JP7221850B2 - fishing reel - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fishing reel, and more particularly to a fishing reel characterized by a drive gear that constitutes a drive gear that is rotationally driven by a winding operation of a handle and a pinion gear that meshes with the drive gear.

Among fishing reels, for example, a double-bearing reel has a winding drive mechanism for transmitting the rotation of a handle to a spool rotatably supported on a reel body, and a power transmission path of the winding drive mechanism, which is connected to the spool. It has a power transmission state that enables winding, and a clutch mechanism that switches the spool to a free rotation state and a power interruption state that enables the fishing line to be released.

The double-bearing reel described above has a structure suitable for casting a device such as a lure. (Patent Documents 1 and 2).

JP-A-10-165057 JP 2013-192507 A

When performing a casting operation using the above-described known double-bearing reel, after adjusting the length of the tackle hanging from the tip of the rod, the spool is thumbed at the same time as the clutch is disengaged while the reel body is held by hand. Casting operation toward the point of. Then, in anticipation of the landing timing of the tackle on the water, a spool thumbing operation and a clutch engagement operation (winding operation of the handle or operation of the clutch operating member) are performed, and a series of operations such as guidance and winding operations of the tackle are repeatedly performed. .

The clutch mechanism for the actual fishing of such a casting reel has each action of "clutching operation from ON to OFF", "clutching operation from OFF to ON", and "clutch winding operation maintaining ON state". Reliable performance without hindrance and efficient replay are required in the course of this series of continuous fishing operations. In other words, the quality of this series of operations affects the fishing results and is an important factor that affects casting performance.
Although the above-mentioned known document states that the flight distance is improved by reducing the inertia of the spool, it does not smoothly and reliably perform a series of continuous operations from the release operation of the tackle to the guidance and winding operation, and the casting is not. It is not possible to fully improve the performance.

The present invention has been made with a focus on the above-described problems, and is a fishing hook that can realize optimum fishing operations (clutch disengagement operability, clutch winding operability, clutch engagement operability) making full use of a clutch mechanism. The purpose is to provide a reel.

In order to achieve the above object, the present invention provides a spool rotatably provided between left and right side plates of a reel body, a drive gear provided on one of the side plates that rotates when a handle is rotated, and a drive gear that meshes with the drive gear. a clutch mechanism that switches the spool between a power transmission state and a power transmission state by sliding the pinion gear in the closed state by operating an external switching member to integrally engage and disengage the spool, the switching member comprising: is vertically movably provided at the rear of the spool of the reel body, wherein the spool radially protrudes from both sides of a bobbin trunk on which the fishing line is wound, and has an outer diameter of 20 mm to 50 mm. The clutch mechanism has a set flange portion, and the clutch mechanism is under meshing conditions in which the torsion angle β of the drive gear and the pinion gear is set to 5° ≤ β ≤ 25°, and the pressure angle α is set to 3° ≤ α ≤ 16°. is characterized by ON/OFF control of power transmission.

The torsion angle β of the pinion gear incorporated in the fishing reel having the above configuration is set to an optimum angle depending on the application, taking into consideration the rotational feel and ease of clutch disengagement. In such a meshing relationship between the drive gear and the pinion gear, by setting the pressure angle α to 3°≦α≦16°, the action acts perpendicularly to the tooth flanks of both gears in the meshed state. The linear force can be reduced, which also reduces the resistance force when the pinion gear slides in the axial direction, making it easier to disengage the clutch mechanism and stabilizing the clutch engagement state, resulting in good winding performance. can be maintained. That is, a series of continuous operations from the fishing line releasing operation in the casting operation to the fishing line winding operation can be performed lightly and reliably while maintaining a good rotational feeling during the winding operation.

According to the present invention, it is possible to obtain a fishing reel capable of realizing optimum fishing operations (clutch disengagement operability, clutch winding operability, and clutch engagement operability) making full use of the clutch mechanism.

1 is a plan view showing a first embodiment of a fishing reel (dual-bearing reel) according to the present invention; FIG. FIG. 2 is a view showing the principal part of the winding drive mechanism of the fishing reel shown in FIG. 1 (clutch ON state); FIG. 2 is a view showing the principal part of the winding drive mechanism of the fishing reel shown in FIG. 1 (clutch OFF state); FIG. 4 is an enlarged view of a drive gear incorporated in the take-up drive mechanism; (a) is a perspective view showing an engaging pin and an engaging wall portion of a pinion gear, and (b) is a cross-sectional view showing a state in which the engaging pin is engaged with the engaging wall portion. The enlarged view which shows the modification of a pinion gear. Schematic diagram showing a state in which gears are meshed to transmit power. FIG. 4 is a plan view showing a second embodiment of a fishing reel (dual-bearing reel) according to the present invention;

First, referring to FIGS. 1 to 3, a fishing reel according to one embodiment of the present invention will be described by exemplifying a dual-bearing reel.
When the present invention is used as a dual-bearing reel, it includes a type that is suitable for various fishing methods such as boat fishing and lure fishing, but it is particularly suitable for lure fishing. .

As shown in FIGS. 1 to 3, a reel body 1 of a dual-bearing reel includes left and right frames 2a and 2b, and left and right frames 2a and 2b mounted on the left and right frames 2a and 2b with a predetermined space therebetween via seal materials. Side plates 3a and 3b are provided. The left and right frames 2a and 2b are integrated via a plurality of supports, and the reel body 1 is attached to the reel seat (not shown) of the fishing rod by reel legs (not shown) provided on the lower supports.

A spool shaft 5 is rotatably supported between the left and right frames 2a and 2b (left and right side plates 3a and 3b) via bearings 4A and 4B. The spool 6 has a fishing line winding body (line winding body) 6a around which the fishing line is wound, and flanges 6b, 6b on both left and right sides. It is regulated and wound around the fishing line winding trunk 6a.

In order to reduce the weight of the spool 6 of the present embodiment, the spool shaft 5 is fitted to the inner central portion of the fishing line winding body portion 6a through a disk-shaped connecting portion 6c so as to prevent rotation. A hollow portion (gap) S is formed between the fishing line winding body portion 6a and the spool shaft 5. As shown in FIG. That is, the spool 6 is configured to reduce the inertial force, mitigate the impact, and improve the clutch engagement operability. In this case, the spool 6 is made of a lightweight metal such as an aluminum alloy or a magnesium alloy so as to reduce its weight, and may have an opening if necessary.

The size of the spool 6 is specified by the outer diameter of the flange portion 6b. As described above, the dual-bearing reel of the present invention is suitable for lure fishing. A small type is considered so that the series of operations described above can be performed without trouble (without getting tired). For this reason, the outer diameter D of the flange portion 6b of the spool 6 is in the range of 20 mm to 50 mm, and the size of the reel body is reduced according to the size of the spool. In addition, although the side plates 3a and 3b of the reel body of the present embodiment are circular in side view, a spool having an outer diameter D of the flange portion 6b in the range of 20 mm to 50 mm is incorporated and gripped. , as long as it is easy to hold, its shape is not limited.

The spool 6 configured as described above is rotated by rotating a handle 10 attached to the end of the handle shaft 7 projecting from the right side plate 3b. The winding operation of the handle 10 is transmitted to the spool 6 via a winding drive mechanism described below.

The handle shaft 7 is rotatably supported between the right frame 2b and the right side plate 3b via a bearing (not shown), and is reeled in by a one-way clutch (not shown) interposed between the right side plate 3b and the right side plate 3b. It is configured to be rotatable only in one direction.

A drive gear 11 is provided between the right frame 2b and the right side plate 3b and is rotatably supported by the handle shaft 7 to transmit the rotational motion of the handle 10 to the spool shaft 5 side. A known drag mechanism 12 that applies a predetermined drag force to the spool 6 by engaging with the drive gear 11 that is rotated by operation is accommodated. The drag mechanism 12 applies a predetermined drag force to the spool 6 when the fishing line is let out from the spool 6 during fishing, and includes a plurality of friction plates 12a that abut against the drive gear 11. - 特許庁Such a drag mechanism 12 is adapted to adjust the pressing force against the drive gear 11 by rotating the operating member 13 arranged at the end of the handle shaft 7 , so that the drag against the spool 6 is adjusted. Configured to be adjustable in force.

The teeth 11A of the drive gear 11 are meshed with a pinion gear 21 (teeth 21A of the pinion gear 21) that constitutes a part of the clutch mechanism 20 and serves as a power transmission member. The pinion gear 21 is a member that transmits the rotation of the drive gear 11 to the spool 6 (spool shaft 5). 5) is penetrated.

In this embodiment, the right end side of the spool shaft 5 is in contact with the large diameter portion 5A, the small diameter portion 5B continuous with the large diameter portion 5A, and the shaft portion 5C extending from the small diameter portion 5B (or the end surface of the small diameter portion 5B). The shaft portion 5C is inserted through the center hole 21a of the pinion gear 21 as described above. The spool shaft 5 is provided inside an adjusting member 60 (dial operating body) whose right end face 5a (of the shaft portion 5C) is screwed to the support portion 3ba of the reel body 1 (right side plate 3b). Movement in the axial direction is restricted by contacting the direction restricting portion 62 . The adjusting member 60 constitutes an operating member of a spool braking mechanism 70 that applies a braking force to the free rotation of the spool. Pressure is applied as a braking force.

A circumferential groove 21b is formed in a part of the pinion gear 21 along the circumferential direction, and a clutch member 23 constituting a clutch mechanism 20 is engaged with the circumferential groove 21b. The clutch mechanism 20 slides the pinion gear 21 by operating a clutch operating member (switching member) 24 arranged vertically movably behind the spool, and integrally engages and disengages the spool 6 to transmit power to the spool. It is a mechanism that switches between the state and the cut-off state. A cam 24b formed on a cam member 24a movably (slidably or rotationally) supported by the right frame can be engaged with the clutch member 23, as is well known. , and 2b, the clutch operating member 24 is moved downward (switching operation from the clutch ON state to the clutch OFF state), and the clutch member 23 is moved by the cam 24b of the moving cam member 24a. , is driven rightward in the figure against the biasing force of the biasing member 90 . That is, the pinion gear 21 is moved to the right along the spool shaft 5 via the cam member 24a by the depressing operation (clutch OFF operation) of the clutch operating member 24, and as will be described later, the engagement with the spool shaft is disengaged. It will come off and will be in a clutch OFF state.

The cam member 24a described above is preferably made of resin, which has good operating efficiency, in order to reduce sliding frictional resistance between the right frame 2b and the clutch member 23. As shown in FIG.
As described above, the clutch operating member 24 is disposed at the rear of the spool so that it is easy to cut while holding the reel body 1. This provides good operating efficiency for reducing the principle of leverage and frictional resistance. The combination with the cam member 24a and the organic coupling relationship between the pressure angles of the drive gear and the pinion gear, which will be described later, enable smooth clutch OFF operation.

The pinion gear 21 has teeth 21A meshing with the drive gear 11 on both sides in the axial direction (both sides of the teeth 21A meshing with the drive gear 11 on the spool 6 side and the side plate 3b side). 3b) is supported via a collar C (resin material) by the bearings 24A and 24B provided in 3b). Supported. That is, the pinion gear 21 is supported by a first bearing 24A on the side connected to the spool 6 and supported by a second bearing 24B on the side opposite to the side connected to the spool 6 . Incidentally, the collar C may be eliminated and both sides of the pinion gear 21 may be directly supported by the bearings 24A and 24B.

A left end portion of the pinion gear 21 on the spool 6 side is provided with a concave portion 25a that can be engaged with and disengaged from an engaging pin 5b provided at the right end portion (small diameter portion 5B) of the spool shaft 5 . In this case, the engaging pin 5b projects in the diametrical direction of the spool shaft 5, and the concave portion 25a is formed in the end face of the pinion gear along the diametrical direction so that the engaging pin 5b is fitted therein. (See Figure 5). As shown in FIG. 2, the state in which the engaging pin 5b of the spool shaft 5 is engaged with the concave portion 25a is the clutch ON state, and as shown in FIG. The state in which the pinion gear 21 is moved rightward in the drawing and the engagement pin 5b is disengaged from the concave portion 25a (the state in which the two are disengaged) is the clutch OFF state.

The pinion gear 21 can be automatically returned from the clutch OFF state to the clutch ON state by a known automatic return mechanism when the clutch operating member 24 is operated to return or when the handle 10 is retracted. ing.

A level wind device 50 is provided between the left and right frames 2a and 2b of the reel body 1. The level wind device 50 includes a guide tube 51 and a guide tube 51 rotatably supported therein. A worm shaft, an engaging member 53 having a pin (not shown) that engages with the worm shaft, and a fishing line guide portion 54 attached to the engaging member 53 are provided. A gear (not shown) is attached to the right side of the worm shaft, and this gear meshes with a gear (not shown) that rotates integrally with the drive gear 11 or the handle shaft 7. .

In the dual-bearing reel constructed as described above, when the handle 10 is rotated in the clutch-on state shown in FIGS. transmitted to the spool side.
That is, the rotation of the handle 10 is transmitted from the handle shaft 7 through the drag mechanism 12 to the drive gear 11 and the gear, and then transmitted through the gear to the worm shaft of the level wind device 50, which rotates the worm shaft. rotate. At this time, the engaging member 53 of the level wind device 50 slides left and right in accordance with the rotational motion of the worm shaft, so that the fishing line is evenly wound around the spool 6 via the fishing line guide portion 54 of the engaging member 53. is turned.

Further, the rotational driving force transmitted to the drive gear 11 by the rotating operation of the handle 10 is transmitted to the pinion gear 21 and is transmitted to the spool shaft 5 via the engagement pin 5b engaged with the concave portion 25a of the pinion gear 21. transmitted. The spool 6 is thereby driven to rotate.

When the clutch operation member 24 is moved from the clutch ON state (fishline winding state) shown in FIGS. 1 and 2 (from the clutch ON state to the clutch OFF state), the clutch member 23 is , through the cam 24b of the cam member 24a, the pinion gear 21 engaged with the clutch member 23 is moved rightward in the drawing against the biasing force of the biasing member 90, As a result, the recess 25a of the pinion gear 21 is disengaged from the engagement pin 5b of the spool shaft 5, as shown in FIG. Therefore, the spool 6 is in a freely rotatable state (fishing line reeling-out state) in which the transmission of rotational power from the drive gear is interrupted.

At this time, the teeth 11A of the drive gear 11 and the teeth 21A of the pinion gear 21 are always in meshing relationship, and therefore the tooth flanks 21F (see FIG. 5A) of the pinion gear 21 and the tooth flanks of the drive gear 11 11F (see FIG. 4) slides in a meshed contact state.

Thereafter, when the handle 10 is rotated or the clutch operating member 24 is operated, the clutch mechanism 20 is returned from the clutch OFF state to the clutch ON state, and the pinion gear 21 is moved toward the spool shaft 5 (left side). . As a result, the end surface of the pinion gear 21 comes into contact with the engagement pin 5b of the spool shaft 5 while rotating in the direction of the arrow in FIG. 5(a). The end face of the pinion gear 21 is formed such that the end 25f1 side is high and the end 25f2 side is low along the circumferential direction, and the engagement pin 5b abuts against the end 25f1 side of the engagement wall portion 25e to form a concave portion. 25a, and abuttingly engages with the engaging wall portion 25e in the rotational direction (see FIG. 5(b)).

As shown in FIG. 5(a), the concave portion 25a of this embodiment is formed in the end surface of the pinion gear along the diametrical direction so that the engaging pin 5b is fitted therein, and the concave portion 25a is formed along the axial direction of the spool shaft 5. is provided with an engaging wall portion 25e parallel to the . By forming the engaging wall portion 25e so as to be parallel to the axial direction of the spool shaft 5 in this way, as shown in FIG. A stable abutment surface can be secured with the wall portion 25e, and unnecessary gaps can be prevented, thereby preventing the engaging pin 5b from accidentally coming off the recessed portion 25a or rattling. This is suppressed, and the operability of engaging the clutch and the state of engagement with the drive gear are stabilized, thereby improving the winding operability (clutch winding operability).
The concave portion 25a into which the engaging pin 5b is fitted may be formed in a cross direction as shown in FIG.

The drive gear 11 and the pinion gear 21 (also collectively referred to as the drive gear) are always in mesh with each other. 21F and the tooth surface 11F of the drive gear 11 have a special feature that they slide in contact with each other. In addition, in the power transmission by meshing the gears of the fishing reel, when the handle is wound, the mesh is as smooth as possible and noise is not generated. Adopted. That is, as shown in FIG. 4, the drive gear 11 is formed such that the teeth 11A (tooth flanks 11F) continuously formed in the circumferential direction are twisted, and the teeth 21A (tooth flanks 21F) of the pinion gear 21 are twisted. is also formed to be twisted as shown in FIG. 5(a).

Here, the torsion angle (β) of the driving gear in the present invention will be explained.
The torsion angle is an angle specifying how much the tooth (tooth trace) 21e is twisted with respect to the axis X of the gear when the pinion gear 21 of FIG. If there is, it is a meshing relationship between the spur gears. As described above, in the fishing reel, the meshing relationship of the drive gear is set to a certain degree of torsional angle so as to ensure smooth meshing and to prevent noise.

In the drive gear incorporated in the fishing reel according to the present invention, the torsion angle (β) is set to 5°≦β≦25°.
When the pinion gear 21 is slid toward the right side plate against the biasing force of the biasing member 90 by pushing down the clutch operating member 24, the torsion angle becomes a factor that hinders the sliding. , the pinion gear 21 becomes easier to slide. However, if the torsion angle is set too small, the smoothness of rotation is reduced, noise is likely to occur, and sliding is likely to occur. . Specifically, in the power transmission state (clutch ON state), when the force of the tooth surface of the gear to press the spool side weakens and a strong load is applied to the fishing line, the pinion gear 21 slides and the spool slides. Problems such as easy disengagement and erroneous return even in the clutch OFF state occur. In particular, if the engaging wall portion 25e of the concave portion 25a formed at the end portion of the pinion gear 21 is inclined so as to correspond to the torsion angle, such a problem is likely to occur.

The lower limit of the twist angle is set to 5°, which is such that the above-described problem does not occur remarkably (inconvenience during use does not occur). If the torsion angle is set large, smoothness is improved, noise is reduced, and malfunction of the pinion gear can be prevented. It becomes difficult to push down. Specifically, when the twist angle is 20° or more, it tends to be difficult to push down. ° is preferred.
In this case, in a small casting reel that is gripped and held together with a fishing rod (as shown in FIG. 1, a reel incorporating a spool having a flange portion with an outer diameter D of 20 mm to 50 mm), during actual fishing, the clutch ON Since it is used to frequently repeat OFF operation, casting operation, clutch ON operation, and handle winding operation, the return operation can be performed smoothly, and even if such operations are repeated for a long time, you will not get tired. It is desirable to In other words, for this type of fishing reel, the upper limit of the twist angle should be set at 20°, preferably 18°.

In fact, when examining various commercially available dual-bearing reels, the torsion angle of the drive gear varies depending on the application, but is generally set within the range of 5°≦β≦20°. That is, for jigging and boat fishing, the noise at the time of winding the fishing line does not matter so much, and the smooth rotation performance is not so much required, so the twist angle is set to a relatively small angle within the above range. In a casting reel using a lure, etc., the twist angle is set to a relatively large angle within the above-described range because frequent turning operations and delicate winding operations are performed. In particular, in a reel incorporating a small-diameter spool 6 as shown in FIG. 1, the helix angle β can be set in the range of 15° to 20° so as to increase the meshing ratio and obtain smooth rotation. preferable.

As described above, in the case of a small reel, especially a reel used for lure casting, it is considered preferable to set the twist angle to a certain extent, but if it is set too large, a strong tension acts on the fishing line. In this case, the clutch mechanism cannot be quickly turned off.
In the present invention, even under such circumstances, the pressure angle of the drive gear is adjusted so that the clutch disengagement operation can be performed smoothly, and further, the clutch engagement operation and the clutch winding operation can be performed smoothly without any trouble. I am paying attention.

Here, the pressure angle (α) of the drive gear incorporated in the fishing reel will be described with reference to the schematic diagram of FIG.
The teeth 11A and 21A of the drive gear 11 and the pinion gear 21 are formed with an involute tooth profile. In the figure, if the radii of the base circle of each gear (the circle forming the base of the involute gear) are indicated by R11 and R21, the involute tooth profile of each tooth assumes that a thread is wound around the base circle, and the thread is wound in a tensioned state. It is defined by the curve drawn by the tip when solving with . The pressure angle is the angle α between the common tangent line L to the base circles of both gears and the common tangent line L1 at the point of contact (pitch point P) of the reference circles (circles indicated by radii R11a and R21a) of both gears. .

That is, the pressure angle is defined in the direction orthogonal to the tooth flanks of the involute tooth profile, and the force Fn acting in this direction becomes the power transmitting force (force pushing the tooth flanks; normal force on each tooth flank). In this case, if the tooth flanks are formed so that the pressure angle α becomes small, the base circles R11 and R21 of each gear become large. becomes small (By setting the pressure angle small, the normal force Fn on each tooth surface can be made small).

As described above, due to the action of the clutch mechanism, the pinion gear 21 slides in the axial direction while being meshed with the drive gear. If the normal force Fn acting on the tooth flanks of the pinion gear 21 becomes smaller, it becomes easier for the pinion gear 21 to slide. That is, as the pressure angle α becomes smaller, the frictional resistance when the pinion gear 21 slides in the axial direction is reduced, making it easier to disengage the clutch.

Currently, a standard reference rack tooth profile (JIS B 1701-1 2012; standard involute tooth profile) is used for a tool (hob) that forms an involute tooth surface of a gear incorporated in a fishing reel, and the pressure angle α is 20° is adopted. In this case, even if such a tool is used, it is possible to form a gear having a pressure angle in the range of 17° to 19° depending on the amount of shift. Regarding the pressure angle α, as described above, it is considered advantageous to make the pressure angle smaller than the conventional general angle of 20° in consideration of the operability of the clutch mechanism. An evaluation test (sensory test) was conducted to determine how small the clutch can be made to improve operability including ease of clutch disengagement.

The evaluation test was conducted by five testers, and a small double-shaft reel for lure fishing was used so that a series of operations such as clutch disengagement operability, clutch engagement operability, and clutch winding operability could be comprehensively evaluated. I did. That is, in lure fishing, the above operation is frequently repeated, and in the winding operation, it is easy to grasp subtle differences. For the evaluation, a plurality of double-bearing reels of the same size with different torsion and pressure angle settings of the drive gear incorporated in the reel body were prepared, and each tester performed the above series of operations on each reel. Comprehensive evaluation was performed repeatedly. Specifically, the reels used were evaluated on a 3-point scale, with 3 points if felt very good, 1 point if felt good, and 0 points if there was no change from before. When the total score was 12 points or more, it was evaluated as ⊙, when it was 8 points or more, it was evaluated as Δ, and when it was 3 points or less, it was evaluated as ×.

In the dual-bearing reel used, the outer diameter D of the flange portion 6b shown in FIG. The center-to-center distance Ld is 22.6 mm, and the gear ratio of the driving gears 11 and 21 is 6.3. Further, the radius of rotation of the handle 10 is 45 mm. Engagement wall portions 25e, 25e are formed so as to be axially parallel to the spool shaft (axis X) (see FIGS. 2 and 5). The end surface of the pinion gear 21 is formed as an inclined surface so that one edge portion 25f2 side is lower than the other edge portion 25f1 side. 25e so as to be easily abutted and engaged.

In the reel of the above configuration, the torsion angles β are formed at 5°, 10°, 15°, 20° and 25°, and the pressure angles α are formed at 14°, 16°, 18° and 20°, respectively. I prepared the one incorporating the drive gear that was designed. In this case, the 20° pressure angle is a drive gear built into a conventional double-bearing reel.
The results of the evaluation test are shown in Table 1 below.

According to the results of the evaluation test described above, when the pressure angle was 18°, the overall evaluation of all testers did not show that much improvement was made between the reel of 20° and the conventional reel. When the angle was set as small as 16° and further 14°, the overall evaluation of the tester as a whole tended to improve, so it can be said that the pressure angle is preferably set to 16° or less. That is, by setting the pressure angle to 16° or less in the range of the twist angle of 5°≦β≦25°, the operability described above is improved.

Further, as the pressure angle is reduced, the involute tooth flank gradually becomes steeper, causing a problem of undercut at the root of the tooth. For this reason, the lower limit of the pressure angle is related to the number of teeth (gear ratio) and module of the driving gear, but when cutting the tooth surface, the angle at which undercut does not occur, specifically 3° (preferably 5°) or more. That is, in the present invention, the pressure angle of the drive gear may be set within the range of 3°≦α≦16°.

When the gear is rotationally driven, the normal force (surface pressure) Fn acting on the tooth surface changes depending on the pressure angle α. As described above, the normal force Fn decreases as the pressure angle decreases, but along with this, the strength on the root side decreases due to the undercut. In other words, when the pressure angle is reduced to reduce the normal force, the tooth flanks tend to become steeper, and the tooth dedendum tends to be ground and undercut, resulting in a decrease in strength as a gear. In particular, in a fishing reel in which the clutch mechanism is continuously turned on and off by sliding the gears in mesh with each other, a reduction in the strength of the gears makes it impossible to stably maintain good clutch performance during actual fishing. Therefore, the permissible surface pressure (maximum surface pressure) for the drive gear is specified, and the strength of the gear is analyzed for the relationship between the torsion angle (β) and pressure angle (α) for each surface pressure. Analysis software was also used to analyze the permissible pressure angle for each torsion angle that can withstand each surface pressure.
In this analysis, when a constant surface pressure acts on the tooth flank of the drive gear, the surface pressure is allowed for each torsion angle of 5°, 10°, 15°, 20°, 25°, and 30°. We obtained the minimum and maximum values of the pressure angle. In addition, the driving gears to be meshed had a center-to-center distance of 22.6 mm, a gear ratio of 6.3, and an arbitrary module.
The analysis results are shown in Table 2 below.

In the table above, the case where the surface pressure is 800 MPa corresponds to the case where a material with relatively high strength and high yield strength is used for the driving gear. Considering such materials, the minimum value of the pressure angle can be set to 6°. That is, if the range of 6° ≤ α ≤ 16° is set, and if a material with high yield strength (yield strength of material strength 400 to 600 MPa) is used, the tooth strength will be sufficient even if the pressure angle is set to 6°. can be maintained. The table also analyzes the case where the maximum surface pressure is 450 MPa, but this corresponds to the case where a material having a low yield strength is used as the driving gear. Even if the drive gear is made of such material, the strength of the teeth can be maintained by setting the pressure angle to 11° or more. That is, if the pressure angle is set within the range of 11°≦α≦16°, it is possible to maintain sufficient tooth strength even if the drive gear is formed using a material with low yield strength. is.

As described above, in the meshing relationship between the drive gear 11 and the pinion gear 21, the torsion angle β is 5°≦β≦25° and the pressure angle α is 3°≦α≦16° (preferably 6°≦α≦16°). °, more preferably 11° ≤ α ≤ 16°), the power transmission of the clutch mechanism is controlled ON/OFF under the meshing conditions, respectively, so that the reel body is gripped and held together with the fishing rod during actual fishing. In this state, the ON/OFF operation of the clutch can be performed smoothly. In addition, even when tension is applied to the fishing line, the clutch operation member 24 installed on the rear side of the spool can be easily pushed down while maintaining the gripping and holding state, and the clutch can be quickly and easily turned off. It becomes possible to do it easily. That is, a series of continuous operations (clutch winding operability, clutch disengagement operability, clutch engagement operability) transitioning from fishing line release in casting operation to fishing line winding while maintaining a good rotational feeling at the time of winding operation ) can be performed easily and reliably.

Also, in a small reel suitable for casting operation, as described above, it is preferable to form the torsion angle β to be relatively large (15° to 20°). For example, since a large sliding resistance is generated when switching the clutch from ON to OFF, it is preferable to set the pressure angle α small within the above range. Specifically, if the torsion angle β is 15°≦β≦20°, the pressure angle α can be set in the range of 6°≦α≦16°, further 6°≦α≦12°. preferable.

Further, an engaging wall portion 25e which is formed at the end of the pinion gear 21 and engages the engaging pin 5b provided on the support shaft of the spool to abut and engage in the rotational direction is arranged parallel to the axial direction of the spool shaft. , the meshing state between the pinion gear 21 and the drive gear 11 is stabilized, so that the winding rotation performance (operability to engage the clutch and clutch winding operability) can be improved. In this case, unlike the prior art, the engagement wall portion of the engagement groove of the pinion gear that engages with the engagement pin of the spool shaft must be precisely machined so that the helical teeth are inclined. Instead, the clutch can be easily turned off simply by forming the engaging wall portion parallel to the axial direction and cutting the tooth surface so as to have a predetermined pressure angle. Therefore, the manufacturing process does not become complicated, and high-precision processing is not required, so the manufacturing cost does not increase.

In addition, as described above, the spool 6 of the present embodiment has a hollow portion (gap) S formed between the fishing line winding body portion 6a and the spool shaft 5 to reduce weight. Such a spool reduces the inertial force when the spool rotates freely during casting, and when the clutch is turned on, the impact on the concave portion 25a of the engagement pin 5b is alleviated, so that the clutch can be reliably turned on. becomes possible.

Further, since the pinion gear 21 is rotatably and axially movably supported on the reel body by bearings 24A and 24B on both axial sides of the teeth 21A that mesh with the drive gear, the pinion gear 21 is axially slidable. is stabilized, the engagement of the engagement pin 5b in the concave portion 25a when the clutch is ON and the disengagement of the engagement pin 5b from the concave portion 25a when the clutch is OFF, and optimum clutch performance can be exhibited.

As described above, it is effective to apply the fishing reel incorporating the drive gear (meshing system) described above to a small reel for lure fishing or the like. For example, in the dual-bearing reel of the second embodiment shown in FIG. 8, the above-described miniaturized spool 6 is incorporated, and the left and right side plates 3a and 3b of the reel body 1A are formed circular when viewed from the side. The other side plate (the left side plate 3a on the side opposite to the handle) is formed to have a smaller diameter in the radial direction than the other side plate (the right side plate 3b on the side of the handle).

In this way, by making the left and right side plates of the reel body different in size (different shape), the side plate side in which the winding drive mechanism is accommodated is enlarged to secure a sufficient space, while at the time of actual fishing, the fishing rod can be used. At the same time, the reel body becomes easier to grasp and hold, and the operability described above can be further improved. In this case, by setting the center-to-center distance Ld between the drive gear and the pinion gear within the range of 15 mm to 30 mm, the above configuration of the spool 6 (the outer diameter of the flange portion 6b is set to 20 mm to 50 mm). ), a compact reel body is constructed, and a dual-bearing reel with good casting operability is obtained.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and can be modified in various ways.
In the miniaturized dual-bearing reel described above, it is preferable that the radius of rotation of the handle is set to 30 mm to 80 mm. That is, with such a radius of rotation, in addition to a good rotational feeling, it is possible to carry out a small-step induction winding operation of the tackle.

In addition, it is preferable that the spool 6 can be driven to take up with a tooth ratio of the drive gear 11 and the pinion gear 21 (the gear ratio is 1:6 or more) so that the spool 6 rotates 6 times or more with one rotation of the handle. . According to such a gear ratio, it is possible to prevent the tackle from sinking unnecessarily by rotating the handle in a state in which the spool is rotating in the payout direction at the time of landing on the water in the casting operation to quickly shift to the winding state. and it is possible to retrieve the device quickly.

Further, the above-described engaging wall portion is not only parallel to the axial direction of the spool shaft at the portion against which the engaging pin abuts in the rotational direction, but also inclined with respect to the axial direction or tapered at the opening edge. etc. may be formed. Further, the fishing reel according to the present invention can be appropriately modified in configuration members such as the shape of the side plate, and can be applied to single bearing reels as well as double bearing reels.

1 reel body 5 spool shaft 5b engagement pin 6 spool 10 handle 11 drive gear 11A teeth 20 clutch mechanism 21 pinion gear 21A teeth 24A, 24B bearing 25a recess

Claims (2)

A spool rotatably provided between the left and right side plates of the reel body, a drive gear that rotates by rotating a handle provided on one side plate, and a pinion gear that is in mesh with the drive gear are operated by an external switching member. a clutch mechanism that switches the spool between a power transmission state and a power transmission state (OFF) by sliding and integrally engaging and disengaging with the spool,
A fishing reel in which the switching member is vertically movably provided behind the spool of the reel body,
The spool has flange portions protruding in the radial direction on both sides of the bobbin trunk portion on which the fishing line is wound and having an outer diameter of 20 mm to 50 mm,
The power transmission of the clutch mechanism is ON/OFF controlled under the meshing conditions in which the torsion angle β of the drive gear and the pinion gear is set to 15°≦β≦20° and the pressure angle α is set to 6°≦α≦12°. ,
The spool is formed in the shape of a disk in the inner central portion of the bobbin trunk, and has a support portion through which a spool shaft for holding the spool penetrates, and a hollow portion is formed between the bobbin trunk and the spool shaft. and
A fishing reel, wherein the distance between the shaft centers of the drive gear and the pinion gear is set to 15 mm to 30 mm, and the other side plate is formed to have a smaller diameter in the radial direction than the one side plate. 2. The fishing reel according to claim 1, wherein said pinion gear is rotatably and axially movably supported by said reel body through bearings on both axial sides of teeth that mesh with said drive gear. .

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