KR20120070959A - Structure for controlling spool rotation of bait cast reel - Google Patents

Abstract

PURPOSE: A spool rotation control structure for a baitcast reel is provided to prevent magnetic force from being applied to a spool. CONSTITUTION: A spool rotation control structure for a baitcast reel comprises a spool cover(100), a first cam(200), a magnet assembly(300), a second cam(400), and a control dial(500). The spool cover is arranged in the upper part of the spool. The first cam is combined with the upper part of the spool cover and is provided with restoring force in the opposite direction of the spool. The magnet assembly is combined with the first cam and is lifted as the first cam is lifted. The second cam is combined with the first cam and lifts the first cam. The control dial forms an insertion groove on the bottom thereof.

Description

STRUCTURE FOR CONTROLLING SPOOL ROTATION OF BAIT CAST REEL}

The present invention relates to a spool rotation control structure of a bait cast reel, and more particularly, to a spool rotation control structure of a bait cast reel in which the spool is controlled by a magnetic force or not, thereby controlling the rotation speed of the spool.

When fishing using a bait cast reel that emits a fishing line by casting, the fishing line is thrown with a bait while holding the reel body mounted on the fishing rod together with the fishing rod.

At this time, the fishing line wound on the spool of the reel is released by drawing a parabola, the acceleration is attached to the spool while falling past the convex vertex of the parabola.

This causes a so-called backlash phenomenon in which the rotation speed of the spool becomes faster than the speed at which the fishing line is released from the spool. Due to such a backlash phenomenon, a fishing line that cannot be smoothly released from the reel is entangled in the reel body.

Therefore, in order to prevent the backlash phenomenon, the skilled person pressed the upper part of the spool with a thumb or the like when the fishing line is released so that the rotation speed of the spool is equal to or smaller than the speed at which the fishing line is released.

However, the inexperienced person who lacks practical experience suffers a lot of trial and error until he or she is used to the above method of preventing the backlash phenomenon.

Various means are proposed to solve this backlash through a mechanical structure, for example, a spool rotation control means using a magnet.

However, the conventional spool rotation control structure including a magnet, because the continuous magnetic force acts to brake the rotation of the spool even when the braking of the spool rotation is unnecessary, resulting in a reduction in flying distance during casting, thereby casting the desired point There is a drawback to not doing it.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and provides a spool rotation control structure in which when the braking is unnecessary for the spool rotation, it can rise further from the allowed lifting width of the magnet so that the influence of magnetic force on the spool is not affected. The purpose is.

In addition, the process of ascending the magnet from the position of the magnetic influence to the spool to the position that does not affect quickly to provide a spool rotation control structure that allows the user to control the spool rotation appropriate to the fishing situation The purpose is.

In order to solve the above problems, the spool rotation control structure of the bait cast reel according to the embodiment of the present invention is disposed on the upper side of the spool and the spool shaft is coupled to rotate material; A first cam coupled to the upper side of the spool cover, the first cam being provided with a restoring force in an opposite direction to the spool by an elastic means provided between the spool cover; A magnet assembly coupled to the first cam and being lifted together according to the elevation of the first cam; A second cam helically coupled to the first cam so that the first cam is lifted according to rotation; And the second cam is coupled to be rotationally constrained, and the first cam is further raised by the restoring force by the elastic means after the first cam is lifted by the rotation of the second cam as the first cam is rotated in one direction, or the other direction. As it rotates, the first cam is lowered while overcoming the restoring force by the elastic means, and includes a control dial for spirally coupling with the second cam.

According to the present invention, a section in which the first cam further rises according to the rotation of the control dial is formed even after the lifting by the rotation of the second cam is completed. Therefore, even if the distance between the adjusting dial and the spool cover is not unnecessarily widened, it is possible to raise the magnet so that the magnetic force is not affected on the spool within the range of the predetermined interval.

In addition, in the lifting section of the first cam in which the magnetic force acts on the spool, the first cam is gradually raised and lowered so that the braking force for the rotation of the spool can be finely adjusted, and the magnet is raised to a position where the braking force is not applied to the spool. In the section, since the first cam vertically rises with the restoring force of the elastic means, there is an advantage that the state in which the braking force is applied to the rotation of the spool and the state in which the braking force is not applied, that is, the free state of the spool can be switched within a short time.

1A and 1B are exploded perspective views illustrating a spool rotation control structure of a bait cast reel according to an embodiment of the present invention;
2A and 2B are exploded perspective views illustrating enlarged main parts of FIGS. 1 and 2;
3 is a cross-sectional view illustrating a state in which the control structure illustrated in FIGS. 1 and 2 is assembled.

The spool rotation control structure of the bait cast reel according to the preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. In addition, the directions set forth below are set to aid understanding based on the accompanying drawings and do not mean that the directions are always limited to these directions regardless of the criteria.

1A and 1B are exploded perspective views illustrating a spool rotation control structure of a bait cast reel according to an exemplary embodiment of the present invention, and FIGS. 2A and 2B illustrate an adjustment dial, a first cam, and the first cam shown in FIGS. 3 is an exploded perspective view illustrating an enlarged second cam, and FIG. 3 is a cross-sectional view illustrating an assembled state of the spool rotation control structure illustrated in FIGS. 1 and 2.

As shown, the spool rotation control structure includes a spool cover 100, a first cam 200, a magnet assembly 300, a second cam 400, and an adjustment dial 500.

As shown in FIG. 3, the spool cover 100 is disposed above the spool 10, and the end of the spool shaft 11 coupled through the spool 10 is coupled to rotate.

As shown as a specific example of the coupling structure, the insertion groove 101 is formed in the lower side of the spool cover 100 and the bearing 102 is coupled to the insertion groove 101, the spool shaft ( 11) a structure in which the rotating material is combined can be presented. At this time, the retainer 103 may be coupled to the lower side of the insertion groove 101 which is the lower portion of the bearing 102 to prevent the bearing 102 from being separated. In addition, the spool on the upper side of the insertion groove 101 to prevent friction wear between the upper end of the spool shaft 11 and the spool cover 100 insertion groove 101 portion that may be generated by the rotation of the spool shaft 11. The washer 104 may be coupled to be interposed with the top of the shaft 11.

On the upper side of the spool cover 100, the main cover 20, which is to be joined, is provided with a screw member to prevent the various parts to be described later, which are arranged between the spool cover 100, from being exposed to the outside, and to maintain the arrangement state. (21) and the like.

The first cam 200 is coupled to be lifted from the upper side of the spool cover 100. Lifting means that a space for lifting the first cam 200 is formed on the upper side of the spool cover 100, and coupled to lift means that they are coupled to each other so as not to be separated with respect to the spool cover 100. to be.

Specifically, the guide rod 110 is formed to protrude upward from the upper side of the spool cover 100, and a guide hole 201 through which the guide rod 110 is inserted into the first cam 200 is formed. 200 may be coupled to the spool cover 100 to be elevated while being guided along the guide rod 110 in a state in which the guide rod 110 is inserted into the guide hole 201.

At this time, the first cam 200 is provided with a restoring force in the opposite direction to the spool 10 by the elastic means 150. A specific example of the elastic means 150 may be presented a coil spring, the coil spring is provided between the spool cover 100 and the first cam 200.

Specifically, the coil spring may be inserted and disposed in the guide rod 110 described above, and the upper end of the coil spring may be compressed and deformed in contact with the bottom surface of the first cam 200 where the guide hole 201 is formed. The cam 200 is provided with a restoring force in the above-described direction.

The magnet assembly 300 is coupled to the first cam 200. The magnet assembly 300 is a means for generating a magnetic force, and is lifted together with the lifting of the first cam 200. As the magnet assembly 300 descends together with the first cam 200, the narrower the gap with the spool 10, the greater the magnetic force acting on the spool 10, thereby reducing the rotational speed of the spool 10. This increases, and as the distance from the spool 10 increases with the first cam 200, the magnetic force acting on the spool 10 decreases, so that the braking force for reducing the rotational speed of the spool 10 decreases.

An example of a specific structure of the magnet assembly 300 may include a magnet holder 310 coupled to the first cam 200 and a plurality of magnets housed in the magnet holder 310, as shown in FIGS. 1A and 1B. An example consisting of 320 may be presented.

At this time, it is preferable that the magnet assembly 300 is disposed at a position close to the spool 10 so that an appropriate magnetic force action is applied to the spool 10.

Therefore, in order to achieve such a structure, a coupling part 202 penetrating through the spool cover 100 may be formed in the first cam 200, and the coupling part 202 penetrates through the spool cover 100 so that the lower end thereof is spool ( 10) is located above. The magnet assembly 300 may be disposed below the spool cover 100 close to the spool 10 while the magnet holder 310 is coupled to the coupling portion 202 by a screw member 12 or the like.

The second cam 400 is coupled to the first cam 200 to control the lifting of the first cam 200 while the first cam 200 is provided with the restoring force by the elastic means 150. The second cam 400 is rotated together in accordance with the rotation of the control dial 500 to be described later so that the first cam 200 is elevated.

The following example may be presented as a specific coupling structure of the first cam 200 and the second cam 400.

The second cam 400 may be coupled while being inserted into the through hole 203 formed in the center of the first cam 200. In this case, the first cam 200 and the second cam 400 are spirally coupled to each other so that the first cam 200 is elevated as the second cam 400 rotates.

In more detail, a spiral protrusion 204 protruding while forming a spiral may be formed on an inner circumferential surface of the through hole 203 of the first cam 200. A spiral groove 401 may be formed on the outer circumferential surface of the second cam 400 to which the spiral protrusion 204 is spirally coupled.

At this time, the spiral groove 401 is formed in the width considering the required lifting width of the first cam 200 on the outer peripheral surface of the second cam 400. In addition, the spiral protrusion 204 is preferably formed to have a length forming a portion and a coupling portion in the circumferential length of the spiral groove 401 portion as shown in order to reduce friction with the spiral groove 401 portion.

Control dial 500 is coupled to the main cover 20 is configured to expose the top surface to the outside, the user adjusts the lifting of the first cam 200 while rotating the control dial 500 and the rotation of the spool 10 Speed is controlled step by step.

An upper surface of the control dial 500 may be formed with a grip portion 501 that can be held by a finger so that the user can easily rotate it.

The adjusting dial 500 is coupled to the upper end of the second cam 400 which is disposed on the upper side of the first cam 200 and exposed to the upper side of the first cam 200. Specifically, the coupling protrusion 402 is formed on the upper portion of the second cam 400 and the coupling groove 502 is formed on the lower side of the adjusting dial 500 so that the coupling protrusion 402 is coupled to the coupling groove 502. 2 cam 400 may be coupled to the control dial (500).

At this time, the second cam 400 is coupled so that rotation is constrained to the control dial 500. In order to restrict the rotation, the coupling protrusion 402 may be formed in a polygon or as shown in a chamfered portion on the outer surface, and the coupling groove 502 may be formed in a shape corresponding to the coupling protrusion 402.

In addition, the O-ring 403 is inserted into the coupling protrusion 402 so that the O-ring 403 is formed between the bottom surface of the coupling groove 502 forming portion and the upper surface portion of the second cam 400 at which the coupling protrusion 402 starts to protrude. Can be intervened. The O-ring 403 is made of rubber or silicone and has a soft and elastic rotational feeling when the user rotates by holding the control dial 500 due to the elastic deformation of the material.

The first cam 200 is elevated while the second cam 400 rotates in accordance with the rotation of the control dial 500 in a spirally coupled state to the second cam 400. The first cam 200 has a lifting width equal to the width of the spiral groove 401 formed in the second cam 400.

When the first cam 200 reaches the highest position in the lifting process, that is, when the magnet assembly 300 is farthest away from the spool 10, the spool 10 generates a magnetic force generated from the magnet assembly 300. It is ideal to be free by being unaffected or minimally affected.

In order to realize this, the height of the second cam 400 is designed to be large so that the width of the spiral groove 401 is large, and the first cam is designed to ensure sufficient space between the spool cover 100 and the adjusting dial 500. It is possible to cause the magnet assembly 300 to rise to a height that does not affect the spool 10 by causing the 200 to rise higher. However, since the overall size of the assembly is inevitably increased, the miniaturization of the assembled finished product is performed. It is placed in the design oriented bar to achieve.

Therefore, a width in which the first cam 200 can be raised may be further added within a predetermined design range regarding the height of the second cam 400, the width between the adjustment dial 500, the spool cover 100, and the like. Means or methods should be provided.

The present embodiment provides a fitting groove 510 on one side of the lower surface of the adjusting dial 500 by such means, and the fitting portion 210 protrudes from one side of the upper surface of the first cam 200 to protrude. According to the rotation, the fitting portion 210 is inserted into the fitting groove 510 or presents a structure for leaving.

In this embodiment, the rising width of the first cam 200 is further obtained by the moving width of the first cam 200 moving in the process of inserting the fitting portion 210 into the fitting groove 510 upwardly.

In more detail, the first cam 200 is raised in accordance with the rotation of the second cam 400 by the one-way rotation of the control dial 500, the point when the ascending ends, that is, the first cam 200 Spiral protrusion 204 of the) is to continue to rise with the restoring force by the elastic means 150 even after the point of escape from the spiral groove 401 of the second cam 400. However, since one side of the upper surface of the first cam 200 is supported by being in contact with one side of the lower surface of the control dial 500, the upper surface of the first cam 200 may not rise any more and maintains its position.

In this case, when the above-described fitting groove 510 and the fitting portion 210 are formed on one side of the lower surface of the adjusting dial 500 and one side of the upper surface of the first cam 200, the fitting portion 210 is fitted after the above-described time point. The first cam 200 is further increased by the width of the up and down direction of the fitting groove 510, that is, the width of the fitting portion 210 is inserted into the fitting groove 510 while the process of upwardly inserting into the 510 is formed. A section is prepared.

Here, the process of inserting the fitting portion 210 into the fitting groove 510 is preferably performed immediately after the above-described time point when the raising of the first cam 200 by the second cam 400 ends. Therefore, the position of the fitting groove 510 should also be formed at a position in consideration of this.

When the control dial 500 rotates in the other direction, the fitting portion 210 is forcedly released downward from the fitting groove 510 while the first cam 200 overcomes the restoring force by the elastic means 150 and descends again. Done. At this time, the outer inclined surface 211 on one side of the fitting portion 210 and the inner inclined surface on one side of the fitting groove 510 to correspond to the outer inclined surface 211 so that the downward departure of the fitting portion 210 is made naturally. 511 may be formed.

As the control dial 500 rotates, the outer inclined surface 211 of the fitting portion 210 is perpendicular to the outer inclined surface 211 by the inner inclined surface 511 of the fitting groove 510 (a direction inclined to the horizontal plane). ) Is transmitted, and the downward force of the first cam 200 is forced by the vertical component of the force.

Immediately after the fitting portion 210 deviates downward from the fitting groove 510, that is, immediately after the first cam 200 is forcedly lowered while receiving force directly from the adjusting dial 500 according to the rotation of the adjusting dial 500. Since the spiral protrusion 204 of the first cam 200 is spirally coupled to the spiral groove 401 of the second cam 400. After the spiral coupling, the first cam 200 is lowered by the rotation of the second cam 400 according to the continuous rotation of the control dial 500.

In other words, according to the present embodiment, as the adjustment dial 500 rotates, the first cam 200 is lowered while overcoming the restoring force of the elastic means 150, so that the adjustment cam 500 is spirally coupled to the second cam 400, and the adjustment dial Rotation of the second cam 400 by the continuous rotation of 500 causes the continuous lowering of the first cam 200.

Then, the first cam 200 is raised by the rotation of the second cam 400 as the control dial 500 rotates in reverse, and the fitting groove 510 immediately after the spiral protrusion 204 is separated from the spiral groove 401. As the fitting portion 210 is inserted into the first cam 200, the width of the first cam 200 is increased.

Meanwhile, ascending of the first cam 200 in the process of fitting the fitting portion 210 to the fitting groove 510 is caused by the spiral protrusion 204 of the spiral groove 401 by the rotation of the second cam 400. Compared with the rise of the first cam 200 made while moving along, there is a difference of vertically rising by the restoring force of the elastic means 150.

That is, when the first cam 200 is raised by the rotation of the second cam 400, the gradual rise is made, but the first cam 200 is inserted in the process of inserting the fitting portion 210 into the fitting groove 510. Ascending, there is a momentary rise vertically.

Therefore, the rotational speed is controlled by the magnetic assembly 300 by the magnet assembly 300 to be controlled in a section in which the first cam 200 is elevated according to the rotation of the second cam 400. As one cam 200 is gradually elevated, the strength of the magnetic force transmitted to the spool 10 may be finely adjusted gradually.

And when the first cam 200 is raised (magnet assembly 300 is raised) to the position (until the spool is free state) to the position where the magnetic force is not affected or at least affects the spool 10. By allowing the first cam 200 to instantaneously ascend in the section in which the portion 210 is inserted into the fitting groove 510, the user can easily when the rotational speed of the spool 10 is not braked by the magnet assembly 300. And it can be selected quickly, thereby improving the ease of use and operation of the bait cast reel.

On the other hand, the fitting portion 210 and the fitting groove 510 is not limited to the above-described example, the fitting groove 510 is on one side of the upper surface of the first cam 200, and the fitting portion 210 of the adjustment dial 500 The lower surface may be formed on one side.

The click sound generating spring 520 may be coupled to the adjustment dial 500. The click sound generating spring 520 is a generally annular spring with both ends spaced apart, and a protrusion 521 is formed at one side. And inserted and coupled to the inner surface of the control dial 500, the one side of the control dial 500 is formed with a cutout groove 503 protruding from the protrusion 521.

In addition, the inner surface of the main cover 20 in the circumferential direction in which the protrusion 521 is moved to the uneven surface 22 to generate a click sound as the protrusion 521 is inserted or released in accordance with the rotation of the control dial 500. It is formed continuously along.

Instructions (not shown) may be formed on the upper surface of the control dial 500 to gradually display the degree of rotation of the control dial 500 corresponding to the divided lifting degree of the magnet assembly 300, and in accordance with the indication of the guide. By rotating the adjustment dial 500, it is possible to control the rotational speed of the spool 10 step by step.

Since the present invention can be variously modified by those skilled in the art without departing from the scope of the claims claimed in the claims, the technical protection scope of the present invention is limited to the specific preferred embodiments described above. It is not limited.

10; Spool 11; Spool Shaft
20; Main cover 22; Uneven surface
100; Spool cover 101; Insert groove
102; Bearing 103; Retainer
104; Washer 110; Guide rod
150; Elastic means 200; First cam
201; Guide hole 202; Engaging portion
203; Through-hole 204; Spiral projection
210; Fitting 211; Outer slope
300; Magnet assembly 310; Magnet holder
320; Magnet 400; 2nd cam
401; Spiral groove 402; Engaging projection
403; O-ring 500; Control dial
501; Gripping portion 502; Joining groove
503; Incision groove 510; Groove
511; Inner slope 520; Click sound spring

Claims (9)

A spool cover disposed on an upper side of the spool, the spool shaft being coupled to the rotating material;
A first cam coupled to the upper side of the spool cover, the first cam being provided with a restoring force in an opposite direction to the spool by an elastic means provided between the spool cover;
A magnet assembly coupled to the first cam to move together in accordance with the elevation of the first cam;
A second cam helically coupled to the first cam so that the first cam is lifted according to rotation; And
The second cam is coupled so as to be rotationally constrained, and the first cam is further raised by the restoring force by the elastic means after the lifting of the first cam by the rotation of the second cam is completed as the second cam rotates in one direction. Or, the first cam is lowered while overcoming the restoring force by the elastic means as it rotates in the other direction; adjustment dial for spirally coupled with the second cam; Spool rotation control of the bait cast reel comprising a rescue.
The method according to claim 1,
A fitting groove is formed at one side of the lower surface of the adjusting dial, and a fitting portion is formed at one side of the upper surface of the first cam.
The first cam is further raised as the fitting portion is inserted upwardly into the fitting groove according to one direction rotation of the adjusting dial, or lowered as the fitting portion is separated downward from the fitting groove according to the other direction rotation of the adjusting dial. The spool rotation control structure of the bait cast reel, characterized in that it is spirally coupled to the cam.
The method according to claim 2,
An outer inclined surface is formed on one side of the fitting portion, and an inner inclined surface is formed on one side of the fitting groove corresponding to the outer inclined surface.
4. The method according to any one of claims 1 to 3,
A coupling part penetrating the spool cover is formed in the first cam,
The magnet assembly is coupled to the coupling portion and the spool rotation control structure of the bait cast reel, characterized in that disposed on the lower side.
The method of claim 4,
The magnet assembly includes a magnet holder coupled to the coupling part, and a plurality of magnets housed in the magnet holder.
4. The method according to any one of claims 1 to 3,
A bait cast reel, wherein a guide rod protruding upward from the upper side of the spool cover is formed, and a guide hole into which the guide rod is inserted is formed in the first cam, and the first cam is guided along the guide rod. Spool rotation control structure.
The method of claim 6,
The elastic means is made of a coil spring, the coil spring is inserted into the guide rod spool rotation control structure of the bait cast reel, characterized in that the upper end is caught on the bottom surface of the guide hole forming portion of the first cam.
4. The method according to any one of claims 1 to 3,
A coupling protrusion is formed on an upper portion of the second cam, and a coupling groove is formed on a lower side of the control dial.
The second cam is a spool rotation control structure of the bait cast reel, characterized in that the coupling projection is coupled to the coupling groove while being rotationally constrained to the adjustment dial.
The method according to claim 8,
The spool rotation control structure of the bait cast reel, characterized in that the coupling ring is fitted with an O-ring.

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