1 counterclockwise (counterclockwise direction indicated by an arrow in FIG. 8) of the drag operation member 2 and moves to the left in the axial direction in FIG. . Further, when the drag operation member 2 is swung clockwise in FIG. 1, the drag operation member 2 moves to the right in the axial direction on the lower side in FIG.

  The second cam member 22 is retained in the axial direction with respect to the drag adjusting member 27 by a retaining member 23. The retaining member 23 is, for example, a C-shaped retaining ring made of synthetic resin having elasticity. The retaining member 23 is disposed so as to be in contact with the outer peripheral surface of the second cam member 22 and the inner peripheral surface of the drag adjusting member 27, and the shaft of both members is caused by the force of the C-shaped retaining ring spreading outward. The movement of the direction is regulated.

  The attachment structure 45 of the drag operation member 2 according to the present invention includes the second cam member 22, the guide member 17, the guide fixing portion 39, and the swing support portion 34 described above.

  As shown in FIG. 5, the drag adjusting member 27 is a bottomed cylindrical cap member, and is an adjusting member for initially setting the drag force. The drag adjusting member 27 is attached to the second cam member 22 so as to be relatively rotatable. The end of the spool shaft 5 protruding outward from the second side cover 13b is screwed together, and the spool shaft 5 is rotated by rotation in the screwing direction. Is a member that pulls out outward in the axial direction (right side in FIG. 5). A female screw portion 27 a is formed on the inner peripheral portion of the drag adjusting member 27, and a male screw portion 5 a formed at the end of the spool shaft 5 is screwed. A third urging member 24c made of a coil spring is mounted between the inner peripheral portion of the drag adjusting member 27 and the axial end surface of the inner peripheral portion of the second cam member 22, and the drag adjusting member 27 is always attached. Energizing outward. Thereby, rattling of the second cam member 22 can be prevented. On the outer peripheral portion of the tip end portion of the drag adjusting member 27, a stepped portion 27b recessed from the other portion is formed in a groove shape along the circumferential direction. When the drag adjusting member 27 is attached or detached, the step 27b is picked and pulled outward in the axial direction (right side in FIG. 5), so that the drag adjusting member 27 can be easily attached and detached.

  The drag adjusting member 27 moves slightly to the left in the axial direction on the upper side of FIG. 5 due to the counterclockwise rotation, and the drag force is slightly weakened. Further, when the drag adjusting member 27 is rotated clockwise, the drag force is slightly increased by slightly moving to the right in the axial direction on the lower side of FIG. The drag adjusting member 27 is mainly used for changing the adjustment range of the drag force.

  As shown in FIG. 2, the spool shaft 5 is a shaft member that is supported on the reel body 1 so as to be movable in the axial direction and not to be relatively rotatable. Bearings 20a and 20b for rotatably mounting the spool 4 and a bearing 20c for rotatably supporting a second braking member 26 described later are mounted on the outer periphery of the spool shaft 5. On the outer periphery of the spool shaft 5 between the bearings 20a and 20b, as shown in FIGS. 2 and 7, a second urging member 24b made of a coil spring that urges the spool 4 inward in the axial direction (left side in FIG. 2). Is installed. Further, on the outer periphery of the spool shaft 5 in the axially inward direction (left side in FIG. 2) of the bearing 20a, as shown in FIG. One urging member 24a is attached. The first biasing member 24a has a stronger biasing force than the second biasing member 24b. For this reason, when the spool shaft 5 moves in the axial direction, the first urging member 24a acts first, and then the second urging member 24b acts.

  A bearing 20d is mounted on the inner peripheral portion of the second side cover 13b, and supports the outer peripheral portion of the pinion gear 61 mounted on the outer periphery of the spool shaft 5. As shown in FIG. 2, the pinion gear 61 meshes with the main gear 60 fixed to the handle shaft 31. The tip of the pinion gear 61 is fixed to the inner peripheral side of the second braking member 26 described later. As a result, the rotation from the handle 3 is transmitted to the first braking member 25 via the main gear 60, the pinion gear 61, and the second braking member 26, and is transmitted from the first braking member 25 to the spool 4, and the spool 4 rotates. To do.

  As shown in FIGS. 2 and 4, the first braking member 25 is an annular member that is fixed to the outside of the spool 4 in the axial direction (right side in FIG. 2) inside the second side plate 11 b. The first braking member 25 is formed to have a larger diameter than the small-diameter portion 4d of the second flange portion 4c, which is a thread winding diameter of the spool 4. The first braking member 25 is fixed to the end surface of the spool 4 with a plurality of screw members 51. The first braking member 25 is made of a heat-resistant synthetic resin such as a fiber reinforced resin obtained by impregnating a carbon fiber woven fabric with a heat-resistant resin such as a phenol resin.

  4 and 9, the second braking member 26 includes a donut-shaped sliding disk 26 a on which the first braking member 25 is disposed so as to be able to press contact with the spool shaft 5 and is not movable in the axial direction and rotates. And a main body member 26b mounted freely. The sliding disk 26a is made of a heat and corrosion resistant metal such as stainless steel. The sliding disk 26 a has a slightly smaller diameter than the first braking member 25 and is fixed to the main body member 26 b by a plurality of screw members 52. The main body member 26b is a disk-shaped member having a boss portion 26c, and is rotatably supported on the spool shaft 5 by a bearing 20c. The main body member 26b meshes with the pinion gear 61 on the inner peripheral surface at the boss portion 26c. Further, the movement of the main body member 26b outward in the axial direction (right side in FIG. 2) is restricted by the reel main body 1 via the pinion gear 61 and the bearing 20d.

  The outer sides of the first and second braking members 25 and 26 are covered with a cover disk 28. The outer peripheral portion of the cover disk 28 is fixed to the tip portion on the axially outer side (right side in FIG. 2) of the large diameter portion 4e of the second flange portion 4c. The cover disk 28 is fixed to the tip end portion of the large diameter portion 4e of the second flange portion 4c by a screw member 53. Further, a seal member 29 having a lip 29a is disposed on the outer periphery of the cover disc 28 and the boss portion 26c, and the inside of the cover disc 28 is sealed. When the lip 29a is in the drag released state shown in FIG. 4, the lip 29a does not come into contact with the cover disk 28, and the first braking member 25 and the second braking member 26 are moved by the operation of the drag operating member 2 as shown in FIG. When in contact with the draggable state, the cover disk 28 is contacted to seal the inside. Thereby, the rotational resistance of the spool 4 when the drag is released can be reduced.

  In the dual-bearing reel configured as described above, the drag adjusting member 27 is used when the adjustment range of the drag force of the drag mechanism 6 is adjusted. When the drag adjusting member 27 is rotated counterclockwise, the drag adjusting member 27 moves slightly to the left in the axial direction on the upper side of FIG. 5 and shifts in a direction in which the adjustment range of the drag force is slightly weakened. Further, when the drag adjusting member 27 is rotated clockwise, the drag adjusting member 27 moves slightly to the right in the axial direction on the lower side of FIG. 5 and shifts in a direction in which the adjustment range of the drag force is slightly increased.

  When adjusting the drag force of the drag mechanism 6, the drag operation member 2 is swung. When the drag operation member 2 is disposed at the drag release position, which is the most pivotal position in FIG. 1, the first cam member 21 is disposed in the recess 22g of the inclined cam 22a. Then, when the drag operation member 2 is swung clockwise in FIG. 1, the first cam member 21 comes into contact with the inclined surface 22e of the inclined cam 22a, and the second cam member 22 moves outward in the spool axial direction (right side in FIG. 2). ) And the spool shaft 4 and the spool 4 gradually move to the right side, and the first braking member 25 and the second braking member 26 come into contact with each other as shown in FIG. The generated drag force gradually increases as the drag operation member 2 swings clockwise. When the first cam member 21 reaches the second flat surface portion 22f of the inclined cam 22a, the drag force is maximized. When the drag adjusting member 2 rotates in such a direction that the drag force becomes stronger, the reaction force at the inclined cam 22a causes the guide member 17 to rotate clockwise (the arrow in FIG. 6) via the second cam member 22. Rotational force is transmitted in the direction indicated by R) and attempts to rotate in that direction. At this time, as described above, in the hexagonal recess 37, the two portions 37a31 on the second and fifth inner peripheral side of the first and second contact portions 37c1, 37c2 and the third and sixth inner peripheral portions 37a3, 37a6. , 37a61 are in contact with the outer peripheral surface of the guide member 17 in total. For this reason, when a large rotational force is applied to the guide member 17, the number of contact portions increases and stabilizes, and variation in contact portions between the hexagonal guide member 17 and the hexagonal recess 37 of the second side cover 13b is reduced. Can be made.

  On the other hand, when the drag operation member 2 is swung in the reverse direction (counterclockwise in FIG. 1), the first biasing member 24a (see FIG. 2) composed of four disc springs and the second attachment composed of a coil spring. The spool 4 and the spool shaft 5 are urged to the left in FIG. 2 by the urging member 24b, and the drag force gradually decreases. At this time, the rotational force transmitted to the guide member 17 is weaker than when the drag force is increased. In this case, only the two portions 37a32 and 37a62 on the fourth and first inner peripheral side of the third and sixth inner peripheral portions 37a3 and 37a6 are in contact with the outer peripheral surface of the guide member 17.

  Thus, in the hexagonal recess 37, the first inner peripheral portion 37a1 and the fourth inner peripheral portion 37a4 are separated from the first and second outer peripheral portions 35a1 and 35a4, and the second inner peripheral portion 37a2 and the fifth inner peripheral portion are separated. By providing the first and second separation portions 37d1 and 37d2 in the portion 37a5, the tool can be released at that portion even if a cylindrical tool is used. Therefore, the first and second contact portions 37c1 and 37c2 and the third and sixth inner peripheral portions 37a3 and 37a6 are replaced with the first and third portions 35a21 and 35a53 of the hexagonal second and fifth outer peripheral portions 35a2 and 35a5. In addition, it can be accurately machined with a tool along the third and sixth outer peripheral portions 35a3 and 35a6. Further, since the first and second contact portions 37c1 and 37c2 are arranged on the upstream side of the swing direction in which a stronger force in the swing direction acts on the guide member 17, the drag operation member 2 swings in the swing direction. When the moving operation is performed, the number of contact portions in contact with each other is larger than the number of contact portions in the reverse direction. Specifically, when the drag operating member 2 is operated in the direction in which the drag force is increased, the second and fifth of the first and second contact portions 37c1 and 37c2 and the third and sixth inner peripheral portions 37a3 and 37a6. A total of four portions of the two portions 37a31 and 37a61 on the inner peripheral side come into contact with the outer peripheral surface of the guide member 17. On the other hand, when the swinging operation is performed in the opposite direction, the outer peripheral surface of the guide member 17 is brought into contact only with the two portions 37a32 and 37a62 on the fourth and first inner peripheral portions side of the third and sixth inner peripheral portions 37a3 and 37a6. do not do. For this reason, the number of contact portions is stabilized, and variations in contact portions between the hexagonal guide member 17 and the hexagonal recesses 37 of the guide fixing portion 39 can be reduced.

Other Embodiment
(A) In the said embodiment, although the 1st cam member 21 and the drag operation member 2 were a different body, you may integrally form a 1st cam member and a drag operation member.

  (B) In the above-described embodiment, the circular hole 22c is formed in the second cam member 22 in order to reduce rattling. However, all the hexagonal holes 22b may be formed without providing the circular hole 22c. In this case, it is not necessary to provide the first to sixth arc portions 35b1 to 35b6 in the hexagonal recess 37.

The perspective view of the double bearing reel which employ | adopted one Embodiment of this invention. Sectional drawing of the said double bearing reel. The perspective view of a 2nd side cover. The expanded sectional view of the drag mechanism of a drag release state. The expanded sectional view around a drag adjustment member. The front view of a guide fixing | fixed part. A half-sectional view of the second cam member. Front view of second cam member FIG. 4 is an enlarged cross-sectional view of the drag mechanism in FIG. 4 in a draggable state.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Reel main body 13b 2nd side cover 15 Expansion part 17 Guide member 21 1st cam member 22 2nd cam member 22a Inclined cam 22b Hexagonal hole 22c Circular hole 22e Inclined surface 45 Drag operation member attachment structure 34 Swing support part 35 Hexagonal part 35a1 to 35a6 First to sixth outer peripheral part 35a21 First part 35a22 Second part 35a53 Third part 35a54 Fourth part 35b1 to 35b6 First to sixth arc part 36 Cylindrical part 36b Caulking part 37 Hexagonal recessed part 37a1 to 37a6 1st-6th outer peripheral part 37b1, 37b2 1st and 2nd contact part 37c1, 37c2 1st and 2nd separation part

Claims (5)

A mounting structure of a drag operation member that is swingably mounted on the side of the reel body of the lever drag reel and adjusts the drag force of the drag mechanism.
A second cam portion that engages with a first cam portion provided on the drag operation member and moves in the swing axis direction in conjunction with the swing of the drag operation member;
A hexagonal portion having first to sixth outer peripheral surfaces for guiding the second cam portion so as not to be rotatable with respect to the reel body and to be movable in the swing axis direction, and disposed adjacent to the hexagonal portion. A guide portion having a cylindrical portion having a smaller diameter than the inscribed circle,
A guide fixing portion provided on a side portion of the reel body, having a hexagonal recess into which the hexagonal portion of the guide portion is fitted, and a through-hole into which the cylindrical portion is fitted, to which the guide portion is fixed;
A swing support portion provided on the reel body on the outer peripheral side of the guide fixing portion, and swingably supporting the drag operation member;
The hexagonal recess is
First and fourth inner peripheral surfaces disposed with a gap between the first outer peripheral surface and the fourth outer peripheral surface facing the first outer peripheral surface;
A first contact portion disposed so as to be in contact with the first outer peripheral surface side of the second outer peripheral surface adjacent to the first outer peripheral surface; and a third outer peripheral surface side adjacent to the second outer peripheral surface. A second inner peripheral surface having a first separating portion disposed with a gap from the second outer peripheral surface in the second part of
Third and sixth inner peripheral surfaces disposed so as to be in contact with the third outer peripheral surface and the sixth outer peripheral surface facing the third outer peripheral surface;
A second contact portion arranged to be in contact with a third portion of the fifth outer peripheral surface adjacent to the fourth outer peripheral surface on the fourth outer peripheral surface side, and a sixth outer peripheral surface side adjacent to the fifth outer peripheral surface; A fifth inner peripheral surface having a second separating portion disposed with a gap from the fifth outer peripheral surface in the fourth portion of
The attachment structure of the drag operation member, wherein the first to sixth inner peripheral surfaces are arranged side by side along a swinging direction in which the drag force of the drag mechanism is increased by the drag operation member. The first cam portion has a plurality of cam pins arranged along the radial direction of the swing shaft,
The second cam portion is
An inclined cam having an inclined surface inclined along the circumferential direction so as to engage with the cam pin;
The drag operation member mounting structure according to claim 1, further comprising a hexagonal hole that is disposed on an inner peripheral portion and engages with the guide member so as to be axially movable and non-rotatable. The hexagonal portion further includes first to sixth arc portions that connect adjacent outer peripheral surfaces of the first to sixth outer peripheral surfaces with an arc centered on a pivot axis;
3. The drag operation member mounting structure according to claim 2, wherein the second cam portion further includes a circular hole formed adjacent to the hexagonal hole in an inner peripheral portion and into which the arc portion can be fitted.   The drag operation member according to any one of claims 1 to 3, wherein the first separation portion of the second inner circumferential surface and the second separation portion of the fifth inner circumferential surface are each formed in an arc shape. Mounting structure. The cylindrical portion of the guide portion has a caulking portion that is formed by a taper surface that penetrates the through-hole and protrudes into the reel body and has an inner peripheral surface that widens.
5. The drag according to claim 1, wherein the guide portion is fixed to the reel body by caulking the caulking portion protruding from the through hole toward an inner wall of the reel body. 6. Mounting structure for operation members.

Images