JPH11308951A - Line-guiding device of double bearing reel - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a line-guiding device having a high strength, capable of readily corresponding to the change of a reel, and having a line-guiding tool capable of being readily produced. SOLUTION: This line guiding device comprises a line-guiding tool body 100A having a penetrated part for allowing a traverse cam 61 to penetrate the line-guiding tool body 100A, and a housing hole of an engaging fragment for engaging with the traverse cam 61, a cap for holding an engaging fragment in a housing hole, an inserting hole for fixing the line-guiding tool body 100A, different from the line-guiding tool body 100A, a holding part of the line-guiding member having a holding hole 114 for guiding the line, and a platy member 100B formed by stamping out a metallic plate and bending the stamped out plate integral with arm parts. The line-guiding tool 100 is formed by integrally fixing the line-guiding body 100A through the penetrating hole of the platy member 100B.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fishing line guide device provided with a line guide that reciprocates with rotation of a spool of a double bearing reel.

[0002]

2. Description of the Related Art A traverse cam which rotates in conjunction with a spool is provided in front of a spool of a double bearing reel, and a thread guide is screwed onto the traverse cam, and the thread guide is traversed in conjunction with the rotation of the spool. 2. Description of the Related Art A fishing line guide device that reciprocates in the axial direction of a cam is known. The line guide has a through hole through which the traverse cam passes, a holding portion formed with a holding hole through which the fishing line passes, and a detent support for preventing the line guide from rotating around the traverse cam. Unit. Conventionally, a thread guide provided with the through hole, the holding portion, and the detent support portion has been manufactured by integral formation.

[0003]

However, if the size of the reel or the diameter of the spool is different, it is necessary to change at least the position and size of the holding hole. In such a case, different types of yarn guides must be prepared for each reel.

On the other hand, a yarn guide manufactured by joining a plurality of members without being integrally formed is disclosed in Japanese Utility Model Publication No. Sho.
Japanese Patent Application Laid-Open No. 7-8468, Japanese Patent Publication No. 7-38768, and Japanese Utility Model Application Laid-Open No. 7-7440.

[0005] However, even with these disclosed techniques, it is possible to flexibly cope with different reels while securing sufficient strength.
Moreover, a yarn guide that is easy to manufacture cannot be obtained.

SUMMARY OF THE INVENTION An object of the present invention is to provide a fishing line guide device having a line guide which has high strength, can easily cope with a change of reel, and is easy to manufacture.

[0007]

According to the first aspect of the present invention, a spool (4) rotatably supported between reel side plates (1, 2) and interlocked with a handle shaft (7a) and is guided on the outer periphery. A traverse cam shaft (6) is provided between the reel side plates (1, 2) at the front of the spool (4) and interlocked with the handle shaft (7a) or the spool (4).
1) and a fishing line guide device for a double bearing reel including a line guide device (100) provided to reciprocate on the traverse cam shaft (61).
1) a thread guide main body (100A) composed of a holding cylinder (102) of an engagement piece (103) engaged with a traverse camshaft (61) and an insertion portion through which the traverse cam shaft (61) is inserted; The cap (105) for holding the piece (103) and the thread guide body (100A) are separate from the thread guide body (100A).
A) The holding part (11) of the fishing line guide member having the fixing part (111) for fixing the fishing line and the guide hole (114) for guiding the fishing line.
5) and a plate-like member (100) formed by punching and bending a metal plate integrally with the detent support portion (113).
B), and the fixing portion (11) of the plate-shaped member (100B).
The thread guide device (100) is formed by integrally fixing the thread guide device body (100A) to 1).

[0008] To facilitate understanding of the present invention, reference numerals in the accompanying drawings are appended in parentheses, but the present invention is not limited to the illustrated form.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a fishing line guide device for a double bearing reel according to the present invention will be described below with reference to FIGS. The double bearing reel for fishing is used in a state of being attached to a rod 200 as shown in FIG. In this specification, “forward” refers to a direction from the user's hand toward the tip of the rod in a state where the rod is normally used, and “upper” refers to an upper part in a use state in which the rod is horizontal.

As shown in FIGS. 1 to 3, the both bearing reels have a reel frame 1, and left and right frame plates 1a and 1b.
The side plates 2 and 3 are respectively attached. And
A spool 4 around which the fishing line is wound is rotatably supported between bearings 5 and 6 between the right frame plate 1b and the left side plate 2.

The spool 4 is connected to a handle 7 disposed outside the reel frame 1 via a driving force transmission system described below. A handle shaft 7a and a pinion shaft 8 are supported in parallel between the frame plate 1b and the side plate 3. A handle 7 is integrally connected to one end of the handle shaft 7a, and a master gear 9 is mounted in the middle of the handle shaft 7a via a drag device 10 or the like. The master gear 9 rotates together with the handle 7 while receiving.

The pinion shaft 8 is disposed on an extension of the rotation axis L of the spool 4, and its left end is supported by a bearing 11a via a pinion 12 on a right frame plate 1b, and its right end is supported by a bearing 11b on a side plate 3. Supported. The pinion shaft 8
, A pinion 12 is rotatably and slidably covered, and the master gear 9 meshes with the pinion 12.

[0013] Between the one end of the pinion 12 and one end of the spool 4, there is provided an engagement uneven portion 13 which is a clutch tooth. The engaging concave / convex portion 13 rotates the clutch cam 15 by operation of a clutch mechanism described later.
4 engages by sliding the pinion 12 on the pinion shaft 8, and separates when the clutch cam 15 rotates in the opposite direction.

When the engaging concave / convex portion 13 is engaged (the clutch mechanism is ON), the spool 4 is prevented from free rotation and stops feeding the fishing line from the spool 4. Then, when the handle 7 is turned in the fishing line winding direction, the power is transmitted to the handle shaft 7a, the master gear 9, and the pinion 12 sequentially, and the spool 4 rotates to wind the fishing line. When the engaging concave / convex portion 13 separates (the clutch mechanism is turned off), the spool 4 becomes free, and the fishing line can be fed out,
Pay out the fishing line with the weight of the device.

The pinion 12 is connected to the pinion shaft 8
Instead of being mounted on the frame plate 1b, the frame plate 1b and the side plate 3 may be rotatably and slidably mounted via bearings. The pinion shaft 8 may be supported by the frame plate 1 b and the side plate 3, or may be supported by another member separately incorporated in the frame plate 1 b or the side plate 3.

As shown in FIG. 1 and FIG.
A traverse cam 61 extending in parallel with the pinion shaft 8 is rotatably interposed between the left and right frame plates 1a and 1b in front of the traverse cam 61. The traverse cam 61 is a traverse cam 61
Is connected to a handle shaft 7a via a gear train including a gear 61b (FIG. 1) fixed to the traverse cam 61 when the handle 7 is rotated. The traverse cam 61 is housed in a protection tube 62 interposed between the left and right frame plates 1a, 1b. The protection tube 62 has a line guide for letting the spool 4 wind the fishing line with a uniform thickness. 100 is slidably mounted in the traverse cam 61 in the axial direction.

As shown in FIG. 5, the yarn guide 100 is formed by joining a resin yarn guide main body 100A and a plate-like member 100B formed by processing a metal plate to each other.
The plate-shaped member 100B is formed by punching a metal plate.
It is manufactured by subjecting it to the necessary bending.

As shown in FIG. 5, the yarn guide main body 100A
Is formed with a through-hole 101 through which the protective cylinder 62 passes.
As shown in FIG. 2, FIG. 4 and FIG.
0A is slidably attached to the protection cylinder 62 via the through hole 101. A cylindrical storage hole 102 is formed in communication with the through hole 101, and is formed as shown in FIG.
As shown in FIG. 5B, the storage hole 102 includes a cylindrical portion 103a having an outer diameter slightly smaller than the diameter of the storage hole 102, and a claw portion 103b fixed to an upper portion of the cylindrical portion 103a in FIG. Is stored.
The engaging piece 103 is rotatably supported around the axis of the storage hole 102, and its claw 103 b is dropped into the cam groove 61 a of the traverse cam 61 through the opening of the protective cylinder 62. As shown in FIG.
5 is screwed into the male screw 104 and tightened, so that the storage hole 102 is closed and the engagement piece 103 is held in the storage hole 102. In FIG. 5A, illustration of the cap 105 is omitted.

As shown in FIG. 5A, the plate-like member 100
B has an insertion hole 111 into which the yarn guide main body 100A is inserted.
Is formed, and the caulking portion 106 is caulked in a state of being inserted into the insertion hole 111, so that the yarn guide main body 10 is formed.
0A and the plate-shaped member 100B are integrated.

On the other hand, the guide hole 11 is formed in the plate-like member 100B.
2 are provided, and two holding portions 113 are provided with holding holes 114 for passing fishing lines. 2, 4 and 5 are provided in the guide holes 112.
As shown in (b), a guide rod 63 extending in parallel with the traverse cam 61 is penetrated between the left and right frame plates 1a and 1b, thereby preventing the yarn guide 100 from rotating around the protection cylinder 62. Is done.

As shown in FIG. 5B, a guide ring 116 having an opening 116A is fitted into the holding hole 114, and the guide ring 11 is
6 is fixed. The guide ring 116 has a holding hole 114
Flange portion 116a having a larger outer diameter than retaining ring 11
The guide ring 116 is fixed so as to sandwich the periphery of the holding hole 114 between the flange portion 116a and the retaining ring 117. As shown in FIG. 5, a hole 118 for reducing the weight of the thread guide 100 is formed in the plate-shaped member 100B.

In this embodiment, when the handle 7 is turned while the fishing line is passed through the holding hole 114, the traverse cam 61 rotates, and the cam groove 61a of the traverse cam 61 is rotated.
Since the engaging piece 103 dropped into the guide moves according to the position of the cam groove 61a, the entire thread guide 100 reciprocates left and right in accordance with the movement of the engaging piece 103. For this reason, the fishing line passed through the holding hole 114 is wound around the spool 4 while reciprocating in the axial direction of the spool 4, so that the fishing line is wound with a uniform thickness over the entire spool 4. Note that, as described above, the engagement piece 103 is
2 so as to be rotatable. Therefore, the engagement piece 1
Reference numeral 03 denotes a thread guide that rotates at both ends of the cam groove 61a of the traverse cam 61 along the direction of the cam groove 61a.
Since the moving direction of 0 is turned back, the yarn guide 100 reciprocates.

On the other hand, the clutch mechanism is turned on / off by a known switching device described below.
As shown in FIGS. 1 and 7, the clutch cam 15 and the shifter 14 are arranged so as to surround the pinion 12, and the shifter 14 is a cam piece 15 of the clutch cam 15.
a so as to be opposed to the clutch cam 15. The clutch cam 15 is rotatably supported on the frame plate 1b, and the shifter 14 is fitted in an annular groove of the pinion 12. When the clutch cam 15 is turned in any direction on the frame plate 1b, the shifter 14 slides the pinion 12 in its axial direction to disengage the engaging uneven portion 13. This enables or disables transmission of power from the handle 7 to the spool 4.

The shifter 14 is guided in the left-right direction on the axis of the pinion shaft 8 by a pin 23 provided on the reel frame 1. A coil spring (not shown) is mounted on the pin 23, and the coil spring constantly biases the pinion 12 via the shifter 14 in the clutch ON direction so that the engaging concave and convex portions 13 can maintain the engaged state. doing.

The clutch cam 15 is operated by operating a clutch lever 16 provided outside the reel. The clutch lever 16 is connected to the left and right frame plates 1a, 1
1 and 7 so as to be rotatable in the up-down direction between FIGS.
Are connected to the clutch cam 15 via a link mechanism shown in FIG. The link mechanism has a lever 24 fixed to one end of a shaft of the clutch lever 16. The lever 24 is connected to one end of a swing link 25 pivotally supported on the frame plate 1 b, and The other end of the moving link 25 is connected to the clutch cam 15 via a pin and a long hole. The swing link 25 is always urged in one direction by a spring 26 interposed between the swing link 25 and the frame plate 1b. The biasing force of the spring 26 causes the clutch cam 15 to rotate in the clutch ON direction and stop, and the clutch lever 16 to rotate upward and stop.

Thus, when the clutch lever 16 is not pressed down with a finger, the shifter 14 is stopped at the position shown by the solid line in FIGS. The engaging concave and convex portion 13 between the spool 12 and the spool 4 is engaged. Therefore,
When the handle 7 is turned, the spool 4 rotates in the winding direction. When the clutch lever 16 is pressed down with a finger, the clutch cam 15 rotates, and the cam piece 15a pushes the shifter 14 rightward in FIG. 1 against the urging force of the spring 26 or the like,
The shifter 14 moves rightward with the pinion 12. For this reason, the engaging concave and convex portions 13 between the pinion 12 and the spool 4 are separated from each other, the spool 4 becomes free, and rotates in the feeding direction with the weight of a device or the like.

As shown in FIG. 1, the spool 4 has a drum-shaped fishing line winding cylinder 4a on the outer periphery of a cylindrical shaft 17 via leg portions 18.
Has a structure attached. A shaft piece 20 is fixed to the right end of the cylindrical shaft 17, and this shaft piece 20 is attached to the right frame plate 1b.
Is supported via a bearing 5. At one end of the shaft piece 20, one uneven piece of the engaging uneven portion 13 is formed. The left end of the cylindrical shaft 17 is supported via a bearing 6 on a spool support 27 on the left side plate 2. The spool support 27 is arranged so as to coincide with the rotation axis L of the spool 4, and is integrated with the side plate 2 via a frame member 28. Thus, the spool 4 can rotate while being supported by the bearings 5 and 6 on both sides of the cylindrical shaft 17.

The spool 4 can be removed from between the two frame plates 1a and 1b of the reel frame 1 as described below. That is, the shaft piece 20 on the right side of the spool 4 is removably inserted into the inner race of the bearing 5. Also, the left frame plate 1a
The spool insertion hole 29 is formed with a diameter slightly larger than the outer diameter of the flange of the spool 4. The spool 4 is provided with a bearing 6, a spool support 27 and a frame member 28.
The spool insertion hole 2 is integrated with the side plate 2 through the
1 is inserted into and removed from between the two frame plates 1a and 1b.

The frame member 28 is fixed in the side plate 2 by a fixing screw 30. The frame member 28 has a boss portion 28a and a rim portion 28b arranged so as to surround the boss portion 28a. The boss portion 28a holds the spool support portion 27, and the rim portion 28b can open and close the spool insertion hole 29. Shielded. The frame member 28 is, as shown in FIG.
1 attaches to and detaches from the frame plate 1a. The screw rod 31 penetrates the right side plate 3 and the left and right frame plates 1a and 1b in the left and right direction,
The right end head 31a contacts the right side plate 3 from the outer surface, and the left end screw portion 31b is screwed into the frame member 28.
The screw rod 31 is covered with a spacer 32 between the right side plate 3 and the frame plate 1b. When the screw rod 31 is turned in any direction while holding the head 31a, the frame member 28 is disengaged from the screw portion 31b, so that the side plate 2 is removed from the spool 4.
Are integrally attached to and detached from the frame 1a.

As shown in FIG. 8, the double bearing reel is provided with a centrifugal braking device which is a spool braking means between the left end of the spool 4 and the side plate 2 opposed thereto.

In this centrifugal braking device, a brake weight 33 movably provided at one end of the spool 4 by a centrifugal force accompanying the rotation of the spool 4 can be brought into contact with the brake weight 33 as the centrifugal force moves. And an annular braking body 34 provided on the side plate 2.

The brake weight 33 is supported by the spool 4 via a pivot shaft 35 disposed at a position away from the rotation axis L of the spool 4 at a right angle to the rotation axis L. The pivot shaft 35 is held by a bracket 36 fixed to one end of the cylindrical shaft 17 of the spool 4. When the spool 4 rotates, the centrifugal force of the rotation causes the brake weight 33 to rotate about the pivot shaft 35 in a plane including the rotation axis L, and the tip thereof can contact the side surface of the annular braking body 34. become.

The center of gravity of the brake weight 33 is disposed on the opposite side of the annular brake 34 with a plane including the axis of the pivot shaft 35 and perpendicular to the axis L of rotation interposed therebetween. The brake weight 33 rotates toward the annular brake 34 while rotating around the rotation axis L of the spool 4 due to the centrifugal force generated when the spool 4 rotates, and contacts the annular brake 34 to control the spool 4. Add power.

Further, the centrifugal braking device is provided with braking force adjusting means for adjusting the magnitude of the braking force. This braking force adjusting means moves the annular braking body 34 in a direction parallel to the rotation axis L of the spool 4 to adjust the magnitude of the braking force due to the contact between the annular braking body 34 and the brake weight 33. And an adjusting operation member 37 provided on the side plate 2.

The adjusting operation member 37 is a dial-shaped knob as shown in FIGS. 6 and 8, and is rotatably held on the side plate 2 via a knob holder 38. The adjustment operation member 37 has a disk portion 37a, a shaft 37b provided at the center of the disk 37a, and a sleeve 37c provided around the disk 37a. The knob holder 38 has a boss 38a through which the shaft 37b of the adjustment operation member 37 passes, and an outer peripheral wall 38b that receives the sleeve 37c of the adjustment operation member 37. A small gear 39 is fixed to a tip of a shaft 37b of the adjusting operation member 37. The boss 28a of the frame member 28 fixed in the side plate 2 has an annular braking member 34.
Is mounted so as to be slidable in a direction parallel to the rotation axis L of the spool 4, and the large gear 4 meshed with the small gear 39 is attached to the brake holder 40.
1 is formed. Thus, when the adjusting operation member 37 is rotated, the brake body holder 40 rotates around the boss 28a together with the annular brake body 34.

As shown in FIGS. 8, 10 and 11, a click stop mechanism and a stopper mechanism are provided between the adjusting operation member 37 and the knob holder 38.

The click stop mechanism includes an adjusting operation member 3
7 and the irregularities 42 formed on the outer surface of the knob holder 38 and the irregularities 42 formed on the outer surface of the knob 37.
And a spring 44 for urging the ringer 43 toward the irregularities 42. When the adjusting operation member 37 is turned, the ringer 43 comes into contact with the unevenness 42 and generates a click sound. When the adjusting operation member 37 is stopped, the ringer 43 engages with the unevenness 42 at that position.

The stopper mechanism comprises first and second stoppers 45 provided on the boss 38a of the knob holder 38.
a, 45b, and a projection 46 provided on the inner surface of the sleeve 37c of the adjustment operation member 37. Adjustment operation member 37
Is rotatable within the angular range between the first and second stoppers 45a and 45b, the position where the projection 46 contacts the first stopper 45a corresponds to a braking force 0 described later, and the projection 46 The position where the stopper 45b hits corresponds to the maximum braking force described later.

The adjusting operation member 37 has an outer surface along the surface of the side plate 2. That is, the outer surface of the disk portion 37 a of the adjustment operation member 37 is substantially flush with the outer surface of the side plate 2. In this embodiment, the outer surface of the side plate 2 is formed as a spherical surface, and the outer surface of the adjusting operation member 37 is also formed as a spherical surface having the same diameter. Since the adjusting operation member 37 has the outer surface along the surface of the side plate 2 in this manner, it is easy to perform the palming, and the rotation of the adjusting operation member 37 during the palming can be prevented.

As shown in FIG. 12, engagement projections 47 are radially provided on the outer periphery of the annular brake 34,
A cam surface 48 cooperating with an engagement projection 47 is provided on the inner frame member 28.
Is provided. As shown in FIG. 8, the annular braking body 34 is held by a braking body holder 40, and the braking body holder 40 is moved toward the frame member 28 by a compression coil spring 49 mounted on a boss 28 a of the frame member 28. , So that the engagement projection 47 is elastically pressed against the cam surface 48. The cam surfaces 48 are provided corresponding to the respective engagement protrusions 47, and the respective cam surfaces 48 are provided on the rim portions 28b of the frame member 28.
It extends upward along an arc centered on the axis of the boss 28a. The outline of each cam surface 48 as a cam curve is shown in FIG.
As shown in FIG. 3, the spool 4 is inclined at a constant gradient in a direction parallel to the rotation axis L of the spool 4. A portion indicated by reference symbol A in FIG. 13 is a range in which the braking force can be adjusted,
When the engagement projection 47 is at the position indicated by the reference numeral 47a, the braking force is minimized, when the engagement projection 47 is at the position indicated by the reference numeral 47b, the braking force is maximum, and when the engagement protrusion 47 is at the position indicated by the reference numeral 47c, the braking force is minimum. And the middle size of the maximum. Accordingly, when the adjusting operation member 37 is rotated, the cam surface 48 and the engaging projection 47 rotate relatively, and the position of the annular braking body 34 is adjusted in a direction parallel to the rotation axis L of the spool 4, The magnitude of the braking force applied to 4 will be adjusted.

The adjustment range of the braking force is indicated by numerical values as shown in FIG. A numerical value from 0 to 15 indicating the magnitude of the braking force is displayed on the side plate 2 around the adjusting operation member 37, and a pointer 37 d is displayed on the adjusting operating member 37. In this case, the value 0 corresponds to no braking force. Numeral 1 corresponds to the minimum braking force, and the position 47 of the engagement projection 47 in FIG.
corresponds to a. Numerical value 15 corresponds to the maximum braking force.
This corresponds to the middle position 47b.

The profile of the cam surface 48 may be formed such that its gradient changes on the way, as shown in FIG. In this case, the braking force can be finely adjusted at the portion 48a with a gentle gradient, and the braking force can be changed quickly at the portion 48b with a steep gradient.

The cam surface 48 and the engagement projection 47 can be exchanged between the frame member 28 and the annular brake 34. Further, it is also possible to provide a cam surface 48 and an engagement projection 47 on a surface of the annular braking body 34 and the adjustment operation member 37 facing each other.

In the centrifugal braking device, even when the braking force is zero, that is, when the spool 4 rotates, the brake weight 33
Is provided with a brake release means for preventing the contact of the vehicle. As shown in FIGS. 12 to 14, this braking release means is provided by providing a braking force zero setting section 51 on the cam surface 48 through a step of the steep portion 50. The engagement of the brake force zero setting portion 51 with the engagement protrusion 47 prevents the brake weight 33 from contacting the annular brake 34 as shown in FIG. When the engagement projection 47 enters this position 47d, no braking force acts on the spool 4. Also,
Since the steep slope portion 50 is interposed between the portion A where the braking force of the cam surface 48 can be adjusted and the braking force zero setting portion 51, switching between generation and release of the braking force is reliably performed, Further, the reel operator can clearly sense that the switching has been completed.

The spool 4 is attached to the two bearing reels.
A mechanical brake device is also provided as a means for applying a braking force to the vehicle. As shown in FIG. 1, the mechanical brake device includes a pinion shaft 8 and a shaft piece 20 integral with the spool 4.
To apply a braking force to the spool 4. The pinion shaft 8 is slidable on an extension of the rotation axis L of the spool 4, and the pressing force on the shaft piece 20 is adjusted by operating the adjustment knob 52 arranged on the side plate 3. The pinion shaft 8 penetrates the side plate 3 to the outside, and the penetrated portion is surrounded by a boss 3a on the side plate 3, and a cap nut-shaped adjustment knob 52 is screwed to the boss 3a. A brake piece 53 is inserted between the pinion shaft 8 and the shaft end. The braking force applied to the spool 4 can be adjusted by turning the adjustment knob 52 in either direction to increase or decrease the force pressing the pinion shaft 8 in the axial direction via the brake piece 53.

Next, the operation of the double bearing reel will be described.

When the finger is released from the clutch lever 16 as shown in FIG. 1, the clutch is in the ON state in which the engaging concave and convex portions 13 are engaged, and when the handle 7 is turned, the power generated by the handle 7 is transmitted to the master gear 9 and the pinion 12. , And transmitted to the spool 4 via the engaging concave and convex portions 13 and the like. As a result, the spool 4 winds the fishing line around it while rotating.

When the clutch lever 16 is depressed with a finger to release the engagement of the engaging concave / convex portion 13, the spool 4 becomes free and rotates in a direction in which the fishing line is paid out by a weight such as a tackle.
In this case, it is determined whether or not braking force is applied to the spool 4 in accordance with the fishing situation. If it is determined that backlash can be prevented without applying braking force, the adjusting operation member 3
7 is turned towards scale 0. As a result, the brake body holder 40 rotates on the boss portion 28 a of the frame member 28, and the engagement protrusion 47 drops from the cam surface 48 to the zero braking force setting portion 51 through the step of the steep portion 50. For this reason, the annular brake 34 is far away from the brake weight 33, so that even if the spool 4 rotates and the brake weight 33 swings, it does not contact the brake weight 33, and the braking force does not act on the spool 4.

On the other hand, when it is determined that the backlash occurs due to the excessive rotation of the spool 4, the adjusting operation member 37
Is turned from the scale 0 toward the scale 15. As a result, the brake body holder 40 is mounted on the boss 28a of the frame member 28.
The rotation rotates in the opposite direction to the above, and the engagement protrusion 47 rides on the cam surface 48 via the step from the zero braking force setting portion 51.
For this reason, the annular brake 34 approaches the brake weight 33, and the spool 4 rotates so that it can contact the brake weight 33 that rises in the radial direction, and a braking force acts on the spool 4. The magnitude of this braking force is adjusted by turning the adjusting operation member 37 in a range from above the scale 0 to the scale 15.

The braking of the spool 4 can also be adjusted by operating a mechanical brake device. In this case, the adjustment knob 52 is operated and the pinion shaft 8 is operated.
The force for pinching the spool 4 between the spool support portion 27 and the spool support portion 27 is adjusted, so that the braking force applied to the spool 4 is adjusted.

By adjusting the braking force in this manner, excessive rotation of the spool 4 is suppressed, and occurrence of backlash of the fishing line is prevented.

If the diameter of the spool and the size of the reel are different, the optimum size and shape of the line guide are naturally different. However, in the fishing line guide device for a double bearing reel of this embodiment, the line guide is different from the line guide main body 100A. Plate member 100 formed on the body
B is joined to the line guide main body 100A to form the line guide 100, a holding portion 115 for guiding the fishing line, an arm 113 for preventing the line guide 100 from rotating, and a line guide main body 100A. And an insertion hole 111 for attaching the same are formed in an integrated plate-like member 100B.
For this reason, even if it is desired to change the size or shape of the yarn guide, it is possible to cope with it only by changing the size or shape of the plate-like member, and the yarn guide main body 100A can be shared for all reels. .

The yarn guide main body 100A and the plate-like member 1
00B is manufactured separately, and the two are joined later. Therefore, the structure of each member is simplified, the manufacture is easy, and a mold having a complicated shape is not required. For this reason, the manufacturing cost can be reduced. Furthermore, since the plate-shaped member 100B can be formed by punching and bending of a metal plate, processing and assembly can be performed with high accuracy, and the work of the manufacturing process can be simplified. .

Further, the parts on which a relatively large force acts are concentrated on one plate-like member 100B, and furthermore, the plate-like member 100B is formed by processing a metal plate.
, The strength of the yarn guide 100 as a whole can be increased. Furthermore, since the plate-like member 100B is formed of a metal plate, necessary strength can be ensured even if the plate-like member 100B is formed thin. For this reason, the fishing line guide device can be reduced in size by the thinner thickness, and the line guide 100 can be arranged closer to the spool 4 by that much, so that the reel itself can be reduced in size. Can be.

Further, since the resin-made yarn guide main body 100A and the plate-like member 100B obtained by processing a thin metal plate are combined, the weight of the yarn guide 100 can be reduced. It can also contribute to weight reduction.

In the present embodiment, the reciprocating motion of the yarn guide 100 is always performed in conjunction with the rotation of the handle 7. For example, the spool and the traverse cam are connected via a gear train. It may be configured so as to be directly connected, and the rotational force from the handle is transmitted to the traverse cam via the spool. By adopting such a configuration, the fishing line guide device can be operated even during the free rotation of the spool when throwing the fishing line. With this configuration, when the drag device is functioning, that is, when the spool does not rotate due to the action of the drag device even when the handle is rotated, the reciprocating motion of the thread guide stops. Therefore, the thread guide device waits at the position when the spool is stopped by the drag device, and the reciprocating motion of the thread guide device is resumed at the same time when the rotation of the spool is resumed. The fishing line is continuously wound from the same position as at the time of stop. Accordingly, it is possible to prevent the fishing line from being randomly wound on the spool due to unnecessary reciprocation of the line guide device.

In this embodiment, the traverse cam 61 is provided below the front part of the spool 4, but the traverse cam may be provided above the front part of the spool.

In this embodiment, the thread guide body 100A and the plate-like member 100B are fixed by caulking. However, the two members are press-fitted, welded, or bonded, or one is sandwiched by the other, so that the two are held together. You may make it mutually fixed. In this case, according to the fixing means,
The configurations of the yarn guide main body and the plate-like member can be arbitrarily changed.

In the present embodiment, the rotation of the yarn guide 100 is prevented by passing the guide bar 63 through the guide hole 112, but various methods may be used as means for preventing the rotation. it can. For example, a guide rail that engages with the plate member 100B without penetrating the plate member is extended in parallel with the traverse cam, and the plate member 100B reciprocates while engaging with the guide rail. This may prevent the yarn guide 100 from rotating.

A part of the plate-like member, for example, a tip portion thereof is formed in a ring shape or a hook shape by bending, and the ring or the hook is engaged with a guide bar extending in parallel with the traverse cam. The rotation may be prevented by combining them.

Further, in this embodiment, the guide ring 116 is fitted into the holding hole 114 and the guide ring 116 is fixed by the retaining ring 117. For example, a member corresponding to the guide ring is screwed to the plate-like member. It may be attached by doing. In addition, an arbitrary method can be adopted as a mounting method.

[0062]

According to the first aspect of the present invention, there is provided a thread guide body including an insertion portion through which the traverse cam shaft is inserted, and a holding cylinder of an engagement piece engaged with the traverse cam shaft. A fixing portion for fixing the main body of the line guide separately from the main body of the line guide, a holding portion for a fishing line guide member having a guide hole for guiding the fishing line, and a detent support portion are integrally formed by punching and bending a metal plate. It is possible to change the size and shape of the yarn guide only by changing the size and shape of the plate-shaped member, and to share the main body of the yarn guide. be able to. Further, since the yarn guide main body and the plate-shaped member are formed separately and fixed to each other, the structure of each member is simplified, and the production becomes easy and the production cost can be reduced. Further, since the plate member is formed by punching and bending the metal plate, the processing and assembly can be performed with high accuracy, and the work of the manufacturing process can be simplified. Furthermore, since the plate member is formed by processing a metal plate,
Sufficient strength is given to the plate-shaped member, so that the strength of the entire yarn guide can be increased. Further, since the plate-shaped member is formed of a metal plate, necessary strength can be ensured even if the plate-shaped member is formed thin, so that the size and weight of the fishing line guide device and the reel can be reduced.

[Brief description of the drawings]

FIG. 1 is a horizontal sectional view of a double bearing reel provided with a fishing line guide device according to the present invention.

FIG. 2 is a front view of the double bearing reel shown in FIG.

FIG. 3 is a partially cutaway rear view of the double bearing reel shown in FIG. 1;

FIG. 4 is a partially cutaway side view of the double bearing reel shown in FIG. 1;

5A and 5B are views showing a thread guide, wherein FIG. 5A is a perspective view of a thread guide main body and a plate-like member constituting the thread guide, and FIG.
FIG. 3 is a cross-sectional view of the yarn guide.

FIG. 6 is a side view of the double bearing reel shown in FIG. 1;

FIG. 7 is a side view showing a link mechanism between a clutch lever and a clutch cam.

FIG. 8 is an enlarged view of a main part in FIG. 1;

FIG. 9 is a partially cutaway sectional view showing a non-braking state.

FIG. 10 is a side view showing another embodiment of the brake lever as viewed in the direction of arrows XX in FIG.

FIG. 11 is a view taken along line XI-XI in FIG. 10;

FIG. 12 is a view taken along line XII-XII in FIG.

FIG. 13 is a development view showing a cam surface.

FIG. 14 is a development view showing a cam surface of another embodiment.

DESCRIPTION OF SYMBOLS 1 Reel side plate 2 Reel side plate 4 Spool 7 Handle 7a Handle shaft 61 Traverse cam 100 Thread guide 100A Thread guide main body 100B Plate member 102 Storage hole 103 Engagement piece 105 Cap 111 Insert hole 113 Arm 114 Holding hole 115 Holding section

Claims (1)

[Claims] 1. A spool rotatably supported between reel side plates and interlocking with a handle shaft, a guide tube provided on the outer periphery, and the handle shaft or the spool provided between the reel side plates at the front of the spool. A fishing line guide device for a double-bearing reel, comprising a traverse cam shaft interlocked with a traverse cam shaft and a line guide device provided to reciprocate on the traverse cam shaft. A thread guide device main body comprising a holding cylinder of an engaging piece engaged with a traverse camshaft; a cap holding the engaging piece in the holding tube; and the thread guide device separately from the thread guide device main body. A fixing portion for fixing the main body, a holding portion of the fishing line guide member having a guide hole for guiding the fishing line, and a plate-like member formed by punching and bending a metal plate integrally with the detent support portion. A fishing line guide device for a double bearing reel, wherein the line guide is formed by integrally fixing the line guide main body to the fixing portion of the plate-shaped member.