JP2011019408A - Fishing reel - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a fishing reel that eliminates an uncomfortable feeling in gripping, holding and operating the fishing reel, prevents obstruction of an operation part in casting operations and troubles of a braking device. <P>SOLUTION: The fishing reel 10 rotatably supports a spool 20 between side plates 16a and 16b of a reel body 12 and adjusts braking force of the braking device 54 for braking rotation of the spool through a rotation operation part 86 arranged on the side plate 16b. The rotation operation part 86 is arranged on a position separated from a hand palm in gripping and holding a fishing rod 8 and the reel body 12 at the lower part of the side plate 16b on the opposite side of a handle 30 for winding a fishing line on the spool 20, and is exposed to the outside, and the rotation operation part 86 is operated by a hand finger holding the reel body. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a fishing reel, and in particular, a spool is rotatably supported between side plates of a reel body, and a braking force of a braking device that brakes the rotation of the spool is adjusted via an operation unit disposed on the side plate. The present invention relates to a fishing reel.

For example, a centrifugal friction brake device or a magnetic brake device has conventionally been provided as a brake device for preventing spool over-rotation when fishing line is released such as casting.
For example, in Patent Document 1, an operation portion of a braking device that applies a braking force to a spool that is rotatably supported between a pair of side plates of a fishing reel is provided in front of the side plate opposite to the handle. For example, in Patent Document 2, an operation portion of a braking device that applies a braking force to a spool rotatably supported between a pair of side plates of a fishing reel is provided between the side plates behind the spool.

Japanese Utility Model Publication No. 7-5362 Japanese Patent Publication No. 1-27698

In the fishing reel of Patent Document 1, the operation portion of the brake device for the spool is operably exposed at the front side portion and the center portion of the side plate. For this reason, when the fishing reel is gripped together with the fishing rod, the protruding portion of the operating portion that is exposed to the palm bites into the palm, resulting in a sense of incongruity and poor grip holding performance.
When the operation part is provided between the side plates on the rear side of the spool as in Patent Document 2, the fishing line releasing operation cannot be performed smoothly because it interferes with the summing operation during casting after the clutch is turned off. There is a risk that the operating state will be touched to change the braking state (braking force), resulting in poor stability.
Furthermore, an external force is likely to be applied to the outer peripheral portion protruding during practical use or when the fishing ground is moved, which may cause a problem with the braking device.

  The present invention has been made in order to solve the above-described problems, eliminates a sense of incongruity when operating by holding and holding, does not disturb the operation unit during casting operation, and provides braking. An object of the present invention is to provide a fishing reel capable of preventing the apparatus from being hindered.

In order to solve the above-mentioned problem, according to the present invention, a first operation unit according to the present invention, wherein a spool is rotatably supported between side plates of a reel body, and a braking force of a braking device that brakes the rotation of the spool is disposed on the side plate. In the fishing reel that can be adjusted via the first reel, the first operating portion is disposed in the outer peripheral area of the lower portion of the side plate opposite to the handle for winding the fishing line on the spool and exposed to the outside. The first operation unit can be operated with a finger of a hand holding a reel body.
It is preferable that the first operation portion is provided at a lower portion of the side plate opposite to the handle, on the handle side from an outer surface of the side plate.
The first operation unit sets a reference braking force, and a second operation unit for finely adjusting the braking force based on the reference braking force is provided on a side plate opposite to the handle. It is preferable.
The side plate opposite to the handle is formed with a recess recessed inwardly from the outer surface of the side plate, and the second operating portion protrudes outward from the extended surface of the outer surface of the side plate. It is preferable that the second operation unit be exposed to the outside by being disposed in the recess without being operated, and the second operation unit can be operated with fingers of the hand holding the reel body.

By arranging the first operation part at the lower part of the side plate opposite to the handle and away from the palm of the hand, the first operation part is held by the palm when the fishing rod and reel are held and held. Is prevented from hitting. For this reason, there is no sense of incongruity in the palm when gripping and holding, and the casting operation can be performed stably without obstructing the first operation section or causing trouble. In addition, since it is difficult for external force to be applied to the first operation unit during actual fishing or when moving to the fishing spot, the braking device is hindered, such as the first operation unit being scratched or turning operation force being reduced. Can be prevented.
Since the first operating portion does not protrude from the outer surface of the side plate, the outer surface of the side plate can be securely held with a palm without a sense of incongruity during gripping and holding.
Suitable not only for the first operating part that greatly changes the braking force of the braking device, but also for the actual situation of the fishing ground by providing a second operating part that finely adjusts the braking force changed by the first operating part. A wide range of braking force adjustment is possible.
Since the second operating portion is disposed in the recess so as not to protrude from the outer surface of the side plate, it is possible to maintain good gripping and holding properties.

The schematic front view which shows the fishing tackle which attached the fishing reel to the fishing rod based on 1st Embodiment, and shows the state which hold | maintained the fishing rod and the reel with the left hand. The schematic which showed the state observed from the opposite side to the side in which the handle was attached among the fishing reels concerning 1st Embodiment, and was seen from the arrow II direction in FIG. The schematic partial cross-sectional view which shows the fishing reel which concerns on 1st Embodiment, and follows the III-III line in FIG. The schematic enlarged view of the part shown by the arrow IV in FIG. 3 of the fishing reel which concerns on 1st Embodiment. The schematic top view which shows the fishing tackle which attached the reel for fishing to the fishing rod based on 2nd Embodiment, hold | maintained the fishing rod and reel with the left hand, and hold | maintained the handle with the right hand. The schematic diagram which showed the state observed from the opposite side to the side in which the handle was attached among the fishing reels concerning 2nd Embodiment, and was seen from the VI-VI direction in FIG. The schematic partial cross-sectional view which shows the fishing reel which concerns on 2nd Embodiment, and follows the VII-VII line in FIG. The schematic enlarged view of the part shown by the arrow VIII in FIG. 7 of the fishing reel which concerns on 2nd Embodiment. Schematic which shows the state observed from the opposite side to the side in which the handle was attached among the fishing reels concerning 2nd Embodiment, and the state which removed the left side board. The rotation operation part of the 1st operation mechanism of the fishing reel which concerns on 2nd Embodiment is shown, (A) is a front view, (B) is a rear view, (C) is in FIG. 10 (A). The longitudinal cross-sectional view which follows the 10C-10C line of FIG. 10, (D) is a longitudinal cross-sectional view which follows the 10D-10D line in FIG. 10 (A). The state which looked at the state observed from the opposite side to the side where the handle was attached among the fishing reels concerning a 2nd embodiment, and the state which removed the rotation operation part of the left side board and the 1st operation mechanism FIG. Schematic which shows the state observed along XII-XII in FIG. 11 about the state observed from the opposite side to the side in which the handle was attached among the fishing reels concerning 2nd Embodiment. The state which observed the 1st operation mechanism from the opposite side to the side in which the handle was attached among fishing reels concerning a 2nd embodiment is shown, and (A) is a rotation operation of the 1st operation mechanism. FIG. 12B is a schematic diagram showing a state in which the inner protruding portion of the first portion is arranged in the first step portion in FIG. 12, and FIG. 12B shows the inner protruding portion of the rotating operation portion of the first operating mechanism in FIG. Schematic which shows the state arrange | positioned in 2 step parts, (C) is the schematic which shows the state which has arrange | positioned the inner side protrusion part of the rotation operation part of a 1st operation mechanism in the 3rd step part in FIG. . Of the fishing reel according to the second embodiment, the schematic cross section of the first operating mechanism is shown, (A) corresponds to the state shown in FIG. FIG. 12B is a schematic diagram showing a state in which the inner protruding portion of the rotation operation portion is arranged in the first step portion in FIG. 12, and FIG. 13B corresponds to the state shown in FIG. 13B and the rotation of the first operation mechanism. FIG. 12C is a schematic view showing a state in which the inner protruding portion of the moving operation portion is arranged at the second step portion in FIG. 12, and FIG. 13C corresponds to the state shown in FIG. Schematic which shows the state which has arrange | positioned the inner side protruding part of the operation part in the 3rd step part in FIG. The schematic longitudinal cross-sectional view which shows the reel for fishing which concerns on 2nd Embodiment, and shows the principal part of the part in alignment with the XV-XV line | wire in FIG. The reel for fishing which concerns on 2nd Embodiment is shown, Comprising: Schematic which shows the state operated by putting the thumb of a left hand on the rotation operation part of the 2nd operation mechanism shown in FIG. 15, holding a reel with a left hand Longitudinal sectional view.

1 to 4 show a fishing reel 10 according to a preferred embodiment of the present invention.
As shown in FIGS. 1 to 3, the fishing reel 10 of the present embodiment is formed as a double-bearing type manually wound reel. As shown in FIG. 1, here, a case where the angler is configured to hold the fishing rod 8 and the fishing reel 10 with the left hand LH and to turn the handle 30 of the fishing reel 10 with the right hand RH will be described. . Of course, the arrangement of the handle 30 may be reversed so that the handle 30 is operated with the left hand LH.

  As shown in FIG. 3, the reel body 12 of the fishing reel 10 is, for example, screwed, screwed or fitted on the outside of a pair of left and right frames 14a, 14b integrated by a connecting member (not shown). Thus, the side plates 16a and 16b are attached to form a rigid housing as a whole, and are fixed to the fishing rod 8 via the reel attachment legs 18.

  The spool 20 around which the fishing line is wound is rotatably supported between the left and right frames 14a and 14b, and the right side plate 16a supports a winding drive unit 22 that drives the spool 20 to rotate. Various mechanisms such as a driving force transmission system and a drag system that form the winding drive unit 22 are accommodated in a space formed between the frame 14a and the frame 14a. As shown in FIG. 1, the left and right indicate the left and right directions during actual fishing.

As shown in FIG. 3, between the frames 14a and 14b of the reel body 12, both ends of a spool shaft 26 that is mounted with a spool 20 and rotates together with the spool 20 are, for example, ball bearings 28a and 28b as shown in the figure. It is supported so that it can rotate freely. On one end side of the spool shaft 26, the handle 30 is rotated via a drive gear 36 via a handle shaft 34 supported by bearings 32 a and 32 b, and a drag mechanism 44 fitted to the handle shaft 34. A pinion gear 38 that is driven to rotate is disposed coaxially with the spool shaft 26.
The handle shaft 34 is provided with a known star drag (drag adjustment knob) 42, and the drive gear 36 is provided with a known drag mechanism 44, which will not be described.

  The pinion gear 38 is linked to a clutch lever 50 disposed between the side plates 16a and 16b via a known clutch (transmission mechanism) 48 (not shown in detail), and the clutch lever 50 is pressed downward. Thus, the clutch 48 is turned off and can move to the right side in FIG. 3 along the axial direction. For example, when the clutch lever 50 is operated, a position where the pinion gear 38 is fitted to the right end portion of the spool shaft 26, that is, a winding state, and a state where the pinion gear 38 is separated from the right end portion of the spool shaft 26 (spool free state). Can do. Further, when the handle 30 is rotated in a state where the pinion gear 38 is separated, the pinion gear 38 is fitted to the right end portion of the spool shaft 26 through a known return mechanism (not shown) to return to the original state (winding state). The spool 20 that is integrated with the spool shaft 26 rotates together with the pinion gear 38.

  The spool 20 has a cylindrical body portion 20b located between a pair of flange portions 20a formed on both sides in the axial direction, and is spooled via a central wall portion 20c located on the inner peripheral side of the body portion 20b. A fishing line (not shown) is wound in an annular groove formed integrally with the shaft 26 and formed by a pair of flanges 20a and the outer peripheral surface of the fishing line winding body 20b. In order to evenly wind the fishing line (not shown) on the trunk 20b that forms the bottom of the annular groove, the pair of left and right frames 14a and 14b reciprocate in conjunction with the fishing line winding rotation of the handle 30. A known level winding mechanism (not shown) is arranged. In this level wind mechanism, the fishing line is evenly wound on the trunk portion 20b of the spool 20 by moving the engaging member interlocking with the driving portion in the right side plate 16a to the left and right as the handle 30 is rotated. Can do.

A magnetic braking device 54 that prevents the spool 20 from over-rotating is disposed on one side that is opposite to the handle 30.
The magnetic braking device 54 includes a conductor 56 attached so as to rotate integrally with the spool 20. As shown in FIG. 4, the conductor 56 of this embodiment includes a boss portion 56a that is firmly fixed to the spool shaft 26, a disk-like portion 56b that extends radially outward from the boss portion 56a, and the disk-like shape. A cylindrical portion 56c extending from the outer peripheral edge of the portion 56b to the opposite side of the handle 30 is formed of a nonmagnetic conductive material such as aluminum or copper.
The cylindrical portion 56 c has an axial dimension substantially equal to that of an inner ring magnet 68 and an outer ring magnet 70 described later, and the entirety thereof is inserted into an annular gap 72 between the magnets 68 and 70. For this reason, the cylindrical portion 56c is disposed within a range of magnetic flux leaking from the side surfaces of the ring magnets 68 and 70. Since these cylindrical conductors 56 are made of a nonmagnetic conductive material, eddy currents are induced when they move in these magnetic fluxes.

  The conductor 56 does not necessarily need to be entirely formed of the same material as long as the cylindrical portion 56c is formed of such a nonmagnetic conductive material. For example, the boss portion 56a and The disk-shaped part 56b may be formed of a lighter resin material or the like. Further, by fixing the boss portion 56a adjacent to the small diameter portion of the end portion of the spool shaft 26, the bearing 28b that supports the spool shaft 26 suppresses the boss portion 56a from moving outward in the axial direction. Can be prevented from falling off the spool shaft 26.

  On the other hand, the left side plate 16b is firmly fixed to the outside of the left frame 14b facing the conductor 56 with, for example, a plurality of screws. The left side plate 16b includes a substantially disc-shaped outer surface OS defined within a range that can be viewed from the direction shown in FIG. 2, and a substantially cylinder formed continuously on the outer peripheral surface of the outer surface OS as shown in FIG. And a cylindrical surface CS. The outer surface OS includes a chamfered edge portion of the left side plate 16b.

  As shown in FIGS. 3 and 4, a receiving member (set plate) 58 and a left side plate 16b are attached to the outside of the left frame 14b by means such as screws, screwing or fitting. The left side plate 16b has a space between it and the left frame 14b, and the receiving member 58 and the spool braking force adjusting portion 80 are disposed in the space.

As shown in FIG. 4, the receiving member 58 has a support base portion in which a small-diameter portion 62a and a large-diameter portion 62b are formed in order from the spool shaft 26 side concentrically with the central opening 60 that accommodates the spool shaft 26 and the bearing 28b. 62.
An annular groove 64 for accommodating the magnet holder 66 is formed on the outer peripheral portion of the small diameter portion 62a. The magnet holder 66 is slidable with respect to the annular groove 64. An inner ring magnet 68 is fixed to the outer periphery of the magnet holder 66. An outer ring magnet 70 facing the inner ring magnet 68 is fixed to the left frame 14b.

  The inner ring magnet 68 can be rotated with respect to the outer ring magnet 70 when the magnet holder 66 slides with respect to the annular groove 64. For this reason, the magnetic field can be changed steplessly by sliding the magnet holder 66 with respect to the small diameter portion 62 a of the support base 62.

  The receiving member 58 has an arm portion 63 that extends distally (on the left side plate 16 b side) with respect to the left frame 14 b on the front side of the reel 10. The arm portion 63 functions as a spacer that separates the rotation operation portion 86 of the spool braking force adjusting portion 80 between the left frame 14b and the left side plate 16b from the outer surface OS of the left side plate 16b. Furthermore, the arm part 63 can also define the operation range of the rotation operation part 86 shown in FIG.

  An extending portion 76 extending from the magnet holder 66 is disposed between the receiving member 58 and the left frame 14b. A rotation operation portion 86 of the spool braking force adjustment portion 80 is formed below the extension portion 76. The rotation operation part 86 is movable in the circumferential space (recessed part) of the cylindrical surface CS formed in the lower area (lower outer peripheral area) of the left frame 14b and the left side plate 16b. It protrudes (exposes) below the plate 16b. The rotation operation unit 86 is provided below the left side plate 16b opposite to the handle 30 and closer to the handle 30 than the outer surface OS of the left side plate 16b. The protrusion amount L of the rotation operation unit 86 with respect to the lower surface (lowermost surface) of the left side plate 16b is preferably greater than 0 mm and 10 mm or less, for example. Like the spool braking force adjusting unit (second operation unit) 172 of the second embodiment, the spool braking force adjusting unit 172 may be pulled into the outer peripheral surface OS of the left frame 14b and the left side plate 16b. That is, it is only necessary that the rotation operation unit 86 is exposed to the lower side of the left frame 14b and the left side plate 16b and can be operated.

  When the turning operation portion 86 is turned with respect to the left frame 14b, for example, in the direction P in FIG. 2, the extension portion 76 receives the force from the pressure receiving portions 15a and 15b of the left frame 14b while the spool shaft Since it rotates around the axis of 26, the magnet holder 66 rotates in the R direction. That is, the inner ring magnet 68 is rotated with respect to the fixed outer ring magnet 70, and the relative position of the outer ring magnet 70 with respect to the inner ring magnet 68 changes. As a result, the strength of the magnetic field in the annular gap 72 formed between the inner ring magnet 68 and the outer ring magnet 70 in which the cylindrical portion 56c of the conductor 56 is disposed can be reduced, for example, by zero braking that does not form any braking force. The state can be changed steplessly from the state of full braking that forms the maximum braking force.

  As shown in FIG. 1, when the angler holds, for example, the fishing rod 8 and the reel 10 with the left hand LH and operates the handle 30 with the right hand, the index finger LF of the left hand LH is applied to the lower side of the fishing rod 8, A region LTh from the base of the index finger LF to the base of the thumb (not shown) is applied to the outer surface OS of the left side plate 16b and held and held. Although not shown, the thumb is applied to the upper side of the reel body 12. For example, as shown in FIG. 1, a line segment connecting the lower region of the outer surface OS of the left side plate 16b and the lower side of the fishing rod 8 (a position corresponding to a tangent when the outer periphery of the fishing rod 8 is assumed to be circular). Virtualize IS. The line segment IS does not cross the rotation operation unit 86 and does not intersect the finger pad of the index finger LF in the vicinity of the rotation operation unit 86. For this reason, the finger pad of the index finger LF is located away from the rotation operation unit 86. That is, the entire left hand LH is away from the rotation operation unit 86. Accordingly, since the left hand LH is prevented from hitting the rotation operation unit 86 (formed to be difficult to touch), it is possible to prevent the rotation operation unit 86 from being erroneously operated. In addition, since there is no protrusion on the outer surface OS of the left side plate 16b to which the palm of the left hand LH hits, it is possible to maintain a good fit when the fishing rod 8 and the reel 10 are held and held by the left hand LH.

  On the other hand, when the rotation operation unit 86 is operated, the operation can be performed by separating the index finger LF from the fishing rod 8 and applying it to the rotation operation unit 86. When the spool 20 is rotated, an eddy current is generated in the conductor 56 due to the magnetic field generated by the inner ring magnet 68 and the outer ring magnet 70, and the rotation of the spool 20 is suppressed.

A series of operations when fishing is actually performed using the fishing tackle in which the reel 10 is attached to the fishing rod 8 via the reel mounting leg 18 will be briefly described. (1) The handle 30 is operated to wind up the fishing line, and the rotary operation unit 86 is operated with the index finger LF while holding the reel 10 with the left hand LH, and adjustment at the next casting is performed. (2) Complete the winding of the fishing line. (3) Change the fishing rod 8 and the reel 10 from the left hand LH to the right hand RH, and hold the fishing rod 8 and the reel 10 with the right hand RH. (4) Cast while holding in this way.
That is, when the fishing tackle according to this embodiment is used, the braking adjustment of the spool 20 can be performed with one index finger LF while operating the fishing rod 8 or operating the handle 30 of the reel 10. Therefore, after holding the fishing rod 8 and the reel 10 with the right hand RH, it is possible to save the trouble of adjusting the rotation operation unit 86 (adjusting the braking of the spool 20) with the left hand LH. For this reason, a series of operation cycles can be shortened, and the number of times of insertion within a certain time can be increased, so that it is difficult to miss a fishing chance. And since there is no trouble of changing the fishing rod 8 in order to operate the rotation operation part 86, the braking force of the spool 20 can be adjusted according to the next throwing plan while fishing.

  On the other hand, as shown in FIG. 1, when holding the fishing rod 8 and the reel 10 with the left hand LH, a space is formed between the turning operation unit 86 and the left hand LH. It is possible to prevent the left hand LH from being applied to 86 and to prevent an erroneous operation of operating the rotation operation unit 86 unintentionally. In addition, since the outer surface OS of the left side plate 16b has no protrusions while the reel 10 is held with the left hand LH, it does not bite into the palm and has good gripping and holding the index finger LF when necessary. The rotation operation unit 86 can be easily operated by moving and placing the index finger LF on a part of the rotation operation unit 86. In addition, an erroneous operation due to the finger strongly hitting the rotation operation unit 86 hardly occurs.

Next, a second embodiment will be described with reference to FIGS. This embodiment is a modification of the first embodiment. The same members as those described in the first embodiment or members having the same functions are denoted by the same reference numerals, and detailed description will be given. Is omitted.
As shown in FIG. 5, also in this embodiment, the case where the fishing rod 8 and the fishing reel 10 are held with the left hand LH and the handle 30 is operated with the right hand RH will be described.
As shown in FIGS. 6 and 7, in this embodiment, the first and second operation mechanisms (spool braking force adjusting units) 110 and 112 for adjusting the braking force of the spool 20 are provided with the left frame 114b and the left side plate 116b. An example disposed between the two will be described. When the operation unit (first operation unit) 124 of the first operation mechanism 110 is operated, the braking effect can be changed greatly to set the reference braking force, and the spool braking force adjustment unit (second operation unit) of the second operation mechanism 112 can be set. ), The reference braking force (braking effect) by the operation of the operation unit 124 of the first operation mechanism 110 can be finely adjusted.
The left side plate 116b has an outer surface OS defined within a range that can be viewed from the direction shown in FIG. 6 and a lower surface continuously formed on the outer peripheral surface of the outer surface OS as shown in FIGS. And a side surface (an outer peripheral region below the left side plate 116b) US. In this embodiment, the outer surface OS of the left side plate 116b is formed in a state in which the position corresponding to the palm of the palm of the left hand LH has a smooth bulge. As will be described later, the outer surface OS is formed with a recess 188 in which the second operation portion 172 is operably disposed, and the operation projection 160 of the first operation portion 124 is operatively disposed on the lower surface US (not shown). An opening (concave portion) is formed.

As shown in FIG. 8, the first operation mechanism 110 includes a set plate 122, a rotation operation unit (first operation unit) 124, an inner magnet holder 126, and an outer magnet holder 128.
The set plate 122 is fixed to the left frame 114b by means such as screwing or fitting. The set plate 122 has a support base part 134 in which a small diameter part 134a and a large diameter part 134b are formed in order from the spool shaft 26 side, concentrically with the central opening 132 that accommodates the spool shaft 26 and the bearing 28b.
An annular groove 136 for accommodating the inner magnet holder 126 is formed on the outer peripheral portion of the small diameter portion 134a. The inner magnet holder 126 is slidable with respect to the annular groove 136. The inner ring magnet 68 described in the first embodiment is fixed to the outer periphery of the inner magnet holder 126.
An annular groove 138 for accommodating the outer magnet holder 128 is formed in the inner peripheral portion of the large diameter portion 134b. The outer magnet holder 128 is slidable with respect to the annular groove 138. The outer ring magnet 70 described in the first embodiment is fixed to the inner periphery of the outer magnet holder 128.
That is, an inner magnet holder 126 and an outer magnet holder 128 are disposed on the spool 20 side of the set plate 122. The inner magnet holder 126 is rotatable with respect to the outer magnet holder 128. Further, the inner magnet holder 126 can move in the axial direction of the spool shaft 26 together with the outer magnet holder 128, but the movement alone is restricted.

  FIG. 9 shows the set plate 122 and the rotation operation unit 124 of the first operation mechanism 110 with the left side plate 116b removed from the left frame 114b. On the outside of the set plate 122, a rotation operation unit 124 shown in FIGS. 10A to 10D is disposed. FIG. 11 shows a state in which the rotation operation unit 124 is removed from the set plate 122. FIG. 12 is a schematic diagram showing a state observed from the direction along the line XII-XII in FIG.

As shown in FIGS. 10 (A) to 10 (D), the rotation operation unit 124 includes an annular part 142 formed in an approximately annular shape, and an edge of the annular part 142, for example, approximately on the central axis of the annular part 142. It has the extension parts 144a and 144b extended in parallel, and the flange parts 146a and 146b which protruded toward the radial direction outward of the annular part 142 from the extension parts 144a and 144b. The extending portions 144 a and 144 b are formed at positions facing the central axis of the annular portion 142. The flange portions 146a and 146b are formed in a direction away from the distal position with respect to the annular portion 142 of the extending portions 144a and 144b with respect to the central axis of the annular portion 142.
On the other hand, the set plate 122 is formed with a pair of holding portions 150a and 150b (see FIGS. 9, 11, 13, and 14) that rotatably hold the flange portions 146a and 146b of the rotation operation portion 124. The rotation operation unit 124 can be rotated within a predetermined range. Note that the central axis of the rotation operation unit 124 substantially coincides with the central axis of the spool shaft 26.

  As shown in FIGS. 10A to 10D, the pair of extending portions 144a and 144b are formed with inner projecting portions 148a and 148b protruding toward the central axis of the annular portion 142, respectively. Yes. As shown in FIG. 12, the outer magnet holder 128 slidably disposed in the annular groove 138 of the large-diameter portion 134b of the set plate 122 is engaged with the engaging groove in which the inner protruding portions 148a and 148b are engaged. 152 is formed. The engagement groove 152 includes an axial groove 154 formed in parallel with the spool shaft 26 and a spiral groove 156 that is continuous with the axial groove 154 and formed, for example, in a substantially spiral shape. Among these, the axial groove 154 is used when the inner protrusions 148 a and 148 b are attached to and detached from the outer magnet holder 128.

  When the rotation operation unit 124 is rotated in a state where the inner protrusions 148a and 148b of the rotation operation unit 124 are engaged with the engagement grooves 152 of the outer magnet holder 128, the rotation operation unit 124 The inner protrusions 148 a and 148 b press the spiral groove 156 of the engagement groove 152 of the outer magnet holder 128 in the axial direction of the spool shaft 26. That is, the outer magnet holder 128 moves along the axial direction of the spool shaft 26. As shown in FIGS. 8 and 14, the outer magnet holder 128 and the inner magnet holder 126 are configured to move integrally with each other in the axial direction of the spool shaft 26. It moves along the axial direction of the shaft 26.

As shown in FIGS. 10A to 10C, the rotation operation unit 124 includes an operation protrusion 160 via a protrusion 160 a extending from the annular portion 142. As shown in FIGS. 6 and 9, the operation protrusion 160 is formed so as to protrude from the lower surface US of the left side plate 116 b of the reel 10. Although not shown, an opening is defined on the lower surface US of the left side plate 116b so as to restrict the amount of rotation of the operation protrusion 160 within a predetermined range.
The operation protrusion 160 has a small protrusion amount that protrudes from the lower surface US of the left side plate 116b, and as explained in the first embodiment, when the fishing rod 8 and the reel 10 according to this embodiment are held and held. Is set so that the left hand LH does not hit.

  Then, as shown in FIGS. 13A to 13C, the operation protrusion 160 of the rotation operation unit 124 attached to the set plate 122 is operated, and the rotation operation unit 124 is moved with respect to the set plate 122. When rotated, the amount of the cylindrical portion 56c of the conductor 56 entering the annular gap 72 between the inner magnet 68 and the outer magnet 70 is changed as shown in FIGS. 14 (A) to 14 (C). The 13A is shown in FIG. 14A, the state shown in FIG. 13B is shown in FIG. 14B, and the state shown in FIG. 13C is shown in FIG. 14C. Correspond.

  In this embodiment, as shown in FIG. 12, the spiral groove 156 of the engagement groove 152 of the outer magnet holder 128 has three step portions 156a, 156b, and 156c in succession. Between the first step portion 156a and the second step portion 156b, there is a step (a portion that is not smoothly continuous) between the second step portion 156b and the third step portion 156c. A click feeling is obtained when the inner projecting portions 148a and 148b of 124 move between the first step portion 156a and the second step portion 156b or between the second step portion 156b and the third step portion 156c.

The first step portion 156a is located close to the axial groove 154. When the inner protrusions 148a and 148b are engaged with the first step portion 156a, as shown in FIG. The position (distance L1) of the disk-like portion 56b of the conductor 56 with respect to 68 and the outer magnet 70 is farthest. For this reason, the quantity by which the cylindrical part 56c of the conductor 56 is arrange | positioned between the magnets 68 and 70 is small.
The second step portion 156b is located between the first step portion 156a and the third step portion 156c on the innermost side of the spiral groove 156. As shown in FIG. 14B, the second step portion 156b is located inside the first step portion 156a. The position of the disk-shaped portion 56b of the conductor 56 relative to the inner magnet 68 and the outer magnet 70 is closer than the state in which the protruding portions 148a and 148b are engaged (distance L2 <L1). For this reason, the amount of the cylindrical portion 56c of the conductor 56 disposed between the magnets 68 and 70 is larger than the state in which the inner protrusions 148a and 148b are engaged with the first step portion 156a. .
The third step portion 156c is located on the innermost side of the spiral groove 156, and as shown in FIG. 14C, the inner side of the second step portion 156b is engaged with the inner protrusions 148a and 148b. The position of the disk-like portion 56b of the conductor 56 with respect to the magnet 68 and the outer magnet 70 is close (distance L3 <L2 <L1). For this reason, the amount of the cylindrical portion 56c of the conductor 56 disposed between the magnets 68 and 70 is larger than the state in which the inner protruding portions 148a and 148b are engaged with the second step portion 156b. .

  That is, when the operation protrusion 160 is rotated from the position shown in FIG. 13A toward the position shown in FIG. 13C, as shown in FIG. 14A to FIG. The amount of 56c entering the annular gap 72 gradually increases. For this reason, in the position shown in FIG.13 (C) and FIG.14 (C), a big magnetic force is received by the magnets 68 and 70. FIG. On the other hand, as shown in FIGS. 13A and 14A, when the amount of the cylindrical portion 56c entering the annular gap 72 decreases, the magnetic force received by the magnets 68 and 70 decreases. In this manner, the reference braking force of the spool 20 can be set by operating the rotation operation unit 124. The reference braking force (suppression force) increases as the first step portion 156a moves from the state in which the inner protrusions 148a and 148b are located to the second step portion 156b and the third step portion 156c and the rear side.

  When the spool 20 is rotated, an eddy current is generated in the conductor 56 due to the magnetic field of the inner ring magnet 68 and the outer ring magnet 70, but the cylindrical portion 56 c of the conductor 56 is between the magnets 68, 70. The rotation restraining force of the spool 20 is defined according to the amount (position where the inner protrusions 148a, 148b are engaged with the step portions 156a, 156b, 156c).

As shown in FIGS. 8, 15, and 16, the second operation mechanism 112 extends from the spool braking force adjustment unit (second operation unit) 172 and the inner magnet holder 126 of the first operation mechanism 110. And an interlocking gear 176 fixed to the distal end of the extending portion 174. Although the extension part 174 and the interlocking gear 176 may be integrated, it is preferable that the extension part 174 and the interlocking gear 176 are separate because they are easily assembled.
The spool braking force adjustment unit 172 includes a screw fixing portion 182 that can be screwed and fixed to the set plate 122 and the left frame 114b, and a rotation operation portion 184 that can rotate around the screw fixing portion 182. ing. The rotation operation unit 184 is moderately pressed against the set plate 122 by the screwing fixing unit 182 so that the rotation operation unit 184 does not rotate unless an appropriate force is applied.

The rotation operation unit 184 has, for example, a circular dial shape in which an anti-slip K due to unevenness is formed at the edge 184d of the outer peripheral part 184c. With such a circular dial shape, the abdomen of the thumb LT shown in FIG. 16 is pressed against the edge portion 184d straddling the outer peripheral portion 184c and the side surface 184e, and the contact area can be increased, and the thumb LT can be obtained. Can be distributed over a wide range. For this reason, the thumb LT of the left hand LH is unlikely to hurt, and the rotation operation unit 184 is easy to operate. In addition, when the thumb LT is pressed against the rotation operation unit 184, the belly of the finger bites into the concavo-convex portion, so that slipping during the operation can be prevented.
In addition, you may form the anti-slip | skid K by an unevenness | corrugation in the whole outer peripheral part 184c of the rotation operation part 184, or the whole side 184e. In addition, a scale 184f is formed on the radially inner side surface 184e of the rotation operation unit 184, and an index unit 190a is formed on the protective member 190 facing the rotation operation unit 184.

As shown in FIGS. 8, 15, and 16, a groove 184 a is formed, for example, in an annular shape on the side surface 184 e near the edge 184 d of the rotation operation unit 184. For this reason, when moisture adheres to the finger, the moisture can be released to the groove 184a, and the rotation operation unit 184 can be made difficult to slip. In particular, since the thumb LT is pressed into the recess 188 formed by the left side plate 116b, the pressing force of the thumb LT on the rotating operation unit 184 is reduced, and prevention of these slips is effective.
In addition, a leaf spring 192 that generates a clicking sound when being brought into contact with the set plate 122 is disposed in the rotation operation unit 184. For this reason, if the rotation operation part 184 is operated, a click sound will generate | occur | produce and an adjustment position becomes difficult to shift | deviate.
A rotation operation unit side gear 184 b is formed on the outer periphery of the rotation operation unit 184 of the spool braking force adjusting unit 80 and meshed with the interlocking gear 176. For this reason, if the rotation operation part 184 is rotated with respect to the left frame 114b, for example in the P direction in FIG. 6, the interlocking gear 176 is rotated in the Q direction via the rotation operation part side gear 184b. Then, the inner magnet holder 66 rotates in the R direction with respect to the outer magnet holder 128 via the extending portion 76 connected to the interlocking gear 176. For this reason, the relative position of the outer ring magnet 70 with respect to the inner ring magnet 68 changes. Thereby, the magnetic field strength of the annular gap 72 formed between the inner ring magnet 68 and the outer ring magnet 70 in which the cylindrical portion 56c of the conductor 56 is disposed can be finely adjusted.

  Therefore, a desired braking force can be applied to the spool 20 by combining the first operation mechanism 110 and the second operation mechanism 112.

  As shown in FIGS. 7 and 8, the left side plate 116b is formed as a cover that covers the left frame 114b and has a space that covers the first and second operating mechanisms 110 and 112 protruding leftward from the left frame 114b. Has been. The left side plate 116 b is formed with a recess (opening) 188 for pressing the thumb LT of the left hand LH so that a part of the rotation operation unit 184 of the second operation mechanism 112 can be operated.

As shown in FIG. 6, the concave portion 188 of the left side plate 116b is formed longer in the front-rear direction than in the vertical direction above and on the front side of the left side plate 116b. Here, the recess 188 is formed in a substantially parallelogram appearance. The rotation operation part 184 disposed on the left frame 114b is in a state where the outer peripheral part and a part of the side part (here, the upper side of the rotation operation part 184 as shown in FIGS. 5 and 6) can be visually recognized through the recess 188. It is in. And the rotation operation part 184 is outside in the state arrange | positioned inside this recessed part 188, without making it protrude outward from the extension surface S of the outer surface of the left side board 116b shown with a broken line in FIG.15 and FIG.16. It is exposed.
The distance from the extended surface S of the outer surface of the left side plate 116b indicated by a broken line in FIGS. 15 and 16 to the rotation operation unit 184 is, for example, about 0 mm to 5 mm, and is more preferably about 0.5 mm to 3.0 mm. preferable. That is, the rotation operation unit 184 is exposed so as not to protrude with respect to the outer surface OS of the left side plate 116b.

  The shape of the extended surface S varies depending on the shape around the recess 188 of the left side plate 116b. When the periphery of the recess 188 is a curved surface as in this embodiment, the extended surface S is also a curved surface, and when the periphery of the recess 188 is a flat surface, the extended surface S is also a flat surface. That is, in FIG. 15 and FIG. 16, since the periphery of the recess 188 is a curved surface, the broken line indicating the extended surface S is a curved line.

  The determination that the rotation operation portion 184 does not protrude outwardly from the extended surface S of the outer surface of the left side plate 116b is based on the horizontal direction and the vertical direction of the concave portion 188 when the reel mounting leg portion 18 is horizontally disposed. It shall be judged in the short dimension direction. In this embodiment, since the vertical direction of the recess 188 shown in FIG. 6 is shorter than the front-rear direction, a reference line (not shown) is taken on the extension surface S in the vertical direction of the recess 188, and the reference line It is determined whether or not the rotation operation unit 184 is protruding depending on whether or not it is touching. The reference line is a curved line in this embodiment because the periphery of the recess 188 is a curved surface. Further, this curved surface is defined in a form in which the curvature surface around the recess 188 is extended.

As shown in FIGS. 6, 15, and 16, the edge of the recess 188 of the left side plate 116b protects the thumb LT of the left hand LH, and dust is left between the recess 188 of the left side plate 116b and the left frame 114b. In order to prevent the intrusion, for example, an annular protective member 190 is fixed. The protective member 190 is preferably made of a resin material such as PTFE, nylon, ABS resin, or acetal resin (POM) as a material having a low hardness and a small friction coefficient.
The protective member 190 disposed on the lower edge of the recess 188 is fixed in a state of protruding outward from the lower edge of the recess 188 as a portion for placing the thumb LT. The protection member 190 disposed on the upper edge of the recess 188 extends from the inner peripheral surface of the left side plate 116b toward the rotation operation unit 184 so as to prevent intrusion of dust.
As shown in FIG. 16, when the thumb LT is pressed against the lower side of the protective member 190, the thumb LT applies a downward force. At this time, since the thumb LT rubs strongly against the protection member 190, the thumb LT is rounded into an R shape in order to prevent a burden from being applied to the thumb LT. The protective member 190 is preferably unpainted and unplated because the thumb LT rubs strongly.

  Then, the angler can press the thumb LT against the upper portion of the rotation operation unit 184 through the recess 188 of the left side plate 116b while holding the reel 10 with the left hand LH. For this reason, when the thumb LT pressed against the upper portion is moved in the front-rear direction along the protective member 190 of the recess 188, the turning operation portion 184 can be turned. When the spool 20 is rotated, an eddy current is generated in the conductor 56 due to the magnetic field generated by the inner ring magnet 68 and the outer ring magnet 70, and the rotation of the spool 20 is suppressed.

In the fishing tackle according to this embodiment, the operation projection 160 of the first operation mechanism 110 is exposed to be operable from the lower surface US of the left side plate 116b. And since the protrusion amount which the operation protrusion 160 protrudes from the lower surface US of the left side board 116b is small, and it is in the position where the left hand LH does not hit when the fishing rod 8 and the reel 10 are gripped and held, the fishing rod 8 and the reel with the left hand LH. 10 is held, there is a gap between the operation protrusion 160 of the first operation mechanism 110 and the left hand LH. For this reason, an erroneous operation of the operation protrusion 160 can be prevented. Further, since the rotation operation unit 184 of the second operation mechanism 112 is disposed inside the recess 188 of the left side plate 116b, it is possible to prevent the rotation operation unit 184 from being erroneously operated with the thumb LT of the left hand LH. That is, when the reel 10 is gripped and held, both the operation projection 160 and the rotation operation unit 184 are prevented from coming into contact with the left hand LH, so that there is a sense of incongruity when the fishing rod 8 and the reel 10 are gripped and held. In addition, the casting operation can be performed stably without any trouble without the operation protrusion 160 and the rotation operation unit 184 being in the way. Further, since it becomes difficult to apply external force to the operation projection 160 and the rotation operation unit 184 during actual fishing or when moving to the fishing spot, the operation projection 160 and the rotation operation unit 184 are damaged, or the operation projection 160 and the rotation operation unit 184 are damaged. It is possible to prevent the rotational operability of the motor from being deteriorated and the magnetic braking device 54 from being hindered.
In this embodiment, since the second operation mechanism 112 is provided in addition to the first operation mechanism 110, a wide braking force suitable for the actual situation of the fishing ground while maintaining good gripping and holding performance. Adjustment is possible.

Since the rotation operation unit 184 of the second operation mechanism 112 is disposed in the recess 188, the rotation operation unit 184 does not bite into the palm while holding the reel 10 with the left hand LH, and is gripped. The holding operation is good, and the rotation operation unit 184 can be easily operated by moving the thumb LT and placing the thumb LT on a part of the rotation operation unit 184 when necessary. In addition, an erroneous operation due to a finger strongly hitting the rotation operation unit 184 hardly occurs.
Further, by forming an anti-slip having unevenness on the rotation operation unit 184, the unevenness of the rotation operation unit 184 can be hooked on the thumb LT, and slipping when attempting to operate the rotation operation unit 184 is prevented. it can. Further, since the groove 184a is formed in the rotation operation portion 184, moisture during operation can be put into the groove 184a. For this reason, the slip of the thumb LT with respect to the rotation operation part 184 can be prevented more reliably. In particular, since the thumb LT is pressed into the recess 188, the pressing force from the thumb LT to the turning operation unit 184 is reduced, and prevention of these slips is effective.

  Although several embodiments have been specifically described so far with reference to the drawings, the present invention is not limited to the above-described embodiments, and all the embodiments performed without departing from the scope of the invention are described. Including implementation.

  OS ... outer surface, 12 ... reel body, 16b, 116b ... left side plate, 20 ... spool, 26 ... spool shaft, 28a, 28b ... ball bearing, 30 ... handle, 54 ... magnetic braking device, 56 ... conductor, 56a ... Boss part, 56b ... disk-like part, 56c ... cylindrical part, 58 ... receiving member, 60 ... central opening, 62a ... small diameter part, 62b ... large diameter part, 62 ... support base part, 64 ... annular groove, 66 ... magnet Holder, 68 ... Inner ring magnet, 70 ... Outer ring magnet, 72 ... Annular gap, 76 ... Extension part, 80 ... Spool braking force adjustment part, 86, 160 ... First operation part (rotation operation part), 184 ... 2nd operation part (rotation operation part).

Claims (4)

This is a fishing reel that supports a spool rotatably between side plates of the reel body, and that can adjust the braking force of a braking device that brakes the rotation of the spool through a first operation unit disposed on the side plate. And
Arranging the first operating part in the outer peripheral area of the lower part of the side plate opposite to the handle for winding the fishing line on the spool, and exposing it to the outside;
A fishing reel characterized in that the first operating portion can be operated with a finger of a hand holding and holding the reel body.   2. The fishing reel according to claim 1, wherein the first operation portion is provided at a lower portion of a side plate opposite to the handle and on the handle side from an outer surface of the side plate. . The first operation unit sets a reference braking force,
The side plate opposite to the handle is provided with a second operation portion that finely adjusts the braking force based on the reference braking force. Fishing reel. On the side plate opposite to the handle, a recess is formed inwardly from the outer surface of the side plate,
Without projecting the second operation portion outward from the extended surface of the outer surface of the side plate, the second operation portion is disposed in the recess and exposed to the outside.
The fishing reel according to claim 3, wherein the second operation unit can be operated by a finger of a hand holding the reel body.

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