JP2004298008A - Reel for fishing - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a reel for fishing instantaneously changing over a clutch mechanism from an OFF state to an ON state. <P>SOLUTION: This reel for fishing is characterized as follows. The reel is provided with a releasing part 70b installed in an engaging part 70 with a changeover member 48 and releasing an engaging state of a power transmission part 86a with the engaging part 70 in the initial stage in which a spool is changed over from a fishing line releasing state to a fishing line winding state and an urging means 76 for urging the changeover member 48 in which the engaging state with the power transmission part 86a is released to a changeover position corresponding to the fishing line winding state. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a fishing reel provided with a clutch mechanism that switches a spool rotatably supported between side plates of a reel body between a fishing line winding state and a fishing line releasing state.
[0002]
[Prior art]
As a method of switching the clutch mechanism, a method of automatically switching by using electric power, such as a motor and a solenoid, is conventionally known in addition to a method of switching manually. Such automatic switching of the clutch mechanism is used as a means for automatically performing a shelving operation or a shackle operation (see, for example, Patent Document 1).
[0003]
[Patent Document 1]
JP 2001-25342 A.
[0004]
[Problems to be solved by the invention]
In the technique disclosed in Patent Document 1, the spool mechanism is switched between a fishing line winding state and a fishing line releasing state by operating the clutch mechanism using the rotational force (reverse rotation) in one direction of the motor. Specifically, a slide plate as a switching member for switching between the two states is provided in the clutch mechanism, and the power of the motor provided in the reel body is transmitted from the planetary gear to the elongated hole formed in the slide plate. The boss part which transmits via the deceleration mechanism which becomes is engaged. The boss portion projects from a carrier that supports the planetary gear of the speed reduction mechanism, and converts the rotational power of the motor into a reciprocating linear motion through the elongated hole and transmits it to the slide plate. Then, the reciprocating linear movement of the slide plate between the switching positions corresponding to the fishing line winding state and the fishing line release state switches the spool between the fishing line winding state and the fishing line release state.
[0005]
However, in such a configuration, since the slide plate is always in engagement with the boss portion through the long hole, the slide plate performs reciprocating linear motion while being always restricted by the movement of the boss. That is, the moving speed of the slide plate, that is, the switching speed of ON / OFF of the clutch depends on the operating speed (rotational speed) of the boss portion via the speed reduction mechanism. Therefore, it is difficult to switch the clutch instantly.
[0006]
In particular, if the clutch mechanism cannot be instantaneously switched from the OFF state (fishing line release spool free state) to the ON state (fishing line winding state), the device cannot be reliably stopped at a predetermined shelf position, Affects fishing results. Further, if the switching speed of the clutch mechanism from OFF to ON is slow, the clutch engaging portion between the spool side and the drive side pinion cannot be engaged smoothly, and the clutch engaging portion may be deformed or damaged. is there.
[0007]
The present invention has been made paying attention to the above circumstances, and an object thereof is to provide a fishing reel capable of instantaneously switching the clutch mechanism from the OFF state to the ON state.
[0008]
[Means for Solving the Problems]
In order to solve the above-mentioned problems, the present invention includes a clutch mechanism that switches a spool rotatably supported between side plates of a reel body between a fishing line winding state and a fishing line releasing state, and the clutch mechanism that switches between the two states. The engaging portion of the switching member is engaged with a power transmission portion that transmits the power of the motor provided in the reel body, and the power of the motor is transmitted to the switching member via the power transmission portion. In the fishing reel in which the spool is switched between the two states, the engagement portion of the switching member is provided in the engagement portion, and the engagement is performed at the initial stage when the spool is switched from the fishing line discharge state to the fishing line winding state. An opening portion for releasing the engagement state of the power transmission portion with respect to the joint portion, and the switching member released from the engagement state with the power transmission portion are moved to a switching position corresponding to the fishing line winding state. Characterized by comprising a biasing means for biasing.
[0009]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
1 to 10 show a first embodiment of the present invention. As shown in FIGS. 1 and 2, the fishing electric reel 1 as a fishing reel according to this embodiment includes a reel body 2. A spool shaft 6 is rotatably supported between the left and right frames 4 a and 4 b of the reel body 2 via a bearing, and a spool 8 is disposed so as to surround the spool shaft 6. The left and right side plates 10a and 10b are attached to the left and right frames 4a and 4b.
[0010]
A spool drive motor 12 (hereinafter simply referred to as a motor) is held between the left and right frames 4a and 4b on the front side (fishing line feeding direction side) of the spool 8 (spool shaft 6). On the upper side, a level wind mechanism (not shown) for winding the fishing line around the spool 8 in parallel is arranged. In the figure, reference numeral 150 denotes an output lever for adjusting the winding output when the motor 12 is rotating forward.
[0011]
The motor 12 is configured to be capable of normal rotation and reverse rotation, and has a left drive shaft 12a extending to one end side (left frame 4a side) and a right drive shaft extending to the other end side (right frame 4b side). 12b. The right drive shaft 12b is connected to a clutch operating mechanism 13 described later via a one-way clutch (hereinafter referred to as a first one-way clutch) 11, and the left drive shaft 12a is connected to a one-way clutch (hereinafter referred to as a first clutch). 2 is connected to a later-described interlocking gear mechanism via 15.
[0012]
The first one-way clutch 11 is in a free-rotation state when the motor 12 rotates in the forward direction so that the driving force of the right drive shaft 12b is not transmitted to the clutch operating mechanism 13, while the motor 12 is rotated in the reverse direction. At this time, the driving force is transmitted, and the driving force of the right drive shaft 12b is transmitted to the clutch operating mechanism 13.
[0013]
The second one-way clutch 15 is in a driving force transmission state when the motor 12 rotates forward, and transmits the driving force of the left driving shaft 12a to the interlocking gear mechanism, while the motor 12 rotates in the reverse direction. At this time, the engine is in a free rotation state so that the driving force of the left drive shaft 12a is not transmitted to the interlocking gear mechanism.
[0014]
Here, the state where the motor 12 is rotating forward means that the interlocking gear mechanism is driven via the second one-way clutch 15 to transmit a driving force for rotating the spool 8 in the fishing line winding direction. On the other hand, the state in which the motor 12 is rotating reversely means that the clutch operating mechanism 13 is driven via the first one-way clutch 11 to control a clutch mechanism 40 described later. It means that there is.
[0015]
The interlocking gear mechanism includes a drive gear 17 connected to the second one-way clutch 15, an intermediate gear 19 meshed with the drive gear 17, and a spool drive gear 14 meshed with the intermediate gear 19. The spool driving gear 14 is non-rotatably fitted to one end side (the left frame 4a side) of the spool shaft 6.
[0016]
The intermediate gear 19 is supported by a fixed shaft 21 that is prevented from rotating around the left frame 4a. Between the fixed shaft 21 and the intermediate gear 19, a one-way clutch (hereinafter referred to as a third one-way clutch). ) 23 is inserted.
[0017]
The third one-way clutch 23 rotates the intermediate gear 19 in one direction and does not rotate in the other direction. Specifically, when the motor 12 rotates forward and the driving force is transmitted to the driving gear 17 via the second one-way clutch 15, the rotational movement of the driving gear 17 is transferred to the spool driving gear 14. As transmitted, the intermediate gear 19 is allowed to rotate in one direction by the third one-way clutch 23. On the other hand, when the manual handle 60 is rotated to rotate the spool 8 in the fishing line winding direction as will be described later, the intermediate gear is controlled so as to restrict the rotation of the spool shaft 6 (spool driving gear 14). 19 is in a state where rotation in the other direction is restricted (stopped) by the third one-way clutch 23.
[0018]
The level wind mechanism is linked to the rotational movement when the spool 8 is rotated in the fishing line winding direction by the motor 12 or when the spool 8 is rotated in the fishing line winding direction by a handle operation described later. It is comprised so that it can drive.
[0019]
Further, a speed reduction mechanism 20 including first and second planetary gear mechanisms 16 and 18 is provided on the other end side (right frame 4b side) of the spool shaft 6. The rotational movement of the spool shaft 6 during normal rotation is decelerated by the first planetary gear mechanism 16 and then further decelerated by the second planetary gear mechanism 18 and transmitted to the spool 8.
[0020]
The first planetary gear mechanism 16 includes a first sun gear 22 that is rotationally fitted to the spool shaft 6, a plurality of first planetary gears 24 that mesh with the first sun gear 22, and the first planetary gears 24. The planetary gear 24 is provided with an internal gear 26 engraved on the end face of the spool 8 so that the planetary gear 24 always meshes. The plurality of first planetary gears 24 are respectively supported by a first carrier 32, and the first carrier 32 is supported so as to be freely rotatable with respect to the spool shaft 6.
[0021]
The second planetary gear mechanism 18 includes a second sun gear 28 fixed to the first carrier 32 and a plurality of second planetary gears 30 meshed with the second sun gear 28. The plurality of second planetary gears 30 are always meshed with the internal gear 26. Each of the plurality of second planetary gears 30 is supported by a second carrier 34, and the second carrier 34 is fitted to a bracket 36 attached to the spool 8 and via a bearing 37. The spool shaft 6 is rotatably supported. The bracket 36 is rotatably supported by the right frame 4b via a bearing 39.
[0022]
On the other end side of the spool shaft 6, a clutch mechanism 40 that is driven (clutch ON / OFF switching control) by a clutch operation mechanism 13 described later is disposed between the right frame 4b and the right side plate 10b. Yes.
The clutch mechanism 40 includes a pinion 42 that is slidable along the spool shaft 6 and that engages or disengages with the speed reduction mechanism 20 (specifically, the second carrier 34).
[0023]
In the present embodiment, the pinion 42 is indirectly engaged with or disengaged from the spool shaft 6 via the speed reduction mechanism 20 (second carrier 34) by ON / OFF switching control of the clutch mechanism 40 by the clutch operation mechanism 13. For example, in a fishing double bearing type reel (not shown) in which the speed reduction mechanism 20 is not disposed on the other end side of the spool shaft 6, the clutch mechanism 40 is controlled by ON / OFF switching control. The pinion 42 may be directly engaged with or disengaged from the spool shaft 6.
[0024]
The pinion 42 is formed with a circumferential groove 42a on the outer peripheral surface thereof. A yoke 44, which is a slide piece, is engaged with the circumferential groove 42a. The yoke 44 slides the pinion 42 along the spool shaft 6 by ON / OFF switching control of the clutch mechanism 40 by the clutch operation mechanism 13.
[0025]
Further, the yoke 44 slides along the spool shaft 6 while being guided by a pair of guide rods 46 (see FIG. 3 and the like) extending along the axial direction of the spool shaft 6. As a configuration for sliding the yoke 44 along the spool shaft 6, the clutch mechanism 40 is switched so as to be slidable in the fixed directions D 1 and D 2 in conjunction with the ON / OFF switching control of the clutch mechanism 40 by the clutch operating mechanism 13. A slide plate 48 as a member is provided. On the surface of the slide plate 48, an inclined cam (inclined surface) 48 a that engages with the yoke 44 and slides it along the spool shaft 6 is formed. Further, an engaging portion 70 is provided at the end of the slide plate 48 so as to be detachably engaged with a boss 86a described later. The engaging portion 70 includes a long groove 70a with which the boss 86a can be engaged, and an open portion 70b formed at one end of the long groove 70a.
[0026]
In the present embodiment, a position detection device for detecting the position of the slide plate 48 is provided. As shown in FIG. 3 and the like, the position detection device includes a pair of magnets 130 and 131 (130; clutch ON detection magnet 131; attached to the slide plate 48 and separated along the moving direction of the slide plate 48; A clutch OFF detection magnet) and a magnetic sensor (reed switch) 132 mounted and fixed on a support plate 75 fixed to the reel body 2 so as to face the magnet 130, and slides in the ON / OFF state of the clutch. When the position of the plate 48 is magnetically detected by the magnetic sensor 132, a stop signal is sent to the motor 12 to stop it. Thereby, the ON / OFF state of the clutch is maintained.
[0027]
Further, as shown in detail in FIG. 5, for example, a pair of springs 76 as urging means are interposed between the right side plate 10 b and the yoke 44. These springs 76 are wound around the above-described guide rod 46 extending from the support plate 75 fixed to the reel body 2, and the yoke 44 is constantly biased toward the slide plate 48, thereby Accordingly, the pinion 42 is constantly urged in the direction in which the pinion 42 is engaged with the second carrier 34. The pinion 42 and the second carrier 34 are engaged by engaging the clutch engaging portion 42b of the pinion 42 with the clutch engaging portion 34a of the second carrier 34. The guide rod 46 is provided with a screw hole 46a into which a screw member 92 for fixing the right side plate 10b to the support plate 75 is screwed.
[0028]
As shown in FIG. 2, a drive gear 52 attached to the handle shaft 50 is engaged with the pinion 42, and the spool 8 is connected between the drive gear 52 and the handle shaft 50 during actual fishing. A well-known drag mechanism 54 capable of applying a desired drag force to the spool 8 when the fishing line is fed out is disposed.
[0029]
Further, in order to prevent the handle shaft 50 from rotating in conjunction with the spool 8 when the spool 8 is rotated in the fishing line winding direction by the motor 12 during actual fishing, the handle shaft 50 has a reverse rotation prevention mechanism. Is provided. For example, as shown in FIG. 3, the reverse rotation prevention mechanism includes a ratchet 56 having ratchet claws 56a formed on the outer peripheral surface at a predetermined pitch, and a stopper that is always engaged with the ratchet claws 56a with a constant urging force. 58, and the ratchet 56 is fitted to the handle shaft 50 in a non-rotating manner.
[0030]
According to such a reverse rotation prevention mechanism, when the spool 8 is rotated by the motor 12 in the fishing line winding direction, the handle 58 is interlocked with the rotation of the motor 12 by engaging the stopper 58 with the ratchet pawl 56a. 50 can be prevented from rotating, and the power of the motor 10 is transmitted to the spool 8 via the speed reduction mechanism 20. In contrast, when the manual handle 60 attached to the handle shaft 50 is rotated to rotate the spool 8 in the fishing line winding direction, the handle shaft 50 is moved in conjunction with the rotation of the manual handle 60. It can be rotated.
Next, the configuration of the clutch operation mechanism 13 will be described.
[0031]
As shown in detail in FIG. 2, the clutch operating mechanism 13 is connected to the right drive shaft 12 b of the motor 12 via the first one-way clutch 11, and the first one-way when the motor 12 rotates in the reverse direction. Using the driving force of the right drive shaft 12b output from the clutch 11, the clutch mechanism 40 is driven (clutch ON / OFF switching control), and the pinion 42 is moved with respect to the speed reduction mechanism 20 (second carrier 34). It is configured so that it can be engaged or disengaged.
[0032]
Specifically, the clutch operating mechanism 13 is connected to the first one-way clutch 11 and transmits a driving force when the motor 12 rotates in the reverse direction, and a rotational movement of the driving force transmitting shaft 90. Clutch operating first and second planetary gear mechanisms 110 and 112 that decelerate and transmit to the clutch mechanism 40 side are provided.
[0033]
The first planetary gear mechanism 110 includes a first sun gear 72 that is prevented from rotating by the driving force transmission shaft 90, a plurality of first planetary gears 74 that mesh with the first sun gear 72, and the first planetary gears 74. The planetary gear 74 is always engaged with an internal gear 96, and the internal gear 96 is fixed to the right frame 4 b via a support frame 78.
[0034]
On the other hand, the second planetary gear mechanism 112 includes a second sun gear 80 supported so as to be freely rotatable with respect to the driving force transmission shaft 90 and a plurality of second planetary gears meshed with the second sun gear 80. The plurality of second planetary gears 82 are always meshed with the internal gear 96.
[0035]
Each of the plurality of first planetary gears 74 is rotatably supported by the first carrier 84, and the first carrier 84 is connected to the second sun gear 80 and rotated integrally therewith. It is like that. Each of the plurality of second planetary gears 82 is rotatably supported by a second carrier 86, and the second carrier 86 is connected to the slide plate 48 of the clutch mechanism 40. In this case, the second carrier 86 is supported by the driving force transmission shaft 90 and has a boss 86 a as a power transmission portion that engages with the engagement portion 70 of the slide plate 48.
[0036]
Next, the operation of winding or unwinding the fishing line by controlling the ON / OFF switching of the clutch mechanism 40 by the clutch operating mechanism 13 will be described.
[0037]
When the switch 190A disposed on the operation panel 190 (see FIGS. 1 and 3) mounted on the surface of the reel body 2 (the surface facing the angler) is operated, the clutch operating mechanism 13 turns on the clutch mechanism 40. / OFF switching control. That is, a clutch ON state (a state where the pinion 42 is engaged with the second carrier 34 of the speed reduction mechanism 20; a state where the fishing line can be wound) and a clutch OFF state (a state where the pinion 42 is not engaged with the second carrier 34) A state in which the spool 8 can be freely rotated).
[0038]
First, in the state where the clutch mechanism 40 is controlled to be switched to the clutch OFF state (the state shown in FIGS. 6 and 7), the yoke 44 resists the biasing force of the spring 76 by the inclined cam 48a of the slide plate 48, and the right side plate 10b. Since the pinion 42 is disengaged from the second carrier 34 of the speed reduction mechanism 20, the spool 8 is maintained in a freely rotatable state. In this state, the fishing line is fed out from the spool 8 by the free fall of the device.
[0039]
When the fishing line is fed out by a desired amount (for example, when the device reaches a desired shelf), when the switch 190A on the operation panel 190 is turned ON, the motor 12 is rotated in reverse, and the reverse movement at that time is the left drive shaft 12a. And output to the right drive shaft 12b. At this time, the left drive shaft 12a is connected to the interlocking gear mechanism via the second one-way clutch 15, and the second one-way clutch 15 is in a free rotation state when the motor 12 is reversely rotated. Therefore, the driving force of the left drive shaft 12a is not transmitted to the interlocking gear mechanism. On the other hand, the right drive shaft 12b is connected to the clutch operating mechanism 13 via the first one-way clutch 11, and this first one-way clutch 11 has a driving force when the motor 12 rotates in the reverse direction. Since the transmission state is established, the driving force of the right drive shaft 12 b is transmitted to the clutch operation mechanism 13.
[0040]
The driving force of the right drive shaft 12 b transmitted to the clutch operation mechanism 13 is decelerated by the first planetary gear mechanism 110 and then decelerated by the second planetary gear mechanism 112. First, the driving force of the right drive shaft 12b transmitted to the first planetary gear mechanism 110 is transmitted to the first sun gear 72 via the drive force transmission shaft 90, and the first sun gear 72 is transmitted to the predetermined sun gear 72. Rotate in the direction. At this time, due to the rotational movement of the first sun gear 72, the plurality of first planetary gears 74 revolve along the internal gear 96 at the same time while rotating.
[0041]
Since the plurality of first planetary gears 74 are rotatably supported by the first carrier 84, when the plurality of first planetary gears 74 revolve while rotating, the first planetary gears 74 are dragged by the revolving motion, The carrier 84 rotates. At this time, the rotational motion of the first carrier 84 is transmitted to the second planetary gear mechanism 112.
[0042]
The rotational movement of the first carrier 84 transmitted to the second planetary gear mechanism 112 is transmitted to the second sun gear 80 connected to the first carrier 84, and the sun gear 80 is moved in a predetermined direction. Rotate. At this time, due to the rotational movement of the second sun gear 80, the plurality of second planetary gears 82 revolve along the internal gear 96 while rotating.
[0043]
Since the plurality of second planetary gears 82 are rotatably supported by the second carrier 86, when the plurality of second planetary gears 82 revolve while rotating, the second planetary gears 82 are dragged by the revolving motion, The carrier 86 rotates. Further, when the second carrier 86 rotates, the boss 86a also starts to rotate with the rotation. Specifically, the boss 86a starts to rotate in the direction indicated by the arrow R in FIG. 6 from the clutch OFF state shown in FIG. 6, and slides along the long groove 70a of the engaging portion 70 of the slide plate 48. At the same time, the rotational motion of the second carrier 86 is converted into a linear motion in the direction of arrow D2 and transmitted to the slide plate 48.
[0044]
When the slide plate 48 slides in the direction of the arrow D2 in this manner, the yoke 44 begins to be detached from the inclined cam 48a, and the biasing force of the spring 76 biasing the yoke 44 toward the slide plate 48 causes the slide plate 48 to slide. 48 is instantaneously slid to the clutch ON state without being restricted by the operation of the boss 86a. Hereinafter, this will be described in more detail with reference to FIGS.
[0045]
8 is the same as FIG. 6, that is, the yoke 44 is moved to the right side plate 10 b against the urging force of the spring 76 by the inclined cam 48 a of the slide plate 48, and the pinion 42 is detached from the second carrier 34. The clutch OFF state is shown. In this state, the yoke 44 is located at the upper end of the inclined cam 48a and is most distant from the slide plate 48 (see FIG. 8B).
[0046]
From this state, when the boss 86a rotates in the direction indicated by the arrow R, the initial stage (here, "initial" is the total rotation angle of the boss 86a from the fishing line discharge state to the fishing line winding state). Since the boss 86a slides along the long groove 70a of the engaging portion 70 of the slide plate 48 at the stage before reaching half of the stage (in this embodiment, the stage before the boss 86a rotates 90 °), the slide The plate 48 is slid in the direction of the arrow D2 while being restrained by the boss 86a. When the boss 86a is positioned at the opening 70b of the engaging portion 70, the engaged state between the boss 86a and the engaging portion 70 is released. Therefore, the slide plate 48 is not restricted by the rotation of the boss 86a. At this time, as shown in FIG. 9B, the yoke 44 is positioned on the inclined surface of the inclined cam 48a. Therefore, the biasing force F of the spring 76 that presses the yoke 44 against the inclined surface. Moves the yoke 44 along the inclined surface to slide the slide plate 48 in the direction of arrow D2. That is, when the boss 86a is released through the opening 70b of the slide plate 48, the arrow D2 is applied not by the boss 86a (without being restrained by the boss 86a) but by the biasing force of the spring 76b via the yoke 44. And is instantaneously shifted to the clutch ON state prior to the rotation of the boss 86a (see the two-dot chain line in FIG. 9A).
[0047]
Then, the boss 86a that is rotated later is engaged in the long groove 70a of the engaging portion 70 of the slide plate 48 that has been moved prior to the clutch ON state (see FIG. 10A). At the time, the reverse rotation of the motor 12 is stopped by the magnetic detection of the magnet 130 by the magnetic sensor 132, and this clutch ON state is maintained. In this clutch ON state, as shown in FIGS. 4 and 5, the yoke 44 is completely detached from the inclined cam 48 a and pressed against the slide plate 48 by the biasing force of the spring 76, and the clutch engaging portion 42 b of the pinion 42. Is completely engaged with the clutch engaging portion 34 a of the second carrier 34.
[0048]
In this embodiment, the rotation of the motor 12 is controlled to stop every 180 ° by detecting the moving position of the slide plate 48. However, as another method for realizing this control, for example, a motor The number of rotations of 12 is electrically or magnetically counted, the rotational position of the second carrier 86 that rotates in conjunction with the motor 12 is detected, or the output state of the current value to the motor 12 is monitored and this current is monitored. A method of stopping the current output when the value exceeds a predetermined value can be exemplified.
[0049]
When the motor 12 is rotated forward by, for example, a switch operation of the operation panel 190 in a state where the clutch mechanism 40 is switched to the clutch ON state (fishing line winding enabled state) by the clutch operating mechanism 13, the forward rotation motion is driven to the left. It is output to the shaft 12a and the right drive shaft 12b, respectively.
[0050]
The right drive shaft 12b is connected to the clutch control mechanism 13 via the first one-way clutch 11, and the first one-way clutch 11 is in a free rotation state when the motor 12 rotates forward. The driving force of the right drive shaft 12b is not transmitted to the clutch operation mechanism 13. On the other hand, the left drive shaft 12a is connected to the interlocking gear mechanism via the second one-way clutch 15, and this second one-way clutch 15 is driven when the motor 12 rotates forward. Since the transmission state is established, the driving force of the left drive shaft 12a is transmitted to the interlocking gear mechanism.
[0051]
The driving force of the left driving shaft 12a transmitted to the interlocking gear mechanism is transmitted from the driving gear 17 connected to the second one-way clutch 15 to the spool driving gear 14 via the intermediate gear 19, and the spool shaft 6 is Rotate in the fishing line feeding direction (the opposite direction to the fishing line winding direction). Then, the rotational movement of the spool shaft 6 is transmitted to the spool 8 via the speed reduction mechanism 20 (the first planetary gear mechanism 16 and the second planetary gear mechanism 18).
[0052]
The rotational motion of the spool shaft 6 transmitted to the first planetary gear mechanism 16 rotates the first sun gear 22 fitted to the spool shaft 6 in the fishing line feeding direction. At this time, the plurality of first planetary gears 24 meshed with the first sun gear 22 revolves around the first sun gear 22 in the fishing line feeding direction while rotating in the fishing line winding direction.
[0053]
In this state, the rotation of the plurality of first planetary gears 24 is transmitted to the internal gear 26 engraved on the end face of the spool 8 and rotates the internal gear 26 in the fishing line winding direction. As a result, the spool 8 in which the internal gear 26 is engraved can be rotated in the fishing line winding direction while being decelerated by the first planetary gear mechanism 16. Further, when the plurality of first planetary gears 24 revolve in the fishing line feeding direction, the first carrier 32 supporting the first planetary gears 24 rotates in the fishing line feeding direction by being dragged by the revolving motion. The rotational motion is transmitted to the second planetary gear mechanism 18.
[0054]
The rotational motion of the first carrier 32 transmitted to the second planetary gear mechanism 18 is transmitted to the second sun gear 28 connected to the first carrier 32, and the second sun gear 28 is fed to the fishing line. Rotate in the feeding direction. At this time, the plurality of second planetary gears 30 meshed with the second sun gear 28 and supported by the second carrier 34 are rotated while rotating the second planetary gears 30 in the fishing line winding direction. At the same time, a force that revolves around the second sun gear 28 in the fishing line feeding direction is exerted, and by the revolving motion, a force that rotates in the fishing line feeding direction acts on the second carrier 34.
[0055]
However, since the rotation of the handle shaft 50 is restricted by the aforementioned reverse rotation prevention mechanism, the rotation of the pinion 42 connected to the handle shaft 50 via the drive gear 52 is also restricted. As a result, the second carrier 34 with which the pinion 42 is engaged is kept stationary at a fixed position without rotating. Therefore, when the second sun gear 28 rotates in the fishing line feeding direction, the plurality of second planetary gears 30 supported by the second carrier 34 do not revolve around the second sun gear 28, Rotates in the fishing line winding direction at a fixed position.
[0056]
In this state, the rotation of the plurality of second planetary gears 28 is transmitted to the internal gear 26 engraved on the end face of the spool 8 and rotates the internal gear 26 in the fishing line winding direction. As a result, the spool 8 in which the internal gear 26 is engraved can be rotated in the fishing line winding direction while being decelerated by the second planetary gear mechanism 18.
[0057]
Thus, the rotational movement of the spool shaft 6 is transmitted to the spool 8 via the speed reduction mechanism 20 (the first planetary gear mechanism 16 and the second planetary gear mechanism 18), and the spool 8 is moved in the direction of winding the fishing line. During the rotation, the level winding mechanism (not shown) is driven at the same time, so that the fishing line can be wound in parallel with the spool 8.
[0058]
When the motor 12 is stopped and the manual handle 60 is rotated, the rotational motion of the manual handle 60 is transmitted from the handle shaft 6 to the drive gear 52 via the drag mechanism 54 and then from the pinion 42 to the speed reduction mechanism. 20 (specifically, the second carrier 34), and the second carrier 34 is rotated in the direction of winding the fishing line. Since the plurality of second planetary gears 30 are supported by the second carrier 34, when the second carrier 34 rotates in the fishing line winding direction, this rotational movement is caused by the plurality of second planetary gears 30. Is transmitted to the first carrier 32 via the second sun gear 28 and then to the first sun gear 22 via the plurality of first planetary gears 24 supported by the first carrier 32. The first sun gear 22 is transmitted and tries to rotate. However, since the rotation of the spool shaft 6 with which the first sun gear 22 is prevented from rotating is stopped (restricted) by the third one-way clutch 23 described above, The gear 22 does not rotate. Accordingly, the plurality of first planetary gears 22 revolve in the fishing line winding direction while rotating around the non-rotating first sun gear 22. At this time, the rotational motion of the plurality of first planetary gears 22 is transmitted to the internal gear 26 without loss, and the internal gear 26 is rotated in the direction of winding the fishing line. As a result, the spool 8 in which the internal gear 26 is engraved can be rotated in the fishing line winding direction. At the same time, the level winding mechanism is driven, so that the fishing line can be wound around the spool 8 in parallel.
[0059]
Further, when the clutch mechanism 40 is in the clutch ON state in this way, the clutch 190 can be set to the clutch OFF state again by turning OFF the switch 190A on the operation panel 190. That is, when the switch 190A on the operation panel 190 is turned OFF, the motor 12 rotates again, and the reverse movement at that time is output to the left drive shaft 12a and the right drive shaft 12b, respectively. In this case, since the second one-way clutch 15 is in a free rotation state, the driving force of the left drive shaft 12a is not transmitted to the interlocking gear mechanism. On the other hand, since the first one-way clutch 11 is in the driving force transmission state, the driving force of the right drive shaft 12b is transmitted to the clutch operation mechanism 13. As described above, the driving force of the right drive shaft 12b transmitted to the clutch operation mechanism 13 is transmitted to the clutch mechanism 40 after being decelerated by the first and second planetary gear mechanisms 110 and 112, and the slide plate 48. Is slid in the direction of arrow D1. Specifically, when the boss 86a is rotated by the clutch operation mechanism 13 from the clutch OFF state shown in FIG. 10, the boss 86a is moved to the 180 ° rotation position (clutch OFF state position) shown in FIG. While sliding along the long groove 70a of the engaging portion 70 of the slide plate 48, the slide plate 48 is always restrained and slid in the direction of the arrow D1 (the state during the slide is shown by a two-dot chain line in FIG. )
[0060]
When the slide plate 48 slides in the direction of the arrow D1, the yoke 44 is lifted against the spring 76 biasing the yoke 44 by the inclined cam 48a (the axis along the pair of guide rods 46). The pinion gear 42 is disengaged from the carrier 34. At this time, since the magnet 131 is detected by the magnetic sensor 132, the reverse rotation of the motor 12 is stopped, and this clutch OFF state is maintained. As a result, the spool 8 is maintained in a freely rotatable state, and in this state, the fishing line is fed out of the spool 8 by the free fall of the device.
[0061]
As described above, the fishing electric reel 1 of the present embodiment is provided in the engaging portion 70 of the slide plate 48 as a switching member, and the spool 8 is initially switched from the fishing line discharge state to the fishing line winding state. The release portion 70b for releasing the engagement state of the boss (power transmission portion) 86a with respect to the engagement portion 70 at the stage and the slide plate 48 in which the engagement state with the boss 86a is released correspond to the fishing line winding state. And a spring 76 as urging means for urging the switching position. Therefore, when the clutch mechanism is switched back from the fishing line release state to the fishing line winding state, the engagement state between the boss 86a and the engagement portion 70 (long groove 70a) is released by the release portion 70b in the initial stage, and thereafter The slide plate 48 can be slid to the clutch ON state by the force of the spring 76 without being restricted by the motor power that has been decelerated and rotated. Therefore, quick switching operation from clutch OFF to clutch ON is possible, smooth and reliable clutch engagement between the spool side and the drive side pinion can be performed, deformation and breakage of the clutch engagement portion can be prevented, and shelf stop can also be performed This can be done with little error.
[0062]
In this embodiment, when the fishing line is fed out by a desired amount (for example, when the device reaches a desired shelf), the motor 12 is reversed by turning on the switch 190A on the operation panel 190. The clutch can be switched from OFF to ON. As shown in FIG. 2, a magnet 150 is integrally provided on the spool 8, and the magnet 150 is magnetically detected by the magnetic sensor 152. It is also possible to detect the feeding amount of the fishing line accompanying the rotation of the spool 8 and send a signal for reversing the motor 12 from the magnetic sensor 152 when the fishing line feeding amount is reached.
[0063]
FIG. 11 shows a configuration in the vicinity of the engaging portion 70 of the clutch mechanism 40 of the fishing reel according to the second embodiment of the present invention. In the first embodiment described above, the open portion 70b communicating with the long groove 70a is formed by cutting out the engaging portion 70. In this embodiment, the long groove 70a is formed without cutting out the engaging portion 70. An open portion 70 b ′ is formed by a closed space formed by bulging the end of the slide plate 48 in the longitudinal direction of the slide plate 48. In this case, the open portion 70b 'is formed in a size that does not interfere with the boss 86a in the closed space portion.
[0064]
Thus, in this embodiment, since the engaging part 70 is not notched, the strength of the engaging part 70 is higher than that of the first embodiment.
[0065]
FIGS. 12 and 13 show a configuration in the vicinity of the engaging portion 70 of the clutch mechanism 40 of the fishing reel according to the third embodiment of the present invention. As shown in the drawing, in the present embodiment, an open portion 70b ″ that allows the boss 86a in the long groove 70a to escape is formed by causing the engaging portion 70 to protrude in an inverted concave shape at the end of the long groove 70a. In FIG. 13, the position of the boss 86a corresponding to FIG. 9 is indicated by a two-dot chain line.
[0066]
Thus, in the present embodiment, since the open portion 70b ″ does not bulge in the longitudinal direction of the slide plate 48 as in the second embodiment, the slide plate 48 can be made compact in the longitudinal direction.
[0067]
FIG. 14 shows the configuration of a clutch mechanism for a fishing reel according to a fourth embodiment of the present invention. As illustrated, in this embodiment, a separate spring 99 is provided between the support plate 75 and the slide plate 48 to urge the slide plate 48 in the direction of arrow D2 (clutch ON direction). In the first embodiment, the spring force of the spring 76 that biases the yoke 44 is indirectly used to move the slide plate 48 to the switching position corresponding to the clutch ON state. Then, the slide plate 48 is directly moved by the spring 99 to the switching position corresponding to the clutch ON state. Of course, in the present embodiment having such a configuration, the slide plate 48 may be moved using not only the spring 99 but also the spring force of the two springs 76 and 99 in combination.
[0068]
【The invention's effect】
According to the fishing reel of the present invention, the clutch mechanism can be instantaneously switched from the OFF state to the ON state.
[Brief description of the drawings]
FIG. 1 is a front view of a fishing reel according to a first embodiment of the present invention.
2 is a cross-sectional view of the fishing reel of FIG. 1. FIG.
3 is a configuration diagram of a clutch mechanism of the fishing reel of FIG. 1. FIG.
FIG. 4 is an enlarged longitudinal sectional view of the clutch mechanism in a clutch ON state.
FIG. 5 is an enlarged cross-sectional view of the vicinity of a yoke in the state of FIG.
FIG. 6 is an enlarged longitudinal sectional view of the clutch mechanism in a clutch OFF state.
7 is an enlarged cross-sectional view of the vicinity of a yoke in the state of FIG.
FIG. 8 is a state diagram in the vicinity of the engaging portion of the slide plate when the clutch is OFF.
FIG. 9 is a state diagram in the vicinity of the engaging portion of the slide plate during the transition from the clutch OFF to the clutch ON.
FIG. 10 is a state diagram in the vicinity of the engaging portion of the slide plate when the clutch is ON.
FIG. 11 is a configuration diagram of the vicinity of an engaging portion of a clutch mechanism of a fishing reel according to a second embodiment of the present invention.
FIG. 12 is a configuration diagram of the vicinity of an engaging portion of a clutch mechanism of a fishing reel according to a third embodiment of the present invention.
13 is a cross-sectional view taken along line AA in FIG.
FIG. 14 is a configuration diagram of a clutch mechanism of a fishing reel according to a fourth embodiment of the present invention.
[Explanation of symbols]
2 Reel body
8 spools
40 Clutch mechanism
48 Slide plate (switching member)
70 engaging part
70b Open part
76 Spring (biasing means)
86a Boss (power transmission part)

Claims (1)

A clutch mechanism for switching a spool rotatably supported between the side plates of the reel body between a fishing line winding state and a fishing line releasing state is provided, and the engaging portion of the switching member of the clutch mechanism for switching between the two states includes a reel The power transmission unit that transmits the power of the motor provided in the main body is engaged, and the power of the motor is transmitted to the switching member via the power transmission unit, so that the spool is switched to the two states. In the fishing reel
An opening portion provided in the engaging portion of the switching member, and releasing the engagement state of the power transmission portion with respect to the engaging portion at an initial stage when the spool is switched from a fishing line discharge state to a fishing line winding state;
Biasing means for biasing the switching member released from the engagement state with the power transmission unit to a switching position corresponding to the fishing line winding state;
A fishing reel comprising:

Images