JP6046385B2 - Electric reel level winding mechanism - Google Patents

Description

  The present invention relates to a level wind mechanism, and more particularly to a level wind mechanism for an electric reel in which a motor mounted on a reel body is disposed in front of a spool.

  2. Description of the Related Art Conventionally, an electric reel in which a motor for driving a spool is disposed in front of the spool is known. The motor is housed in a cylindrical motor housing disposed in front of the motor spool. In the reel in which the motor is arranged in front of the spool, if the fishing line guide of the level wind mechanism is arranged in front of the motor, the distance to the spool becomes long, and the bobbin shape varies and is not stable. Therefore, an electric reel in which a fishing line guide is disposed between a motor and a spool is conventionally known (see FIG. 9 of Patent Document 1).

JP 2012-090645 A

  In the conventional level wind mechanism, since the fishing line guide is disposed between the motor and the spool, there is a possibility that the fishing line coming out of the fishing line guide may come into contact with the outer peripheral surface of the motor storage unit. When contacted, the fishing line feed speed tends to decrease.

  An object of the present invention is to prevent a fishing line from coming into contact with a housing portion of a motor in a level wind mechanism of an electric reel in which a motor is disposed in front of a spool.

  The level winding mechanism of the electric reel according to the first aspect is a mechanism in which a motor housed in the reel body is disposed in front of the spool. The level wind mechanism includes a fishing line guide and a traverse cam shaft. The fishing line guide has a cylindrical guide portion that extends in the front-rear direction across the center of the motor above the motor and guides the fishing line. The traverse cam shaft is formed with a spiral groove intersecting the outer peripheral surface, and reciprocally moves the fishing line guide in a direction parallel to the rotation axis of the spool in conjunction with rotation of the spool in the line winding direction.

  In this level wind mechanism, a tubular guide portion of a fishing line guide that reciprocates as the traverse cam shaft rotates extends substantially in the front-rear direction across the center of the motor. For this reason, the fishing line passing right above the motor is guided to the cylindrical guide portion. This prevents the fishing line from coming into contact with the motor housing.

  The level winding mechanism of the electric reel according to a second aspect of the invention is the mechanism according to the first aspect, wherein the traverse cam shaft is disposed in front of the center of the motor. In this case, even if the traverse cam shaft is disposed in front of the center of the motor, the rear end portion of the guide portion is disposed at a position close to the spool, so that the bobbin shape is stabilized.

  The level winding mechanism of the electric reel according to a third aspect of the invention is the mechanism according to the first or second aspect, wherein the traverse cam shaft is disposed above the center of the motor. In this case, since the traverse cam shaft is disposed above the center of the motor, the distance between the guide portion and the traverse cam shaft is shortened, and the fishing line guide that moves due to the rotation of the traverse cam shaft is less likely to rattle. , Can guide the fishing line stably.

  The level winding mechanism of the electric reel according to a fourth aspect of the invention is the mechanism according to any one of the first to third aspects, wherein the guide portion is inclined upward so that the front end portion is farther from the motor than the rear end portion. In this case, since the guide portion is tilted forward, even if water from a wet fishing line adheres to the guide portion, the attached water is easily removed from the guide portion due to the inclination.

  The level winding mechanism of the electric reel according to a fifth aspect of the present invention is the mechanism according to any one of the first to fourth aspects, wherein the guide portion is a cylindrical shape that allows the fishing line to pass therethrough and is disposed across the center of the motor. It has a passage part and at least one hard ring part arranged inside the passage part. In this case, since the fishing line comes into contact with the hard ring portion, even if the fishing line comes into contact, the guide portion is hardly worn. Further, by smoothing the surface of the hard ring portion, even if the fishing line comes into contact, the feeding speed is unlikely to decrease.

  The level winding mechanism of the electric reel according to a sixth aspect of the present invention is the mechanism according to any one of the first to fifth aspects, wherein the fishing line guide includes a guide body and an engaging member. The guide main body has a guide portion and a storage portion formed integrally with the guide portion, and the traverse cam shaft passes therethrough. The engaging member is housed in the housing portion and engages with the spiral groove. In this case, the fishing line guide reciprocates by engaging the engaging member with the spiral groove intersecting the traverse cam shaft.

  The level winding mechanism of the electric reel according to a seventh aspect is the mechanism according to the sixth aspect, wherein the motor is housed in a cylindrical motor housing portion provided in the reel body. The guide body is formed to be curved along the outer peripheral surface of the motor storage portion from the guide portion toward the storage portion. In this case, since the storage part in which the engaging member is stored from the guide part is formed along the outer peripheral surface of the motor storage part, the guide body can be compactly arranged.

  An electric reel level wine mechanism according to an eighth aspect of the present invention is the mechanism according to the sixth or seventh aspect, further comprising a first guide shaft and a second guide shaft. The first guide shaft is disposed parallel to the traverse cam shaft through the guide portion at the spool-side end of the guide portion. The second guide shaft passes through the guide body between the guide portion and the storage portion and is disposed in parallel with the traverse cam shaft. In this case, in addition to the conventionally provided second guide shaft, by providing the first guide near the entrance where the fishing line is guided when the line is fed, the fishing line is less likely to be entangled. In addition, the second guide shaft can reinforce the guide portion having a long length in the front-rear direction. Accordingly, the fishing line guide is stably guided, and the reciprocating movement of the fishing line guide becomes smooth.

  An electric reel according to a ninth aspect includes a motor, a spool, and the level wind mechanism according to any one of the first to eighth aspects.

  In this case, an electric reel that exhibits the above-described effects can be obtained.

  According to the present invention, the fishing line passing right above the motor is guided to the cylindrical guide portion. This prevents the fishing line from coming into contact with the motor housing.

The top view of the electric reel by 1st Embodiment of this invention . The front view. The right side view . The left side view . The bottom view. The right view of the electric reel of the state which removed the 2nd side cover. Sectional drawing by the cutting line VII-VII of FIG. Sectional drawing by the cutting line VIII-VIII of FIG. Sectional drawing by the cutting line IX-IX of FIG. The left view of the electric reel of the state which removed the 1st side cover. The left view of the electric reel of the state which removed the heat sink cover. FIG. 7 is a partial side view of the rear part of FIG. 6. The figure equivalent to FIG. 9 of the electric reel by 2nd Embodiment of this invention.

<First Embodiment>
1, FIG. 2, FIG. 3, FIG. 4, FIG. 5 and FIG. 6, the electric reel 100 which is a dual bearing reel according to the first embodiment of the present invention is driven by electric power supplied from an external power source. A reel having a power source when used as a manually wound reel. The electric reel is a reel having a water depth display function for displaying the water depth of the device according to the yarn feeding length or the yarn winding length. In the following description, the front-rear direction in which the fishing line is unwound is referred to as a first direction X, and the left-right direction orthogonal thereto is referred to as a second direction Y.

  The electric reel 100 includes a reel body 1 that can be attached to a fishing rod, a handle 2 that is rotatably attached to the reel body 1, a star drag 3 that is disposed on the inside of the handle 2, and a reel 1 A spool 10 for bobbin winding disposed inside.

<Structure of reel body>
As shown in FIGS. 7 and 8, the reel body 1 includes a frame 7, a first side cover 8 a, a second side cover 8 b, a front cover 9, and a counter case 4. The frame 7 connects the integrally formed first side plate 7a, the first side plate 7a, the second side plate 7b arranged at an interval in the second direction Y, and the first side plate 7a and the second side plate 7b. A first connecting member 7c and a second connecting member 7d. The first side cover 8 a covers the side opposite to the mounting side of the handle 2 of the frame 7. The second side cover 8 b covers the handle 2 mounting side of the frame 7. The front cover 9 covers the front part of the frame 7.

  As shown in FIG. 7, a circular opening 7e through which the spool 10 can pass is formed in the first side plate 7a. In the circular opening 7e, a spool support portion 17 that rotatably supports the first end (the right end in FIG. 7) of the spool shaft 14 of the spool 10 is centered and mounted.

  As shown in FIGS. 7 and 11, the spool support portion 17 is a substantially circular member. The spool support portion 17 is fixed to the outer surface of the first side plate 7a with screws at a plurality of locations (for example, three locations) arranged at intervals in the circumferential direction. The spool support portion 17 includes a bearing storage portion 17a for storing a first bearing 18a that supports the first end of the spool shaft 14, and two boss portions 17b for fixing a heat radiation cover 8d (to be described later) of the first side cover 8a. And have. Further, the spool support portion 17 has a sensor arrangement portion 17c where a spool sensor 63 for detecting the rotation of the spool 10 is arranged. The bearing housing portion 17a protrudes from the outer surface of the spool support portion 17 and is formed in a bottomed cylindrical shape. The boss portion 17 b is formed to protrude outward in the axial direction from the outer surface of the spool support portion 17.

  The sensor placement portion 17c has a wall portion 17d surrounding the periphery. When the electrical wiring to the substrate on which the spool sensor 63 is mounted is completed, the sensor placement portion 17c is sealed with a synthetic resin sealant in the wall portion 17d. Thereby, the spool sensor 63 is insulated.

  The spool sensor 63 includes, for example, two magnetic force sensors (for example, a reed switch or a hall element) 63a and 63b that can detect the magnetic force arranged side by side in the rotation direction of the spool 10. The spool 10 has a magnet 10 a at a position that can face the spool sensor 63. By detecting the magnet 10a, the rotational speed and rotational position of the spool 10 can be detected. Further, the rotation direction (the yarn winding direction or the yarn unwinding direction) of the spool 10 can be detected depending on which of the magnetic force detection sensor 63a and the magnetic force sensor 63b detects the magnet 10a first.

  As shown in FIGS. 7 and 8, the second side plate 7b is provided for mounting various mechanisms. Between the second side plate 7b and the second side cover 8b, a spool drive mechanism 13, a clutch control mechanism 20 for controlling a clutch mechanism 16 described later, and a casting control mechanism 21 are provided.

  Between the first side plate 7a and the second side plate 7b, a spool 10, a clutch mechanism 16, and a level wind mechanism 22 according to an embodiment of the present invention for uniformly winding a fishing line around the spool 10 are provided. ing. The clutch mechanism 16 switches between a power transmission state (clutch on) for transmitting power to the spool 10 and a power cutoff state (clutch off) for shutting off the power. A clutch operating member 11 for turning on and off the clutch mechanism 16 is swingably provided between the first side plate 7a and the second side plate 7b at the rear portion of the reel body 1. The clutch operating member 11 swings between a clutch-on position indicated by a solid line in FIG. 12 and a clutch-off position indicated by a two-dot chain line.

  The reel body 1 is disposed on the outer surface of the second side plate 7b with a space in the second direction Y from the second side plate 7b, and a mechanism for mounting the above mechanism in the space between the second side cover 8b. A mounting plate 19 is further provided. The mechanism mounting plate 19 is fixed to the outer surface of the second side plate 7b with screws.

  The 1st connection member 7c connects the lower part of the 1st side board 7a and the 2nd side board 7b in two places front and back. The second connecting member 7 d connects the front part of the spool 10. The first connecting member 7c is a plate-like portion, and a rod attachment leg 7f for attaching to a fishing rod is integrally formed at a substantially central portion in the left-right direction. The second connecting member 7d is a substantially cylindrical portion disposed in front of the spool 10, and a motor 12 for driving the spool 10 (see FIGS. 7 and 9) is accommodated therein. Therefore, the motor 12 is disposed in front of the spool 10. The opening of the second connecting member 7d on the first side plate 7a side is closed by, for example, a metal motor holding portion 15 such as an aluminum alloy.

  As shown in FIGS. 7 and 11, the motor holding portion 15 is a substantially disk-shaped member. The motor holding portion 15 is fixed to the first side plate 7a with screws at a plurality of locations. The motor holding unit 15 fixes the motor 12 with screws. The motor holding portion 15 is provided with a clutch housing portion 15a in which a reverse rotation prohibiting portion 44 having a roller type one-way clutch for prohibiting the rotation of the motor 12 in the yarn unwinding direction and a connection terminal for the motor 12 are arranged. A terminal arrangement hole 15b and two positioning protrusions 15c are provided. The motor holding part 15 has one mounting boss 15d. The clutch housing portion 15a is formed in a bottomed cylindrical shape so as to protrude to the outer surface. The terminal arrangement hole 15b is sealed with a sealant after the electrical wiring is connected. A seal member such as an O-ring is attached between the motor holding portion 15 and the second connecting member 7d. These prevent the liquid from entering the second connecting member 7d. The mounting boss 15 d protrudes axially outward from the outer surface of the motor holding portion 15. A radiation fin 41 for cooling the motor 12 is fixed to the mounting boss 15d with screws.

  The heat radiation fin 41 is made of, for example, an aluminum alloy. The radiation fin 41 has a plurality of linear convex portions 41a on the outer surface for increasing the surface area. The radiation fin 41 has two positioning recesses 41b positioned on the positioning protrusions 15c on the inner surface. Moreover, the radiation fin 41 has a mounting leg 41c extending toward the mounting boss 15d. The mounting leg 41c is fixed to the mounting boss 15d of the motor holding portion 15 with screws.

  The first side cover 8a is, for example, screwed to the outer edge portion of the first side plate 7a. On the lower surface of the front portion of the first side cover 8a, a connector 43 for connecting a power cable is attached downward as shown in FIG. The first side cover 8 a includes a cover body 8 c that covers the rear side of the side portion of the electric reel 100 and a heat dissipation cover 8 d that covers the front side of the side portion of the electric reel 100. The cover body 8c is screwed to the first side plate 7a.

  The heat radiation cover 8 d covers the heat radiation fins 41. The heat dissipation cover 8d has a plurality of slits 8e in order to improve the heat dissipation performance of the heat dissipation fins 41. The heat radiating fins 41 can be seen through the slits 8e. As shown in FIG. 10, the heat radiating cover 8d is not the cover main body 8c, but the rear portion is screwed to the spool support portion 17 at a plurality of locations (for example, two locations), and the front portion is located at the front portion of the first side plate 7a. It is screwed with. Thereby, the whole 1st side cover 8a can be reduced in size, and it becomes easy to assemble the 1st side cover 8a which covers the radiation fin 41. FIG. Moreover, even if sink marks occur in the heat dissipation cover 8d in which the plurality of slits 8e are formed, it is easy to match the cover body 8c. Furthermore, since the first side cover 8a is divided into the cover main body 8c and the heat radiating cover 8d, wiring to the motor 12 and the like is facilitated.

  A first boss portion 8f for rotatably supporting a drive shaft 30 to which the handle 2 is connected so as to be integrally rotatable is formed on the second side cover 8b so as to protrude outward. A second boss portion 8g that supports the second end of the spool shaft 14 is formed to protrude outward from the first boss portion 8f. Above the first boss portion 8f of the second side cover 8b, an adjustment lever 5 (see FIG. 3) for controlling the motor 12 to a plurality of stages (for example, 31 stages) is swingably supported. . A rotary encoder (not shown) is connected to the adjustment lever 5. As shown in FIG. 5, a step 8h and a step 7g are formed at intervals in the second side cover 8b and the lower portion of the second side plate 7b, respectively. This gap functions as a drain hole 56 for draining water that has entered the inside of the reel body 1.

  The front cover 9 is fixed with screws, for example, at two locations on the upper and lower front surfaces of the first side plate 7a and the second side plate 7b. The front cover 9 is formed with a horizontally long opening 9a (FIG. 2) for fishing line passage.

<Configuration of counter case>
As shown in FIGS. 1, 8, and 9, the counter case 4 is placed on top of the first side plate 7a and the second side plate 7b and fixed to the outer surfaces of the first side plate 7a and the second side plate 7b with screws. Has been. Inside the counter case 4 is housed a display 61 composed of a water depth display liquid crystal display. In addition, inside the counter case 4, a reel control unit 60 (FIG. 13) composed of, for example, a microcomputer for controlling the motor 12 and the display 61 is provided.

  On the upper surface of the counter case 4, as shown in FIG. 9, a rectangular opening 4a from which the display 61 is exposed is formed. The opening 4a is covered with a transparent cover member 4b made of synthetic resin. As shown in FIG. 1, an operation key portion 62 is disposed behind the opening 4a (downward in FIG. 1). The operation key unit 62 includes a motor control selection switch SW1, a 0-set switch SW2, and a high-cut switch SW3 arranged side by side. The motor control selection switch SW1 is a switch for selecting either a tension mode for controlling the motor 12 in the constant tension mode or a speed mode for controlling in the constant speed mode. The 0 set switch SW2 is a switch for setting a water depth display value to 0 by arranging a device on the water surface before fishing. The high cut switch SW3 is a switch for setting the water depth display value to 0 by arranging a device on the water surface when the fishing line is cut off in the middle. The counter case 4 has a groove 4c formed along the second direction Y on the lower surface.

<Spool configuration>
As shown in FIG. 7, the spool 10 is attached to the spool shaft 14 so as to be integrally rotatable. The spool 10 includes a cylindrical bobbin trunk 10b, and a large-diameter first flange 10c and a second flange 10d that are integrally formed on both sides of the bobbin trunk 10b. The spool 10 is of a deep groove type in which the diameter of the bobbin trunk 10b is considerably smaller than the diameter of the first flange 10c and the second flange 10d (for example, less than half the diameter). The magnet 10a described above is fixed to the first flange portion 10c. The spool shaft 14 is fixed to the inner peripheral portion of the bobbin trunk 10b by appropriate fixing means such as press fitting.

  The first end of the spool shaft 14 is supported by the first bearing 18a by the spool support portion 17 as described above. The second end (the right end in FIG. 7) of the spool shaft 14 is supported by the second bearing 18b on the second boss portion 8g of the second side cover 8b.

  The spool shaft 14 includes a large diameter portion 14a to which the spool 10 is fixed, a first small diameter portion 14b on the first end side of the large diameter portion 14a, and a second small diameter portion 14c on the second end side of the large diameter portion 14a. ,have. A clutch pin 16a constituting the clutch mechanism 16 is attached through the radial direction on the second small diameter portion 14c side from the spool fixing portion of the large diameter portion 14a.

<Configuration of clutch mechanism and clutch control mechanism>
The clutch mechanism 16 includes a clutch pin 16a, and a clutch recess 16b formed in a cross shape along the radial direction on the right end surface of the pinion gear 32 described later in FIG. The pinion gear 32 constitutes the clutch mechanism 16 and the first rotation transmission mechanism 45 described later. The pinion gear 32 moves along the direction of the spool shaft 14 between the clutch-on position shown in FIG. 7 and the clutch-off position on the left side of FIG. 3 from the clutch-on position. At the clutch-on position, the clutch pin 16a engages with the clutch recess 16b, and the rotation of the pinion gear 32 is transmitted to the spool shaft 14, and the clutch mechanism 16 enters the clutch-on state. In this clutch-on state, the pinion gear 32 and the spool shaft 14 can rotate together. In the clutch-off position, the clutch recess 16b is separated from the clutch pin 16a, and the rotation of the pinion gear 32 is not transmitted to the spool shaft 14. For this reason, the clutch mechanism 16 is in a clutch-off state, and the spool 10 can freely rotate.

  The clutch control mechanism 20 swings the clutch operating member 11 between a clutch-on position indicated by a solid line in FIG. 12 and a clutch-off position indicated by a two-dot chain line in FIG. Switch to. As shown in FIG. 12, the clutch control mechanism 20 moves to an on position (solid line in FIG. 12) and an off position (two-dot chain line in FIG. 12) according to the movement of the clutch operating member 11 between the clutch on position and the clutch off position. A rotating clutch plate 20a is provided. The clutch plate 20a rotates around the spool shaft 14, for example. The clutch plate 20a is provided with a detector 42 of a clutch sensor 64 that detects that the clutch mechanism 16 is in a clutch-off state. The detector 42 has an arm part 42a that moves integrally with the clutch plate 20a, and a magnet 42b provided at the tip of the arm part 42a. The clutch sensor 64 is mounted on a sensor substrate 55 provided on the second side plate 7b. The clutch sensor 64 has a magnetic sensor (for example, a hall element or a reed switch) that can detect the magnetic force. In the clutch sensor 64, when the clutch plate 20a is in the on position, the magnet 42b is disposed on the clutch sensor 64. Therefore, the clutch sensor 64 is turned on when the clutch operating member 11 is in the on position, and is turned off when the clutch operating member 11 is out of the on position. That is, the clutch sensor 64 detects that the clutch mechanism 16 is in the OFF state by detecting that the clutch operating member 11 is not in the clutch on position.

<Configuration of level wind mechanism>
As shown in FIG. 9, the level wind mechanism 22 is a mechanism that reciprocates the fishing line in the second direction Y in conjunction with the rotation in the line winding direction of the spool 10 that rotates relative to the reel body 1 and feeds the fishing line forward. is there. The level wind mechanism 22 includes a fishing line guide 23, a traverse cam shaft 24, and a guide sensor 65. The traverse cam shaft 24 has a spiral groove 24a intersecting the outer peripheral surface, and reciprocates the fishing line guide 23 in the second direction Y. The guide sensor 65 detects that the fishing line guide 23 is in a predetermined position. The traverse cam shaft 24 is an example of a reciprocating mechanism. The guide sensor 65 is an example of a fishing line guide detection unit.

  The fishing line guide 23 includes a guide main body 25 having a guide portion 25 a and an engaging member 26. The guide portion 25a is formed in a cylindrical shape, and extends substantially in the first direction X with a center line CL extending in the vertical direction passing through the center MC of the motor 12 above the motor 12. In this embodiment, the guide portion 25a extends obliquely along the first direction X so that the front end portion is farther from the motor 12 than the rear end portion. As a result, the guide portion 25a is disposed so as to incline forward, and the water adhering to the inside of the guide portion 25a due to the fishing line is easily removed.

The guide portion 25a allows a fishing line to pass therethrough, a cylindrical passage portion 25b disposed with the center MC of the motor 12 interposed therebetween, and at least one hard ring portion 25c disposed inside the passage portion 25b. ,have. In this embodiment, the hard ring portion 25c is a cylindrical member that is longer than the length in the longitudinal direction of the passage portion 25b. The rear end of the hard ring portion 25c is disposed so as to protrude from the rear end of the passage portion 25b. The hard ring portion 25c is made of metal or hard ceramic, for example. Both ends of the inner peripheral surface of the hard ring portion 25c are formed in a fillet shape having a circular cross section.

  The passage portion 25b has a detector housing portion 25d that protrudes so as to be engaged with the groove portion 4c of the counter case 4 at the upper portion on the front end side. A magnet 28 that functions as a detector detected by the guide sensor 65 is stored in the detector storage portion 25d. The magnet 28 is detected by the guide sensor 65 when the fishing line guide 23 is disposed at a predetermined position. For example, as shown in FIG. 2, the predetermined position is a position corresponding to a substantially center position in the second direction Y of the spool 10.

  The guide body 25 is arranged along the second connecting member 7d from the passage portion 25b and is disposed in front of the second connecting member 7d. The guide body 25 has a storage portion 25e in which the engaging member 26 is stored at the tip. A first guide shaft 27a and a second guide shaft 27b that guide the fishing line guide 23 in the second direction Y pass through the rear portion of the passage portion 25b and the middle portion of the guide body 25 in the vertical direction.

  The first guide shaft 27a and the second guide shaft 27b are arranged along the second direction Y, and both ends thereof are fixed to the first side plate 7a and the second side plate 7b, respectively. Thus, in addition to the conventionally provided second guide shaft 27b, by providing the first guide shaft 27a in the vicinity of the entrance where the fishing line is guided when the line is fed, the fishing line is less likely to get entangled. Further, it is possible to reinforce the guide portion 25a having a long length in the front-rear direction with respect to the conventional guide portion. Thereby, the fishing line guide 23 is stably guided in the second direction Y, the reciprocating movement of the fishing line guide 23 becomes smooth, and the position detection accuracy of the guide sensor 65 is improved.

  The engaging member 26 is disposed along the vertical direction, and has a plate-like engaging portion 26 a that engages with the spiral groove 24 a at the tip. The engaging member 26 is rotatably attached to the end portion of the storage portion 25e.

  The traverse cam shaft 24 is disposed through the guide main body 25. The traverse cam shaft 24 is disposed above and in front of the center MC of the motor 12. The traverse cam shaft 24 is covered with an arc-shaped cover portion 29 that covers a part of the outer peripheral surface. The cover part 29 penetrates the guide body 25 and also functions as a guide member in the second direction Y of the fishing line guide 23. When the traverse cam shaft 24 rotates, the fishing line guide 23 reciprocates in the second direction Y. The traverse cam shaft 24 is driven by the spool drive mechanism 13. A driven gear 50 (see FIGS. 6 and 7) to which the driving force is transmitted from the spool driving mechanism 13 is mounted on the end of the traverse cam shaft 24 on the handle mounting side.

  As shown in FIG. 9, the guide sensor 65 is provided above the groove portion 4 c in the lower part of the counter case 4. The guide sensor 65 has a magnetic sensor (for example, a hall element or a reed switch) that can detect the magnetic force of the magnet 28. The guide sensor 65 is disposed at the center position in the moving direction of the fishing line guide 23 (generally the position facing the center position in the second direction Y of the spool 10). That is, the guide sensor 65 is provided corresponding to a predetermined position. Thus, when the guide sensor 65 detects the magnet 28, it can be detected that the fishing line guide 23 has moved to a predetermined position.

<Configuration of spool drive mechanism>
The spool drive mechanism 13 drives the spool 10 in the yarn winding direction. Further, a drag force is generated on the spool 10 during winding to prevent the fishing line from being cut. As shown in FIGS. 6, 7, and 8, the spool drive mechanism 13 includes a motor 12, a reverse rotation prohibition unit 44 that prohibits rotation of the motor 12 in the yarn unwinding direction, a first rotation transmission mechanism 45, A rotation transmission mechanism 46. The first rotation transmission mechanism 45 decelerates the rotation of the motor 12 and transmits it to the spool 10. The second rotation transmission mechanism 46 increases the speed of the rotation of the handle 2 via the first rotation transmission mechanism 45 and transmits the rotation to the spool 10. In FIG. 6, the arrows indicate the rotation directions of the respective gears in the yarn winding direction.

  The first rotation transmission mechanism 45 has a planetary gear mechanism 47 connected to the output shaft 12 a of the motor 12. The planetary gear mechanism 47 reduces the rotation of the motor 12 with a reduction ratio in the range of 1/20 to 1/30 and transmits it to the spool 10. The planetary gear mechanism 47 has a first planetary speed reduction mechanism 48 connected to the output shaft 12 a of the motor 12 and a second planetary speed reduction mechanism 49 connected to the first planetary speed reduction mechanism 48. The planetary gear mechanism 47 is housed in a case 51 that is rotatably supported at both ends by the second side plate 7b and the mechanism mounting plate 19. An internal gear 51 a of the first planetary speed reduction mechanism 48 and the second planetary speed reduction mechanism 49 is formed on the inner peripheral surface of the case 51. The sun gear of the first planetary reduction mechanism 48 is coupled to the output shaft 12a so as to be integrally rotatable. The sun gear of the second planetary speed reduction mechanism 49 is coupled to the carrier of the first planetary speed reduction mechanism 48 so as to be integrally rotatable. The output of the internal gear 51 a formed in the case 51 is transmitted to the spool 10 and the level wind mechanism 22. Therefore, the first rotation transmission mechanism 45 is an example of a rotation transmission mechanism. The first rotation transmission mechanism 45 transmits the rotation of the motor 12 to the spool 10 via the clutch mechanism 16 without passing through the drive shaft 30 of the handle 2, and at the level winding on the motor 12 side than the clutch mechanism 16. A rotation transmission path for transmitting to the mechanism 22 is provided.

  The first rotation transmission mechanism 45 further includes a first gear member 52, a second gear member 53 that meshes with the first gear member 52, and a pinion gear 32 that meshes with the second gear member 53. The first gear member 52 is formed on the outer periphery of the case 51 of the planetary gear mechanism 47. Accordingly, the first gear member 52 can rotate integrally with the internal gear. The first gear member 52 also meshes with the driven gear 50 of the level wind mechanism 22. The second gear member 53 is disposed between the mechanism mounting plate 19 and the outer surface of the second side plate 7b. The second gear member 53 is an intermediate gear for transmitting the rotation of the first gear member 52 to the pinion gear 32 with the rotation direction aligned. The second gear member 53 is rotatably supported by the mechanism mounting plate 19. The pinion gear 32 is mounted on the second side plate 7b so as to be rotatable around the spool shaft 14 and movable in the axial direction. The pinion gear 32 is controlled by the clutch control mechanism 20 and moves in the axial direction between the clutch-on position and the clutch-off position.

  As shown in FIGS. 6 and 8, the second rotation transmission mechanism 46 includes a drive shaft 30, a drive gear 31, a third gear member 54, a drag mechanism 33, to which the handle 2 is connected so as to be integrally rotatable. have.

  As shown in FIG. 6, the drive shaft 30 is rotatably supported by the second boss portion 8f of the second side plate 7b and the second side cover 8b. A drag washer 37 of a drag mechanism 33 is attached to the drive shaft 30 so as to be integrally rotatable. The handle 2 is connected to the tip of the drive shaft 30 so as to be integrally rotatable. In addition, a ratchet wheel 35 of the first one-way clutch 34 is mounted on the drive shaft 30 so as to be integrally rotatable. The ratchet wheel 35 is mounted in a state where movement in the axially inward direction (left side in FIG. 6) is restricted. The ratchet wheel 35 is prohibited from rotating in the yarn feeding direction by a ratchet claw (not shown). The base end of the drive shaft 30 is rotatably supported by a bearing (not shown) on the second side plate 7b. The drive shaft 30 is supported by the first boss 8f of the second side cover 8b by a roller-type second one-way clutch 36. The drive shaft 30 is prohibited from rotating in the yarn feeding direction by the first one-way clutch 34. The drag mechanism 33 can be operated by prohibiting the rotation of the drive shaft 30 in the yarn feeding direction. The second one-way clutch 36 quickly inhibits the rotation of the drive shaft 30 in the yarn unwinding direction.

  The drive gear 31 is rotatably mounted on the drive shaft 30. The drive gear 31 is pressed by the drag washer 37 of the drag mechanism 33. The drive gear 31 is braked by the drag mechanism 33 for rotation in the yarn drawing direction. As a result, the rotation of the spool 10 in the yarn unwinding direction is braked.

  The third gear member 54 is provided to transmit the rotation of the handle 2 to the spool 10. As shown in FIG. 7, the third gear member 54 is coupled to the carrier of the second planetary reduction mechanism 49 so as to be integrally rotatable. The third gear member 54 meshes with the drive gear 31 and transmits the rotation of the handle 2 to the carrier of the second planetary reduction mechanism 49. The rotation transmitted to the carrier is transmitted to the pinion gear 32 via the first gear member 52 and the second gear member 53. The reduction ratio from the third gear member 54 to the second gear member 53 is generally “1”.

  The drag mechanism 33 has a drag washer 37 and a star drag 3 for adjusting the drag force. The drag mechanism 33 is provided to brake the rotation of the spool 10 in the line-feeding direction and prevent the fishing line from being cut. The drag mechanism 33 causes the spool 10 to idle in the yarn feeding direction when a force greater than the set drag force acts on the spool 10.

As shown in FIG. 7, the casting control mechanism 21 is a mechanism that presses both ends of the spool shaft 14 to brake the spool 10.
In the level wind mechanism 22, when the spool 10 is rotated in the line winding direction by the handle 2 or the motor 12, the level wind mechanism 22 is operated and the fishing line guide 23 is reciprocated in the left-right direction, and the fishing line is drawn in front of the spool 10. invite. Thereby, the fishing line is wound around the spool 10 as evenly as possible.

  On the other hand, when the clutch operating member 11 is operated to the clutch-off position and the fishing line is fed out from the spool 10, the motor 12 rotates. The rotation of the motor 12 is transmitted to the traverse cam shaft 24 of the level wind mechanism 22 via the first rotation transmission mechanism 45, and the fishing line guide 23 moves in the spool shaft direction. Then, when the fishing line guide 23 moves to a predetermined position (for example, near the center position of the horizontal movement range of the fishing line guide 23), this is detected by the guide sensor 65, and the fishing line guide 23 is arranged at the predetermined position. . Thereby, in the level wind mechanism 22 that reciprocates when winding the yarn, the resistance at the time of unwinding the yarn can be reduced.

  Further, when the fishing line guide 23 guides the fishing line, the fishing line passing right above the motor 12 is guided to the cylindrical guide portion 25a. As a result, the fishing line does not come into contact with the second connecting member 7d, which is the storage portion of the motor 12.

Second Embodiment
In the first embodiment, the guide portion 25a of the fishing line guide 23 is arranged to greatly exceed the center MC of the motor 12 and to the vicinity of the spool 10, but the present invention is not limited to this, and the guide portion is the What is necessary is just to arrange | position across the center MC.

  In FIG. 13, in the guide main body 125 of the fishing line guide 123 of the level wind mechanism 122 according to the second embodiment, the length in the front-rear direction of the passage portion 125b of the guide portion 125a is shorter than the passage portion 25b of the first embodiment. The rear end portion of the passage portion 125b of the second embodiment is disposed slightly behind the center line CL passing through the center MC of the motor 12. Further, the rear end of the hard ring 125c is disposed so as to be recessed from the rear end of the passage portion 125b. Both ends of the inner peripheral surface of the hard ring 125c are formed in a fillet shape having a circular cross section.

The fishing line guide 123 is guided in the second direction Y by the second guide shaft 27 b and the cover portion 29. In the second embodiment, the first guide shaft 27a does not fulfill the guiding function of the fishing line guide 123, but is provided to prevent the fishing line fed from the spool 10 from coming into contact with the outer peripheral surface of the second connecting member 7d. ing. The first guide shaft 27a may not be provided.

  Since the configuration of the other electric reels is the same as that of the first embodiment, description thereof is omitted.

  In 2nd Embodiment, the rear-end part of the guide part 125a is arrange | positioned ahead of the guide part 25a of 1st Embodiment. For this reason, the resistance at the time of thread | yarn delivery becomes smaller than the level wind mechanism 22 of 1st Embodiment.

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

(A) The level reel mechanism 22 of the electric reel is a mechanism in which the motor 12 housed in the reel body 2 is disposed in front of the spool 10. The level wind mechanism 22 includes a fishing line guide 23 and a traverse cam shaft 24. The fishing line guide 23 has a cylindrical guide portion 25a that extends in the front-rear direction substantially above the motor 12 with the center of the motor 12 interposed therebetween and guides the fishing line. Traverse cam shaft 24, a spiral groove 24a is formed which intersects the outer peripheral surface, reciprocating the fishing Itoga id 23 in the line winding direction parallel to the spool shaft 14 in conjunction with the rotation direction of at least the spool 10.

  In the level wind mechanism 22, a cylindrical guide portion 25 a of a fishing line guide 23 that reciprocates as the traverse cam shaft 24 rotates extends substantially in the front-rear direction across the center MC of the motor 12. For this reason, the fishing line passing right above the motor 12 is guided to the cylindrical guide portion 25a. As a result, the fishing line does not come into contact with the second connecting member 7d, which is the storage portion of the motor 12.

  (B) In the level wind mechanism 22, the traverse cam shaft 24 is disposed in front of the center MC of the motor 12. In this case, even if the traverse cam shaft 24 is disposed in front of the center MC of the motor 12, the rear end portion of the guide portion 25a is disposed at a position close to the spool 10, so that the bobbin shape is stabilized.

  (C) In the level wind mechanism 22, the traverse cam shaft 24 is disposed above the center MC of the motor 12. In this case, since the traverse cam shaft 24 is disposed above the center MC of the motor 12, the distance between the guide portion 25 a and the traverse cam shaft 24 is shortened, and the fishing line guide is moved by the rotation of the traverse cam shaft 24. 23 becomes difficult to rattle and can guide the fishing line stably.

  (D) In the level wind mechanism 22, the guide portion 25 a is inclined forward so that the front end portion is farther from the motor than the rear end portion. In this case, since the guide part 25a is inclined forwardly upward, even if water from a wet fishing line adheres to the guide part 25a, the attached water is easily removed from the guide part 25a due to the inclination.

(E) In the level wind mechanism 22, the guide portion 25 a is capable of passing a fishing line therein, and is disposed inside the passage portion 25 b that has a cylindrical passage portion 25 b that is disposed across the center MC of the motor 12. And at least one hard ring portion 25c. In this case, since the fishing line comes into contact with the hard ring portion 25c, the guide portion 25a is not easily worn even if the fishing line comes into contact. Further, by smoothing the surface of the hard ring portion 25c, even if the fishing line comes into contact, the feeding speed is unlikely to decrease.

(F) In the level wind mechanism 22, the fishing line guide 23 includes a guide body 25 and an engaging member. The guide body 25 includes a guide portion 25a and a storage portion 25e formed integrally with the guide portion 25a, and the traverse cam shaft 24 passes therethrough. The engagement member 26 is received in the receiving portion 25 e engaged with the spiral groove. In this case, the fishing line guide 23 reciprocates by engaging the engaging member 26 with the spiral groove 24 a intersecting the traverse cam shaft 24.

  (G) In the level wind mechanism 22, the motor 12 is housed in a cylindrical second connecting member 2 d provided on the reel body 2. The guide body 25 is formed to be curved along the outer peripheral surface of the second connecting member 7d from the guide portion 25a toward the storage portion 25e. In this case, since the storage part 25e in which the engaging member 26 is stored from the guide part 25a is formed along the outer peripheral surface of the second connecting member 7d, the guide main body 25 can be arranged compactly.

  (H) The level wind mechanism 22 further includes a first guide shaft 27a and a second guide shaft 27b. The first guide shaft 27 a is disposed parallel to the traverse cam shaft 24 through the guide portion 25 a at the end of the guide portion 25 a on the spool 10 side. The second guide shaft 27b passes through the guide body 25 between the guide portion 25a and the storage portion 25e and is disposed in parallel with the traverse cam shaft 24. In this case, in addition to the conventionally provided second guide shaft 27b, the first guide shaft 27a is provided in the vicinity of the entrance where the fishing line is guided when the line is unwound so that the fishing line is less likely to get entangled. Further, the second guide shaft 27b can reinforce the guide portion 25a having a long length in the front-rear direction. Thereby, the fishing line guide 23 is stably guided, and the reciprocating movement of the fishing line guide 23 becomes smooth.

<Other embodiments>
As mentioned above, although one Embodiment of this invention was described, this invention is not limited to the said embodiment, A various change is possible in the range which does not deviate from the summary of invention. In particular, a plurality of embodiments and modifications described in this specification can be arbitrarily combined as necessary.

  (A) In the above embodiment, the present invention has been described by taking the electric reel in which the traverse cam shaft 24 is disposed in front of the motor 12 as an example. However, the electric reel in which the traverse cam shaft is disposed between the motor and the spool is also described. The present invention can be applied. In this case, even if the traverse cam shaft is disposed between the spool and the motor, the front end portion of the guide portion is disposed in front of the center of the motor, so that the fishing line does not contact the motor housing portion.

(B) In the aforementioned embodiment has exemplified the one hard ring 25c of substantially the same length as the passage section 25 b, the present invention is not limited thereto. For example, you may arrange | position two at the front end and rear end of a passage part.

  (C) In the embodiment described above, the guide portion 25a is tilted forward in order to facilitate the drainage of water adhering to the inside of the guide portion 25a. However, the present invention is not limited to this. The guide portion may be disposed along the front-rear direction, or the guide portion may be disposed so as to be inclined forwardly.

1 Reel body 7d Second connecting member (an example of a motor storage unit)
10 Spool 12 Motor 14 Spool shaft (an example of a spool rotation shaft)
22, 122 Level wind mechanism 23, 123 Fishing line guide 24 Screw shaft 24a Spiral groove 25, 125 Guide body 25a, 125a Guide part 25b, 125b Passing part 25c, 125c Hard ring part 25e Storage part 26 Engaging member 26a Engaging part 27a First guide shaft 27b Second guide shaft

Claims (8)

An electric reel level winding mechanism in which the motor housed in the reel body is disposed in front of the spool,
A fishing line guide that has a cylindrical guide portion that extends in the front-rear direction across the center of the motor and guides the fishing line, above the motor,
A traverse cam shaft that is formed with a spiral groove intersecting the outer peripheral surface, and that reciprocally moves the fishing line guide in a direction parallel to the rotation axis of the spool in conjunction with rotation of the spool in the line winding direction;
With
The guide portion is inclined forwardly so that the front end portion is farther from the motor than the rear end portion.
Electric reel level winding mechanism.   The level winding mechanism of the electric reel according to claim 1, wherein the traverse cam shaft is disposed in front of a center of the motor. The level winding mechanism of the electric reel according to claim 1 or 2 , wherein the traverse cam shaft is disposed above a center of the motor.   The guide portion has a tubular passage portion through which a fishing line can pass and is disposed across the center of the motor, and at least one hard ring portion disposed in the passage portion. The level winding mechanism of the electric reel according to any one of claims 1 to 3. The fishing line guide is
A guide main body having the guide portion and a storage portion formed integrally with the guide portion, through which the traverse cam shaft passes,
5. The level winding mechanism of the electric reel according to claim 1, further comprising: an engaging member that is housed in the housing portion and engages with the spiral groove. The motor is housed in a cylindrical motor housing provided in the reel body,
The level winding mechanism of the electric reel according to claim 5, wherein the guide body is formed to be curved along an outer peripheral surface of the motor storage portion from the guide portion toward the storage portion.   A first guide shaft that passes through the guide portion at an end portion on the spool side of the guide portion and is arranged in parallel with the traverse cam shaft, and passes through the guide body between the guide portion and the storage portion. The level winding mechanism of the electric reel according to claim 5 or 6, further comprising a second guide shaft disposed in parallel with the traverse cam shaft. The motor;
The level winding mechanism according to any one of claims 1 to 7, wherein the spool;
Electric reel equipped with.

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