JP2006333810A - Double-bearing reel for fishing - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a double-bearing reel for fishing capable of stably applying smooth braking force to a spool with drag disks placed at both sides of the spool to prevent the generation of a steep rise of the force. <P>SOLUTION: The double-bearing reel for fishing has the 1st compression spring (forcing means) 26 at an end of the spool shaft 2 to separate the 1st drag disk 21 from the spool-side braking part 20 of the spool 1, and the 2nd compression spring (forcing means) 33 at the other end of the spool shaft 2 to separate the 2nd drag disk 32 from the spool-side braking part 31 of the spool 1. The outer diameter R1 of the drag disk 21 is formed to be nearly equal to the outer diameter R2 of the drag disk 32 as shown by the chain double-dashed line, and the inner diameter r1 of the spool-side braking part 20 is formed to be larger than the inner diameter r2 of the spool-side braking part 31. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a fishing double bearing provided with a drag mechanism for applying a braking force to a spool rotatably supported between side plates of a reel body by a displacement operation of an adjusting member provided on the reel body. The present invention relates to improvement of mold reels.

As a conventional double-bearing type reel for fishing with a drag mechanism, a drag disk connected to a drive mechanism disposed opposite to a side surface of a spool that is rotatably supported and a lining material provided on the side surface of the spool A drag mechanism that applies a braking force to a spool by generating a frictional force by pressing them together is generally known as disclosed in Patent Document 1.
JP 2003-134978 A

The problem to be solved is that the drag mechanism disclosed in Japanese Patent Application Laid-Open No. H10-228707 is a drag force generator provided on both sides of the spool (the pressure contact between the pair of left and right drag disks and the lining material on the side of the spool). The force of the compression spring provided between the drag disk and the spool is made strong and weak so that a braking force without a sudden rise can be applied to the spool. .
However, since the drag force generators on both sides of the spool (friction force generators with the drag disk and lining material) are common, the basic drag performance does not change and there is no unevenness at low tension. It is difficult to obtain sufficient drag performance that adapts to the tension that changes depending on the type and size of the fish, such as emphasis on slip friction force (suppression of stick slip occurrence) and emphasis on forced braking force at high tension (strength). Such issues remain.

  An object of the present invention is to provide a double bearing type fishing reel capable of obtaining a smooth sliding frictional force without unevenness at low tension and a forced braking force at high tension in view of the above drawbacks. .

  According to a first aspect of the present invention, there is provided a spool which is rotatably supported by the reel body, and drag members respectively provided on both sides of the spool. A double-bearing type fishing reed having a drag mechanism that applies a braking force to the rotation of the spool by frictional contact with a spool-side braking portion provided on the side of the spool by operation. The gist of the present invention is that the drag disks and the spool-side braking portions provided on both sides of the spool are configured by braking force generating means having different friction braking characteristics.

According to the first aspect of the present invention, a smooth braking force without a sudden rise can be stably applied to the spool by the drag disks arranged on both sides of the spool.
In addition, since the drag force generators on both sides of the spool can be changed (friction force generator by the drag disk and spool side brake), smooth sliding friction is emphasized without unevenness at low tension. The drag performance suitable for the tension that changes depending on the type and size of the fish, such as (suppression of occurrence of stick-slip) and emphasis on forced braking force at high tension (strength), can be sufficiently obtained.

A first compression spring (biasing means) 26 for separating the first drag disk 21 from the spool side braking portion 20 made of the lining material of the spool 1 is provided on one end side of the spool shaft 2. On the other end side of the spool shaft 2, a second compression spring (biasing means) for separating the second drag disk 32 from the spool side braking portion 31 made of the lining material of the spool 1 is provided. 33 is provided.
As shown by a two-dot chain line in FIG. 2, the outer diameter R1 of the drag disk 21 and the outer diameter R2 of the drag disk 32 are formed to be substantially the same, but the inner diameter r1 of the spool-side braking portion 20 is formed.
Is formed to have a larger diameter than the inner diameter r2 of the spool-side braking portion 31, and the contact area of the drag disk 21 is smaller than that of the drag disk 32.
The spool-side braking portion 20 is made of a material having a small friction coefficient such as felt or Teflon (registered trademark), and the spool-side braking portion 31 is made of a friction material made of a composite additive impregnated and cured with a synthetic resin. A material with a large coefficient is used.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
1 is a cross-sectional rear view of a fishing double-bearing type reel, FIG. 2 is an enlarged cross-sectional rear view of an essential part of a fishing double-bearing type reel, and FIG. 3 is a cross-sectional side view of a reel leg. 4 is a rear view of the reel leg.

The double-bearing type reel for fishing has a spool 1 around which a fishing line is wound, and a handle 10 for rotating the spool 1 in the direction of winding the fishing line. Is supported rotatably on the spool shaft 2 via bearings 11 and 12.
The spool shaft 2 is rotatably supported by the reel body 3 via bearings 13 and 14 and can slide along the axial direction.
Specifically, the reel body 3 has left and right side plates 16, 4 fastened to them by screws 15. One end side of the spool shaft 2 (the left side in FIG. The side opposite to the handle) is supported by the bearing 13 provided on the left side plate 16, and the other end side (right side in the figure: handle side) of the spool shaft 2 is fitted with a non-rotating fit. It is supported by a bearing 14 provided on the right side frame 4 via a combined high-speed pinion gear 5 described later.
On the other end side of the spool shaft 2, a large-diameter low-speed pinion gear 17 is mounted together with the small-diameter high-speed pinion gear 5.
In this case, the low-speed pinion gear 17 is non-rotatably fitted to the outer periphery of the high-speed pinion gear 5.
Therefore, these pinion gears 5 and 17 can rotate integrally with the spool shaft 2.

A pressing portion 18 that presses the spool 1 in the axial direction while being frictionally engaged with the spool 1 is attached to one end side of the spool shaft 2.
The pressing portion 18 includes a pressing body 19 that is fixed to the spool shaft 2 and is supported by the pressing body 19 and a side surface on one side of the spool 1 (a lining provided on the side surface of the spool 1). A first drag disk 21 which can be brought into frictional contact with the spool-side braking portion 20) made of a material, and a leaf spring 22 which urges the pressing body 19 in a direction in which the first drag disk 21 is brought into contact with the spool 1. And a gear 23.
In this case, the leaf spring 22 and the gear 23 are provided between the first retainer 24 fastened in the groove of the spool shaft 2 and the pressing body 19, and the rotation is fitted to the spool shaft 2. Are combined.
The gear 23 meshes with a ratchet 25 that restricts rotation of the spool shaft 2 in the reverse direction (fishing line feeding direction).
A first compression spring (biasing means) 26 is interposed between the pressing body 19 and the bearing 11.

The first compression spring 26 urges the pressing body 19 in a direction opposite to the urging direction of the leaf spring 22, and a certain clearance C 1 (between the spool 1 and the first drag disk 21 ( 2).
The first compression spring 26 causes the bearing 11 to abut against the stepped portion of the inner hole of the spool 1 and to the second retainer 27 locked in the groove of the spool shaft 2. It has been hit.
Therefore, the pressing portion 18 attached to the spool shaft 2 in such a state rotates together with the spool shaft 2 and can move in the axial direction together with the spool shaft 2.
The spool 1 is connected to a support member 30 supported on the support 29 and the pressing portion 18 side through an elastic seal material 28, and can move slightly in the axial direction.

The other end side of the spool shaft 2 is in contact with the other side surface of the spool 1 (spool side braking portion 31 made of a lining material provided on the side surface of the spool 1). A support body 29 for supporting the second drag disk 32 is fitted to prevent rotation.
The support 29 meshes with the low-speed pinion gear 17 so that it can rotate together with the spool shaft 2 and the pinion gears 5 and 17.
A second compression spring (biasing means) 33 having a spring force (biasing force) stronger than that of the first compression spring 26 is interposed between the support 29 and the bearing 12.
The outer diameter of the second compression spring 33 is set larger than that of the first compression spring 26, so that the elastic coefficient is larger than that of the first compression spring 26.

The second compression spring 33 urges the support 29 in a direction in which the second drag disk 32 is separated from the spool 1, so that a constant amount is provided between the spool 1 and the second drag disk 32. A clearance C2 (see FIG. 2) is formed, and a structure including the support member 29, the pinion gear 5, and the bearing 14 is abutted against the inner surface of the right side plate 4, and this structure (5, 14, 29). Is restricted from moving in the axial direction of the spool shaft 2.
Accordingly, the structure (5, 14, 29) attached to the spool shaft 2 in this state rotates integrally with the spool shaft 2, but moves in the axial direction together with the spool shaft 2. do not do.
On the other hand, the bearing 12 can move in the axial direction together with the spool shaft 2.
The bearing 12 is abutted against a third retainer 34 that is locked in the groove of the spool shaft 2 by a second compression spring 33.
The low-speed pinion gear 17 meshes with a ratchet 35 that restricts the rotation of the spool shaft 2 in the reverse direction (fishing line feeding direction).

As shown by a two-dot chain line in FIG. 2, the outer diameter R1 of the drag disk 21 and the outer diameter R2 of the drag disk 32 are formed to be substantially the same, but the inner diameter r1 of the spool-side braking portion 20 is formed.
Is formed to have a larger diameter than the inner diameter r2 of the spool-side braking portion 31, and the contact area between the spool-side braking portion 20 and the drag disk 21 is equal to the contact area between the spool-side braking portion 31 and the drag disk 32. It is comprised so that it may become smaller.
The inner diameter dimension of each spool side braking part is appropriately selected and used.
The spool-side braking portion 20 is made of a material having a small friction coefficient such as felt or Teflon (registered trademark), and the spool-side braking portion 31 is made of a friction material made of a composite additive impregnated and cured with a synthetic resin. A material with a large coefficient is used.
The spool-side braking section may be composed of a single piece or a plurality of pieces, and the material is appropriately selected.
Further, the number of the spool-side braking portions 31 is larger than that of the spool-side braking portion 20.

Further, the biasing force of the first compression spring (biasing means) 26 that separates the first drag disk 21 from the spool-side braking portion 20 of the spool 1 is the spool-side braking of the spool 1. It is formed smaller than the biasing force of the second compression spring (biasing means) 33 that separates the second drag disk 32 from the portion 31.
In this way, the first drag disk 21 side and the second drag disk 32 side, which are the drag force generating means, are configured to have different friction braking characteristics, respectively. The disc 21 side is smoothed with a focus on weak braking characteristics, such as reducing the contact area with the spool side braking unit 20 or using a material with a small friction coefficient for the spool side braking unit 20. -It is configured so that a smooth sliding frictional force can be obtained in the initial stage.
Further, the second drag disk 32 side places a greater emphasis on the forced braking force (proof strength) at high tension than the first drag disk 21 side.

On the other end side of the spool shaft 2 where the handle 10 is located, there is provided a drag mechanism 36 for moving the spool shaft 2 in the axial direction and applying a braking force to the rotation of the spool 1 in the fishing line feeding direction. It has been.
The drag mechanism 36 has a drag lever 6 of an adjustment member A that is rotatably mounted on the right side frame 4.
A cam mechanism is disposed in the inner hole 6 a at the base of the drag grabber 6.
This cam mechanism includes a cam member 37 that rotates integrally with the drag lever 6, and a slide member 38 that is fixed to the right side frame 4 projecting inside the inner hole 6 a and is slidable in the axial direction. Consists of.
In this drag mechanism, when the cam member 37 rotates with the rotation of the drag lever 6, the slide member 38 slides in the axial direction by the action of the cam surface of the cam member 37 that contacts the slide member 38.
The drag mechanism 36 includes a drag lever 6 of the adjustment member A, a cam member 37, a slide member 38, and a holding body 39.

A holding body 39 that rotatably holds the other end of the spool shaft 2 is attached to the slide member 38.
The holding body 39 is formed on the screwing member 7 screwed to the slide member 38, a bearing 40 interposed between the screwing member 7 and the spool shaft 2, and the screwing member 7. The claw portion 7a holds the bearing 40 with the retainer 41 locked to the spool shaft 2.
The holding body 39 is integrated with the slide member 38 so that the screw shaft 7 slides in the axial direction, whereby the spool shaft 2 is moved through the bearing 40 engaged with the claw portion 7a of the screw member 7. Move in the axial direction.

Further, a cylindrical handle shaft 42 rotated by the handle 10 is rotatably supported on the right side frame 4.
In this case, the handle shaft 42 is inserted into the support cylinder 8 attached and fixed to the right side frame 4 so as to be able to rotate and advance and retract.
The distal end portion of the handle shaft 42 is supported by a bearing 43 disposed in the reel body 3.
Further, a low-speed gear 44 whose outer teeth mesh with the low-speed pinion gear 17 and a high-speed gear 45 whose outer teeth mesh with the high-speed pinion gear 5 are rotatably supported on the inner extension of the right side frame 4. ing.
In this case, the distal end portion of the handle shaft 42 extends so as to penetrate the center of the gears 45 and 44.

Further, a gear 46 is fitted to the distal end portion of the handle shaft 42 so as not to rotate. The gear 46 has a first position (position in FIG. 1) that meshes with the internal teeth of the high speed gear 45 and a second position that meshes with the internal teeth of the low speed gear 44 as the handle shaft 42 advances and retracts in the axial direction. You can move between.
The handle shaft 42 is provided with a positioning mechanism for positioning the gear 46 between the first position and the second position.
This positioning mechanism is provided on the handle shaft 42 and can be protruded and retracted through an opening formed on the outer peripheral surface of the handle shaft 42, and is formed on the inner peripheral surface of the support cylinder 8 and the ball 47. It has a pair of engaging grooves 8a and 8b to be engaged, and a push rod 9 that is inserted into the handle shaft 42 so as to be able to advance and retreat and controls the projecting and retracting operation of the ball 47.
In this case, the pair of engaging grooves 8a and 8b are separated from each other by a predetermined distance in the longitudinal direction of the handle shaft 42 (specifically, approximately equal to the distance between the first position and the second position). Is located.

Further, the push rod 9 comes into contact with the ball 47 and has a large diameter portion 9 a set to an outer diameter capable of projecting the ball 47 from the outer peripheral surface of the handle shaft 42 by a predetermined amount, and a hand of the rod 9. A small-diameter portion 9b formed on the side and set to an outer diameter capable of completely immersing the ball 47 into the handle shaft 42, and formed between the large-diameter portion 9a and the small-diameter portion 9b. The taper 47 has a taper portion 9c for guiding the rod 47 between the large diameter portion 9a and the small diameter portion 9b.
A compression spring 48 is provided in the handle shaft 42.
The compression spring 48 is inserted between the handle shaft 42 and the push rod 9 and constantly urges the push rod 9 in a direction in which the ball 47 and the large diameter portion 9a of the push rod 9 are in contact with each other. .
In this case, the push rod 9 is brought into contact with a lid 49 provided to close the proximal opening of the handle shaft 42 by the urging force of the compression spring 48. An operation knob 9d is formed at the end of the push rod 9.

The reel body 3 is integrally formed in a U-shape or as a separate body integrally with both side frames 3a, 3b and a fixing plate 3c of the reel legs 50 when viewed from the front or the back.
The left and right side plates 16 and 4 are fastened to the both side frames 3a and 3b by screws 15.
As shown in FIGS. 1, 3, and 4, an elastic member 51 such as a hook-shaped rubber is attached to the bottom surface of the reel leg 50 by means such as adhesion, press-fitting, and welding.
The elastic member 51 is configured so that the reel can be securely mounted on a fishing rod reel leg fixing device (not shown) without rattling.

Next, the operation of the double-bearing type reel for fishing will be described. First, when the handle 10 is rotated in the fishing line winding direction, the handle shaft 42 is rotated, and the high-speed gear 45 meshing with the gear 46 of the handle shaft 42 or The low speed gear 44 rotates.
In the state of FIG. 1, since the gear 46 is engaged with the high speed gear 45, the high speed gear 45 rotates.
When the high speed gear 45 rotates, the spool shaft 2 rotates at high speed via the high speed pinion gear 5 that meshes with the high speed gear 45.

Here, in order to rotate the spool shaft 2 at a low speed, first, the push rod 9 is pushed against the urging force of the compression spring 48.
When the push rod 9 is pushed in, the portion of the push rod 9 that is opposed to the ball 47 shifts from the large diameter portion 9a to the small diameter portion 9b, so that the ball 47 comes into contact with the large diameter portion 9a. From the state of FIG. 1 engaged with the first engaging groove 8b, the taper portion 9c is brought into contact with the small-diameter portion 9b, and is accordingly immersed in the handle shaft 42.
Therefore, the handle shaft 42 can be pushed into the support cylinder 8. Thereafter, when the pressing force to the push rod 9 is released while sliding the entire handle shaft 42 into the support cylinder 8 in this state, the ball 47 faces the second engagement groove 8a. Thus, it is pushed out (projected) by the large-diameter portion 9a of the push rod 9 with the urging force of the compression spring 48, and engages with the second engagement groove 8a.
At this time, the gear 46 of the handle shaft 42 is moved to the front end side (moved from the first position to the second position) as the handle shaft 42 slides, and meshes with the internal teeth of the low speed gear 44.
Accordingly, when the handle 10 is rotated in the fishing line winding direction in this state, the handle shaft 42 is rotated, and the low speed gear 44 meshing with the gear 46 of the handle shaft 42 is rotated, via the low speed pinion gear 17 meshing with the low speed gear 44. As a result, the spool shaft 2 rotates at a low speed.

Thus, when the spool shaft 2 rotates, the entire pressing portion 18 including the first drag disk 21 rotates, and the second drag disk 32 also rotates together with the support 29.
At this time, when the drag lever 6 is positioned in the state shown in FIG. 2, the spool shaft 2 is not moved in the axial direction from its basic position, so that both the drag disks 21, 32 and the spool are connected. 1, constant clearances C 1 and C 2 are formed by the action of the compression springs 26 and 33.
Therefore, the spool 1 can be rotated freely, and the fishing line wound around the spool 1 can be fed out freely without giving any resistance.

In addition, when the drag lever 6 is rotated clockwise from the state of FIG. 2, the cam member 37 is rotated and the slide member 38 is slid in the axial direction.
Therefore, the spool shaft 2 is moved in the axial direction (left side in FIG. 2... Handle side) via the holding body 39 attached to the slide member 38.
When the spool shaft 2 is moved in the axial direction, the pressing portion 18 is also moved in the axial direction via the retainer 24 provided on one end side of the spool shaft 2. 18, the first compression spring 26 is compressed.
In this case, of course, the second compression spring 33 is also compressed.
Then, when the drag lever 6 is rotated to some extent from the initial stage and is positioned in the vertical standing state at the intermediate point, only the first drag disk 21 of the moving pressing portion 18 contacts the side surface on one end side of the spool 1. To do.

Here, when the first compression spring 26 and the second compression spring 33 are set to have the same spring force, the spring 26 and 33 are compressed as the spool shaft 2 moves in the axial direction. And before the first drag disk 21 and the spool 1 come into contact with each other (while leaving the clearance C1), the spool is forced through the bearing 11 by the thrust of the first compression spring 26. 1 itself moves to the handle 10 side, and eventually both drag disks 21 and 32 abut against the spool 1 almost simultaneously.
However, in the present embodiment, since the spring force of the first compression spring 26 is smaller than the spring force of the second compression spring 33, the first compression spring 26 moves in the axial direction together with the spool shaft 2. The first drag disk 21 can be brought into contact with the spool 1 before being compressed by the pressing portion 18 and moving the spool 1 to the handle side.

In a state where only the first drag disk 21 is in contact with the side surface on one end side of the spool 1, the spool 1 is subjected to the spool by a predetermined drag force accompanying the frictional contact with the first drag disk 21. It rotates with the shaft 2.
At this time, if a predetermined tension exceeding the drag force is applied to the fishing line due to the fish caught on the ground, the spool 1 can rotate in the fishing line feeding direction.

When the drag lever 6 is further rotated clockwise from the vertical standing state and the spool shaft 2 is further moved in the axial direction, the compression springs 26 and 33 are further compressed, and the pressing portion 18 is moved to the first drag. The spool 1 is moved in the moving direction of the spool shaft 2 through the disk 21.
Finally, the side surface on the other side of the spool 1 comes into contact with the second drag disk 32 when the drag lever 6 is positioned in the final rotation state.
In this state, the drag force acting on the spool 1 is further increased, and the spool 1 is completely frictionally coupled with the spool shaft 2 so that the spool 1 rotates integrally with the spool shaft 2 without slipping. become.
That is, the spool 1 cannot be rotated in the fishing line feeding direction.

In the drag force application operation described above, the contact time between the first drag disk 21 and the spool 1 can be adjusted to speed up or slow down the drag force.
This can be performed by rotating the screwing member 7 of the holding body 39. That is, when the screwing member 7 is rotated with respect to the slide member 38, the spool shaft 2 moves in the axial direction regardless of the rotation of the drag lever 6, so that the spool 1 and the first drag are moved. The initial set value of the clearance C1 formed between the disc 21 changes.
Therefore, if the initial set value of the clearance C1 is adjusted by adjusting the screwing amount of the screwing member 7, the spool shaft 2 until the first drag disk 21 and the spool 1 are in frictional contact with each other is adjusted. The moving distance (the amount of rotation of the drag lever 6) can be changed, and the rising of the drag force can be adjusted.
That is, in this embodiment, the holding body 39 functions as a drag fine adjustment mechanism.

  The first drag disk 21 having a weak braking characteristic functions in the initial to middle stage by the rotation operation of the drag grabber 6. When the drag grabber 6 is further rotated in accordance with the situation of the fishing spot, it is positioned in the middle to final stage. The second drag disk 32 side functions to obtain forced braking (proof strength) at high tension.

As described above, when the double-bearing type reel for fishing is configured, the drag disk disposed on both sides of the spool stably stabilizes the smooth braking force without a sudden rise. Can be granted.
In addition, since the drag force generators on both sides of the spool can be changed (friction force generator by the drag disk and spool side brake), smooth sliding friction is emphasized without unevenness at low tension. The drag performance suitable for the tension that changes depending on the type and size of the fish, such as (suppression of occurrence of stick-slip) and emphasis on forced braking force at high tension (strength), can be sufficiently obtained.

Needless to say, the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the scope of the invention.
For example, in the embodiment described above, the urging means for urging the drag disks 21 and 32 is a spring, but the urging means is not limited to a spring.
Also, the drag disk and the spool are moved to the handle side by the rotation operation of the drag lever 6. However, as is well known, the drag disk and the spool are pushed to the opposite handle side. May be.

It is a section rear view of the double bearing type reel for fishing concerning one embodiment of the present invention. It is a principal part expanded sectional rear view of the double bearing type reel for fishing. It is a cross-sectional side view of a reel leg. It is a reverse view of a reel leg.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Spool 2 Spool shaft 3 Reel body 20, 31 Spool side brake part 21, 32 Drag disk 26, 33 Compression spring (biasing means)
36 Drag mechanism A Adjustment member

Claims (1)

A spool supported rotatably on the reel body, and drag disks provided on both sides of the spool, respectively, are operated on the side of the spool by operating an adjustment member provided on the reel body. A double-bearing type fishing reel having a drag mechanism that applies a braking force to the rotation of the spool by frictional contact with a spool-side braking portion provided in the portion; A double-bearing type reel for fishing, characterized in that the drag disk and the spool-side braking portion provided on both sides are configured by braking force generating means having different frictional braking characteristics.