JP2010110256A - Fishing reel - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a fishing reel in which a driving portion well holding rotation performance, even when used at a spinning spot severe in use environment and not limiting a forming material, is built. <P>SOLUTION: There is provided the fishing reel in which a line can be wound on a spool by the rotation operation of a handle rotatably supported on a reel body 1, characterized in that the reel body 1 has non-magnetic pinion gears 7, a bearing 6A disposed between the pinion gears 7, and a magnetic seal mechanism 30 disposed to seal the bearing 6A; and the magnetic seal mechanism 30 has a holding member 32 for holding a ring-like magnet 31, a cylindrical magnetic member 33 fit to the non-magnetic pinion gear 7 and having a length for forming a magnetic circuit between at least the holding members 32, and a magnetic fluid 35 held between the ring-like magnet 31 and the cylindrical magnetic member 33. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a fishing reel characterized by a support structure of a drive shaft that is rotationally driven by a rotation operation of a handle connected to a winding drive mechanism provided in a reel body.

  Usually, a fishing reel is configured to wind a fishing line around a spool via a power transmission mechanism by rotating a handle. The power transmission mechanism is provided with a drive shaft that is rotationally driven in accordance with the rotation operation of the handle. Generally, the drive shaft is rotatably supported via a ball bearing (bearing) provided on the reel body. ing.

  By the way, when using a fishing reel at an actual fishing spot, there is a specific problem that seawater, sand, foreign matter, etc. are likely to adhere to the reel body, and these are internal via a gap outside the reel body. And adheres to and enters the ball bearing that supports the drive shaft. If seawater, sand, foreign matter or the like adheres to or enters the ball bearing, the ball bearing is corroded or rotational performance is deteriorated.

  As a countermeasure against such a problem, it is common practice to make the ball bearing waterproof and dustproof by bringing a seal member made of an elastic material into contact with the outer periphery of the drive shaft adjacent to the ball bearing. A problem has been pointed out that the rotational performance of the drive shaft is deteriorated due to the influence of the contact pressure of the seal member made of the above.

Therefore, as a configuration for waterproofing and dustproofing the ball bearing without deteriorating the rotational performance of the drive shaft, for example, Patent Document 1 discloses a configuration between a magnetic holding ring constituting a magnetic circuit and a spool shaft (drive shaft). And a magnetic fluid held and sealed.
JP 2003-319742 A

  In the above-described known technology, the magnetic circuit for holding the magnetic fluid is composed of a ring magnet, a magnetic holding ring, and a spool shaft. Therefore, the spool shaft is necessarily made of a magnetic material (iron-based material). There is a need.

  However, when the spool shaft is made of a magnetic material, there arises a problem that the spool shaft is easily corroded. For this reason, it is necessary to treat the surface as a countermeasure against corrosion. However, if the surface treatment is applied, the accuracy (fitting state, runout, etc.) of the spool shaft will be inferior and abnormal noise will be generated during casting. Problems such as high costs will arise. In addition, forming the spool shaft (drive shaft) with a magnetic material restricts the material to be used, and it is not possible to effectively achieve weight reduction or the like.

  The present invention has been made paying attention to the above-mentioned problems, and has a built-in drive unit that maintains good rotation performance and is not restricted by the forming material even when used in fishing environments where the usage environment is severe. An object is to provide a fishing reel.

  In order to achieve the above-described object, the fishing reel according to the present invention has a configuration in which a fishing line can be wound around a spool by a rotation operation of a handle rotatably supported on the reel body. A non-magnetic drive unit; a bearing disposed between the drive unit; and a magnetic seal mechanism disposed to seal the bearing, wherein the magnetic seal mechanism is a ring-shaped magnet. A holding member that holds the magnet, a cylindrical magnetic body that is fitted to the non-magnetic driving unit and has a length at which a magnetic circuit is formed at least between the holding member, the ring-shaped magnet, and the cylindrical shape And a magnetic fluid held between the two magnetic bodies.

  According to the configuration of the fishing reel described above, the cylindrical magnetic body is fitted to the drive unit to form the magnetic seal mechanism, so that it is not necessary to form the drive unit with a magnetic material. The drive unit is prevented from being corroded and the like, and the drive unit need not be subjected to corrosion treatment or the like. In addition, an optimum material can be selected without being restricted by the material forming the driving unit.

  In the above configuration, the drive unit includes a drive shaft that rotates like a spool shaft of a dual-bearing reel, a drive shaft that slides in an axial direction like a spool shaft of a spinning reel, or such a drive unit. In addition, a member that integrally rotates or slides integrally is included. The bearing may be interposed between the drive shaft and the reel body (including a support part and a holding part mounted in the reel body separately from the reel body). It may be interposed between the reel body and the cylindrical magnetic body.

  Further, in order to achieve the above-mentioned object, the present invention has a configuration in which a fishing line can be wound around a spool by a rotation operation of a handle rotatably supported on the reel body. A nonmagnetic collar member fitted to the drive unit; a bearing disposed on the outer peripheral side of the nonmagnetic collar member; and a magnetic seal mechanism disposed to seal the bearing. The magnetic seal mechanism is a cylindrical member that is fitted to the holding member holding the ring-shaped magnet and the non-magnetic collar member, and has a length at which a magnetic circuit is formed at least between the holding member. A magnetic body and a magnetic fluid held between the ring-shaped magnet and the cylindrical magnetic body are provided.

  As described above, the cylindrical magnetic body constituting the magnetic seal mechanism is not directly fitted to the fishing reel drive unit, but fitted to the non-magnetic color members attached to various drive units. The composition may be combined.

  According to the present invention, it is possible to obtain a fishing reel that incorporates a drive unit that maintains good rotation performance even when used in fishing grounds where the use environment is severe and is not restricted by the forming material.

Hereinafter, embodiments of a fishing reel according to the present invention will be described with reference to the drawings.
1 and 2 are views showing a first embodiment of the present invention. FIG. 1 is a view showing an internal configuration, and FIG. 2 is an enlarged view of a main part shown in FIG.

  The fishing reel according to the present embodiment is configured as a spinning reel of a rotor brake type used particularly in a dredge where seawater or the like is likely to enter.

  A handle shaft 2 is rotatably supported on the reel body 1 of the spinning reel via bearings 3A and 3B, and a handle 2A to be wound is attached to the end of the handle shaft 2. The bearings 3 </ b> A and 3 </ b> B are installed between the reel body 1 and the handle shaft 2, and support the handle shaft 2 so as to be rotatable with respect to the reel body 1.

  The drive shaft 4 is externally fitted to the handle shaft 2 of the present embodiment so that the drive gear 4 can rotate integrally. The bearings 3A and 3B are cylindrical shaft portions (drive portions) 4a formed integrally with the drive gear 4. And the reel body 1, the handle shaft 2 is rotatably supported. In this case, a magnetic seal mechanism 30A, which will be described later, is disposed adjacent to the bearings 3A and 3B on the cylindrical shaft portion 4a serving as a drive unit.

  A drive gear 4 that is externally fitted to the handle shaft 2a so as to be rotatable integrally with the handle shaft 2a extends in a direction orthogonal to the handle shaft 2 and is rotatably supported via bearings 6A and 6B. 7 tooth portions 7A mesh with each other. A rotor 9 provided with a bail 9a and a fishing line guide device 9b is attached to a tip end portion of the pinion gear 7 by screwing a rotor nut 8 so as to rotate integrally. In this case, a magnetic seal mechanism 30 to be described later is disposed on the pinion gear 7 serving as a drive unit adjacent to the bearing 6A.

  The pinion gear 7 penetrates along the axial direction, and a spool shaft (drive unit) 11 holding a spool 10 around which a fishing line is wound is inserted into the pinion gear 7. A known oscillating mechanism (not shown) is connected to the base end side of the spool shaft 11, and when the handle shaft 2 is rotated by the rotation operation of the handle 2 </ b> A, the spool shaft 11 is axially moved. It is driven back and forth along. In this case, a bearing 13 is interposed between the spool shaft 11 and the rotor nut 8 so as to rotatably support the rotor nut 8 that fixes the rotor 9 to the pinion gear 7. Specifically, the spool shaft 11 is inserted into a collar member (made of a non-magnetic member) 15 installed at the front end edge of the pinion gear 7, and the bearing 13 is interposed between the collar member 15 and the rotor nut 8. Intervened. The collar member 15 is formed of, for example, an aluminum alloy or a synthetic resin material (for example, POM material), and is fitted to the outer periphery of the spool shaft 11 so as to be rotatable and slidable. It is inserted with a slight press fit. The collar member 15 is provided with a magnetic seal mechanism 30 </ b> B, which will be described later, adjacent to the bearing 13.

  With the above-described configuration, when the handle 2A is rotated, the spool 10 reciprocates back and forth via the oscillating mechanism, and the rotor 9 is driven to rotate via the drive gear 4 and the pinion gear 7. The fishing line is wound evenly through the fishing line guide device 9b.

  In addition, when the rotor 9 is in the free rotation state, a fish is caught in the reel body 1 and when the rotor 9 rotates in the fishing line discharge direction (when the rotor 9 rotates reversely), a braking force is applied to the rotor 9. A known braking mechanism 20 is provided.

  The brake mechanism 20 is movable in the axial direction with respect to the brake rotor 23 that is rotatably disposed via a bearing 22 on a support member 21 that is integrally fixed to the reel body 1. In this way, the brake plate 25 is rotatively fitted so as to be integrally rotatable and biased rearward by a spring 24, and is disposed so as to sandwich the brake plate 25, and is supported by the frame of the reel body. And a brake shoe 26b slidably supported toward the pressure contact piece 26a.

  A ratchet 9c is fixed to the inner surface of the rotor 9, and a stopper 23a rotatably supported by the brake rotor 23 is supported on the ratchet 9c so as to be engageable. The pinion gear 7 is fitted with a cylindrical member 27 formed with a flange 27a, and a friction spring 28 that engages with the stopper 23a is held on the flange 27a. The friction spring 28 has a function of engaging the stopper 23a with the ratchet 9c when the rotor 9 rotates in the reverse direction.

  When the rotor 9 rotates in the reverse direction, the stopper 23a is engaged with the ratchet 9c by the friction spring 28, and the brake plate 25 rotates in reverse together with the brake rotor 23 by the frictional force generated by the urging force of the spring 24. To do.

  The brake shoe 26b is directed toward the pressure contact piece 26a by pulling an operation lever (not shown) supported so as to be rotatable with respect to a reel mounting leg (not shown) of the reel body 1. Accordingly, when the rotor 9 rotates in the reverse direction, the operation lever is pulled to hold the brake plate 25 between the pressure contact piece 26a and the brake shoe 26b so that the rotor 9 can be moved. Thus, a desired braking force can be applied.

  Next, the magnetic seal mechanism disposed in the spinning reel configured as described above will be described.

  FIG. 3 is an enlarged view showing the magnetic seal mechanism 30 disposed in the pinion gear 7 serving as a drive unit in the configuration shown in FIGS. 1 and 2. In the present embodiment, the magnetic seal mechanism 30 is disposed adjacent to the bearing 6A out of the bearings 6A and 6B that support the pinion gear 7.

  The pinion gear 7 described above is made of a non-magnetic material (for example, copper alloy, aluminum alloy, etc.), and the bearing 6A that rotatably supports the pinion gear 7 with respect to the reel body 1 is sealed by a magnetic seal mechanism 30. It is in the state.

  The magnetic seal mechanism 30 is fitted into a ring-shaped magnet 31 arranged so as to surround the pinion gear 7 with a predetermined gap, a holding member (magnetic ring) 32 for holding the magnet, and a cylindrical portion 7B of the pinion gear 7. And is held between the ring-shaped magnet 31 and the cylindrical magnetic body 33, and at least the cylindrical magnetic body 33 having a length facing the holding member 32. And a magnetic fluid 35.

  In this case, the holding member 32 of the present embodiment is configured so as to sandwich and hold the ring-shaped magnet 31 and to have a recess 31 </ b> A along the circumferential direction inside the ring-shaped magnet 31. In addition, the holding member 32 that holds the ring-shaped magnet 31 is configured such that a slight gap G is generated between the holding member 32 and the outer surface of the cylindrical magnetic body 33.

  The cylindrical magnetic body 33 is formed of an iron-based material, for example, steel, SUS430, SUS440C, SUS630, and the like. Thereby, the ring-shaped magnet 31 holds the holding member 32 and the cylinder. A magnetic circuit is formed between the magnetic bodies 33. Note that the length of the cylindrical magnetic body 33 only needs to be long enough to generate the above-described magnetic circuit (a length that can stably hold the magnetic fluid). The cover member is formed to be slightly longer than the axial length of the holding member.

The magnetic fluid 35 is formed by dispersing magnetic fine particles such as Fe ₃ O ₄ in a surfactant and base oil, and has a characteristic of reacting when a magnet is brought close to the magnet. For this reason, as shown in FIG. 3, the magnetic fluid 35 includes a ring-shaped magnet 31, a holding member 32 that holds the magnet 31, and a magnetic circuit formed by a cylindrical magnetic body 33, so that the inside of the recess 31 </ b> A G is stably held in G and seals the bearing 6A.

  The magnetic seal mechanism 30 configured as described above is fixed to the reel body 1. Specifically, one of the holding members 32 that sandwich and hold the ring-shaped magnet 31 is in close contact with the reel body 1 (here, the recess 21a formed in the support member 21 that is integrally fixed to the reel body 1). The other is abutted against the bearing 6A with a nonmagnetic washer 36 interposed therebetween.

  In the present embodiment, the cylindrical magnetic body 33 is positioned by having one end applied to the end surface of the cylindrical member 27 and the other end applied to the bearing 6A (inner ring portion). Yes.

  In this case, it is preferable that the cylindrical magnetic body 33 is non-rotatably fitted to the nonmagnetic pinion gear 7 so that the sealing performance with respect to the bearing 6A is enhanced. That is, since the cylindrical magnetic body 33 is fitted to the pinion gear 7 so as to rotate together with the pinion gear 7, moisture or the like is transmitted between the inner periphery of the cylindrical magnetic body 33 and the outer periphery of the pinion gear 7. Can be effectively suppressed.

  In such a configuration, a circumferential groove 7 a is further formed on the outer periphery of the pinion gear 7, and a sealing member 37 made of an elastic material is formed between the circumferential groove 7 a and the cylindrical magnetic body 33. Is preferably disposed. In the present embodiment, the seal member 37 is configured as an O-ring made of a rubber material. By providing such a seal member 37, a more reliable seal structure can be obtained. In addition, since the above-mentioned magnetic circuit is comprised about the sealing member 37 besides an O-ring, it can also be comprised with a magnetic fluid.

  By providing the magnetic seal mechanism 30 configured as described above, the following operations and effects can be obtained.

  The magnetic seal mechanism 30 is configured to hold the magnetic fluid 35 by a magnetic circuit and seal the bearing 6A. The magnetic seal mechanism 30 is not configured to seal a seal member made of a conventional elastic material in contact with a drive unit, so that contact pressure is reduced. Thus, the rotational performance of the pinion gear 7 is not deteriorated.

  Further, as described above, by arranging the cylindrical magnetic body 33, it is not necessary to form the pinion gear 7 with a magnetic body such as an iron-based material, and a material that does not corrode (for example, a copper alloy), Alternatively, a material that can be reduced in weight (for example, an aluminum alloy) can be used. For this reason, the room for material selection is widened, and a reliable sealing effect is obtained by the magnetic fluid 35 described above. Therefore, it is not necessary to subject the bearing 6A and the pinion gear 7 to a surface treatment for preventing corrosion, thereby reducing costs. It becomes possible to do.

  Furthermore, since it is not necessary to perform such surface treatment or the like, the accuracy is not lowered, and it is possible to prevent the generation of noise or the like during casting or winding of the fishing line.

  The magnetic seal mechanism as described above is not limited to the bearing portion of the pinion gear 7, and can be installed in various portions. In the spinning reel according to the present embodiment, the bearings 3A and 3B installed between the cylindrical shaft portion (drive portion) 4a of the drive gear 4 that is externally fitted to the handle shaft 2 and rotates integrally with the reel body 1 are further provided. The magnetic seal mechanism 30A having the same configuration is used for sealing (see FIGS. 2 and 4).

  Hereinafter, a magnetic seal mechanism installed in another part will be described. However, constituent members having the same functions as those of the magnetic seal mechanism 30 described above are denoted by the same reference numerals, and detailed description thereof will be omitted. The magnetic fluid constituting the magnetic seal mechanism is omitted in the drawing.

  The handle shaft 2 of the present embodiment can be changed to the left and right with respect to the reel body 1, and a screw 2 a that prevents the handle shaft 2 from coming off from the other side of the reel body is provided at the front end side of the handle shaft 2. Is formed so as to be screwed in with a spacer 2b interposed therebetween. A cover member 2c is screwed to the reel body on the side opposite to the handle of the reel body 1 to close the screw 2a.

  Therefore, when the handle is replaced in the configuration of FIG. 2, the handle shaft 2 is removed by removing the cover member 2c from the reel body 1 and loosening the screw 2a. Then, the removed handle shaft 2 may be fitted to the cylindrical shaft portion 4a from the opposite side, and the screw 2a may be screwed in via the spacer 2b from the opposite side, and finally the cover member 2c may be attached.

  As shown in FIGS. 2 and 4, the magnetic seal mechanism 30 </ b> A is provided between the reel body 1 (the cover support member 1 d integrated with the reel body 1) and the cylindrical shaft portion (drive portion) 4 a of the drive gear 4. Thus, it is installed so as to seal the bearing 3B disposed on the cylindrical shaft portion 4a.

  A cylindrical shaft portion 4a of the drive gear 4 is formed of a nonmagnetic material integrally with the drive gear 4, and a cylindrical magnetic body 33 is connected to the nonmagnetic cylindrical shaft portion 4a by a drive. It is fitted (externally fitted) so that it can rotate integrally with the gear. In this case, the cylindrical magnetic body 33 is positioned and held so that it cannot move in the axial direction between the bearing 3 </ b> B and the stepped portion 2 e formed on the handle shaft 2.

  Further, when the magnetic seal mechanism 30A is installed, a non-magnetic washer may be installed so as to improve the sealing performance with the reel body 1 (the cover support member 1d integrated with the reel body 1). good. In the configuration shown in FIG. 4, a plurality of nonmagnetic washers 36 a and 36 b are provided between one of the holding members 32 that sandwich and hold the ring-shaped magnet 31 and the cover support member 1 d integrated with the reel body 1. On the other hand, a non-magnetic washer 36 is interposed and applied to the bearing 3B.

  In the magnetic seal mechanism 30A as described above, similarly to the magnetic seal mechanism 30 described above, it is not necessary to form the drive gear 4 with a magnetic material, and the bearing 3B can be reliably sealed.

  FIG. 5 is an enlarged view of the rotor nut portion in the configuration shown in FIG.

  As described above, the spool 13 has the bearing 13 with the collar member 15 made of a nonmagnetic member interposed between the spool nut 11 and the rotor nut 8 so as to rotatably support the rotor nut 8 that fixes the rotor 9. The collar member 15 is provided with a magnetic seal mechanism 30 </ b> B adjacent to the bearing 13.

  The magnetic seal mechanism 30 </ b> B is fitted to the holding member 32 that holds (clamps) the ring-shaped magnet 31 and the nonmagnetic collar member 15, and has a length at which a magnetic circuit is formed at least between the holding member 32. A cylindrical magnetic body 33 and a magnetic fluid (not shown) held between the ring-shaped magnet 31 and the cylindrical magnetic body 33 are provided, and these are recesses formed in the rotor nut 8. It is arranged in 8a.

  In the present embodiment, the cylindrical magnetic body 33 is externally fitted to the tip of the collar member 15, and the bearing 13 is arranged on the outer peripheral side of the portion where the cylindrical magnetic body 33 is not externally fitted. Has been established. The base end side of the collar member 15 is bent outward in the radial direction, and the inner ring of the bearing 13 is held against this portion. The rotor nut 8 is formed with a recess 8b in which the bearing 13 is installed continuously with the recess 8a, and the outer ring of the bearing 13 is applied to and held by the step portion of the recess 8b.

  The bearing 13 described above is installed in the recess 8b of the rotor nut 8, and the ring magnet 31 and the holding member 32 sandwiching the ring magnet 31 are installed in the recess 8a of the rotor nut 8. In this state, the nonmagnetic material is provided. The bending member 39 comprised by is attached. The bending member 39 is elastically locked to the flange 8c of the rotor nut 8, so that as shown in FIG. 6, the bearing 13, the ring-shaped magnet 31, and this are sandwiched. The holding member 32 and the nonmagnetic washers 36 and 36 a are held against the rotor nut 8.

  That is, the member mounted on the reel body 1 such as the rotor nut 8 incorporates the bearing 13 as described above, and the ring-shaped magnet 31 constituting the magnetic seal mechanism 30B for sealing the bearing 13, The holding member 32 held (clamped) and the nonmagnetic washers 36 and 36a can be integrated (unitized).

  The rotor nut 8 having such a structure is configured such that the collar member 15 is fitted to the spool shaft 11 and the rotor 9 is prevented from rotating around the pinion gear 7 and then screwed into the male screw portion 7d formed at the tip of the pinion gear 7. Entered. The bearing 13 can be magnetically sealed by filling a magnetic fluid between the ring-shaped magnet 31, the holding member 32 holding the ring-shaped magnet 31, and the cylindrical magnetic body 33.

  In the above configuration, the rotor nut 8 can be unitized by incorporating the bearing 13 and the ring-shaped magnet 31 constituting the magnetic seal mechanism, the holding member 32 sandwiching the magnet, the non-magnetic washers 36 and 36a, etc. In addition to the functions and effects described above, the handleability can be improved. If the collar member 15 formed of a synthetic resin is fitted into the inner ring of the bearing 13 by a slight press fit, the collar member 15 including the collar member 15 can be unitized.

  7 and 8 are views showing a modification of the rotor nut to be unitized. In the configuration shown in FIGS. 5 and 6, the collar member 15 is made of a nonmagnetic material, but in this modification, the collar is formed of a magnetic material (hereinafter referred to as a magnetic collar 15A). In this case, as shown in FIG. 8, the rotor nut 8 has a structure in which the magnetic collar 15 </ b> A, the ring-shaped magnet 31, and the holding member 32 that sandwiches the magnet 15 </ b> A are unitized.

  According to such a configuration, it becomes possible to unitize the magnetic fluid in a state of being filled in advance, and the handling property can be further improved.

  The magnetic seal mechanism as described above can be disposed in various portions where the bearing is installed in the spinning reel. For example, in addition to the above-described portion, as shown in FIG. 2, it may be installed in the portion of the bearing 22 where the braking mechanism 20 is disposed. A magnetic seal mechanism 30 </ b> C installed in this portion is fitted (internally fitted) with a cylindrical magnetic body 33 to the brake rotor 23, which is a non-magnetic drive unit, and is fixed integrally to the reel body 1. On both sides of the bearing 22 of the supporting member 21, a ring-shaped magnet 31, a holding member 32 that holds (holds) the magnet, non-magnetic washers 36 and 36 a, and the like are disposed.

  Even in such a configuration, the bearing 22 can be magnetically sealed without forming the brake rotor 23 of a magnetic material. Of course, the magnetic seal mechanism 30C may have a unit structure as shown in FIGS.

Next, a second embodiment of the fishing reel according to the present invention will be described.
In the above-described embodiment, the spinning reel is exemplified as the fishing reel, but the present invention can also be applied to a dual-bearing type reel.

  FIG. 9 is a diagram showing a second embodiment of the fishing reel according to the present invention, and is a diagram showing an internal configuration.

  A reel body 51 of a fishing reel (double bearing type reel) according to the present embodiment includes left and right side plates 51A and 51B that rotatably support a spool 55 around which a fishing line is wound. The left side plate 51A includes a left frame 52a and a left cover 53a attached to cover the left frame 52a. The right side plate 51B is attached to cover the right frame 52b and the right frame 52b. And a right cover 53b to be worn.

  A handle 57 for rotationally driving the spool 55 is installed on the right side plate 51B side. The handle 57 is rotatably supported in the right side plate 51B via bearings 56A and 56B. It is attached to the end of the.

  The spool 55 is fixed to a spool shaft 55a that is rotatably supported by bearings 58A and 58B with respect to the left and right side plates 51A and 51B.

  A known power transmission mechanism 60 for transmitting the rotational driving force of the handle 57 to the spool 55 is installed in a space formed between the right frame 52b and the right cover 53b. The spool 55 is rotationally driven through the power transmission mechanism 60 by performing the removing operation.

  The magnetic seal mechanism disposed in the dual bearing reel configured as described above will be described.

  FIG. 10 is an enlarged view of the magnetic seal mechanism 30D installed in the bearing 58A portion provided on the left side plate side of the spool shaft 55a serving as the drive unit in the configuration shown in FIG.

  The spool shaft 55a is made of a nonmagnetic material as in the above-described embodiment, and the left end portion of the spool shaft 55a is a cylindrical support formed on the reel body 51 (the left cover 53a constituting the reel body). The part 53d) is rotatably supported by a bearing 58A.

  The magnetic seal mechanism 30D for sealing the bearing 58A is installed on the spool side with respect to the bearing 58A, and holds the ring-shaped magnet 31 arranged so as to surround the spool shaft 55a with a predetermined gap. (Holding) holding member 32, cylindrical magnetic body 33 fitted to spool shaft 55a (externally fitted in this embodiment) and having a length facing at least holding member 32, and ring magnet And a magnetic fluid (not shown) held between the cylinder 31 and the cylindrical magnetic body 33.

  The cylindrical magnetic body 33 only needs to have such a length that a magnetic circuit is generated between the ring-shaped magnet 31 and the holding member 32 (a length that can stably hold the magnetic fluid). The holding member 32 is formed to be slightly longer than the axial length of the holding member so as to be covered.

  The magnetic seal mechanism 30 </ b> D configured as described above is fixed to the reel body 51. Specifically, each of the ring-shaped magnet 31 and the holding member 32 that holds and holds the magnet 31 is fitted (internally fitted) on the inner surface of the cylindrical support portion 53d adjacent to the bearing 58A. One of the members 32 is retained by a nonmagnetic washer 36a that is retained on the inner surface of the cylindrical support portion 53d via a retaining ring 53f, and the other of the retaining members 32 is disposed with a nonmagnetic washer 36 interposed therebetween. It is applied to the bearing 58A.

  In the present embodiment, the cylindrical magnetic body 33 is positioned by one end being applied to the retaining ring 55d attached to the spool shaft 55a and the other end being applied to the bearing 58A. ing.

  In this case, like the above-described embodiment, the cylindrical magnetic body 33 is preferably non-rotatably fitted to the nonmagnetic spool shaft 55a so that the sealing performance with respect to the bearing 58A is enhanced. Further, it is preferable that a seal member 37 as shown in FIG. 3 is disposed between the spool shaft 55a and a cylindrical magnetic body that is fitted to the spool shaft 55a.

  FIG. 11 is an enlarged view of the magnetic seal mechanism 30E installed in the bearing 58B portion installed on the right side plate side of the spool shaft 55a serving as the drive unit in the configuration shown in FIG.

  The right end portion of the spool shaft 55a is rotatably supported by a bearing 58B with respect to the reel body 51 (cylindrical support portion 52e formed on the right frame 52b constituting the reel body.

  Similar to the magnetic seal mechanism 30D described above, the magnetic seal mechanism 30E that seals the bearing 58B is installed on the spool side with respect to the bearing 58B, and is disposed so as to surround the spool shaft 55a with a predetermined gap. A ring-shaped magnet 31, a holding member 32 that holds (holds) the magnet 31, and a cylindrical shape that is fitted to the spool shaft 55 a (externally fitted in this embodiment) and has a length that faces at least the holding member 32. And a magnetic fluid (not shown) held between the ring-shaped magnet 31 and the cylindrical magnetic body 33.

  The ring-shaped magnet 31 constituting the magnetic seal mechanism 30E configured as described above and the holding member 32 for holding and holding the magnet are fitted on the inner surface of the cylindrical support portion 52e adjacent to the bearing 58B. One of the holding members 32 is retained by a non-magnetic washer 36a that is retained on the inner surface of the cylindrical support 52e via a retaining ring 52f, and the other of the retaining members 32 is It is applied to the bearing 58B with a non-magnetic washer 36 interposed therebetween. Further, the cylindrical magnetic body 33 is positioned by one end being applied to the fitting cylindrical portion 55f of the spool 55 fixed to the spool shaft 55a and the other end being applied to the bearing 58B. .

  By installing the magnetic seal mechanisms 30D and 30E as described above, it is not necessary to form the spool shaft 55a with a magnetic material such as an iron-based material, and a material that does not corrode or can be reduced in weight is used. It becomes possible to do. For this reason, the room for material selection is widened, and a reliable sealing effect can be obtained by the magnetic fluid, so that the bearings 58A and 58B and the spool shaft 55a need not be subjected to a surface treatment for preventing corrosion, thereby reducing costs. It becomes possible to do.

  Furthermore, since it is not necessary to perform such surface treatment or the like, the accuracy is not lowered, and it is possible to prevent the generation of noise or the like during casting or winding of the fishing line.

  FIG. 12 is an enlarged view of the magnetic seal mechanism 30F installed on the bearing 56B portion provided on the right cover 53b side of the handle shaft 57a serving as the drive unit in the configuration shown in FIG.

  The handle shaft 57a described above is formed of a non-magnetic material as in the above-described embodiment, and an operating body 71 constituting a known drag mechanism 70 is screwed to the right end portion. When the operation body 71 is rotated, the first pressing body 73 which is a collar member fitted to the handle shaft 57 a so as to be movable in the axial direction moves in the axial direction, and the second pressing body 77 is moved via the disc spring 75. The friction member 78 is pressed with a desired pressing force, and a braking force is generated between the handle shaft 57a and the drive gear 61 constituting the power transmission mechanism 60.

  The right end portion of the handle shaft 57a is rotatably supported by a bearing 56B with respect to the reel body 51 (cylindrical support portion 53e formed on the right cover 53b constituting the reel body). In this case, the bearing 56B is installed on the first pressing body 73 which is a collar member.

  The magnetic seal mechanism 30F for sealing the bearing 56B is installed on the handle side with respect to the bearing 56B, and the ring-shaped magnet 31 disposed so as to surround the handle shaft 57a, and a holding member for holding (holding) the magnet. 32 and a cylindrical magnetic body 33 which is fitted to the first pressing body 73 fitted to the handle shaft 57a (externally fitted in this embodiment) and has a length facing at least the holding member 32; And a magnetic fluid (not shown) held between the ring-shaped magnet 31 and the cylindrical magnetic body 33. The cylindrical magnetic body 33 is fitted on the inner periphery of the inner ring of the bearing 56B and is restricted in the axial direction by a stopper, so that the first pressing body 73 does not move following the axial movement. It has become.

  The cylindrical magnetic body 33 only needs to have such a length that a magnetic circuit is generated between the ring-shaped magnet 31 and the holding member 32 (a length that can stably hold the magnetic fluid). In this embodiment, a flange 33d is formed at the base end portion so as to prevent the bearing 56B from coming off.

  The ring-shaped magnet 31 of the magnetic seal mechanism 30F configured as described above and the holding member 32 that holds and holds the magnet 31 are fitted on the inner surface of the cylindrical support portion 53e adjacent to the bearing 56B (inside One of the holding members 32 is secured by a nonmagnetic washer 36a that is retained on the inner surface of the cylindrical support 53e via a retaining ring 53f, and the other of the retaining members 32 is nonmagnetic. This is applied to the bearing 58A with a washer 36 interposed therebetween.

  Even with such a magnetic seal mechanism 30F, it is not necessary to form the handle shaft 57a with a magnetic material such as an iron-based material as in the case of the magnetic seal mechanism described above, and a material that does not corrode or can be reduced in weight. Can be used.

  Moreover, in this embodiment, you may comprise the 1st press body 73 with a magnetic body. By comprising in this way, the said cylindrical magnetic body 33 becomes unnecessary and it becomes possible to combine the function as a press body of a drag mechanism, and the function as a cylindrical magnetic body of a magnetic seal mechanism.

  FIG. 13 is an enlarged view showing a modified example of the magnetic seal mechanism 30E shown in FIG.

  In the magnetic seal mechanism 30G of this modification, an inner flange 40a is formed on the proximal end side of the cylindrical portion 40 formed of a nonmagnetic material, and a bearing 58B is applied to and held in this portion, and the cylindrical portion 40 is also held. A ring-shaped magnet 31, a holding member 32 that holds (holds) the magnet, and nonmagnetic washers 36 and 36 a are fastened to the inner surface of each of the members, so that a part of the members constituting the magnetic seal mechanism is united. (The unitized part is indicated by reference numeral 30G ′).

  Such a unit body 30G ′ can be installed at a predetermined position by fitting the retaining plate 45 to the inner surface of the cylindrical support portion 52e from the left side of the spool shaft 55a and then screwing it. It becomes possible. Then, the magnetic seal mechanism 30G can be constructed by inserting the cylindrical magnetic body 33 from the left side of the spool shaft 55a and finally filling the magnetic circuit portion with magnetic fluid.

  According to such a configuration, since a part of the magnetic seal mechanism is unitized, the assemblability can be improved.

  14 and 15 are enlarged views showing another modification of the magnetic seal mechanism 30E shown in FIG.

  In the magnetic seal mechanism 30H of this modification, in the configuration shown in FIG. 13, an inner cylindrical portion 47 made of a magnetic material is further formed on the radially inner side of the cylindrical portion 40, and a step portion is formed in this portion. As shown in FIG. 15, the entire magnetic seal mechanism is unitized by providing 47c and a retaining ring 47d and engaging the bearing 58B with the inner cylindrical portion 38b.

  According to the magnetic seal mechanism 30H unitized in this way, the magnetic circuit portion can be filled in advance with the magnetic fluid, so that the incorporation can be further improved.

  As mentioned above, although embodiment of this invention was described, this invention is not limited to above-described embodiment, It can change variously. The magnetic seal mechanism having the above-described configuration can be installed in the bearing portion of various fishing reels, and the type of the target reel and the portion where the bearing is installed are not particularly limited. Absent.

  Moreover, about the cylindrical magnetic body fitted to a drive part or a collar member, it may be externally fitted or may be internally fitted. Furthermore, when configuring the magnetic seal mechanism, the ring-shaped magnet and the shape of the holding member for holding the magnet can be appropriately modified.

It is a figure which shows 1st Embodiment (spinning reel) of the fishing reel which concerns on this invention, and the figure which showed the internal structure. The enlarged view of the principal part shown in FIG. The enlarged view of the magnetic-seal-mechanism part installed in a pinion gear part in the structure shown in FIG. FIG. 3 is an enlarged view of a magnetic seal mechanism portion installed on a handle shaft portion in the configuration shown in FIG. 2. The enlarged view of the magnetic seal mechanism part installed in a rotor nut part in the structure shown in FIG. The enlarged view of the rotor nut part shown in FIG. The figure which shows the modification of the magnetic seal mechanism installed in a rotor nut part. The enlarged view of the rotor nut part shown in FIG. It is a figure which shows 2nd Embodiment (double bearing type reel) of the fishing reel which concerns on this invention, and the figure which showed the internal structure. FIG. 10 is an enlarged view of a magnetic seal mechanism portion installed on the left side plate side of the spool shaft in the configuration shown in FIG. 9. FIG. 10 is an enlarged view of a magnetic seal mechanism portion installed on the right side plate side of the spool shaft in the configuration shown in FIG. 9. In the structure shown in FIG. 9, the enlarged view of the magnetic-seal-mechanism part installed in a handle shaft part. The figure which shows the modification of the magnetic seal mechanism shown in FIG. The figure which shows another modification of the magnetic seal mechanism shown in FIG. The figure which shows the state which removed the magnetic seal mechanism shown in FIG. 14 from the reel main body.

Explanation of symbols

1, 51 Reel body 2A, 57 Handles 3A, 3B, 6A, 6B Bearing 4 Drive gear 4a Tube shaft portion 7 Pinion gear (drive portion)
9 Rotor 10, 55 Spool 11 Spool shaft (drive unit)
13, 22 Bearing 15 Collar member 30, 30A-30H Magnetic seal mechanism 31 Ring magnet 32 Holding member 33 Cylindrical magnetic body 35 Magnetic fluid 56A, 56B, 58A, 58B Bearing

Claims (4)

In a fishing reel that allows a fishing line to be wound around a spool by rotating a handle that is rotatably supported by the reel body,
The reel body includes a non-magnetic driving unit, a bearing disposed between the driving unit, and a magnetic seal mechanism disposed to seal the bearing.
The magnetic seal mechanism is a cylindrical magnetic body that is fitted to the holding member that holds a ring-shaped magnet and the non-magnetic driving unit, and has a length that forms at least a magnetic circuit between the holding member and the magnetic sealing mechanism. And a magnetic fluid held between the ring-shaped magnet and the cylindrical magnetic body.   The fishing reel according to claim 1, wherein the cylindrical magnetic body is prevented from rotating with respect to the non-magnetic driving unit.   The fishing groove according to claim 1 or 2, wherein a circumferential groove is formed in the non-magnetic driving portion, and a sealing member is disposed between the cylindrical magnetic body and the circumferential groove. reel. In a fishing reel that allows a fishing line to be wound around a spool by rotating a handle that is rotatably supported by the reel body,
The reel body is disposed so as to seal the drive unit, a nonmagnetic collar member fitted to the drive unit, a bearing disposed on an outer peripheral side of the nonmagnetic collar member, and the bearing. And a magnetic seal mechanism
The magnetic seal mechanism is a cylindrical magnetic body that is fitted to the holding member holding a ring-shaped magnet and the non-magnetic collar member and has a length at which a magnetic circuit is formed at least between the holding member. And a magnetic fluid held between the ring-shaped magnet and the cylindrical magnetic body.

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